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DEPARTMENT OF MINERALS AND ENERGY
GEOLOGICAL SURVEY OF WESTERN AUSTRALIA
RECORD19985
A REVIEW OF DATA PERTAINING TO THEHYDROCARBON PROSPECTIVITY OF THE
SAVORY SUB-BASIN OFFICER BASINWESTERN AUSTRALIA
by M K Stevens and G M Carlsen
GOVERNMENT OFWESTERN AUSTRALIA
GEOLOGICAL SURVEY OF WESTERN AUSTRALIA
Record 19985
A REVIEW OF DATA PERTAINING TO THE HYDROCARBON PROSPECTIVITY OF THE SAVORY SUB-BASIN OFFICER BASIN WESTERN AUSTRALIA by M K Stevens and G M Carlsen Perth 1998
MINISTER FOR MINES The Hon Norman Moore MLC DIRECTOR GENERAL L C Ranford DIRECTOR GEOLOGICAL SURVEY OF WESTERN AUSTRALIA David Blight The recommended reference for this publication is STEVENS M K and CARLSEN G M 1998 A compilation and review of data pertaining to the
hydrocarbon prospectivity of the Savory Sub-basin Officer Basin Western Australia Western Australia Geological Survey Record 19985 65p
National Library of Australia Card Number and ISBN 0 7309 6588 0 Copies available from Information Centre Department of Minerals and Energy 100 Plain Street EAST PERTH WESTERN AUSTRALIA 6004 Telephone (08) 9222 3459 Facsimile (08) 9222 3444
iii
Contents Abstract 1
Introduction 2
Access and climate 4
Regional geology 6
Stratigraphy 6
Depositional Sequence A Supersequence 1 11
Depositional Sequence B Supersequence 1 11
Depositional Sequence C Supersequence 3 14
Depositional Sequence D Supersequence 4 14
Depositional Sequence E Supersequence 4 14
Other depositional sequences and regional correlations 14
Structural setting 17
Exploration history 19
Hydrocarbon potential 19
Source rocks 22
Maturity 23
Reservoirs 25
Seals 25
Traps 26
Preservation of hydrocarbons 26
Reported hydrocarbon shows and oil seep 27
Geological and geophysical data bases 27
Drilling 28
Petroleum industry data 28
Government data 28
Mineral industry data 28
Hydrogeological data 29
Seismic data 29
Aeromagnetic surveys 29
Government data 29
Mineral industry data 30
Gravity surveys 30
Government data 30
Mineral industry data 30
Government and academic reports 32
Chronostratigraphy and geochemistry 32
Proposed work program 32
Conclusions 33
References 35
iv
Appendices
1 Bibliography 41
2 Meteorological data 44
3 Summary of palynological results 47
4 Cowan Geodata Services Report Savory Sub-basin quantitative magnetic and gravity
interpretation 48
5 Geochemistry 61
6 TWB and BWB waterbore data 64
Figures
1 Structural subdivisions of the Savory Sub-basin 3
2 Localities and access routes of the Savory Sub-basin 5
3 Formations lithology and depositional sequences AndashE of the Savory Sub-basin 7
4 Correlation of Savory Sub-basin formations with the western Officer and Amadeus Basins 10
5 Locations of petroleum exploration wells mineral exploration and stratigraphic drillholes
and waterbores and wells 12
6 Geological cross section through significant drillholes 13
7 Regional geological setting of the Savory Group and western Officer Basin 15
8 Locations of aeromagnetic and gravity surveys 21
9 Petroleum source potential of rocks in Normandy LDDH1 24
10 Regional Bouguer gravity map of the Savory Sub-basin 31
11 Detailed Bouguer gravity map of the Savory 1995 Gravity Survey from the
eastern Savory Sub-basin 31
Tables
1 Summary of formations in the Savory Sub-basin 8
2 Neoproterozoic formations and hydrocarbon shows in diamond drillholes in the
Savory Sub-basin 20
~Version Information13 VERS 120 CWLS log ASCII Standard -VERSION 12013 WRAP NO One line per depth step131313~Well Information Block13MNEMUNIT Data Type Description13--------- ------------ -----------------------------13 STRTM 5000013 STOPM 00013 STEPM -10013 NULL -9992513 COMP COMPANY GEOLOGICAL SURVEY OF WA 13 WELL WELL TWB 6 13 FLD FIELD SAVORY SUB-BASIN 13 LOC LOCATION AGD84 Z51 457 013E 7 274 352N 13 PROV PROVINCE WESTERN AUSTRALIA 13 SRVC SERVICE COMPANY BPB Wireline Services 13 DATE LOG DATE 16-NOV-1995 13 UWI UNIQUE WELL ID 131313~Curve Information Block13MNEMUNIT Curve Description13--------- -----------------------------13 DEPTM DEPTH13 GRNPGAPI GAMMA FROM NEUTRON TOOL 13 LSN SNU LONG SPACED NEUTRON 13 SSN SNU SHORT SPACED NEUTRON 13 RPOR LIMEST NEUTRON POROSITY 13 BISIMM BIT SIZE 131313~Other Information13NEUTRON POROSITY GAMMA RAY LOG 13LOGGED THROUGH PVC CASING 13 13 13 13Run number ONE Log 1st rdg 497 M Log last rdg 0 M 13Driller TD 50 M Logger TD 50 M Water level 8 M 13Perm Datum GL Elevation Approx 455 M Other srvcs 13Dril mes from GL Log meas from GL 0 M Other srvcs 13Elevation KB DF GL 13Casing Driller Casing Logger Casing size 100 MM 13Casing Weight PVC From 0 M To 50 M 13Bit size 168 MM From 4 M To 50 M 13Hole fl type WATER Sample source Fluid loss 13Density Viscosity pH 13RM meas tmp RMF mes tmp RMC mes tmp 13RM BHT RMF source RMC-source 13Max rec temp Time snc circ LsdSecTwpRge 13Equipment no V338 Base PERTH Equip name NN1 13Recorded by RALEES Witnessed by MKSTEVENS Sonde srl no 5094421 13Last title Last line Permit no 131313~A Depth GRNP LSN SSN RPOR BISI13 50000 -999250 -999250 -999250 -999250 15000013 49900 -999250 -999250 -999250 -999250 15000013 49800 -999250 -999250 -999250 -999250 15000013 49700 -999250 -999250 -999250 -999250 15000013 49600 -999250 -999250 -999250 -999250 15000013 49500 -999250 -999250 -999250 -999250 15000013 49400 -999250 216309 1965945 21484 15000013 49300 -999250 209718 1885054 18983 15000013 49200 -999250 193254 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148502 66359 1135554 60513 15000013 11600 146344 65256 1144473 63405 15000013 11500 140639 67052 1155714 61884 15000013 11400 138609 70143 1161241 58545 15000013 11300 136776 73383 1169782 54179 15000013 11200 140599 75074 1173990 51426 15000013 11100 142383 75594 1170913 49375 15000013 11000 146689 73705 1165449 50863 15000013 10900 148521 71791 1160990 52515 15000013 10800 152867 71060 1157285 52997 15000013 10700 153980 72615 1151444 50977 15000013 10600 155133 73532 1148806 50120 15000013 10500 154798 74448 1146042 49180 15000013 10400 155143 74795 1141835 48723 15000013 10300 150739 74820 1146545 49611 15000013 10200 145615 74256 1162183 51824 15000013 10100 140314 73748 1179894 53805 15000013 10000 139496 74244 1193836 53861 15000013 9900 137899 74696 1198672 53426 15000013 9800 141614 73779 1197165 55069 15000013 9700 145033 73538 1182029 55380 15000013 9600 150699 72739 1173048 57444 15000013 9500 148541 73606 1171039 57487 15000013 9400 146275 73637 1176063 58552 15000013 9300 141417 76932 1173613 53695 15000013 9200 140215 77267 1169469 51590 15000013 9100 135456 79274 1158980 46718 15000013 9000 135505 78289 1140704 45690 15000013 8900 135554 78357 1117969 43463 15000013 8800 138323 75204 1091780 44805 15000013 8700 138116 72386 1069673 46168 15000013 8600 139801 69041 1056798 48906 15000013 8500 142186 66576 1059499 51986 15000013 8400 145871 66774 1060629 52960 15000013 8300 146167 75824 1085123 49709 15000013 8200 145733 110647 1183474 41583 15000013 8100 143999 183764 1349401 30789 15000013 8000 142944 286898 1563185 18346 15000013 7900 143151 400172 1777220 8089 15000013 7800 147359 503448 1973607 1414 15000013 7700 153803 580436 2074722 -1884 15000013 7600 160089 619565 2099718 -3567 15000013 7500 162996 629928 2079934 -4067 15000013 7400 165952 636085 2075915 -4206 15000013 7300 164859 642217 2065615 -4382 15000013 7200 161459 639913 2054875 -4355 15000013 7100 158168 626360 2029503 -4206 15000013 7000 157961 613680 1982840 -4213 15000013 6900 158405 600970 1941515 -4233 15000013 6800 158887 594262 1919785 -4253 15000013 6700 161439 596207 1928012 -4289 15000013 6600 163469 607945 1948360 -4430 15000013 6500 163972 618543 1980830 -4468 15000013 6400 161232 620302 2002434 -4364 15000013 6300 163991 612727 2014430 -4100 15000013 6200 167519 603658 2025358 -3808 15000013 6100 177244 597935 2043068 -3542 15000013 6000 183265 597340 2061784 -3404 15000013 5900 193424 599465 2080186 -3331 15000013 5800 193690 609524 2106186 -3401 15000013 5700 191335 633694 2134636 -3731 15000013 5600 179156 661364 2181174 -4027 15000013 5500 170465 686407 2232045 -4214 15000013 5400 159242 703441 2274940 -4297 15000013 5300 153596 713860 2296230 -4373 15000013 5200 148068 710763 2298052 -4316 15000013 5100 146314 703553 2285177 -4259 15000013 5000 141792 695847 2259302 -4274 15000013 4900 136195 695605 2243475 -4358 15000013 4800 129948 700313 2248060 -4425 15000013 4700 125563 710329 2272239 -4478 15000013 4600 123888 720971 2302573 -4509 15000013 4500 123375 724638 2335734 -4385 15000013 4400 121306 727790 2376619 -4210 15000013 4300 118360 734871 2410407 -4137 15000013 4200 113591 747408 2455815 -4106 15000013 4100 107423 759307 2497265 -4090 15000013 4000 100712 773950 2542610 -4111 15000013 3900 93096 774991 2547759 -4092 15000013 3800 86100 750839 2503546 -3812 15000013 3700 80562 693128 2369397 -3394 15000013 3600 78611 618915 2159507 -3108 15000013 3500 78325 537752 1896484 -3046 15000013 3400 79419 465812 1644579 -3150 15000013 3300 81084 411532 1432490 -3451 15000013 3200 82897 383429 1290240 -3871 15000013 3100 81922 368631 1215692 -4084 15000013 3000 78838 363341 1202503 -4031 15000013 2900 76699 359922 1217074 -3739 15000013 2800 74748 360696 1248727 -3411 15000013 2700 73941 362368 1281259 -3104 15000013 2600 72295 370049 1311342 -3054 15000013 2500 72472 375308 1327357 -3070 15000013 2400 72975 381292 1336464 -3198 15000013 2300 72965 381862 1333198 -3256 15000013 2200 71260 385237 1323840 -3471 15000013 2100 70108 388167 1314545 -3642 15000013 2000 69467 398450 1319109 -3935 15000013 1900 68994 411724 -999250 -999250 15000013 1800 68186 -999250 -999250 -999250 15000013 1700 66935 -999250 -999250 -999250 15000013 1600 63259 -999250 -999250 -999250 15000013 1500 57318 -999250 -999250 -999250 15000013 1400 49681 -999250 -999250 -999250 15000013 1300 44153 -999250 -999250 -999250 15000013 1200 39591 -999250 -999250 -999250 15000013 1100 37896 -999250 -999250 -999250 15000013 1000 37887 -999250 -999250 -999250 15000013 900 38872 -999250 -999250 -999250 15000013 800 38448 -999250 -999250 -999250 15000013 700 37394 -999250 -999250 -999250 15000013 600 36960 -999250 -999250 -999250 15000013 500 35896 -999250 -999250 -999250 15000013 400 35827 -999250 -999250 -999250 15000013 300 35709 -999250 -999250 -999250 15000013 200 36872 -999250 -999250 -999250 15000013 100 37778 -999250 -999250 -999250 15000013 000 40399 -999250 -999250 -999250 15000013
1
A review of data pertaining to the hydrocarbon prospectivity of the Savory Sub-basin Officer Basin
Western Australia
by
M K Stevens and G M Carlsen
Abstract
The Savory Sub-basin of the Officer Basin in central Western Australia is part of a large Neoproterozoic episutural basin and is a frontier for hydrocarbon exploration It contains up to 8 km of clastic carbonate and rare evaporite sedimentary rocks with minor volcanic dykes sills and flows No petroleum exploration activity had been undertaken in this sub-basin prior to 1995 and hydrocarbon prospectivity is assessed from mineral and recent petroleum exploration drilling No seismic data have been acquired An interpretation of available data suggests that source-rock quality is the major exploration risk but that further investigation of the sub-basin is warranted
Minor oil shows (fluorescence with solvent cut) recorded in Spearhole Formation sandstones in the northwest of the sub-basin suggest oil has been generated and migrated into potential reservoirs in the sub-basin
Each of the five depositional sequences recognized in the sub-basin contain potential reservoir rocks which are seen in outcrop as friable sandstones The Durba Sandstone is interpreted as the best-quality reservoir Indications of evaporitic environments from the Mundadjini Skates Hills and Boondawari Formations suggest that seals may be provided by evaporites and mudstones Neoproterozoic to Cambrian rocks may provide structural closures including both fold and fault traps for migrating hydrocarbons Salt diapirs are interpreted from the gravity data A large semi-detailed gravity survey in the eastern part of the sub-basin revealed major folds faults and halokinetic structures
Potential source rocks include marine mudstones of the Skates Hills and Mundadjini Formations which are associated with stromatolitic dolomites and evaporites Rare outcrops of black mudstones from other units such as the Boondawari Formation also suggest source potential
The Geological Survey of Western Australia has drilled one stratigraphic hole (Trainor 1) in the sub-basin to assess the source potential of Neoproterozoic sedimentary rocks Five of the six samples analysed for Total Organic Carbon in the Cornelia Formation from this well exceeded 05 but have a high level of maturation with at best dry gas-generating potential The age of the Cornelia Formation is uncertain but at least part of it is interpreted to be Neoproterozoic and hence part of the Savory succession
Maturity data which are very sparse due to limited drilling are inferred from the Thermal Alteration Index of organic matter to be at about the base of the oil window and the top of the gas window in two
2
waterbores in the southeast of the sub-basin and a mineral drillhole in the north of the region Rock cuttings from a waterbore in the southwest of the sub-basin are overmature for hydrocarbon generation but this bore intersected mafic intrusives and hence may not be representative of maturity for the region
KEYWORDS hydrocarbon prospectivity oil shows Neoproterozoic Savory Sub-basin Officer Basin source rocks diamond drilling
Introduction
Recognition in the late 1980s of a thick sequence of generally weakly deformed Neoproterozoic
sedimentary rocks of relatively low thermal maturity previously included within the
Mesoproterozoic Bangemall Basin (defined as the Savory Basin by Williams 1992) revealed a
hydrocarbon exploration frontier The Savory Sub-basin (Fig 1) now recognized as part of the
Officer Basin is located west of outcrops of Phanerozoic cover rocks of that larger basin The
Officer Basin a large episutural basin which contains clastic carbonate and minor evaporite and
volcanic rocks is considered to be part of the Neoproterozoic Centralian Superbasin (Walter and
Gorter 1994) The age of the Officer Basin successions is not well constrained but in the Savory
Sub-basin it is largely Neoproterozoic with possible Palaeozoic strata present in parts
The boundaries defined by Williams (1992) for the sub-basin have been largely used in this
record but data from sedimentary rocks previously assigned to older basins that are now
recognised or inferred to be of early Neoproterozoic age (Supersequence 1) have been used to
assess the hydrocarbon potential of the northwestern part of the Officer Basin
The southern part of the sub-basin unconformably overlies the Mesoproterozoic Bangemall Basin
The western boundary of the sub-basin is faulted against the Bangemall Basin The eastern
boundary of the Savory Basin as defined by Williams (1992) was placed along the western edge
of Phanerozoic outcrops of the Officer Basin at approximately 123degE longitude Recent studies
(Perincek 1996ab) however have indicated there is little difference in the Neoproterozoic
geology of the two regions The northeastern boundary of the sub-basin was defined as a reverse-
and thrust-faulted contact with the Yeneena and Karara Basins of the Paterson Orogen (Williams
1992) However Bagas et al (1995) subdivided strata from the Yeneena Basin into three new
groups the Throssell Lamil and Tarcunyah Groups The older and more deformed Throssell and
Lamil Groups remain part of the Yeneena Basin and the Paterson Orogen The younger and less-
deformed sedimentary rocks of the Yeneena and Karara Basins were considered to be of
Supersequence 1 age and were reassigned to the Tarcunyah Group The Tarcunyah Group was
considered to be coeval with the older strata of the Savory Sub-basin The Tarcunyah Group
Savory Sub-basin and Officer Basin were grouped into a single tectonic unit which was informally
referred to as the greater Officer Basin (Bagas et al 1995)
3
50 km
120deg 121deg30 123deg
25deg
24deg
23deg
22deg
Blake Fault andFold Belt
Wells Foreland S
ub-basin
TrainorPlatform
MKS32200498
HamersleyBasin
PilbaraCraton
YeneenaBasin
YeneenaBasin
YeneenaBasin
CanningBasin
Sylvania Inlier
BangemallBasin
Bangemall Basin
YilgarnCraton
YilgarnCraton
GlengarryBasin
EaraheedyBasin
Ward Inlier
OldhamInlier
KararaBasin
GibsonSub-basin
(Officer Basin)
WestwoodShelf
(Officer Basin)
KingstonShelf
(Officer Basin)
Rudall Complex
Trainor Platform
(Kahrban Subgroup)
Greater Officer Basin
Savory Sub-basin
Surface anticlinesMAP
AREAPerth
Figure 1 Structural subdivisions of the Savory Sub-basin and surface anticlines
4
During 1994 in consultation with the Petroleum Industry the Department of Minerals and
Energy received State Government funding for a Petroleum Exploration Initiative to be
undertaken by the Geological Survey of Western Australia (GSWA) with a view to identifying
prospective onshore areas for oil and gas thus increasing the level of onshore exploration in
Western Australia This initiative was originally funded for the first three years of a five-year work
program Two teams of specialists were formed to investigate the prospectivity of both the western
margin and interior onshore sedimentary basins
The Petroleum Exploration Initiative teams seek to enhance the prospectivity of onshore
basins by reducing through focused investigations the risks perceived by industry to be factors
limiting exploration activity Comprehensive petroleum system reports of the onshore Western
Australian basins are to be completed as a result of the projects undertaken during the five-year
Initiative The objective of the Initiative will be achieved through both the analysis of open-file
exploration data and the acquisition of new data New data will include but not be limited to
geophysical surveys and stratigraphic drilling Project results are to be reported to the industry
through GSWA publications external publications conference reports and oral presentations
This Record is the third in a series of comprehensive reviews by the GSWA of the
hydrocarbon prospectivity of some of Western Australiarsquos interior onshore sedimentary basins
The first Record of this series covered the Canning Basin (Apak and Carlsen 1997) The second
Record reviewed the Western Australian Officer Basin (Perincek 1998) but excluded the Savory
Sub-basin
This study assesses the potential for hydrocarbon exploration within the Savory Sub-basin
based on available geological and geophysical data and defines the scope for future studies
Publications relevant to this investigation but which are not specifically referred to are listed in
Appendix 1
Access and climate
The Savory Sub-basin lies east and southeast of the mining town of Newman in the Pilbara region
(Fig 2) The area is largely uninhabited the only settlement being an outcamp at Poondawari on
the GUNANYA 1250 000 map sheet The outcamp is linked by a graded track to the Jigalong
Community 90 km to the west just outside the northwest margin of the sub-basin A few pastoral
leases lie along the margins of the sub-basin but the majority of the region is Vacant Crown Land
Capitalized names refer to standard map sheets
5
Sealed road
Gravel road
Track
Town
Homestead
Locality
STANLEYSavory Sub-basin boundary 1250 000 map sheet
CornerTrack
Talawana - Windy
Route
Watch Point
NEWMAN
JigalongCommunity
RobertsonRange (abd)
Wokalba
Poondawari
Balfour Downs
Billinnooka
Weelarrana
Beyondie(abd)
Kumarina
Marymia
Glen-ayle
White Lake
Hanging RockBoorabee Hill
WellsRa
EmuRa
Robertson
Ra McFadden R
a
DiebillHills
DurbaHills
Calvert Ra
WardHills
Cornelia Ra
KellyRaBlakeHills
HillsDean
ROBERTSON GUNANYA
TRAINORBULLEN
BALFOUR DOWNS RUDALL
NABBERU STANLEY HERBERT
50 km
Woora Woora Hills
120deg 121deg30 123deg
25deg
24deg
23deg
22deg
Goldfieldsnatural gaspipeline
GR
EA
TN
OR
TH
ER
NH
IGH
WA
Y
Mar
ble
Bar
Nul
lagi
ne-
Rd
MADLEY
Can
ning
Stoc
k
MKS31120598
Goldfields natural gas pipeline
Figure 2 Localities and access routes of the Savory Sub-basin
6
The sealed Great Northern Highway lies west of the Savory Sub-basin and links Meekatharra
to Newman The TalawanandashWindy Corner graded track crosses the northern part of the sub-basin
and graded pastoral station tracks on Balfour Downs Weelarrana Kumarina Marymia and Glen-
Ayle give access to the western and southern margins The Canning Stock Route traverses the sub-
basin from north to south and is a well travelled four-wheel-drive track allowing access to the
eastern half of the sub-basin Additional minor tracks also provide access to other parts of the area
(Williams 1992) Recently flown monochrome aerial photography at 150 000 and Landsat TM
imagery covering the sub-basin is available from the Department of Land Administration
Cross-country access is similar to that in the Canning Basin with the average height of sand
dunes being lower in the Savory Sub-basin Potable water has been found in water bores in the
south of the sub-basin and is inferred to be present throughout the region Fuel and supplies are
available at Wiluna Meekatharra and Newman A good working relationship with the Western
Desert Community who hold native title claims over most of the sub-basin has been established
by GSWA
There are no meteorological stations within the Savory Sub-basin but estimates based on data
from nearby Bureau of Meteorology Stations indicate that the area is arid and has its maximum
rainfall in summer from monsoonal rains The sub-basin has reasonable access and a tolerable
working climate for all exploration activities Meteorological data for the town of Wiluna which
lies about 180 km to the south of the sub-basin are included as Appendix 2
Regional geology
Stratigraphy
Thirteen formations were recognized by Williams (1992) in the Savory Sub-basin and these are
summarized in Table 1 Although unconformities were recognized between some of the
formations and they reflect a wide range of depositional environments provenance and climatic
conditions these formations were defined by Williams (1992) as constituting the Savory Group
Five depositional sequences that are generally unconformity-bounded were recognized by
Williams (1992) (Fig 3) The correlation of significant formations within the sub-basin with other
parts of the Centralian Superbasin is shown in Figure 4 with the four Neoproterozoic
Supersequences having been defined by Walter et al (1995)
7
Durba Ss
McFadden
Woora Woora400
Tchukardine700
Skates Hills
Mundadjini1800
B
Coondra
(B)
Watch Point
Spearhole1100Jilyili
1000(A)
Glass Spring1600(A)
Brassey Range1700(A)
Abs
ent
Absent Absent
Absent
Absent
Absent
A
B
C
D
E
1A
1B
3
4A
4B
1000
2000
3000
4000
5000
6000
Max
imum
thic
knes
s
Sup
erse
quen
ce
AG
EN
EO
PR
OT
ER
OZ
OIC
NE
OP
RO
TE
RO
ZO
ICT
O
CA
MB
RIA
NM
AR
I-N
OA
N
NW SE
Savory Sub-basin Stratigraphy
MKS30 120598
Fault boundary
Unconformity
Disconformity
Conglomerate
Sandstone Mudstone
Siltstone
Evaporite
Dolomite
Boondawari800 Boondawari
Supersequence 2 is not represented in the Savory Sub-basin Total thicknesses are estimated from air photo interpretation Thicknesses of recessive units are unknown
Diamictite
Dep
ositi
onal
seq
uenc
e
Figure 3 Formations lithology and depositional sequences AndashE of the Savory Sub-basin
8
Table 1 Summary of formations in the Savory Sub-basin
Formation Super Depo Lithology Thickness Depositional Savoy Comments Seq(a) Seq(b) (m) environment Group(c)
Durba Sandstone 4 E Quartz sandstone with minor 100 Fluvial lacustrine Y Excellent reservoir basal conglomerate lenses Woora Woora 4 D Medium-grained ferruginous 400 Shallow marine deltaic Y Formation sandstone lithic sandstone quartz wacke siltstone McFadden 4 D Laminated fine- to coarse-grained 1 500 Shallow marine deltaic Y Possible reservoir Formation quartz sandstone feldspathic sandstone quartz wacke minor conglomerate siltstone Tchukardine 4 D Medium- to coarse-grained sandstone 700 Shallow marine Y Formation lithic sandstone quartz wacke conglomerate lenses siltstone minor shale Boondawari 3 C Glacigene diamictite sandstone siltstone Formation shale conglomerate minor dolomite (some stromatolitic and oolitic) rhythmite 800 Glacial shallow marine Y Possible source rock Skates Hills 1 B Thin-bedded dolomite (some stromatolitic) 200 Shallow marine sabkha Y Possible source rock Formation chert evaporites fine- to medium-grained sandstone siltstone shale patchy basal conglomerate Mundadjini 1 B Fine- to coarse-grained sandstone 1 800 Deltaic sabkha Y Possible source rock Formation conglomerate siltstone minor shale shallow marine mudstone dolomite (some stromatolitic) and evaporites Coondra 1 B Coarse- to medium-grained sandstone 1 000 Fan delta Y Possible reservoir Formation poorly sorted conglomerate pebbly sandstone Spearhole 1 B Coarse- to medium-grained sandstone 1 100 Braided fluvial deltaic Y Possible reservoir Formation pebbly sandstone siltstone and oil shows in conglomerate lenses Mundadjini 1 Boondawari 1
9
Watch Point 1 B Shale siltstone fine- to medium-grained 400 Shallow marine deltaic Y Formation sandstone glauconitic sandstone Jilyili Formation 1 A Fine-grained sandstone siltstone minor shale mudstone conglomerate lenses 1 000 Deltaic Y Brassey Range 1 A Fine- to medium-grained sandstone 1 700 Fluvial deltaic Y Formation siltstone shale minor mudstone Glass Spring 1 A Medium- to coarse-grained sandstone 1 600 Shallow marine fluvial Y Formation minor conglomerate and siltstone Tarcunyah Group 1 AampB Quartz sandstone feldspathic sandstone Shallow marine sabkha N Bitumen in LDDH1 quartz wacke shale siltstone fluvial lacustrine conglomerate evaporites dolomite Cornelia 1 A Sandstone siltstone shale mudstone Shallow marine N Overmature source rocks Formation minor glauconitic sandstone deep marine in Trainor 1 Kahrban 1 A Sandstone siltstone shale 1 700 Shallow marine deltaic N Subgroup
NOTES (a) Supersequences of Walter et al (1995) (b) Depositional sequences of Williams (1992) (c) Y= assigned to Savory Group in Williams (1992) N= previously considered to be older than the Savory Group but now included in the greater Officer Basin
10
SAVORY SUB-BASIN GIBSON SUB-BASINCENTRAL OFFICERBASIN
AMADEUS BASIN
PETERMANN RANGES OROGENY
NE
OP
RO
TE
RO
ZO
IC
ST
UR
TIA
NM
AR
INO
AN
ED
IAC
AR
IAN
CAMBRIANTO
NEOPRO-TEROZOIC
AG
E (
Ma)
SOUTHS RANGE MOVEMENT
AREYONGA MOVEMENT
Steptoe
MILES OROGENY
Mission Group
Cassidy Group
Rudall Complex
Bangemall Group
unnamed
Tar
cuny
ah G
roup
4
3
2
1
MKS12a 180598
500
550
600
650
700
750
800
850
900
SU
PE
R
SE
QU
EN
CE
unnamed
Tchukardine Fm
McFadden Fm
ArumberaSst
Julie Fm
Pertatataka Fm
Olympic FmPioneer Sst
Boondawari Fm
Turkey Hill FmLupton Fm
Kanpa Fm
Neale FmBabbagoola
FmHussar
Fm
Browne Fm
Woolnough Fm
Madley Fm
Bitt
er S
prin
gs F
m
LovesCreek M
Gillen M
Heavitree Fm
Arunta Complex
Throssell Group
TownsendQuartzite
Earaheedy Group
olderCornelia Fm
Jilyili Fm
SpearholeFm
MundadjiniFm
Skates Hills Fm
Lefroy Fm
Areyonga Fm
Aralka Fm
ME
SO
-P
RO
TE
RO
ZO
IC
Waters Fm
youngerCornelia Fm
Brassey RangeFormationKahrban
Subgroup
GlassSpring
Fm
Durba Sst
LP1ALP1B EVENT
Figure 4 Correlation of Savory Sub-basin formations with the western Officer and Amadeus Basins Fm = Formation Sst = Sandstone M = Member
11
The depositional sequences recognized in the sub-basin are an order of magnitude thicker than
those described from Phanerozoic passive-margin settings (Payton 1977 Posamentier et al 1988)
and are broadly comparable in scale to the second-order cycles of Vail et al (1977) and to the
megasequences of Hubbard et al (1985) The main subsurface data available to reveal the
unweathered nature of these rocks are Trainor-1 and the three-well diamond coring program in
Petroleum Permit EP 380 (Akubra 1 Boondawari 1 Mundadjini 1) completed in late 1997 in the
central west of the sub-basin (Figs 5 and 6)
The ages of all formations in the Savory Sub-basin are poorly constrained The only fossils
known are stromatolites and palynomorphs (acid-insoluble microfossils) Palynology from
available wells is summarized in Appendix 3 from Grey and Stevens (1997) and Grey and Cotter
(1996) and correlations using stromatolite biostratigraphy (Stevens and Grey 1997 Grey 1995f
Walter et al 1994 1995) are consistent with a Neoproterozoic age for the formations for which
data are available
A dolerite within the Boondawari Formation gave a poorly constrained RbndashSr age of about
640 Ma (Williams 1992) SHRIMP UndashPb dating of sedimentary zircons from the McFadden and
Cornelia Formations in stratigraphic drillhole Trainor 1 are discussed in Stevens and Adamides (in
prep) and Nelson (1997) The youngest ages from these analyses indicate that the maximum age
of the Cornelia Formation is Early Cambrian or Sturtian but these ages are inconsistent with
previous tectonic interpretations (Williams 1992) and current stratigraphic correlations which
suggest the Cornelia Formation is of Supersequence 1 age or older (Fig 4)
Depositional Sequence A Supersequence 1
Depositional Sequence A includes the Glass Spring Jilyili and Brassey Range Formations (Fig
3) All of these units are predominantly quartzose sandstones some of which are friable and have
significant visible porosity in outcrop Conglomerates are present in the Glass Spring and Jilyili
Formations
Depositional Sequence B Supersequence 1
Depositional Sequence B consists of the Watch Point Coondra Mundadjini Spearhole and
Skates Hills Formations (Fig 3) All of these formations contain beds of quartzose sandstone and
some also contain conglomerates The porosity of dolomites in the Skates Hills Formation appears
poor in surface exposures but its subsurface characteristics are unknown
12
50 km
120deg 121deg30 123deg
25deg
24deg
23deg
22deg
Greater Officer Basin
PNCEXP CA11PNCEXP CA12
PNCEXP CA13PNCEXP CA19
PNCEXP CA05
PNCEXP CA09
BD134589
GSWA Trainor 1 and TWB123
Fortescue River 1A
Mundadjini 1
Akubra 1Boondawari 1
TWB4TWB5
TWB6
TWB7
TWB8
TWB9
TWB10
BWB1
BWB2 BWB3
BWB4
BWB5
OD23
Mineral exploration drillhole
Stratigraphic drillhole
Waterbores and wells(TWB and BWB serieswaterbores identified)
MKS33270398
LDDH 1
Savory Sub-basin
Canning SR Well 13
EP380
Petroleum Exploration permit
Petroleum exploration well
Figure 5 Locations of petroleum exploration wells mineral exploration and stratigraphic drillholes water bores and wells and petroleum exploration permit EP380 in the Savory Sub-basin
13
TD=600m
TD=1367m
TD=701m
TD=709m
TD=50m
SS
1S
S1
SS1
SS
1S
S1
SS
1
SS
1
SS1
SS4 SS1
Pha
nero
zoic
or
SS
2
Cz
CzCz
Karst Bitumen
SS1
TD=181m
Mundadjini 1 Akubra 1 Boondawari 1 LDDH 1 Trainor 1 TWB 6
Munda-djini Fm
Spear-hole Fm
Munda-djini Fm
Munda-djini Fm
Spear-hole Fm
Spear-hole Fm
Waters Fm
McFadden Fm
Cornelia Fm
Cornelia Fm
Cornelia Fm
511 plusmn 13Maor 696 plusmn 20Ma(maximum)
779 plusmn 10Ma(maximum)
Mundadjini 1
Akubra 1 Boondawari 1
LDDH 1
Trainor 1TWB 6100 km
N
LOCATION
NW SE
Sea level
0m AHD
Dolerite basalt
Conglomerate
Sandstone
Mudstone
Dolomite
Limestone
Evaporite
TOC gt08
Permeability gt100md
Oil fluorescence
Sedimentary zircon U-Pb age
Identifiable polymorphs
Cainozoic
Supersequence 1 age
Unconformity
Formation contact
Cz
SS1
r
r
0
100
200
metres
VerticalScale
MKS36 120598
LEGEND
Figure 6 Geological cross section through significant drillholes in the Savory Sub-basin
14
Depositional Sequence C Supersequence 3
Depositional Sequence C consists of the Boondawari Formation (Fig 3) and although it contains
sandstone conglomerate and dolomite the sandstones contain significant amounts of feldspar and
clay and hence are likely to be poorer reservoirs than older sandstones
Depositional Sequence D Supersequence 4
Depositional Sequence D includes the McFadden Tchukardine and Woora Woora Formations
(Fig 3) The McFadden Formation is poorly sorted and sandstones contain significant amounts of
feldspathic clasts in the north of the basin but are significantly coarser and cleaner in the northeast
of the sub-basin (Williams 1992)
Sandstones of the Tchukardine and Woora Woora Formations are generally cleaner than those
of the McFadden Formation and are expected to have fair to good porosity although the
Tchukardine Formation has a higher clay content in parts
Depositional Sequence E Supersequence 4
Depositional Sequence E consists of the Durba Sandstone (Fig 3) a coarse sandstone with minor
conglomerate which has good to excellent visible porosity in surface exposures
Other depositional sequences and regional correlations
Sedimentary rocks which were not included in the Savory Group by Williams (1992) but which
are likely to be of Neoproterozoic age and hence part of the greater Officer Basin include the
Tarcunyah Group the Cornelia Formation and the Kahrban Subgroup
As discussed in the Introduction all of the strata in the Karara Basin and the younger strata
of the Yeneena Basin were redefined to form the Tarcunyah Group of the greater Officer Basin
(Bagas et al 1995) (Fig 7) In outcrop the Tarcunyah Group consists predominantly of quartzose
feldspathic and arkosic sandstone shale which is carbonaceous in parts and carbonate which
includes stromatolitic dolomite Mineral hole LDDH1 drilled on GUNANYA intersected the
15
120598
122deg
123deg
21deg
22deg
23deg
24deg
23deg
22deg
21deg
122deg
123deg
Fault
Thrust
Reverse thrust
CANNINGBASIN
OFFICERBASIN
GROUP
PILBARACRATON
TARCUNYAH
SAVORY GROUP
BANGEMALL
GROUP
THROSSELL
GROUP
LAMIL
GROUP
ConnaughtonTerrane
TerraneTalbot
complexTabletop granitic
Tabletop Terrane
Permian
Neoproterozoicgranitoid
50 km
FormationWaltha Woora
McKay Fault
South west Thrust
Vines
Fault
24deg
120deg
YENEENA CANNINGBASIN
ARUNTAINLIERRUDALL
COMPLEX
AMADEUSBASIN
MUSGRAVEBLOCK
OFFICERBASINYILGARN
CRATON
GROUP
GROUP
GROUP
PILBARACRATON
GROUP
EARAHEEDY
GLENGARRY
BANGEMALL
WYLOO GROUP
SAVORY
WA
CARNARVONBASIN
GASCOYNECOMPLEX
GROUPTARCUNYAH
400 kmGROUP
SA
N
T
CamelndashTabletopfault zone
KAHRBANSUBGROUP
CORNELIAFORMATION
MKS37
Figure 7 Regional geological setting of the Savory Group and western Officer Basin The dashed line on the inset map marks the interpreted margin of the greater Officer Basin
16
Tarcunyah Group and consists predominantly of mudstone with minor sandstone limestone
dolomite and anhydrite (Fig 6)
The age of the Tarcunyah Group is uncertain although limited palynological and stromatolite
evidence suggests that it is probably coeval with Supersequence 1 of the Centralian Superbasin
Drillhole LDDH1 contains palynomorphs equivalent to assemblages in the Browne and Bitter
Springs Formations of the Officer and Amadeus Basins respectively and from the Cornelia
Formation in TWB 6 (Grey and Stevens 1997) (Figs 4 and 6) Stromatolite specimens tentatively
assigned to Acaciella australica (Howchin 1914) Walter 1972 occur in the lower Tarcunyah
Group (Bagas et al 1995) The stromatolite Baicalia burra Preiss 1972 and a conical
stromatolite were reported from the upper part of the Tarcunyah Group (Stevens and Grey 1997)
The recognition of two stromatolite assemblages interpreted to have age significance in
Supersequence 1 sedimentary rocks of the Centralian Superbasin has permitted biostratigraphic
correlations between outcrop and well data The Acaciella australica assemblage appears to be
slightly older than 800 Ma and is restricted to the middle part of Supersequence 1 The Baicalia
burra assemblage is considered to be slightly younger than 800 Ma and occurs in the upper part
of Supersequence 1 (Grey 1996b Stevens and Grey 1997) The older A australica assemblage
is recognized in the Skates Hills Formation in the Savory Sub-basin and the stromatolite A
australica itself has been tentatively identified in the lower Tarcunyah Group The occurrence of
the A australica assemblage in the Woolnough Madley and Browne Formations of the Officer
Basin and in the Loves Creek Member of the Bitter Springs Formation of the Amadeus Basin
allows correlations throughout the Centralian Superbasin (Fig 4)
The younger B burra assemblage has not been recognized in sedimentary rocks of the
Savory Group as defined by Williams (1992) but it occurs in the upper parts of the Tarcunyah
Group and allows correlation of this group with outcrops of the Neale Formation and with the
Kanpa Formation in petroleum exploration well Hussar 1 both located in the central Officer Basin
of Western Australia (Fig 4) (Grey 1996b Stevens and Grey 1997) The occurrence of the B
burra assemblage in these units permits their correlation with the Burra Group in the Adelaide
Geosyncline of South Australia (K Grey unpublished data)
The Cornelia Formation and Kahrban Subgroup outcrop in the southeast of the sub-basin and
were considered by Williams (1992) to be part of the Mesoproterozoic Bangemall Basin Limited
evidence suggests that all or parts of these two units are of Neoproterozoic age The Ward and
Oldham Inliers consist of outcrops of the Cornelia Formation Waterbore TWB 6 which was
drilled on TRAINOR in the Cornelia Formation contains palynomorphs consistent with a
Supersequence 1 age (Grey and Stevens 1997) (Figs 5 and 6) In outcrop the Cornelia Formation
17
consists predominantly of sandstone and quartzite with lesser siltstone shale mudstone and chert
In Trainor 1 this formation consists predominantly of indurated mudstone with minor sandstone
chert and dolomite A major erosional unconformity separates the Cornelia Formation from
overlying formations and parts of the Cornelia Formation have been folded with dips exceeding
70deg In contrast the majority of the Savory Sub-basin sedimentary rocks have dips of less than 30deg
except where they are adjacent to faults The Cornelia Formation apparently consists of an older
unit of steeply dipping quartzites cherts and well-indurated mudstones and a younger unit of
shallower dipping sandstones which are sub-friable in parts However caution should be used in
interpreting the age of units based on their structural deformation and additional mapping and age
dating of this formation is required
It is proposed here that the Kahrban Subgroup is likely to be of early Neoproterozoic age and
hence should be considered as part of the greater Officer Basin This proposal is based largely on
the relatively low dip of the strata (generally less than 20deg) and their west-northwest strike which
is parallel with strikes in the overlying Brassey Range Formation of the Savory Group The lower
contact of the Kahrban Subgroup is obscured but is thought to be an unconfirmity on the
Earaheedy Basin on the southeast of STANLEY (Muhling and Brakel 1985)
Structural setting
The Savory Sub-basin forms the most northwesterly sub-basin of the Neoproterozoic to
Phanerozoic Officer Basin The western boundary of the sub-basin with the Mesoproterozoic
Bangemall Basin consists of steep-reverse and strike-slip faults The northeastern boundary of the
Savory Sub-basin was mapped where Supersequence 4 formations of the Savory Group
unconformably overlie sedimentary rocks of the Karara and Yeneena Basins with the two older
units considered to be part of the Paterson Orogen (Williams 1992) This contact was defined as a
series of steeply dipping reverse faults in the northernmost parts of the sub-basin on BALFOUR
DOWNS and RUDALL and was extrapolated as an inferred reverse fault farther along strike to the
southeast on GUNANYA and MADLEY where the contact is obscured by Cainozoic sediments It is
now recognized that all the sedimentary rocks in the Karara Basin and younger sedimentary rocks
of the Yeneena Basin are from the Supersequence 1 Tarcunyah Group and part of the greater
Officer Basin (Bagas et al 1995) The northern boundary of the Tarcunyah Group and the greater
Officer Basin is in thrust-and reverse-faulted contact with the Rudall Complex and other parts of
the Paterson Orogen (Fig 7)
To the south the sub-basin unconformably overlies the Bangemall Basin The eastern
boundary of the sub-basin used in this study is where Permian and younger strata of the Officer
Basin unconformably overlie Neoproterozoic strata although there are no significant structural or
stratigraphic differences between the Neoproterozoic units
18
The sub-basin is subdivided into three principal structural areas (Fig 1) Trainor Platform
Blake Fault and Fold Belt and Wells Foreland Sub-basin (Williams 1992) A major review of
these boundaries is beyond the scope of this report but the processing of regional aeromagnetic
data (Appendix 4) and acquisition of a semi-detailed gravity survey by the GSWA in the east of
the sub-basin has enabled these tectonic units to be reassessed and some modifications are
proposed
The Wells Foreland Sub-basin (originally termed the Wells Foreland Basin in Williams 1992)
and sedimentary rocks of the Tarcunyah Group are both considered to be the northwest
continuation of the Gibson Sub-basin of the Officer Basin Aeromagnetic gravity and outcrop
data suggest that the Blake Fault and Fold Belt is significantly faulted and folded in the west but
is less deformed in the east where the thickest sedimentary section in is located on BULLEN
(Appendix 4) The Trainor Platform is reinterpreted to represent an area of the sub-basin that has
undergone major compression during the Petermann Ranges Orogeny resulting in folding and
faulting with a northwest strike This interpretation contrasts with that proposed by Williams
(1992) who envisaged that only a thin section of the Savory Group was present on the platform
Perincek (1998) has recognized nine periods of tectonic activity in the Officer Basin from the
beginning of the Neoproterozoic to the end of the Cretaceous Three major tectonic episodes are
recognized in the Centralian Superbasin The oldest event is the Areyonga Movement which is
pre-Sturtian and forms the boundary between Supersequences 1 and 2 (Fig 4) The Souths Range
Movement occurred at the end of the Sturtian at the boundary between Supersequences 2 and 3
The youngest major event is the Petermann Ranges Orogeny which occured at the end of the
Marinoan and forms the boundary between Supersequences 3 and 4
One minor and two major tectonic episodes are recognized in the Savory Sub-basin the
LP1ALP1B structural event and the Areyonga Movement and the Petermann Ranges Orogeny
respectively The LP1ALP1B structural event is revealed where the Spearhole Formations rests
disconformably and locally unconformably on the Brassey Range Jilyili and Glass Spring
Formations The Neoproterozoic Areyonga Movement (equivalent to the Blake Movement of
Williams 1992) produced folds and faults with a general northeast strike in the western and
southern parts of the region The Souths Range Movement has not been recognized in the sub-
basin This may be due to the fact that no Sturtian glacial rocks have been identified and hence it
is possible that structures attributed to the Areyonga Movement could be the result of the Souths
Range Movement or a combination of the two movements
The major tectonic event recorded in the sub-basin is the latest Neoproterozoic to Cambrian
Petermann Ranges Orogeny (equivalent to the Paterson Orogeny) which produced large reverse
19
faults thrusts strike-slip faults and folds with a general northwest strike The McFadden
Formation and other Supersequence 4 strata are considered to be at least partially coeval with this
orogeny (Williams 1992) We also interpret the Durba Sandstone as having been deposited during
the later stages of the Petermann Ranges Orogeny as this unit mildly deformed with fold axes
parallel to the strike of other structures attributed to the Petermann Ranges Orogeny
Quantitative aeromagnetic interpretation of the Savory Sub-basin utilizing the 3D Euler
deconvolution method supported by wave-number filtering and image processing has provided
structural trends and depth to magnetic source within the sub-basin (Cowan 1995) Gravity data
are interpreted by Cowan (1995) as changes in both the density of the basement rocks andor
basement topography depending on local conditions Part of Cowanrsquos report is reproduced in
Appendix 4
Exploration history
The only petroleum exploration conducted in the sub-basin has been the recent drilling in the
western part of three diamond drillholes of which two have minor oil shows (Table 2) There has
been some mineral exploration the results of which are stored in the GSWA Western Australian
Mineral Exploration (WAMEX) database system Much of the mineral exploration was in the
southwest and west where the sub-basin is in contact with the Bangemall Basin and along the
northern margin of the sub-basin Many of these mineral exploration programs included
aeromagnetic surveys and surface geochemical sampling (Fig 8)
Hydrocarbon potential
The sub-basin contains a sedimentary succession up to 8 km thick which is generally gently
folded and faulted and apparently unmetamorphosed Limited drilling has shown that thick
mudstones are present in the sub-basin with some mudstones in Trainor 1 having high Total
Organic Carbon (TOC) values Outcrops of sub-friable sandstones in many of the formations
within the sub-basin suggests widespread reservoir potential Mudstone and inferred thick
evaporite sequences are likely to form seals Maturity data suggest that near-surface samples are
approximately at the base of the oil window and top of the gas window in parts of the north and
southeast of the sub-basin However parts of the southwest of the sub-basin and the mudstones in
Trainor 1 have very high levels of maturity Numerous faults and folds have been identified from
surface mapping suggesting good potential for large structural traps Minor oil shows in
20
Table 2 Neoproterozoic formations and hydrocarbon shows in diamond drillholes in the Savory Sub-basin
Drillhole AMG Core TD (m) Approx Formation Depth Formation Depth Formation Depth Shows (AGD84) start (m) GL (m) (m) (m) (m)
LDDH 1 431148E 112 701 350 Tarcunyah 68ndash701 ndash ndash bitumen at 6623 m 7443826N Group Trainor 1 473640E 6 709 455 McFadden 9ndash83 Cornelia Fm 83ndash709 possible bitumen at 4537 m 7287400N Fm Mundadjini 1 319056E 170 600 500 Mundadjini 16ndash361 Spearhole Fm 361ndash600 10 fluorescence at 36102 m 7404844N Fm Boondawari 1 348959E 299 1 367 490 Mundadjini Fm 15ndash312 Spearhole Fm 312ndash1 283 Intrusive 1 283ndash1 367 40 fluorescence at 35364 m 5 7398174N fluorescence at 4963 m Akubra 1 334249E 15 181 530 Mundadjini 15ndash42 Intrusive 42ndash181 None 7401252N Fm
21
50 km
120deg 121deg30 123deg
25deg
24deg
23deg
22deg
Greater Officer Basin
Savory Sub-basin
1
2
3
4
6
8
3 Seismic line (prefixed N83-00)
Aeromagnetic survey
GS
WA
Sav
ory
1995
gra
vity
sur
vey
Gravity survey
MKS34270398
Figure 8 Locations of aeromagnetic and gravity surveys (other than regional BMRAGSO data)
22
sandstones in two petroleum wells in the northwest of the sub-basin and bitumen and oil shows
elsewhere in the region indicate that oil has been generated and migrated through the sub-basin
Source rocks
Source potential is considered to be the major exploration risk in the Savory Sub-basin although
minor oil shows in Mundadjini 1 and Boondawari 1 indicate that at least some oil has been
generated and migrated into potential reservoirs within the sub-basin Sandstone is the
predominant lithology observed in outcrop Outcrops of fine-grained lithologies in the basin are
rare because of intense surface weathering and erosion Only about 8 of the surface area of the
sub-basin is exposed bedrock and recessive lithologies (such as shale evaporite and friable
sandstone) may be present although they rarely outcrop
Outcrops of stromatolitic dolomite with associated cauliflower chert and cubic pseudomorphs
interpreted as being after halite indicate that evaporitic environments are present within the
Mundadjini Skates Hills and Boondawari Formations Evaporitic minerals are also present in
drillhole LDDH1 in the Tarcunyah Group
In 1995 GSWA drilled a continuous-core diamond drillhole (Trainor 1) in the sub-basin on
TRAINOR to a depth of 709 m to test for source rocks thus providing the first such data for the sub-
basin The drillhole intersected flat-lying clastics and carbonates of the McFadden Formation (9ndash
83 m) overlying indurated mudstones of the Cornelia Formation (83ndash709 m total depth) dipping at
about 40deg Of the six samples analysed from the Cornelia Formation in this drillhole the five
located between 375 and 6032 m depth have TOC values exceeding 05 (range 066ndash365)
Rock-Eval pyrolysis of these five samples indicates that they are at best in the dry-gas thermal
stage and as a result of their high level of maturation (Stevens and Adamides in prep) have poor
remaining hydrocarbon-generating potential Although the Cornelia Formation is overmature at
Trainor 1 the high TOC values are encouraging as it is likely that this sequence is less mature
elsewhere in the sub-basin
The Mundadjini Formation contains potential source rocks that comprise marine mudstones
with evaporitic minerals present in parts Thin dark mudstones were intersected in the Mundadjini
Formation in Akubra 1 In Mundadjini 1 and Boondawari 1 however the mudstones appear to be
too oxidized to have source potential
The Boondawari Formation also may be a source rock as it contains black mudstones The
unit is laterally equivalent to the Pertatataka Formation of the Amadeus Basin and the Ungoolya
23
Group of the Officer Basin in South Australia both of which have some source potential
(Summons and Powell 1991 Morton and Drexel 1997) Samples from the Dey Dey Mudstone of
the Ungoolya Group generally have poor TOC values (average 011 range 003ndash081)
moderate hydrogen index (HI) values (100ndash382) and poor to fair genetic potential with a
maximum of 292 kg hydrocarbon per tonne of source rock (Morton and Drexel 1997)
Stromatolitic dolomites and mudstones at the top of the Boondawari Formation and within the
Skates Hills Formation are potential source rocks Stromatolitic dolomite and evaporitic rocks
deposited in a marginal marine to sabkha environment are considered to have good potential to
generate and preserve organic carbon without requiring a deep-water setting (Stevens and Grey
1997) Such conditions are recognized in the Skates Hills Formation and in the upper parts of the
Tarcunyah Group
Maturity
Knowledge of the maturity of sedimentary rocks within the Savory Sub-basin is still limited From
a review of palynological studies Grey and Stevens (1997) report that the thermal maturity
inferred from the Thermal Alteration Index (TAI) of 3+ from Supersequence 1 age palynomorphs
in TWB 6 TWB 9 and LDDH1 is within the hydrocarbon window (Appendix 3) In Phanerozoic
spores and pollen a TAI of 3+ approximately equates to the end of liquid petroleum generation
and the start of dry gas generation and to a vitrinite reflectance of about 13 (Traverse 1988)
However the use of TAI for estimating thermal maturity from Neoproterozoic palynomorphs
requires calibration
In Trainor 1 the Cornelia Formation contains organically rich claystones between 375 and
6032 m depth Based on Rock-Eval maturity data (Stevens and Adamides in prep) and the dark
colour of poorly preserved organic material (Grey 1995de 1996) with TAI 4- to 5 all samples
had a high level of maturation with at best dry-gas generating potential remaining In contrast
drillhole LDDH1 on GUNANYA recorded lower levels of maturity (TAI values of 3+) with two of
sixteen samples from the Tarcunyah Group having greater than 1 TOC (Grey 1995abc Grey
and Cotter 1996) Organic petrology and Rock-Eval maturity data for samples from LDDH1
indicate that the section above 500 m is within the oil-generative window whereas below 500 m
the rocks are within the gas window (Ghori in prep Fig 9 Appendix 5)
Waterbores TWB 1 2 6 and 9 which are located on TRAINOR in the southeast of the sub-
basin all had organic matter with TAI values of 3+ from the McFadden Skates Hills Cornelia
and Brassey Range Formations respectively
24
100
200
300
400
500
600
700
Oil
gene
ratin
g
Gas
gene
ratin
g
Fai
r
Fai
r
Poo
r
Poo
r
Goo
d
Imm
atur
e
Oil
win
dow
Oil
win
dow
Imm
atur
e
01 0110 10 0 150 300 440 480 1
Neo
prot
eroz
oic
TOC S1+S2 mgg Hydrogen Index Tmax degC
Depth(m)
Organicrichness
Generatingpotential
Kerogentype Maturity Maturity
TD=701m
Sandstone
Mudstone
Dolomite
Limestone
Evaporite
Source rock
MKS40 070498
Ro equivalent
Figure 9 Petroleum source potential of rocks in Normandy LDDH1
Small amounts of organic matter associated with basalt and dolerite in cuttings from
waterbore BWB 1 on BULLEN showed high levels of thermal maturity (Grey 1995a Libby 1995)
It is unclear whether all sedimentary rocks on BULLEN are overmature for hydrocarbon generation
or the results from BWB 1 are related to local heating events associated with the volcanic bodies
that are common in the Jilyili Formation
25
Reservoirs
Each of the five depositional sequences of the Savory Group (Table 1) are inferred to contain
significant sandstone reservoirs with the possible exception of depositional sequence C as
discussed above in Stratigraphy The Spearhole Formation was cored in Mundadjini 1 and
Boondawari 1 and visual estimates of porosity vary from generally poor (less than 5) to fair
(approximately 5ndash15) The McFadden Formation in Trainor 1 has porosity values of up to 232
and a maximum permeability of 195 md (Stevens and Adamides in prep) Sandstones from
Neoproterozoic formations form the acquifers in the following waterbores the McFadden
Formation in TWB 1 the Cornelia Formation in TWB 6 and the Brassey Range Formation in
TWB 8 and TWB 9 (Appendix 6 Table 61)
Based on outcrop observations the Durba Sandstone is considered to be the best reservoir of
the Savory Group Similarly some sandstones from the Tarcunyah Group also have good visible
porosity in outcrop
Dolomites occur in several formations in the sub-basin Reservoir potential may exist
particularly where the dolomites are stromatolitic and oolitic However dolomites have not been
drilled in the sub-basin and porosity can only be inferred from the preferential silicification of
some stromatolite bioherms observed in outcrop (Stevens and Grey 1997) Elsewhere in the
Officer Basin porosities of up to10 have been measured in dolomites A limestone breccia
(karst) is described from 663 to 677 m in drillhole LDDH1 (Fig 6 Busbridge 1994)
Seals
Indications of evaporitic environments in the Mundadjini Skates Hills and Boondawari
Formations are described by Williams (1992) In Mundadjini 1 from 287 to 337 m anhydrite and
chert occurs as nodules beds and veins in mudstone of the Mundadjini Formation Evaporitic
minerals (predominantly gypsum) are described in the Tarcunyah Group in LDDH1 The presence
of the Woolnough and Madley salt diapirs in the Officer Basin (approximately 110 km east of the
sub-basin) and halite beds over 25 m thick in the well Hussar 1 (130 km east of the sub-basin)
provide further evidence that evaporite seals may be present in the Savory Sub-basin
Mudstones and shales form only a small proportion of the limited Neoproterozoic outcrop in
the sub-basin but significant thicknesses of mudstone were encountered in the Mundadjini
Formation in Mundadjini 1 and Boondawari 1 the Tarcunyah Group in LDDH1 and in the
26
Cornelia Formation in Trainor 1 These data suggest that mudstones form a significant proportion
of strata in the sub-basin despite their limited outcrop
Traps
Potential structural closures including folds and faults occur at various scales throughout the
Savory Sub-basin However the region has only been mapped at 1250 000 scale and
independently closed structures such as domes have yet to be confirmed The western margin of
the basin contains abundant faults (with a northeast strike) but elsewhere faults are less common
Some anticlines are recognized in outcrop including one with a strike length of up to 45 km
inferred from surface bedding dips in the Mundadjini and Spearhole Formations at approximately
24deg15rsquoS 121deg10rsquoE on BULLEN (Fig 1)
Salt diapirs and other halokinetic structures are recognized in outcrop well and seismic data
in the Officer Basin to the west of the Savory Sub-basin and it is probable that there are
significant thicknesses of evaporitic sedimentary rocks in the sub-basin The gravity field data
suggest there is good potential for salt diapirs and traps related to halokinesis
Although there is potential for stratigraphic traps to be present in the sub-basin insufficient
data are available to assess them
Preservation of hydrocarbons
The range of thermal maturities measured to date and the large periods of time envisaged for
deposition of sediments implies hydrocarbon generation may have occurred a number of times
during the evolution of the Savory Sub-basin Any hydrocarbons that were generated early may
have been trapped in palaeostructures and remigration to younger traps could have taken place
later The Petermann Ranges Orogeny which has been equated with the Paterson Orogeny (Myers
1990) is believed to have occurred in the latest Neoproterozoic to early Cambrian This is the last
major tectonic event recognized in the sub-basin suggesting that it is reasonable to expect that trap
integrity will have been preserved
If the inference of the presence of thick halite beds in the sub-basin is correct the preservation
potential of sub-salt traps should be excellent
27
Reported hydrocarbon shows and oil seep
Amadeus Petroleum recorded minor oil shows in cores from Mundadjini 1 and Boondawari 1 In
Mundadjini 1 at 36102 m (top of the Spearhole Formation) a 3 mm thick zone had 10 moderate
white fluorescence with slow solvent cut This show was in a granular sandstone with visually
estimated porosity of about 10 In Boondawari 1 at 35364 m (within the Spearhole Formation) a
broken surface of sandstone had 40 moderate yellow-white fluorescence with slow solvent cut
Visually estimated porosity is about 5 Because the fluorescing surface was broken during the
drilling process this show could have resulted from contamination A second show occurs in
Boondawari 1 at 4963 m (within the Spearhole Formation) where a 1 cm-thick zone had 5 dull
yellow fluorescence with slow solvent cut in a conglomerate with visually estimated porosity of
about 10 The company intends to further investigate the nature of these occurrences
Minor bitumen is present at 6623 m in drillhole LDDH1 on GUNANYA (Figs 5 and 6) as a
vein in mudstones of the Tarcunyah Group A sample was analysed by gas chromatography
(Ghori in prep) and confirmed that it is natural bitumen (Appendix 5)
Mineral hole OD 23 drilled by Jubilee Gold Mines NL on NABBERU in the Bangemall Basin
immediately to the south of the Savory Sub-basin (Fig 5) encountered bitumen and trace oil in
vugs in dolomite (M Stevens unpublished data) but no further data are available at present
In their popular guide to the Canning Stock Route Gard and Gard (1990 p 218) refer to an
oil seep at Well 13 on TRAINOR (Fig 5) They reported that between 1977 and 1984 lsquonatural oilrsquo
was seen in the well Although the well is now largely filled with sediment four auger drill
samples were collected by the GSWA in 1995 and all four were analysed for oil shows One
sample from 315 m total depth (GSWA sample 135604) yielded just enough extract (519 ppm)
for saturate gas chromatography analysis The gas chromatograph (Appendix 5) shows that the
extract does contain some hydrocarbons probably from recent plant material Because the depth to
the oil was not quoted in Gard and Gard (1990) the hand-augered well may not have been deep
enough to properly test this reported seep
Geological and geophysical databases
Geological and geophysical data available for the Savory Sub-basin are limited The most recently
completed geological maps for the sub-basin were published by the GSWA between 1991 and
1995 (Williams and Tyler 1991 Williams 1992 1995ab)
28
The cores from the five drillholes listed in Table 2 believed to be all of the core available
from the sub-basin are available for inspection at GSWA Mineral exploration reports submitted
to GSWA may be searched using the WAMEX database and open-file reports are available on
microfiche Geophysical data acquired by the mining industry is not required to be filed with
GSWA if acquired over Vacant Crown Land which is the case for much of the sub-basin
Geophysical survey data submitted in mining tenement reports and which extend into Vacant
Crown Land remain confidential to the companies Original regional aeromagnetic and gravity
datasets are available from the Australian Geological Survey Organisation (AGSO)
Data pertinent to oil exploration in the sub-basin such as structural style and salt diapirism
are presented in a review of the hydrocarbon prospectivity of the Officer Basin (Perincek 1998)
Drilling
Significant drillholes in the sub-basin are summarized in Table 2
Petroleum industry data
Amadeus Petroleum drilled three petroleum exploration wells in the central west of the Savory
Sub-basin in late 1997 These wells Mundadjini 1 Boondawari 1 and Akubra 1 were drilled by
continuous diamond coring (Figs 5 and 6) All targeted potential reservoirs within the Spearhole
Formation with the Mundadjini Formation as the proposed seal The wells were located on
structures interpreted from Landsat images and limited geological investigations Both Mundadjini
1 and Boondawari 1 had minor oil shows as discussed above (Reported hydrocarbon shows)
Government data
Stratigraphic drillhole Trainor 1 was drilled by GSWA in 1995 (Stevens and Adamides in prep)
and the main results are discussed above (Source rocks and Maturity)
Mineral industry data
Normandy Exploration drillhole LDDH1 was cored in the Tarcunyah Group to a total depth of
701 m and provided source-rock and maturity data as discussed above
29
Oilmin NL drilled six percussion drillholes (BD 1 3 4 5 8 and 9) through sandstones and
shales in the northern part of the Savory Sub-basin to a maximum depth of 198 m (Fig 5
WAMEX Microfiche File M 26811 I 2610) but only brief geological descriptions are available
Hydrogeological data
Hydrogeological data within the Savory Sub-basin are limited although a long history of water
exploration extends back to the construction of the Canning Stock Route early this century No
detailed geological or wireline logs are available for the older wells along this route A few station
wells have been drilled by various methods on the south and west margins of the basin but data
are unavailable as reports are not required to be filed with the government Depth to watertable
throughout the basin is largely controlled by porosity of the bedrock
The GSWA drilled fifteen waterbores in the winter of 1995 in the southern part of the sub-
basin in preparation for the drilling of Trainor 1 and the proposed Bullen 1 Twelve bores found
water and six of these bores have salinities of less than 1000 mgL (Fig 5 Appendix 6 Table 61)
One waterbore TWB 6 has gamma ray and neutron logs run through PVC casing and these are
available from the GSWA with the digital log data included herein
Seismic data
No geophysical data have been acquired by the petroleum industry in the Savory Sub-basin
Seismic data acquired in the Officer Basin to the east particularly in the Gibson and Yowalga
Sub-basins is pertinent to structural interpretation in the Savory Sub-basin (Perincek 1996a
1998)
Aeromagnetic surveys
Government data
There are over 95 277 line kilometres of aeromagnetic data included in the AGSO dataset There
are three regional aeromagnetic surveys covering the Savory Sub-basin These were flown by the
Bureau of Mineral Resources (BMR now AGSO) in 1984 at a line spacing of 1500 m with 36 740
and 52 587 line kilometres flown and by Aerodata in 1984 at a line spacing of 1000m with 5950
line kilometres flown These data were reprocessed and interpreted for GSWA by Cowan (1995)
An edited copy of this report is included as Appendix 4 and the original report is filed in the
GSWA Library under S-series reports item 10331
30
Mineral industry data
The approximate locations of non-AGSO aeromagnetic surveys are shown in Figure 8 More
detailed information regarding the location of these surveys may be obtained using the GSWA
MAGCAT II database Additional information such as contours of aeromagnetic values may be
obtained by inspecting items on file with the GSWA
Gravity surveys
Government data
The average spacing for gravity data in the Savory Sub-basin is one station per 121 km2 (11 times 11
km grid) These data were principally collected by BMR in the early 1960s There are a few
additional regional gravity traverses across the sub-basin which are also included in the
BMRAGSO dataset These data were reprocessed and interpreted for GSWA (Fig 10) and a
report on this work is also included in Appendix 4
The GSWA completed a large semi-detailed gravity survey in the eastern Savory Sub-basin
utilizing helicopter support and Differential Global Positioning Survey (DGPS) techniques (Fig
8) This gravity survey completed in August 1995 consists of 2300 gravity stations on a 2 times 3 km
grid All stations were acquired by helicopter using Scintrex gravimeters and Ashtek dual
frequency DGPS equipment for determining location This highly efficient system allowed the
acquisition of more than 100 gravity stations per day in remote areas The resolution of this survey
is +30 cm and +05 microms-2 (Daishsat 1995) These data (Fig 11) represent a significant
improvement on the previous regional survey data and are available from GSWA (GSWA
1996ab) The results of the interpretation of these data were presented at the 1997 ASEG
Convention (Carlsen and Shevchenko 1997)
Mineral industry data
Three small gravity surveys were conducted by Oilmin NL (Fig 8) and the relevant WAMEX
reports are M 2681I 2610 I 2435 I 2567 These three surveys are of limited value because height
control was provided by barometers only and the surveys were not tied to the national gravity grid
31
23deg
25deg
120deg 122deg
Trainor 1
SAVORY
SUB-BASIN
MKS54 160498
100 km
1995 SavoryGravity Survey
254
-1056
micromsec2
Figure 10 Regional Bouguer gravity map of the Savory Sub-basin
23deg
24deg
25deg
122deg30 123deg
TRAINOR 1
123deg30
50 km
MKS53 160498
-116
-626
micro msec2
Figure11 Detailed Bouguer gravity map of the
Savory 1995 Gravity Survey from the eastern Savory Sub-basin
32
Government and academic reports
Chronostratigraphy and geochemistry
The understanding of Neoproterozoic organic chemistry palynology and structural evolution is
essential to the interpretation of hydrocarbon prospectivity Pertinent reports are included in the
bibliography (Appendix 1) Unpublished palaeontology reports describe the palynology of wells in
the Savory Sub-basin (Grey 1995andashe 1996a) Grey and Cotter (1996) discussed the potential for
Neoproterozoic palynomorphs to provide a biostratigraphic framework and palaeoenvironmental
interpretation Grey and Stevens (1997) reviewed the results of palynological studies of wells
drilled in the sub-basin and reported that Supersequence 1 palynomorphs are present in TWB 6
TWB 9 and LDDH1 (Appendix 3) Grey (1996b) reported on the use of stromatolites for
correlation in the Neoproterozoic and Stevens and Grey (1997) discussed the application of
stromatolite biostratigraphy in correlating isolated dolomite outcrops in the sub-basin with well
and seismic data in the Officer Basin and Centralian Superbasin
Although geochemical data from the Savory Sub-basin are very limited results mostly
confirm thermal maturities inferred from TAI for LDDH1 and Trainor 1 (Ghori in prep Stevens
and Adamides in prep) Those parts of the Officer Basin in Western Australia which lie to the
east of the Savory Sub-basin are sparsely drilled but Ghori (in prep) reports that most of the
Neoproterozoic succession presently lies within the oil-generative window However his study
has been unable to identify effective source-rock units and the source for oil shows Thin source
rocks are present in the Neoproterozoic in LDDH1 (Fig 9) and in three wells which lie to the east
and southeast of the Savory Sub-basin namely NJD 1 Kanpa 1A and Yowalga 3
Proposed work program
From the above limited information it is concluded that additional research on the hydrocarbon
potential of the sub-basin is justified and proposals are outlined below
bull Additional modelling of gravity and aeromagnetic data from the Savory Sub-basin is required
in light of the results from Trainor 1 and Boondawari 1 Trainor 1 showed that what appeared
to be a structurally simple area based on outcrop aeromagnetic and gravity data was in fact an
area of major structuring Boondawari 1 intersected a dolerite which is in good depth
agreement with aeromagnetic depth to source results showing this technique is useful in
detecting the depth to intrusive bodies
33
bull Additional data from mineral and petroleum exploration bores may become available and
analysis of samples from these wells should be undertaken and interpreted in the context of
their relevance to the Officer Basin
bull Stratigraphic coring in the Blake Fault and Fold Belt and in the Wells Foreland Sub-basin (Fig
1) targeting source rocks is considered essential to the continuing evaluation of the
hydrocarbon prospectivity of the Savory Sub-basin
bull Correlations using at least outcrop well and potential-field data should be prepared to link the
sub-basin with the better known parts of the Officer Basin to the east
bull Remapping is required to clarify boundary positions within the Cornelia Formation this may
resolve some of the current problems of the relationship between this unit and the rest of the
Savory Sub-basin
bull Further work is required to explain the Early Cambrian or Sturtian ages interpreted for the
Cornelia Formation from sedimentary zircon UndashPb dating in drillhole Trainor 1 The
determination of the age of the organically rich but overmature claystones in this well is
critical to assessing the hydrocarbon potential of the region
bull The thin dark mudstones intersected by Akubra 1 in the Mundadjini Formation warrant
geochemical analysis Analyses of the oil shows in Mundadjini 1 and Boondawari 1 are
currently being undertaken by Amadeus Petroleum
bull Geochemical analysis of hydrocarbons in the Bangemall Basin drillhole OD23 has been
performed by Jubilee Gold and the results will be reviewed when they are submitted to
GSWA The possibility of source rocks within the Bangemall Basin charging traps within the
Bangemall Basin and the overlying Savory Sub-basin requires further investigation
Conclusions
The Savory Sub-basin is a frontier region with only three recently drilled petroleum exploration
wells and no seismic data Based on existing geological and geophysical data it is considered too
early to draw conclusions about the hydrocarbon prospectivity of the sub-basin at this stage and
there are several reasons why the area warrants further investigation
34
1 Thick accumulations of sedimentary rocks are present (up to 8 km thickness inferred) which
may contain source reservoir and sealing strata
2 Minor oil shows occur in Mundadjini 1 and Boondawari 1 and bitumen is present in mineral
exploration drillhole LDDH1 suggesting that hydrocarbons have migrated within the
Neoproterozoic sequence of the Savory Sub-basin Oil and bitumen are present in mineral
exploration drillhole OD23 in the Bangemall Basin immediately to the south of the Savory
Sub-basin and it is possible that source rocks from the Bangemall Basin could charge traps in
the overlying Savory Sub-basin
3 The age of sedimentary rocks in the sub-basin is still poorly constrained but some of the
Neoproterozoic sedimentary rocks located on GUNANYA and TRAINOR are within the
hydrocarbon-generation window It is possible that a significant thickness of Phanerozoic
sedimentary rocks may also be present
4 Friable sandstones with visible porosity outcrop extensively suggesting numerous potential
reservoirs
5 Significant but not intense faulting and folding has been mapped implying large structural
traps may be present
6 Evaporitic sedimentary rocks occur in several formations and may provide good source rocks
and excellent seals
35
References
APAK S N and CARLSEN G M 1997 A compilation and review of data pertaining to the
hydrocarbon prospectivity of the Canning Basin Western Australia Geological Survey
Record 199610 103p
BAGAS L GREY K and WILLIAMS I R 1995 Reappraisal of the Paterson Orogen and
Savory Basin Western Australia Geological Survey Annual Review 1994ndash95 p 55ndash63
BUSBRIDGE M 1994 Lake Disappointment Exploration Licence 451064 Third Annual
Report Lake Disappointment Diamond Drill Hole LDDH1 Normandy Exploration Limited
Western Australia Geological Survey M-series Item 7567 A41358 (unpublished)
CARLSEN G M and SHEVCHENKO S I 1997 Petroleum exploration in Proterozoic basins
using potential fields data and stratigraphic coring Australian Society of Exploration
Geophysicists 12th Geophysical Conference Handbook Sydney 1997 Preview no 66 p 83
(abstract only)
COWAN D 1995 Savory Basin quantitative magnetic interpretation Western Australia
Geological Survey S-series S10331 (unpublished)
DAISHSAT PTY LTD 1995 Operational and processing report Savory Basin gravity survey
Western Australia Geological Survey S-series S10332 (unpublished)
GARD E and GARD R 1990 Canning Stock Route a travellerrsquos guide for a journey through
history Perth Western Australia Western Desert Guides 448p
GEOLOGICAL SURVEY OF WESTERN AUSTRALIA 1996a Savory Basin first vertical
derivative of Bouguer gravity image 1250 000 Western Australia Geological Survey
GEOLOGICAL SURVEY OF WESTERN AUSTRALIA 1996b Savory Basin Bouguer gravity
image 1250 000 Western Australia Geological Survey
GHORI K A R in prep Petroleum source rock potential and thermal history Officer Basin
Western Australia Western Australia Geological Survey Record
36
GREY K 1995a Savory Basin drillhole BWB 1 (Bullen waterbore) palynology and thermal
maturation GSWA Palaeontology Report no 199512 (unpublished)
GREY K 1995b Savory Basin drillholes TWB 1 2 6 9 (Trainor waterbores) palynology and
thermal maturation GSWA Palaeontology Report no 199520 (unpublished)
GREY K 1995c Palynology of Normandy-Poseidon Lake Disappointment-1 corehole
Tarcunyah Group Paterson Orogen GSWA Palaeontology Report no 199521 (unpublished)
GREY K 1995d Savory Basin drillhole Trainor 1 (Trainor diamond drilling) palynology and
thermal maturity GSWA Palaeontology Report no 199524 (unpublished)
GREY K 1995e Savory Basin drillhole Trainor 1 (Trainor diamond drilling) Additional
Preparation of two samples GSWA Palaeontology Report no 199528 (unpublished)
GREY K 1995f Neoproterozoic stromatolites from the Skates Hills Formation Savory Basin
Western Australia and a review of the distribution of Acaciella australica Australian Journal
of Earth Sciences v 42 p 123ndash132
GREY K 1996a Savory Basin drillhole Trainor 1 (Trainor diamond drilling) Additional
samples palynology and thermal maturation GSWA Palaeontology Report no 199615
(unpublished)
GREY K 1996b Preliminary stromatolite correlations for the Neoproterozoic of the Officer
Basin and a review of Australia-wide correlations GSWA Palaeontology Report no 199615
(unpublished)
GREY K and COTTER K L 1996 Palynology in the search for Proterozoic hydrocarbons
Western Australia Geological Survey Annual Review for 1995ndash96 p 70ndash80
GREY K and STEVENS M K 1997 Neoproterozoic palynomorphs of the Savory Sub-basin
Western Australia and their relevance to petroleum exploration Western Australia
Geological Survey Annual Review for 1996ndash97 p 49ndash54
HUBBARD R J PAPE J and ROBERTS D G 1985 Depositional sequence mapping as a
technique to establish tectonic and stratigraphic framework and evaluate hydrocarbon
potential on a passive continental margin in Seismic stratigraphy II an integrated approach
37
edited by O R BERG and D G WOOLVERTON American Association of Petroleum
Geologists Memoir 39 p 79ndash91
LIBBY WG 1995 A petrological report on six samples of bore cuttings from the Savory Basin
Western Australia Western Australia Geological Survey S-series S31307 (unpublished)
MORTON JGG and DREXEL JF 1997 The petroleum geology of South Australia Vol 3
Officer Basin South Australia Department of Mines and Energy Resources Report Book
9719
MUHLING P C and BRAKEL A T 1985 Geology of the Bangemall Group mdash the evolution
of an intracratonic Proterozoic basin Western Australia Geological Survey Bulletin 128
219p
MYERS J S 1990 Precambrian tectonic evolution of part of Gondwana southwestern Australia
Geology v18 p 537ndash540
NELSON D R 1997 Compilation of SHRIMP UndashPb zircon data Western Australia Geological
Survey Record 19972 196p
PAYTON C E 1977 Seismic stratigraphy mdash applications to hydrocarbon exploration
American Association of Petroleum Geologists Memoir 26 516p
PERINCEK D 1996a The age of NeoproterozoicndashPalaeozoic sediments within the Officer Basin
of the Centralian Super-basin can be constrained by major sequence-bounding unconformities
APPEA Journal v 36 pt 1 p 350ndash368
PERINCEK D 1996b The stratigraphic and structural development of the Officer Basin
Western Australia a review Western Australia Geological Survey Annual Review 1995ndash
1996 p 135ndash148
PERINCEK D 1998 A compilation and review of data pertaining to the hydrocarbon
prospectivity of the Officer Basin Western Australia Geological Survey Record 19976
POSAMENTIER H W JERSEY M T and VAIL P R 1988 Eustatic controls on clastic
deposition 1 mdash Conceptual framework in Sea-level changes an integrated approach edited by
C K WILGUS B S HASTINGS C G St C KENDALL H W POSAMENTIER
38
C A ROSS and J C VAN WAGONER Society of Economic Paleontologists and
Mineralogists Special Publication no 42
STEVENS M K and ADAMIDES N G in prep GSWA Trainor 1 well completion report
Savory Sub-basin Officer Basin Western Australia with notes on petroleum and mineral
potential Western Australia Geological Survey Record 199612
STEVENS M K and GREY K 1997 Skates Hills Formation and Tarcunyah Group Officer
Basin mdash carbonate cycles stratigraphic position and hydrocarbon prospectivity Western
Australia Geological Survey Annual Review for 1996ndash97 p 55ndash60
SUMMONS RE and POWELL C McA 1991 Petroleum source rocks of the Amadeus Basin
in Geological and geophysical studies in the Amadeus Basin central Australia edited by R J
KORSCH and JM KENNARD Australia BMR Geology and Geophysics Bulletin 236
TRAVERSE A 1988 Palaeopalynology Boston Unwin Hyman 600p
VAIL P R MITCHUM R M Jr TODD R G WIDMIER J M THOMPSON S III
SANGREE J B BUBB J N and HATLELID W G 1977 Seismic stratigraphy and
global changes of sea level in Seismic stratigraphy mdash applications to hydrocarbon
exploration edited by C E PAYTON American Association of Petroleum Geologists
Memoir 26 516p
WALTER M R and GORTER J 1994 The Neoproterozoic Centralian Superbasin in Western
Australia the Savory and Officer Basins in The sedimentary basins of Western Australia
edited by P G PURCELL and R R PURCELL Petroleum Exploration Society of Australia
Symposium Perth WA 1994 Proceedings p851ndash864
WALTER M R GREY K WILLIAMS I R and CALVER C R 1994 Stratigraphy of the
Neoproterozoic to early Palaeozoic Savory Basin and correlation with the Amadeus and
Officer Basins Australian Journal of Earth Sciences v 41 p 533ndash546
WALTER M R VEEVERS J J CALVER C R and GREY K 1995 Neoproterozoic
stratigraphy of the Centralian Superbasin Australia Precambrian Research v 73 p 173ndash195
WILLIAMS I R 1992 Geology of the Savory Basin Western Australia Western Australia
Geological Survey Bulletin 141 115p
39
WILLIAMS I R 1995a Bullen WA (2nd Edition) Western Australia Geological Survey
1250 000 Geological Series Explanatory Notes 23p
WILLIAMS I R 1995b Trainor WA (2nd Edition) Western Australia Geological Survey
1250 000 Geological Series Explanatory Notes 31p
WILLIAMS I R and TYLER I M 1991 Robertson WA (2nd edition) Western Australia
Geological Survey 1250 000 Geological Series Explanatory Notes 36p
40
41
Appendix 1
Bibliography
Reports which are relevant to this investigation but which are not specifically cited are listed
below
BAILLIE P W POWELL C McA LI Z X and RYALL A M 1994 The tectonic
framework of Western Australiarsquos Neoproterozoic to recent sedimentary basins in The
sedimentary basins of Western Australia edited by P G PURCELL and R R PURCELL
Petroleum Exploration Society of Australia Symposium Perth WA 1994 Proceedings p
45ndash62
BRADSHAW M T BRADSHAW J MURRAY A P NEEDHAM D J SPENCER L
SUMMONS R E WILMOT J and WINN S 1994 Petroleum systems in West Australian
basins in The sedimentary basins of Western Australia edited by P G PURCELL and R R
PURCELL Petroleum Exploration Society of Australia Symposium Perth WA 1994
Proceedings p 93ndash118
CLARKE G L 1991 Proterozoic tectonic reworking in the Rudall Complex Western Australia
Australian Journal of Earth Science v38 p 31ndash44
COCKBAIN A E and HOCKING R M 1990 Phanerozoic in Geology and mineral resources
of Western Australia Western Australia Geological Survey Memoir 3 p 750ndash755
ETHERIDGE M and WALL V 1994 Tectonic and structural evolution of the Australian
Proterozoic 12th Australian Geological Convention Geological Society of Australia
Abstracts no 37 p 102ndash103
GOODE A D T 1981 Proterozoic geology of Western Australia in Precambrian of the
Southern Hemisphere Developments in Precambrian geology 2 edited by I R HUNTER
Amsterdam Elsevier p 105ndash203
GREY K and JACKSON M J 1983 A re-assessment of stromatolite evidence for the
correlation of the Late Proterozoic Neale and Ilma Beds Officer Basin Western Australia
Australia BMR Journal of Australian Geology and Geophysics v 8 p 359
42
HICKMAN A H WILLIAMS I R and BAGAS L 1994 Proterozoic geology and
mineralization of the TelferndashRudall region Paterson Orogen Geological Society of Australia
(WA Division) Excursion Guidebook no 5 56p
HOCKING R M MORY A J and WILLIAMS I R 1994 An atlas of Neoproterozoic and
Phanerozoic basins of Western Australia in The sedimentary basins of Western Australia
edited by P G PURCELL and R R PURCELL Petroleum Exploration Society of Australia
Symposium Perth WA 1994 Proceedings p 21ndash 44
JACKSON P R 1966 Geology and review of exploration Officer Basin Western Australia
Hunt Oil Company Western Australia Geological Survey S-series S26 (unpublished)
JACKSON M J 1971 Notes on a geological reconnaissance of the Officer Basin Western
Australia Australia BMR Geology and Geophysics Record 19715 30p
JACKSON M J and van de GRAAFF W J E 1981 Geology of the Officer Basin Western
Australia Australia BMR Geology and Geophysics Bulletin 206 102 p
LOWRY D C JACKSON M J van de GRAAFF W J E and KENNEWELL P J 1971
Preliminary result of geological mapping in the Officer Basin Western Australia Western
Australia Geological Survey Annual Report for 1971 p 50ndash56
MYERS J S 1990 Precambrian in Geology and mineral resources of Western Australia
Western Australia Geological Survey Memoir 3 p 737ndash750
MYERS J S SHAW R D and TYLER I M 1994 Proterozoic tectonic evolution of
Australia 12th Australian Geological Convention Geological Society of Australia Abstracts
no 37 p 312
NEDIN C and JENKINS R J F 1991 Re-evaluation of unconformities separating the
lsquoEdiacaranrsquo and Cambrian systems South Australia Palaios v 6 p 102ndash108
PHILLIPS B J JAMES A W and PHILIP G M 1985 The geology and hydrocarbon
potential of the north-western Officer Basin APEA Journal 25 (1) p 52ndash61
POWELL C McA LI Z X McELHINNY M W MEERT J G and PARK J K 1993
Paleomagnetic constraints on timing of the Neoproterozoic breakup of Rodinia and Cambrian
formation of Gondwana Geology v 21 p 889ndash892
43
POWELL C McA PREISS W V GATEHOUSE C G KRAPEZ B and LI Z X 1994
South Australian record of a Rodinian epicontinental basin and its mid-Neoproterozoic
breakup to form the Palaeo-Pacific Ocean Tectonophysics v 237 no 3ndash4 p 113ndash140
PREISS W V 1976 Proterozoic stromatolites from the Nabberu and Officer Basins Western
Australia and their biostratigraphic significance South Australia Geological Survey Report
of Investigations no 47 p 1ndash51
TOWNSON W G 1985 The subsurface geology of the western Officer Basin mdash results of
Shellrsquos 1980ndash1984 petroleum exploration campaign APEA Journal v 25 (1) p 34ndash51
WATTS K J 1982 The geology of the Townsend Quartzite Upper Proterozoic shallow water
deposit of the Northern Officer Basin Western Australia Perth University of Western
Australia BSc honours thesis (unpublished)
WELLS A T and KENNEWELL P J 1974 Evaporite exploration in the Officer Basin
Western Australia at the Madley Diapirs Australia BMR Record 1974194 (unpublished)
WILLIAMS I R and MYERS J S 1990 Paterson Orogen in Geology and mineral resources
of Western Australia Western Australia Geological Survey Memoir 3 p 274ndash286
WILLIAMS I R 1990 Savory Basin in Geology and mineral resources of Western Australia
Western Australia Geological Survey Memoir 3 p 329ndash334
WILLIAMS I R 1994 The Neoproterozoic Savory Basin Western Australia in The
sedimentary basins of Western Australia edited by P G PURCELL and R R PURCELL
Petroleum Exploration Society of Australia Symposium Perth WA 1994 Proceedings p
841ndash850
WILSON R B 1967 Woolnough Hills and Madley diapiric structures Gibson Desert WA
APEA Journal v 7 p 94ndash102
44
Appendix 2
Meteorological data (from Bureau of Meteorology Perth 1994)
Table 21 Wiluna rainfall (mm)
Year Jan Feb Mar Apr May Jun Jul Aug Sept Oct Nov Dec
1975 0 45 446 309 306 59 276 4 34 886 638 164 1976 16 154 12 138 53 16 34 62 12 238 0 2 1977 44 0 66 74 68 95 24 363 1 58 12 727 1978 234 522 94 16 0 96 367 24 16 353 185 45 1979 19 173 122 88 91 4 0 246 58 0 169 114 1980 148 764 68 1081 259 626 629 06 56 02 174 0 1981 123 476 192 32 196 118 44 74 14 0 28 312 1982 374 705 206 244 1079 92 02 143 368 526 368 118 1983 1 112 928 248 0 212 56 32 5 1 42 496 1984 149 7 342 84 836 0 348 132 224 04 16 172 1985 596 483 0 166 556 0 514 56 0 0 4 0 1986 0 154 35 0 0 1085 23 01 239 137 0 04 1987 1204 119 19 89 17 575 154 126 07 1 0 398 1988 46 202 164 13 388 0 202 104 0 0 224 1309 1989 207 234 26 703 278 536 57 0 01 0 144 02 1990 1035 23 281 46 126 53 94 218 44 9 42 0 1991 48 0 41 45 0 472 297 12 0 1 0 7 1992 112 96 1025 1227 323 65 04 174 0 132 48 4 1993 0 697 0 202 445 0 12 306 18 05 14 33 Mean 25 35 22 27 27 25 18 12 6 13 13 21
JAN FEB MAR APR MAY JUN JUL AUG SEP OCT NOV DEC0
10
20
30
40
Mea
n R
ain
fall
(mm
)
Month
Mean monthly rainfall in Wiluna
MKS41 140498
45
Table 22 Wiluna minimum temperature (degC)
Year Jan Feb Mar Apr May Jun Jul Aug Sept Oct Nov Dec
1975 ndash 23 203 15 94 63 71 62 103 124 169 205 1976 242 229 194 15 10 63 59 73 95 143 16 228 1977 243 25 197 148 96 95 56 86 102 ndash 188 23 1978 241 232 203 18 102 64 76 8 9 152 19 205 1979 255 226 216 167 83 6 59 79 97 145 198 223 1980 255 226 231 155 134 83 68 75 121 108 193 223 1981 245 216 19 182 119 6 54 78 138 159 163 218 1982 232 224 177 16 ndash ndash 37 111 112 164 209 225 1983 235 24 197 147 112 88 39 88 121 162 189 219 1984 241 243 191 156 ndash 72 66 7 95 161 182 211 1985 244 231 ndash 159 98 65 71 73 117 147 205 ndash 1986 ndash 229 226 155 93 96 43 49 10 122 ndash 219 1987 ndash 217 183 175 85 77 68 68 112 ndash ndash 221 1988 238 214 209 178 111 ndash ndash 86 104 157 171 195 1989 ndash 237 199 165 107 67 44 61 107 131 187 ndash 1990 232 ndash 211 155 118 62 57 87 102 149 195 22 1991 26 256 217 168 122 101 78 ndash 113 18 168 219 1992 227 227 214 169 102 98 59 69 ndash 125 159 196 1993 241 218 196 171 103 ndash 49 68 88 128 192 211 Mean 24 23 20 16 10 8 6 8 11 14 18 21
NOTE Dashes indicate data unavailable
JAN FEB MAR APR MAY JUN JUL AUG SEP OCT NOV DEC0
10
20
30
40
Month
MKS43 140498
50
Mean monthly minimum temperatures at Wiluna
Mea
n T
emp
erat
ure
(degC
)
46
Table 23 Wiluna maximum temperature (degC)
Year Jan Feb Mar Apr May Jun Jul Aug Sept Oct Nov Dec
1975 ndash 349 326 281 247 201 197 212 256 248 31 344 1976 374 369 346 297 248 206 208 225 265 287 313 388 1977 397 392 352 296 234 212 222 244 ndash 308 337 383 1978 378 345 346 316 242 195 176 205 231 295 334 356 1979 403 36 364 295 ndash ndash ndash 193 242 318 359 373 1980 392 342 377 275 24 176 179 233 292 288 349 391 1981 385 346 337 342 242 178 201 224 30 326 326 369 1982 372 359 315 307 ndash ndash 196 253 252 305 353 379 1983 381 389 327 272 263 222 187 248 287 321 336 366 1984 378 393 322 299 226 215 178 214 234 ndash 336 364 1985 40 366 ndash 294 224 216 205 212 284 307 355 ndash 1986 ndash 383 372 307 ndash 193 166 196 261 277 ndash 382 1987 ndash 339 328 305 21 202 214 218 275 ndash ndash 374 1988 388 365 353 301 23 ndash ndash 228 283 334 31 33 1989 ndash 375 339 285 238 179 181 219 275 298 336 ndash 1990 368 ndash 36 309 268 19 188 205 274 309 373 393 1991 414 416 363 315 268 206 21 ndash 279 338 332 368 1992 363 383 336 263 213 178 213 197 ndash 285 313 359 1993 396 357 344 301 221 ndash 197 215 253 294 347 362 Mean 39 37 34 30 24 20 20 22 27 30 34 37 NOTE Dashes indicate data unavailable
JAN FEB MAR APR MAY JUN JUL AUG SEP OCT NOV DEC0
10
20
30
40
Month
MKS42 140498
50
Mean monthly maximum temperatures at Wiluna
Mea
n T
emp
erat
ure
(degC
)
47
Appendix 3
Table 31 Summary of palynological results
Drillhole Depth (m) F no(a) GSWA no Lithology Formation Assemblage TAI(b)
BWB 1 74ndash75 F49668 135741 dark-grey siltstone basalt Jilyilli gt5 BWB 1 98ndash100 F49669 135742 dark-grey siltstone basalt Jilyilli gt5 BWB 1 121ndash122 F49670 135743 dark-grey siltstone basalt Jilyilli gt5 TWB 1 86ndash87 F49671 135631 dark-grey siltstone McFadden 3+ TWB 1 104ndash105 F49672 135632 dark-grey siltstone Cornelia 3+ TWB 1 121ndash122 F49673 135633 dark-grey siltstone Cornelia 4 TWB 2 14ndash15 F49674 135634 dark-grey siltstone Skates Hills 3+ TWB 6 49ndash50 F49675 135675 dark-grey siltstone Cornelia 1 3+ TWB 9 49ndash51 F49676 135704 dark-grey siltstone Brassey Range 1 3+ Trainor 1 37497- F49733 138939 black mudstone with Cornelia 5 37509 light-grey siltstone Trainor 1 3809 F49734 138940 dark-grey and black Cornelia 4- laminated mudstone Trainor 1 4170 F49735 138941 black unlaminated mudstone Cornelia 4- Trainor 1 4950 F49851 139501 dark-grey indurated siltstone Cornelia 5 Trainor 1 6032 F49852 139502 dark- and light-grey Cornelia 5 indurated siltstone Trainor 1 6434 F49853 139503 greenish indurated finely Cornelia 5 laminated siltstone LDDH 1 270 F49678 138934 dark-grey siltstone interbeds Waters 1 3+ in enterolithic evaporite Tarcunyah Gp LDDH 1 277 F49679 138935 dark-grey siltstone in cavity Waters 1 3+ in enterolithic evaporite Tarcunyah Gp
NOTES (a) GSWA Fossil Catalogue number (b) TAI = Thermal Alteration Index of Traverse (1988 plate 1)
48
Appendix 4
Savory Sub-basin quantitative magnetic and gravity interpretation (extracted from Cowan 1995)
Summary
A program of quantitative aeromagnetic interpretation has been completed on BMRAGSO data from the Savory Sub-
basin Western Australia Quantitative aeromagnetic interpretation utilized the 3D Euler deconvolution method
supported by wavenumber filtering and image processing The results have provided useful information on structural
trends and depth to magnetic sources in a structurally complex area Depth to magnetic source analysis has provided
information on intra-sedimentary magnetic sources as well as basement rocks
The results of the interpretation support previously identified depocentres However the presence of magnetic
sources at several levels makes it very difficult to produce a reliable magnetic basement depth contour map It is
considered more productive to work with the 3D Euler colour circle plots and images rather than trying to contour the
results It would be necessary to carry out a full-scale interpretation of the BMRAGSO profile data to improve on the
3D Euler results The regional gravity was found to be useful in interpreting the regional setting of the area although
the very wide data spacing limits quantitative use of the data The gravity data show quite a complex picture with
limited consistent correlation between gravity features and basin structures This suggests that gravity anomalies
reflect changes in density of the basement rocks rather than basement topography especially in the northern part of the
basin
It is recommended that the GSWA investigate access to company confidential high-resolution aeromagnetic data
prior to planning further aeromagnetic surveys Private companies have flown large parts of the northern half of the
area as part of their diamond exploration program Additional gravity coverage of the area may be more cost effective
than magnetic surveys as the gravity data provides more information on changes within the sedimentary section
Introduction
The main use of aeromagnetic data in petroleum exploration has been the determination of magnetic basement
topography although there has been increasing interest in analysis of intra-sedimentary magnetic anomalies
intrabasement and suprabasement magnetic anomalies These anomalies are used to determine depth to magnetic
basement rocks and hence determine the thickness of the sedimentary sequence Unfortunately interpretation of the
intrabasement and suprabasement magnetic anomalies is non-unique in terms of position and size of causative sources
because of the inherent ambiguity of potential-field methods However this ambiguity can be reduced by placing
49
constraints on source geometry and magnetization and by using geological and other geophysical data to constrain
the solution
Before 1970 most depth-determination techniques involved graphical determination of slopes of selected
magnetic anomalies and application of various empirical factors to convert the slopes into depth estimates Geological
Society of America Memoir 47 Interpretation of Aeromagnetic Maps by Vacquier et al (1951) was a landmark for
this type of interpretation
Automated interpretation procedures have played an increasingly important role in depth interpretation and a
wide range of techniques have been developed Many of these techniques are designed for application to located data
profiles and assume a two-dimensional geometry However there has been renewed interest in techniques applicable
to gridded data
Two distinct types of method can be recognized In the first case often described as discrete methods individual
isolated magnetic anomalies are interpreted and the results used to produce a map of basement relief In the second
case often described as continuous methods areas of data containing a number of anomalies are interpreted
statistically to produce direct output of basement depths
The discrete methods usually involve a semiautomatic initial phase which generates a large number of possible
depth solutions and an interactive second phase to screen and select acceptable solutions The advantage of this
approach is that the interpreter can select features that are relatively free from interference from adjacent anomalies
and consider all aspects of a particular magnetic anomaly The disadvantage is that interpretation can be very time
consuming as a wide range of depths are usually possible depending on the initial model chosen and a significant
amount of effort is needed to select the correct model In the case of the Savory Sub-basin dataset we encountered
problems in separating basement related effects from the effects of shallower intrasedimentary magnetic sources
Because of these problems we have concentrated on displaying the Euler results accompanied by separation filter
images of the data to show the shallower effects and deeper effects rather than trying to refine a 3D Euler
deconvolution depth-to-crystalline-basement contour
The continuous methods are very direct provided that the rather restrictive assumption can be made that all
anomalies are due to lateral magnetization changes due to basement topography This means that shallow effects and
large intrabasement anomalies must be removed from the data This involves judgement and skill as it is necessary to
distinguish between the lower amplitude suprabasement anomalies due to basement topography and the larger
intrabasement anomalies reflecting magnetization changes within the basement These methods were not considered
suitable for the Savory Sub-basin magnetic dataset but were used to invert the gravity data
50
Limitations of magnetic and gravity interpretation
Interpretation of the area is limited by a shortage of information on the nature and physical properties of the deeper
sedimentary sequence and the underlying basement rocks However using techniques such as cross-correlation of
gravity and pseudo-gravity data it is possible to try to differentiate between anomalies relating to basement and those
related to the sedimentary sequence
Gravity anomalies reflect changes within the sedimentary sequence as well as basement condition These
changes in density of sedimentary rocks produce gravity anomalies without a corresponding magnetic anomaly hence
the complementary nature of gravity and magnetic surveys The main use of magnetics is to determine depth to
magnetic basement and any intra-sedimentary volcanic rocks or intrusives whereas gravity provides much more
general information on the sedimentary sequence
Unfortunately interpretation of gravity anomalies is complicated since they can be due to a number of geological
features including
bull major basement faults
bull basement highs
bull igneous intrusions within the basement
bull sedimentary basins which may or may not be isostatically compensated
bull intra-sedimentary volcanics and associated plutonic centres
Two major problems affect the interpretation of both magnetic and gravity data
1 The inherent ambiguity of potential-field data There is no unique solution to any measured gravity or magnetic
anomaly and theoretically there will be an infinite number of source geometry and magnetizationdensity
combinations which will fit the observed data This means that any a priori information which helps to select a
suitable model is very useful
2 Measured anomalies are the summation of effects from different depths For example an observed gravity profile
may contain contributions from shallow sources (density variations within the sedimentary basin) intermediate
depth sources (density variations due to large igneous intrusions within the basement) and deep sources (crustal
thinning producing a mantle anomaly) Separation of these component responses is the regionalresidual problem
which we solve using spectral analysis and differential upward continuation-based separation filtering
Regional setting and interpretation overview
The area studied includes parts of BALFOUR DOWNS (SF51-9) RUDALL (SF51-10) ROBERTSON (SF51-13) GUNANYA
(SF51-14) COLLIER (SG50-4) BULLEN (SG51-1) TRAINOR (SG51-2) MADLEY (SG51-3) NABBERU (SG50-5)
STANLEY (SG51-6) and HERBERT (SG51-7) 1250 000 sheets Broadly the area lies between latitudes 22deg00rsquondash25deg30rsquoS
and longitudes 119deg30rsquondash123deg30rsquoE
51
Regional gravity
The AGSO regional gravity data (at nominal 11 km spacing) was gridded at a 4 km mesh spacing using a minimum-
curvature algorithm Bouguer gravity values in the area are negative reflecting mass deficiency at depth and range
from -84 mgals to -25 mgals
A Bouguer gravity colour image is shown as Figure 41 A residual grid was produced by removing a fifth-order
orthogonal polynomial from the Bouguer data but did not add to the interpretation
120deg 121deg 122deg 123deg
23deg
24deg
25deg
-25
-84
50 km
MKS46 180598
mgal
Figure 41 Regional Bouguer gravity (BMRAGSO data) gridded at 4 km
52
The data show a complex pattern of positive and negative anomalies with no clearly defined trends Correlations
with aeromagnetic data and known basin structures are poor A vague north-northwest linear trend appears to coincide
with the Marloo Fault (Figure 42) A prominent negative anomaly appears to coincide with the Blake Fold and Fault
Belt depocentre and continues as a narrower negative anomaly to the east until it widens out again near the edge of the
basin Elsewhere the gravity data show little correlation with known basin structures and it is likely that especially in
the north of the area gravity anomalies are due to density changes in the basement rather than changes in basement
topography
Production of wavelength-filtered residual gravity plots and vertical gradient plots showed very patchy aliased
data reflecting poor sampling in much of the area
Regional magnetics
The AGSO regional aeromagnetic data were gridded at a 400 m mesh spacing using a minimum-curvature algorithm
(Figure 43) Most of the data has a line spacing of 1600 m with small areas of 1 km spacing The quality of the data is
acceptable for regional interpretation but is not adequate for detailed analysis The accuracy of the flight path is rather
variable reflecting the vintage of the data and the noise envelope of the data is poor by modern standards Problems
were also encountered in joining different map sheets
The magnetic anomaly pattern over the south and west part of the area shows a strong high frequency signature
reflecting the presence of widespread basic sills and dykes Some of the major north-northeasterly trending dykes can
be traced over considerable distances
Discontinuous high-frequency anomalies extend as a northwest-trending zone through the centre of the area and
this zone includes a conspicuous circular magnetic anomaly which is probably a ring complex
The northern and eastern parts of the area are characterized by long-wavelength deep-seated basement magnetic
anomalies with 120deg and 150deg trends dominant The Marloo and Perentie Faults (Figure 42) appear as distinct linear
zones and offsets A prominent easterly trending negative anomaly in the northwest of the area appears to swing round
to the southeast and may separate different basement blocks One possible interpretation is that this very deep seated
anomaly separates areas of Archaean and Proterozoic basement
Regional geology
The regional geology is described in Williams (1992) The GSWA provided a digitized version of Plate 2 from this
Bulletin the structural interpretation map to use as an overlay (Figure 42)
53
Pp
Pp
PSd
PSd
PSd
PSd
PSd
PSo
PSt
PSt
PSf
PSf
PSf
PSb
PSb
PSb
PSsPSs
PSs
PSb
PSm
PSp
PSc
PSc
PSw
PSw
PSw
PSg
PSr
PSj
PSg
PM
Pk
PY
PY
PSd
L
L
L
L
L
L
L
LL
L
L
L
LL
L
LL
L L
LL
L L
L
L
L
L
L
L
L
LL
L
L
BLAKEDEPOCENTRE
MA
RLO
O
FAU
LT
PERENTIEFAULT
50 km
MKS39120598
120deg 121deg 122deg 123deg
25deg
24deg
23deg
Approximate boundaryof aeromagnetic interpretation
PML
PSgL
PSjL
PML
PSpL
PML
PML
PSfL
PSfL
PSpL
LPc
LPcLPcPSrL
LPA
Durba Sandstone
Woora Woora Formation
McFadden Formation
Tchukardine Formation
Boondawari Formation
Skates Hills Formation
Mundadjini Formation
Coondra Formation
Spearhole Formation
Watch Point Formation
Jilyili Formation
Brassey Range Formation
Glass Spring Formation
Paterson Formation
Yeneena Group
Karara Formation
Cornelia Formation
Kahrban Subgroup
Bangemall Group
Fault
Formation boundary
PSdL
PSoL
PSfL
PStL
PSbL
PSsL
PSmL
PScL
PSpL
PSwL
PSjL
PSrL
PSgL
Pp
PYL
PkL
LPc
LPA
PML
Savory Group Other Units
PYL
Figure 42 Regional geology and structure map (after Williams 1992)
54
120deg 121deg 122deg 123deg
23deg
24deg
25deg
5820
3750
MKS47 180598
nT
50 km
Figure 43 Regional aeromagnetic data total magnetic intensity (BMRAGSO data) gridded at 400 m
Analysis
3D analysis
3D Euler deconvolution was used as the primary depth-determination method The advantage of this approach is that
consistent solutions can be obtained over the entire area with minimal assumptions about source geometries Euler
deconvolution of gridded data is used for positional information and estimation of depth to top of source Euler
55
deconvolution yields a large number of depth solutions which have to be screened to reject spurious solutions Results
are plotted as circles in eight depth ranges with radius proportional to depth and colour coded
The 400 m total magnetic intensity grid was used for the analysis Horizontal gradients in x and y and the vertical
gradient were calculated 3D Euler deconvolution was tested on the 400 m gridded data using windows of 9 times 9 and
11 times 11 and 16 times 16 data points and structural indices 05 (fault) and 10 (sill or dyke) It was concluded that the
16 times 16 window produced the best results overall and final plots were produced for the 16 times 16 window and structural
index 05 (Fig 44) Results were very good over the northern and central parts of the area showing magnetic sources
Figure 44 Depth to magnetic source 3D Euler deconvolution 16 times 16 window of 400 m gridded data structural index 05
56
at several different levels Unfortunately in the extreme south of the area shallow intrasedimentary magnetic sources
(sills and dykes) dominated the inversion and the results contained few basement solutions
In order to reduce these problems the 400 m gridded data were filtered using a separation filter based on
interpretation of the log-energy spectrum The 3D Euler method was run on the filtered data in order to generate more
basement-depth solutions Results for the deep-separation filter data were gridded and presented as a colour image in
Cowan (1995) Attempts to grid the Euler output were unsatisfactory and it is considered safer to interpret the 3D
Euler depth plots The 3D Euler depth results from the separation-filter run should be analysed with care as perfect
separation of the basement can never be achieved and there will always be some contamination from sources at
different levels
The results of original total magnetic intensity 3D Euler depth estimation for structural index 05 using a 16 point
window have been plotted at 1500 000 scale (not included in this publication but available in Cowan (1995) from the
GSWA Library as S10331) and as reduced A4 colour circle plots (Figure 44)
The results of deep-basement 3D Euler depth estimation for structural index 05 using a 16 point window have
been plotted as a colour image at 1500 000 scale and as an A4 image (not included in this publication)
2D analysis
Two equispaced profiles were interpolated with a 50 m station interval from the AGSO-located data profiles for the
BULLEN 1250 000 sheet The interpolated profiles were analysed using 2D Euler deconvolution and Werner
deconvolution Results are included in Cowan (1995) and show the use of these methods for more detailed analysis
Filtered data
In order to reconcile 3D Euler results from shallow basement and intrasedimentary magnetic sources we produced
several separation-filtered maps and images We found the shallow-layer double-separation filter (Figure 45) to be
very effective for shallow sources and the deep-layer standard-separation filter (Figure 46) for the basement layer
Gravity and magnetic data correlation
Both lsquoreduced to the polersquo (RTP) magnetics (Figure 47) and pseudo-gravity data (Figure 48) were produced as part of
the reconciliation of gravity and magnetic signatures In both cases the filtering operations assumed magnetization by
induction in the present Earths field The RTP data are fairly similar to the total magnetic intensity The pseudo-
57
gravity data are dominated by a northwest-trending strong positive anomaly and there is little correlation with the
Bouguer gravity data
The poor magneticgravity correlation is confirmed by cross-correlation of the RTP magnetics and the gravity
gradient The correlation plot in Figure 49 shows little coherent response with numerous zones of positive and
negative correlation
Figure 45 Regional aeromagnetic data shallow layer separation filter (BMRAGSO data) gridded at 400 m
Results
In the north and east of the area on the Wells Foreland Sub-basin trend (refer to Figure 1 main text) we see a range
of quite deep 3D Euler depths and several trend directions with north-northwesterly dominant There are relatively few
shallow intrasedimentary solutions in this zone
The second area of deep 3D Euler solutions lies over the Blake depocentre (Figure 43) with several trend
directions
Elsewhere the 3D Euler results are dominated by shallow intrasedimentary depth solutions reflecting mainly the
dolerite sills dykes and the ring complex However where we do see basement-related solutions in the south and
west of the area they appear to be shallower than those noted for the Wells Foreland Sub-basin and the Blake
depocentre
58
Figure 46 Regional aeromagnetic data deep-layer separation filter (BMRAGSO data) gridded at 400 m
Figure 48 Regional aeromagnetic data pseudo-gravity transform (BMRAGSO data) gridded at 400 m
Figure 47 Regional aeromagnetic data reduced-to-pole (BMRAGSO data) gridded at 400 m
Figure 49 Regional aeromagnetic and gravity data gravitymagnetic correlation using RTP magnetics and gravity gradient (BMRAGSO data) gridded at 4 km
59
This subdivision of the area into two zones of deep solutions is consistent with interpreted depocentres
However the interference between sources at different levels and the complexity of the magnetic response of the
basement rocks precludes more refined interpretation at this stage
The area of deep 3D Euler solutions over the Blake depocentre correlates with the pronounced negative gravity
anomaly discussed in the gravity interpretation section Using a density contrast of -015 gcc the negative gravity
anomaly could indicate up to 6ndash8 km of low-density sedimentary rocks depending on assumptions about the regional
field
The area of deep 3D Euler solutions over the Wells Foreland Sub-basin has a complex gravity expression and no
clear basin structure emerges from inversion of these data As noted previously it is likely that observed gravity
anomalies reflect contrasts in basement density rather than basement topography
Separation filtering applied to the magnetic data helps to enhance the intrasedimentary magnetic signature and to
give a better impression of the basement magnetic signature even though separation of the basement response is not
perfect
Conclusions
Quantitative aeromagnetic interpretation using 3D Euler deconvolution supported by wavenumber filtering and image
processing has been successful in providing structural trend and depth information for the Savory Sub-basin
Quantitative magnetic interpretation has revealed two zones of relatively deep magnetic basement beneath the
Wells Foreland Sub-basin and the Blake depocentre
This analysis of the magnetic data supports interpreted depocentres but the complexity of the basement magnetic
signature and interference from sources at different depths precludes further refinement to a map of basement
topography
Regional gravity proved to be very useful in understanding the regional setting of the area and in providing
support for aspects of the interpretation The gravity data support the interpretation of the Blake depocentre
suggesting up to 6ndash8 km of low-density sedimentary rocks
The deep structure of the Savory Sub-basin area is obviously complex with different areas underlain by
Archaean and Proterozoic basement and with the Capricorn suture occurring in the centre of the area
60
Recommendations
The quantitative magnetic interpretation needs to be reconciled with geological models available for the area
In particular the zones tentatively identified as areas with thick sedimentary rocks the Wells Foreland Sub-
basin and the Blake depocentre need to be investigated
Cross sections should be prepared across the basin for joint magneticgravity modelling especially for the Blake
depocentre It is important to be able to explain the strong negative gravity anomaly in this area
In view of the effects of basement density contrasts on the gravity field for the northern part of the area we think
that additional gravity interpretation and acquisition of new gravity data may not be justified as they will not
contribute significantly to understanding basin evolution and structure
It is recommended that GSWA try to get access to company confidential high-resolution aeromagnetic data
rather than flying new surveys The GSWA might offer to fund flying of new infill areas as a bargaining point
References
The original text of this report by Cowan (1995) and 1500 000 scale maps are filed in the GSWA Library under
S10331
COWAN D 1995 Savory Basin quantitative magnetic interpretation Western Australia Geological Survey S-series
S10331 (unpublished)
VACQUIER V STEENLAND N C HENDERSON R G and ZIETZ I 1951 Interpretation of aeromagnetic
maps The Geological Society of America Memoir 47 151p
WILLIAMS I R 1992 Geology of the Savory Basin Western Australia Western Australia Geological Survey
Bulletin 141 115p
61
Appendix 5
Geochemistry
MKS38 250398
Saturate FractionC12+ GLC
1217
Pr18
Ph
22
31CSR WELL-13 315m Cuttings
Figure 51 Canning Stock Route Well 13 gas chromatograph of extract of auger drill sample
12
17
18
22
31
Pr Ph
LDDH 1 6623m CoreSaturate FractionC12+ GLC
MKS35 240398
Figure 52 Gas chromatograph of extract from core sample at 6623 m LDDH1
62
Table 51 Canning Stock Route Well 13 auger drill samples
GSWA sample Drill depth (m)(a) Comments
135601 150 At watertable 135602 203 (all samples consist 135603 310 of sand mud and water) 135604 315 At total depth
NOTE (a) Datum for drill depth is the top of sediment fill in the well which is 155 m below ground level (ie the total depth of 315 m is 47 m below ground level)
Table 52 Canning Stock Route Well 13 gas chromatography data for 315 m depth sediment sample
Parameter Value
Weight of rock extracted (grams) 945 Total extract (ppm) 519 n-Alkane distribution n-C12 07 n-C13 23 n-C14 26 n-C15 22 n-C16 19 n-C17 14 i-C19 23 n-C18 14 i-C20 08 n-C19 11 n-C20 16 n-C21 25 n-C22 29 n-C23 70 n-C24 42 n-C25 95 n-C26 43 n-C27 83 n-C28 38 n-C29 87 n-C30 31 n-C31 273 Alkane compositional data Pristane phytane ratio 279 Pristane n-C17 ratio 161 Phytane n-C18 ratio 059 CPI (1)(a) 284 CPI (2) 209 (C21 + C22) (C28 + C29) 043
NOTE (a) CPI= Carbon preference index
63
Table 53 LDDH1 extract liquid chromatography data for 6623 m concentration
Rock extracted Total extract (grams) (ppm)
702 313
NOTE ppm= parts per million
Table 54 LDDH1 saturate gas chromatography data of core for 6623 m alkane composition
Pristane Pristane Phytane (a) CPI (1) CPI (2) (C21+C22) Phytane n-C17 n-C18 (C28+C29)
103 026 024 103 102 325
NOTE (a)CPI = carbon preference index
Table 55 LDDH1 saturate gas chromatography data of core for 6623 m n-alkane distributions
Parameter Value
n-C12 17 n-C13 38 n-C14 55 n-C15 60 n-C16 65 n-C17 74 i-C19 19 n-C18 78 i-C20 19 n-C19 80 n-C20 79 n-C21 71 n-C22 64 n-C23 57 n-C25 43 n-C24 38 n-C27 31 n-C28 23 n-C29 19 n-C30 12 n-C31 10
64
Appendix 6
Table 61 Summary of data from Trainor waterbores (TWB) and Bullen waterbores (BWB)
Well AMG Elevation TD Status(b) Completion details Water Salinity Water level Flow rate Depth to consolidated AGD84 GL (m) (m) struck mgl(c) (m) (LHr) lithology aquifer(e) Z51(a) Interval (m) (100 mm PVC) (m) (mgl)(d)
TWB 1 473660E 453 122 comp 0ndash75 plain 63 7 300 24 2 880 12 m 7287404N 75ndash93 slotted (9 260) McFadden Fm 93ndash99 plain TWB 2 472 977E 475 23 abd nil 15 m 7285877N Skates Hills Fm dry TWB 3 473259E 475 50 abd nil 7 m 7285849N Skates Hills Fm dry TWB 4 463225 E 445 50 comp 0ndash22 plain 35 7 200 55 3 600 0 m 7286143N 22ndash34 slotted (8 140) Tertiary sand and gravel 23ndash60 plain TWB 5 463095E 445 31 comp 0ndash19 plain 13 26 000 655 3 600 Tertiary sand and gravel 7277721N 19ndash25 slotted (36 700) 25ndash31 plain TWB 6 457013E 455 50 comp 0ndash42 plain 38 920 119 600 0 m 7274352N 42ndash48 slotted (1 030) Cornelia Fm ss TWB 7 453739E 475 26 susp 0ndash2 plain 11 9 300 48 4 500 0 m 7263891N (10 500) Tertiary sand TWB 8 433893E 535 60 susp 0ndash2 plain 47 8 500 gt46 1 200 0 m 7245991N (10 900) Tertiary sand and Brassey Range Fm ss TWB 9 437219E 505 51 comp 0ndash47 plain 45 1 000 58 600 1 m 7235905N 47ndash51 slotted (990) Brassey Range Fm ss TWB 10 434927E 495 32 susp 0ndash2 plain 235 450 120 0 m 7225875N (500) Dolerite
65
BWB 1 287337E 580 122 abd Nil 1 m 7245861N Jilyili Fm dry BWB 2 288346E 545 50 comp 0ndash26 plain 15 630 3 29 000 0 m 7240423N 26ndash38 slotted (730) Tertiary sand and gravel 38ndash50 plain BWB 3 305637E 545 50 abd 19 8 800 43 7 200 0 m 7240423N (10 550) Tertiary ss BWB 4 320167E 515 445 comp 0ndash20 plain 9 980 445 24 000 0 m 7248097N 20ndash32 slotted (1 190) Tertiary ss 32ndash44 plain BWB 5 353393E 545 20 susp 0ndash2 plain 45 (970) 1 m 7238934N Basalt
NOTES (a) GPS accuracy ~ 150 m (b) Comp = completed abd = abandoned susp = suspended (c) Salinity from conductivity (d) Analysis total dissolved solids (e) Fm = Formation ss = sandstone
GEOLOGICAL SURVEY OF WESTERN AUSTRALIA
Record 19985
A REVIEW OF DATA PERTAINING TO THE HYDROCARBON PROSPECTIVITY OF THE SAVORY SUB-BASIN OFFICER BASIN WESTERN AUSTRALIA by M K Stevens and G M Carlsen Perth 1998
MINISTER FOR MINES The Hon Norman Moore MLC DIRECTOR GENERAL L C Ranford DIRECTOR GEOLOGICAL SURVEY OF WESTERN AUSTRALIA David Blight The recommended reference for this publication is STEVENS M K and CARLSEN G M 1998 A compilation and review of data pertaining to the
hydrocarbon prospectivity of the Savory Sub-basin Officer Basin Western Australia Western Australia Geological Survey Record 19985 65p
National Library of Australia Card Number and ISBN 0 7309 6588 0 Copies available from Information Centre Department of Minerals and Energy 100 Plain Street EAST PERTH WESTERN AUSTRALIA 6004 Telephone (08) 9222 3459 Facsimile (08) 9222 3444
iii
Contents Abstract 1
Introduction 2
Access and climate 4
Regional geology 6
Stratigraphy 6
Depositional Sequence A Supersequence 1 11
Depositional Sequence B Supersequence 1 11
Depositional Sequence C Supersequence 3 14
Depositional Sequence D Supersequence 4 14
Depositional Sequence E Supersequence 4 14
Other depositional sequences and regional correlations 14
Structural setting 17
Exploration history 19
Hydrocarbon potential 19
Source rocks 22
Maturity 23
Reservoirs 25
Seals 25
Traps 26
Preservation of hydrocarbons 26
Reported hydrocarbon shows and oil seep 27
Geological and geophysical data bases 27
Drilling 28
Petroleum industry data 28
Government data 28
Mineral industry data 28
Hydrogeological data 29
Seismic data 29
Aeromagnetic surveys 29
Government data 29
Mineral industry data 30
Gravity surveys 30
Government data 30
Mineral industry data 30
Government and academic reports 32
Chronostratigraphy and geochemistry 32
Proposed work program 32
Conclusions 33
References 35
iv
Appendices
1 Bibliography 41
2 Meteorological data 44
3 Summary of palynological results 47
4 Cowan Geodata Services Report Savory Sub-basin quantitative magnetic and gravity
interpretation 48
5 Geochemistry 61
6 TWB and BWB waterbore data 64
Figures
1 Structural subdivisions of the Savory Sub-basin 3
2 Localities and access routes of the Savory Sub-basin 5
3 Formations lithology and depositional sequences AndashE of the Savory Sub-basin 7
4 Correlation of Savory Sub-basin formations with the western Officer and Amadeus Basins 10
5 Locations of petroleum exploration wells mineral exploration and stratigraphic drillholes
and waterbores and wells 12
6 Geological cross section through significant drillholes 13
7 Regional geological setting of the Savory Group and western Officer Basin 15
8 Locations of aeromagnetic and gravity surveys 21
9 Petroleum source potential of rocks in Normandy LDDH1 24
10 Regional Bouguer gravity map of the Savory Sub-basin 31
11 Detailed Bouguer gravity map of the Savory 1995 Gravity Survey from the
eastern Savory Sub-basin 31
Tables
1 Summary of formations in the Savory Sub-basin 8
2 Neoproterozoic formations and hydrocarbon shows in diamond drillholes in the
Savory Sub-basin 20
~Version Information13 VERS 120 CWLS log ASCII Standard -VERSION 12013 WRAP NO One line per depth step131313~Well Information Block13MNEMUNIT Data Type Description13--------- ------------ -----------------------------13 STRTM 5000013 STOPM 00013 STEPM -10013 NULL -9992513 COMP COMPANY GEOLOGICAL SURVEY OF WA 13 WELL WELL TWB 6 13 FLD FIELD SAVORY SUB-BASIN 13 LOC LOCATION AGD84 Z51 457 013E 7 274 352N 13 PROV PROVINCE WESTERN AUSTRALIA 13 SRVC SERVICE COMPANY BPB Wireline Services 13 DATE LOG DATE 16-NOV-1995 13 UWI UNIQUE WELL ID 131313~Curve Information Block13MNEMUNIT Curve Description13--------- -----------------------------13 DEPTM DEPTH13 GRNPGAPI GAMMA FROM NEUTRON TOOL 13 LSN SNU LONG SPACED NEUTRON 13 SSN SNU SHORT SPACED NEUTRON 13 RPOR LIMEST NEUTRON POROSITY 13 BISIMM BIT SIZE 131313~Other Information13NEUTRON POROSITY GAMMA RAY LOG 13LOGGED THROUGH PVC CASING 13 13 13 13Run number ONE Log 1st rdg 497 M Log last rdg 0 M 13Driller TD 50 M Logger TD 50 M Water level 8 M 13Perm Datum GL Elevation Approx 455 M Other srvcs 13Dril mes from GL Log meas from GL 0 M Other srvcs 13Elevation KB DF GL 13Casing Driller Casing Logger Casing size 100 MM 13Casing Weight PVC From 0 M To 50 M 13Bit size 168 MM From 4 M To 50 M 13Hole fl type WATER Sample source Fluid loss 13Density Viscosity pH 13RM meas tmp RMF mes tmp RMC mes tmp 13RM BHT RMF source RMC-source 13Max rec temp Time snc circ LsdSecTwpRge 13Equipment no V338 Base PERTH Equip name NN1 13Recorded by RALEES Witnessed by MKSTEVENS Sonde srl no 5094421 13Last title Last line Permit no 131313~A Depth GRNP LSN SSN RPOR BISI13 50000 -999250 -999250 -999250 -999250 15000013 49900 -999250 -999250 -999250 -999250 15000013 49800 -999250 -999250 -999250 -999250 15000013 49700 -999250 -999250 -999250 -999250 15000013 49600 -999250 -999250 -999250 -999250 15000013 49500 -999250 -999250 -999250 -999250 15000013 49400 -999250 216309 1965945 21484 15000013 49300 -999250 209718 1885054 18983 15000013 49200 -999250 193254 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1
A review of data pertaining to the hydrocarbon prospectivity of the Savory Sub-basin Officer Basin
Western Australia
by
M K Stevens and G M Carlsen
Abstract
The Savory Sub-basin of the Officer Basin in central Western Australia is part of a large Neoproterozoic episutural basin and is a frontier for hydrocarbon exploration It contains up to 8 km of clastic carbonate and rare evaporite sedimentary rocks with minor volcanic dykes sills and flows No petroleum exploration activity had been undertaken in this sub-basin prior to 1995 and hydrocarbon prospectivity is assessed from mineral and recent petroleum exploration drilling No seismic data have been acquired An interpretation of available data suggests that source-rock quality is the major exploration risk but that further investigation of the sub-basin is warranted
Minor oil shows (fluorescence with solvent cut) recorded in Spearhole Formation sandstones in the northwest of the sub-basin suggest oil has been generated and migrated into potential reservoirs in the sub-basin
Each of the five depositional sequences recognized in the sub-basin contain potential reservoir rocks which are seen in outcrop as friable sandstones The Durba Sandstone is interpreted as the best-quality reservoir Indications of evaporitic environments from the Mundadjini Skates Hills and Boondawari Formations suggest that seals may be provided by evaporites and mudstones Neoproterozoic to Cambrian rocks may provide structural closures including both fold and fault traps for migrating hydrocarbons Salt diapirs are interpreted from the gravity data A large semi-detailed gravity survey in the eastern part of the sub-basin revealed major folds faults and halokinetic structures
Potential source rocks include marine mudstones of the Skates Hills and Mundadjini Formations which are associated with stromatolitic dolomites and evaporites Rare outcrops of black mudstones from other units such as the Boondawari Formation also suggest source potential
The Geological Survey of Western Australia has drilled one stratigraphic hole (Trainor 1) in the sub-basin to assess the source potential of Neoproterozoic sedimentary rocks Five of the six samples analysed for Total Organic Carbon in the Cornelia Formation from this well exceeded 05 but have a high level of maturation with at best dry gas-generating potential The age of the Cornelia Formation is uncertain but at least part of it is interpreted to be Neoproterozoic and hence part of the Savory succession
Maturity data which are very sparse due to limited drilling are inferred from the Thermal Alteration Index of organic matter to be at about the base of the oil window and the top of the gas window in two
2
waterbores in the southeast of the sub-basin and a mineral drillhole in the north of the region Rock cuttings from a waterbore in the southwest of the sub-basin are overmature for hydrocarbon generation but this bore intersected mafic intrusives and hence may not be representative of maturity for the region
KEYWORDS hydrocarbon prospectivity oil shows Neoproterozoic Savory Sub-basin Officer Basin source rocks diamond drilling
Introduction
Recognition in the late 1980s of a thick sequence of generally weakly deformed Neoproterozoic
sedimentary rocks of relatively low thermal maturity previously included within the
Mesoproterozoic Bangemall Basin (defined as the Savory Basin by Williams 1992) revealed a
hydrocarbon exploration frontier The Savory Sub-basin (Fig 1) now recognized as part of the
Officer Basin is located west of outcrops of Phanerozoic cover rocks of that larger basin The
Officer Basin a large episutural basin which contains clastic carbonate and minor evaporite and
volcanic rocks is considered to be part of the Neoproterozoic Centralian Superbasin (Walter and
Gorter 1994) The age of the Officer Basin successions is not well constrained but in the Savory
Sub-basin it is largely Neoproterozoic with possible Palaeozoic strata present in parts
The boundaries defined by Williams (1992) for the sub-basin have been largely used in this
record but data from sedimentary rocks previously assigned to older basins that are now
recognised or inferred to be of early Neoproterozoic age (Supersequence 1) have been used to
assess the hydrocarbon potential of the northwestern part of the Officer Basin
The southern part of the sub-basin unconformably overlies the Mesoproterozoic Bangemall Basin
The western boundary of the sub-basin is faulted against the Bangemall Basin The eastern
boundary of the Savory Basin as defined by Williams (1992) was placed along the western edge
of Phanerozoic outcrops of the Officer Basin at approximately 123degE longitude Recent studies
(Perincek 1996ab) however have indicated there is little difference in the Neoproterozoic
geology of the two regions The northeastern boundary of the sub-basin was defined as a reverse-
and thrust-faulted contact with the Yeneena and Karara Basins of the Paterson Orogen (Williams
1992) However Bagas et al (1995) subdivided strata from the Yeneena Basin into three new
groups the Throssell Lamil and Tarcunyah Groups The older and more deformed Throssell and
Lamil Groups remain part of the Yeneena Basin and the Paterson Orogen The younger and less-
deformed sedimentary rocks of the Yeneena and Karara Basins were considered to be of
Supersequence 1 age and were reassigned to the Tarcunyah Group The Tarcunyah Group was
considered to be coeval with the older strata of the Savory Sub-basin The Tarcunyah Group
Savory Sub-basin and Officer Basin were grouped into a single tectonic unit which was informally
referred to as the greater Officer Basin (Bagas et al 1995)
3
50 km
120deg 121deg30 123deg
25deg
24deg
23deg
22deg
Blake Fault andFold Belt
Wells Foreland S
ub-basin
TrainorPlatform
MKS32200498
HamersleyBasin
PilbaraCraton
YeneenaBasin
YeneenaBasin
YeneenaBasin
CanningBasin
Sylvania Inlier
BangemallBasin
Bangemall Basin
YilgarnCraton
YilgarnCraton
GlengarryBasin
EaraheedyBasin
Ward Inlier
OldhamInlier
KararaBasin
GibsonSub-basin
(Officer Basin)
WestwoodShelf
(Officer Basin)
KingstonShelf
(Officer Basin)
Rudall Complex
Trainor Platform
(Kahrban Subgroup)
Greater Officer Basin
Savory Sub-basin
Surface anticlinesMAP
AREAPerth
Figure 1 Structural subdivisions of the Savory Sub-basin and surface anticlines
4
During 1994 in consultation with the Petroleum Industry the Department of Minerals and
Energy received State Government funding for a Petroleum Exploration Initiative to be
undertaken by the Geological Survey of Western Australia (GSWA) with a view to identifying
prospective onshore areas for oil and gas thus increasing the level of onshore exploration in
Western Australia This initiative was originally funded for the first three years of a five-year work
program Two teams of specialists were formed to investigate the prospectivity of both the western
margin and interior onshore sedimentary basins
The Petroleum Exploration Initiative teams seek to enhance the prospectivity of onshore
basins by reducing through focused investigations the risks perceived by industry to be factors
limiting exploration activity Comprehensive petroleum system reports of the onshore Western
Australian basins are to be completed as a result of the projects undertaken during the five-year
Initiative The objective of the Initiative will be achieved through both the analysis of open-file
exploration data and the acquisition of new data New data will include but not be limited to
geophysical surveys and stratigraphic drilling Project results are to be reported to the industry
through GSWA publications external publications conference reports and oral presentations
This Record is the third in a series of comprehensive reviews by the GSWA of the
hydrocarbon prospectivity of some of Western Australiarsquos interior onshore sedimentary basins
The first Record of this series covered the Canning Basin (Apak and Carlsen 1997) The second
Record reviewed the Western Australian Officer Basin (Perincek 1998) but excluded the Savory
Sub-basin
This study assesses the potential for hydrocarbon exploration within the Savory Sub-basin
based on available geological and geophysical data and defines the scope for future studies
Publications relevant to this investigation but which are not specifically referred to are listed in
Appendix 1
Access and climate
The Savory Sub-basin lies east and southeast of the mining town of Newman in the Pilbara region
(Fig 2) The area is largely uninhabited the only settlement being an outcamp at Poondawari on
the GUNANYA 1250 000 map sheet The outcamp is linked by a graded track to the Jigalong
Community 90 km to the west just outside the northwest margin of the sub-basin A few pastoral
leases lie along the margins of the sub-basin but the majority of the region is Vacant Crown Land
Capitalized names refer to standard map sheets
5
Sealed road
Gravel road
Track
Town
Homestead
Locality
STANLEYSavory Sub-basin boundary 1250 000 map sheet
CornerTrack
Talawana - Windy
Route
Watch Point
NEWMAN
JigalongCommunity
RobertsonRange (abd)
Wokalba
Poondawari
Balfour Downs
Billinnooka
Weelarrana
Beyondie(abd)
Kumarina
Marymia
Glen-ayle
White Lake
Hanging RockBoorabee Hill
WellsRa
EmuRa
Robertson
Ra McFadden R
a
DiebillHills
DurbaHills
Calvert Ra
WardHills
Cornelia Ra
KellyRaBlakeHills
HillsDean
ROBERTSON GUNANYA
TRAINORBULLEN
BALFOUR DOWNS RUDALL
NABBERU STANLEY HERBERT
50 km
Woora Woora Hills
120deg 121deg30 123deg
25deg
24deg
23deg
22deg
Goldfieldsnatural gaspipeline
GR
EA
TN
OR
TH
ER
NH
IGH
WA
Y
Mar
ble
Bar
Nul
lagi
ne-
Rd
MADLEY
Can
ning
Stoc
k
MKS31120598
Goldfields natural gas pipeline
Figure 2 Localities and access routes of the Savory Sub-basin
6
The sealed Great Northern Highway lies west of the Savory Sub-basin and links Meekatharra
to Newman The TalawanandashWindy Corner graded track crosses the northern part of the sub-basin
and graded pastoral station tracks on Balfour Downs Weelarrana Kumarina Marymia and Glen-
Ayle give access to the western and southern margins The Canning Stock Route traverses the sub-
basin from north to south and is a well travelled four-wheel-drive track allowing access to the
eastern half of the sub-basin Additional minor tracks also provide access to other parts of the area
(Williams 1992) Recently flown monochrome aerial photography at 150 000 and Landsat TM
imagery covering the sub-basin is available from the Department of Land Administration
Cross-country access is similar to that in the Canning Basin with the average height of sand
dunes being lower in the Savory Sub-basin Potable water has been found in water bores in the
south of the sub-basin and is inferred to be present throughout the region Fuel and supplies are
available at Wiluna Meekatharra and Newman A good working relationship with the Western
Desert Community who hold native title claims over most of the sub-basin has been established
by GSWA
There are no meteorological stations within the Savory Sub-basin but estimates based on data
from nearby Bureau of Meteorology Stations indicate that the area is arid and has its maximum
rainfall in summer from monsoonal rains The sub-basin has reasonable access and a tolerable
working climate for all exploration activities Meteorological data for the town of Wiluna which
lies about 180 km to the south of the sub-basin are included as Appendix 2
Regional geology
Stratigraphy
Thirteen formations were recognized by Williams (1992) in the Savory Sub-basin and these are
summarized in Table 1 Although unconformities were recognized between some of the
formations and they reflect a wide range of depositional environments provenance and climatic
conditions these formations were defined by Williams (1992) as constituting the Savory Group
Five depositional sequences that are generally unconformity-bounded were recognized by
Williams (1992) (Fig 3) The correlation of significant formations within the sub-basin with other
parts of the Centralian Superbasin is shown in Figure 4 with the four Neoproterozoic
Supersequences having been defined by Walter et al (1995)
7
Durba Ss
McFadden
Woora Woora400
Tchukardine700
Skates Hills
Mundadjini1800
B
Coondra
(B)
Watch Point
Spearhole1100Jilyili
1000(A)
Glass Spring1600(A)
Brassey Range1700(A)
Abs
ent
Absent Absent
Absent
Absent
Absent
A
B
C
D
E
1A
1B
3
4A
4B
1000
2000
3000
4000
5000
6000
Max
imum
thic
knes
s
Sup
erse
quen
ce
AG
EN
EO
PR
OT
ER
OZ
OIC
NE
OP
RO
TE
RO
ZO
ICT
O
CA
MB
RIA
NM
AR
I-N
OA
N
NW SE
Savory Sub-basin Stratigraphy
MKS30 120598
Fault boundary
Unconformity
Disconformity
Conglomerate
Sandstone Mudstone
Siltstone
Evaporite
Dolomite
Boondawari800 Boondawari
Supersequence 2 is not represented in the Savory Sub-basin Total thicknesses are estimated from air photo interpretation Thicknesses of recessive units are unknown
Diamictite
Dep
ositi
onal
seq
uenc
e
Figure 3 Formations lithology and depositional sequences AndashE of the Savory Sub-basin
8
Table 1 Summary of formations in the Savory Sub-basin
Formation Super Depo Lithology Thickness Depositional Savoy Comments Seq(a) Seq(b) (m) environment Group(c)
Durba Sandstone 4 E Quartz sandstone with minor 100 Fluvial lacustrine Y Excellent reservoir basal conglomerate lenses Woora Woora 4 D Medium-grained ferruginous 400 Shallow marine deltaic Y Formation sandstone lithic sandstone quartz wacke siltstone McFadden 4 D Laminated fine- to coarse-grained 1 500 Shallow marine deltaic Y Possible reservoir Formation quartz sandstone feldspathic sandstone quartz wacke minor conglomerate siltstone Tchukardine 4 D Medium- to coarse-grained sandstone 700 Shallow marine Y Formation lithic sandstone quartz wacke conglomerate lenses siltstone minor shale Boondawari 3 C Glacigene diamictite sandstone siltstone Formation shale conglomerate minor dolomite (some stromatolitic and oolitic) rhythmite 800 Glacial shallow marine Y Possible source rock Skates Hills 1 B Thin-bedded dolomite (some stromatolitic) 200 Shallow marine sabkha Y Possible source rock Formation chert evaporites fine- to medium-grained sandstone siltstone shale patchy basal conglomerate Mundadjini 1 B Fine- to coarse-grained sandstone 1 800 Deltaic sabkha Y Possible source rock Formation conglomerate siltstone minor shale shallow marine mudstone dolomite (some stromatolitic) and evaporites Coondra 1 B Coarse- to medium-grained sandstone 1 000 Fan delta Y Possible reservoir Formation poorly sorted conglomerate pebbly sandstone Spearhole 1 B Coarse- to medium-grained sandstone 1 100 Braided fluvial deltaic Y Possible reservoir Formation pebbly sandstone siltstone and oil shows in conglomerate lenses Mundadjini 1 Boondawari 1
9
Watch Point 1 B Shale siltstone fine- to medium-grained 400 Shallow marine deltaic Y Formation sandstone glauconitic sandstone Jilyili Formation 1 A Fine-grained sandstone siltstone minor shale mudstone conglomerate lenses 1 000 Deltaic Y Brassey Range 1 A Fine- to medium-grained sandstone 1 700 Fluvial deltaic Y Formation siltstone shale minor mudstone Glass Spring 1 A Medium- to coarse-grained sandstone 1 600 Shallow marine fluvial Y Formation minor conglomerate and siltstone Tarcunyah Group 1 AampB Quartz sandstone feldspathic sandstone Shallow marine sabkha N Bitumen in LDDH1 quartz wacke shale siltstone fluvial lacustrine conglomerate evaporites dolomite Cornelia 1 A Sandstone siltstone shale mudstone Shallow marine N Overmature source rocks Formation minor glauconitic sandstone deep marine in Trainor 1 Kahrban 1 A Sandstone siltstone shale 1 700 Shallow marine deltaic N Subgroup
NOTES (a) Supersequences of Walter et al (1995) (b) Depositional sequences of Williams (1992) (c) Y= assigned to Savory Group in Williams (1992) N= previously considered to be older than the Savory Group but now included in the greater Officer Basin
10
SAVORY SUB-BASIN GIBSON SUB-BASINCENTRAL OFFICERBASIN
AMADEUS BASIN
PETERMANN RANGES OROGENY
NE
OP
RO
TE
RO
ZO
IC
ST
UR
TIA
NM
AR
INO
AN
ED
IAC
AR
IAN
CAMBRIANTO
NEOPRO-TEROZOIC
AG
E (
Ma)
SOUTHS RANGE MOVEMENT
AREYONGA MOVEMENT
Steptoe
MILES OROGENY
Mission Group
Cassidy Group
Rudall Complex
Bangemall Group
unnamed
Tar
cuny
ah G
roup
4
3
2
1
MKS12a 180598
500
550
600
650
700
750
800
850
900
SU
PE
R
SE
QU
EN
CE
unnamed
Tchukardine Fm
McFadden Fm
ArumberaSst
Julie Fm
Pertatataka Fm
Olympic FmPioneer Sst
Boondawari Fm
Turkey Hill FmLupton Fm
Kanpa Fm
Neale FmBabbagoola
FmHussar
Fm
Browne Fm
Woolnough Fm
Madley Fm
Bitt
er S
prin
gs F
m
LovesCreek M
Gillen M
Heavitree Fm
Arunta Complex
Throssell Group
TownsendQuartzite
Earaheedy Group
olderCornelia Fm
Jilyili Fm
SpearholeFm
MundadjiniFm
Skates Hills Fm
Lefroy Fm
Areyonga Fm
Aralka Fm
ME
SO
-P
RO
TE
RO
ZO
IC
Waters Fm
youngerCornelia Fm
Brassey RangeFormationKahrban
Subgroup
GlassSpring
Fm
Durba Sst
LP1ALP1B EVENT
Figure 4 Correlation of Savory Sub-basin formations with the western Officer and Amadeus Basins Fm = Formation Sst = Sandstone M = Member
11
The depositional sequences recognized in the sub-basin are an order of magnitude thicker than
those described from Phanerozoic passive-margin settings (Payton 1977 Posamentier et al 1988)
and are broadly comparable in scale to the second-order cycles of Vail et al (1977) and to the
megasequences of Hubbard et al (1985) The main subsurface data available to reveal the
unweathered nature of these rocks are Trainor-1 and the three-well diamond coring program in
Petroleum Permit EP 380 (Akubra 1 Boondawari 1 Mundadjini 1) completed in late 1997 in the
central west of the sub-basin (Figs 5 and 6)
The ages of all formations in the Savory Sub-basin are poorly constrained The only fossils
known are stromatolites and palynomorphs (acid-insoluble microfossils) Palynology from
available wells is summarized in Appendix 3 from Grey and Stevens (1997) and Grey and Cotter
(1996) and correlations using stromatolite biostratigraphy (Stevens and Grey 1997 Grey 1995f
Walter et al 1994 1995) are consistent with a Neoproterozoic age for the formations for which
data are available
A dolerite within the Boondawari Formation gave a poorly constrained RbndashSr age of about
640 Ma (Williams 1992) SHRIMP UndashPb dating of sedimentary zircons from the McFadden and
Cornelia Formations in stratigraphic drillhole Trainor 1 are discussed in Stevens and Adamides (in
prep) and Nelson (1997) The youngest ages from these analyses indicate that the maximum age
of the Cornelia Formation is Early Cambrian or Sturtian but these ages are inconsistent with
previous tectonic interpretations (Williams 1992) and current stratigraphic correlations which
suggest the Cornelia Formation is of Supersequence 1 age or older (Fig 4)
Depositional Sequence A Supersequence 1
Depositional Sequence A includes the Glass Spring Jilyili and Brassey Range Formations (Fig
3) All of these units are predominantly quartzose sandstones some of which are friable and have
significant visible porosity in outcrop Conglomerates are present in the Glass Spring and Jilyili
Formations
Depositional Sequence B Supersequence 1
Depositional Sequence B consists of the Watch Point Coondra Mundadjini Spearhole and
Skates Hills Formations (Fig 3) All of these formations contain beds of quartzose sandstone and
some also contain conglomerates The porosity of dolomites in the Skates Hills Formation appears
poor in surface exposures but its subsurface characteristics are unknown
12
50 km
120deg 121deg30 123deg
25deg
24deg
23deg
22deg
Greater Officer Basin
PNCEXP CA11PNCEXP CA12
PNCEXP CA13PNCEXP CA19
PNCEXP CA05
PNCEXP CA09
BD134589
GSWA Trainor 1 and TWB123
Fortescue River 1A
Mundadjini 1
Akubra 1Boondawari 1
TWB4TWB5
TWB6
TWB7
TWB8
TWB9
TWB10
BWB1
BWB2 BWB3
BWB4
BWB5
OD23
Mineral exploration drillhole
Stratigraphic drillhole
Waterbores and wells(TWB and BWB serieswaterbores identified)
MKS33270398
LDDH 1
Savory Sub-basin
Canning SR Well 13
EP380
Petroleum Exploration permit
Petroleum exploration well
Figure 5 Locations of petroleum exploration wells mineral exploration and stratigraphic drillholes water bores and wells and petroleum exploration permit EP380 in the Savory Sub-basin
13
TD=600m
TD=1367m
TD=701m
TD=709m
TD=50m
SS
1S
S1
SS1
SS
1S
S1
SS
1
SS
1
SS1
SS4 SS1
Pha
nero
zoic
or
SS
2
Cz
CzCz
Karst Bitumen
SS1
TD=181m
Mundadjini 1 Akubra 1 Boondawari 1 LDDH 1 Trainor 1 TWB 6
Munda-djini Fm
Spear-hole Fm
Munda-djini Fm
Munda-djini Fm
Spear-hole Fm
Spear-hole Fm
Waters Fm
McFadden Fm
Cornelia Fm
Cornelia Fm
Cornelia Fm
511 plusmn 13Maor 696 plusmn 20Ma(maximum)
779 plusmn 10Ma(maximum)
Mundadjini 1
Akubra 1 Boondawari 1
LDDH 1
Trainor 1TWB 6100 km
N
LOCATION
NW SE
Sea level
0m AHD
Dolerite basalt
Conglomerate
Sandstone
Mudstone
Dolomite
Limestone
Evaporite
TOC gt08
Permeability gt100md
Oil fluorescence
Sedimentary zircon U-Pb age
Identifiable polymorphs
Cainozoic
Supersequence 1 age
Unconformity
Formation contact
Cz
SS1
r
r
0
100
200
metres
VerticalScale
MKS36 120598
LEGEND
Figure 6 Geological cross section through significant drillholes in the Savory Sub-basin
14
Depositional Sequence C Supersequence 3
Depositional Sequence C consists of the Boondawari Formation (Fig 3) and although it contains
sandstone conglomerate and dolomite the sandstones contain significant amounts of feldspar and
clay and hence are likely to be poorer reservoirs than older sandstones
Depositional Sequence D Supersequence 4
Depositional Sequence D includes the McFadden Tchukardine and Woora Woora Formations
(Fig 3) The McFadden Formation is poorly sorted and sandstones contain significant amounts of
feldspathic clasts in the north of the basin but are significantly coarser and cleaner in the northeast
of the sub-basin (Williams 1992)
Sandstones of the Tchukardine and Woora Woora Formations are generally cleaner than those
of the McFadden Formation and are expected to have fair to good porosity although the
Tchukardine Formation has a higher clay content in parts
Depositional Sequence E Supersequence 4
Depositional Sequence E consists of the Durba Sandstone (Fig 3) a coarse sandstone with minor
conglomerate which has good to excellent visible porosity in surface exposures
Other depositional sequences and regional correlations
Sedimentary rocks which were not included in the Savory Group by Williams (1992) but which
are likely to be of Neoproterozoic age and hence part of the greater Officer Basin include the
Tarcunyah Group the Cornelia Formation and the Kahrban Subgroup
As discussed in the Introduction all of the strata in the Karara Basin and the younger strata
of the Yeneena Basin were redefined to form the Tarcunyah Group of the greater Officer Basin
(Bagas et al 1995) (Fig 7) In outcrop the Tarcunyah Group consists predominantly of quartzose
feldspathic and arkosic sandstone shale which is carbonaceous in parts and carbonate which
includes stromatolitic dolomite Mineral hole LDDH1 drilled on GUNANYA intersected the
15
120598
122deg
123deg
21deg
22deg
23deg
24deg
23deg
22deg
21deg
122deg
123deg
Fault
Thrust
Reverse thrust
CANNINGBASIN
OFFICERBASIN
GROUP
PILBARACRATON
TARCUNYAH
SAVORY GROUP
BANGEMALL
GROUP
THROSSELL
GROUP
LAMIL
GROUP
ConnaughtonTerrane
TerraneTalbot
complexTabletop granitic
Tabletop Terrane
Permian
Neoproterozoicgranitoid
50 km
FormationWaltha Woora
McKay Fault
South west Thrust
Vines
Fault
24deg
120deg
YENEENA CANNINGBASIN
ARUNTAINLIERRUDALL
COMPLEX
AMADEUSBASIN
MUSGRAVEBLOCK
OFFICERBASINYILGARN
CRATON
GROUP
GROUP
GROUP
PILBARACRATON
GROUP
EARAHEEDY
GLENGARRY
BANGEMALL
WYLOO GROUP
SAVORY
WA
CARNARVONBASIN
GASCOYNECOMPLEX
GROUPTARCUNYAH
400 kmGROUP
SA
N
T
CamelndashTabletopfault zone
KAHRBANSUBGROUP
CORNELIAFORMATION
MKS37
Figure 7 Regional geological setting of the Savory Group and western Officer Basin The dashed line on the inset map marks the interpreted margin of the greater Officer Basin
16
Tarcunyah Group and consists predominantly of mudstone with minor sandstone limestone
dolomite and anhydrite (Fig 6)
The age of the Tarcunyah Group is uncertain although limited palynological and stromatolite
evidence suggests that it is probably coeval with Supersequence 1 of the Centralian Superbasin
Drillhole LDDH1 contains palynomorphs equivalent to assemblages in the Browne and Bitter
Springs Formations of the Officer and Amadeus Basins respectively and from the Cornelia
Formation in TWB 6 (Grey and Stevens 1997) (Figs 4 and 6) Stromatolite specimens tentatively
assigned to Acaciella australica (Howchin 1914) Walter 1972 occur in the lower Tarcunyah
Group (Bagas et al 1995) The stromatolite Baicalia burra Preiss 1972 and a conical
stromatolite were reported from the upper part of the Tarcunyah Group (Stevens and Grey 1997)
The recognition of two stromatolite assemblages interpreted to have age significance in
Supersequence 1 sedimentary rocks of the Centralian Superbasin has permitted biostratigraphic
correlations between outcrop and well data The Acaciella australica assemblage appears to be
slightly older than 800 Ma and is restricted to the middle part of Supersequence 1 The Baicalia
burra assemblage is considered to be slightly younger than 800 Ma and occurs in the upper part
of Supersequence 1 (Grey 1996b Stevens and Grey 1997) The older A australica assemblage
is recognized in the Skates Hills Formation in the Savory Sub-basin and the stromatolite A
australica itself has been tentatively identified in the lower Tarcunyah Group The occurrence of
the A australica assemblage in the Woolnough Madley and Browne Formations of the Officer
Basin and in the Loves Creek Member of the Bitter Springs Formation of the Amadeus Basin
allows correlations throughout the Centralian Superbasin (Fig 4)
The younger B burra assemblage has not been recognized in sedimentary rocks of the
Savory Group as defined by Williams (1992) but it occurs in the upper parts of the Tarcunyah
Group and allows correlation of this group with outcrops of the Neale Formation and with the
Kanpa Formation in petroleum exploration well Hussar 1 both located in the central Officer Basin
of Western Australia (Fig 4) (Grey 1996b Stevens and Grey 1997) The occurrence of the B
burra assemblage in these units permits their correlation with the Burra Group in the Adelaide
Geosyncline of South Australia (K Grey unpublished data)
The Cornelia Formation and Kahrban Subgroup outcrop in the southeast of the sub-basin and
were considered by Williams (1992) to be part of the Mesoproterozoic Bangemall Basin Limited
evidence suggests that all or parts of these two units are of Neoproterozoic age The Ward and
Oldham Inliers consist of outcrops of the Cornelia Formation Waterbore TWB 6 which was
drilled on TRAINOR in the Cornelia Formation contains palynomorphs consistent with a
Supersequence 1 age (Grey and Stevens 1997) (Figs 5 and 6) In outcrop the Cornelia Formation
17
consists predominantly of sandstone and quartzite with lesser siltstone shale mudstone and chert
In Trainor 1 this formation consists predominantly of indurated mudstone with minor sandstone
chert and dolomite A major erosional unconformity separates the Cornelia Formation from
overlying formations and parts of the Cornelia Formation have been folded with dips exceeding
70deg In contrast the majority of the Savory Sub-basin sedimentary rocks have dips of less than 30deg
except where they are adjacent to faults The Cornelia Formation apparently consists of an older
unit of steeply dipping quartzites cherts and well-indurated mudstones and a younger unit of
shallower dipping sandstones which are sub-friable in parts However caution should be used in
interpreting the age of units based on their structural deformation and additional mapping and age
dating of this formation is required
It is proposed here that the Kahrban Subgroup is likely to be of early Neoproterozoic age and
hence should be considered as part of the greater Officer Basin This proposal is based largely on
the relatively low dip of the strata (generally less than 20deg) and their west-northwest strike which
is parallel with strikes in the overlying Brassey Range Formation of the Savory Group The lower
contact of the Kahrban Subgroup is obscured but is thought to be an unconfirmity on the
Earaheedy Basin on the southeast of STANLEY (Muhling and Brakel 1985)
Structural setting
The Savory Sub-basin forms the most northwesterly sub-basin of the Neoproterozoic to
Phanerozoic Officer Basin The western boundary of the sub-basin with the Mesoproterozoic
Bangemall Basin consists of steep-reverse and strike-slip faults The northeastern boundary of the
Savory Sub-basin was mapped where Supersequence 4 formations of the Savory Group
unconformably overlie sedimentary rocks of the Karara and Yeneena Basins with the two older
units considered to be part of the Paterson Orogen (Williams 1992) This contact was defined as a
series of steeply dipping reverse faults in the northernmost parts of the sub-basin on BALFOUR
DOWNS and RUDALL and was extrapolated as an inferred reverse fault farther along strike to the
southeast on GUNANYA and MADLEY where the contact is obscured by Cainozoic sediments It is
now recognized that all the sedimentary rocks in the Karara Basin and younger sedimentary rocks
of the Yeneena Basin are from the Supersequence 1 Tarcunyah Group and part of the greater
Officer Basin (Bagas et al 1995) The northern boundary of the Tarcunyah Group and the greater
Officer Basin is in thrust-and reverse-faulted contact with the Rudall Complex and other parts of
the Paterson Orogen (Fig 7)
To the south the sub-basin unconformably overlies the Bangemall Basin The eastern
boundary of the sub-basin used in this study is where Permian and younger strata of the Officer
Basin unconformably overlie Neoproterozoic strata although there are no significant structural or
stratigraphic differences between the Neoproterozoic units
18
The sub-basin is subdivided into three principal structural areas (Fig 1) Trainor Platform
Blake Fault and Fold Belt and Wells Foreland Sub-basin (Williams 1992) A major review of
these boundaries is beyond the scope of this report but the processing of regional aeromagnetic
data (Appendix 4) and acquisition of a semi-detailed gravity survey by the GSWA in the east of
the sub-basin has enabled these tectonic units to be reassessed and some modifications are
proposed
The Wells Foreland Sub-basin (originally termed the Wells Foreland Basin in Williams 1992)
and sedimentary rocks of the Tarcunyah Group are both considered to be the northwest
continuation of the Gibson Sub-basin of the Officer Basin Aeromagnetic gravity and outcrop
data suggest that the Blake Fault and Fold Belt is significantly faulted and folded in the west but
is less deformed in the east where the thickest sedimentary section in is located on BULLEN
(Appendix 4) The Trainor Platform is reinterpreted to represent an area of the sub-basin that has
undergone major compression during the Petermann Ranges Orogeny resulting in folding and
faulting with a northwest strike This interpretation contrasts with that proposed by Williams
(1992) who envisaged that only a thin section of the Savory Group was present on the platform
Perincek (1998) has recognized nine periods of tectonic activity in the Officer Basin from the
beginning of the Neoproterozoic to the end of the Cretaceous Three major tectonic episodes are
recognized in the Centralian Superbasin The oldest event is the Areyonga Movement which is
pre-Sturtian and forms the boundary between Supersequences 1 and 2 (Fig 4) The Souths Range
Movement occurred at the end of the Sturtian at the boundary between Supersequences 2 and 3
The youngest major event is the Petermann Ranges Orogeny which occured at the end of the
Marinoan and forms the boundary between Supersequences 3 and 4
One minor and two major tectonic episodes are recognized in the Savory Sub-basin the
LP1ALP1B structural event and the Areyonga Movement and the Petermann Ranges Orogeny
respectively The LP1ALP1B structural event is revealed where the Spearhole Formations rests
disconformably and locally unconformably on the Brassey Range Jilyili and Glass Spring
Formations The Neoproterozoic Areyonga Movement (equivalent to the Blake Movement of
Williams 1992) produced folds and faults with a general northeast strike in the western and
southern parts of the region The Souths Range Movement has not been recognized in the sub-
basin This may be due to the fact that no Sturtian glacial rocks have been identified and hence it
is possible that structures attributed to the Areyonga Movement could be the result of the Souths
Range Movement or a combination of the two movements
The major tectonic event recorded in the sub-basin is the latest Neoproterozoic to Cambrian
Petermann Ranges Orogeny (equivalent to the Paterson Orogeny) which produced large reverse
19
faults thrusts strike-slip faults and folds with a general northwest strike The McFadden
Formation and other Supersequence 4 strata are considered to be at least partially coeval with this
orogeny (Williams 1992) We also interpret the Durba Sandstone as having been deposited during
the later stages of the Petermann Ranges Orogeny as this unit mildly deformed with fold axes
parallel to the strike of other structures attributed to the Petermann Ranges Orogeny
Quantitative aeromagnetic interpretation of the Savory Sub-basin utilizing the 3D Euler
deconvolution method supported by wave-number filtering and image processing has provided
structural trends and depth to magnetic source within the sub-basin (Cowan 1995) Gravity data
are interpreted by Cowan (1995) as changes in both the density of the basement rocks andor
basement topography depending on local conditions Part of Cowanrsquos report is reproduced in
Appendix 4
Exploration history
The only petroleum exploration conducted in the sub-basin has been the recent drilling in the
western part of three diamond drillholes of which two have minor oil shows (Table 2) There has
been some mineral exploration the results of which are stored in the GSWA Western Australian
Mineral Exploration (WAMEX) database system Much of the mineral exploration was in the
southwest and west where the sub-basin is in contact with the Bangemall Basin and along the
northern margin of the sub-basin Many of these mineral exploration programs included
aeromagnetic surveys and surface geochemical sampling (Fig 8)
Hydrocarbon potential
The sub-basin contains a sedimentary succession up to 8 km thick which is generally gently
folded and faulted and apparently unmetamorphosed Limited drilling has shown that thick
mudstones are present in the sub-basin with some mudstones in Trainor 1 having high Total
Organic Carbon (TOC) values Outcrops of sub-friable sandstones in many of the formations
within the sub-basin suggests widespread reservoir potential Mudstone and inferred thick
evaporite sequences are likely to form seals Maturity data suggest that near-surface samples are
approximately at the base of the oil window and top of the gas window in parts of the north and
southeast of the sub-basin However parts of the southwest of the sub-basin and the mudstones in
Trainor 1 have very high levels of maturity Numerous faults and folds have been identified from
surface mapping suggesting good potential for large structural traps Minor oil shows in
20
Table 2 Neoproterozoic formations and hydrocarbon shows in diamond drillholes in the Savory Sub-basin
Drillhole AMG Core TD (m) Approx Formation Depth Formation Depth Formation Depth Shows (AGD84) start (m) GL (m) (m) (m) (m)
LDDH 1 431148E 112 701 350 Tarcunyah 68ndash701 ndash ndash bitumen at 6623 m 7443826N Group Trainor 1 473640E 6 709 455 McFadden 9ndash83 Cornelia Fm 83ndash709 possible bitumen at 4537 m 7287400N Fm Mundadjini 1 319056E 170 600 500 Mundadjini 16ndash361 Spearhole Fm 361ndash600 10 fluorescence at 36102 m 7404844N Fm Boondawari 1 348959E 299 1 367 490 Mundadjini Fm 15ndash312 Spearhole Fm 312ndash1 283 Intrusive 1 283ndash1 367 40 fluorescence at 35364 m 5 7398174N fluorescence at 4963 m Akubra 1 334249E 15 181 530 Mundadjini 15ndash42 Intrusive 42ndash181 None 7401252N Fm
21
50 km
120deg 121deg30 123deg
25deg
24deg
23deg
22deg
Greater Officer Basin
Savory Sub-basin
1
2
3
4
6
8
3 Seismic line (prefixed N83-00)
Aeromagnetic survey
GS
WA
Sav
ory
1995
gra
vity
sur
vey
Gravity survey
MKS34270398
Figure 8 Locations of aeromagnetic and gravity surveys (other than regional BMRAGSO data)
22
sandstones in two petroleum wells in the northwest of the sub-basin and bitumen and oil shows
elsewhere in the region indicate that oil has been generated and migrated through the sub-basin
Source rocks
Source potential is considered to be the major exploration risk in the Savory Sub-basin although
minor oil shows in Mundadjini 1 and Boondawari 1 indicate that at least some oil has been
generated and migrated into potential reservoirs within the sub-basin Sandstone is the
predominant lithology observed in outcrop Outcrops of fine-grained lithologies in the basin are
rare because of intense surface weathering and erosion Only about 8 of the surface area of the
sub-basin is exposed bedrock and recessive lithologies (such as shale evaporite and friable
sandstone) may be present although they rarely outcrop
Outcrops of stromatolitic dolomite with associated cauliflower chert and cubic pseudomorphs
interpreted as being after halite indicate that evaporitic environments are present within the
Mundadjini Skates Hills and Boondawari Formations Evaporitic minerals are also present in
drillhole LDDH1 in the Tarcunyah Group
In 1995 GSWA drilled a continuous-core diamond drillhole (Trainor 1) in the sub-basin on
TRAINOR to a depth of 709 m to test for source rocks thus providing the first such data for the sub-
basin The drillhole intersected flat-lying clastics and carbonates of the McFadden Formation (9ndash
83 m) overlying indurated mudstones of the Cornelia Formation (83ndash709 m total depth) dipping at
about 40deg Of the six samples analysed from the Cornelia Formation in this drillhole the five
located between 375 and 6032 m depth have TOC values exceeding 05 (range 066ndash365)
Rock-Eval pyrolysis of these five samples indicates that they are at best in the dry-gas thermal
stage and as a result of their high level of maturation (Stevens and Adamides in prep) have poor
remaining hydrocarbon-generating potential Although the Cornelia Formation is overmature at
Trainor 1 the high TOC values are encouraging as it is likely that this sequence is less mature
elsewhere in the sub-basin
The Mundadjini Formation contains potential source rocks that comprise marine mudstones
with evaporitic minerals present in parts Thin dark mudstones were intersected in the Mundadjini
Formation in Akubra 1 In Mundadjini 1 and Boondawari 1 however the mudstones appear to be
too oxidized to have source potential
The Boondawari Formation also may be a source rock as it contains black mudstones The
unit is laterally equivalent to the Pertatataka Formation of the Amadeus Basin and the Ungoolya
23
Group of the Officer Basin in South Australia both of which have some source potential
(Summons and Powell 1991 Morton and Drexel 1997) Samples from the Dey Dey Mudstone of
the Ungoolya Group generally have poor TOC values (average 011 range 003ndash081)
moderate hydrogen index (HI) values (100ndash382) and poor to fair genetic potential with a
maximum of 292 kg hydrocarbon per tonne of source rock (Morton and Drexel 1997)
Stromatolitic dolomites and mudstones at the top of the Boondawari Formation and within the
Skates Hills Formation are potential source rocks Stromatolitic dolomite and evaporitic rocks
deposited in a marginal marine to sabkha environment are considered to have good potential to
generate and preserve organic carbon without requiring a deep-water setting (Stevens and Grey
1997) Such conditions are recognized in the Skates Hills Formation and in the upper parts of the
Tarcunyah Group
Maturity
Knowledge of the maturity of sedimentary rocks within the Savory Sub-basin is still limited From
a review of palynological studies Grey and Stevens (1997) report that the thermal maturity
inferred from the Thermal Alteration Index (TAI) of 3+ from Supersequence 1 age palynomorphs
in TWB 6 TWB 9 and LDDH1 is within the hydrocarbon window (Appendix 3) In Phanerozoic
spores and pollen a TAI of 3+ approximately equates to the end of liquid petroleum generation
and the start of dry gas generation and to a vitrinite reflectance of about 13 (Traverse 1988)
However the use of TAI for estimating thermal maturity from Neoproterozoic palynomorphs
requires calibration
In Trainor 1 the Cornelia Formation contains organically rich claystones between 375 and
6032 m depth Based on Rock-Eval maturity data (Stevens and Adamides in prep) and the dark
colour of poorly preserved organic material (Grey 1995de 1996) with TAI 4- to 5 all samples
had a high level of maturation with at best dry-gas generating potential remaining In contrast
drillhole LDDH1 on GUNANYA recorded lower levels of maturity (TAI values of 3+) with two of
sixteen samples from the Tarcunyah Group having greater than 1 TOC (Grey 1995abc Grey
and Cotter 1996) Organic petrology and Rock-Eval maturity data for samples from LDDH1
indicate that the section above 500 m is within the oil-generative window whereas below 500 m
the rocks are within the gas window (Ghori in prep Fig 9 Appendix 5)
Waterbores TWB 1 2 6 and 9 which are located on TRAINOR in the southeast of the sub-
basin all had organic matter with TAI values of 3+ from the McFadden Skates Hills Cornelia
and Brassey Range Formations respectively
24
100
200
300
400
500
600
700
Oil
gene
ratin
g
Gas
gene
ratin
g
Fai
r
Fai
r
Poo
r
Poo
r
Goo
d
Imm
atur
e
Oil
win
dow
Oil
win
dow
Imm
atur
e
01 0110 10 0 150 300 440 480 1
Neo
prot
eroz
oic
TOC S1+S2 mgg Hydrogen Index Tmax degC
Depth(m)
Organicrichness
Generatingpotential
Kerogentype Maturity Maturity
TD=701m
Sandstone
Mudstone
Dolomite
Limestone
Evaporite
Source rock
MKS40 070498
Ro equivalent
Figure 9 Petroleum source potential of rocks in Normandy LDDH1
Small amounts of organic matter associated with basalt and dolerite in cuttings from
waterbore BWB 1 on BULLEN showed high levels of thermal maturity (Grey 1995a Libby 1995)
It is unclear whether all sedimentary rocks on BULLEN are overmature for hydrocarbon generation
or the results from BWB 1 are related to local heating events associated with the volcanic bodies
that are common in the Jilyili Formation
25
Reservoirs
Each of the five depositional sequences of the Savory Group (Table 1) are inferred to contain
significant sandstone reservoirs with the possible exception of depositional sequence C as
discussed above in Stratigraphy The Spearhole Formation was cored in Mundadjini 1 and
Boondawari 1 and visual estimates of porosity vary from generally poor (less than 5) to fair
(approximately 5ndash15) The McFadden Formation in Trainor 1 has porosity values of up to 232
and a maximum permeability of 195 md (Stevens and Adamides in prep) Sandstones from
Neoproterozoic formations form the acquifers in the following waterbores the McFadden
Formation in TWB 1 the Cornelia Formation in TWB 6 and the Brassey Range Formation in
TWB 8 and TWB 9 (Appendix 6 Table 61)
Based on outcrop observations the Durba Sandstone is considered to be the best reservoir of
the Savory Group Similarly some sandstones from the Tarcunyah Group also have good visible
porosity in outcrop
Dolomites occur in several formations in the sub-basin Reservoir potential may exist
particularly where the dolomites are stromatolitic and oolitic However dolomites have not been
drilled in the sub-basin and porosity can only be inferred from the preferential silicification of
some stromatolite bioherms observed in outcrop (Stevens and Grey 1997) Elsewhere in the
Officer Basin porosities of up to10 have been measured in dolomites A limestone breccia
(karst) is described from 663 to 677 m in drillhole LDDH1 (Fig 6 Busbridge 1994)
Seals
Indications of evaporitic environments in the Mundadjini Skates Hills and Boondawari
Formations are described by Williams (1992) In Mundadjini 1 from 287 to 337 m anhydrite and
chert occurs as nodules beds and veins in mudstone of the Mundadjini Formation Evaporitic
minerals (predominantly gypsum) are described in the Tarcunyah Group in LDDH1 The presence
of the Woolnough and Madley salt diapirs in the Officer Basin (approximately 110 km east of the
sub-basin) and halite beds over 25 m thick in the well Hussar 1 (130 km east of the sub-basin)
provide further evidence that evaporite seals may be present in the Savory Sub-basin
Mudstones and shales form only a small proportion of the limited Neoproterozoic outcrop in
the sub-basin but significant thicknesses of mudstone were encountered in the Mundadjini
Formation in Mundadjini 1 and Boondawari 1 the Tarcunyah Group in LDDH1 and in the
26
Cornelia Formation in Trainor 1 These data suggest that mudstones form a significant proportion
of strata in the sub-basin despite their limited outcrop
Traps
Potential structural closures including folds and faults occur at various scales throughout the
Savory Sub-basin However the region has only been mapped at 1250 000 scale and
independently closed structures such as domes have yet to be confirmed The western margin of
the basin contains abundant faults (with a northeast strike) but elsewhere faults are less common
Some anticlines are recognized in outcrop including one with a strike length of up to 45 km
inferred from surface bedding dips in the Mundadjini and Spearhole Formations at approximately
24deg15rsquoS 121deg10rsquoE on BULLEN (Fig 1)
Salt diapirs and other halokinetic structures are recognized in outcrop well and seismic data
in the Officer Basin to the west of the Savory Sub-basin and it is probable that there are
significant thicknesses of evaporitic sedimentary rocks in the sub-basin The gravity field data
suggest there is good potential for salt diapirs and traps related to halokinesis
Although there is potential for stratigraphic traps to be present in the sub-basin insufficient
data are available to assess them
Preservation of hydrocarbons
The range of thermal maturities measured to date and the large periods of time envisaged for
deposition of sediments implies hydrocarbon generation may have occurred a number of times
during the evolution of the Savory Sub-basin Any hydrocarbons that were generated early may
have been trapped in palaeostructures and remigration to younger traps could have taken place
later The Petermann Ranges Orogeny which has been equated with the Paterson Orogeny (Myers
1990) is believed to have occurred in the latest Neoproterozoic to early Cambrian This is the last
major tectonic event recognized in the sub-basin suggesting that it is reasonable to expect that trap
integrity will have been preserved
If the inference of the presence of thick halite beds in the sub-basin is correct the preservation
potential of sub-salt traps should be excellent
27
Reported hydrocarbon shows and oil seep
Amadeus Petroleum recorded minor oil shows in cores from Mundadjini 1 and Boondawari 1 In
Mundadjini 1 at 36102 m (top of the Spearhole Formation) a 3 mm thick zone had 10 moderate
white fluorescence with slow solvent cut This show was in a granular sandstone with visually
estimated porosity of about 10 In Boondawari 1 at 35364 m (within the Spearhole Formation) a
broken surface of sandstone had 40 moderate yellow-white fluorescence with slow solvent cut
Visually estimated porosity is about 5 Because the fluorescing surface was broken during the
drilling process this show could have resulted from contamination A second show occurs in
Boondawari 1 at 4963 m (within the Spearhole Formation) where a 1 cm-thick zone had 5 dull
yellow fluorescence with slow solvent cut in a conglomerate with visually estimated porosity of
about 10 The company intends to further investigate the nature of these occurrences
Minor bitumen is present at 6623 m in drillhole LDDH1 on GUNANYA (Figs 5 and 6) as a
vein in mudstones of the Tarcunyah Group A sample was analysed by gas chromatography
(Ghori in prep) and confirmed that it is natural bitumen (Appendix 5)
Mineral hole OD 23 drilled by Jubilee Gold Mines NL on NABBERU in the Bangemall Basin
immediately to the south of the Savory Sub-basin (Fig 5) encountered bitumen and trace oil in
vugs in dolomite (M Stevens unpublished data) but no further data are available at present
In their popular guide to the Canning Stock Route Gard and Gard (1990 p 218) refer to an
oil seep at Well 13 on TRAINOR (Fig 5) They reported that between 1977 and 1984 lsquonatural oilrsquo
was seen in the well Although the well is now largely filled with sediment four auger drill
samples were collected by the GSWA in 1995 and all four were analysed for oil shows One
sample from 315 m total depth (GSWA sample 135604) yielded just enough extract (519 ppm)
for saturate gas chromatography analysis The gas chromatograph (Appendix 5) shows that the
extract does contain some hydrocarbons probably from recent plant material Because the depth to
the oil was not quoted in Gard and Gard (1990) the hand-augered well may not have been deep
enough to properly test this reported seep
Geological and geophysical databases
Geological and geophysical data available for the Savory Sub-basin are limited The most recently
completed geological maps for the sub-basin were published by the GSWA between 1991 and
1995 (Williams and Tyler 1991 Williams 1992 1995ab)
28
The cores from the five drillholes listed in Table 2 believed to be all of the core available
from the sub-basin are available for inspection at GSWA Mineral exploration reports submitted
to GSWA may be searched using the WAMEX database and open-file reports are available on
microfiche Geophysical data acquired by the mining industry is not required to be filed with
GSWA if acquired over Vacant Crown Land which is the case for much of the sub-basin
Geophysical survey data submitted in mining tenement reports and which extend into Vacant
Crown Land remain confidential to the companies Original regional aeromagnetic and gravity
datasets are available from the Australian Geological Survey Organisation (AGSO)
Data pertinent to oil exploration in the sub-basin such as structural style and salt diapirism
are presented in a review of the hydrocarbon prospectivity of the Officer Basin (Perincek 1998)
Drilling
Significant drillholes in the sub-basin are summarized in Table 2
Petroleum industry data
Amadeus Petroleum drilled three petroleum exploration wells in the central west of the Savory
Sub-basin in late 1997 These wells Mundadjini 1 Boondawari 1 and Akubra 1 were drilled by
continuous diamond coring (Figs 5 and 6) All targeted potential reservoirs within the Spearhole
Formation with the Mundadjini Formation as the proposed seal The wells were located on
structures interpreted from Landsat images and limited geological investigations Both Mundadjini
1 and Boondawari 1 had minor oil shows as discussed above (Reported hydrocarbon shows)
Government data
Stratigraphic drillhole Trainor 1 was drilled by GSWA in 1995 (Stevens and Adamides in prep)
and the main results are discussed above (Source rocks and Maturity)
Mineral industry data
Normandy Exploration drillhole LDDH1 was cored in the Tarcunyah Group to a total depth of
701 m and provided source-rock and maturity data as discussed above
29
Oilmin NL drilled six percussion drillholes (BD 1 3 4 5 8 and 9) through sandstones and
shales in the northern part of the Savory Sub-basin to a maximum depth of 198 m (Fig 5
WAMEX Microfiche File M 26811 I 2610) but only brief geological descriptions are available
Hydrogeological data
Hydrogeological data within the Savory Sub-basin are limited although a long history of water
exploration extends back to the construction of the Canning Stock Route early this century No
detailed geological or wireline logs are available for the older wells along this route A few station
wells have been drilled by various methods on the south and west margins of the basin but data
are unavailable as reports are not required to be filed with the government Depth to watertable
throughout the basin is largely controlled by porosity of the bedrock
The GSWA drilled fifteen waterbores in the winter of 1995 in the southern part of the sub-
basin in preparation for the drilling of Trainor 1 and the proposed Bullen 1 Twelve bores found
water and six of these bores have salinities of less than 1000 mgL (Fig 5 Appendix 6 Table 61)
One waterbore TWB 6 has gamma ray and neutron logs run through PVC casing and these are
available from the GSWA with the digital log data included herein
Seismic data
No geophysical data have been acquired by the petroleum industry in the Savory Sub-basin
Seismic data acquired in the Officer Basin to the east particularly in the Gibson and Yowalga
Sub-basins is pertinent to structural interpretation in the Savory Sub-basin (Perincek 1996a
1998)
Aeromagnetic surveys
Government data
There are over 95 277 line kilometres of aeromagnetic data included in the AGSO dataset There
are three regional aeromagnetic surveys covering the Savory Sub-basin These were flown by the
Bureau of Mineral Resources (BMR now AGSO) in 1984 at a line spacing of 1500 m with 36 740
and 52 587 line kilometres flown and by Aerodata in 1984 at a line spacing of 1000m with 5950
line kilometres flown These data were reprocessed and interpreted for GSWA by Cowan (1995)
An edited copy of this report is included as Appendix 4 and the original report is filed in the
GSWA Library under S-series reports item 10331
30
Mineral industry data
The approximate locations of non-AGSO aeromagnetic surveys are shown in Figure 8 More
detailed information regarding the location of these surveys may be obtained using the GSWA
MAGCAT II database Additional information such as contours of aeromagnetic values may be
obtained by inspecting items on file with the GSWA
Gravity surveys
Government data
The average spacing for gravity data in the Savory Sub-basin is one station per 121 km2 (11 times 11
km grid) These data were principally collected by BMR in the early 1960s There are a few
additional regional gravity traverses across the sub-basin which are also included in the
BMRAGSO dataset These data were reprocessed and interpreted for GSWA (Fig 10) and a
report on this work is also included in Appendix 4
The GSWA completed a large semi-detailed gravity survey in the eastern Savory Sub-basin
utilizing helicopter support and Differential Global Positioning Survey (DGPS) techniques (Fig
8) This gravity survey completed in August 1995 consists of 2300 gravity stations on a 2 times 3 km
grid All stations were acquired by helicopter using Scintrex gravimeters and Ashtek dual
frequency DGPS equipment for determining location This highly efficient system allowed the
acquisition of more than 100 gravity stations per day in remote areas The resolution of this survey
is +30 cm and +05 microms-2 (Daishsat 1995) These data (Fig 11) represent a significant
improvement on the previous regional survey data and are available from GSWA (GSWA
1996ab) The results of the interpretation of these data were presented at the 1997 ASEG
Convention (Carlsen and Shevchenko 1997)
Mineral industry data
Three small gravity surveys were conducted by Oilmin NL (Fig 8) and the relevant WAMEX
reports are M 2681I 2610 I 2435 I 2567 These three surveys are of limited value because height
control was provided by barometers only and the surveys were not tied to the national gravity grid
31
23deg
25deg
120deg 122deg
Trainor 1
SAVORY
SUB-BASIN
MKS54 160498
100 km
1995 SavoryGravity Survey
254
-1056
micromsec2
Figure 10 Regional Bouguer gravity map of the Savory Sub-basin
23deg
24deg
25deg
122deg30 123deg
TRAINOR 1
123deg30
50 km
MKS53 160498
-116
-626
micro msec2
Figure11 Detailed Bouguer gravity map of the
Savory 1995 Gravity Survey from the eastern Savory Sub-basin
32
Government and academic reports
Chronostratigraphy and geochemistry
The understanding of Neoproterozoic organic chemistry palynology and structural evolution is
essential to the interpretation of hydrocarbon prospectivity Pertinent reports are included in the
bibliography (Appendix 1) Unpublished palaeontology reports describe the palynology of wells in
the Savory Sub-basin (Grey 1995andashe 1996a) Grey and Cotter (1996) discussed the potential for
Neoproterozoic palynomorphs to provide a biostratigraphic framework and palaeoenvironmental
interpretation Grey and Stevens (1997) reviewed the results of palynological studies of wells
drilled in the sub-basin and reported that Supersequence 1 palynomorphs are present in TWB 6
TWB 9 and LDDH1 (Appendix 3) Grey (1996b) reported on the use of stromatolites for
correlation in the Neoproterozoic and Stevens and Grey (1997) discussed the application of
stromatolite biostratigraphy in correlating isolated dolomite outcrops in the sub-basin with well
and seismic data in the Officer Basin and Centralian Superbasin
Although geochemical data from the Savory Sub-basin are very limited results mostly
confirm thermal maturities inferred from TAI for LDDH1 and Trainor 1 (Ghori in prep Stevens
and Adamides in prep) Those parts of the Officer Basin in Western Australia which lie to the
east of the Savory Sub-basin are sparsely drilled but Ghori (in prep) reports that most of the
Neoproterozoic succession presently lies within the oil-generative window However his study
has been unable to identify effective source-rock units and the source for oil shows Thin source
rocks are present in the Neoproterozoic in LDDH1 (Fig 9) and in three wells which lie to the east
and southeast of the Savory Sub-basin namely NJD 1 Kanpa 1A and Yowalga 3
Proposed work program
From the above limited information it is concluded that additional research on the hydrocarbon
potential of the sub-basin is justified and proposals are outlined below
bull Additional modelling of gravity and aeromagnetic data from the Savory Sub-basin is required
in light of the results from Trainor 1 and Boondawari 1 Trainor 1 showed that what appeared
to be a structurally simple area based on outcrop aeromagnetic and gravity data was in fact an
area of major structuring Boondawari 1 intersected a dolerite which is in good depth
agreement with aeromagnetic depth to source results showing this technique is useful in
detecting the depth to intrusive bodies
33
bull Additional data from mineral and petroleum exploration bores may become available and
analysis of samples from these wells should be undertaken and interpreted in the context of
their relevance to the Officer Basin
bull Stratigraphic coring in the Blake Fault and Fold Belt and in the Wells Foreland Sub-basin (Fig
1) targeting source rocks is considered essential to the continuing evaluation of the
hydrocarbon prospectivity of the Savory Sub-basin
bull Correlations using at least outcrop well and potential-field data should be prepared to link the
sub-basin with the better known parts of the Officer Basin to the east
bull Remapping is required to clarify boundary positions within the Cornelia Formation this may
resolve some of the current problems of the relationship between this unit and the rest of the
Savory Sub-basin
bull Further work is required to explain the Early Cambrian or Sturtian ages interpreted for the
Cornelia Formation from sedimentary zircon UndashPb dating in drillhole Trainor 1 The
determination of the age of the organically rich but overmature claystones in this well is
critical to assessing the hydrocarbon potential of the region
bull The thin dark mudstones intersected by Akubra 1 in the Mundadjini Formation warrant
geochemical analysis Analyses of the oil shows in Mundadjini 1 and Boondawari 1 are
currently being undertaken by Amadeus Petroleum
bull Geochemical analysis of hydrocarbons in the Bangemall Basin drillhole OD23 has been
performed by Jubilee Gold and the results will be reviewed when they are submitted to
GSWA The possibility of source rocks within the Bangemall Basin charging traps within the
Bangemall Basin and the overlying Savory Sub-basin requires further investigation
Conclusions
The Savory Sub-basin is a frontier region with only three recently drilled petroleum exploration
wells and no seismic data Based on existing geological and geophysical data it is considered too
early to draw conclusions about the hydrocarbon prospectivity of the sub-basin at this stage and
there are several reasons why the area warrants further investigation
34
1 Thick accumulations of sedimentary rocks are present (up to 8 km thickness inferred) which
may contain source reservoir and sealing strata
2 Minor oil shows occur in Mundadjini 1 and Boondawari 1 and bitumen is present in mineral
exploration drillhole LDDH1 suggesting that hydrocarbons have migrated within the
Neoproterozoic sequence of the Savory Sub-basin Oil and bitumen are present in mineral
exploration drillhole OD23 in the Bangemall Basin immediately to the south of the Savory
Sub-basin and it is possible that source rocks from the Bangemall Basin could charge traps in
the overlying Savory Sub-basin
3 The age of sedimentary rocks in the sub-basin is still poorly constrained but some of the
Neoproterozoic sedimentary rocks located on GUNANYA and TRAINOR are within the
hydrocarbon-generation window It is possible that a significant thickness of Phanerozoic
sedimentary rocks may also be present
4 Friable sandstones with visible porosity outcrop extensively suggesting numerous potential
reservoirs
5 Significant but not intense faulting and folding has been mapped implying large structural
traps may be present
6 Evaporitic sedimentary rocks occur in several formations and may provide good source rocks
and excellent seals
35
References
APAK S N and CARLSEN G M 1997 A compilation and review of data pertaining to the
hydrocarbon prospectivity of the Canning Basin Western Australia Geological Survey
Record 199610 103p
BAGAS L GREY K and WILLIAMS I R 1995 Reappraisal of the Paterson Orogen and
Savory Basin Western Australia Geological Survey Annual Review 1994ndash95 p 55ndash63
BUSBRIDGE M 1994 Lake Disappointment Exploration Licence 451064 Third Annual
Report Lake Disappointment Diamond Drill Hole LDDH1 Normandy Exploration Limited
Western Australia Geological Survey M-series Item 7567 A41358 (unpublished)
CARLSEN G M and SHEVCHENKO S I 1997 Petroleum exploration in Proterozoic basins
using potential fields data and stratigraphic coring Australian Society of Exploration
Geophysicists 12th Geophysical Conference Handbook Sydney 1997 Preview no 66 p 83
(abstract only)
COWAN D 1995 Savory Basin quantitative magnetic interpretation Western Australia
Geological Survey S-series S10331 (unpublished)
DAISHSAT PTY LTD 1995 Operational and processing report Savory Basin gravity survey
Western Australia Geological Survey S-series S10332 (unpublished)
GARD E and GARD R 1990 Canning Stock Route a travellerrsquos guide for a journey through
history Perth Western Australia Western Desert Guides 448p
GEOLOGICAL SURVEY OF WESTERN AUSTRALIA 1996a Savory Basin first vertical
derivative of Bouguer gravity image 1250 000 Western Australia Geological Survey
GEOLOGICAL SURVEY OF WESTERN AUSTRALIA 1996b Savory Basin Bouguer gravity
image 1250 000 Western Australia Geological Survey
GHORI K A R in prep Petroleum source rock potential and thermal history Officer Basin
Western Australia Western Australia Geological Survey Record
36
GREY K 1995a Savory Basin drillhole BWB 1 (Bullen waterbore) palynology and thermal
maturation GSWA Palaeontology Report no 199512 (unpublished)
GREY K 1995b Savory Basin drillholes TWB 1 2 6 9 (Trainor waterbores) palynology and
thermal maturation GSWA Palaeontology Report no 199520 (unpublished)
GREY K 1995c Palynology of Normandy-Poseidon Lake Disappointment-1 corehole
Tarcunyah Group Paterson Orogen GSWA Palaeontology Report no 199521 (unpublished)
GREY K 1995d Savory Basin drillhole Trainor 1 (Trainor diamond drilling) palynology and
thermal maturity GSWA Palaeontology Report no 199524 (unpublished)
GREY K 1995e Savory Basin drillhole Trainor 1 (Trainor diamond drilling) Additional
Preparation of two samples GSWA Palaeontology Report no 199528 (unpublished)
GREY K 1995f Neoproterozoic stromatolites from the Skates Hills Formation Savory Basin
Western Australia and a review of the distribution of Acaciella australica Australian Journal
of Earth Sciences v 42 p 123ndash132
GREY K 1996a Savory Basin drillhole Trainor 1 (Trainor diamond drilling) Additional
samples palynology and thermal maturation GSWA Palaeontology Report no 199615
(unpublished)
GREY K 1996b Preliminary stromatolite correlations for the Neoproterozoic of the Officer
Basin and a review of Australia-wide correlations GSWA Palaeontology Report no 199615
(unpublished)
GREY K and COTTER K L 1996 Palynology in the search for Proterozoic hydrocarbons
Western Australia Geological Survey Annual Review for 1995ndash96 p 70ndash80
GREY K and STEVENS M K 1997 Neoproterozoic palynomorphs of the Savory Sub-basin
Western Australia and their relevance to petroleum exploration Western Australia
Geological Survey Annual Review for 1996ndash97 p 49ndash54
HUBBARD R J PAPE J and ROBERTS D G 1985 Depositional sequence mapping as a
technique to establish tectonic and stratigraphic framework and evaluate hydrocarbon
potential on a passive continental margin in Seismic stratigraphy II an integrated approach
37
edited by O R BERG and D G WOOLVERTON American Association of Petroleum
Geologists Memoir 39 p 79ndash91
LIBBY WG 1995 A petrological report on six samples of bore cuttings from the Savory Basin
Western Australia Western Australia Geological Survey S-series S31307 (unpublished)
MORTON JGG and DREXEL JF 1997 The petroleum geology of South Australia Vol 3
Officer Basin South Australia Department of Mines and Energy Resources Report Book
9719
MUHLING P C and BRAKEL A T 1985 Geology of the Bangemall Group mdash the evolution
of an intracratonic Proterozoic basin Western Australia Geological Survey Bulletin 128
219p
MYERS J S 1990 Precambrian tectonic evolution of part of Gondwana southwestern Australia
Geology v18 p 537ndash540
NELSON D R 1997 Compilation of SHRIMP UndashPb zircon data Western Australia Geological
Survey Record 19972 196p
PAYTON C E 1977 Seismic stratigraphy mdash applications to hydrocarbon exploration
American Association of Petroleum Geologists Memoir 26 516p
PERINCEK D 1996a The age of NeoproterozoicndashPalaeozoic sediments within the Officer Basin
of the Centralian Super-basin can be constrained by major sequence-bounding unconformities
APPEA Journal v 36 pt 1 p 350ndash368
PERINCEK D 1996b The stratigraphic and structural development of the Officer Basin
Western Australia a review Western Australia Geological Survey Annual Review 1995ndash
1996 p 135ndash148
PERINCEK D 1998 A compilation and review of data pertaining to the hydrocarbon
prospectivity of the Officer Basin Western Australia Geological Survey Record 19976
POSAMENTIER H W JERSEY M T and VAIL P R 1988 Eustatic controls on clastic
deposition 1 mdash Conceptual framework in Sea-level changes an integrated approach edited by
C K WILGUS B S HASTINGS C G St C KENDALL H W POSAMENTIER
38
C A ROSS and J C VAN WAGONER Society of Economic Paleontologists and
Mineralogists Special Publication no 42
STEVENS M K and ADAMIDES N G in prep GSWA Trainor 1 well completion report
Savory Sub-basin Officer Basin Western Australia with notes on petroleum and mineral
potential Western Australia Geological Survey Record 199612
STEVENS M K and GREY K 1997 Skates Hills Formation and Tarcunyah Group Officer
Basin mdash carbonate cycles stratigraphic position and hydrocarbon prospectivity Western
Australia Geological Survey Annual Review for 1996ndash97 p 55ndash60
SUMMONS RE and POWELL C McA 1991 Petroleum source rocks of the Amadeus Basin
in Geological and geophysical studies in the Amadeus Basin central Australia edited by R J
KORSCH and JM KENNARD Australia BMR Geology and Geophysics Bulletin 236
TRAVERSE A 1988 Palaeopalynology Boston Unwin Hyman 600p
VAIL P R MITCHUM R M Jr TODD R G WIDMIER J M THOMPSON S III
SANGREE J B BUBB J N and HATLELID W G 1977 Seismic stratigraphy and
global changes of sea level in Seismic stratigraphy mdash applications to hydrocarbon
exploration edited by C E PAYTON American Association of Petroleum Geologists
Memoir 26 516p
WALTER M R and GORTER J 1994 The Neoproterozoic Centralian Superbasin in Western
Australia the Savory and Officer Basins in The sedimentary basins of Western Australia
edited by P G PURCELL and R R PURCELL Petroleum Exploration Society of Australia
Symposium Perth WA 1994 Proceedings p851ndash864
WALTER M R GREY K WILLIAMS I R and CALVER C R 1994 Stratigraphy of the
Neoproterozoic to early Palaeozoic Savory Basin and correlation with the Amadeus and
Officer Basins Australian Journal of Earth Sciences v 41 p 533ndash546
WALTER M R VEEVERS J J CALVER C R and GREY K 1995 Neoproterozoic
stratigraphy of the Centralian Superbasin Australia Precambrian Research v 73 p 173ndash195
WILLIAMS I R 1992 Geology of the Savory Basin Western Australia Western Australia
Geological Survey Bulletin 141 115p
39
WILLIAMS I R 1995a Bullen WA (2nd Edition) Western Australia Geological Survey
1250 000 Geological Series Explanatory Notes 23p
WILLIAMS I R 1995b Trainor WA (2nd Edition) Western Australia Geological Survey
1250 000 Geological Series Explanatory Notes 31p
WILLIAMS I R and TYLER I M 1991 Robertson WA (2nd edition) Western Australia
Geological Survey 1250 000 Geological Series Explanatory Notes 36p
40
41
Appendix 1
Bibliography
Reports which are relevant to this investigation but which are not specifically cited are listed
below
BAILLIE P W POWELL C McA LI Z X and RYALL A M 1994 The tectonic
framework of Western Australiarsquos Neoproterozoic to recent sedimentary basins in The
sedimentary basins of Western Australia edited by P G PURCELL and R R PURCELL
Petroleum Exploration Society of Australia Symposium Perth WA 1994 Proceedings p
45ndash62
BRADSHAW M T BRADSHAW J MURRAY A P NEEDHAM D J SPENCER L
SUMMONS R E WILMOT J and WINN S 1994 Petroleum systems in West Australian
basins in The sedimentary basins of Western Australia edited by P G PURCELL and R R
PURCELL Petroleum Exploration Society of Australia Symposium Perth WA 1994
Proceedings p 93ndash118
CLARKE G L 1991 Proterozoic tectonic reworking in the Rudall Complex Western Australia
Australian Journal of Earth Science v38 p 31ndash44
COCKBAIN A E and HOCKING R M 1990 Phanerozoic in Geology and mineral resources
of Western Australia Western Australia Geological Survey Memoir 3 p 750ndash755
ETHERIDGE M and WALL V 1994 Tectonic and structural evolution of the Australian
Proterozoic 12th Australian Geological Convention Geological Society of Australia
Abstracts no 37 p 102ndash103
GOODE A D T 1981 Proterozoic geology of Western Australia in Precambrian of the
Southern Hemisphere Developments in Precambrian geology 2 edited by I R HUNTER
Amsterdam Elsevier p 105ndash203
GREY K and JACKSON M J 1983 A re-assessment of stromatolite evidence for the
correlation of the Late Proterozoic Neale and Ilma Beds Officer Basin Western Australia
Australia BMR Journal of Australian Geology and Geophysics v 8 p 359
42
HICKMAN A H WILLIAMS I R and BAGAS L 1994 Proterozoic geology and
mineralization of the TelferndashRudall region Paterson Orogen Geological Society of Australia
(WA Division) Excursion Guidebook no 5 56p
HOCKING R M MORY A J and WILLIAMS I R 1994 An atlas of Neoproterozoic and
Phanerozoic basins of Western Australia in The sedimentary basins of Western Australia
edited by P G PURCELL and R R PURCELL Petroleum Exploration Society of Australia
Symposium Perth WA 1994 Proceedings p 21ndash 44
JACKSON P R 1966 Geology and review of exploration Officer Basin Western Australia
Hunt Oil Company Western Australia Geological Survey S-series S26 (unpublished)
JACKSON M J 1971 Notes on a geological reconnaissance of the Officer Basin Western
Australia Australia BMR Geology and Geophysics Record 19715 30p
JACKSON M J and van de GRAAFF W J E 1981 Geology of the Officer Basin Western
Australia Australia BMR Geology and Geophysics Bulletin 206 102 p
LOWRY D C JACKSON M J van de GRAAFF W J E and KENNEWELL P J 1971
Preliminary result of geological mapping in the Officer Basin Western Australia Western
Australia Geological Survey Annual Report for 1971 p 50ndash56
MYERS J S 1990 Precambrian in Geology and mineral resources of Western Australia
Western Australia Geological Survey Memoir 3 p 737ndash750
MYERS J S SHAW R D and TYLER I M 1994 Proterozoic tectonic evolution of
Australia 12th Australian Geological Convention Geological Society of Australia Abstracts
no 37 p 312
NEDIN C and JENKINS R J F 1991 Re-evaluation of unconformities separating the
lsquoEdiacaranrsquo and Cambrian systems South Australia Palaios v 6 p 102ndash108
PHILLIPS B J JAMES A W and PHILIP G M 1985 The geology and hydrocarbon
potential of the north-western Officer Basin APEA Journal 25 (1) p 52ndash61
POWELL C McA LI Z X McELHINNY M W MEERT J G and PARK J K 1993
Paleomagnetic constraints on timing of the Neoproterozoic breakup of Rodinia and Cambrian
formation of Gondwana Geology v 21 p 889ndash892
43
POWELL C McA PREISS W V GATEHOUSE C G KRAPEZ B and LI Z X 1994
South Australian record of a Rodinian epicontinental basin and its mid-Neoproterozoic
breakup to form the Palaeo-Pacific Ocean Tectonophysics v 237 no 3ndash4 p 113ndash140
PREISS W V 1976 Proterozoic stromatolites from the Nabberu and Officer Basins Western
Australia and their biostratigraphic significance South Australia Geological Survey Report
of Investigations no 47 p 1ndash51
TOWNSON W G 1985 The subsurface geology of the western Officer Basin mdash results of
Shellrsquos 1980ndash1984 petroleum exploration campaign APEA Journal v 25 (1) p 34ndash51
WATTS K J 1982 The geology of the Townsend Quartzite Upper Proterozoic shallow water
deposit of the Northern Officer Basin Western Australia Perth University of Western
Australia BSc honours thesis (unpublished)
WELLS A T and KENNEWELL P J 1974 Evaporite exploration in the Officer Basin
Western Australia at the Madley Diapirs Australia BMR Record 1974194 (unpublished)
WILLIAMS I R and MYERS J S 1990 Paterson Orogen in Geology and mineral resources
of Western Australia Western Australia Geological Survey Memoir 3 p 274ndash286
WILLIAMS I R 1990 Savory Basin in Geology and mineral resources of Western Australia
Western Australia Geological Survey Memoir 3 p 329ndash334
WILLIAMS I R 1994 The Neoproterozoic Savory Basin Western Australia in The
sedimentary basins of Western Australia edited by P G PURCELL and R R PURCELL
Petroleum Exploration Society of Australia Symposium Perth WA 1994 Proceedings p
841ndash850
WILSON R B 1967 Woolnough Hills and Madley diapiric structures Gibson Desert WA
APEA Journal v 7 p 94ndash102
44
Appendix 2
Meteorological data (from Bureau of Meteorology Perth 1994)
Table 21 Wiluna rainfall (mm)
Year Jan Feb Mar Apr May Jun Jul Aug Sept Oct Nov Dec
1975 0 45 446 309 306 59 276 4 34 886 638 164 1976 16 154 12 138 53 16 34 62 12 238 0 2 1977 44 0 66 74 68 95 24 363 1 58 12 727 1978 234 522 94 16 0 96 367 24 16 353 185 45 1979 19 173 122 88 91 4 0 246 58 0 169 114 1980 148 764 68 1081 259 626 629 06 56 02 174 0 1981 123 476 192 32 196 118 44 74 14 0 28 312 1982 374 705 206 244 1079 92 02 143 368 526 368 118 1983 1 112 928 248 0 212 56 32 5 1 42 496 1984 149 7 342 84 836 0 348 132 224 04 16 172 1985 596 483 0 166 556 0 514 56 0 0 4 0 1986 0 154 35 0 0 1085 23 01 239 137 0 04 1987 1204 119 19 89 17 575 154 126 07 1 0 398 1988 46 202 164 13 388 0 202 104 0 0 224 1309 1989 207 234 26 703 278 536 57 0 01 0 144 02 1990 1035 23 281 46 126 53 94 218 44 9 42 0 1991 48 0 41 45 0 472 297 12 0 1 0 7 1992 112 96 1025 1227 323 65 04 174 0 132 48 4 1993 0 697 0 202 445 0 12 306 18 05 14 33 Mean 25 35 22 27 27 25 18 12 6 13 13 21
JAN FEB MAR APR MAY JUN JUL AUG SEP OCT NOV DEC0
10
20
30
40
Mea
n R
ain
fall
(mm
)
Month
Mean monthly rainfall in Wiluna
MKS41 140498
45
Table 22 Wiluna minimum temperature (degC)
Year Jan Feb Mar Apr May Jun Jul Aug Sept Oct Nov Dec
1975 ndash 23 203 15 94 63 71 62 103 124 169 205 1976 242 229 194 15 10 63 59 73 95 143 16 228 1977 243 25 197 148 96 95 56 86 102 ndash 188 23 1978 241 232 203 18 102 64 76 8 9 152 19 205 1979 255 226 216 167 83 6 59 79 97 145 198 223 1980 255 226 231 155 134 83 68 75 121 108 193 223 1981 245 216 19 182 119 6 54 78 138 159 163 218 1982 232 224 177 16 ndash ndash 37 111 112 164 209 225 1983 235 24 197 147 112 88 39 88 121 162 189 219 1984 241 243 191 156 ndash 72 66 7 95 161 182 211 1985 244 231 ndash 159 98 65 71 73 117 147 205 ndash 1986 ndash 229 226 155 93 96 43 49 10 122 ndash 219 1987 ndash 217 183 175 85 77 68 68 112 ndash ndash 221 1988 238 214 209 178 111 ndash ndash 86 104 157 171 195 1989 ndash 237 199 165 107 67 44 61 107 131 187 ndash 1990 232 ndash 211 155 118 62 57 87 102 149 195 22 1991 26 256 217 168 122 101 78 ndash 113 18 168 219 1992 227 227 214 169 102 98 59 69 ndash 125 159 196 1993 241 218 196 171 103 ndash 49 68 88 128 192 211 Mean 24 23 20 16 10 8 6 8 11 14 18 21
NOTE Dashes indicate data unavailable
JAN FEB MAR APR MAY JUN JUL AUG SEP OCT NOV DEC0
10
20
30
40
Month
MKS43 140498
50
Mean monthly minimum temperatures at Wiluna
Mea
n T
emp
erat
ure
(degC
)
46
Table 23 Wiluna maximum temperature (degC)
Year Jan Feb Mar Apr May Jun Jul Aug Sept Oct Nov Dec
1975 ndash 349 326 281 247 201 197 212 256 248 31 344 1976 374 369 346 297 248 206 208 225 265 287 313 388 1977 397 392 352 296 234 212 222 244 ndash 308 337 383 1978 378 345 346 316 242 195 176 205 231 295 334 356 1979 403 36 364 295 ndash ndash ndash 193 242 318 359 373 1980 392 342 377 275 24 176 179 233 292 288 349 391 1981 385 346 337 342 242 178 201 224 30 326 326 369 1982 372 359 315 307 ndash ndash 196 253 252 305 353 379 1983 381 389 327 272 263 222 187 248 287 321 336 366 1984 378 393 322 299 226 215 178 214 234 ndash 336 364 1985 40 366 ndash 294 224 216 205 212 284 307 355 ndash 1986 ndash 383 372 307 ndash 193 166 196 261 277 ndash 382 1987 ndash 339 328 305 21 202 214 218 275 ndash ndash 374 1988 388 365 353 301 23 ndash ndash 228 283 334 31 33 1989 ndash 375 339 285 238 179 181 219 275 298 336 ndash 1990 368 ndash 36 309 268 19 188 205 274 309 373 393 1991 414 416 363 315 268 206 21 ndash 279 338 332 368 1992 363 383 336 263 213 178 213 197 ndash 285 313 359 1993 396 357 344 301 221 ndash 197 215 253 294 347 362 Mean 39 37 34 30 24 20 20 22 27 30 34 37 NOTE Dashes indicate data unavailable
JAN FEB MAR APR MAY JUN JUL AUG SEP OCT NOV DEC0
10
20
30
40
Month
MKS42 140498
50
Mean monthly maximum temperatures at Wiluna
Mea
n T
emp
erat
ure
(degC
)
47
Appendix 3
Table 31 Summary of palynological results
Drillhole Depth (m) F no(a) GSWA no Lithology Formation Assemblage TAI(b)
BWB 1 74ndash75 F49668 135741 dark-grey siltstone basalt Jilyilli gt5 BWB 1 98ndash100 F49669 135742 dark-grey siltstone basalt Jilyilli gt5 BWB 1 121ndash122 F49670 135743 dark-grey siltstone basalt Jilyilli gt5 TWB 1 86ndash87 F49671 135631 dark-grey siltstone McFadden 3+ TWB 1 104ndash105 F49672 135632 dark-grey siltstone Cornelia 3+ TWB 1 121ndash122 F49673 135633 dark-grey siltstone Cornelia 4 TWB 2 14ndash15 F49674 135634 dark-grey siltstone Skates Hills 3+ TWB 6 49ndash50 F49675 135675 dark-grey siltstone Cornelia 1 3+ TWB 9 49ndash51 F49676 135704 dark-grey siltstone Brassey Range 1 3+ Trainor 1 37497- F49733 138939 black mudstone with Cornelia 5 37509 light-grey siltstone Trainor 1 3809 F49734 138940 dark-grey and black Cornelia 4- laminated mudstone Trainor 1 4170 F49735 138941 black unlaminated mudstone Cornelia 4- Trainor 1 4950 F49851 139501 dark-grey indurated siltstone Cornelia 5 Trainor 1 6032 F49852 139502 dark- and light-grey Cornelia 5 indurated siltstone Trainor 1 6434 F49853 139503 greenish indurated finely Cornelia 5 laminated siltstone LDDH 1 270 F49678 138934 dark-grey siltstone interbeds Waters 1 3+ in enterolithic evaporite Tarcunyah Gp LDDH 1 277 F49679 138935 dark-grey siltstone in cavity Waters 1 3+ in enterolithic evaporite Tarcunyah Gp
NOTES (a) GSWA Fossil Catalogue number (b) TAI = Thermal Alteration Index of Traverse (1988 plate 1)
48
Appendix 4
Savory Sub-basin quantitative magnetic and gravity interpretation (extracted from Cowan 1995)
Summary
A program of quantitative aeromagnetic interpretation has been completed on BMRAGSO data from the Savory Sub-
basin Western Australia Quantitative aeromagnetic interpretation utilized the 3D Euler deconvolution method
supported by wavenumber filtering and image processing The results have provided useful information on structural
trends and depth to magnetic sources in a structurally complex area Depth to magnetic source analysis has provided
information on intra-sedimentary magnetic sources as well as basement rocks
The results of the interpretation support previously identified depocentres However the presence of magnetic
sources at several levels makes it very difficult to produce a reliable magnetic basement depth contour map It is
considered more productive to work with the 3D Euler colour circle plots and images rather than trying to contour the
results It would be necessary to carry out a full-scale interpretation of the BMRAGSO profile data to improve on the
3D Euler results The regional gravity was found to be useful in interpreting the regional setting of the area although
the very wide data spacing limits quantitative use of the data The gravity data show quite a complex picture with
limited consistent correlation between gravity features and basin structures This suggests that gravity anomalies
reflect changes in density of the basement rocks rather than basement topography especially in the northern part of the
basin
It is recommended that the GSWA investigate access to company confidential high-resolution aeromagnetic data
prior to planning further aeromagnetic surveys Private companies have flown large parts of the northern half of the
area as part of their diamond exploration program Additional gravity coverage of the area may be more cost effective
than magnetic surveys as the gravity data provides more information on changes within the sedimentary section
Introduction
The main use of aeromagnetic data in petroleum exploration has been the determination of magnetic basement
topography although there has been increasing interest in analysis of intra-sedimentary magnetic anomalies
intrabasement and suprabasement magnetic anomalies These anomalies are used to determine depth to magnetic
basement rocks and hence determine the thickness of the sedimentary sequence Unfortunately interpretation of the
intrabasement and suprabasement magnetic anomalies is non-unique in terms of position and size of causative sources
because of the inherent ambiguity of potential-field methods However this ambiguity can be reduced by placing
49
constraints on source geometry and magnetization and by using geological and other geophysical data to constrain
the solution
Before 1970 most depth-determination techniques involved graphical determination of slopes of selected
magnetic anomalies and application of various empirical factors to convert the slopes into depth estimates Geological
Society of America Memoir 47 Interpretation of Aeromagnetic Maps by Vacquier et al (1951) was a landmark for
this type of interpretation
Automated interpretation procedures have played an increasingly important role in depth interpretation and a
wide range of techniques have been developed Many of these techniques are designed for application to located data
profiles and assume a two-dimensional geometry However there has been renewed interest in techniques applicable
to gridded data
Two distinct types of method can be recognized In the first case often described as discrete methods individual
isolated magnetic anomalies are interpreted and the results used to produce a map of basement relief In the second
case often described as continuous methods areas of data containing a number of anomalies are interpreted
statistically to produce direct output of basement depths
The discrete methods usually involve a semiautomatic initial phase which generates a large number of possible
depth solutions and an interactive second phase to screen and select acceptable solutions The advantage of this
approach is that the interpreter can select features that are relatively free from interference from adjacent anomalies
and consider all aspects of a particular magnetic anomaly The disadvantage is that interpretation can be very time
consuming as a wide range of depths are usually possible depending on the initial model chosen and a significant
amount of effort is needed to select the correct model In the case of the Savory Sub-basin dataset we encountered
problems in separating basement related effects from the effects of shallower intrasedimentary magnetic sources
Because of these problems we have concentrated on displaying the Euler results accompanied by separation filter
images of the data to show the shallower effects and deeper effects rather than trying to refine a 3D Euler
deconvolution depth-to-crystalline-basement contour
The continuous methods are very direct provided that the rather restrictive assumption can be made that all
anomalies are due to lateral magnetization changes due to basement topography This means that shallow effects and
large intrabasement anomalies must be removed from the data This involves judgement and skill as it is necessary to
distinguish between the lower amplitude suprabasement anomalies due to basement topography and the larger
intrabasement anomalies reflecting magnetization changes within the basement These methods were not considered
suitable for the Savory Sub-basin magnetic dataset but were used to invert the gravity data
50
Limitations of magnetic and gravity interpretation
Interpretation of the area is limited by a shortage of information on the nature and physical properties of the deeper
sedimentary sequence and the underlying basement rocks However using techniques such as cross-correlation of
gravity and pseudo-gravity data it is possible to try to differentiate between anomalies relating to basement and those
related to the sedimentary sequence
Gravity anomalies reflect changes within the sedimentary sequence as well as basement condition These
changes in density of sedimentary rocks produce gravity anomalies without a corresponding magnetic anomaly hence
the complementary nature of gravity and magnetic surveys The main use of magnetics is to determine depth to
magnetic basement and any intra-sedimentary volcanic rocks or intrusives whereas gravity provides much more
general information on the sedimentary sequence
Unfortunately interpretation of gravity anomalies is complicated since they can be due to a number of geological
features including
bull major basement faults
bull basement highs
bull igneous intrusions within the basement
bull sedimentary basins which may or may not be isostatically compensated
bull intra-sedimentary volcanics and associated plutonic centres
Two major problems affect the interpretation of both magnetic and gravity data
1 The inherent ambiguity of potential-field data There is no unique solution to any measured gravity or magnetic
anomaly and theoretically there will be an infinite number of source geometry and magnetizationdensity
combinations which will fit the observed data This means that any a priori information which helps to select a
suitable model is very useful
2 Measured anomalies are the summation of effects from different depths For example an observed gravity profile
may contain contributions from shallow sources (density variations within the sedimentary basin) intermediate
depth sources (density variations due to large igneous intrusions within the basement) and deep sources (crustal
thinning producing a mantle anomaly) Separation of these component responses is the regionalresidual problem
which we solve using spectral analysis and differential upward continuation-based separation filtering
Regional setting and interpretation overview
The area studied includes parts of BALFOUR DOWNS (SF51-9) RUDALL (SF51-10) ROBERTSON (SF51-13) GUNANYA
(SF51-14) COLLIER (SG50-4) BULLEN (SG51-1) TRAINOR (SG51-2) MADLEY (SG51-3) NABBERU (SG50-5)
STANLEY (SG51-6) and HERBERT (SG51-7) 1250 000 sheets Broadly the area lies between latitudes 22deg00rsquondash25deg30rsquoS
and longitudes 119deg30rsquondash123deg30rsquoE
51
Regional gravity
The AGSO regional gravity data (at nominal 11 km spacing) was gridded at a 4 km mesh spacing using a minimum-
curvature algorithm Bouguer gravity values in the area are negative reflecting mass deficiency at depth and range
from -84 mgals to -25 mgals
A Bouguer gravity colour image is shown as Figure 41 A residual grid was produced by removing a fifth-order
orthogonal polynomial from the Bouguer data but did not add to the interpretation
120deg 121deg 122deg 123deg
23deg
24deg
25deg
-25
-84
50 km
MKS46 180598
mgal
Figure 41 Regional Bouguer gravity (BMRAGSO data) gridded at 4 km
52
The data show a complex pattern of positive and negative anomalies with no clearly defined trends Correlations
with aeromagnetic data and known basin structures are poor A vague north-northwest linear trend appears to coincide
with the Marloo Fault (Figure 42) A prominent negative anomaly appears to coincide with the Blake Fold and Fault
Belt depocentre and continues as a narrower negative anomaly to the east until it widens out again near the edge of the
basin Elsewhere the gravity data show little correlation with known basin structures and it is likely that especially in
the north of the area gravity anomalies are due to density changes in the basement rather than changes in basement
topography
Production of wavelength-filtered residual gravity plots and vertical gradient plots showed very patchy aliased
data reflecting poor sampling in much of the area
Regional magnetics
The AGSO regional aeromagnetic data were gridded at a 400 m mesh spacing using a minimum-curvature algorithm
(Figure 43) Most of the data has a line spacing of 1600 m with small areas of 1 km spacing The quality of the data is
acceptable for regional interpretation but is not adequate for detailed analysis The accuracy of the flight path is rather
variable reflecting the vintage of the data and the noise envelope of the data is poor by modern standards Problems
were also encountered in joining different map sheets
The magnetic anomaly pattern over the south and west part of the area shows a strong high frequency signature
reflecting the presence of widespread basic sills and dykes Some of the major north-northeasterly trending dykes can
be traced over considerable distances
Discontinuous high-frequency anomalies extend as a northwest-trending zone through the centre of the area and
this zone includes a conspicuous circular magnetic anomaly which is probably a ring complex
The northern and eastern parts of the area are characterized by long-wavelength deep-seated basement magnetic
anomalies with 120deg and 150deg trends dominant The Marloo and Perentie Faults (Figure 42) appear as distinct linear
zones and offsets A prominent easterly trending negative anomaly in the northwest of the area appears to swing round
to the southeast and may separate different basement blocks One possible interpretation is that this very deep seated
anomaly separates areas of Archaean and Proterozoic basement
Regional geology
The regional geology is described in Williams (1992) The GSWA provided a digitized version of Plate 2 from this
Bulletin the structural interpretation map to use as an overlay (Figure 42)
53
Pp
Pp
PSd
PSd
PSd
PSd
PSd
PSo
PSt
PSt
PSf
PSf
PSf
PSb
PSb
PSb
PSsPSs
PSs
PSb
PSm
PSp
PSc
PSc
PSw
PSw
PSw
PSg
PSr
PSj
PSg
PM
Pk
PY
PY
PSd
L
L
L
L
L
L
L
LL
L
L
L
LL
L
LL
L L
LL
L L
L
L
L
L
L
L
L
LL
L
L
BLAKEDEPOCENTRE
MA
RLO
O
FAU
LT
PERENTIEFAULT
50 km
MKS39120598
120deg 121deg 122deg 123deg
25deg
24deg
23deg
Approximate boundaryof aeromagnetic interpretation
PML
PSgL
PSjL
PML
PSpL
PML
PML
PSfL
PSfL
PSpL
LPc
LPcLPcPSrL
LPA
Durba Sandstone
Woora Woora Formation
McFadden Formation
Tchukardine Formation
Boondawari Formation
Skates Hills Formation
Mundadjini Formation
Coondra Formation
Spearhole Formation
Watch Point Formation
Jilyili Formation
Brassey Range Formation
Glass Spring Formation
Paterson Formation
Yeneena Group
Karara Formation
Cornelia Formation
Kahrban Subgroup
Bangemall Group
Fault
Formation boundary
PSdL
PSoL
PSfL
PStL
PSbL
PSsL
PSmL
PScL
PSpL
PSwL
PSjL
PSrL
PSgL
Pp
PYL
PkL
LPc
LPA
PML
Savory Group Other Units
PYL
Figure 42 Regional geology and structure map (after Williams 1992)
54
120deg 121deg 122deg 123deg
23deg
24deg
25deg
5820
3750
MKS47 180598
nT
50 km
Figure 43 Regional aeromagnetic data total magnetic intensity (BMRAGSO data) gridded at 400 m
Analysis
3D analysis
3D Euler deconvolution was used as the primary depth-determination method The advantage of this approach is that
consistent solutions can be obtained over the entire area with minimal assumptions about source geometries Euler
deconvolution of gridded data is used for positional information and estimation of depth to top of source Euler
55
deconvolution yields a large number of depth solutions which have to be screened to reject spurious solutions Results
are plotted as circles in eight depth ranges with radius proportional to depth and colour coded
The 400 m total magnetic intensity grid was used for the analysis Horizontal gradients in x and y and the vertical
gradient were calculated 3D Euler deconvolution was tested on the 400 m gridded data using windows of 9 times 9 and
11 times 11 and 16 times 16 data points and structural indices 05 (fault) and 10 (sill or dyke) It was concluded that the
16 times 16 window produced the best results overall and final plots were produced for the 16 times 16 window and structural
index 05 (Fig 44) Results were very good over the northern and central parts of the area showing magnetic sources
Figure 44 Depth to magnetic source 3D Euler deconvolution 16 times 16 window of 400 m gridded data structural index 05
56
at several different levels Unfortunately in the extreme south of the area shallow intrasedimentary magnetic sources
(sills and dykes) dominated the inversion and the results contained few basement solutions
In order to reduce these problems the 400 m gridded data were filtered using a separation filter based on
interpretation of the log-energy spectrum The 3D Euler method was run on the filtered data in order to generate more
basement-depth solutions Results for the deep-separation filter data were gridded and presented as a colour image in
Cowan (1995) Attempts to grid the Euler output were unsatisfactory and it is considered safer to interpret the 3D
Euler depth plots The 3D Euler depth results from the separation-filter run should be analysed with care as perfect
separation of the basement can never be achieved and there will always be some contamination from sources at
different levels
The results of original total magnetic intensity 3D Euler depth estimation for structural index 05 using a 16 point
window have been plotted at 1500 000 scale (not included in this publication but available in Cowan (1995) from the
GSWA Library as S10331) and as reduced A4 colour circle plots (Figure 44)
The results of deep-basement 3D Euler depth estimation for structural index 05 using a 16 point window have
been plotted as a colour image at 1500 000 scale and as an A4 image (not included in this publication)
2D analysis
Two equispaced profiles were interpolated with a 50 m station interval from the AGSO-located data profiles for the
BULLEN 1250 000 sheet The interpolated profiles were analysed using 2D Euler deconvolution and Werner
deconvolution Results are included in Cowan (1995) and show the use of these methods for more detailed analysis
Filtered data
In order to reconcile 3D Euler results from shallow basement and intrasedimentary magnetic sources we produced
several separation-filtered maps and images We found the shallow-layer double-separation filter (Figure 45) to be
very effective for shallow sources and the deep-layer standard-separation filter (Figure 46) for the basement layer
Gravity and magnetic data correlation
Both lsquoreduced to the polersquo (RTP) magnetics (Figure 47) and pseudo-gravity data (Figure 48) were produced as part of
the reconciliation of gravity and magnetic signatures In both cases the filtering operations assumed magnetization by
induction in the present Earths field The RTP data are fairly similar to the total magnetic intensity The pseudo-
57
gravity data are dominated by a northwest-trending strong positive anomaly and there is little correlation with the
Bouguer gravity data
The poor magneticgravity correlation is confirmed by cross-correlation of the RTP magnetics and the gravity
gradient The correlation plot in Figure 49 shows little coherent response with numerous zones of positive and
negative correlation
Figure 45 Regional aeromagnetic data shallow layer separation filter (BMRAGSO data) gridded at 400 m
Results
In the north and east of the area on the Wells Foreland Sub-basin trend (refer to Figure 1 main text) we see a range
of quite deep 3D Euler depths and several trend directions with north-northwesterly dominant There are relatively few
shallow intrasedimentary solutions in this zone
The second area of deep 3D Euler solutions lies over the Blake depocentre (Figure 43) with several trend
directions
Elsewhere the 3D Euler results are dominated by shallow intrasedimentary depth solutions reflecting mainly the
dolerite sills dykes and the ring complex However where we do see basement-related solutions in the south and
west of the area they appear to be shallower than those noted for the Wells Foreland Sub-basin and the Blake
depocentre
58
Figure 46 Regional aeromagnetic data deep-layer separation filter (BMRAGSO data) gridded at 400 m
Figure 48 Regional aeromagnetic data pseudo-gravity transform (BMRAGSO data) gridded at 400 m
Figure 47 Regional aeromagnetic data reduced-to-pole (BMRAGSO data) gridded at 400 m
Figure 49 Regional aeromagnetic and gravity data gravitymagnetic correlation using RTP magnetics and gravity gradient (BMRAGSO data) gridded at 4 km
59
This subdivision of the area into two zones of deep solutions is consistent with interpreted depocentres
However the interference between sources at different levels and the complexity of the magnetic response of the
basement rocks precludes more refined interpretation at this stage
The area of deep 3D Euler solutions over the Blake depocentre correlates with the pronounced negative gravity
anomaly discussed in the gravity interpretation section Using a density contrast of -015 gcc the negative gravity
anomaly could indicate up to 6ndash8 km of low-density sedimentary rocks depending on assumptions about the regional
field
The area of deep 3D Euler solutions over the Wells Foreland Sub-basin has a complex gravity expression and no
clear basin structure emerges from inversion of these data As noted previously it is likely that observed gravity
anomalies reflect contrasts in basement density rather than basement topography
Separation filtering applied to the magnetic data helps to enhance the intrasedimentary magnetic signature and to
give a better impression of the basement magnetic signature even though separation of the basement response is not
perfect
Conclusions
Quantitative aeromagnetic interpretation using 3D Euler deconvolution supported by wavenumber filtering and image
processing has been successful in providing structural trend and depth information for the Savory Sub-basin
Quantitative magnetic interpretation has revealed two zones of relatively deep magnetic basement beneath the
Wells Foreland Sub-basin and the Blake depocentre
This analysis of the magnetic data supports interpreted depocentres but the complexity of the basement magnetic
signature and interference from sources at different depths precludes further refinement to a map of basement
topography
Regional gravity proved to be very useful in understanding the regional setting of the area and in providing
support for aspects of the interpretation The gravity data support the interpretation of the Blake depocentre
suggesting up to 6ndash8 km of low-density sedimentary rocks
The deep structure of the Savory Sub-basin area is obviously complex with different areas underlain by
Archaean and Proterozoic basement and with the Capricorn suture occurring in the centre of the area
60
Recommendations
The quantitative magnetic interpretation needs to be reconciled with geological models available for the area
In particular the zones tentatively identified as areas with thick sedimentary rocks the Wells Foreland Sub-
basin and the Blake depocentre need to be investigated
Cross sections should be prepared across the basin for joint magneticgravity modelling especially for the Blake
depocentre It is important to be able to explain the strong negative gravity anomaly in this area
In view of the effects of basement density contrasts on the gravity field for the northern part of the area we think
that additional gravity interpretation and acquisition of new gravity data may not be justified as they will not
contribute significantly to understanding basin evolution and structure
It is recommended that GSWA try to get access to company confidential high-resolution aeromagnetic data
rather than flying new surveys The GSWA might offer to fund flying of new infill areas as a bargaining point
References
The original text of this report by Cowan (1995) and 1500 000 scale maps are filed in the GSWA Library under
S10331
COWAN D 1995 Savory Basin quantitative magnetic interpretation Western Australia Geological Survey S-series
S10331 (unpublished)
VACQUIER V STEENLAND N C HENDERSON R G and ZIETZ I 1951 Interpretation of aeromagnetic
maps The Geological Society of America Memoir 47 151p
WILLIAMS I R 1992 Geology of the Savory Basin Western Australia Western Australia Geological Survey
Bulletin 141 115p
61
Appendix 5
Geochemistry
MKS38 250398
Saturate FractionC12+ GLC
1217
Pr18
Ph
22
31CSR WELL-13 315m Cuttings
Figure 51 Canning Stock Route Well 13 gas chromatograph of extract of auger drill sample
12
17
18
22
31
Pr Ph
LDDH 1 6623m CoreSaturate FractionC12+ GLC
MKS35 240398
Figure 52 Gas chromatograph of extract from core sample at 6623 m LDDH1
62
Table 51 Canning Stock Route Well 13 auger drill samples
GSWA sample Drill depth (m)(a) Comments
135601 150 At watertable 135602 203 (all samples consist 135603 310 of sand mud and water) 135604 315 At total depth
NOTE (a) Datum for drill depth is the top of sediment fill in the well which is 155 m below ground level (ie the total depth of 315 m is 47 m below ground level)
Table 52 Canning Stock Route Well 13 gas chromatography data for 315 m depth sediment sample
Parameter Value
Weight of rock extracted (grams) 945 Total extract (ppm) 519 n-Alkane distribution n-C12 07 n-C13 23 n-C14 26 n-C15 22 n-C16 19 n-C17 14 i-C19 23 n-C18 14 i-C20 08 n-C19 11 n-C20 16 n-C21 25 n-C22 29 n-C23 70 n-C24 42 n-C25 95 n-C26 43 n-C27 83 n-C28 38 n-C29 87 n-C30 31 n-C31 273 Alkane compositional data Pristane phytane ratio 279 Pristane n-C17 ratio 161 Phytane n-C18 ratio 059 CPI (1)(a) 284 CPI (2) 209 (C21 + C22) (C28 + C29) 043
NOTE (a) CPI= Carbon preference index
63
Table 53 LDDH1 extract liquid chromatography data for 6623 m concentration
Rock extracted Total extract (grams) (ppm)
702 313
NOTE ppm= parts per million
Table 54 LDDH1 saturate gas chromatography data of core for 6623 m alkane composition
Pristane Pristane Phytane (a) CPI (1) CPI (2) (C21+C22) Phytane n-C17 n-C18 (C28+C29)
103 026 024 103 102 325
NOTE (a)CPI = carbon preference index
Table 55 LDDH1 saturate gas chromatography data of core for 6623 m n-alkane distributions
Parameter Value
n-C12 17 n-C13 38 n-C14 55 n-C15 60 n-C16 65 n-C17 74 i-C19 19 n-C18 78 i-C20 19 n-C19 80 n-C20 79 n-C21 71 n-C22 64 n-C23 57 n-C25 43 n-C24 38 n-C27 31 n-C28 23 n-C29 19 n-C30 12 n-C31 10
64
Appendix 6
Table 61 Summary of data from Trainor waterbores (TWB) and Bullen waterbores (BWB)
Well AMG Elevation TD Status(b) Completion details Water Salinity Water level Flow rate Depth to consolidated AGD84 GL (m) (m) struck mgl(c) (m) (LHr) lithology aquifer(e) Z51(a) Interval (m) (100 mm PVC) (m) (mgl)(d)
TWB 1 473660E 453 122 comp 0ndash75 plain 63 7 300 24 2 880 12 m 7287404N 75ndash93 slotted (9 260) McFadden Fm 93ndash99 plain TWB 2 472 977E 475 23 abd nil 15 m 7285877N Skates Hills Fm dry TWB 3 473259E 475 50 abd nil 7 m 7285849N Skates Hills Fm dry TWB 4 463225 E 445 50 comp 0ndash22 plain 35 7 200 55 3 600 0 m 7286143N 22ndash34 slotted (8 140) Tertiary sand and gravel 23ndash60 plain TWB 5 463095E 445 31 comp 0ndash19 plain 13 26 000 655 3 600 Tertiary sand and gravel 7277721N 19ndash25 slotted (36 700) 25ndash31 plain TWB 6 457013E 455 50 comp 0ndash42 plain 38 920 119 600 0 m 7274352N 42ndash48 slotted (1 030) Cornelia Fm ss TWB 7 453739E 475 26 susp 0ndash2 plain 11 9 300 48 4 500 0 m 7263891N (10 500) Tertiary sand TWB 8 433893E 535 60 susp 0ndash2 plain 47 8 500 gt46 1 200 0 m 7245991N (10 900) Tertiary sand and Brassey Range Fm ss TWB 9 437219E 505 51 comp 0ndash47 plain 45 1 000 58 600 1 m 7235905N 47ndash51 slotted (990) Brassey Range Fm ss TWB 10 434927E 495 32 susp 0ndash2 plain 235 450 120 0 m 7225875N (500) Dolerite
65
BWB 1 287337E 580 122 abd Nil 1 m 7245861N Jilyili Fm dry BWB 2 288346E 545 50 comp 0ndash26 plain 15 630 3 29 000 0 m 7240423N 26ndash38 slotted (730) Tertiary sand and gravel 38ndash50 plain BWB 3 305637E 545 50 abd 19 8 800 43 7 200 0 m 7240423N (10 550) Tertiary ss BWB 4 320167E 515 445 comp 0ndash20 plain 9 980 445 24 000 0 m 7248097N 20ndash32 slotted (1 190) Tertiary ss 32ndash44 plain BWB 5 353393E 545 20 susp 0ndash2 plain 45 (970) 1 m 7238934N Basalt
NOTES (a) GPS accuracy ~ 150 m (b) Comp = completed abd = abandoned susp = suspended (c) Salinity from conductivity (d) Analysis total dissolved solids (e) Fm = Formation ss = sandstone
MINISTER FOR MINES The Hon Norman Moore MLC DIRECTOR GENERAL L C Ranford DIRECTOR GEOLOGICAL SURVEY OF WESTERN AUSTRALIA David Blight The recommended reference for this publication is STEVENS M K and CARLSEN G M 1998 A compilation and review of data pertaining to the
hydrocarbon prospectivity of the Savory Sub-basin Officer Basin Western Australia Western Australia Geological Survey Record 19985 65p
National Library of Australia Card Number and ISBN 0 7309 6588 0 Copies available from Information Centre Department of Minerals and Energy 100 Plain Street EAST PERTH WESTERN AUSTRALIA 6004 Telephone (08) 9222 3459 Facsimile (08) 9222 3444
iii
Contents Abstract 1
Introduction 2
Access and climate 4
Regional geology 6
Stratigraphy 6
Depositional Sequence A Supersequence 1 11
Depositional Sequence B Supersequence 1 11
Depositional Sequence C Supersequence 3 14
Depositional Sequence D Supersequence 4 14
Depositional Sequence E Supersequence 4 14
Other depositional sequences and regional correlations 14
Structural setting 17
Exploration history 19
Hydrocarbon potential 19
Source rocks 22
Maturity 23
Reservoirs 25
Seals 25
Traps 26
Preservation of hydrocarbons 26
Reported hydrocarbon shows and oil seep 27
Geological and geophysical data bases 27
Drilling 28
Petroleum industry data 28
Government data 28
Mineral industry data 28
Hydrogeological data 29
Seismic data 29
Aeromagnetic surveys 29
Government data 29
Mineral industry data 30
Gravity surveys 30
Government data 30
Mineral industry data 30
Government and academic reports 32
Chronostratigraphy and geochemistry 32
Proposed work program 32
Conclusions 33
References 35
iv
Appendices
1 Bibliography 41
2 Meteorological data 44
3 Summary of palynological results 47
4 Cowan Geodata Services Report Savory Sub-basin quantitative magnetic and gravity
interpretation 48
5 Geochemistry 61
6 TWB and BWB waterbore data 64
Figures
1 Structural subdivisions of the Savory Sub-basin 3
2 Localities and access routes of the Savory Sub-basin 5
3 Formations lithology and depositional sequences AndashE of the Savory Sub-basin 7
4 Correlation of Savory Sub-basin formations with the western Officer and Amadeus Basins 10
5 Locations of petroleum exploration wells mineral exploration and stratigraphic drillholes
and waterbores and wells 12
6 Geological cross section through significant drillholes 13
7 Regional geological setting of the Savory Group and western Officer Basin 15
8 Locations of aeromagnetic and gravity surveys 21
9 Petroleum source potential of rocks in Normandy LDDH1 24
10 Regional Bouguer gravity map of the Savory Sub-basin 31
11 Detailed Bouguer gravity map of the Savory 1995 Gravity Survey from the
eastern Savory Sub-basin 31
Tables
1 Summary of formations in the Savory Sub-basin 8
2 Neoproterozoic formations and hydrocarbon shows in diamond drillholes in the
Savory Sub-basin 20
~Version Information13 VERS 120 CWLS log ASCII Standard -VERSION 12013 WRAP NO One line per depth step131313~Well Information Block13MNEMUNIT Data Type Description13--------- ------------ -----------------------------13 STRTM 5000013 STOPM 00013 STEPM -10013 NULL -9992513 COMP COMPANY GEOLOGICAL SURVEY OF WA 13 WELL WELL TWB 6 13 FLD FIELD SAVORY SUB-BASIN 13 LOC LOCATION AGD84 Z51 457 013E 7 274 352N 13 PROV PROVINCE WESTERN AUSTRALIA 13 SRVC SERVICE COMPANY BPB Wireline Services 13 DATE LOG DATE 16-NOV-1995 13 UWI UNIQUE WELL ID 131313~Curve Information Block13MNEMUNIT Curve Description13--------- -----------------------------13 DEPTM DEPTH13 GRNPGAPI GAMMA FROM NEUTRON TOOL 13 LSN SNU LONG SPACED NEUTRON 13 SSN SNU SHORT SPACED NEUTRON 13 RPOR LIMEST NEUTRON POROSITY 13 BISIMM BIT SIZE 131313~Other Information13NEUTRON POROSITY GAMMA RAY LOG 13LOGGED THROUGH PVC CASING 13 13 13 13Run number ONE Log 1st rdg 497 M Log last rdg 0 M 13Driller TD 50 M Logger TD 50 M Water level 8 M 13Perm Datum GL Elevation Approx 455 M Other srvcs 13Dril mes from GL Log meas from GL 0 M Other srvcs 13Elevation KB DF GL 13Casing Driller Casing Logger Casing size 100 MM 13Casing Weight PVC From 0 M To 50 M 13Bit size 168 MM From 4 M To 50 M 13Hole fl type WATER Sample source Fluid loss 13Density Viscosity pH 13RM meas tmp RMF mes tmp RMC mes tmp 13RM BHT RMF source RMC-source 13Max rec temp Time snc circ LsdSecTwpRge 13Equipment no V338 Base PERTH Equip name NN1 13Recorded by RALEES Witnessed by MKSTEVENS Sonde srl no 5094421 13Last title Last line Permit no 131313~A Depth GRNP LSN SSN RPOR BISI13 50000 -999250 -999250 -999250 -999250 15000013 49900 -999250 -999250 -999250 -999250 15000013 49800 -999250 -999250 -999250 -999250 15000013 49700 -999250 -999250 -999250 -999250 15000013 49600 -999250 -999250 -999250 -999250 15000013 49500 -999250 -999250 -999250 -999250 15000013 49400 -999250 216309 1965945 21484 15000013 49300 -999250 209718 1885054 18983 15000013 49200 -999250 193254 1788650 20017 15000013 49100 -999250 179391 1718687 21242 15000013 49000 -999250 169195 1664613 22255 15000013 48900 -999250 164382 1641439 22881 15000013 48800 -999250 161675 1610665 22813 15000013 48700 -999250 158560 1582780 22969 15000013 48600 -999250 153487 1540073 23222 15000013 48500 -999250 150656 1507227 23153 15000013 48400 -999250 149882 1476893 22537 15000013 48300 -999250 149163 1472245 22684 15000013 48200 -999250 150061 1480661 22713 15000013 48100 -999250 152366 1505029 22817 15000013 48000 -999250 155587 1522300 22376 15000013 47900 -999250 156423 1545663 22756 15000013 47800 -999250 157996 1564316 22732 15000013 47700 -999250 160387 1576311 22387 15000013 47600 -999250 164977 1575181 21193 15000013 47500 -999250 169393 1573485 20161 15000013 47400 -999250 172602 1572606 19401 15000013 47300 -999250 174262 1576876 19106 15000013 47200 125606 176189 1588872 18968 15000013 47100 130283 177279 1602375 19020 15000013 47000 133820 177991 1612297 19135 15000013 46900 133219 177161 1612863 19341 15000013 46800 132529 178270 1613868 19143 15000013 46700 132046 178623 1608090 18950 15000013 46600 132923 178778 1608655 18966 15000013 46500 130992 176622 1610853 19516 15000013 46400 129967 174944 1622095 20144 15000013 46300 125691 174745 1628815 20332 15000013 46200 120912 175222 1643574 20508 15000013 46100 116508 178518 1664739 20243 15000013 46000 113650 183591 1699030 19897 15000013 45900 112428 194771 1736147 18532 15000013 45800 111492 205283 1778413 17500 15000013 45700 110773 213849 1811134 16664 15000013 45600 106644 218024 1834434 16419 15000013 45500 102663 219914 1842913 16259 15000013 45400 100338 218774 1849068 16525 15000013 45300 102289 214865 1845237 17050 15000013 45200 104161 210994 1840464 17548 15000013 45100 107659 206937 1831357 18079 15000013 45000 112103 204434 1829787 18506 15000013 44900 115739 202186 1827652 18884 15000013 44800 114251 205716 1840212 18575 15000013 44700 112034 211533 1865836 18135 15000013 44600 109433 221202 1911306 17408 15000013 44500 107797 227489 1949365 17072 15000013 44400 104201 231491 1968897 16756 15000013 44300 101028 227316 1959728 17256 15000013 44200 99087 220168 1932283 17921 15000013 44100 98535 209315 1882982 18775 15000013 44000 101875 197069 1817352 19952 15000013 43900 108467 183944 1742050 21126 15000013 43800 120232 172206 1663797 22036 15000013 43700 132884 161019 1588055 22923 15000013 43600 146265 149622 1526068 24472 15000013 43500 153222 141321 1497115 26104 15000013 43400 158207 137704 1501072 27243 15000013 43300 160080 138026 1539948 28216 15000013 43200 159607 141619 1597602 28678 15000013 43100 156927 148996 1668570 28332 15000013 43000 153281 163837 1732253 26034 15000013 42900 148472 178047 1798887 24148 15000013 42800 141141 189234 1846618 22675 15000013 42700 135140 193446 1869730 22167 15000013 42600 131564 193049 1855474 21890 15000013 42500 130647 187245 1828405 22388 15000013 42400 133002 177669 1788023 23521 15000013 42300 140875 170564 1751785 24117 15000013 42200 148462 167356 1723711 24236 15000013 42100 153034 171184 1721953 23337 15000013 42000 154680 175167 1734388 22776 15000013 41900 154778 184501 1755427 21227 15000013 41800 150354 191984 1772133 19993 15000013 41700 144127 199051 1792042 18924 15000013 41600 139575 198643 1800897 19190 15000013 41500 136806 195923 1791539 19520 15000013 41400 132500 188280 1755302 20242 15000013 41300 127287 180314 1706001 20760 15000013 41200 124045 170025 1651361 21769 15000013 41100 123228 161868 1603066 22651 15000013 41000 123366 155054 1568147 23585 15000013 40900 124469 150408 1561678 24688 15000013 40800 124174 148909 1579577 25546 15000013 40700 125110 151938 1611293 25604 15000013 40600 125602 156361 1643511 25233 15000013 40500 129130 158646 1672275 25446 15000013 40400 129140 158448 1688290 25975 15000013 40300 131810 155841 1691682 26874 15000013 40200 131179 154620 1691242 27181 15000013 40100 131682 155531 1696706 27112 15000013 40000 129031 160381 1707006 25981 15000013 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1
A review of data pertaining to the hydrocarbon prospectivity of the Savory Sub-basin Officer Basin
Western Australia
by
M K Stevens and G M Carlsen
Abstract
The Savory Sub-basin of the Officer Basin in central Western Australia is part of a large Neoproterozoic episutural basin and is a frontier for hydrocarbon exploration It contains up to 8 km of clastic carbonate and rare evaporite sedimentary rocks with minor volcanic dykes sills and flows No petroleum exploration activity had been undertaken in this sub-basin prior to 1995 and hydrocarbon prospectivity is assessed from mineral and recent petroleum exploration drilling No seismic data have been acquired An interpretation of available data suggests that source-rock quality is the major exploration risk but that further investigation of the sub-basin is warranted
Minor oil shows (fluorescence with solvent cut) recorded in Spearhole Formation sandstones in the northwest of the sub-basin suggest oil has been generated and migrated into potential reservoirs in the sub-basin
Each of the five depositional sequences recognized in the sub-basin contain potential reservoir rocks which are seen in outcrop as friable sandstones The Durba Sandstone is interpreted as the best-quality reservoir Indications of evaporitic environments from the Mundadjini Skates Hills and Boondawari Formations suggest that seals may be provided by evaporites and mudstones Neoproterozoic to Cambrian rocks may provide structural closures including both fold and fault traps for migrating hydrocarbons Salt diapirs are interpreted from the gravity data A large semi-detailed gravity survey in the eastern part of the sub-basin revealed major folds faults and halokinetic structures
Potential source rocks include marine mudstones of the Skates Hills and Mundadjini Formations which are associated with stromatolitic dolomites and evaporites Rare outcrops of black mudstones from other units such as the Boondawari Formation also suggest source potential
The Geological Survey of Western Australia has drilled one stratigraphic hole (Trainor 1) in the sub-basin to assess the source potential of Neoproterozoic sedimentary rocks Five of the six samples analysed for Total Organic Carbon in the Cornelia Formation from this well exceeded 05 but have a high level of maturation with at best dry gas-generating potential The age of the Cornelia Formation is uncertain but at least part of it is interpreted to be Neoproterozoic and hence part of the Savory succession
Maturity data which are very sparse due to limited drilling are inferred from the Thermal Alteration Index of organic matter to be at about the base of the oil window and the top of the gas window in two
2
waterbores in the southeast of the sub-basin and a mineral drillhole in the north of the region Rock cuttings from a waterbore in the southwest of the sub-basin are overmature for hydrocarbon generation but this bore intersected mafic intrusives and hence may not be representative of maturity for the region
KEYWORDS hydrocarbon prospectivity oil shows Neoproterozoic Savory Sub-basin Officer Basin source rocks diamond drilling
Introduction
Recognition in the late 1980s of a thick sequence of generally weakly deformed Neoproterozoic
sedimentary rocks of relatively low thermal maturity previously included within the
Mesoproterozoic Bangemall Basin (defined as the Savory Basin by Williams 1992) revealed a
hydrocarbon exploration frontier The Savory Sub-basin (Fig 1) now recognized as part of the
Officer Basin is located west of outcrops of Phanerozoic cover rocks of that larger basin The
Officer Basin a large episutural basin which contains clastic carbonate and minor evaporite and
volcanic rocks is considered to be part of the Neoproterozoic Centralian Superbasin (Walter and
Gorter 1994) The age of the Officer Basin successions is not well constrained but in the Savory
Sub-basin it is largely Neoproterozoic with possible Palaeozoic strata present in parts
The boundaries defined by Williams (1992) for the sub-basin have been largely used in this
record but data from sedimentary rocks previously assigned to older basins that are now
recognised or inferred to be of early Neoproterozoic age (Supersequence 1) have been used to
assess the hydrocarbon potential of the northwestern part of the Officer Basin
The southern part of the sub-basin unconformably overlies the Mesoproterozoic Bangemall Basin
The western boundary of the sub-basin is faulted against the Bangemall Basin The eastern
boundary of the Savory Basin as defined by Williams (1992) was placed along the western edge
of Phanerozoic outcrops of the Officer Basin at approximately 123degE longitude Recent studies
(Perincek 1996ab) however have indicated there is little difference in the Neoproterozoic
geology of the two regions The northeastern boundary of the sub-basin was defined as a reverse-
and thrust-faulted contact with the Yeneena and Karara Basins of the Paterson Orogen (Williams
1992) However Bagas et al (1995) subdivided strata from the Yeneena Basin into three new
groups the Throssell Lamil and Tarcunyah Groups The older and more deformed Throssell and
Lamil Groups remain part of the Yeneena Basin and the Paterson Orogen The younger and less-
deformed sedimentary rocks of the Yeneena and Karara Basins were considered to be of
Supersequence 1 age and were reassigned to the Tarcunyah Group The Tarcunyah Group was
considered to be coeval with the older strata of the Savory Sub-basin The Tarcunyah Group
Savory Sub-basin and Officer Basin were grouped into a single tectonic unit which was informally
referred to as the greater Officer Basin (Bagas et al 1995)
3
50 km
120deg 121deg30 123deg
25deg
24deg
23deg
22deg
Blake Fault andFold Belt
Wells Foreland S
ub-basin
TrainorPlatform
MKS32200498
HamersleyBasin
PilbaraCraton
YeneenaBasin
YeneenaBasin
YeneenaBasin
CanningBasin
Sylvania Inlier
BangemallBasin
Bangemall Basin
YilgarnCraton
YilgarnCraton
GlengarryBasin
EaraheedyBasin
Ward Inlier
OldhamInlier
KararaBasin
GibsonSub-basin
(Officer Basin)
WestwoodShelf
(Officer Basin)
KingstonShelf
(Officer Basin)
Rudall Complex
Trainor Platform
(Kahrban Subgroup)
Greater Officer Basin
Savory Sub-basin
Surface anticlinesMAP
AREAPerth
Figure 1 Structural subdivisions of the Savory Sub-basin and surface anticlines
4
During 1994 in consultation with the Petroleum Industry the Department of Minerals and
Energy received State Government funding for a Petroleum Exploration Initiative to be
undertaken by the Geological Survey of Western Australia (GSWA) with a view to identifying
prospective onshore areas for oil and gas thus increasing the level of onshore exploration in
Western Australia This initiative was originally funded for the first three years of a five-year work
program Two teams of specialists were formed to investigate the prospectivity of both the western
margin and interior onshore sedimentary basins
The Petroleum Exploration Initiative teams seek to enhance the prospectivity of onshore
basins by reducing through focused investigations the risks perceived by industry to be factors
limiting exploration activity Comprehensive petroleum system reports of the onshore Western
Australian basins are to be completed as a result of the projects undertaken during the five-year
Initiative The objective of the Initiative will be achieved through both the analysis of open-file
exploration data and the acquisition of new data New data will include but not be limited to
geophysical surveys and stratigraphic drilling Project results are to be reported to the industry
through GSWA publications external publications conference reports and oral presentations
This Record is the third in a series of comprehensive reviews by the GSWA of the
hydrocarbon prospectivity of some of Western Australiarsquos interior onshore sedimentary basins
The first Record of this series covered the Canning Basin (Apak and Carlsen 1997) The second
Record reviewed the Western Australian Officer Basin (Perincek 1998) but excluded the Savory
Sub-basin
This study assesses the potential for hydrocarbon exploration within the Savory Sub-basin
based on available geological and geophysical data and defines the scope for future studies
Publications relevant to this investigation but which are not specifically referred to are listed in
Appendix 1
Access and climate
The Savory Sub-basin lies east and southeast of the mining town of Newman in the Pilbara region
(Fig 2) The area is largely uninhabited the only settlement being an outcamp at Poondawari on
the GUNANYA 1250 000 map sheet The outcamp is linked by a graded track to the Jigalong
Community 90 km to the west just outside the northwest margin of the sub-basin A few pastoral
leases lie along the margins of the sub-basin but the majority of the region is Vacant Crown Land
Capitalized names refer to standard map sheets
5
Sealed road
Gravel road
Track
Town
Homestead
Locality
STANLEYSavory Sub-basin boundary 1250 000 map sheet
CornerTrack
Talawana - Windy
Route
Watch Point
NEWMAN
JigalongCommunity
RobertsonRange (abd)
Wokalba
Poondawari
Balfour Downs
Billinnooka
Weelarrana
Beyondie(abd)
Kumarina
Marymia
Glen-ayle
White Lake
Hanging RockBoorabee Hill
WellsRa
EmuRa
Robertson
Ra McFadden R
a
DiebillHills
DurbaHills
Calvert Ra
WardHills
Cornelia Ra
KellyRaBlakeHills
HillsDean
ROBERTSON GUNANYA
TRAINORBULLEN
BALFOUR DOWNS RUDALL
NABBERU STANLEY HERBERT
50 km
Woora Woora Hills
120deg 121deg30 123deg
25deg
24deg
23deg
22deg
Goldfieldsnatural gaspipeline
GR
EA
TN
OR
TH
ER
NH
IGH
WA
Y
Mar
ble
Bar
Nul
lagi
ne-
Rd
MADLEY
Can
ning
Stoc
k
MKS31120598
Goldfields natural gas pipeline
Figure 2 Localities and access routes of the Savory Sub-basin
6
The sealed Great Northern Highway lies west of the Savory Sub-basin and links Meekatharra
to Newman The TalawanandashWindy Corner graded track crosses the northern part of the sub-basin
and graded pastoral station tracks on Balfour Downs Weelarrana Kumarina Marymia and Glen-
Ayle give access to the western and southern margins The Canning Stock Route traverses the sub-
basin from north to south and is a well travelled four-wheel-drive track allowing access to the
eastern half of the sub-basin Additional minor tracks also provide access to other parts of the area
(Williams 1992) Recently flown monochrome aerial photography at 150 000 and Landsat TM
imagery covering the sub-basin is available from the Department of Land Administration
Cross-country access is similar to that in the Canning Basin with the average height of sand
dunes being lower in the Savory Sub-basin Potable water has been found in water bores in the
south of the sub-basin and is inferred to be present throughout the region Fuel and supplies are
available at Wiluna Meekatharra and Newman A good working relationship with the Western
Desert Community who hold native title claims over most of the sub-basin has been established
by GSWA
There are no meteorological stations within the Savory Sub-basin but estimates based on data
from nearby Bureau of Meteorology Stations indicate that the area is arid and has its maximum
rainfall in summer from monsoonal rains The sub-basin has reasonable access and a tolerable
working climate for all exploration activities Meteorological data for the town of Wiluna which
lies about 180 km to the south of the sub-basin are included as Appendix 2
Regional geology
Stratigraphy
Thirteen formations were recognized by Williams (1992) in the Savory Sub-basin and these are
summarized in Table 1 Although unconformities were recognized between some of the
formations and they reflect a wide range of depositional environments provenance and climatic
conditions these formations were defined by Williams (1992) as constituting the Savory Group
Five depositional sequences that are generally unconformity-bounded were recognized by
Williams (1992) (Fig 3) The correlation of significant formations within the sub-basin with other
parts of the Centralian Superbasin is shown in Figure 4 with the four Neoproterozoic
Supersequences having been defined by Walter et al (1995)
7
Durba Ss
McFadden
Woora Woora400
Tchukardine700
Skates Hills
Mundadjini1800
B
Coondra
(B)
Watch Point
Spearhole1100Jilyili
1000(A)
Glass Spring1600(A)
Brassey Range1700(A)
Abs
ent
Absent Absent
Absent
Absent
Absent
A
B
C
D
E
1A
1B
3
4A
4B
1000
2000
3000
4000
5000
6000
Max
imum
thic
knes
s
Sup
erse
quen
ce
AG
EN
EO
PR
OT
ER
OZ
OIC
NE
OP
RO
TE
RO
ZO
ICT
O
CA
MB
RIA
NM
AR
I-N
OA
N
NW SE
Savory Sub-basin Stratigraphy
MKS30 120598
Fault boundary
Unconformity
Disconformity
Conglomerate
Sandstone Mudstone
Siltstone
Evaporite
Dolomite
Boondawari800 Boondawari
Supersequence 2 is not represented in the Savory Sub-basin Total thicknesses are estimated from air photo interpretation Thicknesses of recessive units are unknown
Diamictite
Dep
ositi
onal
seq
uenc
e
Figure 3 Formations lithology and depositional sequences AndashE of the Savory Sub-basin
8
Table 1 Summary of formations in the Savory Sub-basin
Formation Super Depo Lithology Thickness Depositional Savoy Comments Seq(a) Seq(b) (m) environment Group(c)
Durba Sandstone 4 E Quartz sandstone with minor 100 Fluvial lacustrine Y Excellent reservoir basal conglomerate lenses Woora Woora 4 D Medium-grained ferruginous 400 Shallow marine deltaic Y Formation sandstone lithic sandstone quartz wacke siltstone McFadden 4 D Laminated fine- to coarse-grained 1 500 Shallow marine deltaic Y Possible reservoir Formation quartz sandstone feldspathic sandstone quartz wacke minor conglomerate siltstone Tchukardine 4 D Medium- to coarse-grained sandstone 700 Shallow marine Y Formation lithic sandstone quartz wacke conglomerate lenses siltstone minor shale Boondawari 3 C Glacigene diamictite sandstone siltstone Formation shale conglomerate minor dolomite (some stromatolitic and oolitic) rhythmite 800 Glacial shallow marine Y Possible source rock Skates Hills 1 B Thin-bedded dolomite (some stromatolitic) 200 Shallow marine sabkha Y Possible source rock Formation chert evaporites fine- to medium-grained sandstone siltstone shale patchy basal conglomerate Mundadjini 1 B Fine- to coarse-grained sandstone 1 800 Deltaic sabkha Y Possible source rock Formation conglomerate siltstone minor shale shallow marine mudstone dolomite (some stromatolitic) and evaporites Coondra 1 B Coarse- to medium-grained sandstone 1 000 Fan delta Y Possible reservoir Formation poorly sorted conglomerate pebbly sandstone Spearhole 1 B Coarse- to medium-grained sandstone 1 100 Braided fluvial deltaic Y Possible reservoir Formation pebbly sandstone siltstone and oil shows in conglomerate lenses Mundadjini 1 Boondawari 1
9
Watch Point 1 B Shale siltstone fine- to medium-grained 400 Shallow marine deltaic Y Formation sandstone glauconitic sandstone Jilyili Formation 1 A Fine-grained sandstone siltstone minor shale mudstone conglomerate lenses 1 000 Deltaic Y Brassey Range 1 A Fine- to medium-grained sandstone 1 700 Fluvial deltaic Y Formation siltstone shale minor mudstone Glass Spring 1 A Medium- to coarse-grained sandstone 1 600 Shallow marine fluvial Y Formation minor conglomerate and siltstone Tarcunyah Group 1 AampB Quartz sandstone feldspathic sandstone Shallow marine sabkha N Bitumen in LDDH1 quartz wacke shale siltstone fluvial lacustrine conglomerate evaporites dolomite Cornelia 1 A Sandstone siltstone shale mudstone Shallow marine N Overmature source rocks Formation minor glauconitic sandstone deep marine in Trainor 1 Kahrban 1 A Sandstone siltstone shale 1 700 Shallow marine deltaic N Subgroup
NOTES (a) Supersequences of Walter et al (1995) (b) Depositional sequences of Williams (1992) (c) Y= assigned to Savory Group in Williams (1992) N= previously considered to be older than the Savory Group but now included in the greater Officer Basin
10
SAVORY SUB-BASIN GIBSON SUB-BASINCENTRAL OFFICERBASIN
AMADEUS BASIN
PETERMANN RANGES OROGENY
NE
OP
RO
TE
RO
ZO
IC
ST
UR
TIA
NM
AR
INO
AN
ED
IAC
AR
IAN
CAMBRIANTO
NEOPRO-TEROZOIC
AG
E (
Ma)
SOUTHS RANGE MOVEMENT
AREYONGA MOVEMENT
Steptoe
MILES OROGENY
Mission Group
Cassidy Group
Rudall Complex
Bangemall Group
unnamed
Tar
cuny
ah G
roup
4
3
2
1
MKS12a 180598
500
550
600
650
700
750
800
850
900
SU
PE
R
SE
QU
EN
CE
unnamed
Tchukardine Fm
McFadden Fm
ArumberaSst
Julie Fm
Pertatataka Fm
Olympic FmPioneer Sst
Boondawari Fm
Turkey Hill FmLupton Fm
Kanpa Fm
Neale FmBabbagoola
FmHussar
Fm
Browne Fm
Woolnough Fm
Madley Fm
Bitt
er S
prin
gs F
m
LovesCreek M
Gillen M
Heavitree Fm
Arunta Complex
Throssell Group
TownsendQuartzite
Earaheedy Group
olderCornelia Fm
Jilyili Fm
SpearholeFm
MundadjiniFm
Skates Hills Fm
Lefroy Fm
Areyonga Fm
Aralka Fm
ME
SO
-P
RO
TE
RO
ZO
IC
Waters Fm
youngerCornelia Fm
Brassey RangeFormationKahrban
Subgroup
GlassSpring
Fm
Durba Sst
LP1ALP1B EVENT
Figure 4 Correlation of Savory Sub-basin formations with the western Officer and Amadeus Basins Fm = Formation Sst = Sandstone M = Member
11
The depositional sequences recognized in the sub-basin are an order of magnitude thicker than
those described from Phanerozoic passive-margin settings (Payton 1977 Posamentier et al 1988)
and are broadly comparable in scale to the second-order cycles of Vail et al (1977) and to the
megasequences of Hubbard et al (1985) The main subsurface data available to reveal the
unweathered nature of these rocks are Trainor-1 and the three-well diamond coring program in
Petroleum Permit EP 380 (Akubra 1 Boondawari 1 Mundadjini 1) completed in late 1997 in the
central west of the sub-basin (Figs 5 and 6)
The ages of all formations in the Savory Sub-basin are poorly constrained The only fossils
known are stromatolites and palynomorphs (acid-insoluble microfossils) Palynology from
available wells is summarized in Appendix 3 from Grey and Stevens (1997) and Grey and Cotter
(1996) and correlations using stromatolite biostratigraphy (Stevens and Grey 1997 Grey 1995f
Walter et al 1994 1995) are consistent with a Neoproterozoic age for the formations for which
data are available
A dolerite within the Boondawari Formation gave a poorly constrained RbndashSr age of about
640 Ma (Williams 1992) SHRIMP UndashPb dating of sedimentary zircons from the McFadden and
Cornelia Formations in stratigraphic drillhole Trainor 1 are discussed in Stevens and Adamides (in
prep) and Nelson (1997) The youngest ages from these analyses indicate that the maximum age
of the Cornelia Formation is Early Cambrian or Sturtian but these ages are inconsistent with
previous tectonic interpretations (Williams 1992) and current stratigraphic correlations which
suggest the Cornelia Formation is of Supersequence 1 age or older (Fig 4)
Depositional Sequence A Supersequence 1
Depositional Sequence A includes the Glass Spring Jilyili and Brassey Range Formations (Fig
3) All of these units are predominantly quartzose sandstones some of which are friable and have
significant visible porosity in outcrop Conglomerates are present in the Glass Spring and Jilyili
Formations
Depositional Sequence B Supersequence 1
Depositional Sequence B consists of the Watch Point Coondra Mundadjini Spearhole and
Skates Hills Formations (Fig 3) All of these formations contain beds of quartzose sandstone and
some also contain conglomerates The porosity of dolomites in the Skates Hills Formation appears
poor in surface exposures but its subsurface characteristics are unknown
12
50 km
120deg 121deg30 123deg
25deg
24deg
23deg
22deg
Greater Officer Basin
PNCEXP CA11PNCEXP CA12
PNCEXP CA13PNCEXP CA19
PNCEXP CA05
PNCEXP CA09
BD134589
GSWA Trainor 1 and TWB123
Fortescue River 1A
Mundadjini 1
Akubra 1Boondawari 1
TWB4TWB5
TWB6
TWB7
TWB8
TWB9
TWB10
BWB1
BWB2 BWB3
BWB4
BWB5
OD23
Mineral exploration drillhole
Stratigraphic drillhole
Waterbores and wells(TWB and BWB serieswaterbores identified)
MKS33270398
LDDH 1
Savory Sub-basin
Canning SR Well 13
EP380
Petroleum Exploration permit
Petroleum exploration well
Figure 5 Locations of petroleum exploration wells mineral exploration and stratigraphic drillholes water bores and wells and petroleum exploration permit EP380 in the Savory Sub-basin
13
TD=600m
TD=1367m
TD=701m
TD=709m
TD=50m
SS
1S
S1
SS1
SS
1S
S1
SS
1
SS
1
SS1
SS4 SS1
Pha
nero
zoic
or
SS
2
Cz
CzCz
Karst Bitumen
SS1
TD=181m
Mundadjini 1 Akubra 1 Boondawari 1 LDDH 1 Trainor 1 TWB 6
Munda-djini Fm
Spear-hole Fm
Munda-djini Fm
Munda-djini Fm
Spear-hole Fm
Spear-hole Fm
Waters Fm
McFadden Fm
Cornelia Fm
Cornelia Fm
Cornelia Fm
511 plusmn 13Maor 696 plusmn 20Ma(maximum)
779 plusmn 10Ma(maximum)
Mundadjini 1
Akubra 1 Boondawari 1
LDDH 1
Trainor 1TWB 6100 km
N
LOCATION
NW SE
Sea level
0m AHD
Dolerite basalt
Conglomerate
Sandstone
Mudstone
Dolomite
Limestone
Evaporite
TOC gt08
Permeability gt100md
Oil fluorescence
Sedimentary zircon U-Pb age
Identifiable polymorphs
Cainozoic
Supersequence 1 age
Unconformity
Formation contact
Cz
SS1
r
r
0
100
200
metres
VerticalScale
MKS36 120598
LEGEND
Figure 6 Geological cross section through significant drillholes in the Savory Sub-basin
14
Depositional Sequence C Supersequence 3
Depositional Sequence C consists of the Boondawari Formation (Fig 3) and although it contains
sandstone conglomerate and dolomite the sandstones contain significant amounts of feldspar and
clay and hence are likely to be poorer reservoirs than older sandstones
Depositional Sequence D Supersequence 4
Depositional Sequence D includes the McFadden Tchukardine and Woora Woora Formations
(Fig 3) The McFadden Formation is poorly sorted and sandstones contain significant amounts of
feldspathic clasts in the north of the basin but are significantly coarser and cleaner in the northeast
of the sub-basin (Williams 1992)
Sandstones of the Tchukardine and Woora Woora Formations are generally cleaner than those
of the McFadden Formation and are expected to have fair to good porosity although the
Tchukardine Formation has a higher clay content in parts
Depositional Sequence E Supersequence 4
Depositional Sequence E consists of the Durba Sandstone (Fig 3) a coarse sandstone with minor
conglomerate which has good to excellent visible porosity in surface exposures
Other depositional sequences and regional correlations
Sedimentary rocks which were not included in the Savory Group by Williams (1992) but which
are likely to be of Neoproterozoic age and hence part of the greater Officer Basin include the
Tarcunyah Group the Cornelia Formation and the Kahrban Subgroup
As discussed in the Introduction all of the strata in the Karara Basin and the younger strata
of the Yeneena Basin were redefined to form the Tarcunyah Group of the greater Officer Basin
(Bagas et al 1995) (Fig 7) In outcrop the Tarcunyah Group consists predominantly of quartzose
feldspathic and arkosic sandstone shale which is carbonaceous in parts and carbonate which
includes stromatolitic dolomite Mineral hole LDDH1 drilled on GUNANYA intersected the
15
120598
122deg
123deg
21deg
22deg
23deg
24deg
23deg
22deg
21deg
122deg
123deg
Fault
Thrust
Reverse thrust
CANNINGBASIN
OFFICERBASIN
GROUP
PILBARACRATON
TARCUNYAH
SAVORY GROUP
BANGEMALL
GROUP
THROSSELL
GROUP
LAMIL
GROUP
ConnaughtonTerrane
TerraneTalbot
complexTabletop granitic
Tabletop Terrane
Permian
Neoproterozoicgranitoid
50 km
FormationWaltha Woora
McKay Fault
South west Thrust
Vines
Fault
24deg
120deg
YENEENA CANNINGBASIN
ARUNTAINLIERRUDALL
COMPLEX
AMADEUSBASIN
MUSGRAVEBLOCK
OFFICERBASINYILGARN
CRATON
GROUP
GROUP
GROUP
PILBARACRATON
GROUP
EARAHEEDY
GLENGARRY
BANGEMALL
WYLOO GROUP
SAVORY
WA
CARNARVONBASIN
GASCOYNECOMPLEX
GROUPTARCUNYAH
400 kmGROUP
SA
N
T
CamelndashTabletopfault zone
KAHRBANSUBGROUP
CORNELIAFORMATION
MKS37
Figure 7 Regional geological setting of the Savory Group and western Officer Basin The dashed line on the inset map marks the interpreted margin of the greater Officer Basin
16
Tarcunyah Group and consists predominantly of mudstone with minor sandstone limestone
dolomite and anhydrite (Fig 6)
The age of the Tarcunyah Group is uncertain although limited palynological and stromatolite
evidence suggests that it is probably coeval with Supersequence 1 of the Centralian Superbasin
Drillhole LDDH1 contains palynomorphs equivalent to assemblages in the Browne and Bitter
Springs Formations of the Officer and Amadeus Basins respectively and from the Cornelia
Formation in TWB 6 (Grey and Stevens 1997) (Figs 4 and 6) Stromatolite specimens tentatively
assigned to Acaciella australica (Howchin 1914) Walter 1972 occur in the lower Tarcunyah
Group (Bagas et al 1995) The stromatolite Baicalia burra Preiss 1972 and a conical
stromatolite were reported from the upper part of the Tarcunyah Group (Stevens and Grey 1997)
The recognition of two stromatolite assemblages interpreted to have age significance in
Supersequence 1 sedimentary rocks of the Centralian Superbasin has permitted biostratigraphic
correlations between outcrop and well data The Acaciella australica assemblage appears to be
slightly older than 800 Ma and is restricted to the middle part of Supersequence 1 The Baicalia
burra assemblage is considered to be slightly younger than 800 Ma and occurs in the upper part
of Supersequence 1 (Grey 1996b Stevens and Grey 1997) The older A australica assemblage
is recognized in the Skates Hills Formation in the Savory Sub-basin and the stromatolite A
australica itself has been tentatively identified in the lower Tarcunyah Group The occurrence of
the A australica assemblage in the Woolnough Madley and Browne Formations of the Officer
Basin and in the Loves Creek Member of the Bitter Springs Formation of the Amadeus Basin
allows correlations throughout the Centralian Superbasin (Fig 4)
The younger B burra assemblage has not been recognized in sedimentary rocks of the
Savory Group as defined by Williams (1992) but it occurs in the upper parts of the Tarcunyah
Group and allows correlation of this group with outcrops of the Neale Formation and with the
Kanpa Formation in petroleum exploration well Hussar 1 both located in the central Officer Basin
of Western Australia (Fig 4) (Grey 1996b Stevens and Grey 1997) The occurrence of the B
burra assemblage in these units permits their correlation with the Burra Group in the Adelaide
Geosyncline of South Australia (K Grey unpublished data)
The Cornelia Formation and Kahrban Subgroup outcrop in the southeast of the sub-basin and
were considered by Williams (1992) to be part of the Mesoproterozoic Bangemall Basin Limited
evidence suggests that all or parts of these two units are of Neoproterozoic age The Ward and
Oldham Inliers consist of outcrops of the Cornelia Formation Waterbore TWB 6 which was
drilled on TRAINOR in the Cornelia Formation contains palynomorphs consistent with a
Supersequence 1 age (Grey and Stevens 1997) (Figs 5 and 6) In outcrop the Cornelia Formation
17
consists predominantly of sandstone and quartzite with lesser siltstone shale mudstone and chert
In Trainor 1 this formation consists predominantly of indurated mudstone with minor sandstone
chert and dolomite A major erosional unconformity separates the Cornelia Formation from
overlying formations and parts of the Cornelia Formation have been folded with dips exceeding
70deg In contrast the majority of the Savory Sub-basin sedimentary rocks have dips of less than 30deg
except where they are adjacent to faults The Cornelia Formation apparently consists of an older
unit of steeply dipping quartzites cherts and well-indurated mudstones and a younger unit of
shallower dipping sandstones which are sub-friable in parts However caution should be used in
interpreting the age of units based on their structural deformation and additional mapping and age
dating of this formation is required
It is proposed here that the Kahrban Subgroup is likely to be of early Neoproterozoic age and
hence should be considered as part of the greater Officer Basin This proposal is based largely on
the relatively low dip of the strata (generally less than 20deg) and their west-northwest strike which
is parallel with strikes in the overlying Brassey Range Formation of the Savory Group The lower
contact of the Kahrban Subgroup is obscured but is thought to be an unconfirmity on the
Earaheedy Basin on the southeast of STANLEY (Muhling and Brakel 1985)
Structural setting
The Savory Sub-basin forms the most northwesterly sub-basin of the Neoproterozoic to
Phanerozoic Officer Basin The western boundary of the sub-basin with the Mesoproterozoic
Bangemall Basin consists of steep-reverse and strike-slip faults The northeastern boundary of the
Savory Sub-basin was mapped where Supersequence 4 formations of the Savory Group
unconformably overlie sedimentary rocks of the Karara and Yeneena Basins with the two older
units considered to be part of the Paterson Orogen (Williams 1992) This contact was defined as a
series of steeply dipping reverse faults in the northernmost parts of the sub-basin on BALFOUR
DOWNS and RUDALL and was extrapolated as an inferred reverse fault farther along strike to the
southeast on GUNANYA and MADLEY where the contact is obscured by Cainozoic sediments It is
now recognized that all the sedimentary rocks in the Karara Basin and younger sedimentary rocks
of the Yeneena Basin are from the Supersequence 1 Tarcunyah Group and part of the greater
Officer Basin (Bagas et al 1995) The northern boundary of the Tarcunyah Group and the greater
Officer Basin is in thrust-and reverse-faulted contact with the Rudall Complex and other parts of
the Paterson Orogen (Fig 7)
To the south the sub-basin unconformably overlies the Bangemall Basin The eastern
boundary of the sub-basin used in this study is where Permian and younger strata of the Officer
Basin unconformably overlie Neoproterozoic strata although there are no significant structural or
stratigraphic differences between the Neoproterozoic units
18
The sub-basin is subdivided into three principal structural areas (Fig 1) Trainor Platform
Blake Fault and Fold Belt and Wells Foreland Sub-basin (Williams 1992) A major review of
these boundaries is beyond the scope of this report but the processing of regional aeromagnetic
data (Appendix 4) and acquisition of a semi-detailed gravity survey by the GSWA in the east of
the sub-basin has enabled these tectonic units to be reassessed and some modifications are
proposed
The Wells Foreland Sub-basin (originally termed the Wells Foreland Basin in Williams 1992)
and sedimentary rocks of the Tarcunyah Group are both considered to be the northwest
continuation of the Gibson Sub-basin of the Officer Basin Aeromagnetic gravity and outcrop
data suggest that the Blake Fault and Fold Belt is significantly faulted and folded in the west but
is less deformed in the east where the thickest sedimentary section in is located on BULLEN
(Appendix 4) The Trainor Platform is reinterpreted to represent an area of the sub-basin that has
undergone major compression during the Petermann Ranges Orogeny resulting in folding and
faulting with a northwest strike This interpretation contrasts with that proposed by Williams
(1992) who envisaged that only a thin section of the Savory Group was present on the platform
Perincek (1998) has recognized nine periods of tectonic activity in the Officer Basin from the
beginning of the Neoproterozoic to the end of the Cretaceous Three major tectonic episodes are
recognized in the Centralian Superbasin The oldest event is the Areyonga Movement which is
pre-Sturtian and forms the boundary between Supersequences 1 and 2 (Fig 4) The Souths Range
Movement occurred at the end of the Sturtian at the boundary between Supersequences 2 and 3
The youngest major event is the Petermann Ranges Orogeny which occured at the end of the
Marinoan and forms the boundary between Supersequences 3 and 4
One minor and two major tectonic episodes are recognized in the Savory Sub-basin the
LP1ALP1B structural event and the Areyonga Movement and the Petermann Ranges Orogeny
respectively The LP1ALP1B structural event is revealed where the Spearhole Formations rests
disconformably and locally unconformably on the Brassey Range Jilyili and Glass Spring
Formations The Neoproterozoic Areyonga Movement (equivalent to the Blake Movement of
Williams 1992) produced folds and faults with a general northeast strike in the western and
southern parts of the region The Souths Range Movement has not been recognized in the sub-
basin This may be due to the fact that no Sturtian glacial rocks have been identified and hence it
is possible that structures attributed to the Areyonga Movement could be the result of the Souths
Range Movement or a combination of the two movements
The major tectonic event recorded in the sub-basin is the latest Neoproterozoic to Cambrian
Petermann Ranges Orogeny (equivalent to the Paterson Orogeny) which produced large reverse
19
faults thrusts strike-slip faults and folds with a general northwest strike The McFadden
Formation and other Supersequence 4 strata are considered to be at least partially coeval with this
orogeny (Williams 1992) We also interpret the Durba Sandstone as having been deposited during
the later stages of the Petermann Ranges Orogeny as this unit mildly deformed with fold axes
parallel to the strike of other structures attributed to the Petermann Ranges Orogeny
Quantitative aeromagnetic interpretation of the Savory Sub-basin utilizing the 3D Euler
deconvolution method supported by wave-number filtering and image processing has provided
structural trends and depth to magnetic source within the sub-basin (Cowan 1995) Gravity data
are interpreted by Cowan (1995) as changes in both the density of the basement rocks andor
basement topography depending on local conditions Part of Cowanrsquos report is reproduced in
Appendix 4
Exploration history
The only petroleum exploration conducted in the sub-basin has been the recent drilling in the
western part of three diamond drillholes of which two have minor oil shows (Table 2) There has
been some mineral exploration the results of which are stored in the GSWA Western Australian
Mineral Exploration (WAMEX) database system Much of the mineral exploration was in the
southwest and west where the sub-basin is in contact with the Bangemall Basin and along the
northern margin of the sub-basin Many of these mineral exploration programs included
aeromagnetic surveys and surface geochemical sampling (Fig 8)
Hydrocarbon potential
The sub-basin contains a sedimentary succession up to 8 km thick which is generally gently
folded and faulted and apparently unmetamorphosed Limited drilling has shown that thick
mudstones are present in the sub-basin with some mudstones in Trainor 1 having high Total
Organic Carbon (TOC) values Outcrops of sub-friable sandstones in many of the formations
within the sub-basin suggests widespread reservoir potential Mudstone and inferred thick
evaporite sequences are likely to form seals Maturity data suggest that near-surface samples are
approximately at the base of the oil window and top of the gas window in parts of the north and
southeast of the sub-basin However parts of the southwest of the sub-basin and the mudstones in
Trainor 1 have very high levels of maturity Numerous faults and folds have been identified from
surface mapping suggesting good potential for large structural traps Minor oil shows in
20
Table 2 Neoproterozoic formations and hydrocarbon shows in diamond drillholes in the Savory Sub-basin
Drillhole AMG Core TD (m) Approx Formation Depth Formation Depth Formation Depth Shows (AGD84) start (m) GL (m) (m) (m) (m)
LDDH 1 431148E 112 701 350 Tarcunyah 68ndash701 ndash ndash bitumen at 6623 m 7443826N Group Trainor 1 473640E 6 709 455 McFadden 9ndash83 Cornelia Fm 83ndash709 possible bitumen at 4537 m 7287400N Fm Mundadjini 1 319056E 170 600 500 Mundadjini 16ndash361 Spearhole Fm 361ndash600 10 fluorescence at 36102 m 7404844N Fm Boondawari 1 348959E 299 1 367 490 Mundadjini Fm 15ndash312 Spearhole Fm 312ndash1 283 Intrusive 1 283ndash1 367 40 fluorescence at 35364 m 5 7398174N fluorescence at 4963 m Akubra 1 334249E 15 181 530 Mundadjini 15ndash42 Intrusive 42ndash181 None 7401252N Fm
21
50 km
120deg 121deg30 123deg
25deg
24deg
23deg
22deg
Greater Officer Basin
Savory Sub-basin
1
2
3
4
6
8
3 Seismic line (prefixed N83-00)
Aeromagnetic survey
GS
WA
Sav
ory
1995
gra
vity
sur
vey
Gravity survey
MKS34270398
Figure 8 Locations of aeromagnetic and gravity surveys (other than regional BMRAGSO data)
22
sandstones in two petroleum wells in the northwest of the sub-basin and bitumen and oil shows
elsewhere in the region indicate that oil has been generated and migrated through the sub-basin
Source rocks
Source potential is considered to be the major exploration risk in the Savory Sub-basin although
minor oil shows in Mundadjini 1 and Boondawari 1 indicate that at least some oil has been
generated and migrated into potential reservoirs within the sub-basin Sandstone is the
predominant lithology observed in outcrop Outcrops of fine-grained lithologies in the basin are
rare because of intense surface weathering and erosion Only about 8 of the surface area of the
sub-basin is exposed bedrock and recessive lithologies (such as shale evaporite and friable
sandstone) may be present although they rarely outcrop
Outcrops of stromatolitic dolomite with associated cauliflower chert and cubic pseudomorphs
interpreted as being after halite indicate that evaporitic environments are present within the
Mundadjini Skates Hills and Boondawari Formations Evaporitic minerals are also present in
drillhole LDDH1 in the Tarcunyah Group
In 1995 GSWA drilled a continuous-core diamond drillhole (Trainor 1) in the sub-basin on
TRAINOR to a depth of 709 m to test for source rocks thus providing the first such data for the sub-
basin The drillhole intersected flat-lying clastics and carbonates of the McFadden Formation (9ndash
83 m) overlying indurated mudstones of the Cornelia Formation (83ndash709 m total depth) dipping at
about 40deg Of the six samples analysed from the Cornelia Formation in this drillhole the five
located between 375 and 6032 m depth have TOC values exceeding 05 (range 066ndash365)
Rock-Eval pyrolysis of these five samples indicates that they are at best in the dry-gas thermal
stage and as a result of their high level of maturation (Stevens and Adamides in prep) have poor
remaining hydrocarbon-generating potential Although the Cornelia Formation is overmature at
Trainor 1 the high TOC values are encouraging as it is likely that this sequence is less mature
elsewhere in the sub-basin
The Mundadjini Formation contains potential source rocks that comprise marine mudstones
with evaporitic minerals present in parts Thin dark mudstones were intersected in the Mundadjini
Formation in Akubra 1 In Mundadjini 1 and Boondawari 1 however the mudstones appear to be
too oxidized to have source potential
The Boondawari Formation also may be a source rock as it contains black mudstones The
unit is laterally equivalent to the Pertatataka Formation of the Amadeus Basin and the Ungoolya
23
Group of the Officer Basin in South Australia both of which have some source potential
(Summons and Powell 1991 Morton and Drexel 1997) Samples from the Dey Dey Mudstone of
the Ungoolya Group generally have poor TOC values (average 011 range 003ndash081)
moderate hydrogen index (HI) values (100ndash382) and poor to fair genetic potential with a
maximum of 292 kg hydrocarbon per tonne of source rock (Morton and Drexel 1997)
Stromatolitic dolomites and mudstones at the top of the Boondawari Formation and within the
Skates Hills Formation are potential source rocks Stromatolitic dolomite and evaporitic rocks
deposited in a marginal marine to sabkha environment are considered to have good potential to
generate and preserve organic carbon without requiring a deep-water setting (Stevens and Grey
1997) Such conditions are recognized in the Skates Hills Formation and in the upper parts of the
Tarcunyah Group
Maturity
Knowledge of the maturity of sedimentary rocks within the Savory Sub-basin is still limited From
a review of palynological studies Grey and Stevens (1997) report that the thermal maturity
inferred from the Thermal Alteration Index (TAI) of 3+ from Supersequence 1 age palynomorphs
in TWB 6 TWB 9 and LDDH1 is within the hydrocarbon window (Appendix 3) In Phanerozoic
spores and pollen a TAI of 3+ approximately equates to the end of liquid petroleum generation
and the start of dry gas generation and to a vitrinite reflectance of about 13 (Traverse 1988)
However the use of TAI for estimating thermal maturity from Neoproterozoic palynomorphs
requires calibration
In Trainor 1 the Cornelia Formation contains organically rich claystones between 375 and
6032 m depth Based on Rock-Eval maturity data (Stevens and Adamides in prep) and the dark
colour of poorly preserved organic material (Grey 1995de 1996) with TAI 4- to 5 all samples
had a high level of maturation with at best dry-gas generating potential remaining In contrast
drillhole LDDH1 on GUNANYA recorded lower levels of maturity (TAI values of 3+) with two of
sixteen samples from the Tarcunyah Group having greater than 1 TOC (Grey 1995abc Grey
and Cotter 1996) Organic petrology and Rock-Eval maturity data for samples from LDDH1
indicate that the section above 500 m is within the oil-generative window whereas below 500 m
the rocks are within the gas window (Ghori in prep Fig 9 Appendix 5)
Waterbores TWB 1 2 6 and 9 which are located on TRAINOR in the southeast of the sub-
basin all had organic matter with TAI values of 3+ from the McFadden Skates Hills Cornelia
and Brassey Range Formations respectively
24
100
200
300
400
500
600
700
Oil
gene
ratin
g
Gas
gene
ratin
g
Fai
r
Fai
r
Poo
r
Poo
r
Goo
d
Imm
atur
e
Oil
win
dow
Oil
win
dow
Imm
atur
e
01 0110 10 0 150 300 440 480 1
Neo
prot
eroz
oic
TOC S1+S2 mgg Hydrogen Index Tmax degC
Depth(m)
Organicrichness
Generatingpotential
Kerogentype Maturity Maturity
TD=701m
Sandstone
Mudstone
Dolomite
Limestone
Evaporite
Source rock
MKS40 070498
Ro equivalent
Figure 9 Petroleum source potential of rocks in Normandy LDDH1
Small amounts of organic matter associated with basalt and dolerite in cuttings from
waterbore BWB 1 on BULLEN showed high levels of thermal maturity (Grey 1995a Libby 1995)
It is unclear whether all sedimentary rocks on BULLEN are overmature for hydrocarbon generation
or the results from BWB 1 are related to local heating events associated with the volcanic bodies
that are common in the Jilyili Formation
25
Reservoirs
Each of the five depositional sequences of the Savory Group (Table 1) are inferred to contain
significant sandstone reservoirs with the possible exception of depositional sequence C as
discussed above in Stratigraphy The Spearhole Formation was cored in Mundadjini 1 and
Boondawari 1 and visual estimates of porosity vary from generally poor (less than 5) to fair
(approximately 5ndash15) The McFadden Formation in Trainor 1 has porosity values of up to 232
and a maximum permeability of 195 md (Stevens and Adamides in prep) Sandstones from
Neoproterozoic formations form the acquifers in the following waterbores the McFadden
Formation in TWB 1 the Cornelia Formation in TWB 6 and the Brassey Range Formation in
TWB 8 and TWB 9 (Appendix 6 Table 61)
Based on outcrop observations the Durba Sandstone is considered to be the best reservoir of
the Savory Group Similarly some sandstones from the Tarcunyah Group also have good visible
porosity in outcrop
Dolomites occur in several formations in the sub-basin Reservoir potential may exist
particularly where the dolomites are stromatolitic and oolitic However dolomites have not been
drilled in the sub-basin and porosity can only be inferred from the preferential silicification of
some stromatolite bioherms observed in outcrop (Stevens and Grey 1997) Elsewhere in the
Officer Basin porosities of up to10 have been measured in dolomites A limestone breccia
(karst) is described from 663 to 677 m in drillhole LDDH1 (Fig 6 Busbridge 1994)
Seals
Indications of evaporitic environments in the Mundadjini Skates Hills and Boondawari
Formations are described by Williams (1992) In Mundadjini 1 from 287 to 337 m anhydrite and
chert occurs as nodules beds and veins in mudstone of the Mundadjini Formation Evaporitic
minerals (predominantly gypsum) are described in the Tarcunyah Group in LDDH1 The presence
of the Woolnough and Madley salt diapirs in the Officer Basin (approximately 110 km east of the
sub-basin) and halite beds over 25 m thick in the well Hussar 1 (130 km east of the sub-basin)
provide further evidence that evaporite seals may be present in the Savory Sub-basin
Mudstones and shales form only a small proportion of the limited Neoproterozoic outcrop in
the sub-basin but significant thicknesses of mudstone were encountered in the Mundadjini
Formation in Mundadjini 1 and Boondawari 1 the Tarcunyah Group in LDDH1 and in the
26
Cornelia Formation in Trainor 1 These data suggest that mudstones form a significant proportion
of strata in the sub-basin despite their limited outcrop
Traps
Potential structural closures including folds and faults occur at various scales throughout the
Savory Sub-basin However the region has only been mapped at 1250 000 scale and
independently closed structures such as domes have yet to be confirmed The western margin of
the basin contains abundant faults (with a northeast strike) but elsewhere faults are less common
Some anticlines are recognized in outcrop including one with a strike length of up to 45 km
inferred from surface bedding dips in the Mundadjini and Spearhole Formations at approximately
24deg15rsquoS 121deg10rsquoE on BULLEN (Fig 1)
Salt diapirs and other halokinetic structures are recognized in outcrop well and seismic data
in the Officer Basin to the west of the Savory Sub-basin and it is probable that there are
significant thicknesses of evaporitic sedimentary rocks in the sub-basin The gravity field data
suggest there is good potential for salt diapirs and traps related to halokinesis
Although there is potential for stratigraphic traps to be present in the sub-basin insufficient
data are available to assess them
Preservation of hydrocarbons
The range of thermal maturities measured to date and the large periods of time envisaged for
deposition of sediments implies hydrocarbon generation may have occurred a number of times
during the evolution of the Savory Sub-basin Any hydrocarbons that were generated early may
have been trapped in palaeostructures and remigration to younger traps could have taken place
later The Petermann Ranges Orogeny which has been equated with the Paterson Orogeny (Myers
1990) is believed to have occurred in the latest Neoproterozoic to early Cambrian This is the last
major tectonic event recognized in the sub-basin suggesting that it is reasonable to expect that trap
integrity will have been preserved
If the inference of the presence of thick halite beds in the sub-basin is correct the preservation
potential of sub-salt traps should be excellent
27
Reported hydrocarbon shows and oil seep
Amadeus Petroleum recorded minor oil shows in cores from Mundadjini 1 and Boondawari 1 In
Mundadjini 1 at 36102 m (top of the Spearhole Formation) a 3 mm thick zone had 10 moderate
white fluorescence with slow solvent cut This show was in a granular sandstone with visually
estimated porosity of about 10 In Boondawari 1 at 35364 m (within the Spearhole Formation) a
broken surface of sandstone had 40 moderate yellow-white fluorescence with slow solvent cut
Visually estimated porosity is about 5 Because the fluorescing surface was broken during the
drilling process this show could have resulted from contamination A second show occurs in
Boondawari 1 at 4963 m (within the Spearhole Formation) where a 1 cm-thick zone had 5 dull
yellow fluorescence with slow solvent cut in a conglomerate with visually estimated porosity of
about 10 The company intends to further investigate the nature of these occurrences
Minor bitumen is present at 6623 m in drillhole LDDH1 on GUNANYA (Figs 5 and 6) as a
vein in mudstones of the Tarcunyah Group A sample was analysed by gas chromatography
(Ghori in prep) and confirmed that it is natural bitumen (Appendix 5)
Mineral hole OD 23 drilled by Jubilee Gold Mines NL on NABBERU in the Bangemall Basin
immediately to the south of the Savory Sub-basin (Fig 5) encountered bitumen and trace oil in
vugs in dolomite (M Stevens unpublished data) but no further data are available at present
In their popular guide to the Canning Stock Route Gard and Gard (1990 p 218) refer to an
oil seep at Well 13 on TRAINOR (Fig 5) They reported that between 1977 and 1984 lsquonatural oilrsquo
was seen in the well Although the well is now largely filled with sediment four auger drill
samples were collected by the GSWA in 1995 and all four were analysed for oil shows One
sample from 315 m total depth (GSWA sample 135604) yielded just enough extract (519 ppm)
for saturate gas chromatography analysis The gas chromatograph (Appendix 5) shows that the
extract does contain some hydrocarbons probably from recent plant material Because the depth to
the oil was not quoted in Gard and Gard (1990) the hand-augered well may not have been deep
enough to properly test this reported seep
Geological and geophysical databases
Geological and geophysical data available for the Savory Sub-basin are limited The most recently
completed geological maps for the sub-basin were published by the GSWA between 1991 and
1995 (Williams and Tyler 1991 Williams 1992 1995ab)
28
The cores from the five drillholes listed in Table 2 believed to be all of the core available
from the sub-basin are available for inspection at GSWA Mineral exploration reports submitted
to GSWA may be searched using the WAMEX database and open-file reports are available on
microfiche Geophysical data acquired by the mining industry is not required to be filed with
GSWA if acquired over Vacant Crown Land which is the case for much of the sub-basin
Geophysical survey data submitted in mining tenement reports and which extend into Vacant
Crown Land remain confidential to the companies Original regional aeromagnetic and gravity
datasets are available from the Australian Geological Survey Organisation (AGSO)
Data pertinent to oil exploration in the sub-basin such as structural style and salt diapirism
are presented in a review of the hydrocarbon prospectivity of the Officer Basin (Perincek 1998)
Drilling
Significant drillholes in the sub-basin are summarized in Table 2
Petroleum industry data
Amadeus Petroleum drilled three petroleum exploration wells in the central west of the Savory
Sub-basin in late 1997 These wells Mundadjini 1 Boondawari 1 and Akubra 1 were drilled by
continuous diamond coring (Figs 5 and 6) All targeted potential reservoirs within the Spearhole
Formation with the Mundadjini Formation as the proposed seal The wells were located on
structures interpreted from Landsat images and limited geological investigations Both Mundadjini
1 and Boondawari 1 had minor oil shows as discussed above (Reported hydrocarbon shows)
Government data
Stratigraphic drillhole Trainor 1 was drilled by GSWA in 1995 (Stevens and Adamides in prep)
and the main results are discussed above (Source rocks and Maturity)
Mineral industry data
Normandy Exploration drillhole LDDH1 was cored in the Tarcunyah Group to a total depth of
701 m and provided source-rock and maturity data as discussed above
29
Oilmin NL drilled six percussion drillholes (BD 1 3 4 5 8 and 9) through sandstones and
shales in the northern part of the Savory Sub-basin to a maximum depth of 198 m (Fig 5
WAMEX Microfiche File M 26811 I 2610) but only brief geological descriptions are available
Hydrogeological data
Hydrogeological data within the Savory Sub-basin are limited although a long history of water
exploration extends back to the construction of the Canning Stock Route early this century No
detailed geological or wireline logs are available for the older wells along this route A few station
wells have been drilled by various methods on the south and west margins of the basin but data
are unavailable as reports are not required to be filed with the government Depth to watertable
throughout the basin is largely controlled by porosity of the bedrock
The GSWA drilled fifteen waterbores in the winter of 1995 in the southern part of the sub-
basin in preparation for the drilling of Trainor 1 and the proposed Bullen 1 Twelve bores found
water and six of these bores have salinities of less than 1000 mgL (Fig 5 Appendix 6 Table 61)
One waterbore TWB 6 has gamma ray and neutron logs run through PVC casing and these are
available from the GSWA with the digital log data included herein
Seismic data
No geophysical data have been acquired by the petroleum industry in the Savory Sub-basin
Seismic data acquired in the Officer Basin to the east particularly in the Gibson and Yowalga
Sub-basins is pertinent to structural interpretation in the Savory Sub-basin (Perincek 1996a
1998)
Aeromagnetic surveys
Government data
There are over 95 277 line kilometres of aeromagnetic data included in the AGSO dataset There
are three regional aeromagnetic surveys covering the Savory Sub-basin These were flown by the
Bureau of Mineral Resources (BMR now AGSO) in 1984 at a line spacing of 1500 m with 36 740
and 52 587 line kilometres flown and by Aerodata in 1984 at a line spacing of 1000m with 5950
line kilometres flown These data were reprocessed and interpreted for GSWA by Cowan (1995)
An edited copy of this report is included as Appendix 4 and the original report is filed in the
GSWA Library under S-series reports item 10331
30
Mineral industry data
The approximate locations of non-AGSO aeromagnetic surveys are shown in Figure 8 More
detailed information regarding the location of these surveys may be obtained using the GSWA
MAGCAT II database Additional information such as contours of aeromagnetic values may be
obtained by inspecting items on file with the GSWA
Gravity surveys
Government data
The average spacing for gravity data in the Savory Sub-basin is one station per 121 km2 (11 times 11
km grid) These data were principally collected by BMR in the early 1960s There are a few
additional regional gravity traverses across the sub-basin which are also included in the
BMRAGSO dataset These data were reprocessed and interpreted for GSWA (Fig 10) and a
report on this work is also included in Appendix 4
The GSWA completed a large semi-detailed gravity survey in the eastern Savory Sub-basin
utilizing helicopter support and Differential Global Positioning Survey (DGPS) techniques (Fig
8) This gravity survey completed in August 1995 consists of 2300 gravity stations on a 2 times 3 km
grid All stations were acquired by helicopter using Scintrex gravimeters and Ashtek dual
frequency DGPS equipment for determining location This highly efficient system allowed the
acquisition of more than 100 gravity stations per day in remote areas The resolution of this survey
is +30 cm and +05 microms-2 (Daishsat 1995) These data (Fig 11) represent a significant
improvement on the previous regional survey data and are available from GSWA (GSWA
1996ab) The results of the interpretation of these data were presented at the 1997 ASEG
Convention (Carlsen and Shevchenko 1997)
Mineral industry data
Three small gravity surveys were conducted by Oilmin NL (Fig 8) and the relevant WAMEX
reports are M 2681I 2610 I 2435 I 2567 These three surveys are of limited value because height
control was provided by barometers only and the surveys were not tied to the national gravity grid
31
23deg
25deg
120deg 122deg
Trainor 1
SAVORY
SUB-BASIN
MKS54 160498
100 km
1995 SavoryGravity Survey
254
-1056
micromsec2
Figure 10 Regional Bouguer gravity map of the Savory Sub-basin
23deg
24deg
25deg
122deg30 123deg
TRAINOR 1
123deg30
50 km
MKS53 160498
-116
-626
micro msec2
Figure11 Detailed Bouguer gravity map of the
Savory 1995 Gravity Survey from the eastern Savory Sub-basin
32
Government and academic reports
Chronostratigraphy and geochemistry
The understanding of Neoproterozoic organic chemistry palynology and structural evolution is
essential to the interpretation of hydrocarbon prospectivity Pertinent reports are included in the
bibliography (Appendix 1) Unpublished palaeontology reports describe the palynology of wells in
the Savory Sub-basin (Grey 1995andashe 1996a) Grey and Cotter (1996) discussed the potential for
Neoproterozoic palynomorphs to provide a biostratigraphic framework and palaeoenvironmental
interpretation Grey and Stevens (1997) reviewed the results of palynological studies of wells
drilled in the sub-basin and reported that Supersequence 1 palynomorphs are present in TWB 6
TWB 9 and LDDH1 (Appendix 3) Grey (1996b) reported on the use of stromatolites for
correlation in the Neoproterozoic and Stevens and Grey (1997) discussed the application of
stromatolite biostratigraphy in correlating isolated dolomite outcrops in the sub-basin with well
and seismic data in the Officer Basin and Centralian Superbasin
Although geochemical data from the Savory Sub-basin are very limited results mostly
confirm thermal maturities inferred from TAI for LDDH1 and Trainor 1 (Ghori in prep Stevens
and Adamides in prep) Those parts of the Officer Basin in Western Australia which lie to the
east of the Savory Sub-basin are sparsely drilled but Ghori (in prep) reports that most of the
Neoproterozoic succession presently lies within the oil-generative window However his study
has been unable to identify effective source-rock units and the source for oil shows Thin source
rocks are present in the Neoproterozoic in LDDH1 (Fig 9) and in three wells which lie to the east
and southeast of the Savory Sub-basin namely NJD 1 Kanpa 1A and Yowalga 3
Proposed work program
From the above limited information it is concluded that additional research on the hydrocarbon
potential of the sub-basin is justified and proposals are outlined below
bull Additional modelling of gravity and aeromagnetic data from the Savory Sub-basin is required
in light of the results from Trainor 1 and Boondawari 1 Trainor 1 showed that what appeared
to be a structurally simple area based on outcrop aeromagnetic and gravity data was in fact an
area of major structuring Boondawari 1 intersected a dolerite which is in good depth
agreement with aeromagnetic depth to source results showing this technique is useful in
detecting the depth to intrusive bodies
33
bull Additional data from mineral and petroleum exploration bores may become available and
analysis of samples from these wells should be undertaken and interpreted in the context of
their relevance to the Officer Basin
bull Stratigraphic coring in the Blake Fault and Fold Belt and in the Wells Foreland Sub-basin (Fig
1) targeting source rocks is considered essential to the continuing evaluation of the
hydrocarbon prospectivity of the Savory Sub-basin
bull Correlations using at least outcrop well and potential-field data should be prepared to link the
sub-basin with the better known parts of the Officer Basin to the east
bull Remapping is required to clarify boundary positions within the Cornelia Formation this may
resolve some of the current problems of the relationship between this unit and the rest of the
Savory Sub-basin
bull Further work is required to explain the Early Cambrian or Sturtian ages interpreted for the
Cornelia Formation from sedimentary zircon UndashPb dating in drillhole Trainor 1 The
determination of the age of the organically rich but overmature claystones in this well is
critical to assessing the hydrocarbon potential of the region
bull The thin dark mudstones intersected by Akubra 1 in the Mundadjini Formation warrant
geochemical analysis Analyses of the oil shows in Mundadjini 1 and Boondawari 1 are
currently being undertaken by Amadeus Petroleum
bull Geochemical analysis of hydrocarbons in the Bangemall Basin drillhole OD23 has been
performed by Jubilee Gold and the results will be reviewed when they are submitted to
GSWA The possibility of source rocks within the Bangemall Basin charging traps within the
Bangemall Basin and the overlying Savory Sub-basin requires further investigation
Conclusions
The Savory Sub-basin is a frontier region with only three recently drilled petroleum exploration
wells and no seismic data Based on existing geological and geophysical data it is considered too
early to draw conclusions about the hydrocarbon prospectivity of the sub-basin at this stage and
there are several reasons why the area warrants further investigation
34
1 Thick accumulations of sedimentary rocks are present (up to 8 km thickness inferred) which
may contain source reservoir and sealing strata
2 Minor oil shows occur in Mundadjini 1 and Boondawari 1 and bitumen is present in mineral
exploration drillhole LDDH1 suggesting that hydrocarbons have migrated within the
Neoproterozoic sequence of the Savory Sub-basin Oil and bitumen are present in mineral
exploration drillhole OD23 in the Bangemall Basin immediately to the south of the Savory
Sub-basin and it is possible that source rocks from the Bangemall Basin could charge traps in
the overlying Savory Sub-basin
3 The age of sedimentary rocks in the sub-basin is still poorly constrained but some of the
Neoproterozoic sedimentary rocks located on GUNANYA and TRAINOR are within the
hydrocarbon-generation window It is possible that a significant thickness of Phanerozoic
sedimentary rocks may also be present
4 Friable sandstones with visible porosity outcrop extensively suggesting numerous potential
reservoirs
5 Significant but not intense faulting and folding has been mapped implying large structural
traps may be present
6 Evaporitic sedimentary rocks occur in several formations and may provide good source rocks
and excellent seals
35
References
APAK S N and CARLSEN G M 1997 A compilation and review of data pertaining to the
hydrocarbon prospectivity of the Canning Basin Western Australia Geological Survey
Record 199610 103p
BAGAS L GREY K and WILLIAMS I R 1995 Reappraisal of the Paterson Orogen and
Savory Basin Western Australia Geological Survey Annual Review 1994ndash95 p 55ndash63
BUSBRIDGE M 1994 Lake Disappointment Exploration Licence 451064 Third Annual
Report Lake Disappointment Diamond Drill Hole LDDH1 Normandy Exploration Limited
Western Australia Geological Survey M-series Item 7567 A41358 (unpublished)
CARLSEN G M and SHEVCHENKO S I 1997 Petroleum exploration in Proterozoic basins
using potential fields data and stratigraphic coring Australian Society of Exploration
Geophysicists 12th Geophysical Conference Handbook Sydney 1997 Preview no 66 p 83
(abstract only)
COWAN D 1995 Savory Basin quantitative magnetic interpretation Western Australia
Geological Survey S-series S10331 (unpublished)
DAISHSAT PTY LTD 1995 Operational and processing report Savory Basin gravity survey
Western Australia Geological Survey S-series S10332 (unpublished)
GARD E and GARD R 1990 Canning Stock Route a travellerrsquos guide for a journey through
history Perth Western Australia Western Desert Guides 448p
GEOLOGICAL SURVEY OF WESTERN AUSTRALIA 1996a Savory Basin first vertical
derivative of Bouguer gravity image 1250 000 Western Australia Geological Survey
GEOLOGICAL SURVEY OF WESTERN AUSTRALIA 1996b Savory Basin Bouguer gravity
image 1250 000 Western Australia Geological Survey
GHORI K A R in prep Petroleum source rock potential and thermal history Officer Basin
Western Australia Western Australia Geological Survey Record
36
GREY K 1995a Savory Basin drillhole BWB 1 (Bullen waterbore) palynology and thermal
maturation GSWA Palaeontology Report no 199512 (unpublished)
GREY K 1995b Savory Basin drillholes TWB 1 2 6 9 (Trainor waterbores) palynology and
thermal maturation GSWA Palaeontology Report no 199520 (unpublished)
GREY K 1995c Palynology of Normandy-Poseidon Lake Disappointment-1 corehole
Tarcunyah Group Paterson Orogen GSWA Palaeontology Report no 199521 (unpublished)
GREY K 1995d Savory Basin drillhole Trainor 1 (Trainor diamond drilling) palynology and
thermal maturity GSWA Palaeontology Report no 199524 (unpublished)
GREY K 1995e Savory Basin drillhole Trainor 1 (Trainor diamond drilling) Additional
Preparation of two samples GSWA Palaeontology Report no 199528 (unpublished)
GREY K 1995f Neoproterozoic stromatolites from the Skates Hills Formation Savory Basin
Western Australia and a review of the distribution of Acaciella australica Australian Journal
of Earth Sciences v 42 p 123ndash132
GREY K 1996a Savory Basin drillhole Trainor 1 (Trainor diamond drilling) Additional
samples palynology and thermal maturation GSWA Palaeontology Report no 199615
(unpublished)
GREY K 1996b Preliminary stromatolite correlations for the Neoproterozoic of the Officer
Basin and a review of Australia-wide correlations GSWA Palaeontology Report no 199615
(unpublished)
GREY K and COTTER K L 1996 Palynology in the search for Proterozoic hydrocarbons
Western Australia Geological Survey Annual Review for 1995ndash96 p 70ndash80
GREY K and STEVENS M K 1997 Neoproterozoic palynomorphs of the Savory Sub-basin
Western Australia and their relevance to petroleum exploration Western Australia
Geological Survey Annual Review for 1996ndash97 p 49ndash54
HUBBARD R J PAPE J and ROBERTS D G 1985 Depositional sequence mapping as a
technique to establish tectonic and stratigraphic framework and evaluate hydrocarbon
potential on a passive continental margin in Seismic stratigraphy II an integrated approach
37
edited by O R BERG and D G WOOLVERTON American Association of Petroleum
Geologists Memoir 39 p 79ndash91
LIBBY WG 1995 A petrological report on six samples of bore cuttings from the Savory Basin
Western Australia Western Australia Geological Survey S-series S31307 (unpublished)
MORTON JGG and DREXEL JF 1997 The petroleum geology of South Australia Vol 3
Officer Basin South Australia Department of Mines and Energy Resources Report Book
9719
MUHLING P C and BRAKEL A T 1985 Geology of the Bangemall Group mdash the evolution
of an intracratonic Proterozoic basin Western Australia Geological Survey Bulletin 128
219p
MYERS J S 1990 Precambrian tectonic evolution of part of Gondwana southwestern Australia
Geology v18 p 537ndash540
NELSON D R 1997 Compilation of SHRIMP UndashPb zircon data Western Australia Geological
Survey Record 19972 196p
PAYTON C E 1977 Seismic stratigraphy mdash applications to hydrocarbon exploration
American Association of Petroleum Geologists Memoir 26 516p
PERINCEK D 1996a The age of NeoproterozoicndashPalaeozoic sediments within the Officer Basin
of the Centralian Super-basin can be constrained by major sequence-bounding unconformities
APPEA Journal v 36 pt 1 p 350ndash368
PERINCEK D 1996b The stratigraphic and structural development of the Officer Basin
Western Australia a review Western Australia Geological Survey Annual Review 1995ndash
1996 p 135ndash148
PERINCEK D 1998 A compilation and review of data pertaining to the hydrocarbon
prospectivity of the Officer Basin Western Australia Geological Survey Record 19976
POSAMENTIER H W JERSEY M T and VAIL P R 1988 Eustatic controls on clastic
deposition 1 mdash Conceptual framework in Sea-level changes an integrated approach edited by
C K WILGUS B S HASTINGS C G St C KENDALL H W POSAMENTIER
38
C A ROSS and J C VAN WAGONER Society of Economic Paleontologists and
Mineralogists Special Publication no 42
STEVENS M K and ADAMIDES N G in prep GSWA Trainor 1 well completion report
Savory Sub-basin Officer Basin Western Australia with notes on petroleum and mineral
potential Western Australia Geological Survey Record 199612
STEVENS M K and GREY K 1997 Skates Hills Formation and Tarcunyah Group Officer
Basin mdash carbonate cycles stratigraphic position and hydrocarbon prospectivity Western
Australia Geological Survey Annual Review for 1996ndash97 p 55ndash60
SUMMONS RE and POWELL C McA 1991 Petroleum source rocks of the Amadeus Basin
in Geological and geophysical studies in the Amadeus Basin central Australia edited by R J
KORSCH and JM KENNARD Australia BMR Geology and Geophysics Bulletin 236
TRAVERSE A 1988 Palaeopalynology Boston Unwin Hyman 600p
VAIL P R MITCHUM R M Jr TODD R G WIDMIER J M THOMPSON S III
SANGREE J B BUBB J N and HATLELID W G 1977 Seismic stratigraphy and
global changes of sea level in Seismic stratigraphy mdash applications to hydrocarbon
exploration edited by C E PAYTON American Association of Petroleum Geologists
Memoir 26 516p
WALTER M R and GORTER J 1994 The Neoproterozoic Centralian Superbasin in Western
Australia the Savory and Officer Basins in The sedimentary basins of Western Australia
edited by P G PURCELL and R R PURCELL Petroleum Exploration Society of Australia
Symposium Perth WA 1994 Proceedings p851ndash864
WALTER M R GREY K WILLIAMS I R and CALVER C R 1994 Stratigraphy of the
Neoproterozoic to early Palaeozoic Savory Basin and correlation with the Amadeus and
Officer Basins Australian Journal of Earth Sciences v 41 p 533ndash546
WALTER M R VEEVERS J J CALVER C R and GREY K 1995 Neoproterozoic
stratigraphy of the Centralian Superbasin Australia Precambrian Research v 73 p 173ndash195
WILLIAMS I R 1992 Geology of the Savory Basin Western Australia Western Australia
Geological Survey Bulletin 141 115p
39
WILLIAMS I R 1995a Bullen WA (2nd Edition) Western Australia Geological Survey
1250 000 Geological Series Explanatory Notes 23p
WILLIAMS I R 1995b Trainor WA (2nd Edition) Western Australia Geological Survey
1250 000 Geological Series Explanatory Notes 31p
WILLIAMS I R and TYLER I M 1991 Robertson WA (2nd edition) Western Australia
Geological Survey 1250 000 Geological Series Explanatory Notes 36p
40
41
Appendix 1
Bibliography
Reports which are relevant to this investigation but which are not specifically cited are listed
below
BAILLIE P W POWELL C McA LI Z X and RYALL A M 1994 The tectonic
framework of Western Australiarsquos Neoproterozoic to recent sedimentary basins in The
sedimentary basins of Western Australia edited by P G PURCELL and R R PURCELL
Petroleum Exploration Society of Australia Symposium Perth WA 1994 Proceedings p
45ndash62
BRADSHAW M T BRADSHAW J MURRAY A P NEEDHAM D J SPENCER L
SUMMONS R E WILMOT J and WINN S 1994 Petroleum systems in West Australian
basins in The sedimentary basins of Western Australia edited by P G PURCELL and R R
PURCELL Petroleum Exploration Society of Australia Symposium Perth WA 1994
Proceedings p 93ndash118
CLARKE G L 1991 Proterozoic tectonic reworking in the Rudall Complex Western Australia
Australian Journal of Earth Science v38 p 31ndash44
COCKBAIN A E and HOCKING R M 1990 Phanerozoic in Geology and mineral resources
of Western Australia Western Australia Geological Survey Memoir 3 p 750ndash755
ETHERIDGE M and WALL V 1994 Tectonic and structural evolution of the Australian
Proterozoic 12th Australian Geological Convention Geological Society of Australia
Abstracts no 37 p 102ndash103
GOODE A D T 1981 Proterozoic geology of Western Australia in Precambrian of the
Southern Hemisphere Developments in Precambrian geology 2 edited by I R HUNTER
Amsterdam Elsevier p 105ndash203
GREY K and JACKSON M J 1983 A re-assessment of stromatolite evidence for the
correlation of the Late Proterozoic Neale and Ilma Beds Officer Basin Western Australia
Australia BMR Journal of Australian Geology and Geophysics v 8 p 359
42
HICKMAN A H WILLIAMS I R and BAGAS L 1994 Proterozoic geology and
mineralization of the TelferndashRudall region Paterson Orogen Geological Society of Australia
(WA Division) Excursion Guidebook no 5 56p
HOCKING R M MORY A J and WILLIAMS I R 1994 An atlas of Neoproterozoic and
Phanerozoic basins of Western Australia in The sedimentary basins of Western Australia
edited by P G PURCELL and R R PURCELL Petroleum Exploration Society of Australia
Symposium Perth WA 1994 Proceedings p 21ndash 44
JACKSON P R 1966 Geology and review of exploration Officer Basin Western Australia
Hunt Oil Company Western Australia Geological Survey S-series S26 (unpublished)
JACKSON M J 1971 Notes on a geological reconnaissance of the Officer Basin Western
Australia Australia BMR Geology and Geophysics Record 19715 30p
JACKSON M J and van de GRAAFF W J E 1981 Geology of the Officer Basin Western
Australia Australia BMR Geology and Geophysics Bulletin 206 102 p
LOWRY D C JACKSON M J van de GRAAFF W J E and KENNEWELL P J 1971
Preliminary result of geological mapping in the Officer Basin Western Australia Western
Australia Geological Survey Annual Report for 1971 p 50ndash56
MYERS J S 1990 Precambrian in Geology and mineral resources of Western Australia
Western Australia Geological Survey Memoir 3 p 737ndash750
MYERS J S SHAW R D and TYLER I M 1994 Proterozoic tectonic evolution of
Australia 12th Australian Geological Convention Geological Society of Australia Abstracts
no 37 p 312
NEDIN C and JENKINS R J F 1991 Re-evaluation of unconformities separating the
lsquoEdiacaranrsquo and Cambrian systems South Australia Palaios v 6 p 102ndash108
PHILLIPS B J JAMES A W and PHILIP G M 1985 The geology and hydrocarbon
potential of the north-western Officer Basin APEA Journal 25 (1) p 52ndash61
POWELL C McA LI Z X McELHINNY M W MEERT J G and PARK J K 1993
Paleomagnetic constraints on timing of the Neoproterozoic breakup of Rodinia and Cambrian
formation of Gondwana Geology v 21 p 889ndash892
43
POWELL C McA PREISS W V GATEHOUSE C G KRAPEZ B and LI Z X 1994
South Australian record of a Rodinian epicontinental basin and its mid-Neoproterozoic
breakup to form the Palaeo-Pacific Ocean Tectonophysics v 237 no 3ndash4 p 113ndash140
PREISS W V 1976 Proterozoic stromatolites from the Nabberu and Officer Basins Western
Australia and their biostratigraphic significance South Australia Geological Survey Report
of Investigations no 47 p 1ndash51
TOWNSON W G 1985 The subsurface geology of the western Officer Basin mdash results of
Shellrsquos 1980ndash1984 petroleum exploration campaign APEA Journal v 25 (1) p 34ndash51
WATTS K J 1982 The geology of the Townsend Quartzite Upper Proterozoic shallow water
deposit of the Northern Officer Basin Western Australia Perth University of Western
Australia BSc honours thesis (unpublished)
WELLS A T and KENNEWELL P J 1974 Evaporite exploration in the Officer Basin
Western Australia at the Madley Diapirs Australia BMR Record 1974194 (unpublished)
WILLIAMS I R and MYERS J S 1990 Paterson Orogen in Geology and mineral resources
of Western Australia Western Australia Geological Survey Memoir 3 p 274ndash286
WILLIAMS I R 1990 Savory Basin in Geology and mineral resources of Western Australia
Western Australia Geological Survey Memoir 3 p 329ndash334
WILLIAMS I R 1994 The Neoproterozoic Savory Basin Western Australia in The
sedimentary basins of Western Australia edited by P G PURCELL and R R PURCELL
Petroleum Exploration Society of Australia Symposium Perth WA 1994 Proceedings p
841ndash850
WILSON R B 1967 Woolnough Hills and Madley diapiric structures Gibson Desert WA
APEA Journal v 7 p 94ndash102
44
Appendix 2
Meteorological data (from Bureau of Meteorology Perth 1994)
Table 21 Wiluna rainfall (mm)
Year Jan Feb Mar Apr May Jun Jul Aug Sept Oct Nov Dec
1975 0 45 446 309 306 59 276 4 34 886 638 164 1976 16 154 12 138 53 16 34 62 12 238 0 2 1977 44 0 66 74 68 95 24 363 1 58 12 727 1978 234 522 94 16 0 96 367 24 16 353 185 45 1979 19 173 122 88 91 4 0 246 58 0 169 114 1980 148 764 68 1081 259 626 629 06 56 02 174 0 1981 123 476 192 32 196 118 44 74 14 0 28 312 1982 374 705 206 244 1079 92 02 143 368 526 368 118 1983 1 112 928 248 0 212 56 32 5 1 42 496 1984 149 7 342 84 836 0 348 132 224 04 16 172 1985 596 483 0 166 556 0 514 56 0 0 4 0 1986 0 154 35 0 0 1085 23 01 239 137 0 04 1987 1204 119 19 89 17 575 154 126 07 1 0 398 1988 46 202 164 13 388 0 202 104 0 0 224 1309 1989 207 234 26 703 278 536 57 0 01 0 144 02 1990 1035 23 281 46 126 53 94 218 44 9 42 0 1991 48 0 41 45 0 472 297 12 0 1 0 7 1992 112 96 1025 1227 323 65 04 174 0 132 48 4 1993 0 697 0 202 445 0 12 306 18 05 14 33 Mean 25 35 22 27 27 25 18 12 6 13 13 21
JAN FEB MAR APR MAY JUN JUL AUG SEP OCT NOV DEC0
10
20
30
40
Mea
n R
ain
fall
(mm
)
Month
Mean monthly rainfall in Wiluna
MKS41 140498
45
Table 22 Wiluna minimum temperature (degC)
Year Jan Feb Mar Apr May Jun Jul Aug Sept Oct Nov Dec
1975 ndash 23 203 15 94 63 71 62 103 124 169 205 1976 242 229 194 15 10 63 59 73 95 143 16 228 1977 243 25 197 148 96 95 56 86 102 ndash 188 23 1978 241 232 203 18 102 64 76 8 9 152 19 205 1979 255 226 216 167 83 6 59 79 97 145 198 223 1980 255 226 231 155 134 83 68 75 121 108 193 223 1981 245 216 19 182 119 6 54 78 138 159 163 218 1982 232 224 177 16 ndash ndash 37 111 112 164 209 225 1983 235 24 197 147 112 88 39 88 121 162 189 219 1984 241 243 191 156 ndash 72 66 7 95 161 182 211 1985 244 231 ndash 159 98 65 71 73 117 147 205 ndash 1986 ndash 229 226 155 93 96 43 49 10 122 ndash 219 1987 ndash 217 183 175 85 77 68 68 112 ndash ndash 221 1988 238 214 209 178 111 ndash ndash 86 104 157 171 195 1989 ndash 237 199 165 107 67 44 61 107 131 187 ndash 1990 232 ndash 211 155 118 62 57 87 102 149 195 22 1991 26 256 217 168 122 101 78 ndash 113 18 168 219 1992 227 227 214 169 102 98 59 69 ndash 125 159 196 1993 241 218 196 171 103 ndash 49 68 88 128 192 211 Mean 24 23 20 16 10 8 6 8 11 14 18 21
NOTE Dashes indicate data unavailable
JAN FEB MAR APR MAY JUN JUL AUG SEP OCT NOV DEC0
10
20
30
40
Month
MKS43 140498
50
Mean monthly minimum temperatures at Wiluna
Mea
n T
emp
erat
ure
(degC
)
46
Table 23 Wiluna maximum temperature (degC)
Year Jan Feb Mar Apr May Jun Jul Aug Sept Oct Nov Dec
1975 ndash 349 326 281 247 201 197 212 256 248 31 344 1976 374 369 346 297 248 206 208 225 265 287 313 388 1977 397 392 352 296 234 212 222 244 ndash 308 337 383 1978 378 345 346 316 242 195 176 205 231 295 334 356 1979 403 36 364 295 ndash ndash ndash 193 242 318 359 373 1980 392 342 377 275 24 176 179 233 292 288 349 391 1981 385 346 337 342 242 178 201 224 30 326 326 369 1982 372 359 315 307 ndash ndash 196 253 252 305 353 379 1983 381 389 327 272 263 222 187 248 287 321 336 366 1984 378 393 322 299 226 215 178 214 234 ndash 336 364 1985 40 366 ndash 294 224 216 205 212 284 307 355 ndash 1986 ndash 383 372 307 ndash 193 166 196 261 277 ndash 382 1987 ndash 339 328 305 21 202 214 218 275 ndash ndash 374 1988 388 365 353 301 23 ndash ndash 228 283 334 31 33 1989 ndash 375 339 285 238 179 181 219 275 298 336 ndash 1990 368 ndash 36 309 268 19 188 205 274 309 373 393 1991 414 416 363 315 268 206 21 ndash 279 338 332 368 1992 363 383 336 263 213 178 213 197 ndash 285 313 359 1993 396 357 344 301 221 ndash 197 215 253 294 347 362 Mean 39 37 34 30 24 20 20 22 27 30 34 37 NOTE Dashes indicate data unavailable
JAN FEB MAR APR MAY JUN JUL AUG SEP OCT NOV DEC0
10
20
30
40
Month
MKS42 140498
50
Mean monthly maximum temperatures at Wiluna
Mea
n T
emp
erat
ure
(degC
)
47
Appendix 3
Table 31 Summary of palynological results
Drillhole Depth (m) F no(a) GSWA no Lithology Formation Assemblage TAI(b)
BWB 1 74ndash75 F49668 135741 dark-grey siltstone basalt Jilyilli gt5 BWB 1 98ndash100 F49669 135742 dark-grey siltstone basalt Jilyilli gt5 BWB 1 121ndash122 F49670 135743 dark-grey siltstone basalt Jilyilli gt5 TWB 1 86ndash87 F49671 135631 dark-grey siltstone McFadden 3+ TWB 1 104ndash105 F49672 135632 dark-grey siltstone Cornelia 3+ TWB 1 121ndash122 F49673 135633 dark-grey siltstone Cornelia 4 TWB 2 14ndash15 F49674 135634 dark-grey siltstone Skates Hills 3+ TWB 6 49ndash50 F49675 135675 dark-grey siltstone Cornelia 1 3+ TWB 9 49ndash51 F49676 135704 dark-grey siltstone Brassey Range 1 3+ Trainor 1 37497- F49733 138939 black mudstone with Cornelia 5 37509 light-grey siltstone Trainor 1 3809 F49734 138940 dark-grey and black Cornelia 4- laminated mudstone Trainor 1 4170 F49735 138941 black unlaminated mudstone Cornelia 4- Trainor 1 4950 F49851 139501 dark-grey indurated siltstone Cornelia 5 Trainor 1 6032 F49852 139502 dark- and light-grey Cornelia 5 indurated siltstone Trainor 1 6434 F49853 139503 greenish indurated finely Cornelia 5 laminated siltstone LDDH 1 270 F49678 138934 dark-grey siltstone interbeds Waters 1 3+ in enterolithic evaporite Tarcunyah Gp LDDH 1 277 F49679 138935 dark-grey siltstone in cavity Waters 1 3+ in enterolithic evaporite Tarcunyah Gp
NOTES (a) GSWA Fossil Catalogue number (b) TAI = Thermal Alteration Index of Traverse (1988 plate 1)
48
Appendix 4
Savory Sub-basin quantitative magnetic and gravity interpretation (extracted from Cowan 1995)
Summary
A program of quantitative aeromagnetic interpretation has been completed on BMRAGSO data from the Savory Sub-
basin Western Australia Quantitative aeromagnetic interpretation utilized the 3D Euler deconvolution method
supported by wavenumber filtering and image processing The results have provided useful information on structural
trends and depth to magnetic sources in a structurally complex area Depth to magnetic source analysis has provided
information on intra-sedimentary magnetic sources as well as basement rocks
The results of the interpretation support previously identified depocentres However the presence of magnetic
sources at several levels makes it very difficult to produce a reliable magnetic basement depth contour map It is
considered more productive to work with the 3D Euler colour circle plots and images rather than trying to contour the
results It would be necessary to carry out a full-scale interpretation of the BMRAGSO profile data to improve on the
3D Euler results The regional gravity was found to be useful in interpreting the regional setting of the area although
the very wide data spacing limits quantitative use of the data The gravity data show quite a complex picture with
limited consistent correlation between gravity features and basin structures This suggests that gravity anomalies
reflect changes in density of the basement rocks rather than basement topography especially in the northern part of the
basin
It is recommended that the GSWA investigate access to company confidential high-resolution aeromagnetic data
prior to planning further aeromagnetic surveys Private companies have flown large parts of the northern half of the
area as part of their diamond exploration program Additional gravity coverage of the area may be more cost effective
than magnetic surveys as the gravity data provides more information on changes within the sedimentary section
Introduction
The main use of aeromagnetic data in petroleum exploration has been the determination of magnetic basement
topography although there has been increasing interest in analysis of intra-sedimentary magnetic anomalies
intrabasement and suprabasement magnetic anomalies These anomalies are used to determine depth to magnetic
basement rocks and hence determine the thickness of the sedimentary sequence Unfortunately interpretation of the
intrabasement and suprabasement magnetic anomalies is non-unique in terms of position and size of causative sources
because of the inherent ambiguity of potential-field methods However this ambiguity can be reduced by placing
49
constraints on source geometry and magnetization and by using geological and other geophysical data to constrain
the solution
Before 1970 most depth-determination techniques involved graphical determination of slopes of selected
magnetic anomalies and application of various empirical factors to convert the slopes into depth estimates Geological
Society of America Memoir 47 Interpretation of Aeromagnetic Maps by Vacquier et al (1951) was a landmark for
this type of interpretation
Automated interpretation procedures have played an increasingly important role in depth interpretation and a
wide range of techniques have been developed Many of these techniques are designed for application to located data
profiles and assume a two-dimensional geometry However there has been renewed interest in techniques applicable
to gridded data
Two distinct types of method can be recognized In the first case often described as discrete methods individual
isolated magnetic anomalies are interpreted and the results used to produce a map of basement relief In the second
case often described as continuous methods areas of data containing a number of anomalies are interpreted
statistically to produce direct output of basement depths
The discrete methods usually involve a semiautomatic initial phase which generates a large number of possible
depth solutions and an interactive second phase to screen and select acceptable solutions The advantage of this
approach is that the interpreter can select features that are relatively free from interference from adjacent anomalies
and consider all aspects of a particular magnetic anomaly The disadvantage is that interpretation can be very time
consuming as a wide range of depths are usually possible depending on the initial model chosen and a significant
amount of effort is needed to select the correct model In the case of the Savory Sub-basin dataset we encountered
problems in separating basement related effects from the effects of shallower intrasedimentary magnetic sources
Because of these problems we have concentrated on displaying the Euler results accompanied by separation filter
images of the data to show the shallower effects and deeper effects rather than trying to refine a 3D Euler
deconvolution depth-to-crystalline-basement contour
The continuous methods are very direct provided that the rather restrictive assumption can be made that all
anomalies are due to lateral magnetization changes due to basement topography This means that shallow effects and
large intrabasement anomalies must be removed from the data This involves judgement and skill as it is necessary to
distinguish between the lower amplitude suprabasement anomalies due to basement topography and the larger
intrabasement anomalies reflecting magnetization changes within the basement These methods were not considered
suitable for the Savory Sub-basin magnetic dataset but were used to invert the gravity data
50
Limitations of magnetic and gravity interpretation
Interpretation of the area is limited by a shortage of information on the nature and physical properties of the deeper
sedimentary sequence and the underlying basement rocks However using techniques such as cross-correlation of
gravity and pseudo-gravity data it is possible to try to differentiate between anomalies relating to basement and those
related to the sedimentary sequence
Gravity anomalies reflect changes within the sedimentary sequence as well as basement condition These
changes in density of sedimentary rocks produce gravity anomalies without a corresponding magnetic anomaly hence
the complementary nature of gravity and magnetic surveys The main use of magnetics is to determine depth to
magnetic basement and any intra-sedimentary volcanic rocks or intrusives whereas gravity provides much more
general information on the sedimentary sequence
Unfortunately interpretation of gravity anomalies is complicated since they can be due to a number of geological
features including
bull major basement faults
bull basement highs
bull igneous intrusions within the basement
bull sedimentary basins which may or may not be isostatically compensated
bull intra-sedimentary volcanics and associated plutonic centres
Two major problems affect the interpretation of both magnetic and gravity data
1 The inherent ambiguity of potential-field data There is no unique solution to any measured gravity or magnetic
anomaly and theoretically there will be an infinite number of source geometry and magnetizationdensity
combinations which will fit the observed data This means that any a priori information which helps to select a
suitable model is very useful
2 Measured anomalies are the summation of effects from different depths For example an observed gravity profile
may contain contributions from shallow sources (density variations within the sedimentary basin) intermediate
depth sources (density variations due to large igneous intrusions within the basement) and deep sources (crustal
thinning producing a mantle anomaly) Separation of these component responses is the regionalresidual problem
which we solve using spectral analysis and differential upward continuation-based separation filtering
Regional setting and interpretation overview
The area studied includes parts of BALFOUR DOWNS (SF51-9) RUDALL (SF51-10) ROBERTSON (SF51-13) GUNANYA
(SF51-14) COLLIER (SG50-4) BULLEN (SG51-1) TRAINOR (SG51-2) MADLEY (SG51-3) NABBERU (SG50-5)
STANLEY (SG51-6) and HERBERT (SG51-7) 1250 000 sheets Broadly the area lies between latitudes 22deg00rsquondash25deg30rsquoS
and longitudes 119deg30rsquondash123deg30rsquoE
51
Regional gravity
The AGSO regional gravity data (at nominal 11 km spacing) was gridded at a 4 km mesh spacing using a minimum-
curvature algorithm Bouguer gravity values in the area are negative reflecting mass deficiency at depth and range
from -84 mgals to -25 mgals
A Bouguer gravity colour image is shown as Figure 41 A residual grid was produced by removing a fifth-order
orthogonal polynomial from the Bouguer data but did not add to the interpretation
120deg 121deg 122deg 123deg
23deg
24deg
25deg
-25
-84
50 km
MKS46 180598
mgal
Figure 41 Regional Bouguer gravity (BMRAGSO data) gridded at 4 km
52
The data show a complex pattern of positive and negative anomalies with no clearly defined trends Correlations
with aeromagnetic data and known basin structures are poor A vague north-northwest linear trend appears to coincide
with the Marloo Fault (Figure 42) A prominent negative anomaly appears to coincide with the Blake Fold and Fault
Belt depocentre and continues as a narrower negative anomaly to the east until it widens out again near the edge of the
basin Elsewhere the gravity data show little correlation with known basin structures and it is likely that especially in
the north of the area gravity anomalies are due to density changes in the basement rather than changes in basement
topography
Production of wavelength-filtered residual gravity plots and vertical gradient plots showed very patchy aliased
data reflecting poor sampling in much of the area
Regional magnetics
The AGSO regional aeromagnetic data were gridded at a 400 m mesh spacing using a minimum-curvature algorithm
(Figure 43) Most of the data has a line spacing of 1600 m with small areas of 1 km spacing The quality of the data is
acceptable for regional interpretation but is not adequate for detailed analysis The accuracy of the flight path is rather
variable reflecting the vintage of the data and the noise envelope of the data is poor by modern standards Problems
were also encountered in joining different map sheets
The magnetic anomaly pattern over the south and west part of the area shows a strong high frequency signature
reflecting the presence of widespread basic sills and dykes Some of the major north-northeasterly trending dykes can
be traced over considerable distances
Discontinuous high-frequency anomalies extend as a northwest-trending zone through the centre of the area and
this zone includes a conspicuous circular magnetic anomaly which is probably a ring complex
The northern and eastern parts of the area are characterized by long-wavelength deep-seated basement magnetic
anomalies with 120deg and 150deg trends dominant The Marloo and Perentie Faults (Figure 42) appear as distinct linear
zones and offsets A prominent easterly trending negative anomaly in the northwest of the area appears to swing round
to the southeast and may separate different basement blocks One possible interpretation is that this very deep seated
anomaly separates areas of Archaean and Proterozoic basement
Regional geology
The regional geology is described in Williams (1992) The GSWA provided a digitized version of Plate 2 from this
Bulletin the structural interpretation map to use as an overlay (Figure 42)
53
Pp
Pp
PSd
PSd
PSd
PSd
PSd
PSo
PSt
PSt
PSf
PSf
PSf
PSb
PSb
PSb
PSsPSs
PSs
PSb
PSm
PSp
PSc
PSc
PSw
PSw
PSw
PSg
PSr
PSj
PSg
PM
Pk
PY
PY
PSd
L
L
L
L
L
L
L
LL
L
L
L
LL
L
LL
L L
LL
L L
L
L
L
L
L
L
L
LL
L
L
BLAKEDEPOCENTRE
MA
RLO
O
FAU
LT
PERENTIEFAULT
50 km
MKS39120598
120deg 121deg 122deg 123deg
25deg
24deg
23deg
Approximate boundaryof aeromagnetic interpretation
PML
PSgL
PSjL
PML
PSpL
PML
PML
PSfL
PSfL
PSpL
LPc
LPcLPcPSrL
LPA
Durba Sandstone
Woora Woora Formation
McFadden Formation
Tchukardine Formation
Boondawari Formation
Skates Hills Formation
Mundadjini Formation
Coondra Formation
Spearhole Formation
Watch Point Formation
Jilyili Formation
Brassey Range Formation
Glass Spring Formation
Paterson Formation
Yeneena Group
Karara Formation
Cornelia Formation
Kahrban Subgroup
Bangemall Group
Fault
Formation boundary
PSdL
PSoL
PSfL
PStL
PSbL
PSsL
PSmL
PScL
PSpL
PSwL
PSjL
PSrL
PSgL
Pp
PYL
PkL
LPc
LPA
PML
Savory Group Other Units
PYL
Figure 42 Regional geology and structure map (after Williams 1992)
54
120deg 121deg 122deg 123deg
23deg
24deg
25deg
5820
3750
MKS47 180598
nT
50 km
Figure 43 Regional aeromagnetic data total magnetic intensity (BMRAGSO data) gridded at 400 m
Analysis
3D analysis
3D Euler deconvolution was used as the primary depth-determination method The advantage of this approach is that
consistent solutions can be obtained over the entire area with minimal assumptions about source geometries Euler
deconvolution of gridded data is used for positional information and estimation of depth to top of source Euler
55
deconvolution yields a large number of depth solutions which have to be screened to reject spurious solutions Results
are plotted as circles in eight depth ranges with radius proportional to depth and colour coded
The 400 m total magnetic intensity grid was used for the analysis Horizontal gradients in x and y and the vertical
gradient were calculated 3D Euler deconvolution was tested on the 400 m gridded data using windows of 9 times 9 and
11 times 11 and 16 times 16 data points and structural indices 05 (fault) and 10 (sill or dyke) It was concluded that the
16 times 16 window produced the best results overall and final plots were produced for the 16 times 16 window and structural
index 05 (Fig 44) Results were very good over the northern and central parts of the area showing magnetic sources
Figure 44 Depth to magnetic source 3D Euler deconvolution 16 times 16 window of 400 m gridded data structural index 05
56
at several different levels Unfortunately in the extreme south of the area shallow intrasedimentary magnetic sources
(sills and dykes) dominated the inversion and the results contained few basement solutions
In order to reduce these problems the 400 m gridded data were filtered using a separation filter based on
interpretation of the log-energy spectrum The 3D Euler method was run on the filtered data in order to generate more
basement-depth solutions Results for the deep-separation filter data were gridded and presented as a colour image in
Cowan (1995) Attempts to grid the Euler output were unsatisfactory and it is considered safer to interpret the 3D
Euler depth plots The 3D Euler depth results from the separation-filter run should be analysed with care as perfect
separation of the basement can never be achieved and there will always be some contamination from sources at
different levels
The results of original total magnetic intensity 3D Euler depth estimation for structural index 05 using a 16 point
window have been plotted at 1500 000 scale (not included in this publication but available in Cowan (1995) from the
GSWA Library as S10331) and as reduced A4 colour circle plots (Figure 44)
The results of deep-basement 3D Euler depth estimation for structural index 05 using a 16 point window have
been plotted as a colour image at 1500 000 scale and as an A4 image (not included in this publication)
2D analysis
Two equispaced profiles were interpolated with a 50 m station interval from the AGSO-located data profiles for the
BULLEN 1250 000 sheet The interpolated profiles were analysed using 2D Euler deconvolution and Werner
deconvolution Results are included in Cowan (1995) and show the use of these methods for more detailed analysis
Filtered data
In order to reconcile 3D Euler results from shallow basement and intrasedimentary magnetic sources we produced
several separation-filtered maps and images We found the shallow-layer double-separation filter (Figure 45) to be
very effective for shallow sources and the deep-layer standard-separation filter (Figure 46) for the basement layer
Gravity and magnetic data correlation
Both lsquoreduced to the polersquo (RTP) magnetics (Figure 47) and pseudo-gravity data (Figure 48) were produced as part of
the reconciliation of gravity and magnetic signatures In both cases the filtering operations assumed magnetization by
induction in the present Earths field The RTP data are fairly similar to the total magnetic intensity The pseudo-
57
gravity data are dominated by a northwest-trending strong positive anomaly and there is little correlation with the
Bouguer gravity data
The poor magneticgravity correlation is confirmed by cross-correlation of the RTP magnetics and the gravity
gradient The correlation plot in Figure 49 shows little coherent response with numerous zones of positive and
negative correlation
Figure 45 Regional aeromagnetic data shallow layer separation filter (BMRAGSO data) gridded at 400 m
Results
In the north and east of the area on the Wells Foreland Sub-basin trend (refer to Figure 1 main text) we see a range
of quite deep 3D Euler depths and several trend directions with north-northwesterly dominant There are relatively few
shallow intrasedimentary solutions in this zone
The second area of deep 3D Euler solutions lies over the Blake depocentre (Figure 43) with several trend
directions
Elsewhere the 3D Euler results are dominated by shallow intrasedimentary depth solutions reflecting mainly the
dolerite sills dykes and the ring complex However where we do see basement-related solutions in the south and
west of the area they appear to be shallower than those noted for the Wells Foreland Sub-basin and the Blake
depocentre
58
Figure 46 Regional aeromagnetic data deep-layer separation filter (BMRAGSO data) gridded at 400 m
Figure 48 Regional aeromagnetic data pseudo-gravity transform (BMRAGSO data) gridded at 400 m
Figure 47 Regional aeromagnetic data reduced-to-pole (BMRAGSO data) gridded at 400 m
Figure 49 Regional aeromagnetic and gravity data gravitymagnetic correlation using RTP magnetics and gravity gradient (BMRAGSO data) gridded at 4 km
59
This subdivision of the area into two zones of deep solutions is consistent with interpreted depocentres
However the interference between sources at different levels and the complexity of the magnetic response of the
basement rocks precludes more refined interpretation at this stage
The area of deep 3D Euler solutions over the Blake depocentre correlates with the pronounced negative gravity
anomaly discussed in the gravity interpretation section Using a density contrast of -015 gcc the negative gravity
anomaly could indicate up to 6ndash8 km of low-density sedimentary rocks depending on assumptions about the regional
field
The area of deep 3D Euler solutions over the Wells Foreland Sub-basin has a complex gravity expression and no
clear basin structure emerges from inversion of these data As noted previously it is likely that observed gravity
anomalies reflect contrasts in basement density rather than basement topography
Separation filtering applied to the magnetic data helps to enhance the intrasedimentary magnetic signature and to
give a better impression of the basement magnetic signature even though separation of the basement response is not
perfect
Conclusions
Quantitative aeromagnetic interpretation using 3D Euler deconvolution supported by wavenumber filtering and image
processing has been successful in providing structural trend and depth information for the Savory Sub-basin
Quantitative magnetic interpretation has revealed two zones of relatively deep magnetic basement beneath the
Wells Foreland Sub-basin and the Blake depocentre
This analysis of the magnetic data supports interpreted depocentres but the complexity of the basement magnetic
signature and interference from sources at different depths precludes further refinement to a map of basement
topography
Regional gravity proved to be very useful in understanding the regional setting of the area and in providing
support for aspects of the interpretation The gravity data support the interpretation of the Blake depocentre
suggesting up to 6ndash8 km of low-density sedimentary rocks
The deep structure of the Savory Sub-basin area is obviously complex with different areas underlain by
Archaean and Proterozoic basement and with the Capricorn suture occurring in the centre of the area
60
Recommendations
The quantitative magnetic interpretation needs to be reconciled with geological models available for the area
In particular the zones tentatively identified as areas with thick sedimentary rocks the Wells Foreland Sub-
basin and the Blake depocentre need to be investigated
Cross sections should be prepared across the basin for joint magneticgravity modelling especially for the Blake
depocentre It is important to be able to explain the strong negative gravity anomaly in this area
In view of the effects of basement density contrasts on the gravity field for the northern part of the area we think
that additional gravity interpretation and acquisition of new gravity data may not be justified as they will not
contribute significantly to understanding basin evolution and structure
It is recommended that GSWA try to get access to company confidential high-resolution aeromagnetic data
rather than flying new surveys The GSWA might offer to fund flying of new infill areas as a bargaining point
References
The original text of this report by Cowan (1995) and 1500 000 scale maps are filed in the GSWA Library under
S10331
COWAN D 1995 Savory Basin quantitative magnetic interpretation Western Australia Geological Survey S-series
S10331 (unpublished)
VACQUIER V STEENLAND N C HENDERSON R G and ZIETZ I 1951 Interpretation of aeromagnetic
maps The Geological Society of America Memoir 47 151p
WILLIAMS I R 1992 Geology of the Savory Basin Western Australia Western Australia Geological Survey
Bulletin 141 115p
61
Appendix 5
Geochemistry
MKS38 250398
Saturate FractionC12+ GLC
1217
Pr18
Ph
22
31CSR WELL-13 315m Cuttings
Figure 51 Canning Stock Route Well 13 gas chromatograph of extract of auger drill sample
12
17
18
22
31
Pr Ph
LDDH 1 6623m CoreSaturate FractionC12+ GLC
MKS35 240398
Figure 52 Gas chromatograph of extract from core sample at 6623 m LDDH1
62
Table 51 Canning Stock Route Well 13 auger drill samples
GSWA sample Drill depth (m)(a) Comments
135601 150 At watertable 135602 203 (all samples consist 135603 310 of sand mud and water) 135604 315 At total depth
NOTE (a) Datum for drill depth is the top of sediment fill in the well which is 155 m below ground level (ie the total depth of 315 m is 47 m below ground level)
Table 52 Canning Stock Route Well 13 gas chromatography data for 315 m depth sediment sample
Parameter Value
Weight of rock extracted (grams) 945 Total extract (ppm) 519 n-Alkane distribution n-C12 07 n-C13 23 n-C14 26 n-C15 22 n-C16 19 n-C17 14 i-C19 23 n-C18 14 i-C20 08 n-C19 11 n-C20 16 n-C21 25 n-C22 29 n-C23 70 n-C24 42 n-C25 95 n-C26 43 n-C27 83 n-C28 38 n-C29 87 n-C30 31 n-C31 273 Alkane compositional data Pristane phytane ratio 279 Pristane n-C17 ratio 161 Phytane n-C18 ratio 059 CPI (1)(a) 284 CPI (2) 209 (C21 + C22) (C28 + C29) 043
NOTE (a) CPI= Carbon preference index
63
Table 53 LDDH1 extract liquid chromatography data for 6623 m concentration
Rock extracted Total extract (grams) (ppm)
702 313
NOTE ppm= parts per million
Table 54 LDDH1 saturate gas chromatography data of core for 6623 m alkane composition
Pristane Pristane Phytane (a) CPI (1) CPI (2) (C21+C22) Phytane n-C17 n-C18 (C28+C29)
103 026 024 103 102 325
NOTE (a)CPI = carbon preference index
Table 55 LDDH1 saturate gas chromatography data of core for 6623 m n-alkane distributions
Parameter Value
n-C12 17 n-C13 38 n-C14 55 n-C15 60 n-C16 65 n-C17 74 i-C19 19 n-C18 78 i-C20 19 n-C19 80 n-C20 79 n-C21 71 n-C22 64 n-C23 57 n-C25 43 n-C24 38 n-C27 31 n-C28 23 n-C29 19 n-C30 12 n-C31 10
64
Appendix 6
Table 61 Summary of data from Trainor waterbores (TWB) and Bullen waterbores (BWB)
Well AMG Elevation TD Status(b) Completion details Water Salinity Water level Flow rate Depth to consolidated AGD84 GL (m) (m) struck mgl(c) (m) (LHr) lithology aquifer(e) Z51(a) Interval (m) (100 mm PVC) (m) (mgl)(d)
TWB 1 473660E 453 122 comp 0ndash75 plain 63 7 300 24 2 880 12 m 7287404N 75ndash93 slotted (9 260) McFadden Fm 93ndash99 plain TWB 2 472 977E 475 23 abd nil 15 m 7285877N Skates Hills Fm dry TWB 3 473259E 475 50 abd nil 7 m 7285849N Skates Hills Fm dry TWB 4 463225 E 445 50 comp 0ndash22 plain 35 7 200 55 3 600 0 m 7286143N 22ndash34 slotted (8 140) Tertiary sand and gravel 23ndash60 plain TWB 5 463095E 445 31 comp 0ndash19 plain 13 26 000 655 3 600 Tertiary sand and gravel 7277721N 19ndash25 slotted (36 700) 25ndash31 plain TWB 6 457013E 455 50 comp 0ndash42 plain 38 920 119 600 0 m 7274352N 42ndash48 slotted (1 030) Cornelia Fm ss TWB 7 453739E 475 26 susp 0ndash2 plain 11 9 300 48 4 500 0 m 7263891N (10 500) Tertiary sand TWB 8 433893E 535 60 susp 0ndash2 plain 47 8 500 gt46 1 200 0 m 7245991N (10 900) Tertiary sand and Brassey Range Fm ss TWB 9 437219E 505 51 comp 0ndash47 plain 45 1 000 58 600 1 m 7235905N 47ndash51 slotted (990) Brassey Range Fm ss TWB 10 434927E 495 32 susp 0ndash2 plain 235 450 120 0 m 7225875N (500) Dolerite
65
BWB 1 287337E 580 122 abd Nil 1 m 7245861N Jilyili Fm dry BWB 2 288346E 545 50 comp 0ndash26 plain 15 630 3 29 000 0 m 7240423N 26ndash38 slotted (730) Tertiary sand and gravel 38ndash50 plain BWB 3 305637E 545 50 abd 19 8 800 43 7 200 0 m 7240423N (10 550) Tertiary ss BWB 4 320167E 515 445 comp 0ndash20 plain 9 980 445 24 000 0 m 7248097N 20ndash32 slotted (1 190) Tertiary ss 32ndash44 plain BWB 5 353393E 545 20 susp 0ndash2 plain 45 (970) 1 m 7238934N Basalt
NOTES (a) GPS accuracy ~ 150 m (b) Comp = completed abd = abandoned susp = suspended (c) Salinity from conductivity (d) Analysis total dissolved solids (e) Fm = Formation ss = sandstone
iii
Contents Abstract 1
Introduction 2
Access and climate 4
Regional geology 6
Stratigraphy 6
Depositional Sequence A Supersequence 1 11
Depositional Sequence B Supersequence 1 11
Depositional Sequence C Supersequence 3 14
Depositional Sequence D Supersequence 4 14
Depositional Sequence E Supersequence 4 14
Other depositional sequences and regional correlations 14
Structural setting 17
Exploration history 19
Hydrocarbon potential 19
Source rocks 22
Maturity 23
Reservoirs 25
Seals 25
Traps 26
Preservation of hydrocarbons 26
Reported hydrocarbon shows and oil seep 27
Geological and geophysical data bases 27
Drilling 28
Petroleum industry data 28
Government data 28
Mineral industry data 28
Hydrogeological data 29
Seismic data 29
Aeromagnetic surveys 29
Government data 29
Mineral industry data 30
Gravity surveys 30
Government data 30
Mineral industry data 30
Government and academic reports 32
Chronostratigraphy and geochemistry 32
Proposed work program 32
Conclusions 33
References 35
iv
Appendices
1 Bibliography 41
2 Meteorological data 44
3 Summary of palynological results 47
4 Cowan Geodata Services Report Savory Sub-basin quantitative magnetic and gravity
interpretation 48
5 Geochemistry 61
6 TWB and BWB waterbore data 64
Figures
1 Structural subdivisions of the Savory Sub-basin 3
2 Localities and access routes of the Savory Sub-basin 5
3 Formations lithology and depositional sequences AndashE of the Savory Sub-basin 7
4 Correlation of Savory Sub-basin formations with the western Officer and Amadeus Basins 10
5 Locations of petroleum exploration wells mineral exploration and stratigraphic drillholes
and waterbores and wells 12
6 Geological cross section through significant drillholes 13
7 Regional geological setting of the Savory Group and western Officer Basin 15
8 Locations of aeromagnetic and gravity surveys 21
9 Petroleum source potential of rocks in Normandy LDDH1 24
10 Regional Bouguer gravity map of the Savory Sub-basin 31
11 Detailed Bouguer gravity map of the Savory 1995 Gravity Survey from the
eastern Savory Sub-basin 31
Tables
1 Summary of formations in the Savory Sub-basin 8
2 Neoproterozoic formations and hydrocarbon shows in diamond drillholes in the
Savory Sub-basin 20
~Version Information13 VERS 120 CWLS log ASCII Standard -VERSION 12013 WRAP NO One line per depth step131313~Well Information Block13MNEMUNIT Data Type Description13--------- ------------ -----------------------------13 STRTM 5000013 STOPM 00013 STEPM -10013 NULL -9992513 COMP COMPANY GEOLOGICAL SURVEY OF WA 13 WELL WELL TWB 6 13 FLD FIELD SAVORY SUB-BASIN 13 LOC LOCATION AGD84 Z51 457 013E 7 274 352N 13 PROV PROVINCE WESTERN AUSTRALIA 13 SRVC SERVICE COMPANY BPB Wireline Services 13 DATE LOG DATE 16-NOV-1995 13 UWI UNIQUE WELL ID 131313~Curve Information Block13MNEMUNIT Curve Description13--------- -----------------------------13 DEPTM DEPTH13 GRNPGAPI GAMMA FROM NEUTRON TOOL 13 LSN SNU LONG SPACED NEUTRON 13 SSN SNU SHORT SPACED NEUTRON 13 RPOR LIMEST NEUTRON POROSITY 13 BISIMM BIT SIZE 131313~Other Information13NEUTRON POROSITY GAMMA RAY LOG 13LOGGED THROUGH PVC CASING 13 13 13 13Run number ONE Log 1st rdg 497 M Log last rdg 0 M 13Driller TD 50 M Logger TD 50 M Water level 8 M 13Perm Datum GL Elevation Approx 455 M Other srvcs 13Dril mes from GL Log meas from GL 0 M Other srvcs 13Elevation KB DF GL 13Casing Driller Casing Logger Casing size 100 MM 13Casing Weight PVC From 0 M To 50 M 13Bit size 168 MM From 4 M To 50 M 13Hole fl type WATER Sample source Fluid loss 13Density Viscosity pH 13RM meas tmp RMF mes tmp RMC mes tmp 13RM BHT RMF source RMC-source 13Max rec temp Time snc circ LsdSecTwpRge 13Equipment no V338 Base PERTH Equip name NN1 13Recorded by RALEES Witnessed by MKSTEVENS Sonde srl no 5094421 13Last title Last line Permit no 131313~A Depth GRNP LSN SSN RPOR BISI13 50000 -999250 -999250 -999250 -999250 15000013 49900 -999250 -999250 -999250 -999250 15000013 49800 -999250 -999250 -999250 -999250 15000013 49700 -999250 -999250 -999250 -999250 15000013 49600 -999250 -999250 -999250 -999250 15000013 49500 -999250 -999250 -999250 -999250 15000013 49400 -999250 216309 1965945 21484 15000013 49300 -999250 209718 1885054 18983 15000013 49200 -999250 193254 1788650 20017 15000013 49100 -999250 179391 1718687 21242 15000013 49000 -999250 169195 1664613 22255 15000013 48900 -999250 164382 1641439 22881 15000013 48800 -999250 161675 1610665 22813 15000013 48700 -999250 158560 1582780 22969 15000013 48600 -999250 153487 1540073 23222 15000013 48500 -999250 150656 1507227 23153 15000013 48400 -999250 149882 1476893 22537 15000013 48300 -999250 149163 1472245 22684 15000013 48200 -999250 150061 1480661 22713 15000013 48100 -999250 152366 1505029 22817 15000013 48000 -999250 155587 1522300 22376 15000013 47900 -999250 156423 1545663 22756 15000013 47800 -999250 157996 1564316 22732 15000013 47700 -999250 160387 1576311 22387 15000013 47600 -999250 164977 1575181 21193 15000013 47500 -999250 169393 1573485 20161 15000013 47400 -999250 172602 1572606 19401 15000013 47300 -999250 174262 1576876 19106 15000013 47200 125606 176189 1588872 18968 15000013 47100 130283 177279 1602375 19020 15000013 47000 133820 177991 1612297 19135 15000013 46900 133219 177161 1612863 19341 15000013 46800 132529 178270 1613868 19143 15000013 46700 132046 178623 1608090 18950 15000013 46600 132923 178778 1608655 18966 15000013 46500 130992 176622 1610853 19516 15000013 46400 129967 174944 1622095 20144 15000013 46300 125691 174745 1628815 20332 15000013 46200 120912 175222 1643574 20508 15000013 46100 116508 178518 1664739 20243 15000013 46000 113650 183591 1699030 19897 15000013 45900 112428 194771 1736147 18532 15000013 45800 111492 205283 1778413 17500 15000013 45700 110773 213849 1811134 16664 15000013 45600 106644 218024 1834434 16419 15000013 45500 102663 219914 1842913 16259 15000013 45400 100338 218774 1849068 16525 15000013 45300 102289 214865 1845237 17050 15000013 45200 104161 210994 1840464 17548 15000013 45100 107659 206937 1831357 18079 15000013 45000 112103 204434 1829787 18506 15000013 44900 115739 202186 1827652 18884 15000013 44800 114251 205716 1840212 18575 15000013 44700 112034 211533 1865836 18135 15000013 44600 109433 221202 1911306 17408 15000013 44500 107797 227489 1949365 17072 15000013 44400 104201 231491 1968897 16756 15000013 44300 101028 227316 1959728 17256 15000013 44200 99087 220168 1932283 17921 15000013 44100 98535 209315 1882982 18775 15000013 44000 101875 197069 1817352 19952 15000013 43900 108467 183944 1742050 21126 15000013 43800 120232 172206 1663797 22036 15000013 43700 132884 161019 1588055 22923 15000013 43600 146265 149622 1526068 24472 15000013 43500 153222 141321 1497115 26104 15000013 43400 158207 137704 1501072 27243 15000013 43300 160080 138026 1539948 28216 15000013 43200 159607 141619 1597602 28678 15000013 43100 156927 148996 1668570 28332 15000013 43000 153281 163837 1732253 26034 15000013 42900 148472 178047 1798887 24148 15000013 42800 141141 189234 1846618 22675 15000013 42700 135140 193446 1869730 22167 15000013 42600 131564 193049 1855474 21890 15000013 42500 130647 187245 1828405 22388 15000013 42400 133002 177669 1788023 23521 15000013 42300 140875 170564 1751785 24117 15000013 42200 148462 167356 1723711 24236 15000013 42100 153034 171184 1721953 23337 15000013 42000 154680 175167 1734388 22776 15000013 41900 154778 184501 1755427 21227 15000013 41800 150354 191984 1772133 19993 15000013 41700 144127 199051 1792042 18924 15000013 41600 139575 198643 1800897 19190 15000013 41500 136806 195923 1791539 19520 15000013 41400 132500 188280 1755302 20242 15000013 41300 127287 180314 1706001 20760 15000013 41200 124045 170025 1651361 21769 15000013 41100 123228 161868 1603066 22651 15000013 41000 123366 155054 1568147 23585 15000013 40900 124469 150408 1561678 24688 15000013 40800 124174 148909 1579577 25546 15000013 40700 125110 151938 1611293 25604 15000013 40600 125602 156361 1643511 25233 15000013 40500 129130 158646 1672275 25446 15000013 40400 129140 158448 1688290 25975 15000013 40300 131810 155841 1691682 26874 15000013 40200 131179 154620 1691242 27181 15000013 40100 131682 155531 1696706 27112 15000013 40000 129031 160381 1707006 25981 15000013 39900 133643 167349 1715547 24277 15000013 39800 140432 172100 1721890 23087 15000013 39700 151704 171177 1718185 23392 15000013 39600 159853 165417 1701542 24608 15000013 39500 168465 158163 1670391 25845 15000013 39400 172416 152805 1647656 26615 15000013 39300 174633 149745 1632646 27006 15000013 39200 173047 151777 1635598 26416 15000013 39100 169618 157693 1646400 25047 15000013 39000 163578 164711 1668318 23663 15000013 38900 155971 167733 1683705 23276 15000013 38800 149487 169555 1689295 22900 15000013 38700 146295 169573 1682512 22634 15000013 38600 146777 166990 1671961 22987 15000013 38500 150413 161205 1660405 24302 15000013 38400 156375 158993 1642506 24715 15000013 38300 161656 161291 1631578 24161 15000013 38200 164031 163899 1620651 23443 15000013 38100 163528 164797 1622472 23295 15000013 38000 160582 165466 1625110 23058 15000013 37900 156020 167207 1638989 22719 15000013 37800 149487 164686 1652429 23579 15000013 37700 145290 159068 1668507 25707 15000013 37600 142856 152793 1663420 27592 15000013 37500 143959 147367 1644453 29051 15000013 37400 148167 140330 1609660 30183 15000013 37300 155271 135449 1576939 30650 15000013 37200 158444 133901 1547359 29895 15000013 37100 156818 136967 1534798 28371 15000013 37000 149063 141575 1536870 26732 15000013 36900 138747 144926 1556151 26216 15000013 36800 127888 146314 1575746 26322 15000013 36700 121582 147262 1595843 26674 15000013 36600 120774 147708 1609723 26941 15000013 36500 124459 146822 1619457 27561 15000013 36400 126795 145416 1615564 27910 15000013 36300 128884 145533 1599046 27418 15000013 36200 129465 146469 1570408 26231 15000013 36100 132096 145546 1544909 25759 15000013 36000 135219 145131 1529271 25340 15000013 35900 140589 144251 1528015 25527 15000013 35800 143890 142709 1534484 26141 15000013 35700 145989 139321 1536305 27264 15000013 35600 144432 138769 1528769 27222 15000013 35500 141663 138422 1517464 27046 15000013 35400 138885 139259 1501009 26312 15000013 35300 140432 137766 1493536 26705 15000013 35200 141644 138329 1493850 26664 15000013 35100 144176 137035 1511812 27779 15000013 35000 146807 135932 1523116 28588 15000013 34900 151625 132928 1533039 29976 15000013 34800 155567 130320 1528894 31045 15000013 34700 159035 127124 1522488 32114 15000013 34600 162523 123990 1503207 32759 15000013 34500 162504 123575 1488763 32323 15000013 34400 158680 124764 1479279 31532 15000013 34300 154138 128375 1478274 29848 15000013 34200 151418 130500 1472811 28630 15000013 34100 149970 132222 1464018 27459 15000013 34000 151872 131671 1456733 27424 15000013 33900 158680 131516 1461129 27609 15000013 33800 165410 131479 1465400 27740 15000013 33700 167647 133417 1486941 27764 15000013 33600 164149 134669 1511435 28203 15000013 33500 160158 136620 1544972 28686 15000013 33400 153764 135901 1556967 29466 15000013 33300 149536 135703 1566514 29913 15000013 33200 149182 131702 1551818 30978 15000013 33100 153714 128586 1525942 31239 15000013 33000 157902 121878 1477144 32365 15000013 32900 159607 117096 1438017 33255 15000013 32800 157518 111273 1399770 34628 15000013 32700 155754 109390 1371194 34491 15000013 32600 153034 107111 1347643 34852 15000013 32500 152079 107241 1342681 34710 15000013 32400 151862 108207 1336778 34069 15000013 32300 153399 109279 1333260 33456 15000013 32200 156828 107947 1330560 34161 15000013 32100 160523 104590 1328111 35901 15000013 32000 162149 102539 1316618 36465 15000013 31900 161981 101895 1304182 36291 15000013 31800 159518 103859 1296269 34886 15000013 31700 155665 105878 1294950 33729 15000013 31600 149418 108207 1303554 32972 15000013 31500 143743 107835 1316555 33856 15000013 31400 139841 105903 1332884 35650 15000013 31300 139417 102366 1334203 37420 15000013 31200 139190 99430 1330372 38615 15000013 31100 139111 99201 1315424 37669 15000013 31000 141614 100619 1299409 35906 15000013 30900 145753 103239 1280882 33444 15000013 30800 151271 104137 1275481 32822 15000013 30700 153724 104181 1273158 32869 15000013 30600 156808 102682 1284776 34361 15000013 30500 158079 102291 1300979 35381 15000013 30400 159745 100501 1329492 37854 15000013 30300 158641 99461 1357314 39823 15000013 30200 159094 97485 1380489 42322 15000013 30100 161725 96568 1379107 43013 15000013 30000 163381 93446 1363218 44495 15000013 29900 164661 91767 1342493 44493 15000013 29800 165982 90225 1333449 45053 15000013 29700 169007 90652 1334956 44766 15000013 29600 171628 89723 1345319 46199 15000013 29500 172209 91210 1353169 45859 15000013 29400 172377 92635 1353672 45242 15000013 29300 170761 94815 1345570 43396 15000013 29200 167253 96283 1336589 41820 15000013 29100 161971 97107 1325598 40683 15000013 29000 157626 97218 1322019 40338 15000013 28900 154916 94654 1318439 42108 15000013 28800 156188 94134 1317999 42686 15000013 28700 158542 92889 1315990 43949 15000013 28600 159331 94790 1322709 42942 15000013 28500 159252 93880 1335145 44072 15000013 28400 157912 94951 1344816 43362 15000013 28300 156611 93613 1350406 44271 15000013 28200 156976 94319 1350720 43261 15000013 28100 160592 93966 1344628 42857 15000013 28000 163262 94456 1326855 41373 15000013 27900 161173 95521 1307511 39728 15000013 27800 152798 95354 1289800 39169 15000013 27700 143516 94245 1282452 40074 15000013 27600 136678 92889 1281385 41421 15000013 27500 135505 93322 1286409 41666 15000013 27400 141614 93626 1290240 41567 15000013 27300 148521 94220 1290805 40856 15000013 27200 156867 95868 1281699 38807 15000013 27100 159685 96227 1277679 38564 15000013 27000 164287 94846 1271838 39583 15000013 26900 166149 91414 1266249 42167 15000013 26800 169963 89234 1251616 42937 15000013 26700 168120 87456 1229383 43125 15000013 26600 163499 87456 1204638 41366 15000013 26500 156059 88844 1186802 38989 15000013 26400 148669 89891 1180208 37357 15000013 26300 145024 90460 1182406 37075 15000013 26200 146472 88893 1195532 39031 15000013 26100 153951 87357 1220842 41700 15000013 26000 161439 85604 1254505 44963 15000013 25900 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15000013 16400 159242 74287 1127767 47872 15000013 16300 158207 76040 1151569 47299 15000013 16200 153606 76257 1184416 49502 15000013 16100 150039 77384 1210730 50380 15000013 16000 145595 77620 1233717 51938 15000013 15900 144432 79237 1256452 51746 15000013 15800 142471 80921 1271964 51047 15000013 15700 138816 83393 1272215 48219 15000013 15600 134865 83752 1261350 46871 15000013 15500 131790 82792 1243451 46403 15000013 15400 131731 78914 1215190 48897 15000013 15300 132677 74665 1186488 51782 15000013 15200 134628 71048 1161367 54185 15000013 15100 137762 68849 1146168 55677 15000013 15000 136481 68446 1135869 55524 15000013 14900 133209 68384 1135052 55762 15000013 14800 129583 67734 1133670 57532 15000013 14700 128351 67461 1135303 59319 15000013 14600 128844 66972 1135492 61373 15000013 14500 132628 66749 1141207 62646 15000013 14400 137949 65646 1138883 63987 15000013 14300 140018 66631 1137627 61740 15000013 14200 140865 67573 1132414 58844 15000013 14100 140974 68000 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148502 66359 1135554 60513 15000013 11600 146344 65256 1144473 63405 15000013 11500 140639 67052 1155714 61884 15000013 11400 138609 70143 1161241 58545 15000013 11300 136776 73383 1169782 54179 15000013 11200 140599 75074 1173990 51426 15000013 11100 142383 75594 1170913 49375 15000013 11000 146689 73705 1165449 50863 15000013 10900 148521 71791 1160990 52515 15000013 10800 152867 71060 1157285 52997 15000013 10700 153980 72615 1151444 50977 15000013 10600 155133 73532 1148806 50120 15000013 10500 154798 74448 1146042 49180 15000013 10400 155143 74795 1141835 48723 15000013 10300 150739 74820 1146545 49611 15000013 10200 145615 74256 1162183 51824 15000013 10100 140314 73748 1179894 53805 15000013 10000 139496 74244 1193836 53861 15000013 9900 137899 74696 1198672 53426 15000013 9800 141614 73779 1197165 55069 15000013 9700 145033 73538 1182029 55380 15000013 9600 150699 72739 1173048 57444 15000013 9500 148541 73606 1171039 57487 15000013 9400 146275 73637 1176063 58552 15000013 9300 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158405 600970 1941515 -4233 15000013 6800 158887 594262 1919785 -4253 15000013 6700 161439 596207 1928012 -4289 15000013 6600 163469 607945 1948360 -4430 15000013 6500 163972 618543 1980830 -4468 15000013 6400 161232 620302 2002434 -4364 15000013 6300 163991 612727 2014430 -4100 15000013 6200 167519 603658 2025358 -3808 15000013 6100 177244 597935 2043068 -3542 15000013 6000 183265 597340 2061784 -3404 15000013 5900 193424 599465 2080186 -3331 15000013 5800 193690 609524 2106186 -3401 15000013 5700 191335 633694 2134636 -3731 15000013 5600 179156 661364 2181174 -4027 15000013 5500 170465 686407 2232045 -4214 15000013 5400 159242 703441 2274940 -4297 15000013 5300 153596 713860 2296230 -4373 15000013 5200 148068 710763 2298052 -4316 15000013 5100 146314 703553 2285177 -4259 15000013 5000 141792 695847 2259302 -4274 15000013 4900 136195 695605 2243475 -4358 15000013 4800 129948 700313 2248060 -4425 15000013 4700 125563 710329 2272239 -4478 15000013 4600 123888 720971 2302573 -4509 15000013 4500 123375 724638 2335734 -4385 15000013 4400 121306 727790 2376619 -4210 15000013 4300 118360 734871 2410407 -4137 15000013 4200 113591 747408 2455815 -4106 15000013 4100 107423 759307 2497265 -4090 15000013 4000 100712 773950 2542610 -4111 15000013 3900 93096 774991 2547759 -4092 15000013 3800 86100 750839 2503546 -3812 15000013 3700 80562 693128 2369397 -3394 15000013 3600 78611 618915 2159507 -3108 15000013 3500 78325 537752 1896484 -3046 15000013 3400 79419 465812 1644579 -3150 15000013 3300 81084 411532 1432490 -3451 15000013 3200 82897 383429 1290240 -3871 15000013 3100 81922 368631 1215692 -4084 15000013 3000 78838 363341 1202503 -4031 15000013 2900 76699 359922 1217074 -3739 15000013 2800 74748 360696 1248727 -3411 15000013 2700 73941 362368 1281259 -3104 15000013 2600 72295 370049 1311342 -3054 15000013 2500 72472 375308 1327357 -3070 15000013 2400 72975 381292 1336464 -3198 15000013 2300 72965 381862 1333198 -3256 15000013 2200 71260 385237 1323840 -3471 15000013 2100 70108 388167 1314545 -3642 15000013 2000 69467 398450 1319109 -3935 15000013 1900 68994 411724 -999250 -999250 15000013 1800 68186 -999250 -999250 -999250 15000013 1700 66935 -999250 -999250 -999250 15000013 1600 63259 -999250 -999250 -999250 15000013 1500 57318 -999250 -999250 -999250 15000013 1400 49681 -999250 -999250 -999250 15000013 1300 44153 -999250 -999250 -999250 15000013 1200 39591 -999250 -999250 -999250 15000013 1100 37896 -999250 -999250 -999250 15000013 1000 37887 -999250 -999250 -999250 15000013 900 38872 -999250 -999250 -999250 15000013 800 38448 -999250 -999250 -999250 15000013 700 37394 -999250 -999250 -999250 15000013 600 36960 -999250 -999250 -999250 15000013 500 35896 -999250 -999250 -999250 15000013 400 35827 -999250 -999250 -999250 15000013 300 35709 -999250 -999250 -999250 15000013 200 36872 -999250 -999250 -999250 15000013 100 37778 -999250 -999250 -999250 15000013 000 40399 -999250 -999250 -999250 15000013
1
A review of data pertaining to the hydrocarbon prospectivity of the Savory Sub-basin Officer Basin
Western Australia
by
M K Stevens and G M Carlsen
Abstract
The Savory Sub-basin of the Officer Basin in central Western Australia is part of a large Neoproterozoic episutural basin and is a frontier for hydrocarbon exploration It contains up to 8 km of clastic carbonate and rare evaporite sedimentary rocks with minor volcanic dykes sills and flows No petroleum exploration activity had been undertaken in this sub-basin prior to 1995 and hydrocarbon prospectivity is assessed from mineral and recent petroleum exploration drilling No seismic data have been acquired An interpretation of available data suggests that source-rock quality is the major exploration risk but that further investigation of the sub-basin is warranted
Minor oil shows (fluorescence with solvent cut) recorded in Spearhole Formation sandstones in the northwest of the sub-basin suggest oil has been generated and migrated into potential reservoirs in the sub-basin
Each of the five depositional sequences recognized in the sub-basin contain potential reservoir rocks which are seen in outcrop as friable sandstones The Durba Sandstone is interpreted as the best-quality reservoir Indications of evaporitic environments from the Mundadjini Skates Hills and Boondawari Formations suggest that seals may be provided by evaporites and mudstones Neoproterozoic to Cambrian rocks may provide structural closures including both fold and fault traps for migrating hydrocarbons Salt diapirs are interpreted from the gravity data A large semi-detailed gravity survey in the eastern part of the sub-basin revealed major folds faults and halokinetic structures
Potential source rocks include marine mudstones of the Skates Hills and Mundadjini Formations which are associated with stromatolitic dolomites and evaporites Rare outcrops of black mudstones from other units such as the Boondawari Formation also suggest source potential
The Geological Survey of Western Australia has drilled one stratigraphic hole (Trainor 1) in the sub-basin to assess the source potential of Neoproterozoic sedimentary rocks Five of the six samples analysed for Total Organic Carbon in the Cornelia Formation from this well exceeded 05 but have a high level of maturation with at best dry gas-generating potential The age of the Cornelia Formation is uncertain but at least part of it is interpreted to be Neoproterozoic and hence part of the Savory succession
Maturity data which are very sparse due to limited drilling are inferred from the Thermal Alteration Index of organic matter to be at about the base of the oil window and the top of the gas window in two
2
waterbores in the southeast of the sub-basin and a mineral drillhole in the north of the region Rock cuttings from a waterbore in the southwest of the sub-basin are overmature for hydrocarbon generation but this bore intersected mafic intrusives and hence may not be representative of maturity for the region
KEYWORDS hydrocarbon prospectivity oil shows Neoproterozoic Savory Sub-basin Officer Basin source rocks diamond drilling
Introduction
Recognition in the late 1980s of a thick sequence of generally weakly deformed Neoproterozoic
sedimentary rocks of relatively low thermal maturity previously included within the
Mesoproterozoic Bangemall Basin (defined as the Savory Basin by Williams 1992) revealed a
hydrocarbon exploration frontier The Savory Sub-basin (Fig 1) now recognized as part of the
Officer Basin is located west of outcrops of Phanerozoic cover rocks of that larger basin The
Officer Basin a large episutural basin which contains clastic carbonate and minor evaporite and
volcanic rocks is considered to be part of the Neoproterozoic Centralian Superbasin (Walter and
Gorter 1994) The age of the Officer Basin successions is not well constrained but in the Savory
Sub-basin it is largely Neoproterozoic with possible Palaeozoic strata present in parts
The boundaries defined by Williams (1992) for the sub-basin have been largely used in this
record but data from sedimentary rocks previously assigned to older basins that are now
recognised or inferred to be of early Neoproterozoic age (Supersequence 1) have been used to
assess the hydrocarbon potential of the northwestern part of the Officer Basin
The southern part of the sub-basin unconformably overlies the Mesoproterozoic Bangemall Basin
The western boundary of the sub-basin is faulted against the Bangemall Basin The eastern
boundary of the Savory Basin as defined by Williams (1992) was placed along the western edge
of Phanerozoic outcrops of the Officer Basin at approximately 123degE longitude Recent studies
(Perincek 1996ab) however have indicated there is little difference in the Neoproterozoic
geology of the two regions The northeastern boundary of the sub-basin was defined as a reverse-
and thrust-faulted contact with the Yeneena and Karara Basins of the Paterson Orogen (Williams
1992) However Bagas et al (1995) subdivided strata from the Yeneena Basin into three new
groups the Throssell Lamil and Tarcunyah Groups The older and more deformed Throssell and
Lamil Groups remain part of the Yeneena Basin and the Paterson Orogen The younger and less-
deformed sedimentary rocks of the Yeneena and Karara Basins were considered to be of
Supersequence 1 age and were reassigned to the Tarcunyah Group The Tarcunyah Group was
considered to be coeval with the older strata of the Savory Sub-basin The Tarcunyah Group
Savory Sub-basin and Officer Basin were grouped into a single tectonic unit which was informally
referred to as the greater Officer Basin (Bagas et al 1995)
3
50 km
120deg 121deg30 123deg
25deg
24deg
23deg
22deg
Blake Fault andFold Belt
Wells Foreland S
ub-basin
TrainorPlatform
MKS32200498
HamersleyBasin
PilbaraCraton
YeneenaBasin
YeneenaBasin
YeneenaBasin
CanningBasin
Sylvania Inlier
BangemallBasin
Bangemall Basin
YilgarnCraton
YilgarnCraton
GlengarryBasin
EaraheedyBasin
Ward Inlier
OldhamInlier
KararaBasin
GibsonSub-basin
(Officer Basin)
WestwoodShelf
(Officer Basin)
KingstonShelf
(Officer Basin)
Rudall Complex
Trainor Platform
(Kahrban Subgroup)
Greater Officer Basin
Savory Sub-basin
Surface anticlinesMAP
AREAPerth
Figure 1 Structural subdivisions of the Savory Sub-basin and surface anticlines
4
During 1994 in consultation with the Petroleum Industry the Department of Minerals and
Energy received State Government funding for a Petroleum Exploration Initiative to be
undertaken by the Geological Survey of Western Australia (GSWA) with a view to identifying
prospective onshore areas for oil and gas thus increasing the level of onshore exploration in
Western Australia This initiative was originally funded for the first three years of a five-year work
program Two teams of specialists were formed to investigate the prospectivity of both the western
margin and interior onshore sedimentary basins
The Petroleum Exploration Initiative teams seek to enhance the prospectivity of onshore
basins by reducing through focused investigations the risks perceived by industry to be factors
limiting exploration activity Comprehensive petroleum system reports of the onshore Western
Australian basins are to be completed as a result of the projects undertaken during the five-year
Initiative The objective of the Initiative will be achieved through both the analysis of open-file
exploration data and the acquisition of new data New data will include but not be limited to
geophysical surveys and stratigraphic drilling Project results are to be reported to the industry
through GSWA publications external publications conference reports and oral presentations
This Record is the third in a series of comprehensive reviews by the GSWA of the
hydrocarbon prospectivity of some of Western Australiarsquos interior onshore sedimentary basins
The first Record of this series covered the Canning Basin (Apak and Carlsen 1997) The second
Record reviewed the Western Australian Officer Basin (Perincek 1998) but excluded the Savory
Sub-basin
This study assesses the potential for hydrocarbon exploration within the Savory Sub-basin
based on available geological and geophysical data and defines the scope for future studies
Publications relevant to this investigation but which are not specifically referred to are listed in
Appendix 1
Access and climate
The Savory Sub-basin lies east and southeast of the mining town of Newman in the Pilbara region
(Fig 2) The area is largely uninhabited the only settlement being an outcamp at Poondawari on
the GUNANYA 1250 000 map sheet The outcamp is linked by a graded track to the Jigalong
Community 90 km to the west just outside the northwest margin of the sub-basin A few pastoral
leases lie along the margins of the sub-basin but the majority of the region is Vacant Crown Land
Capitalized names refer to standard map sheets
5
Sealed road
Gravel road
Track
Town
Homestead
Locality
STANLEYSavory Sub-basin boundary 1250 000 map sheet
CornerTrack
Talawana - Windy
Route
Watch Point
NEWMAN
JigalongCommunity
RobertsonRange (abd)
Wokalba
Poondawari
Balfour Downs
Billinnooka
Weelarrana
Beyondie(abd)
Kumarina
Marymia
Glen-ayle
White Lake
Hanging RockBoorabee Hill
WellsRa
EmuRa
Robertson
Ra McFadden R
a
DiebillHills
DurbaHills
Calvert Ra
WardHills
Cornelia Ra
KellyRaBlakeHills
HillsDean
ROBERTSON GUNANYA
TRAINORBULLEN
BALFOUR DOWNS RUDALL
NABBERU STANLEY HERBERT
50 km
Woora Woora Hills
120deg 121deg30 123deg
25deg
24deg
23deg
22deg
Goldfieldsnatural gaspipeline
GR
EA
TN
OR
TH
ER
NH
IGH
WA
Y
Mar
ble
Bar
Nul
lagi
ne-
Rd
MADLEY
Can
ning
Stoc
k
MKS31120598
Goldfields natural gas pipeline
Figure 2 Localities and access routes of the Savory Sub-basin
6
The sealed Great Northern Highway lies west of the Savory Sub-basin and links Meekatharra
to Newman The TalawanandashWindy Corner graded track crosses the northern part of the sub-basin
and graded pastoral station tracks on Balfour Downs Weelarrana Kumarina Marymia and Glen-
Ayle give access to the western and southern margins The Canning Stock Route traverses the sub-
basin from north to south and is a well travelled four-wheel-drive track allowing access to the
eastern half of the sub-basin Additional minor tracks also provide access to other parts of the area
(Williams 1992) Recently flown monochrome aerial photography at 150 000 and Landsat TM
imagery covering the sub-basin is available from the Department of Land Administration
Cross-country access is similar to that in the Canning Basin with the average height of sand
dunes being lower in the Savory Sub-basin Potable water has been found in water bores in the
south of the sub-basin and is inferred to be present throughout the region Fuel and supplies are
available at Wiluna Meekatharra and Newman A good working relationship with the Western
Desert Community who hold native title claims over most of the sub-basin has been established
by GSWA
There are no meteorological stations within the Savory Sub-basin but estimates based on data
from nearby Bureau of Meteorology Stations indicate that the area is arid and has its maximum
rainfall in summer from monsoonal rains The sub-basin has reasonable access and a tolerable
working climate for all exploration activities Meteorological data for the town of Wiluna which
lies about 180 km to the south of the sub-basin are included as Appendix 2
Regional geology
Stratigraphy
Thirteen formations were recognized by Williams (1992) in the Savory Sub-basin and these are
summarized in Table 1 Although unconformities were recognized between some of the
formations and they reflect a wide range of depositional environments provenance and climatic
conditions these formations were defined by Williams (1992) as constituting the Savory Group
Five depositional sequences that are generally unconformity-bounded were recognized by
Williams (1992) (Fig 3) The correlation of significant formations within the sub-basin with other
parts of the Centralian Superbasin is shown in Figure 4 with the four Neoproterozoic
Supersequences having been defined by Walter et al (1995)
7
Durba Ss
McFadden
Woora Woora400
Tchukardine700
Skates Hills
Mundadjini1800
B
Coondra
(B)
Watch Point
Spearhole1100Jilyili
1000(A)
Glass Spring1600(A)
Brassey Range1700(A)
Abs
ent
Absent Absent
Absent
Absent
Absent
A
B
C
D
E
1A
1B
3
4A
4B
1000
2000
3000
4000
5000
6000
Max
imum
thic
knes
s
Sup
erse
quen
ce
AG
EN
EO
PR
OT
ER
OZ
OIC
NE
OP
RO
TE
RO
ZO
ICT
O
CA
MB
RIA
NM
AR
I-N
OA
N
NW SE
Savory Sub-basin Stratigraphy
MKS30 120598
Fault boundary
Unconformity
Disconformity
Conglomerate
Sandstone Mudstone
Siltstone
Evaporite
Dolomite
Boondawari800 Boondawari
Supersequence 2 is not represented in the Savory Sub-basin Total thicknesses are estimated from air photo interpretation Thicknesses of recessive units are unknown
Diamictite
Dep
ositi
onal
seq
uenc
e
Figure 3 Formations lithology and depositional sequences AndashE of the Savory Sub-basin
8
Table 1 Summary of formations in the Savory Sub-basin
Formation Super Depo Lithology Thickness Depositional Savoy Comments Seq(a) Seq(b) (m) environment Group(c)
Durba Sandstone 4 E Quartz sandstone with minor 100 Fluvial lacustrine Y Excellent reservoir basal conglomerate lenses Woora Woora 4 D Medium-grained ferruginous 400 Shallow marine deltaic Y Formation sandstone lithic sandstone quartz wacke siltstone McFadden 4 D Laminated fine- to coarse-grained 1 500 Shallow marine deltaic Y Possible reservoir Formation quartz sandstone feldspathic sandstone quartz wacke minor conglomerate siltstone Tchukardine 4 D Medium- to coarse-grained sandstone 700 Shallow marine Y Formation lithic sandstone quartz wacke conglomerate lenses siltstone minor shale Boondawari 3 C Glacigene diamictite sandstone siltstone Formation shale conglomerate minor dolomite (some stromatolitic and oolitic) rhythmite 800 Glacial shallow marine Y Possible source rock Skates Hills 1 B Thin-bedded dolomite (some stromatolitic) 200 Shallow marine sabkha Y Possible source rock Formation chert evaporites fine- to medium-grained sandstone siltstone shale patchy basal conglomerate Mundadjini 1 B Fine- to coarse-grained sandstone 1 800 Deltaic sabkha Y Possible source rock Formation conglomerate siltstone minor shale shallow marine mudstone dolomite (some stromatolitic) and evaporites Coondra 1 B Coarse- to medium-grained sandstone 1 000 Fan delta Y Possible reservoir Formation poorly sorted conglomerate pebbly sandstone Spearhole 1 B Coarse- to medium-grained sandstone 1 100 Braided fluvial deltaic Y Possible reservoir Formation pebbly sandstone siltstone and oil shows in conglomerate lenses Mundadjini 1 Boondawari 1
9
Watch Point 1 B Shale siltstone fine- to medium-grained 400 Shallow marine deltaic Y Formation sandstone glauconitic sandstone Jilyili Formation 1 A Fine-grained sandstone siltstone minor shale mudstone conglomerate lenses 1 000 Deltaic Y Brassey Range 1 A Fine- to medium-grained sandstone 1 700 Fluvial deltaic Y Formation siltstone shale minor mudstone Glass Spring 1 A Medium- to coarse-grained sandstone 1 600 Shallow marine fluvial Y Formation minor conglomerate and siltstone Tarcunyah Group 1 AampB Quartz sandstone feldspathic sandstone Shallow marine sabkha N Bitumen in LDDH1 quartz wacke shale siltstone fluvial lacustrine conglomerate evaporites dolomite Cornelia 1 A Sandstone siltstone shale mudstone Shallow marine N Overmature source rocks Formation minor glauconitic sandstone deep marine in Trainor 1 Kahrban 1 A Sandstone siltstone shale 1 700 Shallow marine deltaic N Subgroup
NOTES (a) Supersequences of Walter et al (1995) (b) Depositional sequences of Williams (1992) (c) Y= assigned to Savory Group in Williams (1992) N= previously considered to be older than the Savory Group but now included in the greater Officer Basin
10
SAVORY SUB-BASIN GIBSON SUB-BASINCENTRAL OFFICERBASIN
AMADEUS BASIN
PETERMANN RANGES OROGENY
NE
OP
RO
TE
RO
ZO
IC
ST
UR
TIA
NM
AR
INO
AN
ED
IAC
AR
IAN
CAMBRIANTO
NEOPRO-TEROZOIC
AG
E (
Ma)
SOUTHS RANGE MOVEMENT
AREYONGA MOVEMENT
Steptoe
MILES OROGENY
Mission Group
Cassidy Group
Rudall Complex
Bangemall Group
unnamed
Tar
cuny
ah G
roup
4
3
2
1
MKS12a 180598
500
550
600
650
700
750
800
850
900
SU
PE
R
SE
QU
EN
CE
unnamed
Tchukardine Fm
McFadden Fm
ArumberaSst
Julie Fm
Pertatataka Fm
Olympic FmPioneer Sst
Boondawari Fm
Turkey Hill FmLupton Fm
Kanpa Fm
Neale FmBabbagoola
FmHussar
Fm
Browne Fm
Woolnough Fm
Madley Fm
Bitt
er S
prin
gs F
m
LovesCreek M
Gillen M
Heavitree Fm
Arunta Complex
Throssell Group
TownsendQuartzite
Earaheedy Group
olderCornelia Fm
Jilyili Fm
SpearholeFm
MundadjiniFm
Skates Hills Fm
Lefroy Fm
Areyonga Fm
Aralka Fm
ME
SO
-P
RO
TE
RO
ZO
IC
Waters Fm
youngerCornelia Fm
Brassey RangeFormationKahrban
Subgroup
GlassSpring
Fm
Durba Sst
LP1ALP1B EVENT
Figure 4 Correlation of Savory Sub-basin formations with the western Officer and Amadeus Basins Fm = Formation Sst = Sandstone M = Member
11
The depositional sequences recognized in the sub-basin are an order of magnitude thicker than
those described from Phanerozoic passive-margin settings (Payton 1977 Posamentier et al 1988)
and are broadly comparable in scale to the second-order cycles of Vail et al (1977) and to the
megasequences of Hubbard et al (1985) The main subsurface data available to reveal the
unweathered nature of these rocks are Trainor-1 and the three-well diamond coring program in
Petroleum Permit EP 380 (Akubra 1 Boondawari 1 Mundadjini 1) completed in late 1997 in the
central west of the sub-basin (Figs 5 and 6)
The ages of all formations in the Savory Sub-basin are poorly constrained The only fossils
known are stromatolites and palynomorphs (acid-insoluble microfossils) Palynology from
available wells is summarized in Appendix 3 from Grey and Stevens (1997) and Grey and Cotter
(1996) and correlations using stromatolite biostratigraphy (Stevens and Grey 1997 Grey 1995f
Walter et al 1994 1995) are consistent with a Neoproterozoic age for the formations for which
data are available
A dolerite within the Boondawari Formation gave a poorly constrained RbndashSr age of about
640 Ma (Williams 1992) SHRIMP UndashPb dating of sedimentary zircons from the McFadden and
Cornelia Formations in stratigraphic drillhole Trainor 1 are discussed in Stevens and Adamides (in
prep) and Nelson (1997) The youngest ages from these analyses indicate that the maximum age
of the Cornelia Formation is Early Cambrian or Sturtian but these ages are inconsistent with
previous tectonic interpretations (Williams 1992) and current stratigraphic correlations which
suggest the Cornelia Formation is of Supersequence 1 age or older (Fig 4)
Depositional Sequence A Supersequence 1
Depositional Sequence A includes the Glass Spring Jilyili and Brassey Range Formations (Fig
3) All of these units are predominantly quartzose sandstones some of which are friable and have
significant visible porosity in outcrop Conglomerates are present in the Glass Spring and Jilyili
Formations
Depositional Sequence B Supersequence 1
Depositional Sequence B consists of the Watch Point Coondra Mundadjini Spearhole and
Skates Hills Formations (Fig 3) All of these formations contain beds of quartzose sandstone and
some also contain conglomerates The porosity of dolomites in the Skates Hills Formation appears
poor in surface exposures but its subsurface characteristics are unknown
12
50 km
120deg 121deg30 123deg
25deg
24deg
23deg
22deg
Greater Officer Basin
PNCEXP CA11PNCEXP CA12
PNCEXP CA13PNCEXP CA19
PNCEXP CA05
PNCEXP CA09
BD134589
GSWA Trainor 1 and TWB123
Fortescue River 1A
Mundadjini 1
Akubra 1Boondawari 1
TWB4TWB5
TWB6
TWB7
TWB8
TWB9
TWB10
BWB1
BWB2 BWB3
BWB4
BWB5
OD23
Mineral exploration drillhole
Stratigraphic drillhole
Waterbores and wells(TWB and BWB serieswaterbores identified)
MKS33270398
LDDH 1
Savory Sub-basin
Canning SR Well 13
EP380
Petroleum Exploration permit
Petroleum exploration well
Figure 5 Locations of petroleum exploration wells mineral exploration and stratigraphic drillholes water bores and wells and petroleum exploration permit EP380 in the Savory Sub-basin
13
TD=600m
TD=1367m
TD=701m
TD=709m
TD=50m
SS
1S
S1
SS1
SS
1S
S1
SS
1
SS
1
SS1
SS4 SS1
Pha
nero
zoic
or
SS
2
Cz
CzCz
Karst Bitumen
SS1
TD=181m
Mundadjini 1 Akubra 1 Boondawari 1 LDDH 1 Trainor 1 TWB 6
Munda-djini Fm
Spear-hole Fm
Munda-djini Fm
Munda-djini Fm
Spear-hole Fm
Spear-hole Fm
Waters Fm
McFadden Fm
Cornelia Fm
Cornelia Fm
Cornelia Fm
511 plusmn 13Maor 696 plusmn 20Ma(maximum)
779 plusmn 10Ma(maximum)
Mundadjini 1
Akubra 1 Boondawari 1
LDDH 1
Trainor 1TWB 6100 km
N
LOCATION
NW SE
Sea level
0m AHD
Dolerite basalt
Conglomerate
Sandstone
Mudstone
Dolomite
Limestone
Evaporite
TOC gt08
Permeability gt100md
Oil fluorescence
Sedimentary zircon U-Pb age
Identifiable polymorphs
Cainozoic
Supersequence 1 age
Unconformity
Formation contact
Cz
SS1
r
r
0
100
200
metres
VerticalScale
MKS36 120598
LEGEND
Figure 6 Geological cross section through significant drillholes in the Savory Sub-basin
14
Depositional Sequence C Supersequence 3
Depositional Sequence C consists of the Boondawari Formation (Fig 3) and although it contains
sandstone conglomerate and dolomite the sandstones contain significant amounts of feldspar and
clay and hence are likely to be poorer reservoirs than older sandstones
Depositional Sequence D Supersequence 4
Depositional Sequence D includes the McFadden Tchukardine and Woora Woora Formations
(Fig 3) The McFadden Formation is poorly sorted and sandstones contain significant amounts of
feldspathic clasts in the north of the basin but are significantly coarser and cleaner in the northeast
of the sub-basin (Williams 1992)
Sandstones of the Tchukardine and Woora Woora Formations are generally cleaner than those
of the McFadden Formation and are expected to have fair to good porosity although the
Tchukardine Formation has a higher clay content in parts
Depositional Sequence E Supersequence 4
Depositional Sequence E consists of the Durba Sandstone (Fig 3) a coarse sandstone with minor
conglomerate which has good to excellent visible porosity in surface exposures
Other depositional sequences and regional correlations
Sedimentary rocks which were not included in the Savory Group by Williams (1992) but which
are likely to be of Neoproterozoic age and hence part of the greater Officer Basin include the
Tarcunyah Group the Cornelia Formation and the Kahrban Subgroup
As discussed in the Introduction all of the strata in the Karara Basin and the younger strata
of the Yeneena Basin were redefined to form the Tarcunyah Group of the greater Officer Basin
(Bagas et al 1995) (Fig 7) In outcrop the Tarcunyah Group consists predominantly of quartzose
feldspathic and arkosic sandstone shale which is carbonaceous in parts and carbonate which
includes stromatolitic dolomite Mineral hole LDDH1 drilled on GUNANYA intersected the
15
120598
122deg
123deg
21deg
22deg
23deg
24deg
23deg
22deg
21deg
122deg
123deg
Fault
Thrust
Reverse thrust
CANNINGBASIN
OFFICERBASIN
GROUP
PILBARACRATON
TARCUNYAH
SAVORY GROUP
BANGEMALL
GROUP
THROSSELL
GROUP
LAMIL
GROUP
ConnaughtonTerrane
TerraneTalbot
complexTabletop granitic
Tabletop Terrane
Permian
Neoproterozoicgranitoid
50 km
FormationWaltha Woora
McKay Fault
South west Thrust
Vines
Fault
24deg
120deg
YENEENA CANNINGBASIN
ARUNTAINLIERRUDALL
COMPLEX
AMADEUSBASIN
MUSGRAVEBLOCK
OFFICERBASINYILGARN
CRATON
GROUP
GROUP
GROUP
PILBARACRATON
GROUP
EARAHEEDY
GLENGARRY
BANGEMALL
WYLOO GROUP
SAVORY
WA
CARNARVONBASIN
GASCOYNECOMPLEX
GROUPTARCUNYAH
400 kmGROUP
SA
N
T
CamelndashTabletopfault zone
KAHRBANSUBGROUP
CORNELIAFORMATION
MKS37
Figure 7 Regional geological setting of the Savory Group and western Officer Basin The dashed line on the inset map marks the interpreted margin of the greater Officer Basin
16
Tarcunyah Group and consists predominantly of mudstone with minor sandstone limestone
dolomite and anhydrite (Fig 6)
The age of the Tarcunyah Group is uncertain although limited palynological and stromatolite
evidence suggests that it is probably coeval with Supersequence 1 of the Centralian Superbasin
Drillhole LDDH1 contains palynomorphs equivalent to assemblages in the Browne and Bitter
Springs Formations of the Officer and Amadeus Basins respectively and from the Cornelia
Formation in TWB 6 (Grey and Stevens 1997) (Figs 4 and 6) Stromatolite specimens tentatively
assigned to Acaciella australica (Howchin 1914) Walter 1972 occur in the lower Tarcunyah
Group (Bagas et al 1995) The stromatolite Baicalia burra Preiss 1972 and a conical
stromatolite were reported from the upper part of the Tarcunyah Group (Stevens and Grey 1997)
The recognition of two stromatolite assemblages interpreted to have age significance in
Supersequence 1 sedimentary rocks of the Centralian Superbasin has permitted biostratigraphic
correlations between outcrop and well data The Acaciella australica assemblage appears to be
slightly older than 800 Ma and is restricted to the middle part of Supersequence 1 The Baicalia
burra assemblage is considered to be slightly younger than 800 Ma and occurs in the upper part
of Supersequence 1 (Grey 1996b Stevens and Grey 1997) The older A australica assemblage
is recognized in the Skates Hills Formation in the Savory Sub-basin and the stromatolite A
australica itself has been tentatively identified in the lower Tarcunyah Group The occurrence of
the A australica assemblage in the Woolnough Madley and Browne Formations of the Officer
Basin and in the Loves Creek Member of the Bitter Springs Formation of the Amadeus Basin
allows correlations throughout the Centralian Superbasin (Fig 4)
The younger B burra assemblage has not been recognized in sedimentary rocks of the
Savory Group as defined by Williams (1992) but it occurs in the upper parts of the Tarcunyah
Group and allows correlation of this group with outcrops of the Neale Formation and with the
Kanpa Formation in petroleum exploration well Hussar 1 both located in the central Officer Basin
of Western Australia (Fig 4) (Grey 1996b Stevens and Grey 1997) The occurrence of the B
burra assemblage in these units permits their correlation with the Burra Group in the Adelaide
Geosyncline of South Australia (K Grey unpublished data)
The Cornelia Formation and Kahrban Subgroup outcrop in the southeast of the sub-basin and
were considered by Williams (1992) to be part of the Mesoproterozoic Bangemall Basin Limited
evidence suggests that all or parts of these two units are of Neoproterozoic age The Ward and
Oldham Inliers consist of outcrops of the Cornelia Formation Waterbore TWB 6 which was
drilled on TRAINOR in the Cornelia Formation contains palynomorphs consistent with a
Supersequence 1 age (Grey and Stevens 1997) (Figs 5 and 6) In outcrop the Cornelia Formation
17
consists predominantly of sandstone and quartzite with lesser siltstone shale mudstone and chert
In Trainor 1 this formation consists predominantly of indurated mudstone with minor sandstone
chert and dolomite A major erosional unconformity separates the Cornelia Formation from
overlying formations and parts of the Cornelia Formation have been folded with dips exceeding
70deg In contrast the majority of the Savory Sub-basin sedimentary rocks have dips of less than 30deg
except where they are adjacent to faults The Cornelia Formation apparently consists of an older
unit of steeply dipping quartzites cherts and well-indurated mudstones and a younger unit of
shallower dipping sandstones which are sub-friable in parts However caution should be used in
interpreting the age of units based on their structural deformation and additional mapping and age
dating of this formation is required
It is proposed here that the Kahrban Subgroup is likely to be of early Neoproterozoic age and
hence should be considered as part of the greater Officer Basin This proposal is based largely on
the relatively low dip of the strata (generally less than 20deg) and their west-northwest strike which
is parallel with strikes in the overlying Brassey Range Formation of the Savory Group The lower
contact of the Kahrban Subgroup is obscured but is thought to be an unconfirmity on the
Earaheedy Basin on the southeast of STANLEY (Muhling and Brakel 1985)
Structural setting
The Savory Sub-basin forms the most northwesterly sub-basin of the Neoproterozoic to
Phanerozoic Officer Basin The western boundary of the sub-basin with the Mesoproterozoic
Bangemall Basin consists of steep-reverse and strike-slip faults The northeastern boundary of the
Savory Sub-basin was mapped where Supersequence 4 formations of the Savory Group
unconformably overlie sedimentary rocks of the Karara and Yeneena Basins with the two older
units considered to be part of the Paterson Orogen (Williams 1992) This contact was defined as a
series of steeply dipping reverse faults in the northernmost parts of the sub-basin on BALFOUR
DOWNS and RUDALL and was extrapolated as an inferred reverse fault farther along strike to the
southeast on GUNANYA and MADLEY where the contact is obscured by Cainozoic sediments It is
now recognized that all the sedimentary rocks in the Karara Basin and younger sedimentary rocks
of the Yeneena Basin are from the Supersequence 1 Tarcunyah Group and part of the greater
Officer Basin (Bagas et al 1995) The northern boundary of the Tarcunyah Group and the greater
Officer Basin is in thrust-and reverse-faulted contact with the Rudall Complex and other parts of
the Paterson Orogen (Fig 7)
To the south the sub-basin unconformably overlies the Bangemall Basin The eastern
boundary of the sub-basin used in this study is where Permian and younger strata of the Officer
Basin unconformably overlie Neoproterozoic strata although there are no significant structural or
stratigraphic differences between the Neoproterozoic units
18
The sub-basin is subdivided into three principal structural areas (Fig 1) Trainor Platform
Blake Fault and Fold Belt and Wells Foreland Sub-basin (Williams 1992) A major review of
these boundaries is beyond the scope of this report but the processing of regional aeromagnetic
data (Appendix 4) and acquisition of a semi-detailed gravity survey by the GSWA in the east of
the sub-basin has enabled these tectonic units to be reassessed and some modifications are
proposed
The Wells Foreland Sub-basin (originally termed the Wells Foreland Basin in Williams 1992)
and sedimentary rocks of the Tarcunyah Group are both considered to be the northwest
continuation of the Gibson Sub-basin of the Officer Basin Aeromagnetic gravity and outcrop
data suggest that the Blake Fault and Fold Belt is significantly faulted and folded in the west but
is less deformed in the east where the thickest sedimentary section in is located on BULLEN
(Appendix 4) The Trainor Platform is reinterpreted to represent an area of the sub-basin that has
undergone major compression during the Petermann Ranges Orogeny resulting in folding and
faulting with a northwest strike This interpretation contrasts with that proposed by Williams
(1992) who envisaged that only a thin section of the Savory Group was present on the platform
Perincek (1998) has recognized nine periods of tectonic activity in the Officer Basin from the
beginning of the Neoproterozoic to the end of the Cretaceous Three major tectonic episodes are
recognized in the Centralian Superbasin The oldest event is the Areyonga Movement which is
pre-Sturtian and forms the boundary between Supersequences 1 and 2 (Fig 4) The Souths Range
Movement occurred at the end of the Sturtian at the boundary between Supersequences 2 and 3
The youngest major event is the Petermann Ranges Orogeny which occured at the end of the
Marinoan and forms the boundary between Supersequences 3 and 4
One minor and two major tectonic episodes are recognized in the Savory Sub-basin the
LP1ALP1B structural event and the Areyonga Movement and the Petermann Ranges Orogeny
respectively The LP1ALP1B structural event is revealed where the Spearhole Formations rests
disconformably and locally unconformably on the Brassey Range Jilyili and Glass Spring
Formations The Neoproterozoic Areyonga Movement (equivalent to the Blake Movement of
Williams 1992) produced folds and faults with a general northeast strike in the western and
southern parts of the region The Souths Range Movement has not been recognized in the sub-
basin This may be due to the fact that no Sturtian glacial rocks have been identified and hence it
is possible that structures attributed to the Areyonga Movement could be the result of the Souths
Range Movement or a combination of the two movements
The major tectonic event recorded in the sub-basin is the latest Neoproterozoic to Cambrian
Petermann Ranges Orogeny (equivalent to the Paterson Orogeny) which produced large reverse
19
faults thrusts strike-slip faults and folds with a general northwest strike The McFadden
Formation and other Supersequence 4 strata are considered to be at least partially coeval with this
orogeny (Williams 1992) We also interpret the Durba Sandstone as having been deposited during
the later stages of the Petermann Ranges Orogeny as this unit mildly deformed with fold axes
parallel to the strike of other structures attributed to the Petermann Ranges Orogeny
Quantitative aeromagnetic interpretation of the Savory Sub-basin utilizing the 3D Euler
deconvolution method supported by wave-number filtering and image processing has provided
structural trends and depth to magnetic source within the sub-basin (Cowan 1995) Gravity data
are interpreted by Cowan (1995) as changes in both the density of the basement rocks andor
basement topography depending on local conditions Part of Cowanrsquos report is reproduced in
Appendix 4
Exploration history
The only petroleum exploration conducted in the sub-basin has been the recent drilling in the
western part of three diamond drillholes of which two have minor oil shows (Table 2) There has
been some mineral exploration the results of which are stored in the GSWA Western Australian
Mineral Exploration (WAMEX) database system Much of the mineral exploration was in the
southwest and west where the sub-basin is in contact with the Bangemall Basin and along the
northern margin of the sub-basin Many of these mineral exploration programs included
aeromagnetic surveys and surface geochemical sampling (Fig 8)
Hydrocarbon potential
The sub-basin contains a sedimentary succession up to 8 km thick which is generally gently
folded and faulted and apparently unmetamorphosed Limited drilling has shown that thick
mudstones are present in the sub-basin with some mudstones in Trainor 1 having high Total
Organic Carbon (TOC) values Outcrops of sub-friable sandstones in many of the formations
within the sub-basin suggests widespread reservoir potential Mudstone and inferred thick
evaporite sequences are likely to form seals Maturity data suggest that near-surface samples are
approximately at the base of the oil window and top of the gas window in parts of the north and
southeast of the sub-basin However parts of the southwest of the sub-basin and the mudstones in
Trainor 1 have very high levels of maturity Numerous faults and folds have been identified from
surface mapping suggesting good potential for large structural traps Minor oil shows in
20
Table 2 Neoproterozoic formations and hydrocarbon shows in diamond drillholes in the Savory Sub-basin
Drillhole AMG Core TD (m) Approx Formation Depth Formation Depth Formation Depth Shows (AGD84) start (m) GL (m) (m) (m) (m)
LDDH 1 431148E 112 701 350 Tarcunyah 68ndash701 ndash ndash bitumen at 6623 m 7443826N Group Trainor 1 473640E 6 709 455 McFadden 9ndash83 Cornelia Fm 83ndash709 possible bitumen at 4537 m 7287400N Fm Mundadjini 1 319056E 170 600 500 Mundadjini 16ndash361 Spearhole Fm 361ndash600 10 fluorescence at 36102 m 7404844N Fm Boondawari 1 348959E 299 1 367 490 Mundadjini Fm 15ndash312 Spearhole Fm 312ndash1 283 Intrusive 1 283ndash1 367 40 fluorescence at 35364 m 5 7398174N fluorescence at 4963 m Akubra 1 334249E 15 181 530 Mundadjini 15ndash42 Intrusive 42ndash181 None 7401252N Fm
21
50 km
120deg 121deg30 123deg
25deg
24deg
23deg
22deg
Greater Officer Basin
Savory Sub-basin
1
2
3
4
6
8
3 Seismic line (prefixed N83-00)
Aeromagnetic survey
GS
WA
Sav
ory
1995
gra
vity
sur
vey
Gravity survey
MKS34270398
Figure 8 Locations of aeromagnetic and gravity surveys (other than regional BMRAGSO data)
22
sandstones in two petroleum wells in the northwest of the sub-basin and bitumen and oil shows
elsewhere in the region indicate that oil has been generated and migrated through the sub-basin
Source rocks
Source potential is considered to be the major exploration risk in the Savory Sub-basin although
minor oil shows in Mundadjini 1 and Boondawari 1 indicate that at least some oil has been
generated and migrated into potential reservoirs within the sub-basin Sandstone is the
predominant lithology observed in outcrop Outcrops of fine-grained lithologies in the basin are
rare because of intense surface weathering and erosion Only about 8 of the surface area of the
sub-basin is exposed bedrock and recessive lithologies (such as shale evaporite and friable
sandstone) may be present although they rarely outcrop
Outcrops of stromatolitic dolomite with associated cauliflower chert and cubic pseudomorphs
interpreted as being after halite indicate that evaporitic environments are present within the
Mundadjini Skates Hills and Boondawari Formations Evaporitic minerals are also present in
drillhole LDDH1 in the Tarcunyah Group
In 1995 GSWA drilled a continuous-core diamond drillhole (Trainor 1) in the sub-basin on
TRAINOR to a depth of 709 m to test for source rocks thus providing the first such data for the sub-
basin The drillhole intersected flat-lying clastics and carbonates of the McFadden Formation (9ndash
83 m) overlying indurated mudstones of the Cornelia Formation (83ndash709 m total depth) dipping at
about 40deg Of the six samples analysed from the Cornelia Formation in this drillhole the five
located between 375 and 6032 m depth have TOC values exceeding 05 (range 066ndash365)
Rock-Eval pyrolysis of these five samples indicates that they are at best in the dry-gas thermal
stage and as a result of their high level of maturation (Stevens and Adamides in prep) have poor
remaining hydrocarbon-generating potential Although the Cornelia Formation is overmature at
Trainor 1 the high TOC values are encouraging as it is likely that this sequence is less mature
elsewhere in the sub-basin
The Mundadjini Formation contains potential source rocks that comprise marine mudstones
with evaporitic minerals present in parts Thin dark mudstones were intersected in the Mundadjini
Formation in Akubra 1 In Mundadjini 1 and Boondawari 1 however the mudstones appear to be
too oxidized to have source potential
The Boondawari Formation also may be a source rock as it contains black mudstones The
unit is laterally equivalent to the Pertatataka Formation of the Amadeus Basin and the Ungoolya
23
Group of the Officer Basin in South Australia both of which have some source potential
(Summons and Powell 1991 Morton and Drexel 1997) Samples from the Dey Dey Mudstone of
the Ungoolya Group generally have poor TOC values (average 011 range 003ndash081)
moderate hydrogen index (HI) values (100ndash382) and poor to fair genetic potential with a
maximum of 292 kg hydrocarbon per tonne of source rock (Morton and Drexel 1997)
Stromatolitic dolomites and mudstones at the top of the Boondawari Formation and within the
Skates Hills Formation are potential source rocks Stromatolitic dolomite and evaporitic rocks
deposited in a marginal marine to sabkha environment are considered to have good potential to
generate and preserve organic carbon without requiring a deep-water setting (Stevens and Grey
1997) Such conditions are recognized in the Skates Hills Formation and in the upper parts of the
Tarcunyah Group
Maturity
Knowledge of the maturity of sedimentary rocks within the Savory Sub-basin is still limited From
a review of palynological studies Grey and Stevens (1997) report that the thermal maturity
inferred from the Thermal Alteration Index (TAI) of 3+ from Supersequence 1 age palynomorphs
in TWB 6 TWB 9 and LDDH1 is within the hydrocarbon window (Appendix 3) In Phanerozoic
spores and pollen a TAI of 3+ approximately equates to the end of liquid petroleum generation
and the start of dry gas generation and to a vitrinite reflectance of about 13 (Traverse 1988)
However the use of TAI for estimating thermal maturity from Neoproterozoic palynomorphs
requires calibration
In Trainor 1 the Cornelia Formation contains organically rich claystones between 375 and
6032 m depth Based on Rock-Eval maturity data (Stevens and Adamides in prep) and the dark
colour of poorly preserved organic material (Grey 1995de 1996) with TAI 4- to 5 all samples
had a high level of maturation with at best dry-gas generating potential remaining In contrast
drillhole LDDH1 on GUNANYA recorded lower levels of maturity (TAI values of 3+) with two of
sixteen samples from the Tarcunyah Group having greater than 1 TOC (Grey 1995abc Grey
and Cotter 1996) Organic petrology and Rock-Eval maturity data for samples from LDDH1
indicate that the section above 500 m is within the oil-generative window whereas below 500 m
the rocks are within the gas window (Ghori in prep Fig 9 Appendix 5)
Waterbores TWB 1 2 6 and 9 which are located on TRAINOR in the southeast of the sub-
basin all had organic matter with TAI values of 3+ from the McFadden Skates Hills Cornelia
and Brassey Range Formations respectively
24
100
200
300
400
500
600
700
Oil
gene
ratin
g
Gas
gene
ratin
g
Fai
r
Fai
r
Poo
r
Poo
r
Goo
d
Imm
atur
e
Oil
win
dow
Oil
win
dow
Imm
atur
e
01 0110 10 0 150 300 440 480 1
Neo
prot
eroz
oic
TOC S1+S2 mgg Hydrogen Index Tmax degC
Depth(m)
Organicrichness
Generatingpotential
Kerogentype Maturity Maturity
TD=701m
Sandstone
Mudstone
Dolomite
Limestone
Evaporite
Source rock
MKS40 070498
Ro equivalent
Figure 9 Petroleum source potential of rocks in Normandy LDDH1
Small amounts of organic matter associated with basalt and dolerite in cuttings from
waterbore BWB 1 on BULLEN showed high levels of thermal maturity (Grey 1995a Libby 1995)
It is unclear whether all sedimentary rocks on BULLEN are overmature for hydrocarbon generation
or the results from BWB 1 are related to local heating events associated with the volcanic bodies
that are common in the Jilyili Formation
25
Reservoirs
Each of the five depositional sequences of the Savory Group (Table 1) are inferred to contain
significant sandstone reservoirs with the possible exception of depositional sequence C as
discussed above in Stratigraphy The Spearhole Formation was cored in Mundadjini 1 and
Boondawari 1 and visual estimates of porosity vary from generally poor (less than 5) to fair
(approximately 5ndash15) The McFadden Formation in Trainor 1 has porosity values of up to 232
and a maximum permeability of 195 md (Stevens and Adamides in prep) Sandstones from
Neoproterozoic formations form the acquifers in the following waterbores the McFadden
Formation in TWB 1 the Cornelia Formation in TWB 6 and the Brassey Range Formation in
TWB 8 and TWB 9 (Appendix 6 Table 61)
Based on outcrop observations the Durba Sandstone is considered to be the best reservoir of
the Savory Group Similarly some sandstones from the Tarcunyah Group also have good visible
porosity in outcrop
Dolomites occur in several formations in the sub-basin Reservoir potential may exist
particularly where the dolomites are stromatolitic and oolitic However dolomites have not been
drilled in the sub-basin and porosity can only be inferred from the preferential silicification of
some stromatolite bioherms observed in outcrop (Stevens and Grey 1997) Elsewhere in the
Officer Basin porosities of up to10 have been measured in dolomites A limestone breccia
(karst) is described from 663 to 677 m in drillhole LDDH1 (Fig 6 Busbridge 1994)
Seals
Indications of evaporitic environments in the Mundadjini Skates Hills and Boondawari
Formations are described by Williams (1992) In Mundadjini 1 from 287 to 337 m anhydrite and
chert occurs as nodules beds and veins in mudstone of the Mundadjini Formation Evaporitic
minerals (predominantly gypsum) are described in the Tarcunyah Group in LDDH1 The presence
of the Woolnough and Madley salt diapirs in the Officer Basin (approximately 110 km east of the
sub-basin) and halite beds over 25 m thick in the well Hussar 1 (130 km east of the sub-basin)
provide further evidence that evaporite seals may be present in the Savory Sub-basin
Mudstones and shales form only a small proportion of the limited Neoproterozoic outcrop in
the sub-basin but significant thicknesses of mudstone were encountered in the Mundadjini
Formation in Mundadjini 1 and Boondawari 1 the Tarcunyah Group in LDDH1 and in the
26
Cornelia Formation in Trainor 1 These data suggest that mudstones form a significant proportion
of strata in the sub-basin despite their limited outcrop
Traps
Potential structural closures including folds and faults occur at various scales throughout the
Savory Sub-basin However the region has only been mapped at 1250 000 scale and
independently closed structures such as domes have yet to be confirmed The western margin of
the basin contains abundant faults (with a northeast strike) but elsewhere faults are less common
Some anticlines are recognized in outcrop including one with a strike length of up to 45 km
inferred from surface bedding dips in the Mundadjini and Spearhole Formations at approximately
24deg15rsquoS 121deg10rsquoE on BULLEN (Fig 1)
Salt diapirs and other halokinetic structures are recognized in outcrop well and seismic data
in the Officer Basin to the west of the Savory Sub-basin and it is probable that there are
significant thicknesses of evaporitic sedimentary rocks in the sub-basin The gravity field data
suggest there is good potential for salt diapirs and traps related to halokinesis
Although there is potential for stratigraphic traps to be present in the sub-basin insufficient
data are available to assess them
Preservation of hydrocarbons
The range of thermal maturities measured to date and the large periods of time envisaged for
deposition of sediments implies hydrocarbon generation may have occurred a number of times
during the evolution of the Savory Sub-basin Any hydrocarbons that were generated early may
have been trapped in palaeostructures and remigration to younger traps could have taken place
later The Petermann Ranges Orogeny which has been equated with the Paterson Orogeny (Myers
1990) is believed to have occurred in the latest Neoproterozoic to early Cambrian This is the last
major tectonic event recognized in the sub-basin suggesting that it is reasonable to expect that trap
integrity will have been preserved
If the inference of the presence of thick halite beds in the sub-basin is correct the preservation
potential of sub-salt traps should be excellent
27
Reported hydrocarbon shows and oil seep
Amadeus Petroleum recorded minor oil shows in cores from Mundadjini 1 and Boondawari 1 In
Mundadjini 1 at 36102 m (top of the Spearhole Formation) a 3 mm thick zone had 10 moderate
white fluorescence with slow solvent cut This show was in a granular sandstone with visually
estimated porosity of about 10 In Boondawari 1 at 35364 m (within the Spearhole Formation) a
broken surface of sandstone had 40 moderate yellow-white fluorescence with slow solvent cut
Visually estimated porosity is about 5 Because the fluorescing surface was broken during the
drilling process this show could have resulted from contamination A second show occurs in
Boondawari 1 at 4963 m (within the Spearhole Formation) where a 1 cm-thick zone had 5 dull
yellow fluorescence with slow solvent cut in a conglomerate with visually estimated porosity of
about 10 The company intends to further investigate the nature of these occurrences
Minor bitumen is present at 6623 m in drillhole LDDH1 on GUNANYA (Figs 5 and 6) as a
vein in mudstones of the Tarcunyah Group A sample was analysed by gas chromatography
(Ghori in prep) and confirmed that it is natural bitumen (Appendix 5)
Mineral hole OD 23 drilled by Jubilee Gold Mines NL on NABBERU in the Bangemall Basin
immediately to the south of the Savory Sub-basin (Fig 5) encountered bitumen and trace oil in
vugs in dolomite (M Stevens unpublished data) but no further data are available at present
In their popular guide to the Canning Stock Route Gard and Gard (1990 p 218) refer to an
oil seep at Well 13 on TRAINOR (Fig 5) They reported that between 1977 and 1984 lsquonatural oilrsquo
was seen in the well Although the well is now largely filled with sediment four auger drill
samples were collected by the GSWA in 1995 and all four were analysed for oil shows One
sample from 315 m total depth (GSWA sample 135604) yielded just enough extract (519 ppm)
for saturate gas chromatography analysis The gas chromatograph (Appendix 5) shows that the
extract does contain some hydrocarbons probably from recent plant material Because the depth to
the oil was not quoted in Gard and Gard (1990) the hand-augered well may not have been deep
enough to properly test this reported seep
Geological and geophysical databases
Geological and geophysical data available for the Savory Sub-basin are limited The most recently
completed geological maps for the sub-basin were published by the GSWA between 1991 and
1995 (Williams and Tyler 1991 Williams 1992 1995ab)
28
The cores from the five drillholes listed in Table 2 believed to be all of the core available
from the sub-basin are available for inspection at GSWA Mineral exploration reports submitted
to GSWA may be searched using the WAMEX database and open-file reports are available on
microfiche Geophysical data acquired by the mining industry is not required to be filed with
GSWA if acquired over Vacant Crown Land which is the case for much of the sub-basin
Geophysical survey data submitted in mining tenement reports and which extend into Vacant
Crown Land remain confidential to the companies Original regional aeromagnetic and gravity
datasets are available from the Australian Geological Survey Organisation (AGSO)
Data pertinent to oil exploration in the sub-basin such as structural style and salt diapirism
are presented in a review of the hydrocarbon prospectivity of the Officer Basin (Perincek 1998)
Drilling
Significant drillholes in the sub-basin are summarized in Table 2
Petroleum industry data
Amadeus Petroleum drilled three petroleum exploration wells in the central west of the Savory
Sub-basin in late 1997 These wells Mundadjini 1 Boondawari 1 and Akubra 1 were drilled by
continuous diamond coring (Figs 5 and 6) All targeted potential reservoirs within the Spearhole
Formation with the Mundadjini Formation as the proposed seal The wells were located on
structures interpreted from Landsat images and limited geological investigations Both Mundadjini
1 and Boondawari 1 had minor oil shows as discussed above (Reported hydrocarbon shows)
Government data
Stratigraphic drillhole Trainor 1 was drilled by GSWA in 1995 (Stevens and Adamides in prep)
and the main results are discussed above (Source rocks and Maturity)
Mineral industry data
Normandy Exploration drillhole LDDH1 was cored in the Tarcunyah Group to a total depth of
701 m and provided source-rock and maturity data as discussed above
29
Oilmin NL drilled six percussion drillholes (BD 1 3 4 5 8 and 9) through sandstones and
shales in the northern part of the Savory Sub-basin to a maximum depth of 198 m (Fig 5
WAMEX Microfiche File M 26811 I 2610) but only brief geological descriptions are available
Hydrogeological data
Hydrogeological data within the Savory Sub-basin are limited although a long history of water
exploration extends back to the construction of the Canning Stock Route early this century No
detailed geological or wireline logs are available for the older wells along this route A few station
wells have been drilled by various methods on the south and west margins of the basin but data
are unavailable as reports are not required to be filed with the government Depth to watertable
throughout the basin is largely controlled by porosity of the bedrock
The GSWA drilled fifteen waterbores in the winter of 1995 in the southern part of the sub-
basin in preparation for the drilling of Trainor 1 and the proposed Bullen 1 Twelve bores found
water and six of these bores have salinities of less than 1000 mgL (Fig 5 Appendix 6 Table 61)
One waterbore TWB 6 has gamma ray and neutron logs run through PVC casing and these are
available from the GSWA with the digital log data included herein
Seismic data
No geophysical data have been acquired by the petroleum industry in the Savory Sub-basin
Seismic data acquired in the Officer Basin to the east particularly in the Gibson and Yowalga
Sub-basins is pertinent to structural interpretation in the Savory Sub-basin (Perincek 1996a
1998)
Aeromagnetic surveys
Government data
There are over 95 277 line kilometres of aeromagnetic data included in the AGSO dataset There
are three regional aeromagnetic surveys covering the Savory Sub-basin These were flown by the
Bureau of Mineral Resources (BMR now AGSO) in 1984 at a line spacing of 1500 m with 36 740
and 52 587 line kilometres flown and by Aerodata in 1984 at a line spacing of 1000m with 5950
line kilometres flown These data were reprocessed and interpreted for GSWA by Cowan (1995)
An edited copy of this report is included as Appendix 4 and the original report is filed in the
GSWA Library under S-series reports item 10331
30
Mineral industry data
The approximate locations of non-AGSO aeromagnetic surveys are shown in Figure 8 More
detailed information regarding the location of these surveys may be obtained using the GSWA
MAGCAT II database Additional information such as contours of aeromagnetic values may be
obtained by inspecting items on file with the GSWA
Gravity surveys
Government data
The average spacing for gravity data in the Savory Sub-basin is one station per 121 km2 (11 times 11
km grid) These data were principally collected by BMR in the early 1960s There are a few
additional regional gravity traverses across the sub-basin which are also included in the
BMRAGSO dataset These data were reprocessed and interpreted for GSWA (Fig 10) and a
report on this work is also included in Appendix 4
The GSWA completed a large semi-detailed gravity survey in the eastern Savory Sub-basin
utilizing helicopter support and Differential Global Positioning Survey (DGPS) techniques (Fig
8) This gravity survey completed in August 1995 consists of 2300 gravity stations on a 2 times 3 km
grid All stations were acquired by helicopter using Scintrex gravimeters and Ashtek dual
frequency DGPS equipment for determining location This highly efficient system allowed the
acquisition of more than 100 gravity stations per day in remote areas The resolution of this survey
is +30 cm and +05 microms-2 (Daishsat 1995) These data (Fig 11) represent a significant
improvement on the previous regional survey data and are available from GSWA (GSWA
1996ab) The results of the interpretation of these data were presented at the 1997 ASEG
Convention (Carlsen and Shevchenko 1997)
Mineral industry data
Three small gravity surveys were conducted by Oilmin NL (Fig 8) and the relevant WAMEX
reports are M 2681I 2610 I 2435 I 2567 These three surveys are of limited value because height
control was provided by barometers only and the surveys were not tied to the national gravity grid
31
23deg
25deg
120deg 122deg
Trainor 1
SAVORY
SUB-BASIN
MKS54 160498
100 km
1995 SavoryGravity Survey
254
-1056
micromsec2
Figure 10 Regional Bouguer gravity map of the Savory Sub-basin
23deg
24deg
25deg
122deg30 123deg
TRAINOR 1
123deg30
50 km
MKS53 160498
-116
-626
micro msec2
Figure11 Detailed Bouguer gravity map of the
Savory 1995 Gravity Survey from the eastern Savory Sub-basin
32
Government and academic reports
Chronostratigraphy and geochemistry
The understanding of Neoproterozoic organic chemistry palynology and structural evolution is
essential to the interpretation of hydrocarbon prospectivity Pertinent reports are included in the
bibliography (Appendix 1) Unpublished palaeontology reports describe the palynology of wells in
the Savory Sub-basin (Grey 1995andashe 1996a) Grey and Cotter (1996) discussed the potential for
Neoproterozoic palynomorphs to provide a biostratigraphic framework and palaeoenvironmental
interpretation Grey and Stevens (1997) reviewed the results of palynological studies of wells
drilled in the sub-basin and reported that Supersequence 1 palynomorphs are present in TWB 6
TWB 9 and LDDH1 (Appendix 3) Grey (1996b) reported on the use of stromatolites for
correlation in the Neoproterozoic and Stevens and Grey (1997) discussed the application of
stromatolite biostratigraphy in correlating isolated dolomite outcrops in the sub-basin with well
and seismic data in the Officer Basin and Centralian Superbasin
Although geochemical data from the Savory Sub-basin are very limited results mostly
confirm thermal maturities inferred from TAI for LDDH1 and Trainor 1 (Ghori in prep Stevens
and Adamides in prep) Those parts of the Officer Basin in Western Australia which lie to the
east of the Savory Sub-basin are sparsely drilled but Ghori (in prep) reports that most of the
Neoproterozoic succession presently lies within the oil-generative window However his study
has been unable to identify effective source-rock units and the source for oil shows Thin source
rocks are present in the Neoproterozoic in LDDH1 (Fig 9) and in three wells which lie to the east
and southeast of the Savory Sub-basin namely NJD 1 Kanpa 1A and Yowalga 3
Proposed work program
From the above limited information it is concluded that additional research on the hydrocarbon
potential of the sub-basin is justified and proposals are outlined below
bull Additional modelling of gravity and aeromagnetic data from the Savory Sub-basin is required
in light of the results from Trainor 1 and Boondawari 1 Trainor 1 showed that what appeared
to be a structurally simple area based on outcrop aeromagnetic and gravity data was in fact an
area of major structuring Boondawari 1 intersected a dolerite which is in good depth
agreement with aeromagnetic depth to source results showing this technique is useful in
detecting the depth to intrusive bodies
33
bull Additional data from mineral and petroleum exploration bores may become available and
analysis of samples from these wells should be undertaken and interpreted in the context of
their relevance to the Officer Basin
bull Stratigraphic coring in the Blake Fault and Fold Belt and in the Wells Foreland Sub-basin (Fig
1) targeting source rocks is considered essential to the continuing evaluation of the
hydrocarbon prospectivity of the Savory Sub-basin
bull Correlations using at least outcrop well and potential-field data should be prepared to link the
sub-basin with the better known parts of the Officer Basin to the east
bull Remapping is required to clarify boundary positions within the Cornelia Formation this may
resolve some of the current problems of the relationship between this unit and the rest of the
Savory Sub-basin
bull Further work is required to explain the Early Cambrian or Sturtian ages interpreted for the
Cornelia Formation from sedimentary zircon UndashPb dating in drillhole Trainor 1 The
determination of the age of the organically rich but overmature claystones in this well is
critical to assessing the hydrocarbon potential of the region
bull The thin dark mudstones intersected by Akubra 1 in the Mundadjini Formation warrant
geochemical analysis Analyses of the oil shows in Mundadjini 1 and Boondawari 1 are
currently being undertaken by Amadeus Petroleum
bull Geochemical analysis of hydrocarbons in the Bangemall Basin drillhole OD23 has been
performed by Jubilee Gold and the results will be reviewed when they are submitted to
GSWA The possibility of source rocks within the Bangemall Basin charging traps within the
Bangemall Basin and the overlying Savory Sub-basin requires further investigation
Conclusions
The Savory Sub-basin is a frontier region with only three recently drilled petroleum exploration
wells and no seismic data Based on existing geological and geophysical data it is considered too
early to draw conclusions about the hydrocarbon prospectivity of the sub-basin at this stage and
there are several reasons why the area warrants further investigation
34
1 Thick accumulations of sedimentary rocks are present (up to 8 km thickness inferred) which
may contain source reservoir and sealing strata
2 Minor oil shows occur in Mundadjini 1 and Boondawari 1 and bitumen is present in mineral
exploration drillhole LDDH1 suggesting that hydrocarbons have migrated within the
Neoproterozoic sequence of the Savory Sub-basin Oil and bitumen are present in mineral
exploration drillhole OD23 in the Bangemall Basin immediately to the south of the Savory
Sub-basin and it is possible that source rocks from the Bangemall Basin could charge traps in
the overlying Savory Sub-basin
3 The age of sedimentary rocks in the sub-basin is still poorly constrained but some of the
Neoproterozoic sedimentary rocks located on GUNANYA and TRAINOR are within the
hydrocarbon-generation window It is possible that a significant thickness of Phanerozoic
sedimentary rocks may also be present
4 Friable sandstones with visible porosity outcrop extensively suggesting numerous potential
reservoirs
5 Significant but not intense faulting and folding has been mapped implying large structural
traps may be present
6 Evaporitic sedimentary rocks occur in several formations and may provide good source rocks
and excellent seals
35
References
APAK S N and CARLSEN G M 1997 A compilation and review of data pertaining to the
hydrocarbon prospectivity of the Canning Basin Western Australia Geological Survey
Record 199610 103p
BAGAS L GREY K and WILLIAMS I R 1995 Reappraisal of the Paterson Orogen and
Savory Basin Western Australia Geological Survey Annual Review 1994ndash95 p 55ndash63
BUSBRIDGE M 1994 Lake Disappointment Exploration Licence 451064 Third Annual
Report Lake Disappointment Diamond Drill Hole LDDH1 Normandy Exploration Limited
Western Australia Geological Survey M-series Item 7567 A41358 (unpublished)
CARLSEN G M and SHEVCHENKO S I 1997 Petroleum exploration in Proterozoic basins
using potential fields data and stratigraphic coring Australian Society of Exploration
Geophysicists 12th Geophysical Conference Handbook Sydney 1997 Preview no 66 p 83
(abstract only)
COWAN D 1995 Savory Basin quantitative magnetic interpretation Western Australia
Geological Survey S-series S10331 (unpublished)
DAISHSAT PTY LTD 1995 Operational and processing report Savory Basin gravity survey
Western Australia Geological Survey S-series S10332 (unpublished)
GARD E and GARD R 1990 Canning Stock Route a travellerrsquos guide for a journey through
history Perth Western Australia Western Desert Guides 448p
GEOLOGICAL SURVEY OF WESTERN AUSTRALIA 1996a Savory Basin first vertical
derivative of Bouguer gravity image 1250 000 Western Australia Geological Survey
GEOLOGICAL SURVEY OF WESTERN AUSTRALIA 1996b Savory Basin Bouguer gravity
image 1250 000 Western Australia Geological Survey
GHORI K A R in prep Petroleum source rock potential and thermal history Officer Basin
Western Australia Western Australia Geological Survey Record
36
GREY K 1995a Savory Basin drillhole BWB 1 (Bullen waterbore) palynology and thermal
maturation GSWA Palaeontology Report no 199512 (unpublished)
GREY K 1995b Savory Basin drillholes TWB 1 2 6 9 (Trainor waterbores) palynology and
thermal maturation GSWA Palaeontology Report no 199520 (unpublished)
GREY K 1995c Palynology of Normandy-Poseidon Lake Disappointment-1 corehole
Tarcunyah Group Paterson Orogen GSWA Palaeontology Report no 199521 (unpublished)
GREY K 1995d Savory Basin drillhole Trainor 1 (Trainor diamond drilling) palynology and
thermal maturity GSWA Palaeontology Report no 199524 (unpublished)
GREY K 1995e Savory Basin drillhole Trainor 1 (Trainor diamond drilling) Additional
Preparation of two samples GSWA Palaeontology Report no 199528 (unpublished)
GREY K 1995f Neoproterozoic stromatolites from the Skates Hills Formation Savory Basin
Western Australia and a review of the distribution of Acaciella australica Australian Journal
of Earth Sciences v 42 p 123ndash132
GREY K 1996a Savory Basin drillhole Trainor 1 (Trainor diamond drilling) Additional
samples palynology and thermal maturation GSWA Palaeontology Report no 199615
(unpublished)
GREY K 1996b Preliminary stromatolite correlations for the Neoproterozoic of the Officer
Basin and a review of Australia-wide correlations GSWA Palaeontology Report no 199615
(unpublished)
GREY K and COTTER K L 1996 Palynology in the search for Proterozoic hydrocarbons
Western Australia Geological Survey Annual Review for 1995ndash96 p 70ndash80
GREY K and STEVENS M K 1997 Neoproterozoic palynomorphs of the Savory Sub-basin
Western Australia and their relevance to petroleum exploration Western Australia
Geological Survey Annual Review for 1996ndash97 p 49ndash54
HUBBARD R J PAPE J and ROBERTS D G 1985 Depositional sequence mapping as a
technique to establish tectonic and stratigraphic framework and evaluate hydrocarbon
potential on a passive continental margin in Seismic stratigraphy II an integrated approach
37
edited by O R BERG and D G WOOLVERTON American Association of Petroleum
Geologists Memoir 39 p 79ndash91
LIBBY WG 1995 A petrological report on six samples of bore cuttings from the Savory Basin
Western Australia Western Australia Geological Survey S-series S31307 (unpublished)
MORTON JGG and DREXEL JF 1997 The petroleum geology of South Australia Vol 3
Officer Basin South Australia Department of Mines and Energy Resources Report Book
9719
MUHLING P C and BRAKEL A T 1985 Geology of the Bangemall Group mdash the evolution
of an intracratonic Proterozoic basin Western Australia Geological Survey Bulletin 128
219p
MYERS J S 1990 Precambrian tectonic evolution of part of Gondwana southwestern Australia
Geology v18 p 537ndash540
NELSON D R 1997 Compilation of SHRIMP UndashPb zircon data Western Australia Geological
Survey Record 19972 196p
PAYTON C E 1977 Seismic stratigraphy mdash applications to hydrocarbon exploration
American Association of Petroleum Geologists Memoir 26 516p
PERINCEK D 1996a The age of NeoproterozoicndashPalaeozoic sediments within the Officer Basin
of the Centralian Super-basin can be constrained by major sequence-bounding unconformities
APPEA Journal v 36 pt 1 p 350ndash368
PERINCEK D 1996b The stratigraphic and structural development of the Officer Basin
Western Australia a review Western Australia Geological Survey Annual Review 1995ndash
1996 p 135ndash148
PERINCEK D 1998 A compilation and review of data pertaining to the hydrocarbon
prospectivity of the Officer Basin Western Australia Geological Survey Record 19976
POSAMENTIER H W JERSEY M T and VAIL P R 1988 Eustatic controls on clastic
deposition 1 mdash Conceptual framework in Sea-level changes an integrated approach edited by
C K WILGUS B S HASTINGS C G St C KENDALL H W POSAMENTIER
38
C A ROSS and J C VAN WAGONER Society of Economic Paleontologists and
Mineralogists Special Publication no 42
STEVENS M K and ADAMIDES N G in prep GSWA Trainor 1 well completion report
Savory Sub-basin Officer Basin Western Australia with notes on petroleum and mineral
potential Western Australia Geological Survey Record 199612
STEVENS M K and GREY K 1997 Skates Hills Formation and Tarcunyah Group Officer
Basin mdash carbonate cycles stratigraphic position and hydrocarbon prospectivity Western
Australia Geological Survey Annual Review for 1996ndash97 p 55ndash60
SUMMONS RE and POWELL C McA 1991 Petroleum source rocks of the Amadeus Basin
in Geological and geophysical studies in the Amadeus Basin central Australia edited by R J
KORSCH and JM KENNARD Australia BMR Geology and Geophysics Bulletin 236
TRAVERSE A 1988 Palaeopalynology Boston Unwin Hyman 600p
VAIL P R MITCHUM R M Jr TODD R G WIDMIER J M THOMPSON S III
SANGREE J B BUBB J N and HATLELID W G 1977 Seismic stratigraphy and
global changes of sea level in Seismic stratigraphy mdash applications to hydrocarbon
exploration edited by C E PAYTON American Association of Petroleum Geologists
Memoir 26 516p
WALTER M R and GORTER J 1994 The Neoproterozoic Centralian Superbasin in Western
Australia the Savory and Officer Basins in The sedimentary basins of Western Australia
edited by P G PURCELL and R R PURCELL Petroleum Exploration Society of Australia
Symposium Perth WA 1994 Proceedings p851ndash864
WALTER M R GREY K WILLIAMS I R and CALVER C R 1994 Stratigraphy of the
Neoproterozoic to early Palaeozoic Savory Basin and correlation with the Amadeus and
Officer Basins Australian Journal of Earth Sciences v 41 p 533ndash546
WALTER M R VEEVERS J J CALVER C R and GREY K 1995 Neoproterozoic
stratigraphy of the Centralian Superbasin Australia Precambrian Research v 73 p 173ndash195
WILLIAMS I R 1992 Geology of the Savory Basin Western Australia Western Australia
Geological Survey Bulletin 141 115p
39
WILLIAMS I R 1995a Bullen WA (2nd Edition) Western Australia Geological Survey
1250 000 Geological Series Explanatory Notes 23p
WILLIAMS I R 1995b Trainor WA (2nd Edition) Western Australia Geological Survey
1250 000 Geological Series Explanatory Notes 31p
WILLIAMS I R and TYLER I M 1991 Robertson WA (2nd edition) Western Australia
Geological Survey 1250 000 Geological Series Explanatory Notes 36p
40
41
Appendix 1
Bibliography
Reports which are relevant to this investigation but which are not specifically cited are listed
below
BAILLIE P W POWELL C McA LI Z X and RYALL A M 1994 The tectonic
framework of Western Australiarsquos Neoproterozoic to recent sedimentary basins in The
sedimentary basins of Western Australia edited by P G PURCELL and R R PURCELL
Petroleum Exploration Society of Australia Symposium Perth WA 1994 Proceedings p
45ndash62
BRADSHAW M T BRADSHAW J MURRAY A P NEEDHAM D J SPENCER L
SUMMONS R E WILMOT J and WINN S 1994 Petroleum systems in West Australian
basins in The sedimentary basins of Western Australia edited by P G PURCELL and R R
PURCELL Petroleum Exploration Society of Australia Symposium Perth WA 1994
Proceedings p 93ndash118
CLARKE G L 1991 Proterozoic tectonic reworking in the Rudall Complex Western Australia
Australian Journal of Earth Science v38 p 31ndash44
COCKBAIN A E and HOCKING R M 1990 Phanerozoic in Geology and mineral resources
of Western Australia Western Australia Geological Survey Memoir 3 p 750ndash755
ETHERIDGE M and WALL V 1994 Tectonic and structural evolution of the Australian
Proterozoic 12th Australian Geological Convention Geological Society of Australia
Abstracts no 37 p 102ndash103
GOODE A D T 1981 Proterozoic geology of Western Australia in Precambrian of the
Southern Hemisphere Developments in Precambrian geology 2 edited by I R HUNTER
Amsterdam Elsevier p 105ndash203
GREY K and JACKSON M J 1983 A re-assessment of stromatolite evidence for the
correlation of the Late Proterozoic Neale and Ilma Beds Officer Basin Western Australia
Australia BMR Journal of Australian Geology and Geophysics v 8 p 359
42
HICKMAN A H WILLIAMS I R and BAGAS L 1994 Proterozoic geology and
mineralization of the TelferndashRudall region Paterson Orogen Geological Society of Australia
(WA Division) Excursion Guidebook no 5 56p
HOCKING R M MORY A J and WILLIAMS I R 1994 An atlas of Neoproterozoic and
Phanerozoic basins of Western Australia in The sedimentary basins of Western Australia
edited by P G PURCELL and R R PURCELL Petroleum Exploration Society of Australia
Symposium Perth WA 1994 Proceedings p 21ndash 44
JACKSON P R 1966 Geology and review of exploration Officer Basin Western Australia
Hunt Oil Company Western Australia Geological Survey S-series S26 (unpublished)
JACKSON M J 1971 Notes on a geological reconnaissance of the Officer Basin Western
Australia Australia BMR Geology and Geophysics Record 19715 30p
JACKSON M J and van de GRAAFF W J E 1981 Geology of the Officer Basin Western
Australia Australia BMR Geology and Geophysics Bulletin 206 102 p
LOWRY D C JACKSON M J van de GRAAFF W J E and KENNEWELL P J 1971
Preliminary result of geological mapping in the Officer Basin Western Australia Western
Australia Geological Survey Annual Report for 1971 p 50ndash56
MYERS J S 1990 Precambrian in Geology and mineral resources of Western Australia
Western Australia Geological Survey Memoir 3 p 737ndash750
MYERS J S SHAW R D and TYLER I M 1994 Proterozoic tectonic evolution of
Australia 12th Australian Geological Convention Geological Society of Australia Abstracts
no 37 p 312
NEDIN C and JENKINS R J F 1991 Re-evaluation of unconformities separating the
lsquoEdiacaranrsquo and Cambrian systems South Australia Palaios v 6 p 102ndash108
PHILLIPS B J JAMES A W and PHILIP G M 1985 The geology and hydrocarbon
potential of the north-western Officer Basin APEA Journal 25 (1) p 52ndash61
POWELL C McA LI Z X McELHINNY M W MEERT J G and PARK J K 1993
Paleomagnetic constraints on timing of the Neoproterozoic breakup of Rodinia and Cambrian
formation of Gondwana Geology v 21 p 889ndash892
43
POWELL C McA PREISS W V GATEHOUSE C G KRAPEZ B and LI Z X 1994
South Australian record of a Rodinian epicontinental basin and its mid-Neoproterozoic
breakup to form the Palaeo-Pacific Ocean Tectonophysics v 237 no 3ndash4 p 113ndash140
PREISS W V 1976 Proterozoic stromatolites from the Nabberu and Officer Basins Western
Australia and their biostratigraphic significance South Australia Geological Survey Report
of Investigations no 47 p 1ndash51
TOWNSON W G 1985 The subsurface geology of the western Officer Basin mdash results of
Shellrsquos 1980ndash1984 petroleum exploration campaign APEA Journal v 25 (1) p 34ndash51
WATTS K J 1982 The geology of the Townsend Quartzite Upper Proterozoic shallow water
deposit of the Northern Officer Basin Western Australia Perth University of Western
Australia BSc honours thesis (unpublished)
WELLS A T and KENNEWELL P J 1974 Evaporite exploration in the Officer Basin
Western Australia at the Madley Diapirs Australia BMR Record 1974194 (unpublished)
WILLIAMS I R and MYERS J S 1990 Paterson Orogen in Geology and mineral resources
of Western Australia Western Australia Geological Survey Memoir 3 p 274ndash286
WILLIAMS I R 1990 Savory Basin in Geology and mineral resources of Western Australia
Western Australia Geological Survey Memoir 3 p 329ndash334
WILLIAMS I R 1994 The Neoproterozoic Savory Basin Western Australia in The
sedimentary basins of Western Australia edited by P G PURCELL and R R PURCELL
Petroleum Exploration Society of Australia Symposium Perth WA 1994 Proceedings p
841ndash850
WILSON R B 1967 Woolnough Hills and Madley diapiric structures Gibson Desert WA
APEA Journal v 7 p 94ndash102
44
Appendix 2
Meteorological data (from Bureau of Meteorology Perth 1994)
Table 21 Wiluna rainfall (mm)
Year Jan Feb Mar Apr May Jun Jul Aug Sept Oct Nov Dec
1975 0 45 446 309 306 59 276 4 34 886 638 164 1976 16 154 12 138 53 16 34 62 12 238 0 2 1977 44 0 66 74 68 95 24 363 1 58 12 727 1978 234 522 94 16 0 96 367 24 16 353 185 45 1979 19 173 122 88 91 4 0 246 58 0 169 114 1980 148 764 68 1081 259 626 629 06 56 02 174 0 1981 123 476 192 32 196 118 44 74 14 0 28 312 1982 374 705 206 244 1079 92 02 143 368 526 368 118 1983 1 112 928 248 0 212 56 32 5 1 42 496 1984 149 7 342 84 836 0 348 132 224 04 16 172 1985 596 483 0 166 556 0 514 56 0 0 4 0 1986 0 154 35 0 0 1085 23 01 239 137 0 04 1987 1204 119 19 89 17 575 154 126 07 1 0 398 1988 46 202 164 13 388 0 202 104 0 0 224 1309 1989 207 234 26 703 278 536 57 0 01 0 144 02 1990 1035 23 281 46 126 53 94 218 44 9 42 0 1991 48 0 41 45 0 472 297 12 0 1 0 7 1992 112 96 1025 1227 323 65 04 174 0 132 48 4 1993 0 697 0 202 445 0 12 306 18 05 14 33 Mean 25 35 22 27 27 25 18 12 6 13 13 21
JAN FEB MAR APR MAY JUN JUL AUG SEP OCT NOV DEC0
10
20
30
40
Mea
n R
ain
fall
(mm
)
Month
Mean monthly rainfall in Wiluna
MKS41 140498
45
Table 22 Wiluna minimum temperature (degC)
Year Jan Feb Mar Apr May Jun Jul Aug Sept Oct Nov Dec
1975 ndash 23 203 15 94 63 71 62 103 124 169 205 1976 242 229 194 15 10 63 59 73 95 143 16 228 1977 243 25 197 148 96 95 56 86 102 ndash 188 23 1978 241 232 203 18 102 64 76 8 9 152 19 205 1979 255 226 216 167 83 6 59 79 97 145 198 223 1980 255 226 231 155 134 83 68 75 121 108 193 223 1981 245 216 19 182 119 6 54 78 138 159 163 218 1982 232 224 177 16 ndash ndash 37 111 112 164 209 225 1983 235 24 197 147 112 88 39 88 121 162 189 219 1984 241 243 191 156 ndash 72 66 7 95 161 182 211 1985 244 231 ndash 159 98 65 71 73 117 147 205 ndash 1986 ndash 229 226 155 93 96 43 49 10 122 ndash 219 1987 ndash 217 183 175 85 77 68 68 112 ndash ndash 221 1988 238 214 209 178 111 ndash ndash 86 104 157 171 195 1989 ndash 237 199 165 107 67 44 61 107 131 187 ndash 1990 232 ndash 211 155 118 62 57 87 102 149 195 22 1991 26 256 217 168 122 101 78 ndash 113 18 168 219 1992 227 227 214 169 102 98 59 69 ndash 125 159 196 1993 241 218 196 171 103 ndash 49 68 88 128 192 211 Mean 24 23 20 16 10 8 6 8 11 14 18 21
NOTE Dashes indicate data unavailable
JAN FEB MAR APR MAY JUN JUL AUG SEP OCT NOV DEC0
10
20
30
40
Month
MKS43 140498
50
Mean monthly minimum temperatures at Wiluna
Mea
n T
emp
erat
ure
(degC
)
46
Table 23 Wiluna maximum temperature (degC)
Year Jan Feb Mar Apr May Jun Jul Aug Sept Oct Nov Dec
1975 ndash 349 326 281 247 201 197 212 256 248 31 344 1976 374 369 346 297 248 206 208 225 265 287 313 388 1977 397 392 352 296 234 212 222 244 ndash 308 337 383 1978 378 345 346 316 242 195 176 205 231 295 334 356 1979 403 36 364 295 ndash ndash ndash 193 242 318 359 373 1980 392 342 377 275 24 176 179 233 292 288 349 391 1981 385 346 337 342 242 178 201 224 30 326 326 369 1982 372 359 315 307 ndash ndash 196 253 252 305 353 379 1983 381 389 327 272 263 222 187 248 287 321 336 366 1984 378 393 322 299 226 215 178 214 234 ndash 336 364 1985 40 366 ndash 294 224 216 205 212 284 307 355 ndash 1986 ndash 383 372 307 ndash 193 166 196 261 277 ndash 382 1987 ndash 339 328 305 21 202 214 218 275 ndash ndash 374 1988 388 365 353 301 23 ndash ndash 228 283 334 31 33 1989 ndash 375 339 285 238 179 181 219 275 298 336 ndash 1990 368 ndash 36 309 268 19 188 205 274 309 373 393 1991 414 416 363 315 268 206 21 ndash 279 338 332 368 1992 363 383 336 263 213 178 213 197 ndash 285 313 359 1993 396 357 344 301 221 ndash 197 215 253 294 347 362 Mean 39 37 34 30 24 20 20 22 27 30 34 37 NOTE Dashes indicate data unavailable
JAN FEB MAR APR MAY JUN JUL AUG SEP OCT NOV DEC0
10
20
30
40
Month
MKS42 140498
50
Mean monthly maximum temperatures at Wiluna
Mea
n T
emp
erat
ure
(degC
)
47
Appendix 3
Table 31 Summary of palynological results
Drillhole Depth (m) F no(a) GSWA no Lithology Formation Assemblage TAI(b)
BWB 1 74ndash75 F49668 135741 dark-grey siltstone basalt Jilyilli gt5 BWB 1 98ndash100 F49669 135742 dark-grey siltstone basalt Jilyilli gt5 BWB 1 121ndash122 F49670 135743 dark-grey siltstone basalt Jilyilli gt5 TWB 1 86ndash87 F49671 135631 dark-grey siltstone McFadden 3+ TWB 1 104ndash105 F49672 135632 dark-grey siltstone Cornelia 3+ TWB 1 121ndash122 F49673 135633 dark-grey siltstone Cornelia 4 TWB 2 14ndash15 F49674 135634 dark-grey siltstone Skates Hills 3+ TWB 6 49ndash50 F49675 135675 dark-grey siltstone Cornelia 1 3+ TWB 9 49ndash51 F49676 135704 dark-grey siltstone Brassey Range 1 3+ Trainor 1 37497- F49733 138939 black mudstone with Cornelia 5 37509 light-grey siltstone Trainor 1 3809 F49734 138940 dark-grey and black Cornelia 4- laminated mudstone Trainor 1 4170 F49735 138941 black unlaminated mudstone Cornelia 4- Trainor 1 4950 F49851 139501 dark-grey indurated siltstone Cornelia 5 Trainor 1 6032 F49852 139502 dark- and light-grey Cornelia 5 indurated siltstone Trainor 1 6434 F49853 139503 greenish indurated finely Cornelia 5 laminated siltstone LDDH 1 270 F49678 138934 dark-grey siltstone interbeds Waters 1 3+ in enterolithic evaporite Tarcunyah Gp LDDH 1 277 F49679 138935 dark-grey siltstone in cavity Waters 1 3+ in enterolithic evaporite Tarcunyah Gp
NOTES (a) GSWA Fossil Catalogue number (b) TAI = Thermal Alteration Index of Traverse (1988 plate 1)
48
Appendix 4
Savory Sub-basin quantitative magnetic and gravity interpretation (extracted from Cowan 1995)
Summary
A program of quantitative aeromagnetic interpretation has been completed on BMRAGSO data from the Savory Sub-
basin Western Australia Quantitative aeromagnetic interpretation utilized the 3D Euler deconvolution method
supported by wavenumber filtering and image processing The results have provided useful information on structural
trends and depth to magnetic sources in a structurally complex area Depth to magnetic source analysis has provided
information on intra-sedimentary magnetic sources as well as basement rocks
The results of the interpretation support previously identified depocentres However the presence of magnetic
sources at several levels makes it very difficult to produce a reliable magnetic basement depth contour map It is
considered more productive to work with the 3D Euler colour circle plots and images rather than trying to contour the
results It would be necessary to carry out a full-scale interpretation of the BMRAGSO profile data to improve on the
3D Euler results The regional gravity was found to be useful in interpreting the regional setting of the area although
the very wide data spacing limits quantitative use of the data The gravity data show quite a complex picture with
limited consistent correlation between gravity features and basin structures This suggests that gravity anomalies
reflect changes in density of the basement rocks rather than basement topography especially in the northern part of the
basin
It is recommended that the GSWA investigate access to company confidential high-resolution aeromagnetic data
prior to planning further aeromagnetic surveys Private companies have flown large parts of the northern half of the
area as part of their diamond exploration program Additional gravity coverage of the area may be more cost effective
than magnetic surveys as the gravity data provides more information on changes within the sedimentary section
Introduction
The main use of aeromagnetic data in petroleum exploration has been the determination of magnetic basement
topography although there has been increasing interest in analysis of intra-sedimentary magnetic anomalies
intrabasement and suprabasement magnetic anomalies These anomalies are used to determine depth to magnetic
basement rocks and hence determine the thickness of the sedimentary sequence Unfortunately interpretation of the
intrabasement and suprabasement magnetic anomalies is non-unique in terms of position and size of causative sources
because of the inherent ambiguity of potential-field methods However this ambiguity can be reduced by placing
49
constraints on source geometry and magnetization and by using geological and other geophysical data to constrain
the solution
Before 1970 most depth-determination techniques involved graphical determination of slopes of selected
magnetic anomalies and application of various empirical factors to convert the slopes into depth estimates Geological
Society of America Memoir 47 Interpretation of Aeromagnetic Maps by Vacquier et al (1951) was a landmark for
this type of interpretation
Automated interpretation procedures have played an increasingly important role in depth interpretation and a
wide range of techniques have been developed Many of these techniques are designed for application to located data
profiles and assume a two-dimensional geometry However there has been renewed interest in techniques applicable
to gridded data
Two distinct types of method can be recognized In the first case often described as discrete methods individual
isolated magnetic anomalies are interpreted and the results used to produce a map of basement relief In the second
case often described as continuous methods areas of data containing a number of anomalies are interpreted
statistically to produce direct output of basement depths
The discrete methods usually involve a semiautomatic initial phase which generates a large number of possible
depth solutions and an interactive second phase to screen and select acceptable solutions The advantage of this
approach is that the interpreter can select features that are relatively free from interference from adjacent anomalies
and consider all aspects of a particular magnetic anomaly The disadvantage is that interpretation can be very time
consuming as a wide range of depths are usually possible depending on the initial model chosen and a significant
amount of effort is needed to select the correct model In the case of the Savory Sub-basin dataset we encountered
problems in separating basement related effects from the effects of shallower intrasedimentary magnetic sources
Because of these problems we have concentrated on displaying the Euler results accompanied by separation filter
images of the data to show the shallower effects and deeper effects rather than trying to refine a 3D Euler
deconvolution depth-to-crystalline-basement contour
The continuous methods are very direct provided that the rather restrictive assumption can be made that all
anomalies are due to lateral magnetization changes due to basement topography This means that shallow effects and
large intrabasement anomalies must be removed from the data This involves judgement and skill as it is necessary to
distinguish between the lower amplitude suprabasement anomalies due to basement topography and the larger
intrabasement anomalies reflecting magnetization changes within the basement These methods were not considered
suitable for the Savory Sub-basin magnetic dataset but were used to invert the gravity data
50
Limitations of magnetic and gravity interpretation
Interpretation of the area is limited by a shortage of information on the nature and physical properties of the deeper
sedimentary sequence and the underlying basement rocks However using techniques such as cross-correlation of
gravity and pseudo-gravity data it is possible to try to differentiate between anomalies relating to basement and those
related to the sedimentary sequence
Gravity anomalies reflect changes within the sedimentary sequence as well as basement condition These
changes in density of sedimentary rocks produce gravity anomalies without a corresponding magnetic anomaly hence
the complementary nature of gravity and magnetic surveys The main use of magnetics is to determine depth to
magnetic basement and any intra-sedimentary volcanic rocks or intrusives whereas gravity provides much more
general information on the sedimentary sequence
Unfortunately interpretation of gravity anomalies is complicated since they can be due to a number of geological
features including
bull major basement faults
bull basement highs
bull igneous intrusions within the basement
bull sedimentary basins which may or may not be isostatically compensated
bull intra-sedimentary volcanics and associated plutonic centres
Two major problems affect the interpretation of both magnetic and gravity data
1 The inherent ambiguity of potential-field data There is no unique solution to any measured gravity or magnetic
anomaly and theoretically there will be an infinite number of source geometry and magnetizationdensity
combinations which will fit the observed data This means that any a priori information which helps to select a
suitable model is very useful
2 Measured anomalies are the summation of effects from different depths For example an observed gravity profile
may contain contributions from shallow sources (density variations within the sedimentary basin) intermediate
depth sources (density variations due to large igneous intrusions within the basement) and deep sources (crustal
thinning producing a mantle anomaly) Separation of these component responses is the regionalresidual problem
which we solve using spectral analysis and differential upward continuation-based separation filtering
Regional setting and interpretation overview
The area studied includes parts of BALFOUR DOWNS (SF51-9) RUDALL (SF51-10) ROBERTSON (SF51-13) GUNANYA
(SF51-14) COLLIER (SG50-4) BULLEN (SG51-1) TRAINOR (SG51-2) MADLEY (SG51-3) NABBERU (SG50-5)
STANLEY (SG51-6) and HERBERT (SG51-7) 1250 000 sheets Broadly the area lies between latitudes 22deg00rsquondash25deg30rsquoS
and longitudes 119deg30rsquondash123deg30rsquoE
51
Regional gravity
The AGSO regional gravity data (at nominal 11 km spacing) was gridded at a 4 km mesh spacing using a minimum-
curvature algorithm Bouguer gravity values in the area are negative reflecting mass deficiency at depth and range
from -84 mgals to -25 mgals
A Bouguer gravity colour image is shown as Figure 41 A residual grid was produced by removing a fifth-order
orthogonal polynomial from the Bouguer data but did not add to the interpretation
120deg 121deg 122deg 123deg
23deg
24deg
25deg
-25
-84
50 km
MKS46 180598
mgal
Figure 41 Regional Bouguer gravity (BMRAGSO data) gridded at 4 km
52
The data show a complex pattern of positive and negative anomalies with no clearly defined trends Correlations
with aeromagnetic data and known basin structures are poor A vague north-northwest linear trend appears to coincide
with the Marloo Fault (Figure 42) A prominent negative anomaly appears to coincide with the Blake Fold and Fault
Belt depocentre and continues as a narrower negative anomaly to the east until it widens out again near the edge of the
basin Elsewhere the gravity data show little correlation with known basin structures and it is likely that especially in
the north of the area gravity anomalies are due to density changes in the basement rather than changes in basement
topography
Production of wavelength-filtered residual gravity plots and vertical gradient plots showed very patchy aliased
data reflecting poor sampling in much of the area
Regional magnetics
The AGSO regional aeromagnetic data were gridded at a 400 m mesh spacing using a minimum-curvature algorithm
(Figure 43) Most of the data has a line spacing of 1600 m with small areas of 1 km spacing The quality of the data is
acceptable for regional interpretation but is not adequate for detailed analysis The accuracy of the flight path is rather
variable reflecting the vintage of the data and the noise envelope of the data is poor by modern standards Problems
were also encountered in joining different map sheets
The magnetic anomaly pattern over the south and west part of the area shows a strong high frequency signature
reflecting the presence of widespread basic sills and dykes Some of the major north-northeasterly trending dykes can
be traced over considerable distances
Discontinuous high-frequency anomalies extend as a northwest-trending zone through the centre of the area and
this zone includes a conspicuous circular magnetic anomaly which is probably a ring complex
The northern and eastern parts of the area are characterized by long-wavelength deep-seated basement magnetic
anomalies with 120deg and 150deg trends dominant The Marloo and Perentie Faults (Figure 42) appear as distinct linear
zones and offsets A prominent easterly trending negative anomaly in the northwest of the area appears to swing round
to the southeast and may separate different basement blocks One possible interpretation is that this very deep seated
anomaly separates areas of Archaean and Proterozoic basement
Regional geology
The regional geology is described in Williams (1992) The GSWA provided a digitized version of Plate 2 from this
Bulletin the structural interpretation map to use as an overlay (Figure 42)
53
Pp
Pp
PSd
PSd
PSd
PSd
PSd
PSo
PSt
PSt
PSf
PSf
PSf
PSb
PSb
PSb
PSsPSs
PSs
PSb
PSm
PSp
PSc
PSc
PSw
PSw
PSw
PSg
PSr
PSj
PSg
PM
Pk
PY
PY
PSd
L
L
L
L
L
L
L
LL
L
L
L
LL
L
LL
L L
LL
L L
L
L
L
L
L
L
L
LL
L
L
BLAKEDEPOCENTRE
MA
RLO
O
FAU
LT
PERENTIEFAULT
50 km
MKS39120598
120deg 121deg 122deg 123deg
25deg
24deg
23deg
Approximate boundaryof aeromagnetic interpretation
PML
PSgL
PSjL
PML
PSpL
PML
PML
PSfL
PSfL
PSpL
LPc
LPcLPcPSrL
LPA
Durba Sandstone
Woora Woora Formation
McFadden Formation
Tchukardine Formation
Boondawari Formation
Skates Hills Formation
Mundadjini Formation
Coondra Formation
Spearhole Formation
Watch Point Formation
Jilyili Formation
Brassey Range Formation
Glass Spring Formation
Paterson Formation
Yeneena Group
Karara Formation
Cornelia Formation
Kahrban Subgroup
Bangemall Group
Fault
Formation boundary
PSdL
PSoL
PSfL
PStL
PSbL
PSsL
PSmL
PScL
PSpL
PSwL
PSjL
PSrL
PSgL
Pp
PYL
PkL
LPc
LPA
PML
Savory Group Other Units
PYL
Figure 42 Regional geology and structure map (after Williams 1992)
54
120deg 121deg 122deg 123deg
23deg
24deg
25deg
5820
3750
MKS47 180598
nT
50 km
Figure 43 Regional aeromagnetic data total magnetic intensity (BMRAGSO data) gridded at 400 m
Analysis
3D analysis
3D Euler deconvolution was used as the primary depth-determination method The advantage of this approach is that
consistent solutions can be obtained over the entire area with minimal assumptions about source geometries Euler
deconvolution of gridded data is used for positional information and estimation of depth to top of source Euler
55
deconvolution yields a large number of depth solutions which have to be screened to reject spurious solutions Results
are plotted as circles in eight depth ranges with radius proportional to depth and colour coded
The 400 m total magnetic intensity grid was used for the analysis Horizontal gradients in x and y and the vertical
gradient were calculated 3D Euler deconvolution was tested on the 400 m gridded data using windows of 9 times 9 and
11 times 11 and 16 times 16 data points and structural indices 05 (fault) and 10 (sill or dyke) It was concluded that the
16 times 16 window produced the best results overall and final plots were produced for the 16 times 16 window and structural
index 05 (Fig 44) Results were very good over the northern and central parts of the area showing magnetic sources
Figure 44 Depth to magnetic source 3D Euler deconvolution 16 times 16 window of 400 m gridded data structural index 05
56
at several different levels Unfortunately in the extreme south of the area shallow intrasedimentary magnetic sources
(sills and dykes) dominated the inversion and the results contained few basement solutions
In order to reduce these problems the 400 m gridded data were filtered using a separation filter based on
interpretation of the log-energy spectrum The 3D Euler method was run on the filtered data in order to generate more
basement-depth solutions Results for the deep-separation filter data were gridded and presented as a colour image in
Cowan (1995) Attempts to grid the Euler output were unsatisfactory and it is considered safer to interpret the 3D
Euler depth plots The 3D Euler depth results from the separation-filter run should be analysed with care as perfect
separation of the basement can never be achieved and there will always be some contamination from sources at
different levels
The results of original total magnetic intensity 3D Euler depth estimation for structural index 05 using a 16 point
window have been plotted at 1500 000 scale (not included in this publication but available in Cowan (1995) from the
GSWA Library as S10331) and as reduced A4 colour circle plots (Figure 44)
The results of deep-basement 3D Euler depth estimation for structural index 05 using a 16 point window have
been plotted as a colour image at 1500 000 scale and as an A4 image (not included in this publication)
2D analysis
Two equispaced profiles were interpolated with a 50 m station interval from the AGSO-located data profiles for the
BULLEN 1250 000 sheet The interpolated profiles were analysed using 2D Euler deconvolution and Werner
deconvolution Results are included in Cowan (1995) and show the use of these methods for more detailed analysis
Filtered data
In order to reconcile 3D Euler results from shallow basement and intrasedimentary magnetic sources we produced
several separation-filtered maps and images We found the shallow-layer double-separation filter (Figure 45) to be
very effective for shallow sources and the deep-layer standard-separation filter (Figure 46) for the basement layer
Gravity and magnetic data correlation
Both lsquoreduced to the polersquo (RTP) magnetics (Figure 47) and pseudo-gravity data (Figure 48) were produced as part of
the reconciliation of gravity and magnetic signatures In both cases the filtering operations assumed magnetization by
induction in the present Earths field The RTP data are fairly similar to the total magnetic intensity The pseudo-
57
gravity data are dominated by a northwest-trending strong positive anomaly and there is little correlation with the
Bouguer gravity data
The poor magneticgravity correlation is confirmed by cross-correlation of the RTP magnetics and the gravity
gradient The correlation plot in Figure 49 shows little coherent response with numerous zones of positive and
negative correlation
Figure 45 Regional aeromagnetic data shallow layer separation filter (BMRAGSO data) gridded at 400 m
Results
In the north and east of the area on the Wells Foreland Sub-basin trend (refer to Figure 1 main text) we see a range
of quite deep 3D Euler depths and several trend directions with north-northwesterly dominant There are relatively few
shallow intrasedimentary solutions in this zone
The second area of deep 3D Euler solutions lies over the Blake depocentre (Figure 43) with several trend
directions
Elsewhere the 3D Euler results are dominated by shallow intrasedimentary depth solutions reflecting mainly the
dolerite sills dykes and the ring complex However where we do see basement-related solutions in the south and
west of the area they appear to be shallower than those noted for the Wells Foreland Sub-basin and the Blake
depocentre
58
Figure 46 Regional aeromagnetic data deep-layer separation filter (BMRAGSO data) gridded at 400 m
Figure 48 Regional aeromagnetic data pseudo-gravity transform (BMRAGSO data) gridded at 400 m
Figure 47 Regional aeromagnetic data reduced-to-pole (BMRAGSO data) gridded at 400 m
Figure 49 Regional aeromagnetic and gravity data gravitymagnetic correlation using RTP magnetics and gravity gradient (BMRAGSO data) gridded at 4 km
59
This subdivision of the area into two zones of deep solutions is consistent with interpreted depocentres
However the interference between sources at different levels and the complexity of the magnetic response of the
basement rocks precludes more refined interpretation at this stage
The area of deep 3D Euler solutions over the Blake depocentre correlates with the pronounced negative gravity
anomaly discussed in the gravity interpretation section Using a density contrast of -015 gcc the negative gravity
anomaly could indicate up to 6ndash8 km of low-density sedimentary rocks depending on assumptions about the regional
field
The area of deep 3D Euler solutions over the Wells Foreland Sub-basin has a complex gravity expression and no
clear basin structure emerges from inversion of these data As noted previously it is likely that observed gravity
anomalies reflect contrasts in basement density rather than basement topography
Separation filtering applied to the magnetic data helps to enhance the intrasedimentary magnetic signature and to
give a better impression of the basement magnetic signature even though separation of the basement response is not
perfect
Conclusions
Quantitative aeromagnetic interpretation using 3D Euler deconvolution supported by wavenumber filtering and image
processing has been successful in providing structural trend and depth information for the Savory Sub-basin
Quantitative magnetic interpretation has revealed two zones of relatively deep magnetic basement beneath the
Wells Foreland Sub-basin and the Blake depocentre
This analysis of the magnetic data supports interpreted depocentres but the complexity of the basement magnetic
signature and interference from sources at different depths precludes further refinement to a map of basement
topography
Regional gravity proved to be very useful in understanding the regional setting of the area and in providing
support for aspects of the interpretation The gravity data support the interpretation of the Blake depocentre
suggesting up to 6ndash8 km of low-density sedimentary rocks
The deep structure of the Savory Sub-basin area is obviously complex with different areas underlain by
Archaean and Proterozoic basement and with the Capricorn suture occurring in the centre of the area
60
Recommendations
The quantitative magnetic interpretation needs to be reconciled with geological models available for the area
In particular the zones tentatively identified as areas with thick sedimentary rocks the Wells Foreland Sub-
basin and the Blake depocentre need to be investigated
Cross sections should be prepared across the basin for joint magneticgravity modelling especially for the Blake
depocentre It is important to be able to explain the strong negative gravity anomaly in this area
In view of the effects of basement density contrasts on the gravity field for the northern part of the area we think
that additional gravity interpretation and acquisition of new gravity data may not be justified as they will not
contribute significantly to understanding basin evolution and structure
It is recommended that GSWA try to get access to company confidential high-resolution aeromagnetic data
rather than flying new surveys The GSWA might offer to fund flying of new infill areas as a bargaining point
References
The original text of this report by Cowan (1995) and 1500 000 scale maps are filed in the GSWA Library under
S10331
COWAN D 1995 Savory Basin quantitative magnetic interpretation Western Australia Geological Survey S-series
S10331 (unpublished)
VACQUIER V STEENLAND N C HENDERSON R G and ZIETZ I 1951 Interpretation of aeromagnetic
maps The Geological Society of America Memoir 47 151p
WILLIAMS I R 1992 Geology of the Savory Basin Western Australia Western Australia Geological Survey
Bulletin 141 115p
61
Appendix 5
Geochemistry
MKS38 250398
Saturate FractionC12+ GLC
1217
Pr18
Ph
22
31CSR WELL-13 315m Cuttings
Figure 51 Canning Stock Route Well 13 gas chromatograph of extract of auger drill sample
12
17
18
22
31
Pr Ph
LDDH 1 6623m CoreSaturate FractionC12+ GLC
MKS35 240398
Figure 52 Gas chromatograph of extract from core sample at 6623 m LDDH1
62
Table 51 Canning Stock Route Well 13 auger drill samples
GSWA sample Drill depth (m)(a) Comments
135601 150 At watertable 135602 203 (all samples consist 135603 310 of sand mud and water) 135604 315 At total depth
NOTE (a) Datum for drill depth is the top of sediment fill in the well which is 155 m below ground level (ie the total depth of 315 m is 47 m below ground level)
Table 52 Canning Stock Route Well 13 gas chromatography data for 315 m depth sediment sample
Parameter Value
Weight of rock extracted (grams) 945 Total extract (ppm) 519 n-Alkane distribution n-C12 07 n-C13 23 n-C14 26 n-C15 22 n-C16 19 n-C17 14 i-C19 23 n-C18 14 i-C20 08 n-C19 11 n-C20 16 n-C21 25 n-C22 29 n-C23 70 n-C24 42 n-C25 95 n-C26 43 n-C27 83 n-C28 38 n-C29 87 n-C30 31 n-C31 273 Alkane compositional data Pristane phytane ratio 279 Pristane n-C17 ratio 161 Phytane n-C18 ratio 059 CPI (1)(a) 284 CPI (2) 209 (C21 + C22) (C28 + C29) 043
NOTE (a) CPI= Carbon preference index
63
Table 53 LDDH1 extract liquid chromatography data for 6623 m concentration
Rock extracted Total extract (grams) (ppm)
702 313
NOTE ppm= parts per million
Table 54 LDDH1 saturate gas chromatography data of core for 6623 m alkane composition
Pristane Pristane Phytane (a) CPI (1) CPI (2) (C21+C22) Phytane n-C17 n-C18 (C28+C29)
103 026 024 103 102 325
NOTE (a)CPI = carbon preference index
Table 55 LDDH1 saturate gas chromatography data of core for 6623 m n-alkane distributions
Parameter Value
n-C12 17 n-C13 38 n-C14 55 n-C15 60 n-C16 65 n-C17 74 i-C19 19 n-C18 78 i-C20 19 n-C19 80 n-C20 79 n-C21 71 n-C22 64 n-C23 57 n-C25 43 n-C24 38 n-C27 31 n-C28 23 n-C29 19 n-C30 12 n-C31 10
64
Appendix 6
Table 61 Summary of data from Trainor waterbores (TWB) and Bullen waterbores (BWB)
Well AMG Elevation TD Status(b) Completion details Water Salinity Water level Flow rate Depth to consolidated AGD84 GL (m) (m) struck mgl(c) (m) (LHr) lithology aquifer(e) Z51(a) Interval (m) (100 mm PVC) (m) (mgl)(d)
TWB 1 473660E 453 122 comp 0ndash75 plain 63 7 300 24 2 880 12 m 7287404N 75ndash93 slotted (9 260) McFadden Fm 93ndash99 plain TWB 2 472 977E 475 23 abd nil 15 m 7285877N Skates Hills Fm dry TWB 3 473259E 475 50 abd nil 7 m 7285849N Skates Hills Fm dry TWB 4 463225 E 445 50 comp 0ndash22 plain 35 7 200 55 3 600 0 m 7286143N 22ndash34 slotted (8 140) Tertiary sand and gravel 23ndash60 plain TWB 5 463095E 445 31 comp 0ndash19 plain 13 26 000 655 3 600 Tertiary sand and gravel 7277721N 19ndash25 slotted (36 700) 25ndash31 plain TWB 6 457013E 455 50 comp 0ndash42 plain 38 920 119 600 0 m 7274352N 42ndash48 slotted (1 030) Cornelia Fm ss TWB 7 453739E 475 26 susp 0ndash2 plain 11 9 300 48 4 500 0 m 7263891N (10 500) Tertiary sand TWB 8 433893E 535 60 susp 0ndash2 plain 47 8 500 gt46 1 200 0 m 7245991N (10 900) Tertiary sand and Brassey Range Fm ss TWB 9 437219E 505 51 comp 0ndash47 plain 45 1 000 58 600 1 m 7235905N 47ndash51 slotted (990) Brassey Range Fm ss TWB 10 434927E 495 32 susp 0ndash2 plain 235 450 120 0 m 7225875N (500) Dolerite
65
BWB 1 287337E 580 122 abd Nil 1 m 7245861N Jilyili Fm dry BWB 2 288346E 545 50 comp 0ndash26 plain 15 630 3 29 000 0 m 7240423N 26ndash38 slotted (730) Tertiary sand and gravel 38ndash50 plain BWB 3 305637E 545 50 abd 19 8 800 43 7 200 0 m 7240423N (10 550) Tertiary ss BWB 4 320167E 515 445 comp 0ndash20 plain 9 980 445 24 000 0 m 7248097N 20ndash32 slotted (1 190) Tertiary ss 32ndash44 plain BWB 5 353393E 545 20 susp 0ndash2 plain 45 (970) 1 m 7238934N Basalt
NOTES (a) GPS accuracy ~ 150 m (b) Comp = completed abd = abandoned susp = suspended (c) Salinity from conductivity (d) Analysis total dissolved solids (e) Fm = Formation ss = sandstone
iv
Appendices
1 Bibliography 41
2 Meteorological data 44
3 Summary of palynological results 47
4 Cowan Geodata Services Report Savory Sub-basin quantitative magnetic and gravity
interpretation 48
5 Geochemistry 61
6 TWB and BWB waterbore data 64
Figures
1 Structural subdivisions of the Savory Sub-basin 3
2 Localities and access routes of the Savory Sub-basin 5
3 Formations lithology and depositional sequences AndashE of the Savory Sub-basin 7
4 Correlation of Savory Sub-basin formations with the western Officer and Amadeus Basins 10
5 Locations of petroleum exploration wells mineral exploration and stratigraphic drillholes
and waterbores and wells 12
6 Geological cross section through significant drillholes 13
7 Regional geological setting of the Savory Group and western Officer Basin 15
8 Locations of aeromagnetic and gravity surveys 21
9 Petroleum source potential of rocks in Normandy LDDH1 24
10 Regional Bouguer gravity map of the Savory Sub-basin 31
11 Detailed Bouguer gravity map of the Savory 1995 Gravity Survey from the
eastern Savory Sub-basin 31
Tables
1 Summary of formations in the Savory Sub-basin 8
2 Neoproterozoic formations and hydrocarbon shows in diamond drillholes in the
Savory Sub-basin 20
~Version Information13 VERS 120 CWLS log ASCII Standard -VERSION 12013 WRAP NO One line per depth step131313~Well Information Block13MNEMUNIT Data Type Description13--------- ------------ -----------------------------13 STRTM 5000013 STOPM 00013 STEPM -10013 NULL -9992513 COMP COMPANY GEOLOGICAL SURVEY OF WA 13 WELL WELL TWB 6 13 FLD FIELD SAVORY SUB-BASIN 13 LOC LOCATION AGD84 Z51 457 013E 7 274 352N 13 PROV PROVINCE WESTERN AUSTRALIA 13 SRVC SERVICE COMPANY BPB Wireline Services 13 DATE LOG DATE 16-NOV-1995 13 UWI UNIQUE WELL ID 131313~Curve Information Block13MNEMUNIT Curve Description13--------- -----------------------------13 DEPTM DEPTH13 GRNPGAPI GAMMA FROM NEUTRON TOOL 13 LSN SNU LONG SPACED NEUTRON 13 SSN SNU SHORT SPACED NEUTRON 13 RPOR LIMEST NEUTRON POROSITY 13 BISIMM BIT SIZE 131313~Other Information13NEUTRON POROSITY GAMMA RAY LOG 13LOGGED THROUGH PVC CASING 13 13 13 13Run number ONE Log 1st rdg 497 M Log last rdg 0 M 13Driller TD 50 M Logger TD 50 M Water level 8 M 13Perm Datum GL Elevation Approx 455 M Other srvcs 13Dril mes from GL Log meas from GL 0 M Other srvcs 13Elevation KB DF GL 13Casing Driller Casing Logger Casing size 100 MM 13Casing Weight PVC From 0 M To 50 M 13Bit size 168 MM From 4 M To 50 M 13Hole fl type WATER Sample source Fluid loss 13Density Viscosity pH 13RM meas tmp RMF mes tmp RMC mes tmp 13RM BHT RMF source RMC-source 13Max rec temp Time snc circ LsdSecTwpRge 13Equipment no V338 Base PERTH Equip name NN1 13Recorded by RALEES Witnessed by MKSTEVENS Sonde srl no 5094421 13Last title Last line Permit no 131313~A Depth GRNP LSN SSN RPOR BISI13 50000 -999250 -999250 -999250 -999250 15000013 49900 -999250 -999250 -999250 -999250 15000013 49800 -999250 -999250 -999250 -999250 15000013 49700 -999250 -999250 -999250 -999250 15000013 49600 -999250 -999250 -999250 -999250 15000013 49500 -999250 -999250 -999250 -999250 15000013 49400 -999250 216309 1965945 21484 15000013 49300 -999250 209718 1885054 18983 15000013 49200 -999250 193254 1788650 20017 15000013 49100 -999250 179391 1718687 21242 15000013 49000 -999250 169195 1664613 22255 15000013 48900 -999250 164382 1641439 22881 15000013 48800 -999250 161675 1610665 22813 15000013 48700 -999250 158560 1582780 22969 15000013 48600 -999250 153487 1540073 23222 15000013 48500 -999250 150656 1507227 23153 15000013 48400 -999250 149882 1476893 22537 15000013 48300 -999250 149163 1472245 22684 15000013 48200 -999250 150061 1480661 22713 15000013 48100 -999250 152366 1505029 22817 15000013 48000 -999250 155587 1522300 22376 15000013 47900 -999250 156423 1545663 22756 15000013 47800 -999250 157996 1564316 22732 15000013 47700 -999250 160387 1576311 22387 15000013 47600 -999250 164977 1575181 21193 15000013 47500 -999250 169393 1573485 20161 15000013 47400 -999250 172602 1572606 19401 15000013 47300 -999250 174262 1576876 19106 15000013 47200 125606 176189 1588872 18968 15000013 47100 130283 177279 1602375 19020 15000013 47000 133820 177991 1612297 19135 15000013 46900 133219 177161 1612863 19341 15000013 46800 132529 178270 1613868 19143 15000013 46700 132046 178623 1608090 18950 15000013 46600 132923 178778 1608655 18966 15000013 46500 130992 176622 1610853 19516 15000013 46400 129967 174944 1622095 20144 15000013 46300 125691 174745 1628815 20332 15000013 46200 120912 175222 1643574 20508 15000013 46100 116508 178518 1664739 20243 15000013 46000 113650 183591 1699030 19897 15000013 45900 112428 194771 1736147 18532 15000013 45800 111492 205283 1778413 17500 15000013 45700 110773 213849 1811134 16664 15000013 45600 106644 218024 1834434 16419 15000013 45500 102663 219914 1842913 16259 15000013 45400 100338 218774 1849068 16525 15000013 45300 102289 214865 1845237 17050 15000013 45200 104161 210994 1840464 17548 15000013 45100 107659 206937 1831357 18079 15000013 45000 112103 204434 1829787 18506 15000013 44900 115739 202186 1827652 18884 15000013 44800 114251 205716 1840212 18575 15000013 44700 112034 211533 1865836 18135 15000013 44600 109433 221202 1911306 17408 15000013 44500 107797 227489 1949365 17072 15000013 44400 104201 231491 1968897 16756 15000013 44300 101028 227316 1959728 17256 15000013 44200 99087 220168 1932283 17921 15000013 44100 98535 209315 1882982 18775 15000013 44000 101875 197069 1817352 19952 15000013 43900 108467 183944 1742050 21126 15000013 43800 120232 172206 1663797 22036 15000013 43700 132884 161019 1588055 22923 15000013 43600 146265 149622 1526068 24472 15000013 43500 153222 141321 1497115 26104 15000013 43400 158207 137704 1501072 27243 15000013 43300 160080 138026 1539948 28216 15000013 43200 159607 141619 1597602 28678 15000013 43100 156927 148996 1668570 28332 15000013 43000 153281 163837 1732253 26034 15000013 42900 148472 178047 1798887 24148 15000013 42800 141141 189234 1846618 22675 15000013 42700 135140 193446 1869730 22167 15000013 42600 131564 193049 1855474 21890 15000013 42500 130647 187245 1828405 22388 15000013 42400 133002 177669 1788023 23521 15000013 42300 140875 170564 1751785 24117 15000013 42200 148462 167356 1723711 24236 15000013 42100 153034 171184 1721953 23337 15000013 42000 154680 175167 1734388 22776 15000013 41900 154778 184501 1755427 21227 15000013 41800 150354 191984 1772133 19993 15000013 41700 144127 199051 1792042 18924 15000013 41600 139575 198643 1800897 19190 15000013 41500 136806 195923 1791539 19520 15000013 41400 132500 188280 1755302 20242 15000013 41300 127287 180314 1706001 20760 15000013 41200 124045 170025 1651361 21769 15000013 41100 123228 161868 1603066 22651 15000013 41000 123366 155054 1568147 23585 15000013 40900 124469 150408 1561678 24688 15000013 40800 124174 148909 1579577 25546 15000013 40700 125110 151938 1611293 25604 15000013 40600 125602 156361 1643511 25233 15000013 40500 129130 158646 1672275 25446 15000013 40400 129140 158448 1688290 25975 15000013 40300 131810 155841 1691682 26874 15000013 40200 131179 154620 1691242 27181 15000013 40100 131682 155531 1696706 27112 15000013 40000 129031 160381 1707006 25981 15000013 39900 133643 167349 1715547 24277 15000013 39800 140432 172100 1721890 23087 15000013 39700 151704 171177 1718185 23392 15000013 39600 159853 165417 1701542 24608 15000013 39500 168465 158163 1670391 25845 15000013 39400 172416 152805 1647656 26615 15000013 39300 174633 149745 1632646 27006 15000013 39200 173047 151777 1635598 26416 15000013 39100 169618 157693 1646400 25047 15000013 39000 163578 164711 1668318 23663 15000013 38900 155971 167733 1683705 23276 15000013 38800 149487 169555 1689295 22900 15000013 38700 146295 169573 1682512 22634 15000013 38600 146777 166990 1671961 22987 15000013 38500 150413 161205 1660405 24302 15000013 38400 156375 158993 1642506 24715 15000013 38300 161656 161291 1631578 24161 15000013 38200 164031 163899 1620651 23443 15000013 38100 163528 164797 1622472 23295 15000013 38000 160582 165466 1625110 23058 15000013 37900 156020 167207 1638989 22719 15000013 37800 149487 164686 1652429 23579 15000013 37700 145290 159068 1668507 25707 15000013 37600 142856 152793 1663420 27592 15000013 37500 143959 147367 1644453 29051 15000013 37400 148167 140330 1609660 30183 15000013 37300 155271 135449 1576939 30650 15000013 37200 158444 133901 1547359 29895 15000013 37100 156818 136967 1534798 28371 15000013 37000 149063 141575 1536870 26732 15000013 36900 138747 144926 1556151 26216 15000013 36800 127888 146314 1575746 26322 15000013 36700 121582 147262 1595843 26674 15000013 36600 120774 147708 1609723 26941 15000013 36500 124459 146822 1619457 27561 15000013 36400 126795 145416 1615564 27910 15000013 36300 128884 145533 1599046 27418 15000013 36200 129465 146469 1570408 26231 15000013 36100 132096 145546 1544909 25759 15000013 36000 135219 145131 1529271 25340 15000013 35900 140589 144251 1528015 25527 15000013 35800 143890 142709 1534484 26141 15000013 35700 145989 139321 1536305 27264 15000013 35600 144432 138769 1528769 27222 15000013 35500 141663 138422 1517464 27046 15000013 35400 138885 139259 1501009 26312 15000013 35300 140432 137766 1493536 26705 15000013 35200 141644 138329 1493850 26664 15000013 35100 144176 137035 1511812 27779 15000013 35000 146807 135932 1523116 28588 15000013 34900 151625 132928 1533039 29976 15000013 34800 155567 130320 1528894 31045 15000013 34700 159035 127124 1522488 32114 15000013 34600 162523 123990 1503207 32759 15000013 34500 162504 123575 1488763 32323 15000013 34400 158680 124764 1479279 31532 15000013 34300 154138 128375 1478274 29848 15000013 34200 151418 130500 1472811 28630 15000013 34100 149970 132222 1464018 27459 15000013 34000 151872 131671 1456733 27424 15000013 33900 158680 131516 1461129 27609 15000013 33800 165410 131479 1465400 27740 15000013 33700 167647 133417 1486941 27764 15000013 33600 164149 134669 1511435 28203 15000013 33500 160158 136620 1544972 28686 15000013 33400 153764 135901 1556967 29466 15000013 33300 149536 135703 1566514 29913 15000013 33200 149182 131702 1551818 30978 15000013 33100 153714 128586 1525942 31239 15000013 33000 157902 121878 1477144 32365 15000013 32900 159607 117096 1438017 33255 15000013 32800 157518 111273 1399770 34628 15000013 32700 155754 109390 1371194 34491 15000013 32600 153034 107111 1347643 34852 15000013 32500 152079 107241 1342681 34710 15000013 32400 151862 108207 1336778 34069 15000013 32300 153399 109279 1333260 33456 15000013 32200 156828 107947 1330560 34161 15000013 32100 160523 104590 1328111 35901 15000013 32000 162149 102539 1316618 36465 15000013 31900 161981 101895 1304182 36291 15000013 31800 159518 103859 1296269 34886 15000013 31700 155665 105878 1294950 33729 15000013 31600 149418 108207 1303554 32972 15000013 31500 143743 107835 1316555 33856 15000013 31400 139841 105903 1332884 35650 15000013 31300 139417 102366 1334203 37420 15000013 31200 139190 99430 1330372 38615 15000013 31100 139111 99201 1315424 37669 15000013 31000 141614 100619 1299409 35906 15000013 30900 145753 103239 1280882 33444 15000013 30800 151271 104137 1275481 32822 15000013 30700 153724 104181 1273158 32869 15000013 30600 156808 102682 1284776 34361 15000013 30500 158079 102291 1300979 35381 15000013 30400 159745 100501 1329492 37854 15000013 30300 158641 99461 1357314 39823 15000013 30200 159094 97485 1380489 42322 15000013 30100 161725 96568 1379107 43013 15000013 30000 163381 93446 1363218 44495 15000013 29900 164661 91767 1342493 44493 15000013 29800 165982 90225 1333449 45053 15000013 29700 169007 90652 1334956 44766 15000013 29600 171628 89723 1345319 46199 15000013 29500 172209 91210 1353169 45859 15000013 29400 172377 92635 1353672 45242 15000013 29300 170761 94815 1345570 43396 15000013 29200 167253 96283 1336589 41820 15000013 29100 161971 97107 1325598 40683 15000013 29000 157626 97218 1322019 40338 15000013 28900 154916 94654 1318439 42108 15000013 28800 156188 94134 1317999 42686 15000013 28700 158542 92889 1315990 43949 15000013 28600 159331 94790 1322709 42942 15000013 28500 159252 93880 1335145 44072 15000013 28400 157912 94951 1344816 43362 15000013 28300 156611 93613 1350406 44271 15000013 28200 156976 94319 1350720 43261 15000013 28100 160592 93966 1344628 42857 15000013 28000 163262 94456 1326855 41373 15000013 27900 161173 95521 1307511 39728 15000013 27800 152798 95354 1289800 39169 15000013 27700 143516 94245 1282452 40074 15000013 27600 136678 92889 1281385 41421 15000013 27500 135505 93322 1286409 41666 15000013 27400 141614 93626 1290240 41567 15000013 27300 148521 94220 1290805 40856 15000013 27200 156867 95868 1281699 38807 15000013 27100 159685 96227 1277679 38564 15000013 27000 164287 94846 1271838 39583 15000013 26900 166149 91414 1266249 42167 15000013 26800 169963 89234 1251616 42937 15000013 26700 168120 87456 1229383 43125 15000013 26600 163499 87456 1204638 41366 15000013 26500 156059 88844 1186802 38989 15000013 26400 148669 89891 1180208 37357 15000013 26300 145024 90460 1182406 37075 15000013 26200 146472 88893 1195532 39031 15000013 26100 153951 87357 1220842 41700 15000013 26000 161439 85604 1254505 44963 15000013 25900 166425 87202 1284274 45517 15000013 25800 166859 88677 1296018 45071 15000013 25700 163371 89153 1297274 45215 15000013 25600 159833 87605 1274665 45529 15000013 25500 158070 85381 1251239 46479 15000013 25400 159252 82272 1231832 47987 15000013 25300 159833 81014 1238490 49654 15000013 25200 161183 81987 1256137 49482 15000013 25100 160129 85883 1286158 47615 15000013 25000 156237 89172 1296583 44864 15000013 24900 150768 90653 1290491 43231 15000013 24800 145792 88546 1261287 43087 15000013 24700 141762 85276 1228881 43788 15000013 24600 136461 82736 1197542 44031 15000013 24500 132273 81417 1182280 44515 15000013 24400 132588 80965 1178010 44812 15000013 24300 137614 80915 1181841 45065 15000013 24200 143250 83418 1177633 42808 15000013 24100 148561 83616 1166893 42151 15000013 24000 150256 83548 1151067 41311 15000013 23900 150788 82544 1139072 41234 15000013 23800 149073 82934 1134236 40492 15000013 23700 149103 82303 1138569 41071 15000013 23600 151123 81609 1147110 41879 15000013 23500 156266 81089 1160236 42937 15000013 23400 158848 80246 1174367 44784 15000013 23300 161459 79323 1184039 46482 15000013 23200 163656 78115 1192643 48188 15000013 23100 167430 78078 1192894 48163 15000013 23000 167342 77180 1188372 48729 15000013 22900 164849 77230 1173111 47659 15000013 22800 160612 77694 1160864 46522 15000013 22700 157222 78444 1151130 45182 15000013 22600 154916 79577 1151507 44388 15000013 22500 158010 80060 1150062 43932 15000013 22400 161282 81033 1157410 43571 15000013 22300 164533 81479 1164570 43591 15000013 22200 162001 83907 1182783 42788 15000013 22100 158887 85090 1197981 42866 15000013 22000 152660 87939 1218455 41631 15000013 21900 151251 88454 1233779 42053 15000013 21800 150364 89277 1251176 42254 15000013 21700 155921 87747 1259717 43996 15000013 21600 160947 87215 1266563 44577 15000013 21500 167785 86143 1270017 45573 15000013 21400 170879 85802 1273032 45973 15000013 21300 173628 84644 1272153 46903 15000013 21200 172515 82984 1261036 47594 15000013 21100 169697 80581 1245021 48734 15000013 21000 164987 78369 1220528 49090 15000013 20900 161242 76715 1200619 49884 15000013 20800 158868 75055 1182532 50862 15000013 20700 155084 72900 1172734 53082 15000013 20600 152512 71865 1165826 53853 15000013 20500 149221 70794 1163628 55063 15000013 20400 146373 71234 1152009 53443 15000013 20300 143703 71531 1135617 51614 15000013 20200 142550 73191 1118535 48073 15000013 20100 143772 72987 1109930 47615 15000013 20000 147014 73724 1105409 46422 15000013 19900 148994 74046 1106413 46225 15000013 19800 151655 73792 1110370 48071 15000013 19700 153527 72194 1114013 51375 15000013 19600 155705 71054 1117090 54025 15000013 19500 155626 70967 1126825 54689 15000013 19400 160188 71754 1141709 54841 15000013 19300 160237 73315 1151444 52602 15000013 19200 159203 74684 1154458 50405 15000013 19100 151852 73916 1146168 50491 15000013 19000 147063 71165 1131786 53593 15000013 18900 140511 68638 1122994 56430 15000013 18800 136067 68335 1130970 57207 15000013 18700 135702 68483 1157347 59197 15000013 18600 139870 70905 1185358 58173 15000013 18500 143812 72980 1205957 56975 15000013 18400 145102 75148 1206146 53918 15000013 18300 147999 75216 1197416 53320 15000013 18200 152019 75786 1173111 50377 15000013 18100 154266 75762 1153516 48271 15000013 18000 156040 74430 1132854 49253 15000013 17900 159006 70658 1124501 54845 15000013 17800 161804 66805 1114264 60430 15000013 17700 159971 65101 1109554 62398 15000013 17600 155281 64866 1112380 63043 15000013 17500 151113 65653 1127704 62820 15000013 17400 147802 66216 1153014 63560 15000013 17300 145368 67926 1177507 62910 15000013 17200 143339 67913 1199991 64944 15000013 17100 143260 67344 1208469 66565 15000013 17000 144275 66532 1210479 67119 15000013 16900 146019 68248 1193271 62804 15000013 16800 146649 69066 1169154 58913 15000013 16700 151645 69759 1142400 55469 15000013 16600 156099 70057 1128458 53664 15000013 16500 161045 72726 1121361 49566 15000013 16400 159242 74287 1127767 47872 15000013 16300 158207 76040 1151569 47299 15000013 16200 153606 76257 1184416 49502 15000013 16100 150039 77384 1210730 50380 15000013 16000 145595 77620 1233717 51938 15000013 15900 144432 79237 1256452 51746 15000013 15800 142471 80921 1271964 51047 15000013 15700 138816 83393 1272215 48219 15000013 15600 134865 83752 1261350 46871 15000013 15500 131790 82792 1243451 46403 15000013 15400 131731 78914 1215190 48897 15000013 15300 132677 74665 1186488 51782 15000013 15200 134628 71048 1161367 54185 15000013 15100 137762 68849 1146168 55677 15000013 15000 136481 68446 1135869 55524 15000013 14900 133209 68384 1135052 55762 15000013 14800 129583 67734 1133670 57532 15000013 14700 128351 67461 1135303 59319 15000013 14600 128844 66972 1135492 61373 15000013 14500 132628 66749 1141207 62646 15000013 14400 137949 65646 1138883 63987 15000013 14300 140018 66631 1137627 61740 15000013 14200 140865 67573 1132414 58844 15000013 14100 140974 68000 1135743 58520 15000013 14000 144482 66947 1130530 60155 15000013 13900 144935 66699 1130719 61673 15000013 13800 147536 65108 1125945 64342 15000013 13700 145900 62630 1127013 68655 15000013 13600 142196 61397 1123433 69475 15000013 13500 134106 61199 1129965 69420 15000013 13400 130332 62079 1143216 68354 15000013 13300 128962 63893 1163691 67092 15000013 13200 132667 67226 1188749 63618 15000013 13100 138510 70546 1212866 60285 15000013 13000 144541 72603 1224673 57935 15000013 12900 147152 74300 1217451 54508 15000013 12800 147270 74634 1206585 52449 15000013 12700 146768 73724 1196348 52679 15000013 12600 144009 72435 1184227 53344 15000013 12500 138924 72584 1165260 51984 15000013 12400 134401 72782 1158478 51587 15000013 12300 131465 73055 1152135 51059 15000013 12200 131189 73581 1143154 50079 15000013 12100 133682 74027 1133482 49037 15000013 12000 140915 73030 1135115 50765 15000013 11900 146718 71203 1138004 53229 15000013 11800 150492 68558 1133796 57074 15000013 11700 148502 66359 1135554 60513 15000013 11600 146344 65256 1144473 63405 15000013 11500 140639 67052 1155714 61884 15000013 11400 138609 70143 1161241 58545 15000013 11300 136776 73383 1169782 54179 15000013 11200 140599 75074 1173990 51426 15000013 11100 142383 75594 1170913 49375 15000013 11000 146689 73705 1165449 50863 15000013 10900 148521 71791 1160990 52515 15000013 10800 152867 71060 1157285 52997 15000013 10700 153980 72615 1151444 50977 15000013 10600 155133 73532 1148806 50120 15000013 10500 154798 74448 1146042 49180 15000013 10400 155143 74795 1141835 48723 15000013 10300 150739 74820 1146545 49611 15000013 10200 145615 74256 1162183 51824 15000013 10100 140314 73748 1179894 53805 15000013 10000 139496 74244 1193836 53861 15000013 9900 137899 74696 1198672 53426 15000013 9800 141614 73779 1197165 55069 15000013 9700 145033 73538 1182029 55380 15000013 9600 150699 72739 1173048 57444 15000013 9500 148541 73606 1171039 57487 15000013 9400 146275 73637 1176063 58552 15000013 9300 141417 76932 1173613 53695 15000013 9200 140215 77267 1169469 51590 15000013 9100 135456 79274 1158980 46718 15000013 9000 135505 78289 1140704 45690 15000013 8900 135554 78357 1117969 43463 15000013 8800 138323 75204 1091780 44805 15000013 8700 138116 72386 1069673 46168 15000013 8600 139801 69041 1056798 48906 15000013 8500 142186 66576 1059499 51986 15000013 8400 145871 66774 1060629 52960 15000013 8300 146167 75824 1085123 49709 15000013 8200 145733 110647 1183474 41583 15000013 8100 143999 183764 1349401 30789 15000013 8000 142944 286898 1563185 18346 15000013 7900 143151 400172 1777220 8089 15000013 7800 147359 503448 1973607 1414 15000013 7700 153803 580436 2074722 -1884 15000013 7600 160089 619565 2099718 -3567 15000013 7500 162996 629928 2079934 -4067 15000013 7400 165952 636085 2075915 -4206 15000013 7300 164859 642217 2065615 -4382 15000013 7200 161459 639913 2054875 -4355 15000013 7100 158168 626360 2029503 -4206 15000013 7000 157961 613680 1982840 -4213 15000013 6900 158405 600970 1941515 -4233 15000013 6800 158887 594262 1919785 -4253 15000013 6700 161439 596207 1928012 -4289 15000013 6600 163469 607945 1948360 -4430 15000013 6500 163972 618543 1980830 -4468 15000013 6400 161232 620302 2002434 -4364 15000013 6300 163991 612727 2014430 -4100 15000013 6200 167519 603658 2025358 -3808 15000013 6100 177244 597935 2043068 -3542 15000013 6000 183265 597340 2061784 -3404 15000013 5900 193424 599465 2080186 -3331 15000013 5800 193690 609524 2106186 -3401 15000013 5700 191335 633694 2134636 -3731 15000013 5600 179156 661364 2181174 -4027 15000013 5500 170465 686407 2232045 -4214 15000013 5400 159242 703441 2274940 -4297 15000013 5300 153596 713860 2296230 -4373 15000013 5200 148068 710763 2298052 -4316 15000013 5100 146314 703553 2285177 -4259 15000013 5000 141792 695847 2259302 -4274 15000013 4900 136195 695605 2243475 -4358 15000013 4800 129948 700313 2248060 -4425 15000013 4700 125563 710329 2272239 -4478 15000013 4600 123888 720971 2302573 -4509 15000013 4500 123375 724638 2335734 -4385 15000013 4400 121306 727790 2376619 -4210 15000013 4300 118360 734871 2410407 -4137 15000013 4200 113591 747408 2455815 -4106 15000013 4100 107423 759307 2497265 -4090 15000013 4000 100712 773950 2542610 -4111 15000013 3900 93096 774991 2547759 -4092 15000013 3800 86100 750839 2503546 -3812 15000013 3700 80562 693128 2369397 -3394 15000013 3600 78611 618915 2159507 -3108 15000013 3500 78325 537752 1896484 -3046 15000013 3400 79419 465812 1644579 -3150 15000013 3300 81084 411532 1432490 -3451 15000013 3200 82897 383429 1290240 -3871 15000013 3100 81922 368631 1215692 -4084 15000013 3000 78838 363341 1202503 -4031 15000013 2900 76699 359922 1217074 -3739 15000013 2800 74748 360696 1248727 -3411 15000013 2700 73941 362368 1281259 -3104 15000013 2600 72295 370049 1311342 -3054 15000013 2500 72472 375308 1327357 -3070 15000013 2400 72975 381292 1336464 -3198 15000013 2300 72965 381862 1333198 -3256 15000013 2200 71260 385237 1323840 -3471 15000013 2100 70108 388167 1314545 -3642 15000013 2000 69467 398450 1319109 -3935 15000013 1900 68994 411724 -999250 -999250 15000013 1800 68186 -999250 -999250 -999250 15000013 1700 66935 -999250 -999250 -999250 15000013 1600 63259 -999250 -999250 -999250 15000013 1500 57318 -999250 -999250 -999250 15000013 1400 49681 -999250 -999250 -999250 15000013 1300 44153 -999250 -999250 -999250 15000013 1200 39591 -999250 -999250 -999250 15000013 1100 37896 -999250 -999250 -999250 15000013 1000 37887 -999250 -999250 -999250 15000013 900 38872 -999250 -999250 -999250 15000013 800 38448 -999250 -999250 -999250 15000013 700 37394 -999250 -999250 -999250 15000013 600 36960 -999250 -999250 -999250 15000013 500 35896 -999250 -999250 -999250 15000013 400 35827 -999250 -999250 -999250 15000013 300 35709 -999250 -999250 -999250 15000013 200 36872 -999250 -999250 -999250 15000013 100 37778 -999250 -999250 -999250 15000013 000 40399 -999250 -999250 -999250 15000013
1
A review of data pertaining to the hydrocarbon prospectivity of the Savory Sub-basin Officer Basin
Western Australia
by
M K Stevens and G M Carlsen
Abstract
The Savory Sub-basin of the Officer Basin in central Western Australia is part of a large Neoproterozoic episutural basin and is a frontier for hydrocarbon exploration It contains up to 8 km of clastic carbonate and rare evaporite sedimentary rocks with minor volcanic dykes sills and flows No petroleum exploration activity had been undertaken in this sub-basin prior to 1995 and hydrocarbon prospectivity is assessed from mineral and recent petroleum exploration drilling No seismic data have been acquired An interpretation of available data suggests that source-rock quality is the major exploration risk but that further investigation of the sub-basin is warranted
Minor oil shows (fluorescence with solvent cut) recorded in Spearhole Formation sandstones in the northwest of the sub-basin suggest oil has been generated and migrated into potential reservoirs in the sub-basin
Each of the five depositional sequences recognized in the sub-basin contain potential reservoir rocks which are seen in outcrop as friable sandstones The Durba Sandstone is interpreted as the best-quality reservoir Indications of evaporitic environments from the Mundadjini Skates Hills and Boondawari Formations suggest that seals may be provided by evaporites and mudstones Neoproterozoic to Cambrian rocks may provide structural closures including both fold and fault traps for migrating hydrocarbons Salt diapirs are interpreted from the gravity data A large semi-detailed gravity survey in the eastern part of the sub-basin revealed major folds faults and halokinetic structures
Potential source rocks include marine mudstones of the Skates Hills and Mundadjini Formations which are associated with stromatolitic dolomites and evaporites Rare outcrops of black mudstones from other units such as the Boondawari Formation also suggest source potential
The Geological Survey of Western Australia has drilled one stratigraphic hole (Trainor 1) in the sub-basin to assess the source potential of Neoproterozoic sedimentary rocks Five of the six samples analysed for Total Organic Carbon in the Cornelia Formation from this well exceeded 05 but have a high level of maturation with at best dry gas-generating potential The age of the Cornelia Formation is uncertain but at least part of it is interpreted to be Neoproterozoic and hence part of the Savory succession
Maturity data which are very sparse due to limited drilling are inferred from the Thermal Alteration Index of organic matter to be at about the base of the oil window and the top of the gas window in two
2
waterbores in the southeast of the sub-basin and a mineral drillhole in the north of the region Rock cuttings from a waterbore in the southwest of the sub-basin are overmature for hydrocarbon generation but this bore intersected mafic intrusives and hence may not be representative of maturity for the region
KEYWORDS hydrocarbon prospectivity oil shows Neoproterozoic Savory Sub-basin Officer Basin source rocks diamond drilling
Introduction
Recognition in the late 1980s of a thick sequence of generally weakly deformed Neoproterozoic
sedimentary rocks of relatively low thermal maturity previously included within the
Mesoproterozoic Bangemall Basin (defined as the Savory Basin by Williams 1992) revealed a
hydrocarbon exploration frontier The Savory Sub-basin (Fig 1) now recognized as part of the
Officer Basin is located west of outcrops of Phanerozoic cover rocks of that larger basin The
Officer Basin a large episutural basin which contains clastic carbonate and minor evaporite and
volcanic rocks is considered to be part of the Neoproterozoic Centralian Superbasin (Walter and
Gorter 1994) The age of the Officer Basin successions is not well constrained but in the Savory
Sub-basin it is largely Neoproterozoic with possible Palaeozoic strata present in parts
The boundaries defined by Williams (1992) for the sub-basin have been largely used in this
record but data from sedimentary rocks previously assigned to older basins that are now
recognised or inferred to be of early Neoproterozoic age (Supersequence 1) have been used to
assess the hydrocarbon potential of the northwestern part of the Officer Basin
The southern part of the sub-basin unconformably overlies the Mesoproterozoic Bangemall Basin
The western boundary of the sub-basin is faulted against the Bangemall Basin The eastern
boundary of the Savory Basin as defined by Williams (1992) was placed along the western edge
of Phanerozoic outcrops of the Officer Basin at approximately 123degE longitude Recent studies
(Perincek 1996ab) however have indicated there is little difference in the Neoproterozoic
geology of the two regions The northeastern boundary of the sub-basin was defined as a reverse-
and thrust-faulted contact with the Yeneena and Karara Basins of the Paterson Orogen (Williams
1992) However Bagas et al (1995) subdivided strata from the Yeneena Basin into three new
groups the Throssell Lamil and Tarcunyah Groups The older and more deformed Throssell and
Lamil Groups remain part of the Yeneena Basin and the Paterson Orogen The younger and less-
deformed sedimentary rocks of the Yeneena and Karara Basins were considered to be of
Supersequence 1 age and were reassigned to the Tarcunyah Group The Tarcunyah Group was
considered to be coeval with the older strata of the Savory Sub-basin The Tarcunyah Group
Savory Sub-basin and Officer Basin were grouped into a single tectonic unit which was informally
referred to as the greater Officer Basin (Bagas et al 1995)
3
50 km
120deg 121deg30 123deg
25deg
24deg
23deg
22deg
Blake Fault andFold Belt
Wells Foreland S
ub-basin
TrainorPlatform
MKS32200498
HamersleyBasin
PilbaraCraton
YeneenaBasin
YeneenaBasin
YeneenaBasin
CanningBasin
Sylvania Inlier
BangemallBasin
Bangemall Basin
YilgarnCraton
YilgarnCraton
GlengarryBasin
EaraheedyBasin
Ward Inlier
OldhamInlier
KararaBasin
GibsonSub-basin
(Officer Basin)
WestwoodShelf
(Officer Basin)
KingstonShelf
(Officer Basin)
Rudall Complex
Trainor Platform
(Kahrban Subgroup)
Greater Officer Basin
Savory Sub-basin
Surface anticlinesMAP
AREAPerth
Figure 1 Structural subdivisions of the Savory Sub-basin and surface anticlines
4
During 1994 in consultation with the Petroleum Industry the Department of Minerals and
Energy received State Government funding for a Petroleum Exploration Initiative to be
undertaken by the Geological Survey of Western Australia (GSWA) with a view to identifying
prospective onshore areas for oil and gas thus increasing the level of onshore exploration in
Western Australia This initiative was originally funded for the first three years of a five-year work
program Two teams of specialists were formed to investigate the prospectivity of both the western
margin and interior onshore sedimentary basins
The Petroleum Exploration Initiative teams seek to enhance the prospectivity of onshore
basins by reducing through focused investigations the risks perceived by industry to be factors
limiting exploration activity Comprehensive petroleum system reports of the onshore Western
Australian basins are to be completed as a result of the projects undertaken during the five-year
Initiative The objective of the Initiative will be achieved through both the analysis of open-file
exploration data and the acquisition of new data New data will include but not be limited to
geophysical surveys and stratigraphic drilling Project results are to be reported to the industry
through GSWA publications external publications conference reports and oral presentations
This Record is the third in a series of comprehensive reviews by the GSWA of the
hydrocarbon prospectivity of some of Western Australiarsquos interior onshore sedimentary basins
The first Record of this series covered the Canning Basin (Apak and Carlsen 1997) The second
Record reviewed the Western Australian Officer Basin (Perincek 1998) but excluded the Savory
Sub-basin
This study assesses the potential for hydrocarbon exploration within the Savory Sub-basin
based on available geological and geophysical data and defines the scope for future studies
Publications relevant to this investigation but which are not specifically referred to are listed in
Appendix 1
Access and climate
The Savory Sub-basin lies east and southeast of the mining town of Newman in the Pilbara region
(Fig 2) The area is largely uninhabited the only settlement being an outcamp at Poondawari on
the GUNANYA 1250 000 map sheet The outcamp is linked by a graded track to the Jigalong
Community 90 km to the west just outside the northwest margin of the sub-basin A few pastoral
leases lie along the margins of the sub-basin but the majority of the region is Vacant Crown Land
Capitalized names refer to standard map sheets
5
Sealed road
Gravel road
Track
Town
Homestead
Locality
STANLEYSavory Sub-basin boundary 1250 000 map sheet
CornerTrack
Talawana - Windy
Route
Watch Point
NEWMAN
JigalongCommunity
RobertsonRange (abd)
Wokalba
Poondawari
Balfour Downs
Billinnooka
Weelarrana
Beyondie(abd)
Kumarina
Marymia
Glen-ayle
White Lake
Hanging RockBoorabee Hill
WellsRa
EmuRa
Robertson
Ra McFadden R
a
DiebillHills
DurbaHills
Calvert Ra
WardHills
Cornelia Ra
KellyRaBlakeHills
HillsDean
ROBERTSON GUNANYA
TRAINORBULLEN
BALFOUR DOWNS RUDALL
NABBERU STANLEY HERBERT
50 km
Woora Woora Hills
120deg 121deg30 123deg
25deg
24deg
23deg
22deg
Goldfieldsnatural gaspipeline
GR
EA
TN
OR
TH
ER
NH
IGH
WA
Y
Mar
ble
Bar
Nul
lagi
ne-
Rd
MADLEY
Can
ning
Stoc
k
MKS31120598
Goldfields natural gas pipeline
Figure 2 Localities and access routes of the Savory Sub-basin
6
The sealed Great Northern Highway lies west of the Savory Sub-basin and links Meekatharra
to Newman The TalawanandashWindy Corner graded track crosses the northern part of the sub-basin
and graded pastoral station tracks on Balfour Downs Weelarrana Kumarina Marymia and Glen-
Ayle give access to the western and southern margins The Canning Stock Route traverses the sub-
basin from north to south and is a well travelled four-wheel-drive track allowing access to the
eastern half of the sub-basin Additional minor tracks also provide access to other parts of the area
(Williams 1992) Recently flown monochrome aerial photography at 150 000 and Landsat TM
imagery covering the sub-basin is available from the Department of Land Administration
Cross-country access is similar to that in the Canning Basin with the average height of sand
dunes being lower in the Savory Sub-basin Potable water has been found in water bores in the
south of the sub-basin and is inferred to be present throughout the region Fuel and supplies are
available at Wiluna Meekatharra and Newman A good working relationship with the Western
Desert Community who hold native title claims over most of the sub-basin has been established
by GSWA
There are no meteorological stations within the Savory Sub-basin but estimates based on data
from nearby Bureau of Meteorology Stations indicate that the area is arid and has its maximum
rainfall in summer from monsoonal rains The sub-basin has reasonable access and a tolerable
working climate for all exploration activities Meteorological data for the town of Wiluna which
lies about 180 km to the south of the sub-basin are included as Appendix 2
Regional geology
Stratigraphy
Thirteen formations were recognized by Williams (1992) in the Savory Sub-basin and these are
summarized in Table 1 Although unconformities were recognized between some of the
formations and they reflect a wide range of depositional environments provenance and climatic
conditions these formations were defined by Williams (1992) as constituting the Savory Group
Five depositional sequences that are generally unconformity-bounded were recognized by
Williams (1992) (Fig 3) The correlation of significant formations within the sub-basin with other
parts of the Centralian Superbasin is shown in Figure 4 with the four Neoproterozoic
Supersequences having been defined by Walter et al (1995)
7
Durba Ss
McFadden
Woora Woora400
Tchukardine700
Skates Hills
Mundadjini1800
B
Coondra
(B)
Watch Point
Spearhole1100Jilyili
1000(A)
Glass Spring1600(A)
Brassey Range1700(A)
Abs
ent
Absent Absent
Absent
Absent
Absent
A
B
C
D
E
1A
1B
3
4A
4B
1000
2000
3000
4000
5000
6000
Max
imum
thic
knes
s
Sup
erse
quen
ce
AG
EN
EO
PR
OT
ER
OZ
OIC
NE
OP
RO
TE
RO
ZO
ICT
O
CA
MB
RIA
NM
AR
I-N
OA
N
NW SE
Savory Sub-basin Stratigraphy
MKS30 120598
Fault boundary
Unconformity
Disconformity
Conglomerate
Sandstone Mudstone
Siltstone
Evaporite
Dolomite
Boondawari800 Boondawari
Supersequence 2 is not represented in the Savory Sub-basin Total thicknesses are estimated from air photo interpretation Thicknesses of recessive units are unknown
Diamictite
Dep
ositi
onal
seq
uenc
e
Figure 3 Formations lithology and depositional sequences AndashE of the Savory Sub-basin
8
Table 1 Summary of formations in the Savory Sub-basin
Formation Super Depo Lithology Thickness Depositional Savoy Comments Seq(a) Seq(b) (m) environment Group(c)
Durba Sandstone 4 E Quartz sandstone with minor 100 Fluvial lacustrine Y Excellent reservoir basal conglomerate lenses Woora Woora 4 D Medium-grained ferruginous 400 Shallow marine deltaic Y Formation sandstone lithic sandstone quartz wacke siltstone McFadden 4 D Laminated fine- to coarse-grained 1 500 Shallow marine deltaic Y Possible reservoir Formation quartz sandstone feldspathic sandstone quartz wacke minor conglomerate siltstone Tchukardine 4 D Medium- to coarse-grained sandstone 700 Shallow marine Y Formation lithic sandstone quartz wacke conglomerate lenses siltstone minor shale Boondawari 3 C Glacigene diamictite sandstone siltstone Formation shale conglomerate minor dolomite (some stromatolitic and oolitic) rhythmite 800 Glacial shallow marine Y Possible source rock Skates Hills 1 B Thin-bedded dolomite (some stromatolitic) 200 Shallow marine sabkha Y Possible source rock Formation chert evaporites fine- to medium-grained sandstone siltstone shale patchy basal conglomerate Mundadjini 1 B Fine- to coarse-grained sandstone 1 800 Deltaic sabkha Y Possible source rock Formation conglomerate siltstone minor shale shallow marine mudstone dolomite (some stromatolitic) and evaporites Coondra 1 B Coarse- to medium-grained sandstone 1 000 Fan delta Y Possible reservoir Formation poorly sorted conglomerate pebbly sandstone Spearhole 1 B Coarse- to medium-grained sandstone 1 100 Braided fluvial deltaic Y Possible reservoir Formation pebbly sandstone siltstone and oil shows in conglomerate lenses Mundadjini 1 Boondawari 1
9
Watch Point 1 B Shale siltstone fine- to medium-grained 400 Shallow marine deltaic Y Formation sandstone glauconitic sandstone Jilyili Formation 1 A Fine-grained sandstone siltstone minor shale mudstone conglomerate lenses 1 000 Deltaic Y Brassey Range 1 A Fine- to medium-grained sandstone 1 700 Fluvial deltaic Y Formation siltstone shale minor mudstone Glass Spring 1 A Medium- to coarse-grained sandstone 1 600 Shallow marine fluvial Y Formation minor conglomerate and siltstone Tarcunyah Group 1 AampB Quartz sandstone feldspathic sandstone Shallow marine sabkha N Bitumen in LDDH1 quartz wacke shale siltstone fluvial lacustrine conglomerate evaporites dolomite Cornelia 1 A Sandstone siltstone shale mudstone Shallow marine N Overmature source rocks Formation minor glauconitic sandstone deep marine in Trainor 1 Kahrban 1 A Sandstone siltstone shale 1 700 Shallow marine deltaic N Subgroup
NOTES (a) Supersequences of Walter et al (1995) (b) Depositional sequences of Williams (1992) (c) Y= assigned to Savory Group in Williams (1992) N= previously considered to be older than the Savory Group but now included in the greater Officer Basin
10
SAVORY SUB-BASIN GIBSON SUB-BASINCENTRAL OFFICERBASIN
AMADEUS BASIN
PETERMANN RANGES OROGENY
NE
OP
RO
TE
RO
ZO
IC
ST
UR
TIA
NM
AR
INO
AN
ED
IAC
AR
IAN
CAMBRIANTO
NEOPRO-TEROZOIC
AG
E (
Ma)
SOUTHS RANGE MOVEMENT
AREYONGA MOVEMENT
Steptoe
MILES OROGENY
Mission Group
Cassidy Group
Rudall Complex
Bangemall Group
unnamed
Tar
cuny
ah G
roup
4
3
2
1
MKS12a 180598
500
550
600
650
700
750
800
850
900
SU
PE
R
SE
QU
EN
CE
unnamed
Tchukardine Fm
McFadden Fm
ArumberaSst
Julie Fm
Pertatataka Fm
Olympic FmPioneer Sst
Boondawari Fm
Turkey Hill FmLupton Fm
Kanpa Fm
Neale FmBabbagoola
FmHussar
Fm
Browne Fm
Woolnough Fm
Madley Fm
Bitt
er S
prin
gs F
m
LovesCreek M
Gillen M
Heavitree Fm
Arunta Complex
Throssell Group
TownsendQuartzite
Earaheedy Group
olderCornelia Fm
Jilyili Fm
SpearholeFm
MundadjiniFm
Skates Hills Fm
Lefroy Fm
Areyonga Fm
Aralka Fm
ME
SO
-P
RO
TE
RO
ZO
IC
Waters Fm
youngerCornelia Fm
Brassey RangeFormationKahrban
Subgroup
GlassSpring
Fm
Durba Sst
LP1ALP1B EVENT
Figure 4 Correlation of Savory Sub-basin formations with the western Officer and Amadeus Basins Fm = Formation Sst = Sandstone M = Member
11
The depositional sequences recognized in the sub-basin are an order of magnitude thicker than
those described from Phanerozoic passive-margin settings (Payton 1977 Posamentier et al 1988)
and are broadly comparable in scale to the second-order cycles of Vail et al (1977) and to the
megasequences of Hubbard et al (1985) The main subsurface data available to reveal the
unweathered nature of these rocks are Trainor-1 and the three-well diamond coring program in
Petroleum Permit EP 380 (Akubra 1 Boondawari 1 Mundadjini 1) completed in late 1997 in the
central west of the sub-basin (Figs 5 and 6)
The ages of all formations in the Savory Sub-basin are poorly constrained The only fossils
known are stromatolites and palynomorphs (acid-insoluble microfossils) Palynology from
available wells is summarized in Appendix 3 from Grey and Stevens (1997) and Grey and Cotter
(1996) and correlations using stromatolite biostratigraphy (Stevens and Grey 1997 Grey 1995f
Walter et al 1994 1995) are consistent with a Neoproterozoic age for the formations for which
data are available
A dolerite within the Boondawari Formation gave a poorly constrained RbndashSr age of about
640 Ma (Williams 1992) SHRIMP UndashPb dating of sedimentary zircons from the McFadden and
Cornelia Formations in stratigraphic drillhole Trainor 1 are discussed in Stevens and Adamides (in
prep) and Nelson (1997) The youngest ages from these analyses indicate that the maximum age
of the Cornelia Formation is Early Cambrian or Sturtian but these ages are inconsistent with
previous tectonic interpretations (Williams 1992) and current stratigraphic correlations which
suggest the Cornelia Formation is of Supersequence 1 age or older (Fig 4)
Depositional Sequence A Supersequence 1
Depositional Sequence A includes the Glass Spring Jilyili and Brassey Range Formations (Fig
3) All of these units are predominantly quartzose sandstones some of which are friable and have
significant visible porosity in outcrop Conglomerates are present in the Glass Spring and Jilyili
Formations
Depositional Sequence B Supersequence 1
Depositional Sequence B consists of the Watch Point Coondra Mundadjini Spearhole and
Skates Hills Formations (Fig 3) All of these formations contain beds of quartzose sandstone and
some also contain conglomerates The porosity of dolomites in the Skates Hills Formation appears
poor in surface exposures but its subsurface characteristics are unknown
12
50 km
120deg 121deg30 123deg
25deg
24deg
23deg
22deg
Greater Officer Basin
PNCEXP CA11PNCEXP CA12
PNCEXP CA13PNCEXP CA19
PNCEXP CA05
PNCEXP CA09
BD134589
GSWA Trainor 1 and TWB123
Fortescue River 1A
Mundadjini 1
Akubra 1Boondawari 1
TWB4TWB5
TWB6
TWB7
TWB8
TWB9
TWB10
BWB1
BWB2 BWB3
BWB4
BWB5
OD23
Mineral exploration drillhole
Stratigraphic drillhole
Waterbores and wells(TWB and BWB serieswaterbores identified)
MKS33270398
LDDH 1
Savory Sub-basin
Canning SR Well 13
EP380
Petroleum Exploration permit
Petroleum exploration well
Figure 5 Locations of petroleum exploration wells mineral exploration and stratigraphic drillholes water bores and wells and petroleum exploration permit EP380 in the Savory Sub-basin
13
TD=600m
TD=1367m
TD=701m
TD=709m
TD=50m
SS
1S
S1
SS1
SS
1S
S1
SS
1
SS
1
SS1
SS4 SS1
Pha
nero
zoic
or
SS
2
Cz
CzCz
Karst Bitumen
SS1
TD=181m
Mundadjini 1 Akubra 1 Boondawari 1 LDDH 1 Trainor 1 TWB 6
Munda-djini Fm
Spear-hole Fm
Munda-djini Fm
Munda-djini Fm
Spear-hole Fm
Spear-hole Fm
Waters Fm
McFadden Fm
Cornelia Fm
Cornelia Fm
Cornelia Fm
511 plusmn 13Maor 696 plusmn 20Ma(maximum)
779 plusmn 10Ma(maximum)
Mundadjini 1
Akubra 1 Boondawari 1
LDDH 1
Trainor 1TWB 6100 km
N
LOCATION
NW SE
Sea level
0m AHD
Dolerite basalt
Conglomerate
Sandstone
Mudstone
Dolomite
Limestone
Evaporite
TOC gt08
Permeability gt100md
Oil fluorescence
Sedimentary zircon U-Pb age
Identifiable polymorphs
Cainozoic
Supersequence 1 age
Unconformity
Formation contact
Cz
SS1
r
r
0
100
200
metres
VerticalScale
MKS36 120598
LEGEND
Figure 6 Geological cross section through significant drillholes in the Savory Sub-basin
14
Depositional Sequence C Supersequence 3
Depositional Sequence C consists of the Boondawari Formation (Fig 3) and although it contains
sandstone conglomerate and dolomite the sandstones contain significant amounts of feldspar and
clay and hence are likely to be poorer reservoirs than older sandstones
Depositional Sequence D Supersequence 4
Depositional Sequence D includes the McFadden Tchukardine and Woora Woora Formations
(Fig 3) The McFadden Formation is poorly sorted and sandstones contain significant amounts of
feldspathic clasts in the north of the basin but are significantly coarser and cleaner in the northeast
of the sub-basin (Williams 1992)
Sandstones of the Tchukardine and Woora Woora Formations are generally cleaner than those
of the McFadden Formation and are expected to have fair to good porosity although the
Tchukardine Formation has a higher clay content in parts
Depositional Sequence E Supersequence 4
Depositional Sequence E consists of the Durba Sandstone (Fig 3) a coarse sandstone with minor
conglomerate which has good to excellent visible porosity in surface exposures
Other depositional sequences and regional correlations
Sedimentary rocks which were not included in the Savory Group by Williams (1992) but which
are likely to be of Neoproterozoic age and hence part of the greater Officer Basin include the
Tarcunyah Group the Cornelia Formation and the Kahrban Subgroup
As discussed in the Introduction all of the strata in the Karara Basin and the younger strata
of the Yeneena Basin were redefined to form the Tarcunyah Group of the greater Officer Basin
(Bagas et al 1995) (Fig 7) In outcrop the Tarcunyah Group consists predominantly of quartzose
feldspathic and arkosic sandstone shale which is carbonaceous in parts and carbonate which
includes stromatolitic dolomite Mineral hole LDDH1 drilled on GUNANYA intersected the
15
120598
122deg
123deg
21deg
22deg
23deg
24deg
23deg
22deg
21deg
122deg
123deg
Fault
Thrust
Reverse thrust
CANNINGBASIN
OFFICERBASIN
GROUP
PILBARACRATON
TARCUNYAH
SAVORY GROUP
BANGEMALL
GROUP
THROSSELL
GROUP
LAMIL
GROUP
ConnaughtonTerrane
TerraneTalbot
complexTabletop granitic
Tabletop Terrane
Permian
Neoproterozoicgranitoid
50 km
FormationWaltha Woora
McKay Fault
South west Thrust
Vines
Fault
24deg
120deg
YENEENA CANNINGBASIN
ARUNTAINLIERRUDALL
COMPLEX
AMADEUSBASIN
MUSGRAVEBLOCK
OFFICERBASINYILGARN
CRATON
GROUP
GROUP
GROUP
PILBARACRATON
GROUP
EARAHEEDY
GLENGARRY
BANGEMALL
WYLOO GROUP
SAVORY
WA
CARNARVONBASIN
GASCOYNECOMPLEX
GROUPTARCUNYAH
400 kmGROUP
SA
N
T
CamelndashTabletopfault zone
KAHRBANSUBGROUP
CORNELIAFORMATION
MKS37
Figure 7 Regional geological setting of the Savory Group and western Officer Basin The dashed line on the inset map marks the interpreted margin of the greater Officer Basin
16
Tarcunyah Group and consists predominantly of mudstone with minor sandstone limestone
dolomite and anhydrite (Fig 6)
The age of the Tarcunyah Group is uncertain although limited palynological and stromatolite
evidence suggests that it is probably coeval with Supersequence 1 of the Centralian Superbasin
Drillhole LDDH1 contains palynomorphs equivalent to assemblages in the Browne and Bitter
Springs Formations of the Officer and Amadeus Basins respectively and from the Cornelia
Formation in TWB 6 (Grey and Stevens 1997) (Figs 4 and 6) Stromatolite specimens tentatively
assigned to Acaciella australica (Howchin 1914) Walter 1972 occur in the lower Tarcunyah
Group (Bagas et al 1995) The stromatolite Baicalia burra Preiss 1972 and a conical
stromatolite were reported from the upper part of the Tarcunyah Group (Stevens and Grey 1997)
The recognition of two stromatolite assemblages interpreted to have age significance in
Supersequence 1 sedimentary rocks of the Centralian Superbasin has permitted biostratigraphic
correlations between outcrop and well data The Acaciella australica assemblage appears to be
slightly older than 800 Ma and is restricted to the middle part of Supersequence 1 The Baicalia
burra assemblage is considered to be slightly younger than 800 Ma and occurs in the upper part
of Supersequence 1 (Grey 1996b Stevens and Grey 1997) The older A australica assemblage
is recognized in the Skates Hills Formation in the Savory Sub-basin and the stromatolite A
australica itself has been tentatively identified in the lower Tarcunyah Group The occurrence of
the A australica assemblage in the Woolnough Madley and Browne Formations of the Officer
Basin and in the Loves Creek Member of the Bitter Springs Formation of the Amadeus Basin
allows correlations throughout the Centralian Superbasin (Fig 4)
The younger B burra assemblage has not been recognized in sedimentary rocks of the
Savory Group as defined by Williams (1992) but it occurs in the upper parts of the Tarcunyah
Group and allows correlation of this group with outcrops of the Neale Formation and with the
Kanpa Formation in petroleum exploration well Hussar 1 both located in the central Officer Basin
of Western Australia (Fig 4) (Grey 1996b Stevens and Grey 1997) The occurrence of the B
burra assemblage in these units permits their correlation with the Burra Group in the Adelaide
Geosyncline of South Australia (K Grey unpublished data)
The Cornelia Formation and Kahrban Subgroup outcrop in the southeast of the sub-basin and
were considered by Williams (1992) to be part of the Mesoproterozoic Bangemall Basin Limited
evidence suggests that all or parts of these two units are of Neoproterozoic age The Ward and
Oldham Inliers consist of outcrops of the Cornelia Formation Waterbore TWB 6 which was
drilled on TRAINOR in the Cornelia Formation contains palynomorphs consistent with a
Supersequence 1 age (Grey and Stevens 1997) (Figs 5 and 6) In outcrop the Cornelia Formation
17
consists predominantly of sandstone and quartzite with lesser siltstone shale mudstone and chert
In Trainor 1 this formation consists predominantly of indurated mudstone with minor sandstone
chert and dolomite A major erosional unconformity separates the Cornelia Formation from
overlying formations and parts of the Cornelia Formation have been folded with dips exceeding
70deg In contrast the majority of the Savory Sub-basin sedimentary rocks have dips of less than 30deg
except where they are adjacent to faults The Cornelia Formation apparently consists of an older
unit of steeply dipping quartzites cherts and well-indurated mudstones and a younger unit of
shallower dipping sandstones which are sub-friable in parts However caution should be used in
interpreting the age of units based on their structural deformation and additional mapping and age
dating of this formation is required
It is proposed here that the Kahrban Subgroup is likely to be of early Neoproterozoic age and
hence should be considered as part of the greater Officer Basin This proposal is based largely on
the relatively low dip of the strata (generally less than 20deg) and their west-northwest strike which
is parallel with strikes in the overlying Brassey Range Formation of the Savory Group The lower
contact of the Kahrban Subgroup is obscured but is thought to be an unconfirmity on the
Earaheedy Basin on the southeast of STANLEY (Muhling and Brakel 1985)
Structural setting
The Savory Sub-basin forms the most northwesterly sub-basin of the Neoproterozoic to
Phanerozoic Officer Basin The western boundary of the sub-basin with the Mesoproterozoic
Bangemall Basin consists of steep-reverse and strike-slip faults The northeastern boundary of the
Savory Sub-basin was mapped where Supersequence 4 formations of the Savory Group
unconformably overlie sedimentary rocks of the Karara and Yeneena Basins with the two older
units considered to be part of the Paterson Orogen (Williams 1992) This contact was defined as a
series of steeply dipping reverse faults in the northernmost parts of the sub-basin on BALFOUR
DOWNS and RUDALL and was extrapolated as an inferred reverse fault farther along strike to the
southeast on GUNANYA and MADLEY where the contact is obscured by Cainozoic sediments It is
now recognized that all the sedimentary rocks in the Karara Basin and younger sedimentary rocks
of the Yeneena Basin are from the Supersequence 1 Tarcunyah Group and part of the greater
Officer Basin (Bagas et al 1995) The northern boundary of the Tarcunyah Group and the greater
Officer Basin is in thrust-and reverse-faulted contact with the Rudall Complex and other parts of
the Paterson Orogen (Fig 7)
To the south the sub-basin unconformably overlies the Bangemall Basin The eastern
boundary of the sub-basin used in this study is where Permian and younger strata of the Officer
Basin unconformably overlie Neoproterozoic strata although there are no significant structural or
stratigraphic differences between the Neoproterozoic units
18
The sub-basin is subdivided into three principal structural areas (Fig 1) Trainor Platform
Blake Fault and Fold Belt and Wells Foreland Sub-basin (Williams 1992) A major review of
these boundaries is beyond the scope of this report but the processing of regional aeromagnetic
data (Appendix 4) and acquisition of a semi-detailed gravity survey by the GSWA in the east of
the sub-basin has enabled these tectonic units to be reassessed and some modifications are
proposed
The Wells Foreland Sub-basin (originally termed the Wells Foreland Basin in Williams 1992)
and sedimentary rocks of the Tarcunyah Group are both considered to be the northwest
continuation of the Gibson Sub-basin of the Officer Basin Aeromagnetic gravity and outcrop
data suggest that the Blake Fault and Fold Belt is significantly faulted and folded in the west but
is less deformed in the east where the thickest sedimentary section in is located on BULLEN
(Appendix 4) The Trainor Platform is reinterpreted to represent an area of the sub-basin that has
undergone major compression during the Petermann Ranges Orogeny resulting in folding and
faulting with a northwest strike This interpretation contrasts with that proposed by Williams
(1992) who envisaged that only a thin section of the Savory Group was present on the platform
Perincek (1998) has recognized nine periods of tectonic activity in the Officer Basin from the
beginning of the Neoproterozoic to the end of the Cretaceous Three major tectonic episodes are
recognized in the Centralian Superbasin The oldest event is the Areyonga Movement which is
pre-Sturtian and forms the boundary between Supersequences 1 and 2 (Fig 4) The Souths Range
Movement occurred at the end of the Sturtian at the boundary between Supersequences 2 and 3
The youngest major event is the Petermann Ranges Orogeny which occured at the end of the
Marinoan and forms the boundary between Supersequences 3 and 4
One minor and two major tectonic episodes are recognized in the Savory Sub-basin the
LP1ALP1B structural event and the Areyonga Movement and the Petermann Ranges Orogeny
respectively The LP1ALP1B structural event is revealed where the Spearhole Formations rests
disconformably and locally unconformably on the Brassey Range Jilyili and Glass Spring
Formations The Neoproterozoic Areyonga Movement (equivalent to the Blake Movement of
Williams 1992) produced folds and faults with a general northeast strike in the western and
southern parts of the region The Souths Range Movement has not been recognized in the sub-
basin This may be due to the fact that no Sturtian glacial rocks have been identified and hence it
is possible that structures attributed to the Areyonga Movement could be the result of the Souths
Range Movement or a combination of the two movements
The major tectonic event recorded in the sub-basin is the latest Neoproterozoic to Cambrian
Petermann Ranges Orogeny (equivalent to the Paterson Orogeny) which produced large reverse
19
faults thrusts strike-slip faults and folds with a general northwest strike The McFadden
Formation and other Supersequence 4 strata are considered to be at least partially coeval with this
orogeny (Williams 1992) We also interpret the Durba Sandstone as having been deposited during
the later stages of the Petermann Ranges Orogeny as this unit mildly deformed with fold axes
parallel to the strike of other structures attributed to the Petermann Ranges Orogeny
Quantitative aeromagnetic interpretation of the Savory Sub-basin utilizing the 3D Euler
deconvolution method supported by wave-number filtering and image processing has provided
structural trends and depth to magnetic source within the sub-basin (Cowan 1995) Gravity data
are interpreted by Cowan (1995) as changes in both the density of the basement rocks andor
basement topography depending on local conditions Part of Cowanrsquos report is reproduced in
Appendix 4
Exploration history
The only petroleum exploration conducted in the sub-basin has been the recent drilling in the
western part of three diamond drillholes of which two have minor oil shows (Table 2) There has
been some mineral exploration the results of which are stored in the GSWA Western Australian
Mineral Exploration (WAMEX) database system Much of the mineral exploration was in the
southwest and west where the sub-basin is in contact with the Bangemall Basin and along the
northern margin of the sub-basin Many of these mineral exploration programs included
aeromagnetic surveys and surface geochemical sampling (Fig 8)
Hydrocarbon potential
The sub-basin contains a sedimentary succession up to 8 km thick which is generally gently
folded and faulted and apparently unmetamorphosed Limited drilling has shown that thick
mudstones are present in the sub-basin with some mudstones in Trainor 1 having high Total
Organic Carbon (TOC) values Outcrops of sub-friable sandstones in many of the formations
within the sub-basin suggests widespread reservoir potential Mudstone and inferred thick
evaporite sequences are likely to form seals Maturity data suggest that near-surface samples are
approximately at the base of the oil window and top of the gas window in parts of the north and
southeast of the sub-basin However parts of the southwest of the sub-basin and the mudstones in
Trainor 1 have very high levels of maturity Numerous faults and folds have been identified from
surface mapping suggesting good potential for large structural traps Minor oil shows in
20
Table 2 Neoproterozoic formations and hydrocarbon shows in diamond drillholes in the Savory Sub-basin
Drillhole AMG Core TD (m) Approx Formation Depth Formation Depth Formation Depth Shows (AGD84) start (m) GL (m) (m) (m) (m)
LDDH 1 431148E 112 701 350 Tarcunyah 68ndash701 ndash ndash bitumen at 6623 m 7443826N Group Trainor 1 473640E 6 709 455 McFadden 9ndash83 Cornelia Fm 83ndash709 possible bitumen at 4537 m 7287400N Fm Mundadjini 1 319056E 170 600 500 Mundadjini 16ndash361 Spearhole Fm 361ndash600 10 fluorescence at 36102 m 7404844N Fm Boondawari 1 348959E 299 1 367 490 Mundadjini Fm 15ndash312 Spearhole Fm 312ndash1 283 Intrusive 1 283ndash1 367 40 fluorescence at 35364 m 5 7398174N fluorescence at 4963 m Akubra 1 334249E 15 181 530 Mundadjini 15ndash42 Intrusive 42ndash181 None 7401252N Fm
21
50 km
120deg 121deg30 123deg
25deg
24deg
23deg
22deg
Greater Officer Basin
Savory Sub-basin
1
2
3
4
6
8
3 Seismic line (prefixed N83-00)
Aeromagnetic survey
GS
WA
Sav
ory
1995
gra
vity
sur
vey
Gravity survey
MKS34270398
Figure 8 Locations of aeromagnetic and gravity surveys (other than regional BMRAGSO data)
22
sandstones in two petroleum wells in the northwest of the sub-basin and bitumen and oil shows
elsewhere in the region indicate that oil has been generated and migrated through the sub-basin
Source rocks
Source potential is considered to be the major exploration risk in the Savory Sub-basin although
minor oil shows in Mundadjini 1 and Boondawari 1 indicate that at least some oil has been
generated and migrated into potential reservoirs within the sub-basin Sandstone is the
predominant lithology observed in outcrop Outcrops of fine-grained lithologies in the basin are
rare because of intense surface weathering and erosion Only about 8 of the surface area of the
sub-basin is exposed bedrock and recessive lithologies (such as shale evaporite and friable
sandstone) may be present although they rarely outcrop
Outcrops of stromatolitic dolomite with associated cauliflower chert and cubic pseudomorphs
interpreted as being after halite indicate that evaporitic environments are present within the
Mundadjini Skates Hills and Boondawari Formations Evaporitic minerals are also present in
drillhole LDDH1 in the Tarcunyah Group
In 1995 GSWA drilled a continuous-core diamond drillhole (Trainor 1) in the sub-basin on
TRAINOR to a depth of 709 m to test for source rocks thus providing the first such data for the sub-
basin The drillhole intersected flat-lying clastics and carbonates of the McFadden Formation (9ndash
83 m) overlying indurated mudstones of the Cornelia Formation (83ndash709 m total depth) dipping at
about 40deg Of the six samples analysed from the Cornelia Formation in this drillhole the five
located between 375 and 6032 m depth have TOC values exceeding 05 (range 066ndash365)
Rock-Eval pyrolysis of these five samples indicates that they are at best in the dry-gas thermal
stage and as a result of their high level of maturation (Stevens and Adamides in prep) have poor
remaining hydrocarbon-generating potential Although the Cornelia Formation is overmature at
Trainor 1 the high TOC values are encouraging as it is likely that this sequence is less mature
elsewhere in the sub-basin
The Mundadjini Formation contains potential source rocks that comprise marine mudstones
with evaporitic minerals present in parts Thin dark mudstones were intersected in the Mundadjini
Formation in Akubra 1 In Mundadjini 1 and Boondawari 1 however the mudstones appear to be
too oxidized to have source potential
The Boondawari Formation also may be a source rock as it contains black mudstones The
unit is laterally equivalent to the Pertatataka Formation of the Amadeus Basin and the Ungoolya
23
Group of the Officer Basin in South Australia both of which have some source potential
(Summons and Powell 1991 Morton and Drexel 1997) Samples from the Dey Dey Mudstone of
the Ungoolya Group generally have poor TOC values (average 011 range 003ndash081)
moderate hydrogen index (HI) values (100ndash382) and poor to fair genetic potential with a
maximum of 292 kg hydrocarbon per tonne of source rock (Morton and Drexel 1997)
Stromatolitic dolomites and mudstones at the top of the Boondawari Formation and within the
Skates Hills Formation are potential source rocks Stromatolitic dolomite and evaporitic rocks
deposited in a marginal marine to sabkha environment are considered to have good potential to
generate and preserve organic carbon without requiring a deep-water setting (Stevens and Grey
1997) Such conditions are recognized in the Skates Hills Formation and in the upper parts of the
Tarcunyah Group
Maturity
Knowledge of the maturity of sedimentary rocks within the Savory Sub-basin is still limited From
a review of palynological studies Grey and Stevens (1997) report that the thermal maturity
inferred from the Thermal Alteration Index (TAI) of 3+ from Supersequence 1 age palynomorphs
in TWB 6 TWB 9 and LDDH1 is within the hydrocarbon window (Appendix 3) In Phanerozoic
spores and pollen a TAI of 3+ approximately equates to the end of liquid petroleum generation
and the start of dry gas generation and to a vitrinite reflectance of about 13 (Traverse 1988)
However the use of TAI for estimating thermal maturity from Neoproterozoic palynomorphs
requires calibration
In Trainor 1 the Cornelia Formation contains organically rich claystones between 375 and
6032 m depth Based on Rock-Eval maturity data (Stevens and Adamides in prep) and the dark
colour of poorly preserved organic material (Grey 1995de 1996) with TAI 4- to 5 all samples
had a high level of maturation with at best dry-gas generating potential remaining In contrast
drillhole LDDH1 on GUNANYA recorded lower levels of maturity (TAI values of 3+) with two of
sixteen samples from the Tarcunyah Group having greater than 1 TOC (Grey 1995abc Grey
and Cotter 1996) Organic petrology and Rock-Eval maturity data for samples from LDDH1
indicate that the section above 500 m is within the oil-generative window whereas below 500 m
the rocks are within the gas window (Ghori in prep Fig 9 Appendix 5)
Waterbores TWB 1 2 6 and 9 which are located on TRAINOR in the southeast of the sub-
basin all had organic matter with TAI values of 3+ from the McFadden Skates Hills Cornelia
and Brassey Range Formations respectively
24
100
200
300
400
500
600
700
Oil
gene
ratin
g
Gas
gene
ratin
g
Fai
r
Fai
r
Poo
r
Poo
r
Goo
d
Imm
atur
e
Oil
win
dow
Oil
win
dow
Imm
atur
e
01 0110 10 0 150 300 440 480 1
Neo
prot
eroz
oic
TOC S1+S2 mgg Hydrogen Index Tmax degC
Depth(m)
Organicrichness
Generatingpotential
Kerogentype Maturity Maturity
TD=701m
Sandstone
Mudstone
Dolomite
Limestone
Evaporite
Source rock
MKS40 070498
Ro equivalent
Figure 9 Petroleum source potential of rocks in Normandy LDDH1
Small amounts of organic matter associated with basalt and dolerite in cuttings from
waterbore BWB 1 on BULLEN showed high levels of thermal maturity (Grey 1995a Libby 1995)
It is unclear whether all sedimentary rocks on BULLEN are overmature for hydrocarbon generation
or the results from BWB 1 are related to local heating events associated with the volcanic bodies
that are common in the Jilyili Formation
25
Reservoirs
Each of the five depositional sequences of the Savory Group (Table 1) are inferred to contain
significant sandstone reservoirs with the possible exception of depositional sequence C as
discussed above in Stratigraphy The Spearhole Formation was cored in Mundadjini 1 and
Boondawari 1 and visual estimates of porosity vary from generally poor (less than 5) to fair
(approximately 5ndash15) The McFadden Formation in Trainor 1 has porosity values of up to 232
and a maximum permeability of 195 md (Stevens and Adamides in prep) Sandstones from
Neoproterozoic formations form the acquifers in the following waterbores the McFadden
Formation in TWB 1 the Cornelia Formation in TWB 6 and the Brassey Range Formation in
TWB 8 and TWB 9 (Appendix 6 Table 61)
Based on outcrop observations the Durba Sandstone is considered to be the best reservoir of
the Savory Group Similarly some sandstones from the Tarcunyah Group also have good visible
porosity in outcrop
Dolomites occur in several formations in the sub-basin Reservoir potential may exist
particularly where the dolomites are stromatolitic and oolitic However dolomites have not been
drilled in the sub-basin and porosity can only be inferred from the preferential silicification of
some stromatolite bioherms observed in outcrop (Stevens and Grey 1997) Elsewhere in the
Officer Basin porosities of up to10 have been measured in dolomites A limestone breccia
(karst) is described from 663 to 677 m in drillhole LDDH1 (Fig 6 Busbridge 1994)
Seals
Indications of evaporitic environments in the Mundadjini Skates Hills and Boondawari
Formations are described by Williams (1992) In Mundadjini 1 from 287 to 337 m anhydrite and
chert occurs as nodules beds and veins in mudstone of the Mundadjini Formation Evaporitic
minerals (predominantly gypsum) are described in the Tarcunyah Group in LDDH1 The presence
of the Woolnough and Madley salt diapirs in the Officer Basin (approximately 110 km east of the
sub-basin) and halite beds over 25 m thick in the well Hussar 1 (130 km east of the sub-basin)
provide further evidence that evaporite seals may be present in the Savory Sub-basin
Mudstones and shales form only a small proportion of the limited Neoproterozoic outcrop in
the sub-basin but significant thicknesses of mudstone were encountered in the Mundadjini
Formation in Mundadjini 1 and Boondawari 1 the Tarcunyah Group in LDDH1 and in the
26
Cornelia Formation in Trainor 1 These data suggest that mudstones form a significant proportion
of strata in the sub-basin despite their limited outcrop
Traps
Potential structural closures including folds and faults occur at various scales throughout the
Savory Sub-basin However the region has only been mapped at 1250 000 scale and
independently closed structures such as domes have yet to be confirmed The western margin of
the basin contains abundant faults (with a northeast strike) but elsewhere faults are less common
Some anticlines are recognized in outcrop including one with a strike length of up to 45 km
inferred from surface bedding dips in the Mundadjini and Spearhole Formations at approximately
24deg15rsquoS 121deg10rsquoE on BULLEN (Fig 1)
Salt diapirs and other halokinetic structures are recognized in outcrop well and seismic data
in the Officer Basin to the west of the Savory Sub-basin and it is probable that there are
significant thicknesses of evaporitic sedimentary rocks in the sub-basin The gravity field data
suggest there is good potential for salt diapirs and traps related to halokinesis
Although there is potential for stratigraphic traps to be present in the sub-basin insufficient
data are available to assess them
Preservation of hydrocarbons
The range of thermal maturities measured to date and the large periods of time envisaged for
deposition of sediments implies hydrocarbon generation may have occurred a number of times
during the evolution of the Savory Sub-basin Any hydrocarbons that were generated early may
have been trapped in palaeostructures and remigration to younger traps could have taken place
later The Petermann Ranges Orogeny which has been equated with the Paterson Orogeny (Myers
1990) is believed to have occurred in the latest Neoproterozoic to early Cambrian This is the last
major tectonic event recognized in the sub-basin suggesting that it is reasonable to expect that trap
integrity will have been preserved
If the inference of the presence of thick halite beds in the sub-basin is correct the preservation
potential of sub-salt traps should be excellent
27
Reported hydrocarbon shows and oil seep
Amadeus Petroleum recorded minor oil shows in cores from Mundadjini 1 and Boondawari 1 In
Mundadjini 1 at 36102 m (top of the Spearhole Formation) a 3 mm thick zone had 10 moderate
white fluorescence with slow solvent cut This show was in a granular sandstone with visually
estimated porosity of about 10 In Boondawari 1 at 35364 m (within the Spearhole Formation) a
broken surface of sandstone had 40 moderate yellow-white fluorescence with slow solvent cut
Visually estimated porosity is about 5 Because the fluorescing surface was broken during the
drilling process this show could have resulted from contamination A second show occurs in
Boondawari 1 at 4963 m (within the Spearhole Formation) where a 1 cm-thick zone had 5 dull
yellow fluorescence with slow solvent cut in a conglomerate with visually estimated porosity of
about 10 The company intends to further investigate the nature of these occurrences
Minor bitumen is present at 6623 m in drillhole LDDH1 on GUNANYA (Figs 5 and 6) as a
vein in mudstones of the Tarcunyah Group A sample was analysed by gas chromatography
(Ghori in prep) and confirmed that it is natural bitumen (Appendix 5)
Mineral hole OD 23 drilled by Jubilee Gold Mines NL on NABBERU in the Bangemall Basin
immediately to the south of the Savory Sub-basin (Fig 5) encountered bitumen and trace oil in
vugs in dolomite (M Stevens unpublished data) but no further data are available at present
In their popular guide to the Canning Stock Route Gard and Gard (1990 p 218) refer to an
oil seep at Well 13 on TRAINOR (Fig 5) They reported that between 1977 and 1984 lsquonatural oilrsquo
was seen in the well Although the well is now largely filled with sediment four auger drill
samples were collected by the GSWA in 1995 and all four were analysed for oil shows One
sample from 315 m total depth (GSWA sample 135604) yielded just enough extract (519 ppm)
for saturate gas chromatography analysis The gas chromatograph (Appendix 5) shows that the
extract does contain some hydrocarbons probably from recent plant material Because the depth to
the oil was not quoted in Gard and Gard (1990) the hand-augered well may not have been deep
enough to properly test this reported seep
Geological and geophysical databases
Geological and geophysical data available for the Savory Sub-basin are limited The most recently
completed geological maps for the sub-basin were published by the GSWA between 1991 and
1995 (Williams and Tyler 1991 Williams 1992 1995ab)
28
The cores from the five drillholes listed in Table 2 believed to be all of the core available
from the sub-basin are available for inspection at GSWA Mineral exploration reports submitted
to GSWA may be searched using the WAMEX database and open-file reports are available on
microfiche Geophysical data acquired by the mining industry is not required to be filed with
GSWA if acquired over Vacant Crown Land which is the case for much of the sub-basin
Geophysical survey data submitted in mining tenement reports and which extend into Vacant
Crown Land remain confidential to the companies Original regional aeromagnetic and gravity
datasets are available from the Australian Geological Survey Organisation (AGSO)
Data pertinent to oil exploration in the sub-basin such as structural style and salt diapirism
are presented in a review of the hydrocarbon prospectivity of the Officer Basin (Perincek 1998)
Drilling
Significant drillholes in the sub-basin are summarized in Table 2
Petroleum industry data
Amadeus Petroleum drilled three petroleum exploration wells in the central west of the Savory
Sub-basin in late 1997 These wells Mundadjini 1 Boondawari 1 and Akubra 1 were drilled by
continuous diamond coring (Figs 5 and 6) All targeted potential reservoirs within the Spearhole
Formation with the Mundadjini Formation as the proposed seal The wells were located on
structures interpreted from Landsat images and limited geological investigations Both Mundadjini
1 and Boondawari 1 had minor oil shows as discussed above (Reported hydrocarbon shows)
Government data
Stratigraphic drillhole Trainor 1 was drilled by GSWA in 1995 (Stevens and Adamides in prep)
and the main results are discussed above (Source rocks and Maturity)
Mineral industry data
Normandy Exploration drillhole LDDH1 was cored in the Tarcunyah Group to a total depth of
701 m and provided source-rock and maturity data as discussed above
29
Oilmin NL drilled six percussion drillholes (BD 1 3 4 5 8 and 9) through sandstones and
shales in the northern part of the Savory Sub-basin to a maximum depth of 198 m (Fig 5
WAMEX Microfiche File M 26811 I 2610) but only brief geological descriptions are available
Hydrogeological data
Hydrogeological data within the Savory Sub-basin are limited although a long history of water
exploration extends back to the construction of the Canning Stock Route early this century No
detailed geological or wireline logs are available for the older wells along this route A few station
wells have been drilled by various methods on the south and west margins of the basin but data
are unavailable as reports are not required to be filed with the government Depth to watertable
throughout the basin is largely controlled by porosity of the bedrock
The GSWA drilled fifteen waterbores in the winter of 1995 in the southern part of the sub-
basin in preparation for the drilling of Trainor 1 and the proposed Bullen 1 Twelve bores found
water and six of these bores have salinities of less than 1000 mgL (Fig 5 Appendix 6 Table 61)
One waterbore TWB 6 has gamma ray and neutron logs run through PVC casing and these are
available from the GSWA with the digital log data included herein
Seismic data
No geophysical data have been acquired by the petroleum industry in the Savory Sub-basin
Seismic data acquired in the Officer Basin to the east particularly in the Gibson and Yowalga
Sub-basins is pertinent to structural interpretation in the Savory Sub-basin (Perincek 1996a
1998)
Aeromagnetic surveys
Government data
There are over 95 277 line kilometres of aeromagnetic data included in the AGSO dataset There
are three regional aeromagnetic surveys covering the Savory Sub-basin These were flown by the
Bureau of Mineral Resources (BMR now AGSO) in 1984 at a line spacing of 1500 m with 36 740
and 52 587 line kilometres flown and by Aerodata in 1984 at a line spacing of 1000m with 5950
line kilometres flown These data were reprocessed and interpreted for GSWA by Cowan (1995)
An edited copy of this report is included as Appendix 4 and the original report is filed in the
GSWA Library under S-series reports item 10331
30
Mineral industry data
The approximate locations of non-AGSO aeromagnetic surveys are shown in Figure 8 More
detailed information regarding the location of these surveys may be obtained using the GSWA
MAGCAT II database Additional information such as contours of aeromagnetic values may be
obtained by inspecting items on file with the GSWA
Gravity surveys
Government data
The average spacing for gravity data in the Savory Sub-basin is one station per 121 km2 (11 times 11
km grid) These data were principally collected by BMR in the early 1960s There are a few
additional regional gravity traverses across the sub-basin which are also included in the
BMRAGSO dataset These data were reprocessed and interpreted for GSWA (Fig 10) and a
report on this work is also included in Appendix 4
The GSWA completed a large semi-detailed gravity survey in the eastern Savory Sub-basin
utilizing helicopter support and Differential Global Positioning Survey (DGPS) techniques (Fig
8) This gravity survey completed in August 1995 consists of 2300 gravity stations on a 2 times 3 km
grid All stations were acquired by helicopter using Scintrex gravimeters and Ashtek dual
frequency DGPS equipment for determining location This highly efficient system allowed the
acquisition of more than 100 gravity stations per day in remote areas The resolution of this survey
is +30 cm and +05 microms-2 (Daishsat 1995) These data (Fig 11) represent a significant
improvement on the previous regional survey data and are available from GSWA (GSWA
1996ab) The results of the interpretation of these data were presented at the 1997 ASEG
Convention (Carlsen and Shevchenko 1997)
Mineral industry data
Three small gravity surveys were conducted by Oilmin NL (Fig 8) and the relevant WAMEX
reports are M 2681I 2610 I 2435 I 2567 These three surveys are of limited value because height
control was provided by barometers only and the surveys were not tied to the national gravity grid
31
23deg
25deg
120deg 122deg
Trainor 1
SAVORY
SUB-BASIN
MKS54 160498
100 km
1995 SavoryGravity Survey
254
-1056
micromsec2
Figure 10 Regional Bouguer gravity map of the Savory Sub-basin
23deg
24deg
25deg
122deg30 123deg
TRAINOR 1
123deg30
50 km
MKS53 160498
-116
-626
micro msec2
Figure11 Detailed Bouguer gravity map of the
Savory 1995 Gravity Survey from the eastern Savory Sub-basin
32
Government and academic reports
Chronostratigraphy and geochemistry
The understanding of Neoproterozoic organic chemistry palynology and structural evolution is
essential to the interpretation of hydrocarbon prospectivity Pertinent reports are included in the
bibliography (Appendix 1) Unpublished palaeontology reports describe the palynology of wells in
the Savory Sub-basin (Grey 1995andashe 1996a) Grey and Cotter (1996) discussed the potential for
Neoproterozoic palynomorphs to provide a biostratigraphic framework and palaeoenvironmental
interpretation Grey and Stevens (1997) reviewed the results of palynological studies of wells
drilled in the sub-basin and reported that Supersequence 1 palynomorphs are present in TWB 6
TWB 9 and LDDH1 (Appendix 3) Grey (1996b) reported on the use of stromatolites for
correlation in the Neoproterozoic and Stevens and Grey (1997) discussed the application of
stromatolite biostratigraphy in correlating isolated dolomite outcrops in the sub-basin with well
and seismic data in the Officer Basin and Centralian Superbasin
Although geochemical data from the Savory Sub-basin are very limited results mostly
confirm thermal maturities inferred from TAI for LDDH1 and Trainor 1 (Ghori in prep Stevens
and Adamides in prep) Those parts of the Officer Basin in Western Australia which lie to the
east of the Savory Sub-basin are sparsely drilled but Ghori (in prep) reports that most of the
Neoproterozoic succession presently lies within the oil-generative window However his study
has been unable to identify effective source-rock units and the source for oil shows Thin source
rocks are present in the Neoproterozoic in LDDH1 (Fig 9) and in three wells which lie to the east
and southeast of the Savory Sub-basin namely NJD 1 Kanpa 1A and Yowalga 3
Proposed work program
From the above limited information it is concluded that additional research on the hydrocarbon
potential of the sub-basin is justified and proposals are outlined below
bull Additional modelling of gravity and aeromagnetic data from the Savory Sub-basin is required
in light of the results from Trainor 1 and Boondawari 1 Trainor 1 showed that what appeared
to be a structurally simple area based on outcrop aeromagnetic and gravity data was in fact an
area of major structuring Boondawari 1 intersected a dolerite which is in good depth
agreement with aeromagnetic depth to source results showing this technique is useful in
detecting the depth to intrusive bodies
33
bull Additional data from mineral and petroleum exploration bores may become available and
analysis of samples from these wells should be undertaken and interpreted in the context of
their relevance to the Officer Basin
bull Stratigraphic coring in the Blake Fault and Fold Belt and in the Wells Foreland Sub-basin (Fig
1) targeting source rocks is considered essential to the continuing evaluation of the
hydrocarbon prospectivity of the Savory Sub-basin
bull Correlations using at least outcrop well and potential-field data should be prepared to link the
sub-basin with the better known parts of the Officer Basin to the east
bull Remapping is required to clarify boundary positions within the Cornelia Formation this may
resolve some of the current problems of the relationship between this unit and the rest of the
Savory Sub-basin
bull Further work is required to explain the Early Cambrian or Sturtian ages interpreted for the
Cornelia Formation from sedimentary zircon UndashPb dating in drillhole Trainor 1 The
determination of the age of the organically rich but overmature claystones in this well is
critical to assessing the hydrocarbon potential of the region
bull The thin dark mudstones intersected by Akubra 1 in the Mundadjini Formation warrant
geochemical analysis Analyses of the oil shows in Mundadjini 1 and Boondawari 1 are
currently being undertaken by Amadeus Petroleum
bull Geochemical analysis of hydrocarbons in the Bangemall Basin drillhole OD23 has been
performed by Jubilee Gold and the results will be reviewed when they are submitted to
GSWA The possibility of source rocks within the Bangemall Basin charging traps within the
Bangemall Basin and the overlying Savory Sub-basin requires further investigation
Conclusions
The Savory Sub-basin is a frontier region with only three recently drilled petroleum exploration
wells and no seismic data Based on existing geological and geophysical data it is considered too
early to draw conclusions about the hydrocarbon prospectivity of the sub-basin at this stage and
there are several reasons why the area warrants further investigation
34
1 Thick accumulations of sedimentary rocks are present (up to 8 km thickness inferred) which
may contain source reservoir and sealing strata
2 Minor oil shows occur in Mundadjini 1 and Boondawari 1 and bitumen is present in mineral
exploration drillhole LDDH1 suggesting that hydrocarbons have migrated within the
Neoproterozoic sequence of the Savory Sub-basin Oil and bitumen are present in mineral
exploration drillhole OD23 in the Bangemall Basin immediately to the south of the Savory
Sub-basin and it is possible that source rocks from the Bangemall Basin could charge traps in
the overlying Savory Sub-basin
3 The age of sedimentary rocks in the sub-basin is still poorly constrained but some of the
Neoproterozoic sedimentary rocks located on GUNANYA and TRAINOR are within the
hydrocarbon-generation window It is possible that a significant thickness of Phanerozoic
sedimentary rocks may also be present
4 Friable sandstones with visible porosity outcrop extensively suggesting numerous potential
reservoirs
5 Significant but not intense faulting and folding has been mapped implying large structural
traps may be present
6 Evaporitic sedimentary rocks occur in several formations and may provide good source rocks
and excellent seals
35
References
APAK S N and CARLSEN G M 1997 A compilation and review of data pertaining to the
hydrocarbon prospectivity of the Canning Basin Western Australia Geological Survey
Record 199610 103p
BAGAS L GREY K and WILLIAMS I R 1995 Reappraisal of the Paterson Orogen and
Savory Basin Western Australia Geological Survey Annual Review 1994ndash95 p 55ndash63
BUSBRIDGE M 1994 Lake Disappointment Exploration Licence 451064 Third Annual
Report Lake Disappointment Diamond Drill Hole LDDH1 Normandy Exploration Limited
Western Australia Geological Survey M-series Item 7567 A41358 (unpublished)
CARLSEN G M and SHEVCHENKO S I 1997 Petroleum exploration in Proterozoic basins
using potential fields data and stratigraphic coring Australian Society of Exploration
Geophysicists 12th Geophysical Conference Handbook Sydney 1997 Preview no 66 p 83
(abstract only)
COWAN D 1995 Savory Basin quantitative magnetic interpretation Western Australia
Geological Survey S-series S10331 (unpublished)
DAISHSAT PTY LTD 1995 Operational and processing report Savory Basin gravity survey
Western Australia Geological Survey S-series S10332 (unpublished)
GARD E and GARD R 1990 Canning Stock Route a travellerrsquos guide for a journey through
history Perth Western Australia Western Desert Guides 448p
GEOLOGICAL SURVEY OF WESTERN AUSTRALIA 1996a Savory Basin first vertical
derivative of Bouguer gravity image 1250 000 Western Australia Geological Survey
GEOLOGICAL SURVEY OF WESTERN AUSTRALIA 1996b Savory Basin Bouguer gravity
image 1250 000 Western Australia Geological Survey
GHORI K A R in prep Petroleum source rock potential and thermal history Officer Basin
Western Australia Western Australia Geological Survey Record
36
GREY K 1995a Savory Basin drillhole BWB 1 (Bullen waterbore) palynology and thermal
maturation GSWA Palaeontology Report no 199512 (unpublished)
GREY K 1995b Savory Basin drillholes TWB 1 2 6 9 (Trainor waterbores) palynology and
thermal maturation GSWA Palaeontology Report no 199520 (unpublished)
GREY K 1995c Palynology of Normandy-Poseidon Lake Disappointment-1 corehole
Tarcunyah Group Paterson Orogen GSWA Palaeontology Report no 199521 (unpublished)
GREY K 1995d Savory Basin drillhole Trainor 1 (Trainor diamond drilling) palynology and
thermal maturity GSWA Palaeontology Report no 199524 (unpublished)
GREY K 1995e Savory Basin drillhole Trainor 1 (Trainor diamond drilling) Additional
Preparation of two samples GSWA Palaeontology Report no 199528 (unpublished)
GREY K 1995f Neoproterozoic stromatolites from the Skates Hills Formation Savory Basin
Western Australia and a review of the distribution of Acaciella australica Australian Journal
of Earth Sciences v 42 p 123ndash132
GREY K 1996a Savory Basin drillhole Trainor 1 (Trainor diamond drilling) Additional
samples palynology and thermal maturation GSWA Palaeontology Report no 199615
(unpublished)
GREY K 1996b Preliminary stromatolite correlations for the Neoproterozoic of the Officer
Basin and a review of Australia-wide correlations GSWA Palaeontology Report no 199615
(unpublished)
GREY K and COTTER K L 1996 Palynology in the search for Proterozoic hydrocarbons
Western Australia Geological Survey Annual Review for 1995ndash96 p 70ndash80
GREY K and STEVENS M K 1997 Neoproterozoic palynomorphs of the Savory Sub-basin
Western Australia and their relevance to petroleum exploration Western Australia
Geological Survey Annual Review for 1996ndash97 p 49ndash54
HUBBARD R J PAPE J and ROBERTS D G 1985 Depositional sequence mapping as a
technique to establish tectonic and stratigraphic framework and evaluate hydrocarbon
potential on a passive continental margin in Seismic stratigraphy II an integrated approach
37
edited by O R BERG and D G WOOLVERTON American Association of Petroleum
Geologists Memoir 39 p 79ndash91
LIBBY WG 1995 A petrological report on six samples of bore cuttings from the Savory Basin
Western Australia Western Australia Geological Survey S-series S31307 (unpublished)
MORTON JGG and DREXEL JF 1997 The petroleum geology of South Australia Vol 3
Officer Basin South Australia Department of Mines and Energy Resources Report Book
9719
MUHLING P C and BRAKEL A T 1985 Geology of the Bangemall Group mdash the evolution
of an intracratonic Proterozoic basin Western Australia Geological Survey Bulletin 128
219p
MYERS J S 1990 Precambrian tectonic evolution of part of Gondwana southwestern Australia
Geology v18 p 537ndash540
NELSON D R 1997 Compilation of SHRIMP UndashPb zircon data Western Australia Geological
Survey Record 19972 196p
PAYTON C E 1977 Seismic stratigraphy mdash applications to hydrocarbon exploration
American Association of Petroleum Geologists Memoir 26 516p
PERINCEK D 1996a The age of NeoproterozoicndashPalaeozoic sediments within the Officer Basin
of the Centralian Super-basin can be constrained by major sequence-bounding unconformities
APPEA Journal v 36 pt 1 p 350ndash368
PERINCEK D 1996b The stratigraphic and structural development of the Officer Basin
Western Australia a review Western Australia Geological Survey Annual Review 1995ndash
1996 p 135ndash148
PERINCEK D 1998 A compilation and review of data pertaining to the hydrocarbon
prospectivity of the Officer Basin Western Australia Geological Survey Record 19976
POSAMENTIER H W JERSEY M T and VAIL P R 1988 Eustatic controls on clastic
deposition 1 mdash Conceptual framework in Sea-level changes an integrated approach edited by
C K WILGUS B S HASTINGS C G St C KENDALL H W POSAMENTIER
38
C A ROSS and J C VAN WAGONER Society of Economic Paleontologists and
Mineralogists Special Publication no 42
STEVENS M K and ADAMIDES N G in prep GSWA Trainor 1 well completion report
Savory Sub-basin Officer Basin Western Australia with notes on petroleum and mineral
potential Western Australia Geological Survey Record 199612
STEVENS M K and GREY K 1997 Skates Hills Formation and Tarcunyah Group Officer
Basin mdash carbonate cycles stratigraphic position and hydrocarbon prospectivity Western
Australia Geological Survey Annual Review for 1996ndash97 p 55ndash60
SUMMONS RE and POWELL C McA 1991 Petroleum source rocks of the Amadeus Basin
in Geological and geophysical studies in the Amadeus Basin central Australia edited by R J
KORSCH and JM KENNARD Australia BMR Geology and Geophysics Bulletin 236
TRAVERSE A 1988 Palaeopalynology Boston Unwin Hyman 600p
VAIL P R MITCHUM R M Jr TODD R G WIDMIER J M THOMPSON S III
SANGREE J B BUBB J N and HATLELID W G 1977 Seismic stratigraphy and
global changes of sea level in Seismic stratigraphy mdash applications to hydrocarbon
exploration edited by C E PAYTON American Association of Petroleum Geologists
Memoir 26 516p
WALTER M R and GORTER J 1994 The Neoproterozoic Centralian Superbasin in Western
Australia the Savory and Officer Basins in The sedimentary basins of Western Australia
edited by P G PURCELL and R R PURCELL Petroleum Exploration Society of Australia
Symposium Perth WA 1994 Proceedings p851ndash864
WALTER M R GREY K WILLIAMS I R and CALVER C R 1994 Stratigraphy of the
Neoproterozoic to early Palaeozoic Savory Basin and correlation with the Amadeus and
Officer Basins Australian Journal of Earth Sciences v 41 p 533ndash546
WALTER M R VEEVERS J J CALVER C R and GREY K 1995 Neoproterozoic
stratigraphy of the Centralian Superbasin Australia Precambrian Research v 73 p 173ndash195
WILLIAMS I R 1992 Geology of the Savory Basin Western Australia Western Australia
Geological Survey Bulletin 141 115p
39
WILLIAMS I R 1995a Bullen WA (2nd Edition) Western Australia Geological Survey
1250 000 Geological Series Explanatory Notes 23p
WILLIAMS I R 1995b Trainor WA (2nd Edition) Western Australia Geological Survey
1250 000 Geological Series Explanatory Notes 31p
WILLIAMS I R and TYLER I M 1991 Robertson WA (2nd edition) Western Australia
Geological Survey 1250 000 Geological Series Explanatory Notes 36p
40
41
Appendix 1
Bibliography
Reports which are relevant to this investigation but which are not specifically cited are listed
below
BAILLIE P W POWELL C McA LI Z X and RYALL A M 1994 The tectonic
framework of Western Australiarsquos Neoproterozoic to recent sedimentary basins in The
sedimentary basins of Western Australia edited by P G PURCELL and R R PURCELL
Petroleum Exploration Society of Australia Symposium Perth WA 1994 Proceedings p
45ndash62
BRADSHAW M T BRADSHAW J MURRAY A P NEEDHAM D J SPENCER L
SUMMONS R E WILMOT J and WINN S 1994 Petroleum systems in West Australian
basins in The sedimentary basins of Western Australia edited by P G PURCELL and R R
PURCELL Petroleum Exploration Society of Australia Symposium Perth WA 1994
Proceedings p 93ndash118
CLARKE G L 1991 Proterozoic tectonic reworking in the Rudall Complex Western Australia
Australian Journal of Earth Science v38 p 31ndash44
COCKBAIN A E and HOCKING R M 1990 Phanerozoic in Geology and mineral resources
of Western Australia Western Australia Geological Survey Memoir 3 p 750ndash755
ETHERIDGE M and WALL V 1994 Tectonic and structural evolution of the Australian
Proterozoic 12th Australian Geological Convention Geological Society of Australia
Abstracts no 37 p 102ndash103
GOODE A D T 1981 Proterozoic geology of Western Australia in Precambrian of the
Southern Hemisphere Developments in Precambrian geology 2 edited by I R HUNTER
Amsterdam Elsevier p 105ndash203
GREY K and JACKSON M J 1983 A re-assessment of stromatolite evidence for the
correlation of the Late Proterozoic Neale and Ilma Beds Officer Basin Western Australia
Australia BMR Journal of Australian Geology and Geophysics v 8 p 359
42
HICKMAN A H WILLIAMS I R and BAGAS L 1994 Proterozoic geology and
mineralization of the TelferndashRudall region Paterson Orogen Geological Society of Australia
(WA Division) Excursion Guidebook no 5 56p
HOCKING R M MORY A J and WILLIAMS I R 1994 An atlas of Neoproterozoic and
Phanerozoic basins of Western Australia in The sedimentary basins of Western Australia
edited by P G PURCELL and R R PURCELL Petroleum Exploration Society of Australia
Symposium Perth WA 1994 Proceedings p 21ndash 44
JACKSON P R 1966 Geology and review of exploration Officer Basin Western Australia
Hunt Oil Company Western Australia Geological Survey S-series S26 (unpublished)
JACKSON M J 1971 Notes on a geological reconnaissance of the Officer Basin Western
Australia Australia BMR Geology and Geophysics Record 19715 30p
JACKSON M J and van de GRAAFF W J E 1981 Geology of the Officer Basin Western
Australia Australia BMR Geology and Geophysics Bulletin 206 102 p
LOWRY D C JACKSON M J van de GRAAFF W J E and KENNEWELL P J 1971
Preliminary result of geological mapping in the Officer Basin Western Australia Western
Australia Geological Survey Annual Report for 1971 p 50ndash56
MYERS J S 1990 Precambrian in Geology and mineral resources of Western Australia
Western Australia Geological Survey Memoir 3 p 737ndash750
MYERS J S SHAW R D and TYLER I M 1994 Proterozoic tectonic evolution of
Australia 12th Australian Geological Convention Geological Society of Australia Abstracts
no 37 p 312
NEDIN C and JENKINS R J F 1991 Re-evaluation of unconformities separating the
lsquoEdiacaranrsquo and Cambrian systems South Australia Palaios v 6 p 102ndash108
PHILLIPS B J JAMES A W and PHILIP G M 1985 The geology and hydrocarbon
potential of the north-western Officer Basin APEA Journal 25 (1) p 52ndash61
POWELL C McA LI Z X McELHINNY M W MEERT J G and PARK J K 1993
Paleomagnetic constraints on timing of the Neoproterozoic breakup of Rodinia and Cambrian
formation of Gondwana Geology v 21 p 889ndash892
43
POWELL C McA PREISS W V GATEHOUSE C G KRAPEZ B and LI Z X 1994
South Australian record of a Rodinian epicontinental basin and its mid-Neoproterozoic
breakup to form the Palaeo-Pacific Ocean Tectonophysics v 237 no 3ndash4 p 113ndash140
PREISS W V 1976 Proterozoic stromatolites from the Nabberu and Officer Basins Western
Australia and their biostratigraphic significance South Australia Geological Survey Report
of Investigations no 47 p 1ndash51
TOWNSON W G 1985 The subsurface geology of the western Officer Basin mdash results of
Shellrsquos 1980ndash1984 petroleum exploration campaign APEA Journal v 25 (1) p 34ndash51
WATTS K J 1982 The geology of the Townsend Quartzite Upper Proterozoic shallow water
deposit of the Northern Officer Basin Western Australia Perth University of Western
Australia BSc honours thesis (unpublished)
WELLS A T and KENNEWELL P J 1974 Evaporite exploration in the Officer Basin
Western Australia at the Madley Diapirs Australia BMR Record 1974194 (unpublished)
WILLIAMS I R and MYERS J S 1990 Paterson Orogen in Geology and mineral resources
of Western Australia Western Australia Geological Survey Memoir 3 p 274ndash286
WILLIAMS I R 1990 Savory Basin in Geology and mineral resources of Western Australia
Western Australia Geological Survey Memoir 3 p 329ndash334
WILLIAMS I R 1994 The Neoproterozoic Savory Basin Western Australia in The
sedimentary basins of Western Australia edited by P G PURCELL and R R PURCELL
Petroleum Exploration Society of Australia Symposium Perth WA 1994 Proceedings p
841ndash850
WILSON R B 1967 Woolnough Hills and Madley diapiric structures Gibson Desert WA
APEA Journal v 7 p 94ndash102
44
Appendix 2
Meteorological data (from Bureau of Meteorology Perth 1994)
Table 21 Wiluna rainfall (mm)
Year Jan Feb Mar Apr May Jun Jul Aug Sept Oct Nov Dec
1975 0 45 446 309 306 59 276 4 34 886 638 164 1976 16 154 12 138 53 16 34 62 12 238 0 2 1977 44 0 66 74 68 95 24 363 1 58 12 727 1978 234 522 94 16 0 96 367 24 16 353 185 45 1979 19 173 122 88 91 4 0 246 58 0 169 114 1980 148 764 68 1081 259 626 629 06 56 02 174 0 1981 123 476 192 32 196 118 44 74 14 0 28 312 1982 374 705 206 244 1079 92 02 143 368 526 368 118 1983 1 112 928 248 0 212 56 32 5 1 42 496 1984 149 7 342 84 836 0 348 132 224 04 16 172 1985 596 483 0 166 556 0 514 56 0 0 4 0 1986 0 154 35 0 0 1085 23 01 239 137 0 04 1987 1204 119 19 89 17 575 154 126 07 1 0 398 1988 46 202 164 13 388 0 202 104 0 0 224 1309 1989 207 234 26 703 278 536 57 0 01 0 144 02 1990 1035 23 281 46 126 53 94 218 44 9 42 0 1991 48 0 41 45 0 472 297 12 0 1 0 7 1992 112 96 1025 1227 323 65 04 174 0 132 48 4 1993 0 697 0 202 445 0 12 306 18 05 14 33 Mean 25 35 22 27 27 25 18 12 6 13 13 21
JAN FEB MAR APR MAY JUN JUL AUG SEP OCT NOV DEC0
10
20
30
40
Mea
n R
ain
fall
(mm
)
Month
Mean monthly rainfall in Wiluna
MKS41 140498
45
Table 22 Wiluna minimum temperature (degC)
Year Jan Feb Mar Apr May Jun Jul Aug Sept Oct Nov Dec
1975 ndash 23 203 15 94 63 71 62 103 124 169 205 1976 242 229 194 15 10 63 59 73 95 143 16 228 1977 243 25 197 148 96 95 56 86 102 ndash 188 23 1978 241 232 203 18 102 64 76 8 9 152 19 205 1979 255 226 216 167 83 6 59 79 97 145 198 223 1980 255 226 231 155 134 83 68 75 121 108 193 223 1981 245 216 19 182 119 6 54 78 138 159 163 218 1982 232 224 177 16 ndash ndash 37 111 112 164 209 225 1983 235 24 197 147 112 88 39 88 121 162 189 219 1984 241 243 191 156 ndash 72 66 7 95 161 182 211 1985 244 231 ndash 159 98 65 71 73 117 147 205 ndash 1986 ndash 229 226 155 93 96 43 49 10 122 ndash 219 1987 ndash 217 183 175 85 77 68 68 112 ndash ndash 221 1988 238 214 209 178 111 ndash ndash 86 104 157 171 195 1989 ndash 237 199 165 107 67 44 61 107 131 187 ndash 1990 232 ndash 211 155 118 62 57 87 102 149 195 22 1991 26 256 217 168 122 101 78 ndash 113 18 168 219 1992 227 227 214 169 102 98 59 69 ndash 125 159 196 1993 241 218 196 171 103 ndash 49 68 88 128 192 211 Mean 24 23 20 16 10 8 6 8 11 14 18 21
NOTE Dashes indicate data unavailable
JAN FEB MAR APR MAY JUN JUL AUG SEP OCT NOV DEC0
10
20
30
40
Month
MKS43 140498
50
Mean monthly minimum temperatures at Wiluna
Mea
n T
emp
erat
ure
(degC
)
46
Table 23 Wiluna maximum temperature (degC)
Year Jan Feb Mar Apr May Jun Jul Aug Sept Oct Nov Dec
1975 ndash 349 326 281 247 201 197 212 256 248 31 344 1976 374 369 346 297 248 206 208 225 265 287 313 388 1977 397 392 352 296 234 212 222 244 ndash 308 337 383 1978 378 345 346 316 242 195 176 205 231 295 334 356 1979 403 36 364 295 ndash ndash ndash 193 242 318 359 373 1980 392 342 377 275 24 176 179 233 292 288 349 391 1981 385 346 337 342 242 178 201 224 30 326 326 369 1982 372 359 315 307 ndash ndash 196 253 252 305 353 379 1983 381 389 327 272 263 222 187 248 287 321 336 366 1984 378 393 322 299 226 215 178 214 234 ndash 336 364 1985 40 366 ndash 294 224 216 205 212 284 307 355 ndash 1986 ndash 383 372 307 ndash 193 166 196 261 277 ndash 382 1987 ndash 339 328 305 21 202 214 218 275 ndash ndash 374 1988 388 365 353 301 23 ndash ndash 228 283 334 31 33 1989 ndash 375 339 285 238 179 181 219 275 298 336 ndash 1990 368 ndash 36 309 268 19 188 205 274 309 373 393 1991 414 416 363 315 268 206 21 ndash 279 338 332 368 1992 363 383 336 263 213 178 213 197 ndash 285 313 359 1993 396 357 344 301 221 ndash 197 215 253 294 347 362 Mean 39 37 34 30 24 20 20 22 27 30 34 37 NOTE Dashes indicate data unavailable
JAN FEB MAR APR MAY JUN JUL AUG SEP OCT NOV DEC0
10
20
30
40
Month
MKS42 140498
50
Mean monthly maximum temperatures at Wiluna
Mea
n T
emp
erat
ure
(degC
)
47
Appendix 3
Table 31 Summary of palynological results
Drillhole Depth (m) F no(a) GSWA no Lithology Formation Assemblage TAI(b)
BWB 1 74ndash75 F49668 135741 dark-grey siltstone basalt Jilyilli gt5 BWB 1 98ndash100 F49669 135742 dark-grey siltstone basalt Jilyilli gt5 BWB 1 121ndash122 F49670 135743 dark-grey siltstone basalt Jilyilli gt5 TWB 1 86ndash87 F49671 135631 dark-grey siltstone McFadden 3+ TWB 1 104ndash105 F49672 135632 dark-grey siltstone Cornelia 3+ TWB 1 121ndash122 F49673 135633 dark-grey siltstone Cornelia 4 TWB 2 14ndash15 F49674 135634 dark-grey siltstone Skates Hills 3+ TWB 6 49ndash50 F49675 135675 dark-grey siltstone Cornelia 1 3+ TWB 9 49ndash51 F49676 135704 dark-grey siltstone Brassey Range 1 3+ Trainor 1 37497- F49733 138939 black mudstone with Cornelia 5 37509 light-grey siltstone Trainor 1 3809 F49734 138940 dark-grey and black Cornelia 4- laminated mudstone Trainor 1 4170 F49735 138941 black unlaminated mudstone Cornelia 4- Trainor 1 4950 F49851 139501 dark-grey indurated siltstone Cornelia 5 Trainor 1 6032 F49852 139502 dark- and light-grey Cornelia 5 indurated siltstone Trainor 1 6434 F49853 139503 greenish indurated finely Cornelia 5 laminated siltstone LDDH 1 270 F49678 138934 dark-grey siltstone interbeds Waters 1 3+ in enterolithic evaporite Tarcunyah Gp LDDH 1 277 F49679 138935 dark-grey siltstone in cavity Waters 1 3+ in enterolithic evaporite Tarcunyah Gp
NOTES (a) GSWA Fossil Catalogue number (b) TAI = Thermal Alteration Index of Traverse (1988 plate 1)
48
Appendix 4
Savory Sub-basin quantitative magnetic and gravity interpretation (extracted from Cowan 1995)
Summary
A program of quantitative aeromagnetic interpretation has been completed on BMRAGSO data from the Savory Sub-
basin Western Australia Quantitative aeromagnetic interpretation utilized the 3D Euler deconvolution method
supported by wavenumber filtering and image processing The results have provided useful information on structural
trends and depth to magnetic sources in a structurally complex area Depth to magnetic source analysis has provided
information on intra-sedimentary magnetic sources as well as basement rocks
The results of the interpretation support previously identified depocentres However the presence of magnetic
sources at several levels makes it very difficult to produce a reliable magnetic basement depth contour map It is
considered more productive to work with the 3D Euler colour circle plots and images rather than trying to contour the
results It would be necessary to carry out a full-scale interpretation of the BMRAGSO profile data to improve on the
3D Euler results The regional gravity was found to be useful in interpreting the regional setting of the area although
the very wide data spacing limits quantitative use of the data The gravity data show quite a complex picture with
limited consistent correlation between gravity features and basin structures This suggests that gravity anomalies
reflect changes in density of the basement rocks rather than basement topography especially in the northern part of the
basin
It is recommended that the GSWA investigate access to company confidential high-resolution aeromagnetic data
prior to planning further aeromagnetic surveys Private companies have flown large parts of the northern half of the
area as part of their diamond exploration program Additional gravity coverage of the area may be more cost effective
than magnetic surveys as the gravity data provides more information on changes within the sedimentary section
Introduction
The main use of aeromagnetic data in petroleum exploration has been the determination of magnetic basement
topography although there has been increasing interest in analysis of intra-sedimentary magnetic anomalies
intrabasement and suprabasement magnetic anomalies These anomalies are used to determine depth to magnetic
basement rocks and hence determine the thickness of the sedimentary sequence Unfortunately interpretation of the
intrabasement and suprabasement magnetic anomalies is non-unique in terms of position and size of causative sources
because of the inherent ambiguity of potential-field methods However this ambiguity can be reduced by placing
49
constraints on source geometry and magnetization and by using geological and other geophysical data to constrain
the solution
Before 1970 most depth-determination techniques involved graphical determination of slopes of selected
magnetic anomalies and application of various empirical factors to convert the slopes into depth estimates Geological
Society of America Memoir 47 Interpretation of Aeromagnetic Maps by Vacquier et al (1951) was a landmark for
this type of interpretation
Automated interpretation procedures have played an increasingly important role in depth interpretation and a
wide range of techniques have been developed Many of these techniques are designed for application to located data
profiles and assume a two-dimensional geometry However there has been renewed interest in techniques applicable
to gridded data
Two distinct types of method can be recognized In the first case often described as discrete methods individual
isolated magnetic anomalies are interpreted and the results used to produce a map of basement relief In the second
case often described as continuous methods areas of data containing a number of anomalies are interpreted
statistically to produce direct output of basement depths
The discrete methods usually involve a semiautomatic initial phase which generates a large number of possible
depth solutions and an interactive second phase to screen and select acceptable solutions The advantage of this
approach is that the interpreter can select features that are relatively free from interference from adjacent anomalies
and consider all aspects of a particular magnetic anomaly The disadvantage is that interpretation can be very time
consuming as a wide range of depths are usually possible depending on the initial model chosen and a significant
amount of effort is needed to select the correct model In the case of the Savory Sub-basin dataset we encountered
problems in separating basement related effects from the effects of shallower intrasedimentary magnetic sources
Because of these problems we have concentrated on displaying the Euler results accompanied by separation filter
images of the data to show the shallower effects and deeper effects rather than trying to refine a 3D Euler
deconvolution depth-to-crystalline-basement contour
The continuous methods are very direct provided that the rather restrictive assumption can be made that all
anomalies are due to lateral magnetization changes due to basement topography This means that shallow effects and
large intrabasement anomalies must be removed from the data This involves judgement and skill as it is necessary to
distinguish between the lower amplitude suprabasement anomalies due to basement topography and the larger
intrabasement anomalies reflecting magnetization changes within the basement These methods were not considered
suitable for the Savory Sub-basin magnetic dataset but were used to invert the gravity data
50
Limitations of magnetic and gravity interpretation
Interpretation of the area is limited by a shortage of information on the nature and physical properties of the deeper
sedimentary sequence and the underlying basement rocks However using techniques such as cross-correlation of
gravity and pseudo-gravity data it is possible to try to differentiate between anomalies relating to basement and those
related to the sedimentary sequence
Gravity anomalies reflect changes within the sedimentary sequence as well as basement condition These
changes in density of sedimentary rocks produce gravity anomalies without a corresponding magnetic anomaly hence
the complementary nature of gravity and magnetic surveys The main use of magnetics is to determine depth to
magnetic basement and any intra-sedimentary volcanic rocks or intrusives whereas gravity provides much more
general information on the sedimentary sequence
Unfortunately interpretation of gravity anomalies is complicated since they can be due to a number of geological
features including
bull major basement faults
bull basement highs
bull igneous intrusions within the basement
bull sedimentary basins which may or may not be isostatically compensated
bull intra-sedimentary volcanics and associated plutonic centres
Two major problems affect the interpretation of both magnetic and gravity data
1 The inherent ambiguity of potential-field data There is no unique solution to any measured gravity or magnetic
anomaly and theoretically there will be an infinite number of source geometry and magnetizationdensity
combinations which will fit the observed data This means that any a priori information which helps to select a
suitable model is very useful
2 Measured anomalies are the summation of effects from different depths For example an observed gravity profile
may contain contributions from shallow sources (density variations within the sedimentary basin) intermediate
depth sources (density variations due to large igneous intrusions within the basement) and deep sources (crustal
thinning producing a mantle anomaly) Separation of these component responses is the regionalresidual problem
which we solve using spectral analysis and differential upward continuation-based separation filtering
Regional setting and interpretation overview
The area studied includes parts of BALFOUR DOWNS (SF51-9) RUDALL (SF51-10) ROBERTSON (SF51-13) GUNANYA
(SF51-14) COLLIER (SG50-4) BULLEN (SG51-1) TRAINOR (SG51-2) MADLEY (SG51-3) NABBERU (SG50-5)
STANLEY (SG51-6) and HERBERT (SG51-7) 1250 000 sheets Broadly the area lies between latitudes 22deg00rsquondash25deg30rsquoS
and longitudes 119deg30rsquondash123deg30rsquoE
51
Regional gravity
The AGSO regional gravity data (at nominal 11 km spacing) was gridded at a 4 km mesh spacing using a minimum-
curvature algorithm Bouguer gravity values in the area are negative reflecting mass deficiency at depth and range
from -84 mgals to -25 mgals
A Bouguer gravity colour image is shown as Figure 41 A residual grid was produced by removing a fifth-order
orthogonal polynomial from the Bouguer data but did not add to the interpretation
120deg 121deg 122deg 123deg
23deg
24deg
25deg
-25
-84
50 km
MKS46 180598
mgal
Figure 41 Regional Bouguer gravity (BMRAGSO data) gridded at 4 km
52
The data show a complex pattern of positive and negative anomalies with no clearly defined trends Correlations
with aeromagnetic data and known basin structures are poor A vague north-northwest linear trend appears to coincide
with the Marloo Fault (Figure 42) A prominent negative anomaly appears to coincide with the Blake Fold and Fault
Belt depocentre and continues as a narrower negative anomaly to the east until it widens out again near the edge of the
basin Elsewhere the gravity data show little correlation with known basin structures and it is likely that especially in
the north of the area gravity anomalies are due to density changes in the basement rather than changes in basement
topography
Production of wavelength-filtered residual gravity plots and vertical gradient plots showed very patchy aliased
data reflecting poor sampling in much of the area
Regional magnetics
The AGSO regional aeromagnetic data were gridded at a 400 m mesh spacing using a minimum-curvature algorithm
(Figure 43) Most of the data has a line spacing of 1600 m with small areas of 1 km spacing The quality of the data is
acceptable for regional interpretation but is not adequate for detailed analysis The accuracy of the flight path is rather
variable reflecting the vintage of the data and the noise envelope of the data is poor by modern standards Problems
were also encountered in joining different map sheets
The magnetic anomaly pattern over the south and west part of the area shows a strong high frequency signature
reflecting the presence of widespread basic sills and dykes Some of the major north-northeasterly trending dykes can
be traced over considerable distances
Discontinuous high-frequency anomalies extend as a northwest-trending zone through the centre of the area and
this zone includes a conspicuous circular magnetic anomaly which is probably a ring complex
The northern and eastern parts of the area are characterized by long-wavelength deep-seated basement magnetic
anomalies with 120deg and 150deg trends dominant The Marloo and Perentie Faults (Figure 42) appear as distinct linear
zones and offsets A prominent easterly trending negative anomaly in the northwest of the area appears to swing round
to the southeast and may separate different basement blocks One possible interpretation is that this very deep seated
anomaly separates areas of Archaean and Proterozoic basement
Regional geology
The regional geology is described in Williams (1992) The GSWA provided a digitized version of Plate 2 from this
Bulletin the structural interpretation map to use as an overlay (Figure 42)
53
Pp
Pp
PSd
PSd
PSd
PSd
PSd
PSo
PSt
PSt
PSf
PSf
PSf
PSb
PSb
PSb
PSsPSs
PSs
PSb
PSm
PSp
PSc
PSc
PSw
PSw
PSw
PSg
PSr
PSj
PSg
PM
Pk
PY
PY
PSd
L
L
L
L
L
L
L
LL
L
L
L
LL
L
LL
L L
LL
L L
L
L
L
L
L
L
L
LL
L
L
BLAKEDEPOCENTRE
MA
RLO
O
FAU
LT
PERENTIEFAULT
50 km
MKS39120598
120deg 121deg 122deg 123deg
25deg
24deg
23deg
Approximate boundaryof aeromagnetic interpretation
PML
PSgL
PSjL
PML
PSpL
PML
PML
PSfL
PSfL
PSpL
LPc
LPcLPcPSrL
LPA
Durba Sandstone
Woora Woora Formation
McFadden Formation
Tchukardine Formation
Boondawari Formation
Skates Hills Formation
Mundadjini Formation
Coondra Formation
Spearhole Formation
Watch Point Formation
Jilyili Formation
Brassey Range Formation
Glass Spring Formation
Paterson Formation
Yeneena Group
Karara Formation
Cornelia Formation
Kahrban Subgroup
Bangemall Group
Fault
Formation boundary
PSdL
PSoL
PSfL
PStL
PSbL
PSsL
PSmL
PScL
PSpL
PSwL
PSjL
PSrL
PSgL
Pp
PYL
PkL
LPc
LPA
PML
Savory Group Other Units
PYL
Figure 42 Regional geology and structure map (after Williams 1992)
54
120deg 121deg 122deg 123deg
23deg
24deg
25deg
5820
3750
MKS47 180598
nT
50 km
Figure 43 Regional aeromagnetic data total magnetic intensity (BMRAGSO data) gridded at 400 m
Analysis
3D analysis
3D Euler deconvolution was used as the primary depth-determination method The advantage of this approach is that
consistent solutions can be obtained over the entire area with minimal assumptions about source geometries Euler
deconvolution of gridded data is used for positional information and estimation of depth to top of source Euler
55
deconvolution yields a large number of depth solutions which have to be screened to reject spurious solutions Results
are plotted as circles in eight depth ranges with radius proportional to depth and colour coded
The 400 m total magnetic intensity grid was used for the analysis Horizontal gradients in x and y and the vertical
gradient were calculated 3D Euler deconvolution was tested on the 400 m gridded data using windows of 9 times 9 and
11 times 11 and 16 times 16 data points and structural indices 05 (fault) and 10 (sill or dyke) It was concluded that the
16 times 16 window produced the best results overall and final plots were produced for the 16 times 16 window and structural
index 05 (Fig 44) Results were very good over the northern and central parts of the area showing magnetic sources
Figure 44 Depth to magnetic source 3D Euler deconvolution 16 times 16 window of 400 m gridded data structural index 05
56
at several different levels Unfortunately in the extreme south of the area shallow intrasedimentary magnetic sources
(sills and dykes) dominated the inversion and the results contained few basement solutions
In order to reduce these problems the 400 m gridded data were filtered using a separation filter based on
interpretation of the log-energy spectrum The 3D Euler method was run on the filtered data in order to generate more
basement-depth solutions Results for the deep-separation filter data were gridded and presented as a colour image in
Cowan (1995) Attempts to grid the Euler output were unsatisfactory and it is considered safer to interpret the 3D
Euler depth plots The 3D Euler depth results from the separation-filter run should be analysed with care as perfect
separation of the basement can never be achieved and there will always be some contamination from sources at
different levels
The results of original total magnetic intensity 3D Euler depth estimation for structural index 05 using a 16 point
window have been plotted at 1500 000 scale (not included in this publication but available in Cowan (1995) from the
GSWA Library as S10331) and as reduced A4 colour circle plots (Figure 44)
The results of deep-basement 3D Euler depth estimation for structural index 05 using a 16 point window have
been plotted as a colour image at 1500 000 scale and as an A4 image (not included in this publication)
2D analysis
Two equispaced profiles were interpolated with a 50 m station interval from the AGSO-located data profiles for the
BULLEN 1250 000 sheet The interpolated profiles were analysed using 2D Euler deconvolution and Werner
deconvolution Results are included in Cowan (1995) and show the use of these methods for more detailed analysis
Filtered data
In order to reconcile 3D Euler results from shallow basement and intrasedimentary magnetic sources we produced
several separation-filtered maps and images We found the shallow-layer double-separation filter (Figure 45) to be
very effective for shallow sources and the deep-layer standard-separation filter (Figure 46) for the basement layer
Gravity and magnetic data correlation
Both lsquoreduced to the polersquo (RTP) magnetics (Figure 47) and pseudo-gravity data (Figure 48) were produced as part of
the reconciliation of gravity and magnetic signatures In both cases the filtering operations assumed magnetization by
induction in the present Earths field The RTP data are fairly similar to the total magnetic intensity The pseudo-
57
gravity data are dominated by a northwest-trending strong positive anomaly and there is little correlation with the
Bouguer gravity data
The poor magneticgravity correlation is confirmed by cross-correlation of the RTP magnetics and the gravity
gradient The correlation plot in Figure 49 shows little coherent response with numerous zones of positive and
negative correlation
Figure 45 Regional aeromagnetic data shallow layer separation filter (BMRAGSO data) gridded at 400 m
Results
In the north and east of the area on the Wells Foreland Sub-basin trend (refer to Figure 1 main text) we see a range
of quite deep 3D Euler depths and several trend directions with north-northwesterly dominant There are relatively few
shallow intrasedimentary solutions in this zone
The second area of deep 3D Euler solutions lies over the Blake depocentre (Figure 43) with several trend
directions
Elsewhere the 3D Euler results are dominated by shallow intrasedimentary depth solutions reflecting mainly the
dolerite sills dykes and the ring complex However where we do see basement-related solutions in the south and
west of the area they appear to be shallower than those noted for the Wells Foreland Sub-basin and the Blake
depocentre
58
Figure 46 Regional aeromagnetic data deep-layer separation filter (BMRAGSO data) gridded at 400 m
Figure 48 Regional aeromagnetic data pseudo-gravity transform (BMRAGSO data) gridded at 400 m
Figure 47 Regional aeromagnetic data reduced-to-pole (BMRAGSO data) gridded at 400 m
Figure 49 Regional aeromagnetic and gravity data gravitymagnetic correlation using RTP magnetics and gravity gradient (BMRAGSO data) gridded at 4 km
59
This subdivision of the area into two zones of deep solutions is consistent with interpreted depocentres
However the interference between sources at different levels and the complexity of the magnetic response of the
basement rocks precludes more refined interpretation at this stage
The area of deep 3D Euler solutions over the Blake depocentre correlates with the pronounced negative gravity
anomaly discussed in the gravity interpretation section Using a density contrast of -015 gcc the negative gravity
anomaly could indicate up to 6ndash8 km of low-density sedimentary rocks depending on assumptions about the regional
field
The area of deep 3D Euler solutions over the Wells Foreland Sub-basin has a complex gravity expression and no
clear basin structure emerges from inversion of these data As noted previously it is likely that observed gravity
anomalies reflect contrasts in basement density rather than basement topography
Separation filtering applied to the magnetic data helps to enhance the intrasedimentary magnetic signature and to
give a better impression of the basement magnetic signature even though separation of the basement response is not
perfect
Conclusions
Quantitative aeromagnetic interpretation using 3D Euler deconvolution supported by wavenumber filtering and image
processing has been successful in providing structural trend and depth information for the Savory Sub-basin
Quantitative magnetic interpretation has revealed two zones of relatively deep magnetic basement beneath the
Wells Foreland Sub-basin and the Blake depocentre
This analysis of the magnetic data supports interpreted depocentres but the complexity of the basement magnetic
signature and interference from sources at different depths precludes further refinement to a map of basement
topography
Regional gravity proved to be very useful in understanding the regional setting of the area and in providing
support for aspects of the interpretation The gravity data support the interpretation of the Blake depocentre
suggesting up to 6ndash8 km of low-density sedimentary rocks
The deep structure of the Savory Sub-basin area is obviously complex with different areas underlain by
Archaean and Proterozoic basement and with the Capricorn suture occurring in the centre of the area
60
Recommendations
The quantitative magnetic interpretation needs to be reconciled with geological models available for the area
In particular the zones tentatively identified as areas with thick sedimentary rocks the Wells Foreland Sub-
basin and the Blake depocentre need to be investigated
Cross sections should be prepared across the basin for joint magneticgravity modelling especially for the Blake
depocentre It is important to be able to explain the strong negative gravity anomaly in this area
In view of the effects of basement density contrasts on the gravity field for the northern part of the area we think
that additional gravity interpretation and acquisition of new gravity data may not be justified as they will not
contribute significantly to understanding basin evolution and structure
It is recommended that GSWA try to get access to company confidential high-resolution aeromagnetic data
rather than flying new surveys The GSWA might offer to fund flying of new infill areas as a bargaining point
References
The original text of this report by Cowan (1995) and 1500 000 scale maps are filed in the GSWA Library under
S10331
COWAN D 1995 Savory Basin quantitative magnetic interpretation Western Australia Geological Survey S-series
S10331 (unpublished)
VACQUIER V STEENLAND N C HENDERSON R G and ZIETZ I 1951 Interpretation of aeromagnetic
maps The Geological Society of America Memoir 47 151p
WILLIAMS I R 1992 Geology of the Savory Basin Western Australia Western Australia Geological Survey
Bulletin 141 115p
61
Appendix 5
Geochemistry
MKS38 250398
Saturate FractionC12+ GLC
1217
Pr18
Ph
22
31CSR WELL-13 315m Cuttings
Figure 51 Canning Stock Route Well 13 gas chromatograph of extract of auger drill sample
12
17
18
22
31
Pr Ph
LDDH 1 6623m CoreSaturate FractionC12+ GLC
MKS35 240398
Figure 52 Gas chromatograph of extract from core sample at 6623 m LDDH1
62
Table 51 Canning Stock Route Well 13 auger drill samples
GSWA sample Drill depth (m)(a) Comments
135601 150 At watertable 135602 203 (all samples consist 135603 310 of sand mud and water) 135604 315 At total depth
NOTE (a) Datum for drill depth is the top of sediment fill in the well which is 155 m below ground level (ie the total depth of 315 m is 47 m below ground level)
Table 52 Canning Stock Route Well 13 gas chromatography data for 315 m depth sediment sample
Parameter Value
Weight of rock extracted (grams) 945 Total extract (ppm) 519 n-Alkane distribution n-C12 07 n-C13 23 n-C14 26 n-C15 22 n-C16 19 n-C17 14 i-C19 23 n-C18 14 i-C20 08 n-C19 11 n-C20 16 n-C21 25 n-C22 29 n-C23 70 n-C24 42 n-C25 95 n-C26 43 n-C27 83 n-C28 38 n-C29 87 n-C30 31 n-C31 273 Alkane compositional data Pristane phytane ratio 279 Pristane n-C17 ratio 161 Phytane n-C18 ratio 059 CPI (1)(a) 284 CPI (2) 209 (C21 + C22) (C28 + C29) 043
NOTE (a) CPI= Carbon preference index
63
Table 53 LDDH1 extract liquid chromatography data for 6623 m concentration
Rock extracted Total extract (grams) (ppm)
702 313
NOTE ppm= parts per million
Table 54 LDDH1 saturate gas chromatography data of core for 6623 m alkane composition
Pristane Pristane Phytane (a) CPI (1) CPI (2) (C21+C22) Phytane n-C17 n-C18 (C28+C29)
103 026 024 103 102 325
NOTE (a)CPI = carbon preference index
Table 55 LDDH1 saturate gas chromatography data of core for 6623 m n-alkane distributions
Parameter Value
n-C12 17 n-C13 38 n-C14 55 n-C15 60 n-C16 65 n-C17 74 i-C19 19 n-C18 78 i-C20 19 n-C19 80 n-C20 79 n-C21 71 n-C22 64 n-C23 57 n-C25 43 n-C24 38 n-C27 31 n-C28 23 n-C29 19 n-C30 12 n-C31 10
64
Appendix 6
Table 61 Summary of data from Trainor waterbores (TWB) and Bullen waterbores (BWB)
Well AMG Elevation TD Status(b) Completion details Water Salinity Water level Flow rate Depth to consolidated AGD84 GL (m) (m) struck mgl(c) (m) (LHr) lithology aquifer(e) Z51(a) Interval (m) (100 mm PVC) (m) (mgl)(d)
TWB 1 473660E 453 122 comp 0ndash75 plain 63 7 300 24 2 880 12 m 7287404N 75ndash93 slotted (9 260) McFadden Fm 93ndash99 plain TWB 2 472 977E 475 23 abd nil 15 m 7285877N Skates Hills Fm dry TWB 3 473259E 475 50 abd nil 7 m 7285849N Skates Hills Fm dry TWB 4 463225 E 445 50 comp 0ndash22 plain 35 7 200 55 3 600 0 m 7286143N 22ndash34 slotted (8 140) Tertiary sand and gravel 23ndash60 plain TWB 5 463095E 445 31 comp 0ndash19 plain 13 26 000 655 3 600 Tertiary sand and gravel 7277721N 19ndash25 slotted (36 700) 25ndash31 plain TWB 6 457013E 455 50 comp 0ndash42 plain 38 920 119 600 0 m 7274352N 42ndash48 slotted (1 030) Cornelia Fm ss TWB 7 453739E 475 26 susp 0ndash2 plain 11 9 300 48 4 500 0 m 7263891N (10 500) Tertiary sand TWB 8 433893E 535 60 susp 0ndash2 plain 47 8 500 gt46 1 200 0 m 7245991N (10 900) Tertiary sand and Brassey Range Fm ss TWB 9 437219E 505 51 comp 0ndash47 plain 45 1 000 58 600 1 m 7235905N 47ndash51 slotted (990) Brassey Range Fm ss TWB 10 434927E 495 32 susp 0ndash2 plain 235 450 120 0 m 7225875N (500) Dolerite
65
BWB 1 287337E 580 122 abd Nil 1 m 7245861N Jilyili Fm dry BWB 2 288346E 545 50 comp 0ndash26 plain 15 630 3 29 000 0 m 7240423N 26ndash38 slotted (730) Tertiary sand and gravel 38ndash50 plain BWB 3 305637E 545 50 abd 19 8 800 43 7 200 0 m 7240423N (10 550) Tertiary ss BWB 4 320167E 515 445 comp 0ndash20 plain 9 980 445 24 000 0 m 7248097N 20ndash32 slotted (1 190) Tertiary ss 32ndash44 plain BWB 5 353393E 545 20 susp 0ndash2 plain 45 (970) 1 m 7238934N Basalt
NOTES (a) GPS accuracy ~ 150 m (b) Comp = completed abd = abandoned susp = suspended (c) Salinity from conductivity (d) Analysis total dissolved solids (e) Fm = Formation ss = sandstone
1
A review of data pertaining to the hydrocarbon prospectivity of the Savory Sub-basin Officer Basin
Western Australia
by
M K Stevens and G M Carlsen
Abstract
The Savory Sub-basin of the Officer Basin in central Western Australia is part of a large Neoproterozoic episutural basin and is a frontier for hydrocarbon exploration It contains up to 8 km of clastic carbonate and rare evaporite sedimentary rocks with minor volcanic dykes sills and flows No petroleum exploration activity had been undertaken in this sub-basin prior to 1995 and hydrocarbon prospectivity is assessed from mineral and recent petroleum exploration drilling No seismic data have been acquired An interpretation of available data suggests that source-rock quality is the major exploration risk but that further investigation of the sub-basin is warranted
Minor oil shows (fluorescence with solvent cut) recorded in Spearhole Formation sandstones in the northwest of the sub-basin suggest oil has been generated and migrated into potential reservoirs in the sub-basin
Each of the five depositional sequences recognized in the sub-basin contain potential reservoir rocks which are seen in outcrop as friable sandstones The Durba Sandstone is interpreted as the best-quality reservoir Indications of evaporitic environments from the Mundadjini Skates Hills and Boondawari Formations suggest that seals may be provided by evaporites and mudstones Neoproterozoic to Cambrian rocks may provide structural closures including both fold and fault traps for migrating hydrocarbons Salt diapirs are interpreted from the gravity data A large semi-detailed gravity survey in the eastern part of the sub-basin revealed major folds faults and halokinetic structures
Potential source rocks include marine mudstones of the Skates Hills and Mundadjini Formations which are associated with stromatolitic dolomites and evaporites Rare outcrops of black mudstones from other units such as the Boondawari Formation also suggest source potential
The Geological Survey of Western Australia has drilled one stratigraphic hole (Trainor 1) in the sub-basin to assess the source potential of Neoproterozoic sedimentary rocks Five of the six samples analysed for Total Organic Carbon in the Cornelia Formation from this well exceeded 05 but have a high level of maturation with at best dry gas-generating potential The age of the Cornelia Formation is uncertain but at least part of it is interpreted to be Neoproterozoic and hence part of the Savory succession
Maturity data which are very sparse due to limited drilling are inferred from the Thermal Alteration Index of organic matter to be at about the base of the oil window and the top of the gas window in two
2
waterbores in the southeast of the sub-basin and a mineral drillhole in the north of the region Rock cuttings from a waterbore in the southwest of the sub-basin are overmature for hydrocarbon generation but this bore intersected mafic intrusives and hence may not be representative of maturity for the region
KEYWORDS hydrocarbon prospectivity oil shows Neoproterozoic Savory Sub-basin Officer Basin source rocks diamond drilling
Introduction
Recognition in the late 1980s of a thick sequence of generally weakly deformed Neoproterozoic
sedimentary rocks of relatively low thermal maturity previously included within the
Mesoproterozoic Bangemall Basin (defined as the Savory Basin by Williams 1992) revealed a
hydrocarbon exploration frontier The Savory Sub-basin (Fig 1) now recognized as part of the
Officer Basin is located west of outcrops of Phanerozoic cover rocks of that larger basin The
Officer Basin a large episutural basin which contains clastic carbonate and minor evaporite and
volcanic rocks is considered to be part of the Neoproterozoic Centralian Superbasin (Walter and
Gorter 1994) The age of the Officer Basin successions is not well constrained but in the Savory
Sub-basin it is largely Neoproterozoic with possible Palaeozoic strata present in parts
The boundaries defined by Williams (1992) for the sub-basin have been largely used in this
record but data from sedimentary rocks previously assigned to older basins that are now
recognised or inferred to be of early Neoproterozoic age (Supersequence 1) have been used to
assess the hydrocarbon potential of the northwestern part of the Officer Basin
The southern part of the sub-basin unconformably overlies the Mesoproterozoic Bangemall Basin
The western boundary of the sub-basin is faulted against the Bangemall Basin The eastern
boundary of the Savory Basin as defined by Williams (1992) was placed along the western edge
of Phanerozoic outcrops of the Officer Basin at approximately 123degE longitude Recent studies
(Perincek 1996ab) however have indicated there is little difference in the Neoproterozoic
geology of the two regions The northeastern boundary of the sub-basin was defined as a reverse-
and thrust-faulted contact with the Yeneena and Karara Basins of the Paterson Orogen (Williams
1992) However Bagas et al (1995) subdivided strata from the Yeneena Basin into three new
groups the Throssell Lamil and Tarcunyah Groups The older and more deformed Throssell and
Lamil Groups remain part of the Yeneena Basin and the Paterson Orogen The younger and less-
deformed sedimentary rocks of the Yeneena and Karara Basins were considered to be of
Supersequence 1 age and were reassigned to the Tarcunyah Group The Tarcunyah Group was
considered to be coeval with the older strata of the Savory Sub-basin The Tarcunyah Group
Savory Sub-basin and Officer Basin were grouped into a single tectonic unit which was informally
referred to as the greater Officer Basin (Bagas et al 1995)
3
50 km
120deg 121deg30 123deg
25deg
24deg
23deg
22deg
Blake Fault andFold Belt
Wells Foreland S
ub-basin
TrainorPlatform
MKS32200498
HamersleyBasin
PilbaraCraton
YeneenaBasin
YeneenaBasin
YeneenaBasin
CanningBasin
Sylvania Inlier
BangemallBasin
Bangemall Basin
YilgarnCraton
YilgarnCraton
GlengarryBasin
EaraheedyBasin
Ward Inlier
OldhamInlier
KararaBasin
GibsonSub-basin
(Officer Basin)
WestwoodShelf
(Officer Basin)
KingstonShelf
(Officer Basin)
Rudall Complex
Trainor Platform
(Kahrban Subgroup)
Greater Officer Basin
Savory Sub-basin
Surface anticlinesMAP
AREAPerth
Figure 1 Structural subdivisions of the Savory Sub-basin and surface anticlines
4
During 1994 in consultation with the Petroleum Industry the Department of Minerals and
Energy received State Government funding for a Petroleum Exploration Initiative to be
undertaken by the Geological Survey of Western Australia (GSWA) with a view to identifying
prospective onshore areas for oil and gas thus increasing the level of onshore exploration in
Western Australia This initiative was originally funded for the first three years of a five-year work
program Two teams of specialists were formed to investigate the prospectivity of both the western
margin and interior onshore sedimentary basins
The Petroleum Exploration Initiative teams seek to enhance the prospectivity of onshore
basins by reducing through focused investigations the risks perceived by industry to be factors
limiting exploration activity Comprehensive petroleum system reports of the onshore Western
Australian basins are to be completed as a result of the projects undertaken during the five-year
Initiative The objective of the Initiative will be achieved through both the analysis of open-file
exploration data and the acquisition of new data New data will include but not be limited to
geophysical surveys and stratigraphic drilling Project results are to be reported to the industry
through GSWA publications external publications conference reports and oral presentations
This Record is the third in a series of comprehensive reviews by the GSWA of the
hydrocarbon prospectivity of some of Western Australiarsquos interior onshore sedimentary basins
The first Record of this series covered the Canning Basin (Apak and Carlsen 1997) The second
Record reviewed the Western Australian Officer Basin (Perincek 1998) but excluded the Savory
Sub-basin
This study assesses the potential for hydrocarbon exploration within the Savory Sub-basin
based on available geological and geophysical data and defines the scope for future studies
Publications relevant to this investigation but which are not specifically referred to are listed in
Appendix 1
Access and climate
The Savory Sub-basin lies east and southeast of the mining town of Newman in the Pilbara region
(Fig 2) The area is largely uninhabited the only settlement being an outcamp at Poondawari on
the GUNANYA 1250 000 map sheet The outcamp is linked by a graded track to the Jigalong
Community 90 km to the west just outside the northwest margin of the sub-basin A few pastoral
leases lie along the margins of the sub-basin but the majority of the region is Vacant Crown Land
Capitalized names refer to standard map sheets
5
Sealed road
Gravel road
Track
Town
Homestead
Locality
STANLEYSavory Sub-basin boundary 1250 000 map sheet
CornerTrack
Talawana - Windy
Route
Watch Point
NEWMAN
JigalongCommunity
RobertsonRange (abd)
Wokalba
Poondawari
Balfour Downs
Billinnooka
Weelarrana
Beyondie(abd)
Kumarina
Marymia
Glen-ayle
White Lake
Hanging RockBoorabee Hill
WellsRa
EmuRa
Robertson
Ra McFadden R
a
DiebillHills
DurbaHills
Calvert Ra
WardHills
Cornelia Ra
KellyRaBlakeHills
HillsDean
ROBERTSON GUNANYA
TRAINORBULLEN
BALFOUR DOWNS RUDALL
NABBERU STANLEY HERBERT
50 km
Woora Woora Hills
120deg 121deg30 123deg
25deg
24deg
23deg
22deg
Goldfieldsnatural gaspipeline
GR
EA
TN
OR
TH
ER
NH
IGH
WA
Y
Mar
ble
Bar
Nul
lagi
ne-
Rd
MADLEY
Can
ning
Stoc
k
MKS31120598
Goldfields natural gas pipeline
Figure 2 Localities and access routes of the Savory Sub-basin
6
The sealed Great Northern Highway lies west of the Savory Sub-basin and links Meekatharra
to Newman The TalawanandashWindy Corner graded track crosses the northern part of the sub-basin
and graded pastoral station tracks on Balfour Downs Weelarrana Kumarina Marymia and Glen-
Ayle give access to the western and southern margins The Canning Stock Route traverses the sub-
basin from north to south and is a well travelled four-wheel-drive track allowing access to the
eastern half of the sub-basin Additional minor tracks also provide access to other parts of the area
(Williams 1992) Recently flown monochrome aerial photography at 150 000 and Landsat TM
imagery covering the sub-basin is available from the Department of Land Administration
Cross-country access is similar to that in the Canning Basin with the average height of sand
dunes being lower in the Savory Sub-basin Potable water has been found in water bores in the
south of the sub-basin and is inferred to be present throughout the region Fuel and supplies are
available at Wiluna Meekatharra and Newman A good working relationship with the Western
Desert Community who hold native title claims over most of the sub-basin has been established
by GSWA
There are no meteorological stations within the Savory Sub-basin but estimates based on data
from nearby Bureau of Meteorology Stations indicate that the area is arid and has its maximum
rainfall in summer from monsoonal rains The sub-basin has reasonable access and a tolerable
working climate for all exploration activities Meteorological data for the town of Wiluna which
lies about 180 km to the south of the sub-basin are included as Appendix 2
Regional geology
Stratigraphy
Thirteen formations were recognized by Williams (1992) in the Savory Sub-basin and these are
summarized in Table 1 Although unconformities were recognized between some of the
formations and they reflect a wide range of depositional environments provenance and climatic
conditions these formations were defined by Williams (1992) as constituting the Savory Group
Five depositional sequences that are generally unconformity-bounded were recognized by
Williams (1992) (Fig 3) The correlation of significant formations within the sub-basin with other
parts of the Centralian Superbasin is shown in Figure 4 with the four Neoproterozoic
Supersequences having been defined by Walter et al (1995)
7
Durba Ss
McFadden
Woora Woora400
Tchukardine700
Skates Hills
Mundadjini1800
B
Coondra
(B)
Watch Point
Spearhole1100Jilyili
1000(A)
Glass Spring1600(A)
Brassey Range1700(A)
Abs
ent
Absent Absent
Absent
Absent
Absent
A
B
C
D
E
1A
1B
3
4A
4B
1000
2000
3000
4000
5000
6000
Max
imum
thic
knes
s
Sup
erse
quen
ce
AG
EN
EO
PR
OT
ER
OZ
OIC
NE
OP
RO
TE
RO
ZO
ICT
O
CA
MB
RIA
NM
AR
I-N
OA
N
NW SE
Savory Sub-basin Stratigraphy
MKS30 120598
Fault boundary
Unconformity
Disconformity
Conglomerate
Sandstone Mudstone
Siltstone
Evaporite
Dolomite
Boondawari800 Boondawari
Supersequence 2 is not represented in the Savory Sub-basin Total thicknesses are estimated from air photo interpretation Thicknesses of recessive units are unknown
Diamictite
Dep
ositi
onal
seq
uenc
e
Figure 3 Formations lithology and depositional sequences AndashE of the Savory Sub-basin
8
Table 1 Summary of formations in the Savory Sub-basin
Formation Super Depo Lithology Thickness Depositional Savoy Comments Seq(a) Seq(b) (m) environment Group(c)
Durba Sandstone 4 E Quartz sandstone with minor 100 Fluvial lacustrine Y Excellent reservoir basal conglomerate lenses Woora Woora 4 D Medium-grained ferruginous 400 Shallow marine deltaic Y Formation sandstone lithic sandstone quartz wacke siltstone McFadden 4 D Laminated fine- to coarse-grained 1 500 Shallow marine deltaic Y Possible reservoir Formation quartz sandstone feldspathic sandstone quartz wacke minor conglomerate siltstone Tchukardine 4 D Medium- to coarse-grained sandstone 700 Shallow marine Y Formation lithic sandstone quartz wacke conglomerate lenses siltstone minor shale Boondawari 3 C Glacigene diamictite sandstone siltstone Formation shale conglomerate minor dolomite (some stromatolitic and oolitic) rhythmite 800 Glacial shallow marine Y Possible source rock Skates Hills 1 B Thin-bedded dolomite (some stromatolitic) 200 Shallow marine sabkha Y Possible source rock Formation chert evaporites fine- to medium-grained sandstone siltstone shale patchy basal conglomerate Mundadjini 1 B Fine- to coarse-grained sandstone 1 800 Deltaic sabkha Y Possible source rock Formation conglomerate siltstone minor shale shallow marine mudstone dolomite (some stromatolitic) and evaporites Coondra 1 B Coarse- to medium-grained sandstone 1 000 Fan delta Y Possible reservoir Formation poorly sorted conglomerate pebbly sandstone Spearhole 1 B Coarse- to medium-grained sandstone 1 100 Braided fluvial deltaic Y Possible reservoir Formation pebbly sandstone siltstone and oil shows in conglomerate lenses Mundadjini 1 Boondawari 1
9
Watch Point 1 B Shale siltstone fine- to medium-grained 400 Shallow marine deltaic Y Formation sandstone glauconitic sandstone Jilyili Formation 1 A Fine-grained sandstone siltstone minor shale mudstone conglomerate lenses 1 000 Deltaic Y Brassey Range 1 A Fine- to medium-grained sandstone 1 700 Fluvial deltaic Y Formation siltstone shale minor mudstone Glass Spring 1 A Medium- to coarse-grained sandstone 1 600 Shallow marine fluvial Y Formation minor conglomerate and siltstone Tarcunyah Group 1 AampB Quartz sandstone feldspathic sandstone Shallow marine sabkha N Bitumen in LDDH1 quartz wacke shale siltstone fluvial lacustrine conglomerate evaporites dolomite Cornelia 1 A Sandstone siltstone shale mudstone Shallow marine N Overmature source rocks Formation minor glauconitic sandstone deep marine in Trainor 1 Kahrban 1 A Sandstone siltstone shale 1 700 Shallow marine deltaic N Subgroup
NOTES (a) Supersequences of Walter et al (1995) (b) Depositional sequences of Williams (1992) (c) Y= assigned to Savory Group in Williams (1992) N= previously considered to be older than the Savory Group but now included in the greater Officer Basin
10
SAVORY SUB-BASIN GIBSON SUB-BASINCENTRAL OFFICERBASIN
AMADEUS BASIN
PETERMANN RANGES OROGENY
NE
OP
RO
TE
RO
ZO
IC
ST
UR
TIA
NM
AR
INO
AN
ED
IAC
AR
IAN
CAMBRIANTO
NEOPRO-TEROZOIC
AG
E (
Ma)
SOUTHS RANGE MOVEMENT
AREYONGA MOVEMENT
Steptoe
MILES OROGENY
Mission Group
Cassidy Group
Rudall Complex
Bangemall Group
unnamed
Tar
cuny
ah G
roup
4
3
2
1
MKS12a 180598
500
550
600
650
700
750
800
850
900
SU
PE
R
SE
QU
EN
CE
unnamed
Tchukardine Fm
McFadden Fm
ArumberaSst
Julie Fm
Pertatataka Fm
Olympic FmPioneer Sst
Boondawari Fm
Turkey Hill FmLupton Fm
Kanpa Fm
Neale FmBabbagoola
FmHussar
Fm
Browne Fm
Woolnough Fm
Madley Fm
Bitt
er S
prin
gs F
m
LovesCreek M
Gillen M
Heavitree Fm
Arunta Complex
Throssell Group
TownsendQuartzite
Earaheedy Group
olderCornelia Fm
Jilyili Fm
SpearholeFm
MundadjiniFm
Skates Hills Fm
Lefroy Fm
Areyonga Fm
Aralka Fm
ME
SO
-P
RO
TE
RO
ZO
IC
Waters Fm
youngerCornelia Fm
Brassey RangeFormationKahrban
Subgroup
GlassSpring
Fm
Durba Sst
LP1ALP1B EVENT
Figure 4 Correlation of Savory Sub-basin formations with the western Officer and Amadeus Basins Fm = Formation Sst = Sandstone M = Member
11
The depositional sequences recognized in the sub-basin are an order of magnitude thicker than
those described from Phanerozoic passive-margin settings (Payton 1977 Posamentier et al 1988)
and are broadly comparable in scale to the second-order cycles of Vail et al (1977) and to the
megasequences of Hubbard et al (1985) The main subsurface data available to reveal the
unweathered nature of these rocks are Trainor-1 and the three-well diamond coring program in
Petroleum Permit EP 380 (Akubra 1 Boondawari 1 Mundadjini 1) completed in late 1997 in the
central west of the sub-basin (Figs 5 and 6)
The ages of all formations in the Savory Sub-basin are poorly constrained The only fossils
known are stromatolites and palynomorphs (acid-insoluble microfossils) Palynology from
available wells is summarized in Appendix 3 from Grey and Stevens (1997) and Grey and Cotter
(1996) and correlations using stromatolite biostratigraphy (Stevens and Grey 1997 Grey 1995f
Walter et al 1994 1995) are consistent with a Neoproterozoic age for the formations for which
data are available
A dolerite within the Boondawari Formation gave a poorly constrained RbndashSr age of about
640 Ma (Williams 1992) SHRIMP UndashPb dating of sedimentary zircons from the McFadden and
Cornelia Formations in stratigraphic drillhole Trainor 1 are discussed in Stevens and Adamides (in
prep) and Nelson (1997) The youngest ages from these analyses indicate that the maximum age
of the Cornelia Formation is Early Cambrian or Sturtian but these ages are inconsistent with
previous tectonic interpretations (Williams 1992) and current stratigraphic correlations which
suggest the Cornelia Formation is of Supersequence 1 age or older (Fig 4)
Depositional Sequence A Supersequence 1
Depositional Sequence A includes the Glass Spring Jilyili and Brassey Range Formations (Fig
3) All of these units are predominantly quartzose sandstones some of which are friable and have
significant visible porosity in outcrop Conglomerates are present in the Glass Spring and Jilyili
Formations
Depositional Sequence B Supersequence 1
Depositional Sequence B consists of the Watch Point Coondra Mundadjini Spearhole and
Skates Hills Formations (Fig 3) All of these formations contain beds of quartzose sandstone and
some also contain conglomerates The porosity of dolomites in the Skates Hills Formation appears
poor in surface exposures but its subsurface characteristics are unknown
12
50 km
120deg 121deg30 123deg
25deg
24deg
23deg
22deg
Greater Officer Basin
PNCEXP CA11PNCEXP CA12
PNCEXP CA13PNCEXP CA19
PNCEXP CA05
PNCEXP CA09
BD134589
GSWA Trainor 1 and TWB123
Fortescue River 1A
Mundadjini 1
Akubra 1Boondawari 1
TWB4TWB5
TWB6
TWB7
TWB8
TWB9
TWB10
BWB1
BWB2 BWB3
BWB4
BWB5
OD23
Mineral exploration drillhole
Stratigraphic drillhole
Waterbores and wells(TWB and BWB serieswaterbores identified)
MKS33270398
LDDH 1
Savory Sub-basin
Canning SR Well 13
EP380
Petroleum Exploration permit
Petroleum exploration well
Figure 5 Locations of petroleum exploration wells mineral exploration and stratigraphic drillholes water bores and wells and petroleum exploration permit EP380 in the Savory Sub-basin
13
TD=600m
TD=1367m
TD=701m
TD=709m
TD=50m
SS
1S
S1
SS1
SS
1S
S1
SS
1
SS
1
SS1
SS4 SS1
Pha
nero
zoic
or
SS
2
Cz
CzCz
Karst Bitumen
SS1
TD=181m
Mundadjini 1 Akubra 1 Boondawari 1 LDDH 1 Trainor 1 TWB 6
Munda-djini Fm
Spear-hole Fm
Munda-djini Fm
Munda-djini Fm
Spear-hole Fm
Spear-hole Fm
Waters Fm
McFadden Fm
Cornelia Fm
Cornelia Fm
Cornelia Fm
511 plusmn 13Maor 696 plusmn 20Ma(maximum)
779 plusmn 10Ma(maximum)
Mundadjini 1
Akubra 1 Boondawari 1
LDDH 1
Trainor 1TWB 6100 km
N
LOCATION
NW SE
Sea level
0m AHD
Dolerite basalt
Conglomerate
Sandstone
Mudstone
Dolomite
Limestone
Evaporite
TOC gt08
Permeability gt100md
Oil fluorescence
Sedimentary zircon U-Pb age
Identifiable polymorphs
Cainozoic
Supersequence 1 age
Unconformity
Formation contact
Cz
SS1
r
r
0
100
200
metres
VerticalScale
MKS36 120598
LEGEND
Figure 6 Geological cross section through significant drillholes in the Savory Sub-basin
14
Depositional Sequence C Supersequence 3
Depositional Sequence C consists of the Boondawari Formation (Fig 3) and although it contains
sandstone conglomerate and dolomite the sandstones contain significant amounts of feldspar and
clay and hence are likely to be poorer reservoirs than older sandstones
Depositional Sequence D Supersequence 4
Depositional Sequence D includes the McFadden Tchukardine and Woora Woora Formations
(Fig 3) The McFadden Formation is poorly sorted and sandstones contain significant amounts of
feldspathic clasts in the north of the basin but are significantly coarser and cleaner in the northeast
of the sub-basin (Williams 1992)
Sandstones of the Tchukardine and Woora Woora Formations are generally cleaner than those
of the McFadden Formation and are expected to have fair to good porosity although the
Tchukardine Formation has a higher clay content in parts
Depositional Sequence E Supersequence 4
Depositional Sequence E consists of the Durba Sandstone (Fig 3) a coarse sandstone with minor
conglomerate which has good to excellent visible porosity in surface exposures
Other depositional sequences and regional correlations
Sedimentary rocks which were not included in the Savory Group by Williams (1992) but which
are likely to be of Neoproterozoic age and hence part of the greater Officer Basin include the
Tarcunyah Group the Cornelia Formation and the Kahrban Subgroup
As discussed in the Introduction all of the strata in the Karara Basin and the younger strata
of the Yeneena Basin were redefined to form the Tarcunyah Group of the greater Officer Basin
(Bagas et al 1995) (Fig 7) In outcrop the Tarcunyah Group consists predominantly of quartzose
feldspathic and arkosic sandstone shale which is carbonaceous in parts and carbonate which
includes stromatolitic dolomite Mineral hole LDDH1 drilled on GUNANYA intersected the
15
120598
122deg
123deg
21deg
22deg
23deg
24deg
23deg
22deg
21deg
122deg
123deg
Fault
Thrust
Reverse thrust
CANNINGBASIN
OFFICERBASIN
GROUP
PILBARACRATON
TARCUNYAH
SAVORY GROUP
BANGEMALL
GROUP
THROSSELL
GROUP
LAMIL
GROUP
ConnaughtonTerrane
TerraneTalbot
complexTabletop granitic
Tabletop Terrane
Permian
Neoproterozoicgranitoid
50 km
FormationWaltha Woora
McKay Fault
South west Thrust
Vines
Fault
24deg
120deg
YENEENA CANNINGBASIN
ARUNTAINLIERRUDALL
COMPLEX
AMADEUSBASIN
MUSGRAVEBLOCK
OFFICERBASINYILGARN
CRATON
GROUP
GROUP
GROUP
PILBARACRATON
GROUP
EARAHEEDY
GLENGARRY
BANGEMALL
WYLOO GROUP
SAVORY
WA
CARNARVONBASIN
GASCOYNECOMPLEX
GROUPTARCUNYAH
400 kmGROUP
SA
N
T
CamelndashTabletopfault zone
KAHRBANSUBGROUP
CORNELIAFORMATION
MKS37
Figure 7 Regional geological setting of the Savory Group and western Officer Basin The dashed line on the inset map marks the interpreted margin of the greater Officer Basin
16
Tarcunyah Group and consists predominantly of mudstone with minor sandstone limestone
dolomite and anhydrite (Fig 6)
The age of the Tarcunyah Group is uncertain although limited palynological and stromatolite
evidence suggests that it is probably coeval with Supersequence 1 of the Centralian Superbasin
Drillhole LDDH1 contains palynomorphs equivalent to assemblages in the Browne and Bitter
Springs Formations of the Officer and Amadeus Basins respectively and from the Cornelia
Formation in TWB 6 (Grey and Stevens 1997) (Figs 4 and 6) Stromatolite specimens tentatively
assigned to Acaciella australica (Howchin 1914) Walter 1972 occur in the lower Tarcunyah
Group (Bagas et al 1995) The stromatolite Baicalia burra Preiss 1972 and a conical
stromatolite were reported from the upper part of the Tarcunyah Group (Stevens and Grey 1997)
The recognition of two stromatolite assemblages interpreted to have age significance in
Supersequence 1 sedimentary rocks of the Centralian Superbasin has permitted biostratigraphic
correlations between outcrop and well data The Acaciella australica assemblage appears to be
slightly older than 800 Ma and is restricted to the middle part of Supersequence 1 The Baicalia
burra assemblage is considered to be slightly younger than 800 Ma and occurs in the upper part
of Supersequence 1 (Grey 1996b Stevens and Grey 1997) The older A australica assemblage
is recognized in the Skates Hills Formation in the Savory Sub-basin and the stromatolite A
australica itself has been tentatively identified in the lower Tarcunyah Group The occurrence of
the A australica assemblage in the Woolnough Madley and Browne Formations of the Officer
Basin and in the Loves Creek Member of the Bitter Springs Formation of the Amadeus Basin
allows correlations throughout the Centralian Superbasin (Fig 4)
The younger B burra assemblage has not been recognized in sedimentary rocks of the
Savory Group as defined by Williams (1992) but it occurs in the upper parts of the Tarcunyah
Group and allows correlation of this group with outcrops of the Neale Formation and with the
Kanpa Formation in petroleum exploration well Hussar 1 both located in the central Officer Basin
of Western Australia (Fig 4) (Grey 1996b Stevens and Grey 1997) The occurrence of the B
burra assemblage in these units permits their correlation with the Burra Group in the Adelaide
Geosyncline of South Australia (K Grey unpublished data)
The Cornelia Formation and Kahrban Subgroup outcrop in the southeast of the sub-basin and
were considered by Williams (1992) to be part of the Mesoproterozoic Bangemall Basin Limited
evidence suggests that all or parts of these two units are of Neoproterozoic age The Ward and
Oldham Inliers consist of outcrops of the Cornelia Formation Waterbore TWB 6 which was
drilled on TRAINOR in the Cornelia Formation contains palynomorphs consistent with a
Supersequence 1 age (Grey and Stevens 1997) (Figs 5 and 6) In outcrop the Cornelia Formation
17
consists predominantly of sandstone and quartzite with lesser siltstone shale mudstone and chert
In Trainor 1 this formation consists predominantly of indurated mudstone with minor sandstone
chert and dolomite A major erosional unconformity separates the Cornelia Formation from
overlying formations and parts of the Cornelia Formation have been folded with dips exceeding
70deg In contrast the majority of the Savory Sub-basin sedimentary rocks have dips of less than 30deg
except where they are adjacent to faults The Cornelia Formation apparently consists of an older
unit of steeply dipping quartzites cherts and well-indurated mudstones and a younger unit of
shallower dipping sandstones which are sub-friable in parts However caution should be used in
interpreting the age of units based on their structural deformation and additional mapping and age
dating of this formation is required
It is proposed here that the Kahrban Subgroup is likely to be of early Neoproterozoic age and
hence should be considered as part of the greater Officer Basin This proposal is based largely on
the relatively low dip of the strata (generally less than 20deg) and their west-northwest strike which
is parallel with strikes in the overlying Brassey Range Formation of the Savory Group The lower
contact of the Kahrban Subgroup is obscured but is thought to be an unconfirmity on the
Earaheedy Basin on the southeast of STANLEY (Muhling and Brakel 1985)
Structural setting
The Savory Sub-basin forms the most northwesterly sub-basin of the Neoproterozoic to
Phanerozoic Officer Basin The western boundary of the sub-basin with the Mesoproterozoic
Bangemall Basin consists of steep-reverse and strike-slip faults The northeastern boundary of the
Savory Sub-basin was mapped where Supersequence 4 formations of the Savory Group
unconformably overlie sedimentary rocks of the Karara and Yeneena Basins with the two older
units considered to be part of the Paterson Orogen (Williams 1992) This contact was defined as a
series of steeply dipping reverse faults in the northernmost parts of the sub-basin on BALFOUR
DOWNS and RUDALL and was extrapolated as an inferred reverse fault farther along strike to the
southeast on GUNANYA and MADLEY where the contact is obscured by Cainozoic sediments It is
now recognized that all the sedimentary rocks in the Karara Basin and younger sedimentary rocks
of the Yeneena Basin are from the Supersequence 1 Tarcunyah Group and part of the greater
Officer Basin (Bagas et al 1995) The northern boundary of the Tarcunyah Group and the greater
Officer Basin is in thrust-and reverse-faulted contact with the Rudall Complex and other parts of
the Paterson Orogen (Fig 7)
To the south the sub-basin unconformably overlies the Bangemall Basin The eastern
boundary of the sub-basin used in this study is where Permian and younger strata of the Officer
Basin unconformably overlie Neoproterozoic strata although there are no significant structural or
stratigraphic differences between the Neoproterozoic units
18
The sub-basin is subdivided into three principal structural areas (Fig 1) Trainor Platform
Blake Fault and Fold Belt and Wells Foreland Sub-basin (Williams 1992) A major review of
these boundaries is beyond the scope of this report but the processing of regional aeromagnetic
data (Appendix 4) and acquisition of a semi-detailed gravity survey by the GSWA in the east of
the sub-basin has enabled these tectonic units to be reassessed and some modifications are
proposed
The Wells Foreland Sub-basin (originally termed the Wells Foreland Basin in Williams 1992)
and sedimentary rocks of the Tarcunyah Group are both considered to be the northwest
continuation of the Gibson Sub-basin of the Officer Basin Aeromagnetic gravity and outcrop
data suggest that the Blake Fault and Fold Belt is significantly faulted and folded in the west but
is less deformed in the east where the thickest sedimentary section in is located on BULLEN
(Appendix 4) The Trainor Platform is reinterpreted to represent an area of the sub-basin that has
undergone major compression during the Petermann Ranges Orogeny resulting in folding and
faulting with a northwest strike This interpretation contrasts with that proposed by Williams
(1992) who envisaged that only a thin section of the Savory Group was present on the platform
Perincek (1998) has recognized nine periods of tectonic activity in the Officer Basin from the
beginning of the Neoproterozoic to the end of the Cretaceous Three major tectonic episodes are
recognized in the Centralian Superbasin The oldest event is the Areyonga Movement which is
pre-Sturtian and forms the boundary between Supersequences 1 and 2 (Fig 4) The Souths Range
Movement occurred at the end of the Sturtian at the boundary between Supersequences 2 and 3
The youngest major event is the Petermann Ranges Orogeny which occured at the end of the
Marinoan and forms the boundary between Supersequences 3 and 4
One minor and two major tectonic episodes are recognized in the Savory Sub-basin the
LP1ALP1B structural event and the Areyonga Movement and the Petermann Ranges Orogeny
respectively The LP1ALP1B structural event is revealed where the Spearhole Formations rests
disconformably and locally unconformably on the Brassey Range Jilyili and Glass Spring
Formations The Neoproterozoic Areyonga Movement (equivalent to the Blake Movement of
Williams 1992) produced folds and faults with a general northeast strike in the western and
southern parts of the region The Souths Range Movement has not been recognized in the sub-
basin This may be due to the fact that no Sturtian glacial rocks have been identified and hence it
is possible that structures attributed to the Areyonga Movement could be the result of the Souths
Range Movement or a combination of the two movements
The major tectonic event recorded in the sub-basin is the latest Neoproterozoic to Cambrian
Petermann Ranges Orogeny (equivalent to the Paterson Orogeny) which produced large reverse
19
faults thrusts strike-slip faults and folds with a general northwest strike The McFadden
Formation and other Supersequence 4 strata are considered to be at least partially coeval with this
orogeny (Williams 1992) We also interpret the Durba Sandstone as having been deposited during
the later stages of the Petermann Ranges Orogeny as this unit mildly deformed with fold axes
parallel to the strike of other structures attributed to the Petermann Ranges Orogeny
Quantitative aeromagnetic interpretation of the Savory Sub-basin utilizing the 3D Euler
deconvolution method supported by wave-number filtering and image processing has provided
structural trends and depth to magnetic source within the sub-basin (Cowan 1995) Gravity data
are interpreted by Cowan (1995) as changes in both the density of the basement rocks andor
basement topography depending on local conditions Part of Cowanrsquos report is reproduced in
Appendix 4
Exploration history
The only petroleum exploration conducted in the sub-basin has been the recent drilling in the
western part of three diamond drillholes of which two have minor oil shows (Table 2) There has
been some mineral exploration the results of which are stored in the GSWA Western Australian
Mineral Exploration (WAMEX) database system Much of the mineral exploration was in the
southwest and west where the sub-basin is in contact with the Bangemall Basin and along the
northern margin of the sub-basin Many of these mineral exploration programs included
aeromagnetic surveys and surface geochemical sampling (Fig 8)
Hydrocarbon potential
The sub-basin contains a sedimentary succession up to 8 km thick which is generally gently
folded and faulted and apparently unmetamorphosed Limited drilling has shown that thick
mudstones are present in the sub-basin with some mudstones in Trainor 1 having high Total
Organic Carbon (TOC) values Outcrops of sub-friable sandstones in many of the formations
within the sub-basin suggests widespread reservoir potential Mudstone and inferred thick
evaporite sequences are likely to form seals Maturity data suggest that near-surface samples are
approximately at the base of the oil window and top of the gas window in parts of the north and
southeast of the sub-basin However parts of the southwest of the sub-basin and the mudstones in
Trainor 1 have very high levels of maturity Numerous faults and folds have been identified from
surface mapping suggesting good potential for large structural traps Minor oil shows in
20
Table 2 Neoproterozoic formations and hydrocarbon shows in diamond drillholes in the Savory Sub-basin
Drillhole AMG Core TD (m) Approx Formation Depth Formation Depth Formation Depth Shows (AGD84) start (m) GL (m) (m) (m) (m)
LDDH 1 431148E 112 701 350 Tarcunyah 68ndash701 ndash ndash bitumen at 6623 m 7443826N Group Trainor 1 473640E 6 709 455 McFadden 9ndash83 Cornelia Fm 83ndash709 possible bitumen at 4537 m 7287400N Fm Mundadjini 1 319056E 170 600 500 Mundadjini 16ndash361 Spearhole Fm 361ndash600 10 fluorescence at 36102 m 7404844N Fm Boondawari 1 348959E 299 1 367 490 Mundadjini Fm 15ndash312 Spearhole Fm 312ndash1 283 Intrusive 1 283ndash1 367 40 fluorescence at 35364 m 5 7398174N fluorescence at 4963 m Akubra 1 334249E 15 181 530 Mundadjini 15ndash42 Intrusive 42ndash181 None 7401252N Fm
21
50 km
120deg 121deg30 123deg
25deg
24deg
23deg
22deg
Greater Officer Basin
Savory Sub-basin
1
2
3
4
6
8
3 Seismic line (prefixed N83-00)
Aeromagnetic survey
GS
WA
Sav
ory
1995
gra
vity
sur
vey
Gravity survey
MKS34270398
Figure 8 Locations of aeromagnetic and gravity surveys (other than regional BMRAGSO data)
22
sandstones in two petroleum wells in the northwest of the sub-basin and bitumen and oil shows
elsewhere in the region indicate that oil has been generated and migrated through the sub-basin
Source rocks
Source potential is considered to be the major exploration risk in the Savory Sub-basin although
minor oil shows in Mundadjini 1 and Boondawari 1 indicate that at least some oil has been
generated and migrated into potential reservoirs within the sub-basin Sandstone is the
predominant lithology observed in outcrop Outcrops of fine-grained lithologies in the basin are
rare because of intense surface weathering and erosion Only about 8 of the surface area of the
sub-basin is exposed bedrock and recessive lithologies (such as shale evaporite and friable
sandstone) may be present although they rarely outcrop
Outcrops of stromatolitic dolomite with associated cauliflower chert and cubic pseudomorphs
interpreted as being after halite indicate that evaporitic environments are present within the
Mundadjini Skates Hills and Boondawari Formations Evaporitic minerals are also present in
drillhole LDDH1 in the Tarcunyah Group
In 1995 GSWA drilled a continuous-core diamond drillhole (Trainor 1) in the sub-basin on
TRAINOR to a depth of 709 m to test for source rocks thus providing the first such data for the sub-
basin The drillhole intersected flat-lying clastics and carbonates of the McFadden Formation (9ndash
83 m) overlying indurated mudstones of the Cornelia Formation (83ndash709 m total depth) dipping at
about 40deg Of the six samples analysed from the Cornelia Formation in this drillhole the five
located between 375 and 6032 m depth have TOC values exceeding 05 (range 066ndash365)
Rock-Eval pyrolysis of these five samples indicates that they are at best in the dry-gas thermal
stage and as a result of their high level of maturation (Stevens and Adamides in prep) have poor
remaining hydrocarbon-generating potential Although the Cornelia Formation is overmature at
Trainor 1 the high TOC values are encouraging as it is likely that this sequence is less mature
elsewhere in the sub-basin
The Mundadjini Formation contains potential source rocks that comprise marine mudstones
with evaporitic minerals present in parts Thin dark mudstones were intersected in the Mundadjini
Formation in Akubra 1 In Mundadjini 1 and Boondawari 1 however the mudstones appear to be
too oxidized to have source potential
The Boondawari Formation also may be a source rock as it contains black mudstones The
unit is laterally equivalent to the Pertatataka Formation of the Amadeus Basin and the Ungoolya
23
Group of the Officer Basin in South Australia both of which have some source potential
(Summons and Powell 1991 Morton and Drexel 1997) Samples from the Dey Dey Mudstone of
the Ungoolya Group generally have poor TOC values (average 011 range 003ndash081)
moderate hydrogen index (HI) values (100ndash382) and poor to fair genetic potential with a
maximum of 292 kg hydrocarbon per tonne of source rock (Morton and Drexel 1997)
Stromatolitic dolomites and mudstones at the top of the Boondawari Formation and within the
Skates Hills Formation are potential source rocks Stromatolitic dolomite and evaporitic rocks
deposited in a marginal marine to sabkha environment are considered to have good potential to
generate and preserve organic carbon without requiring a deep-water setting (Stevens and Grey
1997) Such conditions are recognized in the Skates Hills Formation and in the upper parts of the
Tarcunyah Group
Maturity
Knowledge of the maturity of sedimentary rocks within the Savory Sub-basin is still limited From
a review of palynological studies Grey and Stevens (1997) report that the thermal maturity
inferred from the Thermal Alteration Index (TAI) of 3+ from Supersequence 1 age palynomorphs
in TWB 6 TWB 9 and LDDH1 is within the hydrocarbon window (Appendix 3) In Phanerozoic
spores and pollen a TAI of 3+ approximately equates to the end of liquid petroleum generation
and the start of dry gas generation and to a vitrinite reflectance of about 13 (Traverse 1988)
However the use of TAI for estimating thermal maturity from Neoproterozoic palynomorphs
requires calibration
In Trainor 1 the Cornelia Formation contains organically rich claystones between 375 and
6032 m depth Based on Rock-Eval maturity data (Stevens and Adamides in prep) and the dark
colour of poorly preserved organic material (Grey 1995de 1996) with TAI 4- to 5 all samples
had a high level of maturation with at best dry-gas generating potential remaining In contrast
drillhole LDDH1 on GUNANYA recorded lower levels of maturity (TAI values of 3+) with two of
sixteen samples from the Tarcunyah Group having greater than 1 TOC (Grey 1995abc Grey
and Cotter 1996) Organic petrology and Rock-Eval maturity data for samples from LDDH1
indicate that the section above 500 m is within the oil-generative window whereas below 500 m
the rocks are within the gas window (Ghori in prep Fig 9 Appendix 5)
Waterbores TWB 1 2 6 and 9 which are located on TRAINOR in the southeast of the sub-
basin all had organic matter with TAI values of 3+ from the McFadden Skates Hills Cornelia
and Brassey Range Formations respectively
24
100
200
300
400
500
600
700
Oil
gene
ratin
g
Gas
gene
ratin
g
Fai
r
Fai
r
Poo
r
Poo
r
Goo
d
Imm
atur
e
Oil
win
dow
Oil
win
dow
Imm
atur
e
01 0110 10 0 150 300 440 480 1
Neo
prot
eroz
oic
TOC S1+S2 mgg Hydrogen Index Tmax degC
Depth(m)
Organicrichness
Generatingpotential
Kerogentype Maturity Maturity
TD=701m
Sandstone
Mudstone
Dolomite
Limestone
Evaporite
Source rock
MKS40 070498
Ro equivalent
Figure 9 Petroleum source potential of rocks in Normandy LDDH1
Small amounts of organic matter associated with basalt and dolerite in cuttings from
waterbore BWB 1 on BULLEN showed high levels of thermal maturity (Grey 1995a Libby 1995)
It is unclear whether all sedimentary rocks on BULLEN are overmature for hydrocarbon generation
or the results from BWB 1 are related to local heating events associated with the volcanic bodies
that are common in the Jilyili Formation
25
Reservoirs
Each of the five depositional sequences of the Savory Group (Table 1) are inferred to contain
significant sandstone reservoirs with the possible exception of depositional sequence C as
discussed above in Stratigraphy The Spearhole Formation was cored in Mundadjini 1 and
Boondawari 1 and visual estimates of porosity vary from generally poor (less than 5) to fair
(approximately 5ndash15) The McFadden Formation in Trainor 1 has porosity values of up to 232
and a maximum permeability of 195 md (Stevens and Adamides in prep) Sandstones from
Neoproterozoic formations form the acquifers in the following waterbores the McFadden
Formation in TWB 1 the Cornelia Formation in TWB 6 and the Brassey Range Formation in
TWB 8 and TWB 9 (Appendix 6 Table 61)
Based on outcrop observations the Durba Sandstone is considered to be the best reservoir of
the Savory Group Similarly some sandstones from the Tarcunyah Group also have good visible
porosity in outcrop
Dolomites occur in several formations in the sub-basin Reservoir potential may exist
particularly where the dolomites are stromatolitic and oolitic However dolomites have not been
drilled in the sub-basin and porosity can only be inferred from the preferential silicification of
some stromatolite bioherms observed in outcrop (Stevens and Grey 1997) Elsewhere in the
Officer Basin porosities of up to10 have been measured in dolomites A limestone breccia
(karst) is described from 663 to 677 m in drillhole LDDH1 (Fig 6 Busbridge 1994)
Seals
Indications of evaporitic environments in the Mundadjini Skates Hills and Boondawari
Formations are described by Williams (1992) In Mundadjini 1 from 287 to 337 m anhydrite and
chert occurs as nodules beds and veins in mudstone of the Mundadjini Formation Evaporitic
minerals (predominantly gypsum) are described in the Tarcunyah Group in LDDH1 The presence
of the Woolnough and Madley salt diapirs in the Officer Basin (approximately 110 km east of the
sub-basin) and halite beds over 25 m thick in the well Hussar 1 (130 km east of the sub-basin)
provide further evidence that evaporite seals may be present in the Savory Sub-basin
Mudstones and shales form only a small proportion of the limited Neoproterozoic outcrop in
the sub-basin but significant thicknesses of mudstone were encountered in the Mundadjini
Formation in Mundadjini 1 and Boondawari 1 the Tarcunyah Group in LDDH1 and in the
26
Cornelia Formation in Trainor 1 These data suggest that mudstones form a significant proportion
of strata in the sub-basin despite their limited outcrop
Traps
Potential structural closures including folds and faults occur at various scales throughout the
Savory Sub-basin However the region has only been mapped at 1250 000 scale and
independently closed structures such as domes have yet to be confirmed The western margin of
the basin contains abundant faults (with a northeast strike) but elsewhere faults are less common
Some anticlines are recognized in outcrop including one with a strike length of up to 45 km
inferred from surface bedding dips in the Mundadjini and Spearhole Formations at approximately
24deg15rsquoS 121deg10rsquoE on BULLEN (Fig 1)
Salt diapirs and other halokinetic structures are recognized in outcrop well and seismic data
in the Officer Basin to the west of the Savory Sub-basin and it is probable that there are
significant thicknesses of evaporitic sedimentary rocks in the sub-basin The gravity field data
suggest there is good potential for salt diapirs and traps related to halokinesis
Although there is potential for stratigraphic traps to be present in the sub-basin insufficient
data are available to assess them
Preservation of hydrocarbons
The range of thermal maturities measured to date and the large periods of time envisaged for
deposition of sediments implies hydrocarbon generation may have occurred a number of times
during the evolution of the Savory Sub-basin Any hydrocarbons that were generated early may
have been trapped in palaeostructures and remigration to younger traps could have taken place
later The Petermann Ranges Orogeny which has been equated with the Paterson Orogeny (Myers
1990) is believed to have occurred in the latest Neoproterozoic to early Cambrian This is the last
major tectonic event recognized in the sub-basin suggesting that it is reasonable to expect that trap
integrity will have been preserved
If the inference of the presence of thick halite beds in the sub-basin is correct the preservation
potential of sub-salt traps should be excellent
27
Reported hydrocarbon shows and oil seep
Amadeus Petroleum recorded minor oil shows in cores from Mundadjini 1 and Boondawari 1 In
Mundadjini 1 at 36102 m (top of the Spearhole Formation) a 3 mm thick zone had 10 moderate
white fluorescence with slow solvent cut This show was in a granular sandstone with visually
estimated porosity of about 10 In Boondawari 1 at 35364 m (within the Spearhole Formation) a
broken surface of sandstone had 40 moderate yellow-white fluorescence with slow solvent cut
Visually estimated porosity is about 5 Because the fluorescing surface was broken during the
drilling process this show could have resulted from contamination A second show occurs in
Boondawari 1 at 4963 m (within the Spearhole Formation) where a 1 cm-thick zone had 5 dull
yellow fluorescence with slow solvent cut in a conglomerate with visually estimated porosity of
about 10 The company intends to further investigate the nature of these occurrences
Minor bitumen is present at 6623 m in drillhole LDDH1 on GUNANYA (Figs 5 and 6) as a
vein in mudstones of the Tarcunyah Group A sample was analysed by gas chromatography
(Ghori in prep) and confirmed that it is natural bitumen (Appendix 5)
Mineral hole OD 23 drilled by Jubilee Gold Mines NL on NABBERU in the Bangemall Basin
immediately to the south of the Savory Sub-basin (Fig 5) encountered bitumen and trace oil in
vugs in dolomite (M Stevens unpublished data) but no further data are available at present
In their popular guide to the Canning Stock Route Gard and Gard (1990 p 218) refer to an
oil seep at Well 13 on TRAINOR (Fig 5) They reported that between 1977 and 1984 lsquonatural oilrsquo
was seen in the well Although the well is now largely filled with sediment four auger drill
samples were collected by the GSWA in 1995 and all four were analysed for oil shows One
sample from 315 m total depth (GSWA sample 135604) yielded just enough extract (519 ppm)
for saturate gas chromatography analysis The gas chromatograph (Appendix 5) shows that the
extract does contain some hydrocarbons probably from recent plant material Because the depth to
the oil was not quoted in Gard and Gard (1990) the hand-augered well may not have been deep
enough to properly test this reported seep
Geological and geophysical databases
Geological and geophysical data available for the Savory Sub-basin are limited The most recently
completed geological maps for the sub-basin were published by the GSWA between 1991 and
1995 (Williams and Tyler 1991 Williams 1992 1995ab)
28
The cores from the five drillholes listed in Table 2 believed to be all of the core available
from the sub-basin are available for inspection at GSWA Mineral exploration reports submitted
to GSWA may be searched using the WAMEX database and open-file reports are available on
microfiche Geophysical data acquired by the mining industry is not required to be filed with
GSWA if acquired over Vacant Crown Land which is the case for much of the sub-basin
Geophysical survey data submitted in mining tenement reports and which extend into Vacant
Crown Land remain confidential to the companies Original regional aeromagnetic and gravity
datasets are available from the Australian Geological Survey Organisation (AGSO)
Data pertinent to oil exploration in the sub-basin such as structural style and salt diapirism
are presented in a review of the hydrocarbon prospectivity of the Officer Basin (Perincek 1998)
Drilling
Significant drillholes in the sub-basin are summarized in Table 2
Petroleum industry data
Amadeus Petroleum drilled three petroleum exploration wells in the central west of the Savory
Sub-basin in late 1997 These wells Mundadjini 1 Boondawari 1 and Akubra 1 were drilled by
continuous diamond coring (Figs 5 and 6) All targeted potential reservoirs within the Spearhole
Formation with the Mundadjini Formation as the proposed seal The wells were located on
structures interpreted from Landsat images and limited geological investigations Both Mundadjini
1 and Boondawari 1 had minor oil shows as discussed above (Reported hydrocarbon shows)
Government data
Stratigraphic drillhole Trainor 1 was drilled by GSWA in 1995 (Stevens and Adamides in prep)
and the main results are discussed above (Source rocks and Maturity)
Mineral industry data
Normandy Exploration drillhole LDDH1 was cored in the Tarcunyah Group to a total depth of
701 m and provided source-rock and maturity data as discussed above
29
Oilmin NL drilled six percussion drillholes (BD 1 3 4 5 8 and 9) through sandstones and
shales in the northern part of the Savory Sub-basin to a maximum depth of 198 m (Fig 5
WAMEX Microfiche File M 26811 I 2610) but only brief geological descriptions are available
Hydrogeological data
Hydrogeological data within the Savory Sub-basin are limited although a long history of water
exploration extends back to the construction of the Canning Stock Route early this century No
detailed geological or wireline logs are available for the older wells along this route A few station
wells have been drilled by various methods on the south and west margins of the basin but data
are unavailable as reports are not required to be filed with the government Depth to watertable
throughout the basin is largely controlled by porosity of the bedrock
The GSWA drilled fifteen waterbores in the winter of 1995 in the southern part of the sub-
basin in preparation for the drilling of Trainor 1 and the proposed Bullen 1 Twelve bores found
water and six of these bores have salinities of less than 1000 mgL (Fig 5 Appendix 6 Table 61)
One waterbore TWB 6 has gamma ray and neutron logs run through PVC casing and these are
available from the GSWA with the digital log data included herein
Seismic data
No geophysical data have been acquired by the petroleum industry in the Savory Sub-basin
Seismic data acquired in the Officer Basin to the east particularly in the Gibson and Yowalga
Sub-basins is pertinent to structural interpretation in the Savory Sub-basin (Perincek 1996a
1998)
Aeromagnetic surveys
Government data
There are over 95 277 line kilometres of aeromagnetic data included in the AGSO dataset There
are three regional aeromagnetic surveys covering the Savory Sub-basin These were flown by the
Bureau of Mineral Resources (BMR now AGSO) in 1984 at a line spacing of 1500 m with 36 740
and 52 587 line kilometres flown and by Aerodata in 1984 at a line spacing of 1000m with 5950
line kilometres flown These data were reprocessed and interpreted for GSWA by Cowan (1995)
An edited copy of this report is included as Appendix 4 and the original report is filed in the
GSWA Library under S-series reports item 10331
30
Mineral industry data
The approximate locations of non-AGSO aeromagnetic surveys are shown in Figure 8 More
detailed information regarding the location of these surveys may be obtained using the GSWA
MAGCAT II database Additional information such as contours of aeromagnetic values may be
obtained by inspecting items on file with the GSWA
Gravity surveys
Government data
The average spacing for gravity data in the Savory Sub-basin is one station per 121 km2 (11 times 11
km grid) These data were principally collected by BMR in the early 1960s There are a few
additional regional gravity traverses across the sub-basin which are also included in the
BMRAGSO dataset These data were reprocessed and interpreted for GSWA (Fig 10) and a
report on this work is also included in Appendix 4
The GSWA completed a large semi-detailed gravity survey in the eastern Savory Sub-basin
utilizing helicopter support and Differential Global Positioning Survey (DGPS) techniques (Fig
8) This gravity survey completed in August 1995 consists of 2300 gravity stations on a 2 times 3 km
grid All stations were acquired by helicopter using Scintrex gravimeters and Ashtek dual
frequency DGPS equipment for determining location This highly efficient system allowed the
acquisition of more than 100 gravity stations per day in remote areas The resolution of this survey
is +30 cm and +05 microms-2 (Daishsat 1995) These data (Fig 11) represent a significant
improvement on the previous regional survey data and are available from GSWA (GSWA
1996ab) The results of the interpretation of these data were presented at the 1997 ASEG
Convention (Carlsen and Shevchenko 1997)
Mineral industry data
Three small gravity surveys were conducted by Oilmin NL (Fig 8) and the relevant WAMEX
reports are M 2681I 2610 I 2435 I 2567 These three surveys are of limited value because height
control was provided by barometers only and the surveys were not tied to the national gravity grid
31
23deg
25deg
120deg 122deg
Trainor 1
SAVORY
SUB-BASIN
MKS54 160498
100 km
1995 SavoryGravity Survey
254
-1056
micromsec2
Figure 10 Regional Bouguer gravity map of the Savory Sub-basin
23deg
24deg
25deg
122deg30 123deg
TRAINOR 1
123deg30
50 km
MKS53 160498
-116
-626
micro msec2
Figure11 Detailed Bouguer gravity map of the
Savory 1995 Gravity Survey from the eastern Savory Sub-basin
32
Government and academic reports
Chronostratigraphy and geochemistry
The understanding of Neoproterozoic organic chemistry palynology and structural evolution is
essential to the interpretation of hydrocarbon prospectivity Pertinent reports are included in the
bibliography (Appendix 1) Unpublished palaeontology reports describe the palynology of wells in
the Savory Sub-basin (Grey 1995andashe 1996a) Grey and Cotter (1996) discussed the potential for
Neoproterozoic palynomorphs to provide a biostratigraphic framework and palaeoenvironmental
interpretation Grey and Stevens (1997) reviewed the results of palynological studies of wells
drilled in the sub-basin and reported that Supersequence 1 palynomorphs are present in TWB 6
TWB 9 and LDDH1 (Appendix 3) Grey (1996b) reported on the use of stromatolites for
correlation in the Neoproterozoic and Stevens and Grey (1997) discussed the application of
stromatolite biostratigraphy in correlating isolated dolomite outcrops in the sub-basin with well
and seismic data in the Officer Basin and Centralian Superbasin
Although geochemical data from the Savory Sub-basin are very limited results mostly
confirm thermal maturities inferred from TAI for LDDH1 and Trainor 1 (Ghori in prep Stevens
and Adamides in prep) Those parts of the Officer Basin in Western Australia which lie to the
east of the Savory Sub-basin are sparsely drilled but Ghori (in prep) reports that most of the
Neoproterozoic succession presently lies within the oil-generative window However his study
has been unable to identify effective source-rock units and the source for oil shows Thin source
rocks are present in the Neoproterozoic in LDDH1 (Fig 9) and in three wells which lie to the east
and southeast of the Savory Sub-basin namely NJD 1 Kanpa 1A and Yowalga 3
Proposed work program
From the above limited information it is concluded that additional research on the hydrocarbon
potential of the sub-basin is justified and proposals are outlined below
bull Additional modelling of gravity and aeromagnetic data from the Savory Sub-basin is required
in light of the results from Trainor 1 and Boondawari 1 Trainor 1 showed that what appeared
to be a structurally simple area based on outcrop aeromagnetic and gravity data was in fact an
area of major structuring Boondawari 1 intersected a dolerite which is in good depth
agreement with aeromagnetic depth to source results showing this technique is useful in
detecting the depth to intrusive bodies
33
bull Additional data from mineral and petroleum exploration bores may become available and
analysis of samples from these wells should be undertaken and interpreted in the context of
their relevance to the Officer Basin
bull Stratigraphic coring in the Blake Fault and Fold Belt and in the Wells Foreland Sub-basin (Fig
1) targeting source rocks is considered essential to the continuing evaluation of the
hydrocarbon prospectivity of the Savory Sub-basin
bull Correlations using at least outcrop well and potential-field data should be prepared to link the
sub-basin with the better known parts of the Officer Basin to the east
bull Remapping is required to clarify boundary positions within the Cornelia Formation this may
resolve some of the current problems of the relationship between this unit and the rest of the
Savory Sub-basin
bull Further work is required to explain the Early Cambrian or Sturtian ages interpreted for the
Cornelia Formation from sedimentary zircon UndashPb dating in drillhole Trainor 1 The
determination of the age of the organically rich but overmature claystones in this well is
critical to assessing the hydrocarbon potential of the region
bull The thin dark mudstones intersected by Akubra 1 in the Mundadjini Formation warrant
geochemical analysis Analyses of the oil shows in Mundadjini 1 and Boondawari 1 are
currently being undertaken by Amadeus Petroleum
bull Geochemical analysis of hydrocarbons in the Bangemall Basin drillhole OD23 has been
performed by Jubilee Gold and the results will be reviewed when they are submitted to
GSWA The possibility of source rocks within the Bangemall Basin charging traps within the
Bangemall Basin and the overlying Savory Sub-basin requires further investigation
Conclusions
The Savory Sub-basin is a frontier region with only three recently drilled petroleum exploration
wells and no seismic data Based on existing geological and geophysical data it is considered too
early to draw conclusions about the hydrocarbon prospectivity of the sub-basin at this stage and
there are several reasons why the area warrants further investigation
34
1 Thick accumulations of sedimentary rocks are present (up to 8 km thickness inferred) which
may contain source reservoir and sealing strata
2 Minor oil shows occur in Mundadjini 1 and Boondawari 1 and bitumen is present in mineral
exploration drillhole LDDH1 suggesting that hydrocarbons have migrated within the
Neoproterozoic sequence of the Savory Sub-basin Oil and bitumen are present in mineral
exploration drillhole OD23 in the Bangemall Basin immediately to the south of the Savory
Sub-basin and it is possible that source rocks from the Bangemall Basin could charge traps in
the overlying Savory Sub-basin
3 The age of sedimentary rocks in the sub-basin is still poorly constrained but some of the
Neoproterozoic sedimentary rocks located on GUNANYA and TRAINOR are within the
hydrocarbon-generation window It is possible that a significant thickness of Phanerozoic
sedimentary rocks may also be present
4 Friable sandstones with visible porosity outcrop extensively suggesting numerous potential
reservoirs
5 Significant but not intense faulting and folding has been mapped implying large structural
traps may be present
6 Evaporitic sedimentary rocks occur in several formations and may provide good source rocks
and excellent seals
35
References
APAK S N and CARLSEN G M 1997 A compilation and review of data pertaining to the
hydrocarbon prospectivity of the Canning Basin Western Australia Geological Survey
Record 199610 103p
BAGAS L GREY K and WILLIAMS I R 1995 Reappraisal of the Paterson Orogen and
Savory Basin Western Australia Geological Survey Annual Review 1994ndash95 p 55ndash63
BUSBRIDGE M 1994 Lake Disappointment Exploration Licence 451064 Third Annual
Report Lake Disappointment Diamond Drill Hole LDDH1 Normandy Exploration Limited
Western Australia Geological Survey M-series Item 7567 A41358 (unpublished)
CARLSEN G M and SHEVCHENKO S I 1997 Petroleum exploration in Proterozoic basins
using potential fields data and stratigraphic coring Australian Society of Exploration
Geophysicists 12th Geophysical Conference Handbook Sydney 1997 Preview no 66 p 83
(abstract only)
COWAN D 1995 Savory Basin quantitative magnetic interpretation Western Australia
Geological Survey S-series S10331 (unpublished)
DAISHSAT PTY LTD 1995 Operational and processing report Savory Basin gravity survey
Western Australia Geological Survey S-series S10332 (unpublished)
GARD E and GARD R 1990 Canning Stock Route a travellerrsquos guide for a journey through
history Perth Western Australia Western Desert Guides 448p
GEOLOGICAL SURVEY OF WESTERN AUSTRALIA 1996a Savory Basin first vertical
derivative of Bouguer gravity image 1250 000 Western Australia Geological Survey
GEOLOGICAL SURVEY OF WESTERN AUSTRALIA 1996b Savory Basin Bouguer gravity
image 1250 000 Western Australia Geological Survey
GHORI K A R in prep Petroleum source rock potential and thermal history Officer Basin
Western Australia Western Australia Geological Survey Record
36
GREY K 1995a Savory Basin drillhole BWB 1 (Bullen waterbore) palynology and thermal
maturation GSWA Palaeontology Report no 199512 (unpublished)
GREY K 1995b Savory Basin drillholes TWB 1 2 6 9 (Trainor waterbores) palynology and
thermal maturation GSWA Palaeontology Report no 199520 (unpublished)
GREY K 1995c Palynology of Normandy-Poseidon Lake Disappointment-1 corehole
Tarcunyah Group Paterson Orogen GSWA Palaeontology Report no 199521 (unpublished)
GREY K 1995d Savory Basin drillhole Trainor 1 (Trainor diamond drilling) palynology and
thermal maturity GSWA Palaeontology Report no 199524 (unpublished)
GREY K 1995e Savory Basin drillhole Trainor 1 (Trainor diamond drilling) Additional
Preparation of two samples GSWA Palaeontology Report no 199528 (unpublished)
GREY K 1995f Neoproterozoic stromatolites from the Skates Hills Formation Savory Basin
Western Australia and a review of the distribution of Acaciella australica Australian Journal
of Earth Sciences v 42 p 123ndash132
GREY K 1996a Savory Basin drillhole Trainor 1 (Trainor diamond drilling) Additional
samples palynology and thermal maturation GSWA Palaeontology Report no 199615
(unpublished)
GREY K 1996b Preliminary stromatolite correlations for the Neoproterozoic of the Officer
Basin and a review of Australia-wide correlations GSWA Palaeontology Report no 199615
(unpublished)
GREY K and COTTER K L 1996 Palynology in the search for Proterozoic hydrocarbons
Western Australia Geological Survey Annual Review for 1995ndash96 p 70ndash80
GREY K and STEVENS M K 1997 Neoproterozoic palynomorphs of the Savory Sub-basin
Western Australia and their relevance to petroleum exploration Western Australia
Geological Survey Annual Review for 1996ndash97 p 49ndash54
HUBBARD R J PAPE J and ROBERTS D G 1985 Depositional sequence mapping as a
technique to establish tectonic and stratigraphic framework and evaluate hydrocarbon
potential on a passive continental margin in Seismic stratigraphy II an integrated approach
37
edited by O R BERG and D G WOOLVERTON American Association of Petroleum
Geologists Memoir 39 p 79ndash91
LIBBY WG 1995 A petrological report on six samples of bore cuttings from the Savory Basin
Western Australia Western Australia Geological Survey S-series S31307 (unpublished)
MORTON JGG and DREXEL JF 1997 The petroleum geology of South Australia Vol 3
Officer Basin South Australia Department of Mines and Energy Resources Report Book
9719
MUHLING P C and BRAKEL A T 1985 Geology of the Bangemall Group mdash the evolution
of an intracratonic Proterozoic basin Western Australia Geological Survey Bulletin 128
219p
MYERS J S 1990 Precambrian tectonic evolution of part of Gondwana southwestern Australia
Geology v18 p 537ndash540
NELSON D R 1997 Compilation of SHRIMP UndashPb zircon data Western Australia Geological
Survey Record 19972 196p
PAYTON C E 1977 Seismic stratigraphy mdash applications to hydrocarbon exploration
American Association of Petroleum Geologists Memoir 26 516p
PERINCEK D 1996a The age of NeoproterozoicndashPalaeozoic sediments within the Officer Basin
of the Centralian Super-basin can be constrained by major sequence-bounding unconformities
APPEA Journal v 36 pt 1 p 350ndash368
PERINCEK D 1996b The stratigraphic and structural development of the Officer Basin
Western Australia a review Western Australia Geological Survey Annual Review 1995ndash
1996 p 135ndash148
PERINCEK D 1998 A compilation and review of data pertaining to the hydrocarbon
prospectivity of the Officer Basin Western Australia Geological Survey Record 19976
POSAMENTIER H W JERSEY M T and VAIL P R 1988 Eustatic controls on clastic
deposition 1 mdash Conceptual framework in Sea-level changes an integrated approach edited by
C K WILGUS B S HASTINGS C G St C KENDALL H W POSAMENTIER
38
C A ROSS and J C VAN WAGONER Society of Economic Paleontologists and
Mineralogists Special Publication no 42
STEVENS M K and ADAMIDES N G in prep GSWA Trainor 1 well completion report
Savory Sub-basin Officer Basin Western Australia with notes on petroleum and mineral
potential Western Australia Geological Survey Record 199612
STEVENS M K and GREY K 1997 Skates Hills Formation and Tarcunyah Group Officer
Basin mdash carbonate cycles stratigraphic position and hydrocarbon prospectivity Western
Australia Geological Survey Annual Review for 1996ndash97 p 55ndash60
SUMMONS RE and POWELL C McA 1991 Petroleum source rocks of the Amadeus Basin
in Geological and geophysical studies in the Amadeus Basin central Australia edited by R J
KORSCH and JM KENNARD Australia BMR Geology and Geophysics Bulletin 236
TRAVERSE A 1988 Palaeopalynology Boston Unwin Hyman 600p
VAIL P R MITCHUM R M Jr TODD R G WIDMIER J M THOMPSON S III
SANGREE J B BUBB J N and HATLELID W G 1977 Seismic stratigraphy and
global changes of sea level in Seismic stratigraphy mdash applications to hydrocarbon
exploration edited by C E PAYTON American Association of Petroleum Geologists
Memoir 26 516p
WALTER M R and GORTER J 1994 The Neoproterozoic Centralian Superbasin in Western
Australia the Savory and Officer Basins in The sedimentary basins of Western Australia
edited by P G PURCELL and R R PURCELL Petroleum Exploration Society of Australia
Symposium Perth WA 1994 Proceedings p851ndash864
WALTER M R GREY K WILLIAMS I R and CALVER C R 1994 Stratigraphy of the
Neoproterozoic to early Palaeozoic Savory Basin and correlation with the Amadeus and
Officer Basins Australian Journal of Earth Sciences v 41 p 533ndash546
WALTER M R VEEVERS J J CALVER C R and GREY K 1995 Neoproterozoic
stratigraphy of the Centralian Superbasin Australia Precambrian Research v 73 p 173ndash195
WILLIAMS I R 1992 Geology of the Savory Basin Western Australia Western Australia
Geological Survey Bulletin 141 115p
39
WILLIAMS I R 1995a Bullen WA (2nd Edition) Western Australia Geological Survey
1250 000 Geological Series Explanatory Notes 23p
WILLIAMS I R 1995b Trainor WA (2nd Edition) Western Australia Geological Survey
1250 000 Geological Series Explanatory Notes 31p
WILLIAMS I R and TYLER I M 1991 Robertson WA (2nd edition) Western Australia
Geological Survey 1250 000 Geological Series Explanatory Notes 36p
40
41
Appendix 1
Bibliography
Reports which are relevant to this investigation but which are not specifically cited are listed
below
BAILLIE P W POWELL C McA LI Z X and RYALL A M 1994 The tectonic
framework of Western Australiarsquos Neoproterozoic to recent sedimentary basins in The
sedimentary basins of Western Australia edited by P G PURCELL and R R PURCELL
Petroleum Exploration Society of Australia Symposium Perth WA 1994 Proceedings p
45ndash62
BRADSHAW M T BRADSHAW J MURRAY A P NEEDHAM D J SPENCER L
SUMMONS R E WILMOT J and WINN S 1994 Petroleum systems in West Australian
basins in The sedimentary basins of Western Australia edited by P G PURCELL and R R
PURCELL Petroleum Exploration Society of Australia Symposium Perth WA 1994
Proceedings p 93ndash118
CLARKE G L 1991 Proterozoic tectonic reworking in the Rudall Complex Western Australia
Australian Journal of Earth Science v38 p 31ndash44
COCKBAIN A E and HOCKING R M 1990 Phanerozoic in Geology and mineral resources
of Western Australia Western Australia Geological Survey Memoir 3 p 750ndash755
ETHERIDGE M and WALL V 1994 Tectonic and structural evolution of the Australian
Proterozoic 12th Australian Geological Convention Geological Society of Australia
Abstracts no 37 p 102ndash103
GOODE A D T 1981 Proterozoic geology of Western Australia in Precambrian of the
Southern Hemisphere Developments in Precambrian geology 2 edited by I R HUNTER
Amsterdam Elsevier p 105ndash203
GREY K and JACKSON M J 1983 A re-assessment of stromatolite evidence for the
correlation of the Late Proterozoic Neale and Ilma Beds Officer Basin Western Australia
Australia BMR Journal of Australian Geology and Geophysics v 8 p 359
42
HICKMAN A H WILLIAMS I R and BAGAS L 1994 Proterozoic geology and
mineralization of the TelferndashRudall region Paterson Orogen Geological Society of Australia
(WA Division) Excursion Guidebook no 5 56p
HOCKING R M MORY A J and WILLIAMS I R 1994 An atlas of Neoproterozoic and
Phanerozoic basins of Western Australia in The sedimentary basins of Western Australia
edited by P G PURCELL and R R PURCELL Petroleum Exploration Society of Australia
Symposium Perth WA 1994 Proceedings p 21ndash 44
JACKSON P R 1966 Geology and review of exploration Officer Basin Western Australia
Hunt Oil Company Western Australia Geological Survey S-series S26 (unpublished)
JACKSON M J 1971 Notes on a geological reconnaissance of the Officer Basin Western
Australia Australia BMR Geology and Geophysics Record 19715 30p
JACKSON M J and van de GRAAFF W J E 1981 Geology of the Officer Basin Western
Australia Australia BMR Geology and Geophysics Bulletin 206 102 p
LOWRY D C JACKSON M J van de GRAAFF W J E and KENNEWELL P J 1971
Preliminary result of geological mapping in the Officer Basin Western Australia Western
Australia Geological Survey Annual Report for 1971 p 50ndash56
MYERS J S 1990 Precambrian in Geology and mineral resources of Western Australia
Western Australia Geological Survey Memoir 3 p 737ndash750
MYERS J S SHAW R D and TYLER I M 1994 Proterozoic tectonic evolution of
Australia 12th Australian Geological Convention Geological Society of Australia Abstracts
no 37 p 312
NEDIN C and JENKINS R J F 1991 Re-evaluation of unconformities separating the
lsquoEdiacaranrsquo and Cambrian systems South Australia Palaios v 6 p 102ndash108
PHILLIPS B J JAMES A W and PHILIP G M 1985 The geology and hydrocarbon
potential of the north-western Officer Basin APEA Journal 25 (1) p 52ndash61
POWELL C McA LI Z X McELHINNY M W MEERT J G and PARK J K 1993
Paleomagnetic constraints on timing of the Neoproterozoic breakup of Rodinia and Cambrian
formation of Gondwana Geology v 21 p 889ndash892
43
POWELL C McA PREISS W V GATEHOUSE C G KRAPEZ B and LI Z X 1994
South Australian record of a Rodinian epicontinental basin and its mid-Neoproterozoic
breakup to form the Palaeo-Pacific Ocean Tectonophysics v 237 no 3ndash4 p 113ndash140
PREISS W V 1976 Proterozoic stromatolites from the Nabberu and Officer Basins Western
Australia and their biostratigraphic significance South Australia Geological Survey Report
of Investigations no 47 p 1ndash51
TOWNSON W G 1985 The subsurface geology of the western Officer Basin mdash results of
Shellrsquos 1980ndash1984 petroleum exploration campaign APEA Journal v 25 (1) p 34ndash51
WATTS K J 1982 The geology of the Townsend Quartzite Upper Proterozoic shallow water
deposit of the Northern Officer Basin Western Australia Perth University of Western
Australia BSc honours thesis (unpublished)
WELLS A T and KENNEWELL P J 1974 Evaporite exploration in the Officer Basin
Western Australia at the Madley Diapirs Australia BMR Record 1974194 (unpublished)
WILLIAMS I R and MYERS J S 1990 Paterson Orogen in Geology and mineral resources
of Western Australia Western Australia Geological Survey Memoir 3 p 274ndash286
WILLIAMS I R 1990 Savory Basin in Geology and mineral resources of Western Australia
Western Australia Geological Survey Memoir 3 p 329ndash334
WILLIAMS I R 1994 The Neoproterozoic Savory Basin Western Australia in The
sedimentary basins of Western Australia edited by P G PURCELL and R R PURCELL
Petroleum Exploration Society of Australia Symposium Perth WA 1994 Proceedings p
841ndash850
WILSON R B 1967 Woolnough Hills and Madley diapiric structures Gibson Desert WA
APEA Journal v 7 p 94ndash102
44
Appendix 2
Meteorological data (from Bureau of Meteorology Perth 1994)
Table 21 Wiluna rainfall (mm)
Year Jan Feb Mar Apr May Jun Jul Aug Sept Oct Nov Dec
1975 0 45 446 309 306 59 276 4 34 886 638 164 1976 16 154 12 138 53 16 34 62 12 238 0 2 1977 44 0 66 74 68 95 24 363 1 58 12 727 1978 234 522 94 16 0 96 367 24 16 353 185 45 1979 19 173 122 88 91 4 0 246 58 0 169 114 1980 148 764 68 1081 259 626 629 06 56 02 174 0 1981 123 476 192 32 196 118 44 74 14 0 28 312 1982 374 705 206 244 1079 92 02 143 368 526 368 118 1983 1 112 928 248 0 212 56 32 5 1 42 496 1984 149 7 342 84 836 0 348 132 224 04 16 172 1985 596 483 0 166 556 0 514 56 0 0 4 0 1986 0 154 35 0 0 1085 23 01 239 137 0 04 1987 1204 119 19 89 17 575 154 126 07 1 0 398 1988 46 202 164 13 388 0 202 104 0 0 224 1309 1989 207 234 26 703 278 536 57 0 01 0 144 02 1990 1035 23 281 46 126 53 94 218 44 9 42 0 1991 48 0 41 45 0 472 297 12 0 1 0 7 1992 112 96 1025 1227 323 65 04 174 0 132 48 4 1993 0 697 0 202 445 0 12 306 18 05 14 33 Mean 25 35 22 27 27 25 18 12 6 13 13 21
JAN FEB MAR APR MAY JUN JUL AUG SEP OCT NOV DEC0
10
20
30
40
Mea
n R
ain
fall
(mm
)
Month
Mean monthly rainfall in Wiluna
MKS41 140498
45
Table 22 Wiluna minimum temperature (degC)
Year Jan Feb Mar Apr May Jun Jul Aug Sept Oct Nov Dec
1975 ndash 23 203 15 94 63 71 62 103 124 169 205 1976 242 229 194 15 10 63 59 73 95 143 16 228 1977 243 25 197 148 96 95 56 86 102 ndash 188 23 1978 241 232 203 18 102 64 76 8 9 152 19 205 1979 255 226 216 167 83 6 59 79 97 145 198 223 1980 255 226 231 155 134 83 68 75 121 108 193 223 1981 245 216 19 182 119 6 54 78 138 159 163 218 1982 232 224 177 16 ndash ndash 37 111 112 164 209 225 1983 235 24 197 147 112 88 39 88 121 162 189 219 1984 241 243 191 156 ndash 72 66 7 95 161 182 211 1985 244 231 ndash 159 98 65 71 73 117 147 205 ndash 1986 ndash 229 226 155 93 96 43 49 10 122 ndash 219 1987 ndash 217 183 175 85 77 68 68 112 ndash ndash 221 1988 238 214 209 178 111 ndash ndash 86 104 157 171 195 1989 ndash 237 199 165 107 67 44 61 107 131 187 ndash 1990 232 ndash 211 155 118 62 57 87 102 149 195 22 1991 26 256 217 168 122 101 78 ndash 113 18 168 219 1992 227 227 214 169 102 98 59 69 ndash 125 159 196 1993 241 218 196 171 103 ndash 49 68 88 128 192 211 Mean 24 23 20 16 10 8 6 8 11 14 18 21
NOTE Dashes indicate data unavailable
JAN FEB MAR APR MAY JUN JUL AUG SEP OCT NOV DEC0
10
20
30
40
Month
MKS43 140498
50
Mean monthly minimum temperatures at Wiluna
Mea
n T
emp
erat
ure
(degC
)
46
Table 23 Wiluna maximum temperature (degC)
Year Jan Feb Mar Apr May Jun Jul Aug Sept Oct Nov Dec
1975 ndash 349 326 281 247 201 197 212 256 248 31 344 1976 374 369 346 297 248 206 208 225 265 287 313 388 1977 397 392 352 296 234 212 222 244 ndash 308 337 383 1978 378 345 346 316 242 195 176 205 231 295 334 356 1979 403 36 364 295 ndash ndash ndash 193 242 318 359 373 1980 392 342 377 275 24 176 179 233 292 288 349 391 1981 385 346 337 342 242 178 201 224 30 326 326 369 1982 372 359 315 307 ndash ndash 196 253 252 305 353 379 1983 381 389 327 272 263 222 187 248 287 321 336 366 1984 378 393 322 299 226 215 178 214 234 ndash 336 364 1985 40 366 ndash 294 224 216 205 212 284 307 355 ndash 1986 ndash 383 372 307 ndash 193 166 196 261 277 ndash 382 1987 ndash 339 328 305 21 202 214 218 275 ndash ndash 374 1988 388 365 353 301 23 ndash ndash 228 283 334 31 33 1989 ndash 375 339 285 238 179 181 219 275 298 336 ndash 1990 368 ndash 36 309 268 19 188 205 274 309 373 393 1991 414 416 363 315 268 206 21 ndash 279 338 332 368 1992 363 383 336 263 213 178 213 197 ndash 285 313 359 1993 396 357 344 301 221 ndash 197 215 253 294 347 362 Mean 39 37 34 30 24 20 20 22 27 30 34 37 NOTE Dashes indicate data unavailable
JAN FEB MAR APR MAY JUN JUL AUG SEP OCT NOV DEC0
10
20
30
40
Month
MKS42 140498
50
Mean monthly maximum temperatures at Wiluna
Mea
n T
emp
erat
ure
(degC
)
47
Appendix 3
Table 31 Summary of palynological results
Drillhole Depth (m) F no(a) GSWA no Lithology Formation Assemblage TAI(b)
BWB 1 74ndash75 F49668 135741 dark-grey siltstone basalt Jilyilli gt5 BWB 1 98ndash100 F49669 135742 dark-grey siltstone basalt Jilyilli gt5 BWB 1 121ndash122 F49670 135743 dark-grey siltstone basalt Jilyilli gt5 TWB 1 86ndash87 F49671 135631 dark-grey siltstone McFadden 3+ TWB 1 104ndash105 F49672 135632 dark-grey siltstone Cornelia 3+ TWB 1 121ndash122 F49673 135633 dark-grey siltstone Cornelia 4 TWB 2 14ndash15 F49674 135634 dark-grey siltstone Skates Hills 3+ TWB 6 49ndash50 F49675 135675 dark-grey siltstone Cornelia 1 3+ TWB 9 49ndash51 F49676 135704 dark-grey siltstone Brassey Range 1 3+ Trainor 1 37497- F49733 138939 black mudstone with Cornelia 5 37509 light-grey siltstone Trainor 1 3809 F49734 138940 dark-grey and black Cornelia 4- laminated mudstone Trainor 1 4170 F49735 138941 black unlaminated mudstone Cornelia 4- Trainor 1 4950 F49851 139501 dark-grey indurated siltstone Cornelia 5 Trainor 1 6032 F49852 139502 dark- and light-grey Cornelia 5 indurated siltstone Trainor 1 6434 F49853 139503 greenish indurated finely Cornelia 5 laminated siltstone LDDH 1 270 F49678 138934 dark-grey siltstone interbeds Waters 1 3+ in enterolithic evaporite Tarcunyah Gp LDDH 1 277 F49679 138935 dark-grey siltstone in cavity Waters 1 3+ in enterolithic evaporite Tarcunyah Gp
NOTES (a) GSWA Fossil Catalogue number (b) TAI = Thermal Alteration Index of Traverse (1988 plate 1)
48
Appendix 4
Savory Sub-basin quantitative magnetic and gravity interpretation (extracted from Cowan 1995)
Summary
A program of quantitative aeromagnetic interpretation has been completed on BMRAGSO data from the Savory Sub-
basin Western Australia Quantitative aeromagnetic interpretation utilized the 3D Euler deconvolution method
supported by wavenumber filtering and image processing The results have provided useful information on structural
trends and depth to magnetic sources in a structurally complex area Depth to magnetic source analysis has provided
information on intra-sedimentary magnetic sources as well as basement rocks
The results of the interpretation support previously identified depocentres However the presence of magnetic
sources at several levels makes it very difficult to produce a reliable magnetic basement depth contour map It is
considered more productive to work with the 3D Euler colour circle plots and images rather than trying to contour the
results It would be necessary to carry out a full-scale interpretation of the BMRAGSO profile data to improve on the
3D Euler results The regional gravity was found to be useful in interpreting the regional setting of the area although
the very wide data spacing limits quantitative use of the data The gravity data show quite a complex picture with
limited consistent correlation between gravity features and basin structures This suggests that gravity anomalies
reflect changes in density of the basement rocks rather than basement topography especially in the northern part of the
basin
It is recommended that the GSWA investigate access to company confidential high-resolution aeromagnetic data
prior to planning further aeromagnetic surveys Private companies have flown large parts of the northern half of the
area as part of their diamond exploration program Additional gravity coverage of the area may be more cost effective
than magnetic surveys as the gravity data provides more information on changes within the sedimentary section
Introduction
The main use of aeromagnetic data in petroleum exploration has been the determination of magnetic basement
topography although there has been increasing interest in analysis of intra-sedimentary magnetic anomalies
intrabasement and suprabasement magnetic anomalies These anomalies are used to determine depth to magnetic
basement rocks and hence determine the thickness of the sedimentary sequence Unfortunately interpretation of the
intrabasement and suprabasement magnetic anomalies is non-unique in terms of position and size of causative sources
because of the inherent ambiguity of potential-field methods However this ambiguity can be reduced by placing
49
constraints on source geometry and magnetization and by using geological and other geophysical data to constrain
the solution
Before 1970 most depth-determination techniques involved graphical determination of slopes of selected
magnetic anomalies and application of various empirical factors to convert the slopes into depth estimates Geological
Society of America Memoir 47 Interpretation of Aeromagnetic Maps by Vacquier et al (1951) was a landmark for
this type of interpretation
Automated interpretation procedures have played an increasingly important role in depth interpretation and a
wide range of techniques have been developed Many of these techniques are designed for application to located data
profiles and assume a two-dimensional geometry However there has been renewed interest in techniques applicable
to gridded data
Two distinct types of method can be recognized In the first case often described as discrete methods individual
isolated magnetic anomalies are interpreted and the results used to produce a map of basement relief In the second
case often described as continuous methods areas of data containing a number of anomalies are interpreted
statistically to produce direct output of basement depths
The discrete methods usually involve a semiautomatic initial phase which generates a large number of possible
depth solutions and an interactive second phase to screen and select acceptable solutions The advantage of this
approach is that the interpreter can select features that are relatively free from interference from adjacent anomalies
and consider all aspects of a particular magnetic anomaly The disadvantage is that interpretation can be very time
consuming as a wide range of depths are usually possible depending on the initial model chosen and a significant
amount of effort is needed to select the correct model In the case of the Savory Sub-basin dataset we encountered
problems in separating basement related effects from the effects of shallower intrasedimentary magnetic sources
Because of these problems we have concentrated on displaying the Euler results accompanied by separation filter
images of the data to show the shallower effects and deeper effects rather than trying to refine a 3D Euler
deconvolution depth-to-crystalline-basement contour
The continuous methods are very direct provided that the rather restrictive assumption can be made that all
anomalies are due to lateral magnetization changes due to basement topography This means that shallow effects and
large intrabasement anomalies must be removed from the data This involves judgement and skill as it is necessary to
distinguish between the lower amplitude suprabasement anomalies due to basement topography and the larger
intrabasement anomalies reflecting magnetization changes within the basement These methods were not considered
suitable for the Savory Sub-basin magnetic dataset but were used to invert the gravity data
50
Limitations of magnetic and gravity interpretation
Interpretation of the area is limited by a shortage of information on the nature and physical properties of the deeper
sedimentary sequence and the underlying basement rocks However using techniques such as cross-correlation of
gravity and pseudo-gravity data it is possible to try to differentiate between anomalies relating to basement and those
related to the sedimentary sequence
Gravity anomalies reflect changes within the sedimentary sequence as well as basement condition These
changes in density of sedimentary rocks produce gravity anomalies without a corresponding magnetic anomaly hence
the complementary nature of gravity and magnetic surveys The main use of magnetics is to determine depth to
magnetic basement and any intra-sedimentary volcanic rocks or intrusives whereas gravity provides much more
general information on the sedimentary sequence
Unfortunately interpretation of gravity anomalies is complicated since they can be due to a number of geological
features including
bull major basement faults
bull basement highs
bull igneous intrusions within the basement
bull sedimentary basins which may or may not be isostatically compensated
bull intra-sedimentary volcanics and associated plutonic centres
Two major problems affect the interpretation of both magnetic and gravity data
1 The inherent ambiguity of potential-field data There is no unique solution to any measured gravity or magnetic
anomaly and theoretically there will be an infinite number of source geometry and magnetizationdensity
combinations which will fit the observed data This means that any a priori information which helps to select a
suitable model is very useful
2 Measured anomalies are the summation of effects from different depths For example an observed gravity profile
may contain contributions from shallow sources (density variations within the sedimentary basin) intermediate
depth sources (density variations due to large igneous intrusions within the basement) and deep sources (crustal
thinning producing a mantle anomaly) Separation of these component responses is the regionalresidual problem
which we solve using spectral analysis and differential upward continuation-based separation filtering
Regional setting and interpretation overview
The area studied includes parts of BALFOUR DOWNS (SF51-9) RUDALL (SF51-10) ROBERTSON (SF51-13) GUNANYA
(SF51-14) COLLIER (SG50-4) BULLEN (SG51-1) TRAINOR (SG51-2) MADLEY (SG51-3) NABBERU (SG50-5)
STANLEY (SG51-6) and HERBERT (SG51-7) 1250 000 sheets Broadly the area lies between latitudes 22deg00rsquondash25deg30rsquoS
and longitudes 119deg30rsquondash123deg30rsquoE
51
Regional gravity
The AGSO regional gravity data (at nominal 11 km spacing) was gridded at a 4 km mesh spacing using a minimum-
curvature algorithm Bouguer gravity values in the area are negative reflecting mass deficiency at depth and range
from -84 mgals to -25 mgals
A Bouguer gravity colour image is shown as Figure 41 A residual grid was produced by removing a fifth-order
orthogonal polynomial from the Bouguer data but did not add to the interpretation
120deg 121deg 122deg 123deg
23deg
24deg
25deg
-25
-84
50 km
MKS46 180598
mgal
Figure 41 Regional Bouguer gravity (BMRAGSO data) gridded at 4 km
52
The data show a complex pattern of positive and negative anomalies with no clearly defined trends Correlations
with aeromagnetic data and known basin structures are poor A vague north-northwest linear trend appears to coincide
with the Marloo Fault (Figure 42) A prominent negative anomaly appears to coincide with the Blake Fold and Fault
Belt depocentre and continues as a narrower negative anomaly to the east until it widens out again near the edge of the
basin Elsewhere the gravity data show little correlation with known basin structures and it is likely that especially in
the north of the area gravity anomalies are due to density changes in the basement rather than changes in basement
topography
Production of wavelength-filtered residual gravity plots and vertical gradient plots showed very patchy aliased
data reflecting poor sampling in much of the area
Regional magnetics
The AGSO regional aeromagnetic data were gridded at a 400 m mesh spacing using a minimum-curvature algorithm
(Figure 43) Most of the data has a line spacing of 1600 m with small areas of 1 km spacing The quality of the data is
acceptable for regional interpretation but is not adequate for detailed analysis The accuracy of the flight path is rather
variable reflecting the vintage of the data and the noise envelope of the data is poor by modern standards Problems
were also encountered in joining different map sheets
The magnetic anomaly pattern over the south and west part of the area shows a strong high frequency signature
reflecting the presence of widespread basic sills and dykes Some of the major north-northeasterly trending dykes can
be traced over considerable distances
Discontinuous high-frequency anomalies extend as a northwest-trending zone through the centre of the area and
this zone includes a conspicuous circular magnetic anomaly which is probably a ring complex
The northern and eastern parts of the area are characterized by long-wavelength deep-seated basement magnetic
anomalies with 120deg and 150deg trends dominant The Marloo and Perentie Faults (Figure 42) appear as distinct linear
zones and offsets A prominent easterly trending negative anomaly in the northwest of the area appears to swing round
to the southeast and may separate different basement blocks One possible interpretation is that this very deep seated
anomaly separates areas of Archaean and Proterozoic basement
Regional geology
The regional geology is described in Williams (1992) The GSWA provided a digitized version of Plate 2 from this
Bulletin the structural interpretation map to use as an overlay (Figure 42)
53
Pp
Pp
PSd
PSd
PSd
PSd
PSd
PSo
PSt
PSt
PSf
PSf
PSf
PSb
PSb
PSb
PSsPSs
PSs
PSb
PSm
PSp
PSc
PSc
PSw
PSw
PSw
PSg
PSr
PSj
PSg
PM
Pk
PY
PY
PSd
L
L
L
L
L
L
L
LL
L
L
L
LL
L
LL
L L
LL
L L
L
L
L
L
L
L
L
LL
L
L
BLAKEDEPOCENTRE
MA
RLO
O
FAU
LT
PERENTIEFAULT
50 km
MKS39120598
120deg 121deg 122deg 123deg
25deg
24deg
23deg
Approximate boundaryof aeromagnetic interpretation
PML
PSgL
PSjL
PML
PSpL
PML
PML
PSfL
PSfL
PSpL
LPc
LPcLPcPSrL
LPA
Durba Sandstone
Woora Woora Formation
McFadden Formation
Tchukardine Formation
Boondawari Formation
Skates Hills Formation
Mundadjini Formation
Coondra Formation
Spearhole Formation
Watch Point Formation
Jilyili Formation
Brassey Range Formation
Glass Spring Formation
Paterson Formation
Yeneena Group
Karara Formation
Cornelia Formation
Kahrban Subgroup
Bangemall Group
Fault
Formation boundary
PSdL
PSoL
PSfL
PStL
PSbL
PSsL
PSmL
PScL
PSpL
PSwL
PSjL
PSrL
PSgL
Pp
PYL
PkL
LPc
LPA
PML
Savory Group Other Units
PYL
Figure 42 Regional geology and structure map (after Williams 1992)
54
120deg 121deg 122deg 123deg
23deg
24deg
25deg
5820
3750
MKS47 180598
nT
50 km
Figure 43 Regional aeromagnetic data total magnetic intensity (BMRAGSO data) gridded at 400 m
Analysis
3D analysis
3D Euler deconvolution was used as the primary depth-determination method The advantage of this approach is that
consistent solutions can be obtained over the entire area with minimal assumptions about source geometries Euler
deconvolution of gridded data is used for positional information and estimation of depth to top of source Euler
55
deconvolution yields a large number of depth solutions which have to be screened to reject spurious solutions Results
are plotted as circles in eight depth ranges with radius proportional to depth and colour coded
The 400 m total magnetic intensity grid was used for the analysis Horizontal gradients in x and y and the vertical
gradient were calculated 3D Euler deconvolution was tested on the 400 m gridded data using windows of 9 times 9 and
11 times 11 and 16 times 16 data points and structural indices 05 (fault) and 10 (sill or dyke) It was concluded that the
16 times 16 window produced the best results overall and final plots were produced for the 16 times 16 window and structural
index 05 (Fig 44) Results were very good over the northern and central parts of the area showing magnetic sources
Figure 44 Depth to magnetic source 3D Euler deconvolution 16 times 16 window of 400 m gridded data structural index 05
56
at several different levels Unfortunately in the extreme south of the area shallow intrasedimentary magnetic sources
(sills and dykes) dominated the inversion and the results contained few basement solutions
In order to reduce these problems the 400 m gridded data were filtered using a separation filter based on
interpretation of the log-energy spectrum The 3D Euler method was run on the filtered data in order to generate more
basement-depth solutions Results for the deep-separation filter data were gridded and presented as a colour image in
Cowan (1995) Attempts to grid the Euler output were unsatisfactory and it is considered safer to interpret the 3D
Euler depth plots The 3D Euler depth results from the separation-filter run should be analysed with care as perfect
separation of the basement can never be achieved and there will always be some contamination from sources at
different levels
The results of original total magnetic intensity 3D Euler depth estimation for structural index 05 using a 16 point
window have been plotted at 1500 000 scale (not included in this publication but available in Cowan (1995) from the
GSWA Library as S10331) and as reduced A4 colour circle plots (Figure 44)
The results of deep-basement 3D Euler depth estimation for structural index 05 using a 16 point window have
been plotted as a colour image at 1500 000 scale and as an A4 image (not included in this publication)
2D analysis
Two equispaced profiles were interpolated with a 50 m station interval from the AGSO-located data profiles for the
BULLEN 1250 000 sheet The interpolated profiles were analysed using 2D Euler deconvolution and Werner
deconvolution Results are included in Cowan (1995) and show the use of these methods for more detailed analysis
Filtered data
In order to reconcile 3D Euler results from shallow basement and intrasedimentary magnetic sources we produced
several separation-filtered maps and images We found the shallow-layer double-separation filter (Figure 45) to be
very effective for shallow sources and the deep-layer standard-separation filter (Figure 46) for the basement layer
Gravity and magnetic data correlation
Both lsquoreduced to the polersquo (RTP) magnetics (Figure 47) and pseudo-gravity data (Figure 48) were produced as part of
the reconciliation of gravity and magnetic signatures In both cases the filtering operations assumed magnetization by
induction in the present Earths field The RTP data are fairly similar to the total magnetic intensity The pseudo-
57
gravity data are dominated by a northwest-trending strong positive anomaly and there is little correlation with the
Bouguer gravity data
The poor magneticgravity correlation is confirmed by cross-correlation of the RTP magnetics and the gravity
gradient The correlation plot in Figure 49 shows little coherent response with numerous zones of positive and
negative correlation
Figure 45 Regional aeromagnetic data shallow layer separation filter (BMRAGSO data) gridded at 400 m
Results
In the north and east of the area on the Wells Foreland Sub-basin trend (refer to Figure 1 main text) we see a range
of quite deep 3D Euler depths and several trend directions with north-northwesterly dominant There are relatively few
shallow intrasedimentary solutions in this zone
The second area of deep 3D Euler solutions lies over the Blake depocentre (Figure 43) with several trend
directions
Elsewhere the 3D Euler results are dominated by shallow intrasedimentary depth solutions reflecting mainly the
dolerite sills dykes and the ring complex However where we do see basement-related solutions in the south and
west of the area they appear to be shallower than those noted for the Wells Foreland Sub-basin and the Blake
depocentre
58
Figure 46 Regional aeromagnetic data deep-layer separation filter (BMRAGSO data) gridded at 400 m
Figure 48 Regional aeromagnetic data pseudo-gravity transform (BMRAGSO data) gridded at 400 m
Figure 47 Regional aeromagnetic data reduced-to-pole (BMRAGSO data) gridded at 400 m
Figure 49 Regional aeromagnetic and gravity data gravitymagnetic correlation using RTP magnetics and gravity gradient (BMRAGSO data) gridded at 4 km
59
This subdivision of the area into two zones of deep solutions is consistent with interpreted depocentres
However the interference between sources at different levels and the complexity of the magnetic response of the
basement rocks precludes more refined interpretation at this stage
The area of deep 3D Euler solutions over the Blake depocentre correlates with the pronounced negative gravity
anomaly discussed in the gravity interpretation section Using a density contrast of -015 gcc the negative gravity
anomaly could indicate up to 6ndash8 km of low-density sedimentary rocks depending on assumptions about the regional
field
The area of deep 3D Euler solutions over the Wells Foreland Sub-basin has a complex gravity expression and no
clear basin structure emerges from inversion of these data As noted previously it is likely that observed gravity
anomalies reflect contrasts in basement density rather than basement topography
Separation filtering applied to the magnetic data helps to enhance the intrasedimentary magnetic signature and to
give a better impression of the basement magnetic signature even though separation of the basement response is not
perfect
Conclusions
Quantitative aeromagnetic interpretation using 3D Euler deconvolution supported by wavenumber filtering and image
processing has been successful in providing structural trend and depth information for the Savory Sub-basin
Quantitative magnetic interpretation has revealed two zones of relatively deep magnetic basement beneath the
Wells Foreland Sub-basin and the Blake depocentre
This analysis of the magnetic data supports interpreted depocentres but the complexity of the basement magnetic
signature and interference from sources at different depths precludes further refinement to a map of basement
topography
Regional gravity proved to be very useful in understanding the regional setting of the area and in providing
support for aspects of the interpretation The gravity data support the interpretation of the Blake depocentre
suggesting up to 6ndash8 km of low-density sedimentary rocks
The deep structure of the Savory Sub-basin area is obviously complex with different areas underlain by
Archaean and Proterozoic basement and with the Capricorn suture occurring in the centre of the area
60
Recommendations
The quantitative magnetic interpretation needs to be reconciled with geological models available for the area
In particular the zones tentatively identified as areas with thick sedimentary rocks the Wells Foreland Sub-
basin and the Blake depocentre need to be investigated
Cross sections should be prepared across the basin for joint magneticgravity modelling especially for the Blake
depocentre It is important to be able to explain the strong negative gravity anomaly in this area
In view of the effects of basement density contrasts on the gravity field for the northern part of the area we think
that additional gravity interpretation and acquisition of new gravity data may not be justified as they will not
contribute significantly to understanding basin evolution and structure
It is recommended that GSWA try to get access to company confidential high-resolution aeromagnetic data
rather than flying new surveys The GSWA might offer to fund flying of new infill areas as a bargaining point
References
The original text of this report by Cowan (1995) and 1500 000 scale maps are filed in the GSWA Library under
S10331
COWAN D 1995 Savory Basin quantitative magnetic interpretation Western Australia Geological Survey S-series
S10331 (unpublished)
VACQUIER V STEENLAND N C HENDERSON R G and ZIETZ I 1951 Interpretation of aeromagnetic
maps The Geological Society of America Memoir 47 151p
WILLIAMS I R 1992 Geology of the Savory Basin Western Australia Western Australia Geological Survey
Bulletin 141 115p
61
Appendix 5
Geochemistry
MKS38 250398
Saturate FractionC12+ GLC
1217
Pr18
Ph
22
31CSR WELL-13 315m Cuttings
Figure 51 Canning Stock Route Well 13 gas chromatograph of extract of auger drill sample
12
17
18
22
31
Pr Ph
LDDH 1 6623m CoreSaturate FractionC12+ GLC
MKS35 240398
Figure 52 Gas chromatograph of extract from core sample at 6623 m LDDH1
62
Table 51 Canning Stock Route Well 13 auger drill samples
GSWA sample Drill depth (m)(a) Comments
135601 150 At watertable 135602 203 (all samples consist 135603 310 of sand mud and water) 135604 315 At total depth
NOTE (a) Datum for drill depth is the top of sediment fill in the well which is 155 m below ground level (ie the total depth of 315 m is 47 m below ground level)
Table 52 Canning Stock Route Well 13 gas chromatography data for 315 m depth sediment sample
Parameter Value
Weight of rock extracted (grams) 945 Total extract (ppm) 519 n-Alkane distribution n-C12 07 n-C13 23 n-C14 26 n-C15 22 n-C16 19 n-C17 14 i-C19 23 n-C18 14 i-C20 08 n-C19 11 n-C20 16 n-C21 25 n-C22 29 n-C23 70 n-C24 42 n-C25 95 n-C26 43 n-C27 83 n-C28 38 n-C29 87 n-C30 31 n-C31 273 Alkane compositional data Pristane phytane ratio 279 Pristane n-C17 ratio 161 Phytane n-C18 ratio 059 CPI (1)(a) 284 CPI (2) 209 (C21 + C22) (C28 + C29) 043
NOTE (a) CPI= Carbon preference index
63
Table 53 LDDH1 extract liquid chromatography data for 6623 m concentration
Rock extracted Total extract (grams) (ppm)
702 313
NOTE ppm= parts per million
Table 54 LDDH1 saturate gas chromatography data of core for 6623 m alkane composition
Pristane Pristane Phytane (a) CPI (1) CPI (2) (C21+C22) Phytane n-C17 n-C18 (C28+C29)
103 026 024 103 102 325
NOTE (a)CPI = carbon preference index
Table 55 LDDH1 saturate gas chromatography data of core for 6623 m n-alkane distributions
Parameter Value
n-C12 17 n-C13 38 n-C14 55 n-C15 60 n-C16 65 n-C17 74 i-C19 19 n-C18 78 i-C20 19 n-C19 80 n-C20 79 n-C21 71 n-C22 64 n-C23 57 n-C25 43 n-C24 38 n-C27 31 n-C28 23 n-C29 19 n-C30 12 n-C31 10
64
Appendix 6
Table 61 Summary of data from Trainor waterbores (TWB) and Bullen waterbores (BWB)
Well AMG Elevation TD Status(b) Completion details Water Salinity Water level Flow rate Depth to consolidated AGD84 GL (m) (m) struck mgl(c) (m) (LHr) lithology aquifer(e) Z51(a) Interval (m) (100 mm PVC) (m) (mgl)(d)
TWB 1 473660E 453 122 comp 0ndash75 plain 63 7 300 24 2 880 12 m 7287404N 75ndash93 slotted (9 260) McFadden Fm 93ndash99 plain TWB 2 472 977E 475 23 abd nil 15 m 7285877N Skates Hills Fm dry TWB 3 473259E 475 50 abd nil 7 m 7285849N Skates Hills Fm dry TWB 4 463225 E 445 50 comp 0ndash22 plain 35 7 200 55 3 600 0 m 7286143N 22ndash34 slotted (8 140) Tertiary sand and gravel 23ndash60 plain TWB 5 463095E 445 31 comp 0ndash19 plain 13 26 000 655 3 600 Tertiary sand and gravel 7277721N 19ndash25 slotted (36 700) 25ndash31 plain TWB 6 457013E 455 50 comp 0ndash42 plain 38 920 119 600 0 m 7274352N 42ndash48 slotted (1 030) Cornelia Fm ss TWB 7 453739E 475 26 susp 0ndash2 plain 11 9 300 48 4 500 0 m 7263891N (10 500) Tertiary sand TWB 8 433893E 535 60 susp 0ndash2 plain 47 8 500 gt46 1 200 0 m 7245991N (10 900) Tertiary sand and Brassey Range Fm ss TWB 9 437219E 505 51 comp 0ndash47 plain 45 1 000 58 600 1 m 7235905N 47ndash51 slotted (990) Brassey Range Fm ss TWB 10 434927E 495 32 susp 0ndash2 plain 235 450 120 0 m 7225875N (500) Dolerite
65
BWB 1 287337E 580 122 abd Nil 1 m 7245861N Jilyili Fm dry BWB 2 288346E 545 50 comp 0ndash26 plain 15 630 3 29 000 0 m 7240423N 26ndash38 slotted (730) Tertiary sand and gravel 38ndash50 plain BWB 3 305637E 545 50 abd 19 8 800 43 7 200 0 m 7240423N (10 550) Tertiary ss BWB 4 320167E 515 445 comp 0ndash20 plain 9 980 445 24 000 0 m 7248097N 20ndash32 slotted (1 190) Tertiary ss 32ndash44 plain BWB 5 353393E 545 20 susp 0ndash2 plain 45 (970) 1 m 7238934N Basalt
NOTES (a) GPS accuracy ~ 150 m (b) Comp = completed abd = abandoned susp = suspended (c) Salinity from conductivity (d) Analysis total dissolved solids (e) Fm = Formation ss = sandstone
2
waterbores in the southeast of the sub-basin and a mineral drillhole in the north of the region Rock cuttings from a waterbore in the southwest of the sub-basin are overmature for hydrocarbon generation but this bore intersected mafic intrusives and hence may not be representative of maturity for the region
KEYWORDS hydrocarbon prospectivity oil shows Neoproterozoic Savory Sub-basin Officer Basin source rocks diamond drilling
Introduction
Recognition in the late 1980s of a thick sequence of generally weakly deformed Neoproterozoic
sedimentary rocks of relatively low thermal maturity previously included within the
Mesoproterozoic Bangemall Basin (defined as the Savory Basin by Williams 1992) revealed a
hydrocarbon exploration frontier The Savory Sub-basin (Fig 1) now recognized as part of the
Officer Basin is located west of outcrops of Phanerozoic cover rocks of that larger basin The
Officer Basin a large episutural basin which contains clastic carbonate and minor evaporite and
volcanic rocks is considered to be part of the Neoproterozoic Centralian Superbasin (Walter and
Gorter 1994) The age of the Officer Basin successions is not well constrained but in the Savory
Sub-basin it is largely Neoproterozoic with possible Palaeozoic strata present in parts
The boundaries defined by Williams (1992) for the sub-basin have been largely used in this
record but data from sedimentary rocks previously assigned to older basins that are now
recognised or inferred to be of early Neoproterozoic age (Supersequence 1) have been used to
assess the hydrocarbon potential of the northwestern part of the Officer Basin
The southern part of the sub-basin unconformably overlies the Mesoproterozoic Bangemall Basin
The western boundary of the sub-basin is faulted against the Bangemall Basin The eastern
boundary of the Savory Basin as defined by Williams (1992) was placed along the western edge
of Phanerozoic outcrops of the Officer Basin at approximately 123degE longitude Recent studies
(Perincek 1996ab) however have indicated there is little difference in the Neoproterozoic
geology of the two regions The northeastern boundary of the sub-basin was defined as a reverse-
and thrust-faulted contact with the Yeneena and Karara Basins of the Paterson Orogen (Williams
1992) However Bagas et al (1995) subdivided strata from the Yeneena Basin into three new
groups the Throssell Lamil and Tarcunyah Groups The older and more deformed Throssell and
Lamil Groups remain part of the Yeneena Basin and the Paterson Orogen The younger and less-
deformed sedimentary rocks of the Yeneena and Karara Basins were considered to be of
Supersequence 1 age and were reassigned to the Tarcunyah Group The Tarcunyah Group was
considered to be coeval with the older strata of the Savory Sub-basin The Tarcunyah Group
Savory Sub-basin and Officer Basin were grouped into a single tectonic unit which was informally
referred to as the greater Officer Basin (Bagas et al 1995)
3
50 km
120deg 121deg30 123deg
25deg
24deg
23deg
22deg
Blake Fault andFold Belt
Wells Foreland S
ub-basin
TrainorPlatform
MKS32200498
HamersleyBasin
PilbaraCraton
YeneenaBasin
YeneenaBasin
YeneenaBasin
CanningBasin
Sylvania Inlier
BangemallBasin
Bangemall Basin
YilgarnCraton
YilgarnCraton
GlengarryBasin
EaraheedyBasin
Ward Inlier
OldhamInlier
KararaBasin
GibsonSub-basin
(Officer Basin)
WestwoodShelf
(Officer Basin)
KingstonShelf
(Officer Basin)
Rudall Complex
Trainor Platform
(Kahrban Subgroup)
Greater Officer Basin
Savory Sub-basin
Surface anticlinesMAP
AREAPerth
Figure 1 Structural subdivisions of the Savory Sub-basin and surface anticlines
4
During 1994 in consultation with the Petroleum Industry the Department of Minerals and
Energy received State Government funding for a Petroleum Exploration Initiative to be
undertaken by the Geological Survey of Western Australia (GSWA) with a view to identifying
prospective onshore areas for oil and gas thus increasing the level of onshore exploration in
Western Australia This initiative was originally funded for the first three years of a five-year work
program Two teams of specialists were formed to investigate the prospectivity of both the western
margin and interior onshore sedimentary basins
The Petroleum Exploration Initiative teams seek to enhance the prospectivity of onshore
basins by reducing through focused investigations the risks perceived by industry to be factors
limiting exploration activity Comprehensive petroleum system reports of the onshore Western
Australian basins are to be completed as a result of the projects undertaken during the five-year
Initiative The objective of the Initiative will be achieved through both the analysis of open-file
exploration data and the acquisition of new data New data will include but not be limited to
geophysical surveys and stratigraphic drilling Project results are to be reported to the industry
through GSWA publications external publications conference reports and oral presentations
This Record is the third in a series of comprehensive reviews by the GSWA of the
hydrocarbon prospectivity of some of Western Australiarsquos interior onshore sedimentary basins
The first Record of this series covered the Canning Basin (Apak and Carlsen 1997) The second
Record reviewed the Western Australian Officer Basin (Perincek 1998) but excluded the Savory
Sub-basin
This study assesses the potential for hydrocarbon exploration within the Savory Sub-basin
based on available geological and geophysical data and defines the scope for future studies
Publications relevant to this investigation but which are not specifically referred to are listed in
Appendix 1
Access and climate
The Savory Sub-basin lies east and southeast of the mining town of Newman in the Pilbara region
(Fig 2) The area is largely uninhabited the only settlement being an outcamp at Poondawari on
the GUNANYA 1250 000 map sheet The outcamp is linked by a graded track to the Jigalong
Community 90 km to the west just outside the northwest margin of the sub-basin A few pastoral
leases lie along the margins of the sub-basin but the majority of the region is Vacant Crown Land
Capitalized names refer to standard map sheets
5
Sealed road
Gravel road
Track
Town
Homestead
Locality
STANLEYSavory Sub-basin boundary 1250 000 map sheet
CornerTrack
Talawana - Windy
Route
Watch Point
NEWMAN
JigalongCommunity
RobertsonRange (abd)
Wokalba
Poondawari
Balfour Downs
Billinnooka
Weelarrana
Beyondie(abd)
Kumarina
Marymia
Glen-ayle
White Lake
Hanging RockBoorabee Hill
WellsRa
EmuRa
Robertson
Ra McFadden R
a
DiebillHills
DurbaHills
Calvert Ra
WardHills
Cornelia Ra
KellyRaBlakeHills
HillsDean
ROBERTSON GUNANYA
TRAINORBULLEN
BALFOUR DOWNS RUDALL
NABBERU STANLEY HERBERT
50 km
Woora Woora Hills
120deg 121deg30 123deg
25deg
24deg
23deg
22deg
Goldfieldsnatural gaspipeline
GR
EA
TN
OR
TH
ER
NH
IGH
WA
Y
Mar
ble
Bar
Nul
lagi
ne-
Rd
MADLEY
Can
ning
Stoc
k
MKS31120598
Goldfields natural gas pipeline
Figure 2 Localities and access routes of the Savory Sub-basin
6
The sealed Great Northern Highway lies west of the Savory Sub-basin and links Meekatharra
to Newman The TalawanandashWindy Corner graded track crosses the northern part of the sub-basin
and graded pastoral station tracks on Balfour Downs Weelarrana Kumarina Marymia and Glen-
Ayle give access to the western and southern margins The Canning Stock Route traverses the sub-
basin from north to south and is a well travelled four-wheel-drive track allowing access to the
eastern half of the sub-basin Additional minor tracks also provide access to other parts of the area
(Williams 1992) Recently flown monochrome aerial photography at 150 000 and Landsat TM
imagery covering the sub-basin is available from the Department of Land Administration
Cross-country access is similar to that in the Canning Basin with the average height of sand
dunes being lower in the Savory Sub-basin Potable water has been found in water bores in the
south of the sub-basin and is inferred to be present throughout the region Fuel and supplies are
available at Wiluna Meekatharra and Newman A good working relationship with the Western
Desert Community who hold native title claims over most of the sub-basin has been established
by GSWA
There are no meteorological stations within the Savory Sub-basin but estimates based on data
from nearby Bureau of Meteorology Stations indicate that the area is arid and has its maximum
rainfall in summer from monsoonal rains The sub-basin has reasonable access and a tolerable
working climate for all exploration activities Meteorological data for the town of Wiluna which
lies about 180 km to the south of the sub-basin are included as Appendix 2
Regional geology
Stratigraphy
Thirteen formations were recognized by Williams (1992) in the Savory Sub-basin and these are
summarized in Table 1 Although unconformities were recognized between some of the
formations and they reflect a wide range of depositional environments provenance and climatic
conditions these formations were defined by Williams (1992) as constituting the Savory Group
Five depositional sequences that are generally unconformity-bounded were recognized by
Williams (1992) (Fig 3) The correlation of significant formations within the sub-basin with other
parts of the Centralian Superbasin is shown in Figure 4 with the four Neoproterozoic
Supersequences having been defined by Walter et al (1995)
7
Durba Ss
McFadden
Woora Woora400
Tchukardine700
Skates Hills
Mundadjini1800
B
Coondra
(B)
Watch Point
Spearhole1100Jilyili
1000(A)
Glass Spring1600(A)
Brassey Range1700(A)
Abs
ent
Absent Absent
Absent
Absent
Absent
A
B
C
D
E
1A
1B
3
4A
4B
1000
2000
3000
4000
5000
6000
Max
imum
thic
knes
s
Sup
erse
quen
ce
AG
EN
EO
PR
OT
ER
OZ
OIC
NE
OP
RO
TE
RO
ZO
ICT
O
CA
MB
RIA
NM
AR
I-N
OA
N
NW SE
Savory Sub-basin Stratigraphy
MKS30 120598
Fault boundary
Unconformity
Disconformity
Conglomerate
Sandstone Mudstone
Siltstone
Evaporite
Dolomite
Boondawari800 Boondawari
Supersequence 2 is not represented in the Savory Sub-basin Total thicknesses are estimated from air photo interpretation Thicknesses of recessive units are unknown
Diamictite
Dep
ositi
onal
seq
uenc
e
Figure 3 Formations lithology and depositional sequences AndashE of the Savory Sub-basin
8
Table 1 Summary of formations in the Savory Sub-basin
Formation Super Depo Lithology Thickness Depositional Savoy Comments Seq(a) Seq(b) (m) environment Group(c)
Durba Sandstone 4 E Quartz sandstone with minor 100 Fluvial lacustrine Y Excellent reservoir basal conglomerate lenses Woora Woora 4 D Medium-grained ferruginous 400 Shallow marine deltaic Y Formation sandstone lithic sandstone quartz wacke siltstone McFadden 4 D Laminated fine- to coarse-grained 1 500 Shallow marine deltaic Y Possible reservoir Formation quartz sandstone feldspathic sandstone quartz wacke minor conglomerate siltstone Tchukardine 4 D Medium- to coarse-grained sandstone 700 Shallow marine Y Formation lithic sandstone quartz wacke conglomerate lenses siltstone minor shale Boondawari 3 C Glacigene diamictite sandstone siltstone Formation shale conglomerate minor dolomite (some stromatolitic and oolitic) rhythmite 800 Glacial shallow marine Y Possible source rock Skates Hills 1 B Thin-bedded dolomite (some stromatolitic) 200 Shallow marine sabkha Y Possible source rock Formation chert evaporites fine- to medium-grained sandstone siltstone shale patchy basal conglomerate Mundadjini 1 B Fine- to coarse-grained sandstone 1 800 Deltaic sabkha Y Possible source rock Formation conglomerate siltstone minor shale shallow marine mudstone dolomite (some stromatolitic) and evaporites Coondra 1 B Coarse- to medium-grained sandstone 1 000 Fan delta Y Possible reservoir Formation poorly sorted conglomerate pebbly sandstone Spearhole 1 B Coarse- to medium-grained sandstone 1 100 Braided fluvial deltaic Y Possible reservoir Formation pebbly sandstone siltstone and oil shows in conglomerate lenses Mundadjini 1 Boondawari 1
9
Watch Point 1 B Shale siltstone fine- to medium-grained 400 Shallow marine deltaic Y Formation sandstone glauconitic sandstone Jilyili Formation 1 A Fine-grained sandstone siltstone minor shale mudstone conglomerate lenses 1 000 Deltaic Y Brassey Range 1 A Fine- to medium-grained sandstone 1 700 Fluvial deltaic Y Formation siltstone shale minor mudstone Glass Spring 1 A Medium- to coarse-grained sandstone 1 600 Shallow marine fluvial Y Formation minor conglomerate and siltstone Tarcunyah Group 1 AampB Quartz sandstone feldspathic sandstone Shallow marine sabkha N Bitumen in LDDH1 quartz wacke shale siltstone fluvial lacustrine conglomerate evaporites dolomite Cornelia 1 A Sandstone siltstone shale mudstone Shallow marine N Overmature source rocks Formation minor glauconitic sandstone deep marine in Trainor 1 Kahrban 1 A Sandstone siltstone shale 1 700 Shallow marine deltaic N Subgroup
NOTES (a) Supersequences of Walter et al (1995) (b) Depositional sequences of Williams (1992) (c) Y= assigned to Savory Group in Williams (1992) N= previously considered to be older than the Savory Group but now included in the greater Officer Basin
10
SAVORY SUB-BASIN GIBSON SUB-BASINCENTRAL OFFICERBASIN
AMADEUS BASIN
PETERMANN RANGES OROGENY
NE
OP
RO
TE
RO
ZO
IC
ST
UR
TIA
NM
AR
INO
AN
ED
IAC
AR
IAN
CAMBRIANTO
NEOPRO-TEROZOIC
AG
E (
Ma)
SOUTHS RANGE MOVEMENT
AREYONGA MOVEMENT
Steptoe
MILES OROGENY
Mission Group
Cassidy Group
Rudall Complex
Bangemall Group
unnamed
Tar
cuny
ah G
roup
4
3
2
1
MKS12a 180598
500
550
600
650
700
750
800
850
900
SU
PE
R
SE
QU
EN
CE
unnamed
Tchukardine Fm
McFadden Fm
ArumberaSst
Julie Fm
Pertatataka Fm
Olympic FmPioneer Sst
Boondawari Fm
Turkey Hill FmLupton Fm
Kanpa Fm
Neale FmBabbagoola
FmHussar
Fm
Browne Fm
Woolnough Fm
Madley Fm
Bitt
er S
prin
gs F
m
LovesCreek M
Gillen M
Heavitree Fm
Arunta Complex
Throssell Group
TownsendQuartzite
Earaheedy Group
olderCornelia Fm
Jilyili Fm
SpearholeFm
MundadjiniFm
Skates Hills Fm
Lefroy Fm
Areyonga Fm
Aralka Fm
ME
SO
-P
RO
TE
RO
ZO
IC
Waters Fm
youngerCornelia Fm
Brassey RangeFormationKahrban
Subgroup
GlassSpring
Fm
Durba Sst
LP1ALP1B EVENT
Figure 4 Correlation of Savory Sub-basin formations with the western Officer and Amadeus Basins Fm = Formation Sst = Sandstone M = Member
11
The depositional sequences recognized in the sub-basin are an order of magnitude thicker than
those described from Phanerozoic passive-margin settings (Payton 1977 Posamentier et al 1988)
and are broadly comparable in scale to the second-order cycles of Vail et al (1977) and to the
megasequences of Hubbard et al (1985) The main subsurface data available to reveal the
unweathered nature of these rocks are Trainor-1 and the three-well diamond coring program in
Petroleum Permit EP 380 (Akubra 1 Boondawari 1 Mundadjini 1) completed in late 1997 in the
central west of the sub-basin (Figs 5 and 6)
The ages of all formations in the Savory Sub-basin are poorly constrained The only fossils
known are stromatolites and palynomorphs (acid-insoluble microfossils) Palynology from
available wells is summarized in Appendix 3 from Grey and Stevens (1997) and Grey and Cotter
(1996) and correlations using stromatolite biostratigraphy (Stevens and Grey 1997 Grey 1995f
Walter et al 1994 1995) are consistent with a Neoproterozoic age for the formations for which
data are available
A dolerite within the Boondawari Formation gave a poorly constrained RbndashSr age of about
640 Ma (Williams 1992) SHRIMP UndashPb dating of sedimentary zircons from the McFadden and
Cornelia Formations in stratigraphic drillhole Trainor 1 are discussed in Stevens and Adamides (in
prep) and Nelson (1997) The youngest ages from these analyses indicate that the maximum age
of the Cornelia Formation is Early Cambrian or Sturtian but these ages are inconsistent with
previous tectonic interpretations (Williams 1992) and current stratigraphic correlations which
suggest the Cornelia Formation is of Supersequence 1 age or older (Fig 4)
Depositional Sequence A Supersequence 1
Depositional Sequence A includes the Glass Spring Jilyili and Brassey Range Formations (Fig
3) All of these units are predominantly quartzose sandstones some of which are friable and have
significant visible porosity in outcrop Conglomerates are present in the Glass Spring and Jilyili
Formations
Depositional Sequence B Supersequence 1
Depositional Sequence B consists of the Watch Point Coondra Mundadjini Spearhole and
Skates Hills Formations (Fig 3) All of these formations contain beds of quartzose sandstone and
some also contain conglomerates The porosity of dolomites in the Skates Hills Formation appears
poor in surface exposures but its subsurface characteristics are unknown
12
50 km
120deg 121deg30 123deg
25deg
24deg
23deg
22deg
Greater Officer Basin
PNCEXP CA11PNCEXP CA12
PNCEXP CA13PNCEXP CA19
PNCEXP CA05
PNCEXP CA09
BD134589
GSWA Trainor 1 and TWB123
Fortescue River 1A
Mundadjini 1
Akubra 1Boondawari 1
TWB4TWB5
TWB6
TWB7
TWB8
TWB9
TWB10
BWB1
BWB2 BWB3
BWB4
BWB5
OD23
Mineral exploration drillhole
Stratigraphic drillhole
Waterbores and wells(TWB and BWB serieswaterbores identified)
MKS33270398
LDDH 1
Savory Sub-basin
Canning SR Well 13
EP380
Petroleum Exploration permit
Petroleum exploration well
Figure 5 Locations of petroleum exploration wells mineral exploration and stratigraphic drillholes water bores and wells and petroleum exploration permit EP380 in the Savory Sub-basin
13
TD=600m
TD=1367m
TD=701m
TD=709m
TD=50m
SS
1S
S1
SS1
SS
1S
S1
SS
1
SS
1
SS1
SS4 SS1
Pha
nero
zoic
or
SS
2
Cz
CzCz
Karst Bitumen
SS1
TD=181m
Mundadjini 1 Akubra 1 Boondawari 1 LDDH 1 Trainor 1 TWB 6
Munda-djini Fm
Spear-hole Fm
Munda-djini Fm
Munda-djini Fm
Spear-hole Fm
Spear-hole Fm
Waters Fm
McFadden Fm
Cornelia Fm
Cornelia Fm
Cornelia Fm
511 plusmn 13Maor 696 plusmn 20Ma(maximum)
779 plusmn 10Ma(maximum)
Mundadjini 1
Akubra 1 Boondawari 1
LDDH 1
Trainor 1TWB 6100 km
N
LOCATION
NW SE
Sea level
0m AHD
Dolerite basalt
Conglomerate
Sandstone
Mudstone
Dolomite
Limestone
Evaporite
TOC gt08
Permeability gt100md
Oil fluorescence
Sedimentary zircon U-Pb age
Identifiable polymorphs
Cainozoic
Supersequence 1 age
Unconformity
Formation contact
Cz
SS1
r
r
0
100
200
metres
VerticalScale
MKS36 120598
LEGEND
Figure 6 Geological cross section through significant drillholes in the Savory Sub-basin
14
Depositional Sequence C Supersequence 3
Depositional Sequence C consists of the Boondawari Formation (Fig 3) and although it contains
sandstone conglomerate and dolomite the sandstones contain significant amounts of feldspar and
clay and hence are likely to be poorer reservoirs than older sandstones
Depositional Sequence D Supersequence 4
Depositional Sequence D includes the McFadden Tchukardine and Woora Woora Formations
(Fig 3) The McFadden Formation is poorly sorted and sandstones contain significant amounts of
feldspathic clasts in the north of the basin but are significantly coarser and cleaner in the northeast
of the sub-basin (Williams 1992)
Sandstones of the Tchukardine and Woora Woora Formations are generally cleaner than those
of the McFadden Formation and are expected to have fair to good porosity although the
Tchukardine Formation has a higher clay content in parts
Depositional Sequence E Supersequence 4
Depositional Sequence E consists of the Durba Sandstone (Fig 3) a coarse sandstone with minor
conglomerate which has good to excellent visible porosity in surface exposures
Other depositional sequences and regional correlations
Sedimentary rocks which were not included in the Savory Group by Williams (1992) but which
are likely to be of Neoproterozoic age and hence part of the greater Officer Basin include the
Tarcunyah Group the Cornelia Formation and the Kahrban Subgroup
As discussed in the Introduction all of the strata in the Karara Basin and the younger strata
of the Yeneena Basin were redefined to form the Tarcunyah Group of the greater Officer Basin
(Bagas et al 1995) (Fig 7) In outcrop the Tarcunyah Group consists predominantly of quartzose
feldspathic and arkosic sandstone shale which is carbonaceous in parts and carbonate which
includes stromatolitic dolomite Mineral hole LDDH1 drilled on GUNANYA intersected the
15
120598
122deg
123deg
21deg
22deg
23deg
24deg
23deg
22deg
21deg
122deg
123deg
Fault
Thrust
Reverse thrust
CANNINGBASIN
OFFICERBASIN
GROUP
PILBARACRATON
TARCUNYAH
SAVORY GROUP
BANGEMALL
GROUP
THROSSELL
GROUP
LAMIL
GROUP
ConnaughtonTerrane
TerraneTalbot
complexTabletop granitic
Tabletop Terrane
Permian
Neoproterozoicgranitoid
50 km
FormationWaltha Woora
McKay Fault
South west Thrust
Vines
Fault
24deg
120deg
YENEENA CANNINGBASIN
ARUNTAINLIERRUDALL
COMPLEX
AMADEUSBASIN
MUSGRAVEBLOCK
OFFICERBASINYILGARN
CRATON
GROUP
GROUP
GROUP
PILBARACRATON
GROUP
EARAHEEDY
GLENGARRY
BANGEMALL
WYLOO GROUP
SAVORY
WA
CARNARVONBASIN
GASCOYNECOMPLEX
GROUPTARCUNYAH
400 kmGROUP
SA
N
T
CamelndashTabletopfault zone
KAHRBANSUBGROUP
CORNELIAFORMATION
MKS37
Figure 7 Regional geological setting of the Savory Group and western Officer Basin The dashed line on the inset map marks the interpreted margin of the greater Officer Basin
16
Tarcunyah Group and consists predominantly of mudstone with minor sandstone limestone
dolomite and anhydrite (Fig 6)
The age of the Tarcunyah Group is uncertain although limited palynological and stromatolite
evidence suggests that it is probably coeval with Supersequence 1 of the Centralian Superbasin
Drillhole LDDH1 contains palynomorphs equivalent to assemblages in the Browne and Bitter
Springs Formations of the Officer and Amadeus Basins respectively and from the Cornelia
Formation in TWB 6 (Grey and Stevens 1997) (Figs 4 and 6) Stromatolite specimens tentatively
assigned to Acaciella australica (Howchin 1914) Walter 1972 occur in the lower Tarcunyah
Group (Bagas et al 1995) The stromatolite Baicalia burra Preiss 1972 and a conical
stromatolite were reported from the upper part of the Tarcunyah Group (Stevens and Grey 1997)
The recognition of two stromatolite assemblages interpreted to have age significance in
Supersequence 1 sedimentary rocks of the Centralian Superbasin has permitted biostratigraphic
correlations between outcrop and well data The Acaciella australica assemblage appears to be
slightly older than 800 Ma and is restricted to the middle part of Supersequence 1 The Baicalia
burra assemblage is considered to be slightly younger than 800 Ma and occurs in the upper part
of Supersequence 1 (Grey 1996b Stevens and Grey 1997) The older A australica assemblage
is recognized in the Skates Hills Formation in the Savory Sub-basin and the stromatolite A
australica itself has been tentatively identified in the lower Tarcunyah Group The occurrence of
the A australica assemblage in the Woolnough Madley and Browne Formations of the Officer
Basin and in the Loves Creek Member of the Bitter Springs Formation of the Amadeus Basin
allows correlations throughout the Centralian Superbasin (Fig 4)
The younger B burra assemblage has not been recognized in sedimentary rocks of the
Savory Group as defined by Williams (1992) but it occurs in the upper parts of the Tarcunyah
Group and allows correlation of this group with outcrops of the Neale Formation and with the
Kanpa Formation in petroleum exploration well Hussar 1 both located in the central Officer Basin
of Western Australia (Fig 4) (Grey 1996b Stevens and Grey 1997) The occurrence of the B
burra assemblage in these units permits their correlation with the Burra Group in the Adelaide
Geosyncline of South Australia (K Grey unpublished data)
The Cornelia Formation and Kahrban Subgroup outcrop in the southeast of the sub-basin and
were considered by Williams (1992) to be part of the Mesoproterozoic Bangemall Basin Limited
evidence suggests that all or parts of these two units are of Neoproterozoic age The Ward and
Oldham Inliers consist of outcrops of the Cornelia Formation Waterbore TWB 6 which was
drilled on TRAINOR in the Cornelia Formation contains palynomorphs consistent with a
Supersequence 1 age (Grey and Stevens 1997) (Figs 5 and 6) In outcrop the Cornelia Formation
17
consists predominantly of sandstone and quartzite with lesser siltstone shale mudstone and chert
In Trainor 1 this formation consists predominantly of indurated mudstone with minor sandstone
chert and dolomite A major erosional unconformity separates the Cornelia Formation from
overlying formations and parts of the Cornelia Formation have been folded with dips exceeding
70deg In contrast the majority of the Savory Sub-basin sedimentary rocks have dips of less than 30deg
except where they are adjacent to faults The Cornelia Formation apparently consists of an older
unit of steeply dipping quartzites cherts and well-indurated mudstones and a younger unit of
shallower dipping sandstones which are sub-friable in parts However caution should be used in
interpreting the age of units based on their structural deformation and additional mapping and age
dating of this formation is required
It is proposed here that the Kahrban Subgroup is likely to be of early Neoproterozoic age and
hence should be considered as part of the greater Officer Basin This proposal is based largely on
the relatively low dip of the strata (generally less than 20deg) and their west-northwest strike which
is parallel with strikes in the overlying Brassey Range Formation of the Savory Group The lower
contact of the Kahrban Subgroup is obscured but is thought to be an unconfirmity on the
Earaheedy Basin on the southeast of STANLEY (Muhling and Brakel 1985)
Structural setting
The Savory Sub-basin forms the most northwesterly sub-basin of the Neoproterozoic to
Phanerozoic Officer Basin The western boundary of the sub-basin with the Mesoproterozoic
Bangemall Basin consists of steep-reverse and strike-slip faults The northeastern boundary of the
Savory Sub-basin was mapped where Supersequence 4 formations of the Savory Group
unconformably overlie sedimentary rocks of the Karara and Yeneena Basins with the two older
units considered to be part of the Paterson Orogen (Williams 1992) This contact was defined as a
series of steeply dipping reverse faults in the northernmost parts of the sub-basin on BALFOUR
DOWNS and RUDALL and was extrapolated as an inferred reverse fault farther along strike to the
southeast on GUNANYA and MADLEY where the contact is obscured by Cainozoic sediments It is
now recognized that all the sedimentary rocks in the Karara Basin and younger sedimentary rocks
of the Yeneena Basin are from the Supersequence 1 Tarcunyah Group and part of the greater
Officer Basin (Bagas et al 1995) The northern boundary of the Tarcunyah Group and the greater
Officer Basin is in thrust-and reverse-faulted contact with the Rudall Complex and other parts of
the Paterson Orogen (Fig 7)
To the south the sub-basin unconformably overlies the Bangemall Basin The eastern
boundary of the sub-basin used in this study is where Permian and younger strata of the Officer
Basin unconformably overlie Neoproterozoic strata although there are no significant structural or
stratigraphic differences between the Neoproterozoic units
18
The sub-basin is subdivided into three principal structural areas (Fig 1) Trainor Platform
Blake Fault and Fold Belt and Wells Foreland Sub-basin (Williams 1992) A major review of
these boundaries is beyond the scope of this report but the processing of regional aeromagnetic
data (Appendix 4) and acquisition of a semi-detailed gravity survey by the GSWA in the east of
the sub-basin has enabled these tectonic units to be reassessed and some modifications are
proposed
The Wells Foreland Sub-basin (originally termed the Wells Foreland Basin in Williams 1992)
and sedimentary rocks of the Tarcunyah Group are both considered to be the northwest
continuation of the Gibson Sub-basin of the Officer Basin Aeromagnetic gravity and outcrop
data suggest that the Blake Fault and Fold Belt is significantly faulted and folded in the west but
is less deformed in the east where the thickest sedimentary section in is located on BULLEN
(Appendix 4) The Trainor Platform is reinterpreted to represent an area of the sub-basin that has
undergone major compression during the Petermann Ranges Orogeny resulting in folding and
faulting with a northwest strike This interpretation contrasts with that proposed by Williams
(1992) who envisaged that only a thin section of the Savory Group was present on the platform
Perincek (1998) has recognized nine periods of tectonic activity in the Officer Basin from the
beginning of the Neoproterozoic to the end of the Cretaceous Three major tectonic episodes are
recognized in the Centralian Superbasin The oldest event is the Areyonga Movement which is
pre-Sturtian and forms the boundary between Supersequences 1 and 2 (Fig 4) The Souths Range
Movement occurred at the end of the Sturtian at the boundary between Supersequences 2 and 3
The youngest major event is the Petermann Ranges Orogeny which occured at the end of the
Marinoan and forms the boundary between Supersequences 3 and 4
One minor and two major tectonic episodes are recognized in the Savory Sub-basin the
LP1ALP1B structural event and the Areyonga Movement and the Petermann Ranges Orogeny
respectively The LP1ALP1B structural event is revealed where the Spearhole Formations rests
disconformably and locally unconformably on the Brassey Range Jilyili and Glass Spring
Formations The Neoproterozoic Areyonga Movement (equivalent to the Blake Movement of
Williams 1992) produced folds and faults with a general northeast strike in the western and
southern parts of the region The Souths Range Movement has not been recognized in the sub-
basin This may be due to the fact that no Sturtian glacial rocks have been identified and hence it
is possible that structures attributed to the Areyonga Movement could be the result of the Souths
Range Movement or a combination of the two movements
The major tectonic event recorded in the sub-basin is the latest Neoproterozoic to Cambrian
Petermann Ranges Orogeny (equivalent to the Paterson Orogeny) which produced large reverse
19
faults thrusts strike-slip faults and folds with a general northwest strike The McFadden
Formation and other Supersequence 4 strata are considered to be at least partially coeval with this
orogeny (Williams 1992) We also interpret the Durba Sandstone as having been deposited during
the later stages of the Petermann Ranges Orogeny as this unit mildly deformed with fold axes
parallel to the strike of other structures attributed to the Petermann Ranges Orogeny
Quantitative aeromagnetic interpretation of the Savory Sub-basin utilizing the 3D Euler
deconvolution method supported by wave-number filtering and image processing has provided
structural trends and depth to magnetic source within the sub-basin (Cowan 1995) Gravity data
are interpreted by Cowan (1995) as changes in both the density of the basement rocks andor
basement topography depending on local conditions Part of Cowanrsquos report is reproduced in
Appendix 4
Exploration history
The only petroleum exploration conducted in the sub-basin has been the recent drilling in the
western part of three diamond drillholes of which two have minor oil shows (Table 2) There has
been some mineral exploration the results of which are stored in the GSWA Western Australian
Mineral Exploration (WAMEX) database system Much of the mineral exploration was in the
southwest and west where the sub-basin is in contact with the Bangemall Basin and along the
northern margin of the sub-basin Many of these mineral exploration programs included
aeromagnetic surveys and surface geochemical sampling (Fig 8)
Hydrocarbon potential
The sub-basin contains a sedimentary succession up to 8 km thick which is generally gently
folded and faulted and apparently unmetamorphosed Limited drilling has shown that thick
mudstones are present in the sub-basin with some mudstones in Trainor 1 having high Total
Organic Carbon (TOC) values Outcrops of sub-friable sandstones in many of the formations
within the sub-basin suggests widespread reservoir potential Mudstone and inferred thick
evaporite sequences are likely to form seals Maturity data suggest that near-surface samples are
approximately at the base of the oil window and top of the gas window in parts of the north and
southeast of the sub-basin However parts of the southwest of the sub-basin and the mudstones in
Trainor 1 have very high levels of maturity Numerous faults and folds have been identified from
surface mapping suggesting good potential for large structural traps Minor oil shows in
20
Table 2 Neoproterozoic formations and hydrocarbon shows in diamond drillholes in the Savory Sub-basin
Drillhole AMG Core TD (m) Approx Formation Depth Formation Depth Formation Depth Shows (AGD84) start (m) GL (m) (m) (m) (m)
LDDH 1 431148E 112 701 350 Tarcunyah 68ndash701 ndash ndash bitumen at 6623 m 7443826N Group Trainor 1 473640E 6 709 455 McFadden 9ndash83 Cornelia Fm 83ndash709 possible bitumen at 4537 m 7287400N Fm Mundadjini 1 319056E 170 600 500 Mundadjini 16ndash361 Spearhole Fm 361ndash600 10 fluorescence at 36102 m 7404844N Fm Boondawari 1 348959E 299 1 367 490 Mundadjini Fm 15ndash312 Spearhole Fm 312ndash1 283 Intrusive 1 283ndash1 367 40 fluorescence at 35364 m 5 7398174N fluorescence at 4963 m Akubra 1 334249E 15 181 530 Mundadjini 15ndash42 Intrusive 42ndash181 None 7401252N Fm
21
50 km
120deg 121deg30 123deg
25deg
24deg
23deg
22deg
Greater Officer Basin
Savory Sub-basin
1
2
3
4
6
8
3 Seismic line (prefixed N83-00)
Aeromagnetic survey
GS
WA
Sav
ory
1995
gra
vity
sur
vey
Gravity survey
MKS34270398
Figure 8 Locations of aeromagnetic and gravity surveys (other than regional BMRAGSO data)
22
sandstones in two petroleum wells in the northwest of the sub-basin and bitumen and oil shows
elsewhere in the region indicate that oil has been generated and migrated through the sub-basin
Source rocks
Source potential is considered to be the major exploration risk in the Savory Sub-basin although
minor oil shows in Mundadjini 1 and Boondawari 1 indicate that at least some oil has been
generated and migrated into potential reservoirs within the sub-basin Sandstone is the
predominant lithology observed in outcrop Outcrops of fine-grained lithologies in the basin are
rare because of intense surface weathering and erosion Only about 8 of the surface area of the
sub-basin is exposed bedrock and recessive lithologies (such as shale evaporite and friable
sandstone) may be present although they rarely outcrop
Outcrops of stromatolitic dolomite with associated cauliflower chert and cubic pseudomorphs
interpreted as being after halite indicate that evaporitic environments are present within the
Mundadjini Skates Hills and Boondawari Formations Evaporitic minerals are also present in
drillhole LDDH1 in the Tarcunyah Group
In 1995 GSWA drilled a continuous-core diamond drillhole (Trainor 1) in the sub-basin on
TRAINOR to a depth of 709 m to test for source rocks thus providing the first such data for the sub-
basin The drillhole intersected flat-lying clastics and carbonates of the McFadden Formation (9ndash
83 m) overlying indurated mudstones of the Cornelia Formation (83ndash709 m total depth) dipping at
about 40deg Of the six samples analysed from the Cornelia Formation in this drillhole the five
located between 375 and 6032 m depth have TOC values exceeding 05 (range 066ndash365)
Rock-Eval pyrolysis of these five samples indicates that they are at best in the dry-gas thermal
stage and as a result of their high level of maturation (Stevens and Adamides in prep) have poor
remaining hydrocarbon-generating potential Although the Cornelia Formation is overmature at
Trainor 1 the high TOC values are encouraging as it is likely that this sequence is less mature
elsewhere in the sub-basin
The Mundadjini Formation contains potential source rocks that comprise marine mudstones
with evaporitic minerals present in parts Thin dark mudstones were intersected in the Mundadjini
Formation in Akubra 1 In Mundadjini 1 and Boondawari 1 however the mudstones appear to be
too oxidized to have source potential
The Boondawari Formation also may be a source rock as it contains black mudstones The
unit is laterally equivalent to the Pertatataka Formation of the Amadeus Basin and the Ungoolya
23
Group of the Officer Basin in South Australia both of which have some source potential
(Summons and Powell 1991 Morton and Drexel 1997) Samples from the Dey Dey Mudstone of
the Ungoolya Group generally have poor TOC values (average 011 range 003ndash081)
moderate hydrogen index (HI) values (100ndash382) and poor to fair genetic potential with a
maximum of 292 kg hydrocarbon per tonne of source rock (Morton and Drexel 1997)
Stromatolitic dolomites and mudstones at the top of the Boondawari Formation and within the
Skates Hills Formation are potential source rocks Stromatolitic dolomite and evaporitic rocks
deposited in a marginal marine to sabkha environment are considered to have good potential to
generate and preserve organic carbon without requiring a deep-water setting (Stevens and Grey
1997) Such conditions are recognized in the Skates Hills Formation and in the upper parts of the
Tarcunyah Group
Maturity
Knowledge of the maturity of sedimentary rocks within the Savory Sub-basin is still limited From
a review of palynological studies Grey and Stevens (1997) report that the thermal maturity
inferred from the Thermal Alteration Index (TAI) of 3+ from Supersequence 1 age palynomorphs
in TWB 6 TWB 9 and LDDH1 is within the hydrocarbon window (Appendix 3) In Phanerozoic
spores and pollen a TAI of 3+ approximately equates to the end of liquid petroleum generation
and the start of dry gas generation and to a vitrinite reflectance of about 13 (Traverse 1988)
However the use of TAI for estimating thermal maturity from Neoproterozoic palynomorphs
requires calibration
In Trainor 1 the Cornelia Formation contains organically rich claystones between 375 and
6032 m depth Based on Rock-Eval maturity data (Stevens and Adamides in prep) and the dark
colour of poorly preserved organic material (Grey 1995de 1996) with TAI 4- to 5 all samples
had a high level of maturation with at best dry-gas generating potential remaining In contrast
drillhole LDDH1 on GUNANYA recorded lower levels of maturity (TAI values of 3+) with two of
sixteen samples from the Tarcunyah Group having greater than 1 TOC (Grey 1995abc Grey
and Cotter 1996) Organic petrology and Rock-Eval maturity data for samples from LDDH1
indicate that the section above 500 m is within the oil-generative window whereas below 500 m
the rocks are within the gas window (Ghori in prep Fig 9 Appendix 5)
Waterbores TWB 1 2 6 and 9 which are located on TRAINOR in the southeast of the sub-
basin all had organic matter with TAI values of 3+ from the McFadden Skates Hills Cornelia
and Brassey Range Formations respectively
24
100
200
300
400
500
600
700
Oil
gene
ratin
g
Gas
gene
ratin
g
Fai
r
Fai
r
Poo
r
Poo
r
Goo
d
Imm
atur
e
Oil
win
dow
Oil
win
dow
Imm
atur
e
01 0110 10 0 150 300 440 480 1
Neo
prot
eroz
oic
TOC S1+S2 mgg Hydrogen Index Tmax degC
Depth(m)
Organicrichness
Generatingpotential
Kerogentype Maturity Maturity
TD=701m
Sandstone
Mudstone
Dolomite
Limestone
Evaporite
Source rock
MKS40 070498
Ro equivalent
Figure 9 Petroleum source potential of rocks in Normandy LDDH1
Small amounts of organic matter associated with basalt and dolerite in cuttings from
waterbore BWB 1 on BULLEN showed high levels of thermal maturity (Grey 1995a Libby 1995)
It is unclear whether all sedimentary rocks on BULLEN are overmature for hydrocarbon generation
or the results from BWB 1 are related to local heating events associated with the volcanic bodies
that are common in the Jilyili Formation
25
Reservoirs
Each of the five depositional sequences of the Savory Group (Table 1) are inferred to contain
significant sandstone reservoirs with the possible exception of depositional sequence C as
discussed above in Stratigraphy The Spearhole Formation was cored in Mundadjini 1 and
Boondawari 1 and visual estimates of porosity vary from generally poor (less than 5) to fair
(approximately 5ndash15) The McFadden Formation in Trainor 1 has porosity values of up to 232
and a maximum permeability of 195 md (Stevens and Adamides in prep) Sandstones from
Neoproterozoic formations form the acquifers in the following waterbores the McFadden
Formation in TWB 1 the Cornelia Formation in TWB 6 and the Brassey Range Formation in
TWB 8 and TWB 9 (Appendix 6 Table 61)
Based on outcrop observations the Durba Sandstone is considered to be the best reservoir of
the Savory Group Similarly some sandstones from the Tarcunyah Group also have good visible
porosity in outcrop
Dolomites occur in several formations in the sub-basin Reservoir potential may exist
particularly where the dolomites are stromatolitic and oolitic However dolomites have not been
drilled in the sub-basin and porosity can only be inferred from the preferential silicification of
some stromatolite bioherms observed in outcrop (Stevens and Grey 1997) Elsewhere in the
Officer Basin porosities of up to10 have been measured in dolomites A limestone breccia
(karst) is described from 663 to 677 m in drillhole LDDH1 (Fig 6 Busbridge 1994)
Seals
Indications of evaporitic environments in the Mundadjini Skates Hills and Boondawari
Formations are described by Williams (1992) In Mundadjini 1 from 287 to 337 m anhydrite and
chert occurs as nodules beds and veins in mudstone of the Mundadjini Formation Evaporitic
minerals (predominantly gypsum) are described in the Tarcunyah Group in LDDH1 The presence
of the Woolnough and Madley salt diapirs in the Officer Basin (approximately 110 km east of the
sub-basin) and halite beds over 25 m thick in the well Hussar 1 (130 km east of the sub-basin)
provide further evidence that evaporite seals may be present in the Savory Sub-basin
Mudstones and shales form only a small proportion of the limited Neoproterozoic outcrop in
the sub-basin but significant thicknesses of mudstone were encountered in the Mundadjini
Formation in Mundadjini 1 and Boondawari 1 the Tarcunyah Group in LDDH1 and in the
26
Cornelia Formation in Trainor 1 These data suggest that mudstones form a significant proportion
of strata in the sub-basin despite their limited outcrop
Traps
Potential structural closures including folds and faults occur at various scales throughout the
Savory Sub-basin However the region has only been mapped at 1250 000 scale and
independently closed structures such as domes have yet to be confirmed The western margin of
the basin contains abundant faults (with a northeast strike) but elsewhere faults are less common
Some anticlines are recognized in outcrop including one with a strike length of up to 45 km
inferred from surface bedding dips in the Mundadjini and Spearhole Formations at approximately
24deg15rsquoS 121deg10rsquoE on BULLEN (Fig 1)
Salt diapirs and other halokinetic structures are recognized in outcrop well and seismic data
in the Officer Basin to the west of the Savory Sub-basin and it is probable that there are
significant thicknesses of evaporitic sedimentary rocks in the sub-basin The gravity field data
suggest there is good potential for salt diapirs and traps related to halokinesis
Although there is potential for stratigraphic traps to be present in the sub-basin insufficient
data are available to assess them
Preservation of hydrocarbons
The range of thermal maturities measured to date and the large periods of time envisaged for
deposition of sediments implies hydrocarbon generation may have occurred a number of times
during the evolution of the Savory Sub-basin Any hydrocarbons that were generated early may
have been trapped in palaeostructures and remigration to younger traps could have taken place
later The Petermann Ranges Orogeny which has been equated with the Paterson Orogeny (Myers
1990) is believed to have occurred in the latest Neoproterozoic to early Cambrian This is the last
major tectonic event recognized in the sub-basin suggesting that it is reasonable to expect that trap
integrity will have been preserved
If the inference of the presence of thick halite beds in the sub-basin is correct the preservation
potential of sub-salt traps should be excellent
27
Reported hydrocarbon shows and oil seep
Amadeus Petroleum recorded minor oil shows in cores from Mundadjini 1 and Boondawari 1 In
Mundadjini 1 at 36102 m (top of the Spearhole Formation) a 3 mm thick zone had 10 moderate
white fluorescence with slow solvent cut This show was in a granular sandstone with visually
estimated porosity of about 10 In Boondawari 1 at 35364 m (within the Spearhole Formation) a
broken surface of sandstone had 40 moderate yellow-white fluorescence with slow solvent cut
Visually estimated porosity is about 5 Because the fluorescing surface was broken during the
drilling process this show could have resulted from contamination A second show occurs in
Boondawari 1 at 4963 m (within the Spearhole Formation) where a 1 cm-thick zone had 5 dull
yellow fluorescence with slow solvent cut in a conglomerate with visually estimated porosity of
about 10 The company intends to further investigate the nature of these occurrences
Minor bitumen is present at 6623 m in drillhole LDDH1 on GUNANYA (Figs 5 and 6) as a
vein in mudstones of the Tarcunyah Group A sample was analysed by gas chromatography
(Ghori in prep) and confirmed that it is natural bitumen (Appendix 5)
Mineral hole OD 23 drilled by Jubilee Gold Mines NL on NABBERU in the Bangemall Basin
immediately to the south of the Savory Sub-basin (Fig 5) encountered bitumen and trace oil in
vugs in dolomite (M Stevens unpublished data) but no further data are available at present
In their popular guide to the Canning Stock Route Gard and Gard (1990 p 218) refer to an
oil seep at Well 13 on TRAINOR (Fig 5) They reported that between 1977 and 1984 lsquonatural oilrsquo
was seen in the well Although the well is now largely filled with sediment four auger drill
samples were collected by the GSWA in 1995 and all four were analysed for oil shows One
sample from 315 m total depth (GSWA sample 135604) yielded just enough extract (519 ppm)
for saturate gas chromatography analysis The gas chromatograph (Appendix 5) shows that the
extract does contain some hydrocarbons probably from recent plant material Because the depth to
the oil was not quoted in Gard and Gard (1990) the hand-augered well may not have been deep
enough to properly test this reported seep
Geological and geophysical databases
Geological and geophysical data available for the Savory Sub-basin are limited The most recently
completed geological maps for the sub-basin were published by the GSWA between 1991 and
1995 (Williams and Tyler 1991 Williams 1992 1995ab)
28
The cores from the five drillholes listed in Table 2 believed to be all of the core available
from the sub-basin are available for inspection at GSWA Mineral exploration reports submitted
to GSWA may be searched using the WAMEX database and open-file reports are available on
microfiche Geophysical data acquired by the mining industry is not required to be filed with
GSWA if acquired over Vacant Crown Land which is the case for much of the sub-basin
Geophysical survey data submitted in mining tenement reports and which extend into Vacant
Crown Land remain confidential to the companies Original regional aeromagnetic and gravity
datasets are available from the Australian Geological Survey Organisation (AGSO)
Data pertinent to oil exploration in the sub-basin such as structural style and salt diapirism
are presented in a review of the hydrocarbon prospectivity of the Officer Basin (Perincek 1998)
Drilling
Significant drillholes in the sub-basin are summarized in Table 2
Petroleum industry data
Amadeus Petroleum drilled three petroleum exploration wells in the central west of the Savory
Sub-basin in late 1997 These wells Mundadjini 1 Boondawari 1 and Akubra 1 were drilled by
continuous diamond coring (Figs 5 and 6) All targeted potential reservoirs within the Spearhole
Formation with the Mundadjini Formation as the proposed seal The wells were located on
structures interpreted from Landsat images and limited geological investigations Both Mundadjini
1 and Boondawari 1 had minor oil shows as discussed above (Reported hydrocarbon shows)
Government data
Stratigraphic drillhole Trainor 1 was drilled by GSWA in 1995 (Stevens and Adamides in prep)
and the main results are discussed above (Source rocks and Maturity)
Mineral industry data
Normandy Exploration drillhole LDDH1 was cored in the Tarcunyah Group to a total depth of
701 m and provided source-rock and maturity data as discussed above
29
Oilmin NL drilled six percussion drillholes (BD 1 3 4 5 8 and 9) through sandstones and
shales in the northern part of the Savory Sub-basin to a maximum depth of 198 m (Fig 5
WAMEX Microfiche File M 26811 I 2610) but only brief geological descriptions are available
Hydrogeological data
Hydrogeological data within the Savory Sub-basin are limited although a long history of water
exploration extends back to the construction of the Canning Stock Route early this century No
detailed geological or wireline logs are available for the older wells along this route A few station
wells have been drilled by various methods on the south and west margins of the basin but data
are unavailable as reports are not required to be filed with the government Depth to watertable
throughout the basin is largely controlled by porosity of the bedrock
The GSWA drilled fifteen waterbores in the winter of 1995 in the southern part of the sub-
basin in preparation for the drilling of Trainor 1 and the proposed Bullen 1 Twelve bores found
water and six of these bores have salinities of less than 1000 mgL (Fig 5 Appendix 6 Table 61)
One waterbore TWB 6 has gamma ray and neutron logs run through PVC casing and these are
available from the GSWA with the digital log data included herein
Seismic data
No geophysical data have been acquired by the petroleum industry in the Savory Sub-basin
Seismic data acquired in the Officer Basin to the east particularly in the Gibson and Yowalga
Sub-basins is pertinent to structural interpretation in the Savory Sub-basin (Perincek 1996a
1998)
Aeromagnetic surveys
Government data
There are over 95 277 line kilometres of aeromagnetic data included in the AGSO dataset There
are three regional aeromagnetic surveys covering the Savory Sub-basin These were flown by the
Bureau of Mineral Resources (BMR now AGSO) in 1984 at a line spacing of 1500 m with 36 740
and 52 587 line kilometres flown and by Aerodata in 1984 at a line spacing of 1000m with 5950
line kilometres flown These data were reprocessed and interpreted for GSWA by Cowan (1995)
An edited copy of this report is included as Appendix 4 and the original report is filed in the
GSWA Library under S-series reports item 10331
30
Mineral industry data
The approximate locations of non-AGSO aeromagnetic surveys are shown in Figure 8 More
detailed information regarding the location of these surveys may be obtained using the GSWA
MAGCAT II database Additional information such as contours of aeromagnetic values may be
obtained by inspecting items on file with the GSWA
Gravity surveys
Government data
The average spacing for gravity data in the Savory Sub-basin is one station per 121 km2 (11 times 11
km grid) These data were principally collected by BMR in the early 1960s There are a few
additional regional gravity traverses across the sub-basin which are also included in the
BMRAGSO dataset These data were reprocessed and interpreted for GSWA (Fig 10) and a
report on this work is also included in Appendix 4
The GSWA completed a large semi-detailed gravity survey in the eastern Savory Sub-basin
utilizing helicopter support and Differential Global Positioning Survey (DGPS) techniques (Fig
8) This gravity survey completed in August 1995 consists of 2300 gravity stations on a 2 times 3 km
grid All stations were acquired by helicopter using Scintrex gravimeters and Ashtek dual
frequency DGPS equipment for determining location This highly efficient system allowed the
acquisition of more than 100 gravity stations per day in remote areas The resolution of this survey
is +30 cm and +05 microms-2 (Daishsat 1995) These data (Fig 11) represent a significant
improvement on the previous regional survey data and are available from GSWA (GSWA
1996ab) The results of the interpretation of these data were presented at the 1997 ASEG
Convention (Carlsen and Shevchenko 1997)
Mineral industry data
Three small gravity surveys were conducted by Oilmin NL (Fig 8) and the relevant WAMEX
reports are M 2681I 2610 I 2435 I 2567 These three surveys are of limited value because height
control was provided by barometers only and the surveys were not tied to the national gravity grid
31
23deg
25deg
120deg 122deg
Trainor 1
SAVORY
SUB-BASIN
MKS54 160498
100 km
1995 SavoryGravity Survey
254
-1056
micromsec2
Figure 10 Regional Bouguer gravity map of the Savory Sub-basin
23deg
24deg
25deg
122deg30 123deg
TRAINOR 1
123deg30
50 km
MKS53 160498
-116
-626
micro msec2
Figure11 Detailed Bouguer gravity map of the
Savory 1995 Gravity Survey from the eastern Savory Sub-basin
32
Government and academic reports
Chronostratigraphy and geochemistry
The understanding of Neoproterozoic organic chemistry palynology and structural evolution is
essential to the interpretation of hydrocarbon prospectivity Pertinent reports are included in the
bibliography (Appendix 1) Unpublished palaeontology reports describe the palynology of wells in
the Savory Sub-basin (Grey 1995andashe 1996a) Grey and Cotter (1996) discussed the potential for
Neoproterozoic palynomorphs to provide a biostratigraphic framework and palaeoenvironmental
interpretation Grey and Stevens (1997) reviewed the results of palynological studies of wells
drilled in the sub-basin and reported that Supersequence 1 palynomorphs are present in TWB 6
TWB 9 and LDDH1 (Appendix 3) Grey (1996b) reported on the use of stromatolites for
correlation in the Neoproterozoic and Stevens and Grey (1997) discussed the application of
stromatolite biostratigraphy in correlating isolated dolomite outcrops in the sub-basin with well
and seismic data in the Officer Basin and Centralian Superbasin
Although geochemical data from the Savory Sub-basin are very limited results mostly
confirm thermal maturities inferred from TAI for LDDH1 and Trainor 1 (Ghori in prep Stevens
and Adamides in prep) Those parts of the Officer Basin in Western Australia which lie to the
east of the Savory Sub-basin are sparsely drilled but Ghori (in prep) reports that most of the
Neoproterozoic succession presently lies within the oil-generative window However his study
has been unable to identify effective source-rock units and the source for oil shows Thin source
rocks are present in the Neoproterozoic in LDDH1 (Fig 9) and in three wells which lie to the east
and southeast of the Savory Sub-basin namely NJD 1 Kanpa 1A and Yowalga 3
Proposed work program
From the above limited information it is concluded that additional research on the hydrocarbon
potential of the sub-basin is justified and proposals are outlined below
bull Additional modelling of gravity and aeromagnetic data from the Savory Sub-basin is required
in light of the results from Trainor 1 and Boondawari 1 Trainor 1 showed that what appeared
to be a structurally simple area based on outcrop aeromagnetic and gravity data was in fact an
area of major structuring Boondawari 1 intersected a dolerite which is in good depth
agreement with aeromagnetic depth to source results showing this technique is useful in
detecting the depth to intrusive bodies
33
bull Additional data from mineral and petroleum exploration bores may become available and
analysis of samples from these wells should be undertaken and interpreted in the context of
their relevance to the Officer Basin
bull Stratigraphic coring in the Blake Fault and Fold Belt and in the Wells Foreland Sub-basin (Fig
1) targeting source rocks is considered essential to the continuing evaluation of the
hydrocarbon prospectivity of the Savory Sub-basin
bull Correlations using at least outcrop well and potential-field data should be prepared to link the
sub-basin with the better known parts of the Officer Basin to the east
bull Remapping is required to clarify boundary positions within the Cornelia Formation this may
resolve some of the current problems of the relationship between this unit and the rest of the
Savory Sub-basin
bull Further work is required to explain the Early Cambrian or Sturtian ages interpreted for the
Cornelia Formation from sedimentary zircon UndashPb dating in drillhole Trainor 1 The
determination of the age of the organically rich but overmature claystones in this well is
critical to assessing the hydrocarbon potential of the region
bull The thin dark mudstones intersected by Akubra 1 in the Mundadjini Formation warrant
geochemical analysis Analyses of the oil shows in Mundadjini 1 and Boondawari 1 are
currently being undertaken by Amadeus Petroleum
bull Geochemical analysis of hydrocarbons in the Bangemall Basin drillhole OD23 has been
performed by Jubilee Gold and the results will be reviewed when they are submitted to
GSWA The possibility of source rocks within the Bangemall Basin charging traps within the
Bangemall Basin and the overlying Savory Sub-basin requires further investigation
Conclusions
The Savory Sub-basin is a frontier region with only three recently drilled petroleum exploration
wells and no seismic data Based on existing geological and geophysical data it is considered too
early to draw conclusions about the hydrocarbon prospectivity of the sub-basin at this stage and
there are several reasons why the area warrants further investigation
34
1 Thick accumulations of sedimentary rocks are present (up to 8 km thickness inferred) which
may contain source reservoir and sealing strata
2 Minor oil shows occur in Mundadjini 1 and Boondawari 1 and bitumen is present in mineral
exploration drillhole LDDH1 suggesting that hydrocarbons have migrated within the
Neoproterozoic sequence of the Savory Sub-basin Oil and bitumen are present in mineral
exploration drillhole OD23 in the Bangemall Basin immediately to the south of the Savory
Sub-basin and it is possible that source rocks from the Bangemall Basin could charge traps in
the overlying Savory Sub-basin
3 The age of sedimentary rocks in the sub-basin is still poorly constrained but some of the
Neoproterozoic sedimentary rocks located on GUNANYA and TRAINOR are within the
hydrocarbon-generation window It is possible that a significant thickness of Phanerozoic
sedimentary rocks may also be present
4 Friable sandstones with visible porosity outcrop extensively suggesting numerous potential
reservoirs
5 Significant but not intense faulting and folding has been mapped implying large structural
traps may be present
6 Evaporitic sedimentary rocks occur in several formations and may provide good source rocks
and excellent seals
35
References
APAK S N and CARLSEN G M 1997 A compilation and review of data pertaining to the
hydrocarbon prospectivity of the Canning Basin Western Australia Geological Survey
Record 199610 103p
BAGAS L GREY K and WILLIAMS I R 1995 Reappraisal of the Paterson Orogen and
Savory Basin Western Australia Geological Survey Annual Review 1994ndash95 p 55ndash63
BUSBRIDGE M 1994 Lake Disappointment Exploration Licence 451064 Third Annual
Report Lake Disappointment Diamond Drill Hole LDDH1 Normandy Exploration Limited
Western Australia Geological Survey M-series Item 7567 A41358 (unpublished)
CARLSEN G M and SHEVCHENKO S I 1997 Petroleum exploration in Proterozoic basins
using potential fields data and stratigraphic coring Australian Society of Exploration
Geophysicists 12th Geophysical Conference Handbook Sydney 1997 Preview no 66 p 83
(abstract only)
COWAN D 1995 Savory Basin quantitative magnetic interpretation Western Australia
Geological Survey S-series S10331 (unpublished)
DAISHSAT PTY LTD 1995 Operational and processing report Savory Basin gravity survey
Western Australia Geological Survey S-series S10332 (unpublished)
GARD E and GARD R 1990 Canning Stock Route a travellerrsquos guide for a journey through
history Perth Western Australia Western Desert Guides 448p
GEOLOGICAL SURVEY OF WESTERN AUSTRALIA 1996a Savory Basin first vertical
derivative of Bouguer gravity image 1250 000 Western Australia Geological Survey
GEOLOGICAL SURVEY OF WESTERN AUSTRALIA 1996b Savory Basin Bouguer gravity
image 1250 000 Western Australia Geological Survey
GHORI K A R in prep Petroleum source rock potential and thermal history Officer Basin
Western Australia Western Australia Geological Survey Record
36
GREY K 1995a Savory Basin drillhole BWB 1 (Bullen waterbore) palynology and thermal
maturation GSWA Palaeontology Report no 199512 (unpublished)
GREY K 1995b Savory Basin drillholes TWB 1 2 6 9 (Trainor waterbores) palynology and
thermal maturation GSWA Palaeontology Report no 199520 (unpublished)
GREY K 1995c Palynology of Normandy-Poseidon Lake Disappointment-1 corehole
Tarcunyah Group Paterson Orogen GSWA Palaeontology Report no 199521 (unpublished)
GREY K 1995d Savory Basin drillhole Trainor 1 (Trainor diamond drilling) palynology and
thermal maturity GSWA Palaeontology Report no 199524 (unpublished)
GREY K 1995e Savory Basin drillhole Trainor 1 (Trainor diamond drilling) Additional
Preparation of two samples GSWA Palaeontology Report no 199528 (unpublished)
GREY K 1995f Neoproterozoic stromatolites from the Skates Hills Formation Savory Basin
Western Australia and a review of the distribution of Acaciella australica Australian Journal
of Earth Sciences v 42 p 123ndash132
GREY K 1996a Savory Basin drillhole Trainor 1 (Trainor diamond drilling) Additional
samples palynology and thermal maturation GSWA Palaeontology Report no 199615
(unpublished)
GREY K 1996b Preliminary stromatolite correlations for the Neoproterozoic of the Officer
Basin and a review of Australia-wide correlations GSWA Palaeontology Report no 199615
(unpublished)
GREY K and COTTER K L 1996 Palynology in the search for Proterozoic hydrocarbons
Western Australia Geological Survey Annual Review for 1995ndash96 p 70ndash80
GREY K and STEVENS M K 1997 Neoproterozoic palynomorphs of the Savory Sub-basin
Western Australia and their relevance to petroleum exploration Western Australia
Geological Survey Annual Review for 1996ndash97 p 49ndash54
HUBBARD R J PAPE J and ROBERTS D G 1985 Depositional sequence mapping as a
technique to establish tectonic and stratigraphic framework and evaluate hydrocarbon
potential on a passive continental margin in Seismic stratigraphy II an integrated approach
37
edited by O R BERG and D G WOOLVERTON American Association of Petroleum
Geologists Memoir 39 p 79ndash91
LIBBY WG 1995 A petrological report on six samples of bore cuttings from the Savory Basin
Western Australia Western Australia Geological Survey S-series S31307 (unpublished)
MORTON JGG and DREXEL JF 1997 The petroleum geology of South Australia Vol 3
Officer Basin South Australia Department of Mines and Energy Resources Report Book
9719
MUHLING P C and BRAKEL A T 1985 Geology of the Bangemall Group mdash the evolution
of an intracratonic Proterozoic basin Western Australia Geological Survey Bulletin 128
219p
MYERS J S 1990 Precambrian tectonic evolution of part of Gondwana southwestern Australia
Geology v18 p 537ndash540
NELSON D R 1997 Compilation of SHRIMP UndashPb zircon data Western Australia Geological
Survey Record 19972 196p
PAYTON C E 1977 Seismic stratigraphy mdash applications to hydrocarbon exploration
American Association of Petroleum Geologists Memoir 26 516p
PERINCEK D 1996a The age of NeoproterozoicndashPalaeozoic sediments within the Officer Basin
of the Centralian Super-basin can be constrained by major sequence-bounding unconformities
APPEA Journal v 36 pt 1 p 350ndash368
PERINCEK D 1996b The stratigraphic and structural development of the Officer Basin
Western Australia a review Western Australia Geological Survey Annual Review 1995ndash
1996 p 135ndash148
PERINCEK D 1998 A compilation and review of data pertaining to the hydrocarbon
prospectivity of the Officer Basin Western Australia Geological Survey Record 19976
POSAMENTIER H W JERSEY M T and VAIL P R 1988 Eustatic controls on clastic
deposition 1 mdash Conceptual framework in Sea-level changes an integrated approach edited by
C K WILGUS B S HASTINGS C G St C KENDALL H W POSAMENTIER
38
C A ROSS and J C VAN WAGONER Society of Economic Paleontologists and
Mineralogists Special Publication no 42
STEVENS M K and ADAMIDES N G in prep GSWA Trainor 1 well completion report
Savory Sub-basin Officer Basin Western Australia with notes on petroleum and mineral
potential Western Australia Geological Survey Record 199612
STEVENS M K and GREY K 1997 Skates Hills Formation and Tarcunyah Group Officer
Basin mdash carbonate cycles stratigraphic position and hydrocarbon prospectivity Western
Australia Geological Survey Annual Review for 1996ndash97 p 55ndash60
SUMMONS RE and POWELL C McA 1991 Petroleum source rocks of the Amadeus Basin
in Geological and geophysical studies in the Amadeus Basin central Australia edited by R J
KORSCH and JM KENNARD Australia BMR Geology and Geophysics Bulletin 236
TRAVERSE A 1988 Palaeopalynology Boston Unwin Hyman 600p
VAIL P R MITCHUM R M Jr TODD R G WIDMIER J M THOMPSON S III
SANGREE J B BUBB J N and HATLELID W G 1977 Seismic stratigraphy and
global changes of sea level in Seismic stratigraphy mdash applications to hydrocarbon
exploration edited by C E PAYTON American Association of Petroleum Geologists
Memoir 26 516p
WALTER M R and GORTER J 1994 The Neoproterozoic Centralian Superbasin in Western
Australia the Savory and Officer Basins in The sedimentary basins of Western Australia
edited by P G PURCELL and R R PURCELL Petroleum Exploration Society of Australia
Symposium Perth WA 1994 Proceedings p851ndash864
WALTER M R GREY K WILLIAMS I R and CALVER C R 1994 Stratigraphy of the
Neoproterozoic to early Palaeozoic Savory Basin and correlation with the Amadeus and
Officer Basins Australian Journal of Earth Sciences v 41 p 533ndash546
WALTER M R VEEVERS J J CALVER C R and GREY K 1995 Neoproterozoic
stratigraphy of the Centralian Superbasin Australia Precambrian Research v 73 p 173ndash195
WILLIAMS I R 1992 Geology of the Savory Basin Western Australia Western Australia
Geological Survey Bulletin 141 115p
39
WILLIAMS I R 1995a Bullen WA (2nd Edition) Western Australia Geological Survey
1250 000 Geological Series Explanatory Notes 23p
WILLIAMS I R 1995b Trainor WA (2nd Edition) Western Australia Geological Survey
1250 000 Geological Series Explanatory Notes 31p
WILLIAMS I R and TYLER I M 1991 Robertson WA (2nd edition) Western Australia
Geological Survey 1250 000 Geological Series Explanatory Notes 36p
40
41
Appendix 1
Bibliography
Reports which are relevant to this investigation but which are not specifically cited are listed
below
BAILLIE P W POWELL C McA LI Z X and RYALL A M 1994 The tectonic
framework of Western Australiarsquos Neoproterozoic to recent sedimentary basins in The
sedimentary basins of Western Australia edited by P G PURCELL and R R PURCELL
Petroleum Exploration Society of Australia Symposium Perth WA 1994 Proceedings p
45ndash62
BRADSHAW M T BRADSHAW J MURRAY A P NEEDHAM D J SPENCER L
SUMMONS R E WILMOT J and WINN S 1994 Petroleum systems in West Australian
basins in The sedimentary basins of Western Australia edited by P G PURCELL and R R
PURCELL Petroleum Exploration Society of Australia Symposium Perth WA 1994
Proceedings p 93ndash118
CLARKE G L 1991 Proterozoic tectonic reworking in the Rudall Complex Western Australia
Australian Journal of Earth Science v38 p 31ndash44
COCKBAIN A E and HOCKING R M 1990 Phanerozoic in Geology and mineral resources
of Western Australia Western Australia Geological Survey Memoir 3 p 750ndash755
ETHERIDGE M and WALL V 1994 Tectonic and structural evolution of the Australian
Proterozoic 12th Australian Geological Convention Geological Society of Australia
Abstracts no 37 p 102ndash103
GOODE A D T 1981 Proterozoic geology of Western Australia in Precambrian of the
Southern Hemisphere Developments in Precambrian geology 2 edited by I R HUNTER
Amsterdam Elsevier p 105ndash203
GREY K and JACKSON M J 1983 A re-assessment of stromatolite evidence for the
correlation of the Late Proterozoic Neale and Ilma Beds Officer Basin Western Australia
Australia BMR Journal of Australian Geology and Geophysics v 8 p 359
42
HICKMAN A H WILLIAMS I R and BAGAS L 1994 Proterozoic geology and
mineralization of the TelferndashRudall region Paterson Orogen Geological Society of Australia
(WA Division) Excursion Guidebook no 5 56p
HOCKING R M MORY A J and WILLIAMS I R 1994 An atlas of Neoproterozoic and
Phanerozoic basins of Western Australia in The sedimentary basins of Western Australia
edited by P G PURCELL and R R PURCELL Petroleum Exploration Society of Australia
Symposium Perth WA 1994 Proceedings p 21ndash 44
JACKSON P R 1966 Geology and review of exploration Officer Basin Western Australia
Hunt Oil Company Western Australia Geological Survey S-series S26 (unpublished)
JACKSON M J 1971 Notes on a geological reconnaissance of the Officer Basin Western
Australia Australia BMR Geology and Geophysics Record 19715 30p
JACKSON M J and van de GRAAFF W J E 1981 Geology of the Officer Basin Western
Australia Australia BMR Geology and Geophysics Bulletin 206 102 p
LOWRY D C JACKSON M J van de GRAAFF W J E and KENNEWELL P J 1971
Preliminary result of geological mapping in the Officer Basin Western Australia Western
Australia Geological Survey Annual Report for 1971 p 50ndash56
MYERS J S 1990 Precambrian in Geology and mineral resources of Western Australia
Western Australia Geological Survey Memoir 3 p 737ndash750
MYERS J S SHAW R D and TYLER I M 1994 Proterozoic tectonic evolution of
Australia 12th Australian Geological Convention Geological Society of Australia Abstracts
no 37 p 312
NEDIN C and JENKINS R J F 1991 Re-evaluation of unconformities separating the
lsquoEdiacaranrsquo and Cambrian systems South Australia Palaios v 6 p 102ndash108
PHILLIPS B J JAMES A W and PHILIP G M 1985 The geology and hydrocarbon
potential of the north-western Officer Basin APEA Journal 25 (1) p 52ndash61
POWELL C McA LI Z X McELHINNY M W MEERT J G and PARK J K 1993
Paleomagnetic constraints on timing of the Neoproterozoic breakup of Rodinia and Cambrian
formation of Gondwana Geology v 21 p 889ndash892
43
POWELL C McA PREISS W V GATEHOUSE C G KRAPEZ B and LI Z X 1994
South Australian record of a Rodinian epicontinental basin and its mid-Neoproterozoic
breakup to form the Palaeo-Pacific Ocean Tectonophysics v 237 no 3ndash4 p 113ndash140
PREISS W V 1976 Proterozoic stromatolites from the Nabberu and Officer Basins Western
Australia and their biostratigraphic significance South Australia Geological Survey Report
of Investigations no 47 p 1ndash51
TOWNSON W G 1985 The subsurface geology of the western Officer Basin mdash results of
Shellrsquos 1980ndash1984 petroleum exploration campaign APEA Journal v 25 (1) p 34ndash51
WATTS K J 1982 The geology of the Townsend Quartzite Upper Proterozoic shallow water
deposit of the Northern Officer Basin Western Australia Perth University of Western
Australia BSc honours thesis (unpublished)
WELLS A T and KENNEWELL P J 1974 Evaporite exploration in the Officer Basin
Western Australia at the Madley Diapirs Australia BMR Record 1974194 (unpublished)
WILLIAMS I R and MYERS J S 1990 Paterson Orogen in Geology and mineral resources
of Western Australia Western Australia Geological Survey Memoir 3 p 274ndash286
WILLIAMS I R 1990 Savory Basin in Geology and mineral resources of Western Australia
Western Australia Geological Survey Memoir 3 p 329ndash334
WILLIAMS I R 1994 The Neoproterozoic Savory Basin Western Australia in The
sedimentary basins of Western Australia edited by P G PURCELL and R R PURCELL
Petroleum Exploration Society of Australia Symposium Perth WA 1994 Proceedings p
841ndash850
WILSON R B 1967 Woolnough Hills and Madley diapiric structures Gibson Desert WA
APEA Journal v 7 p 94ndash102
44
Appendix 2
Meteorological data (from Bureau of Meteorology Perth 1994)
Table 21 Wiluna rainfall (mm)
Year Jan Feb Mar Apr May Jun Jul Aug Sept Oct Nov Dec
1975 0 45 446 309 306 59 276 4 34 886 638 164 1976 16 154 12 138 53 16 34 62 12 238 0 2 1977 44 0 66 74 68 95 24 363 1 58 12 727 1978 234 522 94 16 0 96 367 24 16 353 185 45 1979 19 173 122 88 91 4 0 246 58 0 169 114 1980 148 764 68 1081 259 626 629 06 56 02 174 0 1981 123 476 192 32 196 118 44 74 14 0 28 312 1982 374 705 206 244 1079 92 02 143 368 526 368 118 1983 1 112 928 248 0 212 56 32 5 1 42 496 1984 149 7 342 84 836 0 348 132 224 04 16 172 1985 596 483 0 166 556 0 514 56 0 0 4 0 1986 0 154 35 0 0 1085 23 01 239 137 0 04 1987 1204 119 19 89 17 575 154 126 07 1 0 398 1988 46 202 164 13 388 0 202 104 0 0 224 1309 1989 207 234 26 703 278 536 57 0 01 0 144 02 1990 1035 23 281 46 126 53 94 218 44 9 42 0 1991 48 0 41 45 0 472 297 12 0 1 0 7 1992 112 96 1025 1227 323 65 04 174 0 132 48 4 1993 0 697 0 202 445 0 12 306 18 05 14 33 Mean 25 35 22 27 27 25 18 12 6 13 13 21
JAN FEB MAR APR MAY JUN JUL AUG SEP OCT NOV DEC0
10
20
30
40
Mea
n R
ain
fall
(mm
)
Month
Mean monthly rainfall in Wiluna
MKS41 140498
45
Table 22 Wiluna minimum temperature (degC)
Year Jan Feb Mar Apr May Jun Jul Aug Sept Oct Nov Dec
1975 ndash 23 203 15 94 63 71 62 103 124 169 205 1976 242 229 194 15 10 63 59 73 95 143 16 228 1977 243 25 197 148 96 95 56 86 102 ndash 188 23 1978 241 232 203 18 102 64 76 8 9 152 19 205 1979 255 226 216 167 83 6 59 79 97 145 198 223 1980 255 226 231 155 134 83 68 75 121 108 193 223 1981 245 216 19 182 119 6 54 78 138 159 163 218 1982 232 224 177 16 ndash ndash 37 111 112 164 209 225 1983 235 24 197 147 112 88 39 88 121 162 189 219 1984 241 243 191 156 ndash 72 66 7 95 161 182 211 1985 244 231 ndash 159 98 65 71 73 117 147 205 ndash 1986 ndash 229 226 155 93 96 43 49 10 122 ndash 219 1987 ndash 217 183 175 85 77 68 68 112 ndash ndash 221 1988 238 214 209 178 111 ndash ndash 86 104 157 171 195 1989 ndash 237 199 165 107 67 44 61 107 131 187 ndash 1990 232 ndash 211 155 118 62 57 87 102 149 195 22 1991 26 256 217 168 122 101 78 ndash 113 18 168 219 1992 227 227 214 169 102 98 59 69 ndash 125 159 196 1993 241 218 196 171 103 ndash 49 68 88 128 192 211 Mean 24 23 20 16 10 8 6 8 11 14 18 21
NOTE Dashes indicate data unavailable
JAN FEB MAR APR MAY JUN JUL AUG SEP OCT NOV DEC0
10
20
30
40
Month
MKS43 140498
50
Mean monthly minimum temperatures at Wiluna
Mea
n T
emp
erat
ure
(degC
)
46
Table 23 Wiluna maximum temperature (degC)
Year Jan Feb Mar Apr May Jun Jul Aug Sept Oct Nov Dec
1975 ndash 349 326 281 247 201 197 212 256 248 31 344 1976 374 369 346 297 248 206 208 225 265 287 313 388 1977 397 392 352 296 234 212 222 244 ndash 308 337 383 1978 378 345 346 316 242 195 176 205 231 295 334 356 1979 403 36 364 295 ndash ndash ndash 193 242 318 359 373 1980 392 342 377 275 24 176 179 233 292 288 349 391 1981 385 346 337 342 242 178 201 224 30 326 326 369 1982 372 359 315 307 ndash ndash 196 253 252 305 353 379 1983 381 389 327 272 263 222 187 248 287 321 336 366 1984 378 393 322 299 226 215 178 214 234 ndash 336 364 1985 40 366 ndash 294 224 216 205 212 284 307 355 ndash 1986 ndash 383 372 307 ndash 193 166 196 261 277 ndash 382 1987 ndash 339 328 305 21 202 214 218 275 ndash ndash 374 1988 388 365 353 301 23 ndash ndash 228 283 334 31 33 1989 ndash 375 339 285 238 179 181 219 275 298 336 ndash 1990 368 ndash 36 309 268 19 188 205 274 309 373 393 1991 414 416 363 315 268 206 21 ndash 279 338 332 368 1992 363 383 336 263 213 178 213 197 ndash 285 313 359 1993 396 357 344 301 221 ndash 197 215 253 294 347 362 Mean 39 37 34 30 24 20 20 22 27 30 34 37 NOTE Dashes indicate data unavailable
JAN FEB MAR APR MAY JUN JUL AUG SEP OCT NOV DEC0
10
20
30
40
Month
MKS42 140498
50
Mean monthly maximum temperatures at Wiluna
Mea
n T
emp
erat
ure
(degC
)
47
Appendix 3
Table 31 Summary of palynological results
Drillhole Depth (m) F no(a) GSWA no Lithology Formation Assemblage TAI(b)
BWB 1 74ndash75 F49668 135741 dark-grey siltstone basalt Jilyilli gt5 BWB 1 98ndash100 F49669 135742 dark-grey siltstone basalt Jilyilli gt5 BWB 1 121ndash122 F49670 135743 dark-grey siltstone basalt Jilyilli gt5 TWB 1 86ndash87 F49671 135631 dark-grey siltstone McFadden 3+ TWB 1 104ndash105 F49672 135632 dark-grey siltstone Cornelia 3+ TWB 1 121ndash122 F49673 135633 dark-grey siltstone Cornelia 4 TWB 2 14ndash15 F49674 135634 dark-grey siltstone Skates Hills 3+ TWB 6 49ndash50 F49675 135675 dark-grey siltstone Cornelia 1 3+ TWB 9 49ndash51 F49676 135704 dark-grey siltstone Brassey Range 1 3+ Trainor 1 37497- F49733 138939 black mudstone with Cornelia 5 37509 light-grey siltstone Trainor 1 3809 F49734 138940 dark-grey and black Cornelia 4- laminated mudstone Trainor 1 4170 F49735 138941 black unlaminated mudstone Cornelia 4- Trainor 1 4950 F49851 139501 dark-grey indurated siltstone Cornelia 5 Trainor 1 6032 F49852 139502 dark- and light-grey Cornelia 5 indurated siltstone Trainor 1 6434 F49853 139503 greenish indurated finely Cornelia 5 laminated siltstone LDDH 1 270 F49678 138934 dark-grey siltstone interbeds Waters 1 3+ in enterolithic evaporite Tarcunyah Gp LDDH 1 277 F49679 138935 dark-grey siltstone in cavity Waters 1 3+ in enterolithic evaporite Tarcunyah Gp
NOTES (a) GSWA Fossil Catalogue number (b) TAI = Thermal Alteration Index of Traverse (1988 plate 1)
48
Appendix 4
Savory Sub-basin quantitative magnetic and gravity interpretation (extracted from Cowan 1995)
Summary
A program of quantitative aeromagnetic interpretation has been completed on BMRAGSO data from the Savory Sub-
basin Western Australia Quantitative aeromagnetic interpretation utilized the 3D Euler deconvolution method
supported by wavenumber filtering and image processing The results have provided useful information on structural
trends and depth to magnetic sources in a structurally complex area Depth to magnetic source analysis has provided
information on intra-sedimentary magnetic sources as well as basement rocks
The results of the interpretation support previously identified depocentres However the presence of magnetic
sources at several levels makes it very difficult to produce a reliable magnetic basement depth contour map It is
considered more productive to work with the 3D Euler colour circle plots and images rather than trying to contour the
results It would be necessary to carry out a full-scale interpretation of the BMRAGSO profile data to improve on the
3D Euler results The regional gravity was found to be useful in interpreting the regional setting of the area although
the very wide data spacing limits quantitative use of the data The gravity data show quite a complex picture with
limited consistent correlation between gravity features and basin structures This suggests that gravity anomalies
reflect changes in density of the basement rocks rather than basement topography especially in the northern part of the
basin
It is recommended that the GSWA investigate access to company confidential high-resolution aeromagnetic data
prior to planning further aeromagnetic surveys Private companies have flown large parts of the northern half of the
area as part of their diamond exploration program Additional gravity coverage of the area may be more cost effective
than magnetic surveys as the gravity data provides more information on changes within the sedimentary section
Introduction
The main use of aeromagnetic data in petroleum exploration has been the determination of magnetic basement
topography although there has been increasing interest in analysis of intra-sedimentary magnetic anomalies
intrabasement and suprabasement magnetic anomalies These anomalies are used to determine depth to magnetic
basement rocks and hence determine the thickness of the sedimentary sequence Unfortunately interpretation of the
intrabasement and suprabasement magnetic anomalies is non-unique in terms of position and size of causative sources
because of the inherent ambiguity of potential-field methods However this ambiguity can be reduced by placing
49
constraints on source geometry and magnetization and by using geological and other geophysical data to constrain
the solution
Before 1970 most depth-determination techniques involved graphical determination of slopes of selected
magnetic anomalies and application of various empirical factors to convert the slopes into depth estimates Geological
Society of America Memoir 47 Interpretation of Aeromagnetic Maps by Vacquier et al (1951) was a landmark for
this type of interpretation
Automated interpretation procedures have played an increasingly important role in depth interpretation and a
wide range of techniques have been developed Many of these techniques are designed for application to located data
profiles and assume a two-dimensional geometry However there has been renewed interest in techniques applicable
to gridded data
Two distinct types of method can be recognized In the first case often described as discrete methods individual
isolated magnetic anomalies are interpreted and the results used to produce a map of basement relief In the second
case often described as continuous methods areas of data containing a number of anomalies are interpreted
statistically to produce direct output of basement depths
The discrete methods usually involve a semiautomatic initial phase which generates a large number of possible
depth solutions and an interactive second phase to screen and select acceptable solutions The advantage of this
approach is that the interpreter can select features that are relatively free from interference from adjacent anomalies
and consider all aspects of a particular magnetic anomaly The disadvantage is that interpretation can be very time
consuming as a wide range of depths are usually possible depending on the initial model chosen and a significant
amount of effort is needed to select the correct model In the case of the Savory Sub-basin dataset we encountered
problems in separating basement related effects from the effects of shallower intrasedimentary magnetic sources
Because of these problems we have concentrated on displaying the Euler results accompanied by separation filter
images of the data to show the shallower effects and deeper effects rather than trying to refine a 3D Euler
deconvolution depth-to-crystalline-basement contour
The continuous methods are very direct provided that the rather restrictive assumption can be made that all
anomalies are due to lateral magnetization changes due to basement topography This means that shallow effects and
large intrabasement anomalies must be removed from the data This involves judgement and skill as it is necessary to
distinguish between the lower amplitude suprabasement anomalies due to basement topography and the larger
intrabasement anomalies reflecting magnetization changes within the basement These methods were not considered
suitable for the Savory Sub-basin magnetic dataset but were used to invert the gravity data
50
Limitations of magnetic and gravity interpretation
Interpretation of the area is limited by a shortage of information on the nature and physical properties of the deeper
sedimentary sequence and the underlying basement rocks However using techniques such as cross-correlation of
gravity and pseudo-gravity data it is possible to try to differentiate between anomalies relating to basement and those
related to the sedimentary sequence
Gravity anomalies reflect changes within the sedimentary sequence as well as basement condition These
changes in density of sedimentary rocks produce gravity anomalies without a corresponding magnetic anomaly hence
the complementary nature of gravity and magnetic surveys The main use of magnetics is to determine depth to
magnetic basement and any intra-sedimentary volcanic rocks or intrusives whereas gravity provides much more
general information on the sedimentary sequence
Unfortunately interpretation of gravity anomalies is complicated since they can be due to a number of geological
features including
bull major basement faults
bull basement highs
bull igneous intrusions within the basement
bull sedimentary basins which may or may not be isostatically compensated
bull intra-sedimentary volcanics and associated plutonic centres
Two major problems affect the interpretation of both magnetic and gravity data
1 The inherent ambiguity of potential-field data There is no unique solution to any measured gravity or magnetic
anomaly and theoretically there will be an infinite number of source geometry and magnetizationdensity
combinations which will fit the observed data This means that any a priori information which helps to select a
suitable model is very useful
2 Measured anomalies are the summation of effects from different depths For example an observed gravity profile
may contain contributions from shallow sources (density variations within the sedimentary basin) intermediate
depth sources (density variations due to large igneous intrusions within the basement) and deep sources (crustal
thinning producing a mantle anomaly) Separation of these component responses is the regionalresidual problem
which we solve using spectral analysis and differential upward continuation-based separation filtering
Regional setting and interpretation overview
The area studied includes parts of BALFOUR DOWNS (SF51-9) RUDALL (SF51-10) ROBERTSON (SF51-13) GUNANYA
(SF51-14) COLLIER (SG50-4) BULLEN (SG51-1) TRAINOR (SG51-2) MADLEY (SG51-3) NABBERU (SG50-5)
STANLEY (SG51-6) and HERBERT (SG51-7) 1250 000 sheets Broadly the area lies between latitudes 22deg00rsquondash25deg30rsquoS
and longitudes 119deg30rsquondash123deg30rsquoE
51
Regional gravity
The AGSO regional gravity data (at nominal 11 km spacing) was gridded at a 4 km mesh spacing using a minimum-
curvature algorithm Bouguer gravity values in the area are negative reflecting mass deficiency at depth and range
from -84 mgals to -25 mgals
A Bouguer gravity colour image is shown as Figure 41 A residual grid was produced by removing a fifth-order
orthogonal polynomial from the Bouguer data but did not add to the interpretation
120deg 121deg 122deg 123deg
23deg
24deg
25deg
-25
-84
50 km
MKS46 180598
mgal
Figure 41 Regional Bouguer gravity (BMRAGSO data) gridded at 4 km
52
The data show a complex pattern of positive and negative anomalies with no clearly defined trends Correlations
with aeromagnetic data and known basin structures are poor A vague north-northwest linear trend appears to coincide
with the Marloo Fault (Figure 42) A prominent negative anomaly appears to coincide with the Blake Fold and Fault
Belt depocentre and continues as a narrower negative anomaly to the east until it widens out again near the edge of the
basin Elsewhere the gravity data show little correlation with known basin structures and it is likely that especially in
the north of the area gravity anomalies are due to density changes in the basement rather than changes in basement
topography
Production of wavelength-filtered residual gravity plots and vertical gradient plots showed very patchy aliased
data reflecting poor sampling in much of the area
Regional magnetics
The AGSO regional aeromagnetic data were gridded at a 400 m mesh spacing using a minimum-curvature algorithm
(Figure 43) Most of the data has a line spacing of 1600 m with small areas of 1 km spacing The quality of the data is
acceptable for regional interpretation but is not adequate for detailed analysis The accuracy of the flight path is rather
variable reflecting the vintage of the data and the noise envelope of the data is poor by modern standards Problems
were also encountered in joining different map sheets
The magnetic anomaly pattern over the south and west part of the area shows a strong high frequency signature
reflecting the presence of widespread basic sills and dykes Some of the major north-northeasterly trending dykes can
be traced over considerable distances
Discontinuous high-frequency anomalies extend as a northwest-trending zone through the centre of the area and
this zone includes a conspicuous circular magnetic anomaly which is probably a ring complex
The northern and eastern parts of the area are characterized by long-wavelength deep-seated basement magnetic
anomalies with 120deg and 150deg trends dominant The Marloo and Perentie Faults (Figure 42) appear as distinct linear
zones and offsets A prominent easterly trending negative anomaly in the northwest of the area appears to swing round
to the southeast and may separate different basement blocks One possible interpretation is that this very deep seated
anomaly separates areas of Archaean and Proterozoic basement
Regional geology
The regional geology is described in Williams (1992) The GSWA provided a digitized version of Plate 2 from this
Bulletin the structural interpretation map to use as an overlay (Figure 42)
53
Pp
Pp
PSd
PSd
PSd
PSd
PSd
PSo
PSt
PSt
PSf
PSf
PSf
PSb
PSb
PSb
PSsPSs
PSs
PSb
PSm
PSp
PSc
PSc
PSw
PSw
PSw
PSg
PSr
PSj
PSg
PM
Pk
PY
PY
PSd
L
L
L
L
L
L
L
LL
L
L
L
LL
L
LL
L L
LL
L L
L
L
L
L
L
L
L
LL
L
L
BLAKEDEPOCENTRE
MA
RLO
O
FAU
LT
PERENTIEFAULT
50 km
MKS39120598
120deg 121deg 122deg 123deg
25deg
24deg
23deg
Approximate boundaryof aeromagnetic interpretation
PML
PSgL
PSjL
PML
PSpL
PML
PML
PSfL
PSfL
PSpL
LPc
LPcLPcPSrL
LPA
Durba Sandstone
Woora Woora Formation
McFadden Formation
Tchukardine Formation
Boondawari Formation
Skates Hills Formation
Mundadjini Formation
Coondra Formation
Spearhole Formation
Watch Point Formation
Jilyili Formation
Brassey Range Formation
Glass Spring Formation
Paterson Formation
Yeneena Group
Karara Formation
Cornelia Formation
Kahrban Subgroup
Bangemall Group
Fault
Formation boundary
PSdL
PSoL
PSfL
PStL
PSbL
PSsL
PSmL
PScL
PSpL
PSwL
PSjL
PSrL
PSgL
Pp
PYL
PkL
LPc
LPA
PML
Savory Group Other Units
PYL
Figure 42 Regional geology and structure map (after Williams 1992)
54
120deg 121deg 122deg 123deg
23deg
24deg
25deg
5820
3750
MKS47 180598
nT
50 km
Figure 43 Regional aeromagnetic data total magnetic intensity (BMRAGSO data) gridded at 400 m
Analysis
3D analysis
3D Euler deconvolution was used as the primary depth-determination method The advantage of this approach is that
consistent solutions can be obtained over the entire area with minimal assumptions about source geometries Euler
deconvolution of gridded data is used for positional information and estimation of depth to top of source Euler
55
deconvolution yields a large number of depth solutions which have to be screened to reject spurious solutions Results
are plotted as circles in eight depth ranges with radius proportional to depth and colour coded
The 400 m total magnetic intensity grid was used for the analysis Horizontal gradients in x and y and the vertical
gradient were calculated 3D Euler deconvolution was tested on the 400 m gridded data using windows of 9 times 9 and
11 times 11 and 16 times 16 data points and structural indices 05 (fault) and 10 (sill or dyke) It was concluded that the
16 times 16 window produced the best results overall and final plots were produced for the 16 times 16 window and structural
index 05 (Fig 44) Results were very good over the northern and central parts of the area showing magnetic sources
Figure 44 Depth to magnetic source 3D Euler deconvolution 16 times 16 window of 400 m gridded data structural index 05
56
at several different levels Unfortunately in the extreme south of the area shallow intrasedimentary magnetic sources
(sills and dykes) dominated the inversion and the results contained few basement solutions
In order to reduce these problems the 400 m gridded data were filtered using a separation filter based on
interpretation of the log-energy spectrum The 3D Euler method was run on the filtered data in order to generate more
basement-depth solutions Results for the deep-separation filter data were gridded and presented as a colour image in
Cowan (1995) Attempts to grid the Euler output were unsatisfactory and it is considered safer to interpret the 3D
Euler depth plots The 3D Euler depth results from the separation-filter run should be analysed with care as perfect
separation of the basement can never be achieved and there will always be some contamination from sources at
different levels
The results of original total magnetic intensity 3D Euler depth estimation for structural index 05 using a 16 point
window have been plotted at 1500 000 scale (not included in this publication but available in Cowan (1995) from the
GSWA Library as S10331) and as reduced A4 colour circle plots (Figure 44)
The results of deep-basement 3D Euler depth estimation for structural index 05 using a 16 point window have
been plotted as a colour image at 1500 000 scale and as an A4 image (not included in this publication)
2D analysis
Two equispaced profiles were interpolated with a 50 m station interval from the AGSO-located data profiles for the
BULLEN 1250 000 sheet The interpolated profiles were analysed using 2D Euler deconvolution and Werner
deconvolution Results are included in Cowan (1995) and show the use of these methods for more detailed analysis
Filtered data
In order to reconcile 3D Euler results from shallow basement and intrasedimentary magnetic sources we produced
several separation-filtered maps and images We found the shallow-layer double-separation filter (Figure 45) to be
very effective for shallow sources and the deep-layer standard-separation filter (Figure 46) for the basement layer
Gravity and magnetic data correlation
Both lsquoreduced to the polersquo (RTP) magnetics (Figure 47) and pseudo-gravity data (Figure 48) were produced as part of
the reconciliation of gravity and magnetic signatures In both cases the filtering operations assumed magnetization by
induction in the present Earths field The RTP data are fairly similar to the total magnetic intensity The pseudo-
57
gravity data are dominated by a northwest-trending strong positive anomaly and there is little correlation with the
Bouguer gravity data
The poor magneticgravity correlation is confirmed by cross-correlation of the RTP magnetics and the gravity
gradient The correlation plot in Figure 49 shows little coherent response with numerous zones of positive and
negative correlation
Figure 45 Regional aeromagnetic data shallow layer separation filter (BMRAGSO data) gridded at 400 m
Results
In the north and east of the area on the Wells Foreland Sub-basin trend (refer to Figure 1 main text) we see a range
of quite deep 3D Euler depths and several trend directions with north-northwesterly dominant There are relatively few
shallow intrasedimentary solutions in this zone
The second area of deep 3D Euler solutions lies over the Blake depocentre (Figure 43) with several trend
directions
Elsewhere the 3D Euler results are dominated by shallow intrasedimentary depth solutions reflecting mainly the
dolerite sills dykes and the ring complex However where we do see basement-related solutions in the south and
west of the area they appear to be shallower than those noted for the Wells Foreland Sub-basin and the Blake
depocentre
58
Figure 46 Regional aeromagnetic data deep-layer separation filter (BMRAGSO data) gridded at 400 m
Figure 48 Regional aeromagnetic data pseudo-gravity transform (BMRAGSO data) gridded at 400 m
Figure 47 Regional aeromagnetic data reduced-to-pole (BMRAGSO data) gridded at 400 m
Figure 49 Regional aeromagnetic and gravity data gravitymagnetic correlation using RTP magnetics and gravity gradient (BMRAGSO data) gridded at 4 km
59
This subdivision of the area into two zones of deep solutions is consistent with interpreted depocentres
However the interference between sources at different levels and the complexity of the magnetic response of the
basement rocks precludes more refined interpretation at this stage
The area of deep 3D Euler solutions over the Blake depocentre correlates with the pronounced negative gravity
anomaly discussed in the gravity interpretation section Using a density contrast of -015 gcc the negative gravity
anomaly could indicate up to 6ndash8 km of low-density sedimentary rocks depending on assumptions about the regional
field
The area of deep 3D Euler solutions over the Wells Foreland Sub-basin has a complex gravity expression and no
clear basin structure emerges from inversion of these data As noted previously it is likely that observed gravity
anomalies reflect contrasts in basement density rather than basement topography
Separation filtering applied to the magnetic data helps to enhance the intrasedimentary magnetic signature and to
give a better impression of the basement magnetic signature even though separation of the basement response is not
perfect
Conclusions
Quantitative aeromagnetic interpretation using 3D Euler deconvolution supported by wavenumber filtering and image
processing has been successful in providing structural trend and depth information for the Savory Sub-basin
Quantitative magnetic interpretation has revealed two zones of relatively deep magnetic basement beneath the
Wells Foreland Sub-basin and the Blake depocentre
This analysis of the magnetic data supports interpreted depocentres but the complexity of the basement magnetic
signature and interference from sources at different depths precludes further refinement to a map of basement
topography
Regional gravity proved to be very useful in understanding the regional setting of the area and in providing
support for aspects of the interpretation The gravity data support the interpretation of the Blake depocentre
suggesting up to 6ndash8 km of low-density sedimentary rocks
The deep structure of the Savory Sub-basin area is obviously complex with different areas underlain by
Archaean and Proterozoic basement and with the Capricorn suture occurring in the centre of the area
60
Recommendations
The quantitative magnetic interpretation needs to be reconciled with geological models available for the area
In particular the zones tentatively identified as areas with thick sedimentary rocks the Wells Foreland Sub-
basin and the Blake depocentre need to be investigated
Cross sections should be prepared across the basin for joint magneticgravity modelling especially for the Blake
depocentre It is important to be able to explain the strong negative gravity anomaly in this area
In view of the effects of basement density contrasts on the gravity field for the northern part of the area we think
that additional gravity interpretation and acquisition of new gravity data may not be justified as they will not
contribute significantly to understanding basin evolution and structure
It is recommended that GSWA try to get access to company confidential high-resolution aeromagnetic data
rather than flying new surveys The GSWA might offer to fund flying of new infill areas as a bargaining point
References
The original text of this report by Cowan (1995) and 1500 000 scale maps are filed in the GSWA Library under
S10331
COWAN D 1995 Savory Basin quantitative magnetic interpretation Western Australia Geological Survey S-series
S10331 (unpublished)
VACQUIER V STEENLAND N C HENDERSON R G and ZIETZ I 1951 Interpretation of aeromagnetic
maps The Geological Society of America Memoir 47 151p
WILLIAMS I R 1992 Geology of the Savory Basin Western Australia Western Australia Geological Survey
Bulletin 141 115p
61
Appendix 5
Geochemistry
MKS38 250398
Saturate FractionC12+ GLC
1217
Pr18
Ph
22
31CSR WELL-13 315m Cuttings
Figure 51 Canning Stock Route Well 13 gas chromatograph of extract of auger drill sample
12
17
18
22
31
Pr Ph
LDDH 1 6623m CoreSaturate FractionC12+ GLC
MKS35 240398
Figure 52 Gas chromatograph of extract from core sample at 6623 m LDDH1
62
Table 51 Canning Stock Route Well 13 auger drill samples
GSWA sample Drill depth (m)(a) Comments
135601 150 At watertable 135602 203 (all samples consist 135603 310 of sand mud and water) 135604 315 At total depth
NOTE (a) Datum for drill depth is the top of sediment fill in the well which is 155 m below ground level (ie the total depth of 315 m is 47 m below ground level)
Table 52 Canning Stock Route Well 13 gas chromatography data for 315 m depth sediment sample
Parameter Value
Weight of rock extracted (grams) 945 Total extract (ppm) 519 n-Alkane distribution n-C12 07 n-C13 23 n-C14 26 n-C15 22 n-C16 19 n-C17 14 i-C19 23 n-C18 14 i-C20 08 n-C19 11 n-C20 16 n-C21 25 n-C22 29 n-C23 70 n-C24 42 n-C25 95 n-C26 43 n-C27 83 n-C28 38 n-C29 87 n-C30 31 n-C31 273 Alkane compositional data Pristane phytane ratio 279 Pristane n-C17 ratio 161 Phytane n-C18 ratio 059 CPI (1)(a) 284 CPI (2) 209 (C21 + C22) (C28 + C29) 043
NOTE (a) CPI= Carbon preference index
63
Table 53 LDDH1 extract liquid chromatography data for 6623 m concentration
Rock extracted Total extract (grams) (ppm)
702 313
NOTE ppm= parts per million
Table 54 LDDH1 saturate gas chromatography data of core for 6623 m alkane composition
Pristane Pristane Phytane (a) CPI (1) CPI (2) (C21+C22) Phytane n-C17 n-C18 (C28+C29)
103 026 024 103 102 325
NOTE (a)CPI = carbon preference index
Table 55 LDDH1 saturate gas chromatography data of core for 6623 m n-alkane distributions
Parameter Value
n-C12 17 n-C13 38 n-C14 55 n-C15 60 n-C16 65 n-C17 74 i-C19 19 n-C18 78 i-C20 19 n-C19 80 n-C20 79 n-C21 71 n-C22 64 n-C23 57 n-C25 43 n-C24 38 n-C27 31 n-C28 23 n-C29 19 n-C30 12 n-C31 10
64
Appendix 6
Table 61 Summary of data from Trainor waterbores (TWB) and Bullen waterbores (BWB)
Well AMG Elevation TD Status(b) Completion details Water Salinity Water level Flow rate Depth to consolidated AGD84 GL (m) (m) struck mgl(c) (m) (LHr) lithology aquifer(e) Z51(a) Interval (m) (100 mm PVC) (m) (mgl)(d)
TWB 1 473660E 453 122 comp 0ndash75 plain 63 7 300 24 2 880 12 m 7287404N 75ndash93 slotted (9 260) McFadden Fm 93ndash99 plain TWB 2 472 977E 475 23 abd nil 15 m 7285877N Skates Hills Fm dry TWB 3 473259E 475 50 abd nil 7 m 7285849N Skates Hills Fm dry TWB 4 463225 E 445 50 comp 0ndash22 plain 35 7 200 55 3 600 0 m 7286143N 22ndash34 slotted (8 140) Tertiary sand and gravel 23ndash60 plain TWB 5 463095E 445 31 comp 0ndash19 plain 13 26 000 655 3 600 Tertiary sand and gravel 7277721N 19ndash25 slotted (36 700) 25ndash31 plain TWB 6 457013E 455 50 comp 0ndash42 plain 38 920 119 600 0 m 7274352N 42ndash48 slotted (1 030) Cornelia Fm ss TWB 7 453739E 475 26 susp 0ndash2 plain 11 9 300 48 4 500 0 m 7263891N (10 500) Tertiary sand TWB 8 433893E 535 60 susp 0ndash2 plain 47 8 500 gt46 1 200 0 m 7245991N (10 900) Tertiary sand and Brassey Range Fm ss TWB 9 437219E 505 51 comp 0ndash47 plain 45 1 000 58 600 1 m 7235905N 47ndash51 slotted (990) Brassey Range Fm ss TWB 10 434927E 495 32 susp 0ndash2 plain 235 450 120 0 m 7225875N (500) Dolerite
65
BWB 1 287337E 580 122 abd Nil 1 m 7245861N Jilyili Fm dry BWB 2 288346E 545 50 comp 0ndash26 plain 15 630 3 29 000 0 m 7240423N 26ndash38 slotted (730) Tertiary sand and gravel 38ndash50 plain BWB 3 305637E 545 50 abd 19 8 800 43 7 200 0 m 7240423N (10 550) Tertiary ss BWB 4 320167E 515 445 comp 0ndash20 plain 9 980 445 24 000 0 m 7248097N 20ndash32 slotted (1 190) Tertiary ss 32ndash44 plain BWB 5 353393E 545 20 susp 0ndash2 plain 45 (970) 1 m 7238934N Basalt
NOTES (a) GPS accuracy ~ 150 m (b) Comp = completed abd = abandoned susp = suspended (c) Salinity from conductivity (d) Analysis total dissolved solids (e) Fm = Formation ss = sandstone
3
50 km
120deg 121deg30 123deg
25deg
24deg
23deg
22deg
Blake Fault andFold Belt
Wells Foreland S
ub-basin
TrainorPlatform
MKS32200498
HamersleyBasin
PilbaraCraton
YeneenaBasin
YeneenaBasin
YeneenaBasin
CanningBasin
Sylvania Inlier
BangemallBasin
Bangemall Basin
YilgarnCraton
YilgarnCraton
GlengarryBasin
EaraheedyBasin
Ward Inlier
OldhamInlier
KararaBasin
GibsonSub-basin
(Officer Basin)
WestwoodShelf
(Officer Basin)
KingstonShelf
(Officer Basin)
Rudall Complex
Trainor Platform
(Kahrban Subgroup)
Greater Officer Basin
Savory Sub-basin
Surface anticlinesMAP
AREAPerth
Figure 1 Structural subdivisions of the Savory Sub-basin and surface anticlines
4
During 1994 in consultation with the Petroleum Industry the Department of Minerals and
Energy received State Government funding for a Petroleum Exploration Initiative to be
undertaken by the Geological Survey of Western Australia (GSWA) with a view to identifying
prospective onshore areas for oil and gas thus increasing the level of onshore exploration in
Western Australia This initiative was originally funded for the first three years of a five-year work
program Two teams of specialists were formed to investigate the prospectivity of both the western
margin and interior onshore sedimentary basins
The Petroleum Exploration Initiative teams seek to enhance the prospectivity of onshore
basins by reducing through focused investigations the risks perceived by industry to be factors
limiting exploration activity Comprehensive petroleum system reports of the onshore Western
Australian basins are to be completed as a result of the projects undertaken during the five-year
Initiative The objective of the Initiative will be achieved through both the analysis of open-file
exploration data and the acquisition of new data New data will include but not be limited to
geophysical surveys and stratigraphic drilling Project results are to be reported to the industry
through GSWA publications external publications conference reports and oral presentations
This Record is the third in a series of comprehensive reviews by the GSWA of the
hydrocarbon prospectivity of some of Western Australiarsquos interior onshore sedimentary basins
The first Record of this series covered the Canning Basin (Apak and Carlsen 1997) The second
Record reviewed the Western Australian Officer Basin (Perincek 1998) but excluded the Savory
Sub-basin
This study assesses the potential for hydrocarbon exploration within the Savory Sub-basin
based on available geological and geophysical data and defines the scope for future studies
Publications relevant to this investigation but which are not specifically referred to are listed in
Appendix 1
Access and climate
The Savory Sub-basin lies east and southeast of the mining town of Newman in the Pilbara region
(Fig 2) The area is largely uninhabited the only settlement being an outcamp at Poondawari on
the GUNANYA 1250 000 map sheet The outcamp is linked by a graded track to the Jigalong
Community 90 km to the west just outside the northwest margin of the sub-basin A few pastoral
leases lie along the margins of the sub-basin but the majority of the region is Vacant Crown Land
Capitalized names refer to standard map sheets
5
Sealed road
Gravel road
Track
Town
Homestead
Locality
STANLEYSavory Sub-basin boundary 1250 000 map sheet
CornerTrack
Talawana - Windy
Route
Watch Point
NEWMAN
JigalongCommunity
RobertsonRange (abd)
Wokalba
Poondawari
Balfour Downs
Billinnooka
Weelarrana
Beyondie(abd)
Kumarina
Marymia
Glen-ayle
White Lake
Hanging RockBoorabee Hill
WellsRa
EmuRa
Robertson
Ra McFadden R
a
DiebillHills
DurbaHills
Calvert Ra
WardHills
Cornelia Ra
KellyRaBlakeHills
HillsDean
ROBERTSON GUNANYA
TRAINORBULLEN
BALFOUR DOWNS RUDALL
NABBERU STANLEY HERBERT
50 km
Woora Woora Hills
120deg 121deg30 123deg
25deg
24deg
23deg
22deg
Goldfieldsnatural gaspipeline
GR
EA
TN
OR
TH
ER
NH
IGH
WA
Y
Mar
ble
Bar
Nul
lagi
ne-
Rd
MADLEY
Can
ning
Stoc
k
MKS31120598
Goldfields natural gas pipeline
Figure 2 Localities and access routes of the Savory Sub-basin
6
The sealed Great Northern Highway lies west of the Savory Sub-basin and links Meekatharra
to Newman The TalawanandashWindy Corner graded track crosses the northern part of the sub-basin
and graded pastoral station tracks on Balfour Downs Weelarrana Kumarina Marymia and Glen-
Ayle give access to the western and southern margins The Canning Stock Route traverses the sub-
basin from north to south and is a well travelled four-wheel-drive track allowing access to the
eastern half of the sub-basin Additional minor tracks also provide access to other parts of the area
(Williams 1992) Recently flown monochrome aerial photography at 150 000 and Landsat TM
imagery covering the sub-basin is available from the Department of Land Administration
Cross-country access is similar to that in the Canning Basin with the average height of sand
dunes being lower in the Savory Sub-basin Potable water has been found in water bores in the
south of the sub-basin and is inferred to be present throughout the region Fuel and supplies are
available at Wiluna Meekatharra and Newman A good working relationship with the Western
Desert Community who hold native title claims over most of the sub-basin has been established
by GSWA
There are no meteorological stations within the Savory Sub-basin but estimates based on data
from nearby Bureau of Meteorology Stations indicate that the area is arid and has its maximum
rainfall in summer from monsoonal rains The sub-basin has reasonable access and a tolerable
working climate for all exploration activities Meteorological data for the town of Wiluna which
lies about 180 km to the south of the sub-basin are included as Appendix 2
Regional geology
Stratigraphy
Thirteen formations were recognized by Williams (1992) in the Savory Sub-basin and these are
summarized in Table 1 Although unconformities were recognized between some of the
formations and they reflect a wide range of depositional environments provenance and climatic
conditions these formations were defined by Williams (1992) as constituting the Savory Group
Five depositional sequences that are generally unconformity-bounded were recognized by
Williams (1992) (Fig 3) The correlation of significant formations within the sub-basin with other
parts of the Centralian Superbasin is shown in Figure 4 with the four Neoproterozoic
Supersequences having been defined by Walter et al (1995)
7
Durba Ss
McFadden
Woora Woora400
Tchukardine700
Skates Hills
Mundadjini1800
B
Coondra
(B)
Watch Point
Spearhole1100Jilyili
1000(A)
Glass Spring1600(A)
Brassey Range1700(A)
Abs
ent
Absent Absent
Absent
Absent
Absent
A
B
C
D
E
1A
1B
3
4A
4B
1000
2000
3000
4000
5000
6000
Max
imum
thic
knes
s
Sup
erse
quen
ce
AG
EN
EO
PR
OT
ER
OZ
OIC
NE
OP
RO
TE
RO
ZO
ICT
O
CA
MB
RIA
NM
AR
I-N
OA
N
NW SE
Savory Sub-basin Stratigraphy
MKS30 120598
Fault boundary
Unconformity
Disconformity
Conglomerate
Sandstone Mudstone
Siltstone
Evaporite
Dolomite
Boondawari800 Boondawari
Supersequence 2 is not represented in the Savory Sub-basin Total thicknesses are estimated from air photo interpretation Thicknesses of recessive units are unknown
Diamictite
Dep
ositi
onal
seq
uenc
e
Figure 3 Formations lithology and depositional sequences AndashE of the Savory Sub-basin
8
Table 1 Summary of formations in the Savory Sub-basin
Formation Super Depo Lithology Thickness Depositional Savoy Comments Seq(a) Seq(b) (m) environment Group(c)
Durba Sandstone 4 E Quartz sandstone with minor 100 Fluvial lacustrine Y Excellent reservoir basal conglomerate lenses Woora Woora 4 D Medium-grained ferruginous 400 Shallow marine deltaic Y Formation sandstone lithic sandstone quartz wacke siltstone McFadden 4 D Laminated fine- to coarse-grained 1 500 Shallow marine deltaic Y Possible reservoir Formation quartz sandstone feldspathic sandstone quartz wacke minor conglomerate siltstone Tchukardine 4 D Medium- to coarse-grained sandstone 700 Shallow marine Y Formation lithic sandstone quartz wacke conglomerate lenses siltstone minor shale Boondawari 3 C Glacigene diamictite sandstone siltstone Formation shale conglomerate minor dolomite (some stromatolitic and oolitic) rhythmite 800 Glacial shallow marine Y Possible source rock Skates Hills 1 B Thin-bedded dolomite (some stromatolitic) 200 Shallow marine sabkha Y Possible source rock Formation chert evaporites fine- to medium-grained sandstone siltstone shale patchy basal conglomerate Mundadjini 1 B Fine- to coarse-grained sandstone 1 800 Deltaic sabkha Y Possible source rock Formation conglomerate siltstone minor shale shallow marine mudstone dolomite (some stromatolitic) and evaporites Coondra 1 B Coarse- to medium-grained sandstone 1 000 Fan delta Y Possible reservoir Formation poorly sorted conglomerate pebbly sandstone Spearhole 1 B Coarse- to medium-grained sandstone 1 100 Braided fluvial deltaic Y Possible reservoir Formation pebbly sandstone siltstone and oil shows in conglomerate lenses Mundadjini 1 Boondawari 1
9
Watch Point 1 B Shale siltstone fine- to medium-grained 400 Shallow marine deltaic Y Formation sandstone glauconitic sandstone Jilyili Formation 1 A Fine-grained sandstone siltstone minor shale mudstone conglomerate lenses 1 000 Deltaic Y Brassey Range 1 A Fine- to medium-grained sandstone 1 700 Fluvial deltaic Y Formation siltstone shale minor mudstone Glass Spring 1 A Medium- to coarse-grained sandstone 1 600 Shallow marine fluvial Y Formation minor conglomerate and siltstone Tarcunyah Group 1 AampB Quartz sandstone feldspathic sandstone Shallow marine sabkha N Bitumen in LDDH1 quartz wacke shale siltstone fluvial lacustrine conglomerate evaporites dolomite Cornelia 1 A Sandstone siltstone shale mudstone Shallow marine N Overmature source rocks Formation minor glauconitic sandstone deep marine in Trainor 1 Kahrban 1 A Sandstone siltstone shale 1 700 Shallow marine deltaic N Subgroup
NOTES (a) Supersequences of Walter et al (1995) (b) Depositional sequences of Williams (1992) (c) Y= assigned to Savory Group in Williams (1992) N= previously considered to be older than the Savory Group but now included in the greater Officer Basin
10
SAVORY SUB-BASIN GIBSON SUB-BASINCENTRAL OFFICERBASIN
AMADEUS BASIN
PETERMANN RANGES OROGENY
NE
OP
RO
TE
RO
ZO
IC
ST
UR
TIA
NM
AR
INO
AN
ED
IAC
AR
IAN
CAMBRIANTO
NEOPRO-TEROZOIC
AG
E (
Ma)
SOUTHS RANGE MOVEMENT
AREYONGA MOVEMENT
Steptoe
MILES OROGENY
Mission Group
Cassidy Group
Rudall Complex
Bangemall Group
unnamed
Tar
cuny
ah G
roup
4
3
2
1
MKS12a 180598
500
550
600
650
700
750
800
850
900
SU
PE
R
SE
QU
EN
CE
unnamed
Tchukardine Fm
McFadden Fm
ArumberaSst
Julie Fm
Pertatataka Fm
Olympic FmPioneer Sst
Boondawari Fm
Turkey Hill FmLupton Fm
Kanpa Fm
Neale FmBabbagoola
FmHussar
Fm
Browne Fm
Woolnough Fm
Madley Fm
Bitt
er S
prin
gs F
m
LovesCreek M
Gillen M
Heavitree Fm
Arunta Complex
Throssell Group
TownsendQuartzite
Earaheedy Group
olderCornelia Fm
Jilyili Fm
SpearholeFm
MundadjiniFm
Skates Hills Fm
Lefroy Fm
Areyonga Fm
Aralka Fm
ME
SO
-P
RO
TE
RO
ZO
IC
Waters Fm
youngerCornelia Fm
Brassey RangeFormationKahrban
Subgroup
GlassSpring
Fm
Durba Sst
LP1ALP1B EVENT
Figure 4 Correlation of Savory Sub-basin formations with the western Officer and Amadeus Basins Fm = Formation Sst = Sandstone M = Member
11
The depositional sequences recognized in the sub-basin are an order of magnitude thicker than
those described from Phanerozoic passive-margin settings (Payton 1977 Posamentier et al 1988)
and are broadly comparable in scale to the second-order cycles of Vail et al (1977) and to the
megasequences of Hubbard et al (1985) The main subsurface data available to reveal the
unweathered nature of these rocks are Trainor-1 and the three-well diamond coring program in
Petroleum Permit EP 380 (Akubra 1 Boondawari 1 Mundadjini 1) completed in late 1997 in the
central west of the sub-basin (Figs 5 and 6)
The ages of all formations in the Savory Sub-basin are poorly constrained The only fossils
known are stromatolites and palynomorphs (acid-insoluble microfossils) Palynology from
available wells is summarized in Appendix 3 from Grey and Stevens (1997) and Grey and Cotter
(1996) and correlations using stromatolite biostratigraphy (Stevens and Grey 1997 Grey 1995f
Walter et al 1994 1995) are consistent with a Neoproterozoic age for the formations for which
data are available
A dolerite within the Boondawari Formation gave a poorly constrained RbndashSr age of about
640 Ma (Williams 1992) SHRIMP UndashPb dating of sedimentary zircons from the McFadden and
Cornelia Formations in stratigraphic drillhole Trainor 1 are discussed in Stevens and Adamides (in
prep) and Nelson (1997) The youngest ages from these analyses indicate that the maximum age
of the Cornelia Formation is Early Cambrian or Sturtian but these ages are inconsistent with
previous tectonic interpretations (Williams 1992) and current stratigraphic correlations which
suggest the Cornelia Formation is of Supersequence 1 age or older (Fig 4)
Depositional Sequence A Supersequence 1
Depositional Sequence A includes the Glass Spring Jilyili and Brassey Range Formations (Fig
3) All of these units are predominantly quartzose sandstones some of which are friable and have
significant visible porosity in outcrop Conglomerates are present in the Glass Spring and Jilyili
Formations
Depositional Sequence B Supersequence 1
Depositional Sequence B consists of the Watch Point Coondra Mundadjini Spearhole and
Skates Hills Formations (Fig 3) All of these formations contain beds of quartzose sandstone and
some also contain conglomerates The porosity of dolomites in the Skates Hills Formation appears
poor in surface exposures but its subsurface characteristics are unknown
12
50 km
120deg 121deg30 123deg
25deg
24deg
23deg
22deg
Greater Officer Basin
PNCEXP CA11PNCEXP CA12
PNCEXP CA13PNCEXP CA19
PNCEXP CA05
PNCEXP CA09
BD134589
GSWA Trainor 1 and TWB123
Fortescue River 1A
Mundadjini 1
Akubra 1Boondawari 1
TWB4TWB5
TWB6
TWB7
TWB8
TWB9
TWB10
BWB1
BWB2 BWB3
BWB4
BWB5
OD23
Mineral exploration drillhole
Stratigraphic drillhole
Waterbores and wells(TWB and BWB serieswaterbores identified)
MKS33270398
LDDH 1
Savory Sub-basin
Canning SR Well 13
EP380
Petroleum Exploration permit
Petroleum exploration well
Figure 5 Locations of petroleum exploration wells mineral exploration and stratigraphic drillholes water bores and wells and petroleum exploration permit EP380 in the Savory Sub-basin
13
TD=600m
TD=1367m
TD=701m
TD=709m
TD=50m
SS
1S
S1
SS1
SS
1S
S1
SS
1
SS
1
SS1
SS4 SS1
Pha
nero
zoic
or
SS
2
Cz
CzCz
Karst Bitumen
SS1
TD=181m
Mundadjini 1 Akubra 1 Boondawari 1 LDDH 1 Trainor 1 TWB 6
Munda-djini Fm
Spear-hole Fm
Munda-djini Fm
Munda-djini Fm
Spear-hole Fm
Spear-hole Fm
Waters Fm
McFadden Fm
Cornelia Fm
Cornelia Fm
Cornelia Fm
511 plusmn 13Maor 696 plusmn 20Ma(maximum)
779 plusmn 10Ma(maximum)
Mundadjini 1
Akubra 1 Boondawari 1
LDDH 1
Trainor 1TWB 6100 km
N
LOCATION
NW SE
Sea level
0m AHD
Dolerite basalt
Conglomerate
Sandstone
Mudstone
Dolomite
Limestone
Evaporite
TOC gt08
Permeability gt100md
Oil fluorescence
Sedimentary zircon U-Pb age
Identifiable polymorphs
Cainozoic
Supersequence 1 age
Unconformity
Formation contact
Cz
SS1
r
r
0
100
200
metres
VerticalScale
MKS36 120598
LEGEND
Figure 6 Geological cross section through significant drillholes in the Savory Sub-basin
14
Depositional Sequence C Supersequence 3
Depositional Sequence C consists of the Boondawari Formation (Fig 3) and although it contains
sandstone conglomerate and dolomite the sandstones contain significant amounts of feldspar and
clay and hence are likely to be poorer reservoirs than older sandstones
Depositional Sequence D Supersequence 4
Depositional Sequence D includes the McFadden Tchukardine and Woora Woora Formations
(Fig 3) The McFadden Formation is poorly sorted and sandstones contain significant amounts of
feldspathic clasts in the north of the basin but are significantly coarser and cleaner in the northeast
of the sub-basin (Williams 1992)
Sandstones of the Tchukardine and Woora Woora Formations are generally cleaner than those
of the McFadden Formation and are expected to have fair to good porosity although the
Tchukardine Formation has a higher clay content in parts
Depositional Sequence E Supersequence 4
Depositional Sequence E consists of the Durba Sandstone (Fig 3) a coarse sandstone with minor
conglomerate which has good to excellent visible porosity in surface exposures
Other depositional sequences and regional correlations
Sedimentary rocks which were not included in the Savory Group by Williams (1992) but which
are likely to be of Neoproterozoic age and hence part of the greater Officer Basin include the
Tarcunyah Group the Cornelia Formation and the Kahrban Subgroup
As discussed in the Introduction all of the strata in the Karara Basin and the younger strata
of the Yeneena Basin were redefined to form the Tarcunyah Group of the greater Officer Basin
(Bagas et al 1995) (Fig 7) In outcrop the Tarcunyah Group consists predominantly of quartzose
feldspathic and arkosic sandstone shale which is carbonaceous in parts and carbonate which
includes stromatolitic dolomite Mineral hole LDDH1 drilled on GUNANYA intersected the
15
120598
122deg
123deg
21deg
22deg
23deg
24deg
23deg
22deg
21deg
122deg
123deg
Fault
Thrust
Reverse thrust
CANNINGBASIN
OFFICERBASIN
GROUP
PILBARACRATON
TARCUNYAH
SAVORY GROUP
BANGEMALL
GROUP
THROSSELL
GROUP
LAMIL
GROUP
ConnaughtonTerrane
TerraneTalbot
complexTabletop granitic
Tabletop Terrane
Permian
Neoproterozoicgranitoid
50 km
FormationWaltha Woora
McKay Fault
South west Thrust
Vines
Fault
24deg
120deg
YENEENA CANNINGBASIN
ARUNTAINLIERRUDALL
COMPLEX
AMADEUSBASIN
MUSGRAVEBLOCK
OFFICERBASINYILGARN
CRATON
GROUP
GROUP
GROUP
PILBARACRATON
GROUP
EARAHEEDY
GLENGARRY
BANGEMALL
WYLOO GROUP
SAVORY
WA
CARNARVONBASIN
GASCOYNECOMPLEX
GROUPTARCUNYAH
400 kmGROUP
SA
N
T
CamelndashTabletopfault zone
KAHRBANSUBGROUP
CORNELIAFORMATION
MKS37
Figure 7 Regional geological setting of the Savory Group and western Officer Basin The dashed line on the inset map marks the interpreted margin of the greater Officer Basin
16
Tarcunyah Group and consists predominantly of mudstone with minor sandstone limestone
dolomite and anhydrite (Fig 6)
The age of the Tarcunyah Group is uncertain although limited palynological and stromatolite
evidence suggests that it is probably coeval with Supersequence 1 of the Centralian Superbasin
Drillhole LDDH1 contains palynomorphs equivalent to assemblages in the Browne and Bitter
Springs Formations of the Officer and Amadeus Basins respectively and from the Cornelia
Formation in TWB 6 (Grey and Stevens 1997) (Figs 4 and 6) Stromatolite specimens tentatively
assigned to Acaciella australica (Howchin 1914) Walter 1972 occur in the lower Tarcunyah
Group (Bagas et al 1995) The stromatolite Baicalia burra Preiss 1972 and a conical
stromatolite were reported from the upper part of the Tarcunyah Group (Stevens and Grey 1997)
The recognition of two stromatolite assemblages interpreted to have age significance in
Supersequence 1 sedimentary rocks of the Centralian Superbasin has permitted biostratigraphic
correlations between outcrop and well data The Acaciella australica assemblage appears to be
slightly older than 800 Ma and is restricted to the middle part of Supersequence 1 The Baicalia
burra assemblage is considered to be slightly younger than 800 Ma and occurs in the upper part
of Supersequence 1 (Grey 1996b Stevens and Grey 1997) The older A australica assemblage
is recognized in the Skates Hills Formation in the Savory Sub-basin and the stromatolite A
australica itself has been tentatively identified in the lower Tarcunyah Group The occurrence of
the A australica assemblage in the Woolnough Madley and Browne Formations of the Officer
Basin and in the Loves Creek Member of the Bitter Springs Formation of the Amadeus Basin
allows correlations throughout the Centralian Superbasin (Fig 4)
The younger B burra assemblage has not been recognized in sedimentary rocks of the
Savory Group as defined by Williams (1992) but it occurs in the upper parts of the Tarcunyah
Group and allows correlation of this group with outcrops of the Neale Formation and with the
Kanpa Formation in petroleum exploration well Hussar 1 both located in the central Officer Basin
of Western Australia (Fig 4) (Grey 1996b Stevens and Grey 1997) The occurrence of the B
burra assemblage in these units permits their correlation with the Burra Group in the Adelaide
Geosyncline of South Australia (K Grey unpublished data)
The Cornelia Formation and Kahrban Subgroup outcrop in the southeast of the sub-basin and
were considered by Williams (1992) to be part of the Mesoproterozoic Bangemall Basin Limited
evidence suggests that all or parts of these two units are of Neoproterozoic age The Ward and
Oldham Inliers consist of outcrops of the Cornelia Formation Waterbore TWB 6 which was
drilled on TRAINOR in the Cornelia Formation contains palynomorphs consistent with a
Supersequence 1 age (Grey and Stevens 1997) (Figs 5 and 6) In outcrop the Cornelia Formation
17
consists predominantly of sandstone and quartzite with lesser siltstone shale mudstone and chert
In Trainor 1 this formation consists predominantly of indurated mudstone with minor sandstone
chert and dolomite A major erosional unconformity separates the Cornelia Formation from
overlying formations and parts of the Cornelia Formation have been folded with dips exceeding
70deg In contrast the majority of the Savory Sub-basin sedimentary rocks have dips of less than 30deg
except where they are adjacent to faults The Cornelia Formation apparently consists of an older
unit of steeply dipping quartzites cherts and well-indurated mudstones and a younger unit of
shallower dipping sandstones which are sub-friable in parts However caution should be used in
interpreting the age of units based on their structural deformation and additional mapping and age
dating of this formation is required
It is proposed here that the Kahrban Subgroup is likely to be of early Neoproterozoic age and
hence should be considered as part of the greater Officer Basin This proposal is based largely on
the relatively low dip of the strata (generally less than 20deg) and their west-northwest strike which
is parallel with strikes in the overlying Brassey Range Formation of the Savory Group The lower
contact of the Kahrban Subgroup is obscured but is thought to be an unconfirmity on the
Earaheedy Basin on the southeast of STANLEY (Muhling and Brakel 1985)
Structural setting
The Savory Sub-basin forms the most northwesterly sub-basin of the Neoproterozoic to
Phanerozoic Officer Basin The western boundary of the sub-basin with the Mesoproterozoic
Bangemall Basin consists of steep-reverse and strike-slip faults The northeastern boundary of the
Savory Sub-basin was mapped where Supersequence 4 formations of the Savory Group
unconformably overlie sedimentary rocks of the Karara and Yeneena Basins with the two older
units considered to be part of the Paterson Orogen (Williams 1992) This contact was defined as a
series of steeply dipping reverse faults in the northernmost parts of the sub-basin on BALFOUR
DOWNS and RUDALL and was extrapolated as an inferred reverse fault farther along strike to the
southeast on GUNANYA and MADLEY where the contact is obscured by Cainozoic sediments It is
now recognized that all the sedimentary rocks in the Karara Basin and younger sedimentary rocks
of the Yeneena Basin are from the Supersequence 1 Tarcunyah Group and part of the greater
Officer Basin (Bagas et al 1995) The northern boundary of the Tarcunyah Group and the greater
Officer Basin is in thrust-and reverse-faulted contact with the Rudall Complex and other parts of
the Paterson Orogen (Fig 7)
To the south the sub-basin unconformably overlies the Bangemall Basin The eastern
boundary of the sub-basin used in this study is where Permian and younger strata of the Officer
Basin unconformably overlie Neoproterozoic strata although there are no significant structural or
stratigraphic differences between the Neoproterozoic units
18
The sub-basin is subdivided into three principal structural areas (Fig 1) Trainor Platform
Blake Fault and Fold Belt and Wells Foreland Sub-basin (Williams 1992) A major review of
these boundaries is beyond the scope of this report but the processing of regional aeromagnetic
data (Appendix 4) and acquisition of a semi-detailed gravity survey by the GSWA in the east of
the sub-basin has enabled these tectonic units to be reassessed and some modifications are
proposed
The Wells Foreland Sub-basin (originally termed the Wells Foreland Basin in Williams 1992)
and sedimentary rocks of the Tarcunyah Group are both considered to be the northwest
continuation of the Gibson Sub-basin of the Officer Basin Aeromagnetic gravity and outcrop
data suggest that the Blake Fault and Fold Belt is significantly faulted and folded in the west but
is less deformed in the east where the thickest sedimentary section in is located on BULLEN
(Appendix 4) The Trainor Platform is reinterpreted to represent an area of the sub-basin that has
undergone major compression during the Petermann Ranges Orogeny resulting in folding and
faulting with a northwest strike This interpretation contrasts with that proposed by Williams
(1992) who envisaged that only a thin section of the Savory Group was present on the platform
Perincek (1998) has recognized nine periods of tectonic activity in the Officer Basin from the
beginning of the Neoproterozoic to the end of the Cretaceous Three major tectonic episodes are
recognized in the Centralian Superbasin The oldest event is the Areyonga Movement which is
pre-Sturtian and forms the boundary between Supersequences 1 and 2 (Fig 4) The Souths Range
Movement occurred at the end of the Sturtian at the boundary between Supersequences 2 and 3
The youngest major event is the Petermann Ranges Orogeny which occured at the end of the
Marinoan and forms the boundary between Supersequences 3 and 4
One minor and two major tectonic episodes are recognized in the Savory Sub-basin the
LP1ALP1B structural event and the Areyonga Movement and the Petermann Ranges Orogeny
respectively The LP1ALP1B structural event is revealed where the Spearhole Formations rests
disconformably and locally unconformably on the Brassey Range Jilyili and Glass Spring
Formations The Neoproterozoic Areyonga Movement (equivalent to the Blake Movement of
Williams 1992) produced folds and faults with a general northeast strike in the western and
southern parts of the region The Souths Range Movement has not been recognized in the sub-
basin This may be due to the fact that no Sturtian glacial rocks have been identified and hence it
is possible that structures attributed to the Areyonga Movement could be the result of the Souths
Range Movement or a combination of the two movements
The major tectonic event recorded in the sub-basin is the latest Neoproterozoic to Cambrian
Petermann Ranges Orogeny (equivalent to the Paterson Orogeny) which produced large reverse
19
faults thrusts strike-slip faults and folds with a general northwest strike The McFadden
Formation and other Supersequence 4 strata are considered to be at least partially coeval with this
orogeny (Williams 1992) We also interpret the Durba Sandstone as having been deposited during
the later stages of the Petermann Ranges Orogeny as this unit mildly deformed with fold axes
parallel to the strike of other structures attributed to the Petermann Ranges Orogeny
Quantitative aeromagnetic interpretation of the Savory Sub-basin utilizing the 3D Euler
deconvolution method supported by wave-number filtering and image processing has provided
structural trends and depth to magnetic source within the sub-basin (Cowan 1995) Gravity data
are interpreted by Cowan (1995) as changes in both the density of the basement rocks andor
basement topography depending on local conditions Part of Cowanrsquos report is reproduced in
Appendix 4
Exploration history
The only petroleum exploration conducted in the sub-basin has been the recent drilling in the
western part of three diamond drillholes of which two have minor oil shows (Table 2) There has
been some mineral exploration the results of which are stored in the GSWA Western Australian
Mineral Exploration (WAMEX) database system Much of the mineral exploration was in the
southwest and west where the sub-basin is in contact with the Bangemall Basin and along the
northern margin of the sub-basin Many of these mineral exploration programs included
aeromagnetic surveys and surface geochemical sampling (Fig 8)
Hydrocarbon potential
The sub-basin contains a sedimentary succession up to 8 km thick which is generally gently
folded and faulted and apparently unmetamorphosed Limited drilling has shown that thick
mudstones are present in the sub-basin with some mudstones in Trainor 1 having high Total
Organic Carbon (TOC) values Outcrops of sub-friable sandstones in many of the formations
within the sub-basin suggests widespread reservoir potential Mudstone and inferred thick
evaporite sequences are likely to form seals Maturity data suggest that near-surface samples are
approximately at the base of the oil window and top of the gas window in parts of the north and
southeast of the sub-basin However parts of the southwest of the sub-basin and the mudstones in
Trainor 1 have very high levels of maturity Numerous faults and folds have been identified from
surface mapping suggesting good potential for large structural traps Minor oil shows in
20
Table 2 Neoproterozoic formations and hydrocarbon shows in diamond drillholes in the Savory Sub-basin
Drillhole AMG Core TD (m) Approx Formation Depth Formation Depth Formation Depth Shows (AGD84) start (m) GL (m) (m) (m) (m)
LDDH 1 431148E 112 701 350 Tarcunyah 68ndash701 ndash ndash bitumen at 6623 m 7443826N Group Trainor 1 473640E 6 709 455 McFadden 9ndash83 Cornelia Fm 83ndash709 possible bitumen at 4537 m 7287400N Fm Mundadjini 1 319056E 170 600 500 Mundadjini 16ndash361 Spearhole Fm 361ndash600 10 fluorescence at 36102 m 7404844N Fm Boondawari 1 348959E 299 1 367 490 Mundadjini Fm 15ndash312 Spearhole Fm 312ndash1 283 Intrusive 1 283ndash1 367 40 fluorescence at 35364 m 5 7398174N fluorescence at 4963 m Akubra 1 334249E 15 181 530 Mundadjini 15ndash42 Intrusive 42ndash181 None 7401252N Fm
21
50 km
120deg 121deg30 123deg
25deg
24deg
23deg
22deg
Greater Officer Basin
Savory Sub-basin
1
2
3
4
6
8
3 Seismic line (prefixed N83-00)
Aeromagnetic survey
GS
WA
Sav
ory
1995
gra
vity
sur
vey
Gravity survey
MKS34270398
Figure 8 Locations of aeromagnetic and gravity surveys (other than regional BMRAGSO data)
22
sandstones in two petroleum wells in the northwest of the sub-basin and bitumen and oil shows
elsewhere in the region indicate that oil has been generated and migrated through the sub-basin
Source rocks
Source potential is considered to be the major exploration risk in the Savory Sub-basin although
minor oil shows in Mundadjini 1 and Boondawari 1 indicate that at least some oil has been
generated and migrated into potential reservoirs within the sub-basin Sandstone is the
predominant lithology observed in outcrop Outcrops of fine-grained lithologies in the basin are
rare because of intense surface weathering and erosion Only about 8 of the surface area of the
sub-basin is exposed bedrock and recessive lithologies (such as shale evaporite and friable
sandstone) may be present although they rarely outcrop
Outcrops of stromatolitic dolomite with associated cauliflower chert and cubic pseudomorphs
interpreted as being after halite indicate that evaporitic environments are present within the
Mundadjini Skates Hills and Boondawari Formations Evaporitic minerals are also present in
drillhole LDDH1 in the Tarcunyah Group
In 1995 GSWA drilled a continuous-core diamond drillhole (Trainor 1) in the sub-basin on
TRAINOR to a depth of 709 m to test for source rocks thus providing the first such data for the sub-
basin The drillhole intersected flat-lying clastics and carbonates of the McFadden Formation (9ndash
83 m) overlying indurated mudstones of the Cornelia Formation (83ndash709 m total depth) dipping at
about 40deg Of the six samples analysed from the Cornelia Formation in this drillhole the five
located between 375 and 6032 m depth have TOC values exceeding 05 (range 066ndash365)
Rock-Eval pyrolysis of these five samples indicates that they are at best in the dry-gas thermal
stage and as a result of their high level of maturation (Stevens and Adamides in prep) have poor
remaining hydrocarbon-generating potential Although the Cornelia Formation is overmature at
Trainor 1 the high TOC values are encouraging as it is likely that this sequence is less mature
elsewhere in the sub-basin
The Mundadjini Formation contains potential source rocks that comprise marine mudstones
with evaporitic minerals present in parts Thin dark mudstones were intersected in the Mundadjini
Formation in Akubra 1 In Mundadjini 1 and Boondawari 1 however the mudstones appear to be
too oxidized to have source potential
The Boondawari Formation also may be a source rock as it contains black mudstones The
unit is laterally equivalent to the Pertatataka Formation of the Amadeus Basin and the Ungoolya
23
Group of the Officer Basin in South Australia both of which have some source potential
(Summons and Powell 1991 Morton and Drexel 1997) Samples from the Dey Dey Mudstone of
the Ungoolya Group generally have poor TOC values (average 011 range 003ndash081)
moderate hydrogen index (HI) values (100ndash382) and poor to fair genetic potential with a
maximum of 292 kg hydrocarbon per tonne of source rock (Morton and Drexel 1997)
Stromatolitic dolomites and mudstones at the top of the Boondawari Formation and within the
Skates Hills Formation are potential source rocks Stromatolitic dolomite and evaporitic rocks
deposited in a marginal marine to sabkha environment are considered to have good potential to
generate and preserve organic carbon without requiring a deep-water setting (Stevens and Grey
1997) Such conditions are recognized in the Skates Hills Formation and in the upper parts of the
Tarcunyah Group
Maturity
Knowledge of the maturity of sedimentary rocks within the Savory Sub-basin is still limited From
a review of palynological studies Grey and Stevens (1997) report that the thermal maturity
inferred from the Thermal Alteration Index (TAI) of 3+ from Supersequence 1 age palynomorphs
in TWB 6 TWB 9 and LDDH1 is within the hydrocarbon window (Appendix 3) In Phanerozoic
spores and pollen a TAI of 3+ approximately equates to the end of liquid petroleum generation
and the start of dry gas generation and to a vitrinite reflectance of about 13 (Traverse 1988)
However the use of TAI for estimating thermal maturity from Neoproterozoic palynomorphs
requires calibration
In Trainor 1 the Cornelia Formation contains organically rich claystones between 375 and
6032 m depth Based on Rock-Eval maturity data (Stevens and Adamides in prep) and the dark
colour of poorly preserved organic material (Grey 1995de 1996) with TAI 4- to 5 all samples
had a high level of maturation with at best dry-gas generating potential remaining In contrast
drillhole LDDH1 on GUNANYA recorded lower levels of maturity (TAI values of 3+) with two of
sixteen samples from the Tarcunyah Group having greater than 1 TOC (Grey 1995abc Grey
and Cotter 1996) Organic petrology and Rock-Eval maturity data for samples from LDDH1
indicate that the section above 500 m is within the oil-generative window whereas below 500 m
the rocks are within the gas window (Ghori in prep Fig 9 Appendix 5)
Waterbores TWB 1 2 6 and 9 which are located on TRAINOR in the southeast of the sub-
basin all had organic matter with TAI values of 3+ from the McFadden Skates Hills Cornelia
and Brassey Range Formations respectively
24
100
200
300
400
500
600
700
Oil
gene
ratin
g
Gas
gene
ratin
g
Fai
r
Fai
r
Poo
r
Poo
r
Goo
d
Imm
atur
e
Oil
win
dow
Oil
win
dow
Imm
atur
e
01 0110 10 0 150 300 440 480 1
Neo
prot
eroz
oic
TOC S1+S2 mgg Hydrogen Index Tmax degC
Depth(m)
Organicrichness
Generatingpotential
Kerogentype Maturity Maturity
TD=701m
Sandstone
Mudstone
Dolomite
Limestone
Evaporite
Source rock
MKS40 070498
Ro equivalent
Figure 9 Petroleum source potential of rocks in Normandy LDDH1
Small amounts of organic matter associated with basalt and dolerite in cuttings from
waterbore BWB 1 on BULLEN showed high levels of thermal maturity (Grey 1995a Libby 1995)
It is unclear whether all sedimentary rocks on BULLEN are overmature for hydrocarbon generation
or the results from BWB 1 are related to local heating events associated with the volcanic bodies
that are common in the Jilyili Formation
25
Reservoirs
Each of the five depositional sequences of the Savory Group (Table 1) are inferred to contain
significant sandstone reservoirs with the possible exception of depositional sequence C as
discussed above in Stratigraphy The Spearhole Formation was cored in Mundadjini 1 and
Boondawari 1 and visual estimates of porosity vary from generally poor (less than 5) to fair
(approximately 5ndash15) The McFadden Formation in Trainor 1 has porosity values of up to 232
and a maximum permeability of 195 md (Stevens and Adamides in prep) Sandstones from
Neoproterozoic formations form the acquifers in the following waterbores the McFadden
Formation in TWB 1 the Cornelia Formation in TWB 6 and the Brassey Range Formation in
TWB 8 and TWB 9 (Appendix 6 Table 61)
Based on outcrop observations the Durba Sandstone is considered to be the best reservoir of
the Savory Group Similarly some sandstones from the Tarcunyah Group also have good visible
porosity in outcrop
Dolomites occur in several formations in the sub-basin Reservoir potential may exist
particularly where the dolomites are stromatolitic and oolitic However dolomites have not been
drilled in the sub-basin and porosity can only be inferred from the preferential silicification of
some stromatolite bioherms observed in outcrop (Stevens and Grey 1997) Elsewhere in the
Officer Basin porosities of up to10 have been measured in dolomites A limestone breccia
(karst) is described from 663 to 677 m in drillhole LDDH1 (Fig 6 Busbridge 1994)
Seals
Indications of evaporitic environments in the Mundadjini Skates Hills and Boondawari
Formations are described by Williams (1992) In Mundadjini 1 from 287 to 337 m anhydrite and
chert occurs as nodules beds and veins in mudstone of the Mundadjini Formation Evaporitic
minerals (predominantly gypsum) are described in the Tarcunyah Group in LDDH1 The presence
of the Woolnough and Madley salt diapirs in the Officer Basin (approximately 110 km east of the
sub-basin) and halite beds over 25 m thick in the well Hussar 1 (130 km east of the sub-basin)
provide further evidence that evaporite seals may be present in the Savory Sub-basin
Mudstones and shales form only a small proportion of the limited Neoproterozoic outcrop in
the sub-basin but significant thicknesses of mudstone were encountered in the Mundadjini
Formation in Mundadjini 1 and Boondawari 1 the Tarcunyah Group in LDDH1 and in the
26
Cornelia Formation in Trainor 1 These data suggest that mudstones form a significant proportion
of strata in the sub-basin despite their limited outcrop
Traps
Potential structural closures including folds and faults occur at various scales throughout the
Savory Sub-basin However the region has only been mapped at 1250 000 scale and
independently closed structures such as domes have yet to be confirmed The western margin of
the basin contains abundant faults (with a northeast strike) but elsewhere faults are less common
Some anticlines are recognized in outcrop including one with a strike length of up to 45 km
inferred from surface bedding dips in the Mundadjini and Spearhole Formations at approximately
24deg15rsquoS 121deg10rsquoE on BULLEN (Fig 1)
Salt diapirs and other halokinetic structures are recognized in outcrop well and seismic data
in the Officer Basin to the west of the Savory Sub-basin and it is probable that there are
significant thicknesses of evaporitic sedimentary rocks in the sub-basin The gravity field data
suggest there is good potential for salt diapirs and traps related to halokinesis
Although there is potential for stratigraphic traps to be present in the sub-basin insufficient
data are available to assess them
Preservation of hydrocarbons
The range of thermal maturities measured to date and the large periods of time envisaged for
deposition of sediments implies hydrocarbon generation may have occurred a number of times
during the evolution of the Savory Sub-basin Any hydrocarbons that were generated early may
have been trapped in palaeostructures and remigration to younger traps could have taken place
later The Petermann Ranges Orogeny which has been equated with the Paterson Orogeny (Myers
1990) is believed to have occurred in the latest Neoproterozoic to early Cambrian This is the last
major tectonic event recognized in the sub-basin suggesting that it is reasonable to expect that trap
integrity will have been preserved
If the inference of the presence of thick halite beds in the sub-basin is correct the preservation
potential of sub-salt traps should be excellent
27
Reported hydrocarbon shows and oil seep
Amadeus Petroleum recorded minor oil shows in cores from Mundadjini 1 and Boondawari 1 In
Mundadjini 1 at 36102 m (top of the Spearhole Formation) a 3 mm thick zone had 10 moderate
white fluorescence with slow solvent cut This show was in a granular sandstone with visually
estimated porosity of about 10 In Boondawari 1 at 35364 m (within the Spearhole Formation) a
broken surface of sandstone had 40 moderate yellow-white fluorescence with slow solvent cut
Visually estimated porosity is about 5 Because the fluorescing surface was broken during the
drilling process this show could have resulted from contamination A second show occurs in
Boondawari 1 at 4963 m (within the Spearhole Formation) where a 1 cm-thick zone had 5 dull
yellow fluorescence with slow solvent cut in a conglomerate with visually estimated porosity of
about 10 The company intends to further investigate the nature of these occurrences
Minor bitumen is present at 6623 m in drillhole LDDH1 on GUNANYA (Figs 5 and 6) as a
vein in mudstones of the Tarcunyah Group A sample was analysed by gas chromatography
(Ghori in prep) and confirmed that it is natural bitumen (Appendix 5)
Mineral hole OD 23 drilled by Jubilee Gold Mines NL on NABBERU in the Bangemall Basin
immediately to the south of the Savory Sub-basin (Fig 5) encountered bitumen and trace oil in
vugs in dolomite (M Stevens unpublished data) but no further data are available at present
In their popular guide to the Canning Stock Route Gard and Gard (1990 p 218) refer to an
oil seep at Well 13 on TRAINOR (Fig 5) They reported that between 1977 and 1984 lsquonatural oilrsquo
was seen in the well Although the well is now largely filled with sediment four auger drill
samples were collected by the GSWA in 1995 and all four were analysed for oil shows One
sample from 315 m total depth (GSWA sample 135604) yielded just enough extract (519 ppm)
for saturate gas chromatography analysis The gas chromatograph (Appendix 5) shows that the
extract does contain some hydrocarbons probably from recent plant material Because the depth to
the oil was not quoted in Gard and Gard (1990) the hand-augered well may not have been deep
enough to properly test this reported seep
Geological and geophysical databases
Geological and geophysical data available for the Savory Sub-basin are limited The most recently
completed geological maps for the sub-basin were published by the GSWA between 1991 and
1995 (Williams and Tyler 1991 Williams 1992 1995ab)
28
The cores from the five drillholes listed in Table 2 believed to be all of the core available
from the sub-basin are available for inspection at GSWA Mineral exploration reports submitted
to GSWA may be searched using the WAMEX database and open-file reports are available on
microfiche Geophysical data acquired by the mining industry is not required to be filed with
GSWA if acquired over Vacant Crown Land which is the case for much of the sub-basin
Geophysical survey data submitted in mining tenement reports and which extend into Vacant
Crown Land remain confidential to the companies Original regional aeromagnetic and gravity
datasets are available from the Australian Geological Survey Organisation (AGSO)
Data pertinent to oil exploration in the sub-basin such as structural style and salt diapirism
are presented in a review of the hydrocarbon prospectivity of the Officer Basin (Perincek 1998)
Drilling
Significant drillholes in the sub-basin are summarized in Table 2
Petroleum industry data
Amadeus Petroleum drilled three petroleum exploration wells in the central west of the Savory
Sub-basin in late 1997 These wells Mundadjini 1 Boondawari 1 and Akubra 1 were drilled by
continuous diamond coring (Figs 5 and 6) All targeted potential reservoirs within the Spearhole
Formation with the Mundadjini Formation as the proposed seal The wells were located on
structures interpreted from Landsat images and limited geological investigations Both Mundadjini
1 and Boondawari 1 had minor oil shows as discussed above (Reported hydrocarbon shows)
Government data
Stratigraphic drillhole Trainor 1 was drilled by GSWA in 1995 (Stevens and Adamides in prep)
and the main results are discussed above (Source rocks and Maturity)
Mineral industry data
Normandy Exploration drillhole LDDH1 was cored in the Tarcunyah Group to a total depth of
701 m and provided source-rock and maturity data as discussed above
29
Oilmin NL drilled six percussion drillholes (BD 1 3 4 5 8 and 9) through sandstones and
shales in the northern part of the Savory Sub-basin to a maximum depth of 198 m (Fig 5
WAMEX Microfiche File M 26811 I 2610) but only brief geological descriptions are available
Hydrogeological data
Hydrogeological data within the Savory Sub-basin are limited although a long history of water
exploration extends back to the construction of the Canning Stock Route early this century No
detailed geological or wireline logs are available for the older wells along this route A few station
wells have been drilled by various methods on the south and west margins of the basin but data
are unavailable as reports are not required to be filed with the government Depth to watertable
throughout the basin is largely controlled by porosity of the bedrock
The GSWA drilled fifteen waterbores in the winter of 1995 in the southern part of the sub-
basin in preparation for the drilling of Trainor 1 and the proposed Bullen 1 Twelve bores found
water and six of these bores have salinities of less than 1000 mgL (Fig 5 Appendix 6 Table 61)
One waterbore TWB 6 has gamma ray and neutron logs run through PVC casing and these are
available from the GSWA with the digital log data included herein
Seismic data
No geophysical data have been acquired by the petroleum industry in the Savory Sub-basin
Seismic data acquired in the Officer Basin to the east particularly in the Gibson and Yowalga
Sub-basins is pertinent to structural interpretation in the Savory Sub-basin (Perincek 1996a
1998)
Aeromagnetic surveys
Government data
There are over 95 277 line kilometres of aeromagnetic data included in the AGSO dataset There
are three regional aeromagnetic surveys covering the Savory Sub-basin These were flown by the
Bureau of Mineral Resources (BMR now AGSO) in 1984 at a line spacing of 1500 m with 36 740
and 52 587 line kilometres flown and by Aerodata in 1984 at a line spacing of 1000m with 5950
line kilometres flown These data were reprocessed and interpreted for GSWA by Cowan (1995)
An edited copy of this report is included as Appendix 4 and the original report is filed in the
GSWA Library under S-series reports item 10331
30
Mineral industry data
The approximate locations of non-AGSO aeromagnetic surveys are shown in Figure 8 More
detailed information regarding the location of these surveys may be obtained using the GSWA
MAGCAT II database Additional information such as contours of aeromagnetic values may be
obtained by inspecting items on file with the GSWA
Gravity surveys
Government data
The average spacing for gravity data in the Savory Sub-basin is one station per 121 km2 (11 times 11
km grid) These data were principally collected by BMR in the early 1960s There are a few
additional regional gravity traverses across the sub-basin which are also included in the
BMRAGSO dataset These data were reprocessed and interpreted for GSWA (Fig 10) and a
report on this work is also included in Appendix 4
The GSWA completed a large semi-detailed gravity survey in the eastern Savory Sub-basin
utilizing helicopter support and Differential Global Positioning Survey (DGPS) techniques (Fig
8) This gravity survey completed in August 1995 consists of 2300 gravity stations on a 2 times 3 km
grid All stations were acquired by helicopter using Scintrex gravimeters and Ashtek dual
frequency DGPS equipment for determining location This highly efficient system allowed the
acquisition of more than 100 gravity stations per day in remote areas The resolution of this survey
is +30 cm and +05 microms-2 (Daishsat 1995) These data (Fig 11) represent a significant
improvement on the previous regional survey data and are available from GSWA (GSWA
1996ab) The results of the interpretation of these data were presented at the 1997 ASEG
Convention (Carlsen and Shevchenko 1997)
Mineral industry data
Three small gravity surveys were conducted by Oilmin NL (Fig 8) and the relevant WAMEX
reports are M 2681I 2610 I 2435 I 2567 These three surveys are of limited value because height
control was provided by barometers only and the surveys were not tied to the national gravity grid
31
23deg
25deg
120deg 122deg
Trainor 1
SAVORY
SUB-BASIN
MKS54 160498
100 km
1995 SavoryGravity Survey
254
-1056
micromsec2
Figure 10 Regional Bouguer gravity map of the Savory Sub-basin
23deg
24deg
25deg
122deg30 123deg
TRAINOR 1
123deg30
50 km
MKS53 160498
-116
-626
micro msec2
Figure11 Detailed Bouguer gravity map of the
Savory 1995 Gravity Survey from the eastern Savory Sub-basin
32
Government and academic reports
Chronostratigraphy and geochemistry
The understanding of Neoproterozoic organic chemistry palynology and structural evolution is
essential to the interpretation of hydrocarbon prospectivity Pertinent reports are included in the
bibliography (Appendix 1) Unpublished palaeontology reports describe the palynology of wells in
the Savory Sub-basin (Grey 1995andashe 1996a) Grey and Cotter (1996) discussed the potential for
Neoproterozoic palynomorphs to provide a biostratigraphic framework and palaeoenvironmental
interpretation Grey and Stevens (1997) reviewed the results of palynological studies of wells
drilled in the sub-basin and reported that Supersequence 1 palynomorphs are present in TWB 6
TWB 9 and LDDH1 (Appendix 3) Grey (1996b) reported on the use of stromatolites for
correlation in the Neoproterozoic and Stevens and Grey (1997) discussed the application of
stromatolite biostratigraphy in correlating isolated dolomite outcrops in the sub-basin with well
and seismic data in the Officer Basin and Centralian Superbasin
Although geochemical data from the Savory Sub-basin are very limited results mostly
confirm thermal maturities inferred from TAI for LDDH1 and Trainor 1 (Ghori in prep Stevens
and Adamides in prep) Those parts of the Officer Basin in Western Australia which lie to the
east of the Savory Sub-basin are sparsely drilled but Ghori (in prep) reports that most of the
Neoproterozoic succession presently lies within the oil-generative window However his study
has been unable to identify effective source-rock units and the source for oil shows Thin source
rocks are present in the Neoproterozoic in LDDH1 (Fig 9) and in three wells which lie to the east
and southeast of the Savory Sub-basin namely NJD 1 Kanpa 1A and Yowalga 3
Proposed work program
From the above limited information it is concluded that additional research on the hydrocarbon
potential of the sub-basin is justified and proposals are outlined below
bull Additional modelling of gravity and aeromagnetic data from the Savory Sub-basin is required
in light of the results from Trainor 1 and Boondawari 1 Trainor 1 showed that what appeared
to be a structurally simple area based on outcrop aeromagnetic and gravity data was in fact an
area of major structuring Boondawari 1 intersected a dolerite which is in good depth
agreement with aeromagnetic depth to source results showing this technique is useful in
detecting the depth to intrusive bodies
33
bull Additional data from mineral and petroleum exploration bores may become available and
analysis of samples from these wells should be undertaken and interpreted in the context of
their relevance to the Officer Basin
bull Stratigraphic coring in the Blake Fault and Fold Belt and in the Wells Foreland Sub-basin (Fig
1) targeting source rocks is considered essential to the continuing evaluation of the
hydrocarbon prospectivity of the Savory Sub-basin
bull Correlations using at least outcrop well and potential-field data should be prepared to link the
sub-basin with the better known parts of the Officer Basin to the east
bull Remapping is required to clarify boundary positions within the Cornelia Formation this may
resolve some of the current problems of the relationship between this unit and the rest of the
Savory Sub-basin
bull Further work is required to explain the Early Cambrian or Sturtian ages interpreted for the
Cornelia Formation from sedimentary zircon UndashPb dating in drillhole Trainor 1 The
determination of the age of the organically rich but overmature claystones in this well is
critical to assessing the hydrocarbon potential of the region
bull The thin dark mudstones intersected by Akubra 1 in the Mundadjini Formation warrant
geochemical analysis Analyses of the oil shows in Mundadjini 1 and Boondawari 1 are
currently being undertaken by Amadeus Petroleum
bull Geochemical analysis of hydrocarbons in the Bangemall Basin drillhole OD23 has been
performed by Jubilee Gold and the results will be reviewed when they are submitted to
GSWA The possibility of source rocks within the Bangemall Basin charging traps within the
Bangemall Basin and the overlying Savory Sub-basin requires further investigation
Conclusions
The Savory Sub-basin is a frontier region with only three recently drilled petroleum exploration
wells and no seismic data Based on existing geological and geophysical data it is considered too
early to draw conclusions about the hydrocarbon prospectivity of the sub-basin at this stage and
there are several reasons why the area warrants further investigation
34
1 Thick accumulations of sedimentary rocks are present (up to 8 km thickness inferred) which
may contain source reservoir and sealing strata
2 Minor oil shows occur in Mundadjini 1 and Boondawari 1 and bitumen is present in mineral
exploration drillhole LDDH1 suggesting that hydrocarbons have migrated within the
Neoproterozoic sequence of the Savory Sub-basin Oil and bitumen are present in mineral
exploration drillhole OD23 in the Bangemall Basin immediately to the south of the Savory
Sub-basin and it is possible that source rocks from the Bangemall Basin could charge traps in
the overlying Savory Sub-basin
3 The age of sedimentary rocks in the sub-basin is still poorly constrained but some of the
Neoproterozoic sedimentary rocks located on GUNANYA and TRAINOR are within the
hydrocarbon-generation window It is possible that a significant thickness of Phanerozoic
sedimentary rocks may also be present
4 Friable sandstones with visible porosity outcrop extensively suggesting numerous potential
reservoirs
5 Significant but not intense faulting and folding has been mapped implying large structural
traps may be present
6 Evaporitic sedimentary rocks occur in several formations and may provide good source rocks
and excellent seals
35
References
APAK S N and CARLSEN G M 1997 A compilation and review of data pertaining to the
hydrocarbon prospectivity of the Canning Basin Western Australia Geological Survey
Record 199610 103p
BAGAS L GREY K and WILLIAMS I R 1995 Reappraisal of the Paterson Orogen and
Savory Basin Western Australia Geological Survey Annual Review 1994ndash95 p 55ndash63
BUSBRIDGE M 1994 Lake Disappointment Exploration Licence 451064 Third Annual
Report Lake Disappointment Diamond Drill Hole LDDH1 Normandy Exploration Limited
Western Australia Geological Survey M-series Item 7567 A41358 (unpublished)
CARLSEN G M and SHEVCHENKO S I 1997 Petroleum exploration in Proterozoic basins
using potential fields data and stratigraphic coring Australian Society of Exploration
Geophysicists 12th Geophysical Conference Handbook Sydney 1997 Preview no 66 p 83
(abstract only)
COWAN D 1995 Savory Basin quantitative magnetic interpretation Western Australia
Geological Survey S-series S10331 (unpublished)
DAISHSAT PTY LTD 1995 Operational and processing report Savory Basin gravity survey
Western Australia Geological Survey S-series S10332 (unpublished)
GARD E and GARD R 1990 Canning Stock Route a travellerrsquos guide for a journey through
history Perth Western Australia Western Desert Guides 448p
GEOLOGICAL SURVEY OF WESTERN AUSTRALIA 1996a Savory Basin first vertical
derivative of Bouguer gravity image 1250 000 Western Australia Geological Survey
GEOLOGICAL SURVEY OF WESTERN AUSTRALIA 1996b Savory Basin Bouguer gravity
image 1250 000 Western Australia Geological Survey
GHORI K A R in prep Petroleum source rock potential and thermal history Officer Basin
Western Australia Western Australia Geological Survey Record
36
GREY K 1995a Savory Basin drillhole BWB 1 (Bullen waterbore) palynology and thermal
maturation GSWA Palaeontology Report no 199512 (unpublished)
GREY K 1995b Savory Basin drillholes TWB 1 2 6 9 (Trainor waterbores) palynology and
thermal maturation GSWA Palaeontology Report no 199520 (unpublished)
GREY K 1995c Palynology of Normandy-Poseidon Lake Disappointment-1 corehole
Tarcunyah Group Paterson Orogen GSWA Palaeontology Report no 199521 (unpublished)
GREY K 1995d Savory Basin drillhole Trainor 1 (Trainor diamond drilling) palynology and
thermal maturity GSWA Palaeontology Report no 199524 (unpublished)
GREY K 1995e Savory Basin drillhole Trainor 1 (Trainor diamond drilling) Additional
Preparation of two samples GSWA Palaeontology Report no 199528 (unpublished)
GREY K 1995f Neoproterozoic stromatolites from the Skates Hills Formation Savory Basin
Western Australia and a review of the distribution of Acaciella australica Australian Journal
of Earth Sciences v 42 p 123ndash132
GREY K 1996a Savory Basin drillhole Trainor 1 (Trainor diamond drilling) Additional
samples palynology and thermal maturation GSWA Palaeontology Report no 199615
(unpublished)
GREY K 1996b Preliminary stromatolite correlations for the Neoproterozoic of the Officer
Basin and a review of Australia-wide correlations GSWA Palaeontology Report no 199615
(unpublished)
GREY K and COTTER K L 1996 Palynology in the search for Proterozoic hydrocarbons
Western Australia Geological Survey Annual Review for 1995ndash96 p 70ndash80
GREY K and STEVENS M K 1997 Neoproterozoic palynomorphs of the Savory Sub-basin
Western Australia and their relevance to petroleum exploration Western Australia
Geological Survey Annual Review for 1996ndash97 p 49ndash54
HUBBARD R J PAPE J and ROBERTS D G 1985 Depositional sequence mapping as a
technique to establish tectonic and stratigraphic framework and evaluate hydrocarbon
potential on a passive continental margin in Seismic stratigraphy II an integrated approach
37
edited by O R BERG and D G WOOLVERTON American Association of Petroleum
Geologists Memoir 39 p 79ndash91
LIBBY WG 1995 A petrological report on six samples of bore cuttings from the Savory Basin
Western Australia Western Australia Geological Survey S-series S31307 (unpublished)
MORTON JGG and DREXEL JF 1997 The petroleum geology of South Australia Vol 3
Officer Basin South Australia Department of Mines and Energy Resources Report Book
9719
MUHLING P C and BRAKEL A T 1985 Geology of the Bangemall Group mdash the evolution
of an intracratonic Proterozoic basin Western Australia Geological Survey Bulletin 128
219p
MYERS J S 1990 Precambrian tectonic evolution of part of Gondwana southwestern Australia
Geology v18 p 537ndash540
NELSON D R 1997 Compilation of SHRIMP UndashPb zircon data Western Australia Geological
Survey Record 19972 196p
PAYTON C E 1977 Seismic stratigraphy mdash applications to hydrocarbon exploration
American Association of Petroleum Geologists Memoir 26 516p
PERINCEK D 1996a The age of NeoproterozoicndashPalaeozoic sediments within the Officer Basin
of the Centralian Super-basin can be constrained by major sequence-bounding unconformities
APPEA Journal v 36 pt 1 p 350ndash368
PERINCEK D 1996b The stratigraphic and structural development of the Officer Basin
Western Australia a review Western Australia Geological Survey Annual Review 1995ndash
1996 p 135ndash148
PERINCEK D 1998 A compilation and review of data pertaining to the hydrocarbon
prospectivity of the Officer Basin Western Australia Geological Survey Record 19976
POSAMENTIER H W JERSEY M T and VAIL P R 1988 Eustatic controls on clastic
deposition 1 mdash Conceptual framework in Sea-level changes an integrated approach edited by
C K WILGUS B S HASTINGS C G St C KENDALL H W POSAMENTIER
38
C A ROSS and J C VAN WAGONER Society of Economic Paleontologists and
Mineralogists Special Publication no 42
STEVENS M K and ADAMIDES N G in prep GSWA Trainor 1 well completion report
Savory Sub-basin Officer Basin Western Australia with notes on petroleum and mineral
potential Western Australia Geological Survey Record 199612
STEVENS M K and GREY K 1997 Skates Hills Formation and Tarcunyah Group Officer
Basin mdash carbonate cycles stratigraphic position and hydrocarbon prospectivity Western
Australia Geological Survey Annual Review for 1996ndash97 p 55ndash60
SUMMONS RE and POWELL C McA 1991 Petroleum source rocks of the Amadeus Basin
in Geological and geophysical studies in the Amadeus Basin central Australia edited by R J
KORSCH and JM KENNARD Australia BMR Geology and Geophysics Bulletin 236
TRAVERSE A 1988 Palaeopalynology Boston Unwin Hyman 600p
VAIL P R MITCHUM R M Jr TODD R G WIDMIER J M THOMPSON S III
SANGREE J B BUBB J N and HATLELID W G 1977 Seismic stratigraphy and
global changes of sea level in Seismic stratigraphy mdash applications to hydrocarbon
exploration edited by C E PAYTON American Association of Petroleum Geologists
Memoir 26 516p
WALTER M R and GORTER J 1994 The Neoproterozoic Centralian Superbasin in Western
Australia the Savory and Officer Basins in The sedimentary basins of Western Australia
edited by P G PURCELL and R R PURCELL Petroleum Exploration Society of Australia
Symposium Perth WA 1994 Proceedings p851ndash864
WALTER M R GREY K WILLIAMS I R and CALVER C R 1994 Stratigraphy of the
Neoproterozoic to early Palaeozoic Savory Basin and correlation with the Amadeus and
Officer Basins Australian Journal of Earth Sciences v 41 p 533ndash546
WALTER M R VEEVERS J J CALVER C R and GREY K 1995 Neoproterozoic
stratigraphy of the Centralian Superbasin Australia Precambrian Research v 73 p 173ndash195
WILLIAMS I R 1992 Geology of the Savory Basin Western Australia Western Australia
Geological Survey Bulletin 141 115p
39
WILLIAMS I R 1995a Bullen WA (2nd Edition) Western Australia Geological Survey
1250 000 Geological Series Explanatory Notes 23p
WILLIAMS I R 1995b Trainor WA (2nd Edition) Western Australia Geological Survey
1250 000 Geological Series Explanatory Notes 31p
WILLIAMS I R and TYLER I M 1991 Robertson WA (2nd edition) Western Australia
Geological Survey 1250 000 Geological Series Explanatory Notes 36p
40
41
Appendix 1
Bibliography
Reports which are relevant to this investigation but which are not specifically cited are listed
below
BAILLIE P W POWELL C McA LI Z X and RYALL A M 1994 The tectonic
framework of Western Australiarsquos Neoproterozoic to recent sedimentary basins in The
sedimentary basins of Western Australia edited by P G PURCELL and R R PURCELL
Petroleum Exploration Society of Australia Symposium Perth WA 1994 Proceedings p
45ndash62
BRADSHAW M T BRADSHAW J MURRAY A P NEEDHAM D J SPENCER L
SUMMONS R E WILMOT J and WINN S 1994 Petroleum systems in West Australian
basins in The sedimentary basins of Western Australia edited by P G PURCELL and R R
PURCELL Petroleum Exploration Society of Australia Symposium Perth WA 1994
Proceedings p 93ndash118
CLARKE G L 1991 Proterozoic tectonic reworking in the Rudall Complex Western Australia
Australian Journal of Earth Science v38 p 31ndash44
COCKBAIN A E and HOCKING R M 1990 Phanerozoic in Geology and mineral resources
of Western Australia Western Australia Geological Survey Memoir 3 p 750ndash755
ETHERIDGE M and WALL V 1994 Tectonic and structural evolution of the Australian
Proterozoic 12th Australian Geological Convention Geological Society of Australia
Abstracts no 37 p 102ndash103
GOODE A D T 1981 Proterozoic geology of Western Australia in Precambrian of the
Southern Hemisphere Developments in Precambrian geology 2 edited by I R HUNTER
Amsterdam Elsevier p 105ndash203
GREY K and JACKSON M J 1983 A re-assessment of stromatolite evidence for the
correlation of the Late Proterozoic Neale and Ilma Beds Officer Basin Western Australia
Australia BMR Journal of Australian Geology and Geophysics v 8 p 359
42
HICKMAN A H WILLIAMS I R and BAGAS L 1994 Proterozoic geology and
mineralization of the TelferndashRudall region Paterson Orogen Geological Society of Australia
(WA Division) Excursion Guidebook no 5 56p
HOCKING R M MORY A J and WILLIAMS I R 1994 An atlas of Neoproterozoic and
Phanerozoic basins of Western Australia in The sedimentary basins of Western Australia
edited by P G PURCELL and R R PURCELL Petroleum Exploration Society of Australia
Symposium Perth WA 1994 Proceedings p 21ndash 44
JACKSON P R 1966 Geology and review of exploration Officer Basin Western Australia
Hunt Oil Company Western Australia Geological Survey S-series S26 (unpublished)
JACKSON M J 1971 Notes on a geological reconnaissance of the Officer Basin Western
Australia Australia BMR Geology and Geophysics Record 19715 30p
JACKSON M J and van de GRAAFF W J E 1981 Geology of the Officer Basin Western
Australia Australia BMR Geology and Geophysics Bulletin 206 102 p
LOWRY D C JACKSON M J van de GRAAFF W J E and KENNEWELL P J 1971
Preliminary result of geological mapping in the Officer Basin Western Australia Western
Australia Geological Survey Annual Report for 1971 p 50ndash56
MYERS J S 1990 Precambrian in Geology and mineral resources of Western Australia
Western Australia Geological Survey Memoir 3 p 737ndash750
MYERS J S SHAW R D and TYLER I M 1994 Proterozoic tectonic evolution of
Australia 12th Australian Geological Convention Geological Society of Australia Abstracts
no 37 p 312
NEDIN C and JENKINS R J F 1991 Re-evaluation of unconformities separating the
lsquoEdiacaranrsquo and Cambrian systems South Australia Palaios v 6 p 102ndash108
PHILLIPS B J JAMES A W and PHILIP G M 1985 The geology and hydrocarbon
potential of the north-western Officer Basin APEA Journal 25 (1) p 52ndash61
POWELL C McA LI Z X McELHINNY M W MEERT J G and PARK J K 1993
Paleomagnetic constraints on timing of the Neoproterozoic breakup of Rodinia and Cambrian
formation of Gondwana Geology v 21 p 889ndash892
43
POWELL C McA PREISS W V GATEHOUSE C G KRAPEZ B and LI Z X 1994
South Australian record of a Rodinian epicontinental basin and its mid-Neoproterozoic
breakup to form the Palaeo-Pacific Ocean Tectonophysics v 237 no 3ndash4 p 113ndash140
PREISS W V 1976 Proterozoic stromatolites from the Nabberu and Officer Basins Western
Australia and their biostratigraphic significance South Australia Geological Survey Report
of Investigations no 47 p 1ndash51
TOWNSON W G 1985 The subsurface geology of the western Officer Basin mdash results of
Shellrsquos 1980ndash1984 petroleum exploration campaign APEA Journal v 25 (1) p 34ndash51
WATTS K J 1982 The geology of the Townsend Quartzite Upper Proterozoic shallow water
deposit of the Northern Officer Basin Western Australia Perth University of Western
Australia BSc honours thesis (unpublished)
WELLS A T and KENNEWELL P J 1974 Evaporite exploration in the Officer Basin
Western Australia at the Madley Diapirs Australia BMR Record 1974194 (unpublished)
WILLIAMS I R and MYERS J S 1990 Paterson Orogen in Geology and mineral resources
of Western Australia Western Australia Geological Survey Memoir 3 p 274ndash286
WILLIAMS I R 1990 Savory Basin in Geology and mineral resources of Western Australia
Western Australia Geological Survey Memoir 3 p 329ndash334
WILLIAMS I R 1994 The Neoproterozoic Savory Basin Western Australia in The
sedimentary basins of Western Australia edited by P G PURCELL and R R PURCELL
Petroleum Exploration Society of Australia Symposium Perth WA 1994 Proceedings p
841ndash850
WILSON R B 1967 Woolnough Hills and Madley diapiric structures Gibson Desert WA
APEA Journal v 7 p 94ndash102
44
Appendix 2
Meteorological data (from Bureau of Meteorology Perth 1994)
Table 21 Wiluna rainfall (mm)
Year Jan Feb Mar Apr May Jun Jul Aug Sept Oct Nov Dec
1975 0 45 446 309 306 59 276 4 34 886 638 164 1976 16 154 12 138 53 16 34 62 12 238 0 2 1977 44 0 66 74 68 95 24 363 1 58 12 727 1978 234 522 94 16 0 96 367 24 16 353 185 45 1979 19 173 122 88 91 4 0 246 58 0 169 114 1980 148 764 68 1081 259 626 629 06 56 02 174 0 1981 123 476 192 32 196 118 44 74 14 0 28 312 1982 374 705 206 244 1079 92 02 143 368 526 368 118 1983 1 112 928 248 0 212 56 32 5 1 42 496 1984 149 7 342 84 836 0 348 132 224 04 16 172 1985 596 483 0 166 556 0 514 56 0 0 4 0 1986 0 154 35 0 0 1085 23 01 239 137 0 04 1987 1204 119 19 89 17 575 154 126 07 1 0 398 1988 46 202 164 13 388 0 202 104 0 0 224 1309 1989 207 234 26 703 278 536 57 0 01 0 144 02 1990 1035 23 281 46 126 53 94 218 44 9 42 0 1991 48 0 41 45 0 472 297 12 0 1 0 7 1992 112 96 1025 1227 323 65 04 174 0 132 48 4 1993 0 697 0 202 445 0 12 306 18 05 14 33 Mean 25 35 22 27 27 25 18 12 6 13 13 21
JAN FEB MAR APR MAY JUN JUL AUG SEP OCT NOV DEC0
10
20
30
40
Mea
n R
ain
fall
(mm
)
Month
Mean monthly rainfall in Wiluna
MKS41 140498
45
Table 22 Wiluna minimum temperature (degC)
Year Jan Feb Mar Apr May Jun Jul Aug Sept Oct Nov Dec
1975 ndash 23 203 15 94 63 71 62 103 124 169 205 1976 242 229 194 15 10 63 59 73 95 143 16 228 1977 243 25 197 148 96 95 56 86 102 ndash 188 23 1978 241 232 203 18 102 64 76 8 9 152 19 205 1979 255 226 216 167 83 6 59 79 97 145 198 223 1980 255 226 231 155 134 83 68 75 121 108 193 223 1981 245 216 19 182 119 6 54 78 138 159 163 218 1982 232 224 177 16 ndash ndash 37 111 112 164 209 225 1983 235 24 197 147 112 88 39 88 121 162 189 219 1984 241 243 191 156 ndash 72 66 7 95 161 182 211 1985 244 231 ndash 159 98 65 71 73 117 147 205 ndash 1986 ndash 229 226 155 93 96 43 49 10 122 ndash 219 1987 ndash 217 183 175 85 77 68 68 112 ndash ndash 221 1988 238 214 209 178 111 ndash ndash 86 104 157 171 195 1989 ndash 237 199 165 107 67 44 61 107 131 187 ndash 1990 232 ndash 211 155 118 62 57 87 102 149 195 22 1991 26 256 217 168 122 101 78 ndash 113 18 168 219 1992 227 227 214 169 102 98 59 69 ndash 125 159 196 1993 241 218 196 171 103 ndash 49 68 88 128 192 211 Mean 24 23 20 16 10 8 6 8 11 14 18 21
NOTE Dashes indicate data unavailable
JAN FEB MAR APR MAY JUN JUL AUG SEP OCT NOV DEC0
10
20
30
40
Month
MKS43 140498
50
Mean monthly minimum temperatures at Wiluna
Mea
n T
emp
erat
ure
(degC
)
46
Table 23 Wiluna maximum temperature (degC)
Year Jan Feb Mar Apr May Jun Jul Aug Sept Oct Nov Dec
1975 ndash 349 326 281 247 201 197 212 256 248 31 344 1976 374 369 346 297 248 206 208 225 265 287 313 388 1977 397 392 352 296 234 212 222 244 ndash 308 337 383 1978 378 345 346 316 242 195 176 205 231 295 334 356 1979 403 36 364 295 ndash ndash ndash 193 242 318 359 373 1980 392 342 377 275 24 176 179 233 292 288 349 391 1981 385 346 337 342 242 178 201 224 30 326 326 369 1982 372 359 315 307 ndash ndash 196 253 252 305 353 379 1983 381 389 327 272 263 222 187 248 287 321 336 366 1984 378 393 322 299 226 215 178 214 234 ndash 336 364 1985 40 366 ndash 294 224 216 205 212 284 307 355 ndash 1986 ndash 383 372 307 ndash 193 166 196 261 277 ndash 382 1987 ndash 339 328 305 21 202 214 218 275 ndash ndash 374 1988 388 365 353 301 23 ndash ndash 228 283 334 31 33 1989 ndash 375 339 285 238 179 181 219 275 298 336 ndash 1990 368 ndash 36 309 268 19 188 205 274 309 373 393 1991 414 416 363 315 268 206 21 ndash 279 338 332 368 1992 363 383 336 263 213 178 213 197 ndash 285 313 359 1993 396 357 344 301 221 ndash 197 215 253 294 347 362 Mean 39 37 34 30 24 20 20 22 27 30 34 37 NOTE Dashes indicate data unavailable
JAN FEB MAR APR MAY JUN JUL AUG SEP OCT NOV DEC0
10
20
30
40
Month
MKS42 140498
50
Mean monthly maximum temperatures at Wiluna
Mea
n T
emp
erat
ure
(degC
)
47
Appendix 3
Table 31 Summary of palynological results
Drillhole Depth (m) F no(a) GSWA no Lithology Formation Assemblage TAI(b)
BWB 1 74ndash75 F49668 135741 dark-grey siltstone basalt Jilyilli gt5 BWB 1 98ndash100 F49669 135742 dark-grey siltstone basalt Jilyilli gt5 BWB 1 121ndash122 F49670 135743 dark-grey siltstone basalt Jilyilli gt5 TWB 1 86ndash87 F49671 135631 dark-grey siltstone McFadden 3+ TWB 1 104ndash105 F49672 135632 dark-grey siltstone Cornelia 3+ TWB 1 121ndash122 F49673 135633 dark-grey siltstone Cornelia 4 TWB 2 14ndash15 F49674 135634 dark-grey siltstone Skates Hills 3+ TWB 6 49ndash50 F49675 135675 dark-grey siltstone Cornelia 1 3+ TWB 9 49ndash51 F49676 135704 dark-grey siltstone Brassey Range 1 3+ Trainor 1 37497- F49733 138939 black mudstone with Cornelia 5 37509 light-grey siltstone Trainor 1 3809 F49734 138940 dark-grey and black Cornelia 4- laminated mudstone Trainor 1 4170 F49735 138941 black unlaminated mudstone Cornelia 4- Trainor 1 4950 F49851 139501 dark-grey indurated siltstone Cornelia 5 Trainor 1 6032 F49852 139502 dark- and light-grey Cornelia 5 indurated siltstone Trainor 1 6434 F49853 139503 greenish indurated finely Cornelia 5 laminated siltstone LDDH 1 270 F49678 138934 dark-grey siltstone interbeds Waters 1 3+ in enterolithic evaporite Tarcunyah Gp LDDH 1 277 F49679 138935 dark-grey siltstone in cavity Waters 1 3+ in enterolithic evaporite Tarcunyah Gp
NOTES (a) GSWA Fossil Catalogue number (b) TAI = Thermal Alteration Index of Traverse (1988 plate 1)
48
Appendix 4
Savory Sub-basin quantitative magnetic and gravity interpretation (extracted from Cowan 1995)
Summary
A program of quantitative aeromagnetic interpretation has been completed on BMRAGSO data from the Savory Sub-
basin Western Australia Quantitative aeromagnetic interpretation utilized the 3D Euler deconvolution method
supported by wavenumber filtering and image processing The results have provided useful information on structural
trends and depth to magnetic sources in a structurally complex area Depth to magnetic source analysis has provided
information on intra-sedimentary magnetic sources as well as basement rocks
The results of the interpretation support previously identified depocentres However the presence of magnetic
sources at several levels makes it very difficult to produce a reliable magnetic basement depth contour map It is
considered more productive to work with the 3D Euler colour circle plots and images rather than trying to contour the
results It would be necessary to carry out a full-scale interpretation of the BMRAGSO profile data to improve on the
3D Euler results The regional gravity was found to be useful in interpreting the regional setting of the area although
the very wide data spacing limits quantitative use of the data The gravity data show quite a complex picture with
limited consistent correlation between gravity features and basin structures This suggests that gravity anomalies
reflect changes in density of the basement rocks rather than basement topography especially in the northern part of the
basin
It is recommended that the GSWA investigate access to company confidential high-resolution aeromagnetic data
prior to planning further aeromagnetic surveys Private companies have flown large parts of the northern half of the
area as part of their diamond exploration program Additional gravity coverage of the area may be more cost effective
than magnetic surveys as the gravity data provides more information on changes within the sedimentary section
Introduction
The main use of aeromagnetic data in petroleum exploration has been the determination of magnetic basement
topography although there has been increasing interest in analysis of intra-sedimentary magnetic anomalies
intrabasement and suprabasement magnetic anomalies These anomalies are used to determine depth to magnetic
basement rocks and hence determine the thickness of the sedimentary sequence Unfortunately interpretation of the
intrabasement and suprabasement magnetic anomalies is non-unique in terms of position and size of causative sources
because of the inherent ambiguity of potential-field methods However this ambiguity can be reduced by placing
49
constraints on source geometry and magnetization and by using geological and other geophysical data to constrain
the solution
Before 1970 most depth-determination techniques involved graphical determination of slopes of selected
magnetic anomalies and application of various empirical factors to convert the slopes into depth estimates Geological
Society of America Memoir 47 Interpretation of Aeromagnetic Maps by Vacquier et al (1951) was a landmark for
this type of interpretation
Automated interpretation procedures have played an increasingly important role in depth interpretation and a
wide range of techniques have been developed Many of these techniques are designed for application to located data
profiles and assume a two-dimensional geometry However there has been renewed interest in techniques applicable
to gridded data
Two distinct types of method can be recognized In the first case often described as discrete methods individual
isolated magnetic anomalies are interpreted and the results used to produce a map of basement relief In the second
case often described as continuous methods areas of data containing a number of anomalies are interpreted
statistically to produce direct output of basement depths
The discrete methods usually involve a semiautomatic initial phase which generates a large number of possible
depth solutions and an interactive second phase to screen and select acceptable solutions The advantage of this
approach is that the interpreter can select features that are relatively free from interference from adjacent anomalies
and consider all aspects of a particular magnetic anomaly The disadvantage is that interpretation can be very time
consuming as a wide range of depths are usually possible depending on the initial model chosen and a significant
amount of effort is needed to select the correct model In the case of the Savory Sub-basin dataset we encountered
problems in separating basement related effects from the effects of shallower intrasedimentary magnetic sources
Because of these problems we have concentrated on displaying the Euler results accompanied by separation filter
images of the data to show the shallower effects and deeper effects rather than trying to refine a 3D Euler
deconvolution depth-to-crystalline-basement contour
The continuous methods are very direct provided that the rather restrictive assumption can be made that all
anomalies are due to lateral magnetization changes due to basement topography This means that shallow effects and
large intrabasement anomalies must be removed from the data This involves judgement and skill as it is necessary to
distinguish between the lower amplitude suprabasement anomalies due to basement topography and the larger
intrabasement anomalies reflecting magnetization changes within the basement These methods were not considered
suitable for the Savory Sub-basin magnetic dataset but were used to invert the gravity data
50
Limitations of magnetic and gravity interpretation
Interpretation of the area is limited by a shortage of information on the nature and physical properties of the deeper
sedimentary sequence and the underlying basement rocks However using techniques such as cross-correlation of
gravity and pseudo-gravity data it is possible to try to differentiate between anomalies relating to basement and those
related to the sedimentary sequence
Gravity anomalies reflect changes within the sedimentary sequence as well as basement condition These
changes in density of sedimentary rocks produce gravity anomalies without a corresponding magnetic anomaly hence
the complementary nature of gravity and magnetic surveys The main use of magnetics is to determine depth to
magnetic basement and any intra-sedimentary volcanic rocks or intrusives whereas gravity provides much more
general information on the sedimentary sequence
Unfortunately interpretation of gravity anomalies is complicated since they can be due to a number of geological
features including
bull major basement faults
bull basement highs
bull igneous intrusions within the basement
bull sedimentary basins which may or may not be isostatically compensated
bull intra-sedimentary volcanics and associated plutonic centres
Two major problems affect the interpretation of both magnetic and gravity data
1 The inherent ambiguity of potential-field data There is no unique solution to any measured gravity or magnetic
anomaly and theoretically there will be an infinite number of source geometry and magnetizationdensity
combinations which will fit the observed data This means that any a priori information which helps to select a
suitable model is very useful
2 Measured anomalies are the summation of effects from different depths For example an observed gravity profile
may contain contributions from shallow sources (density variations within the sedimentary basin) intermediate
depth sources (density variations due to large igneous intrusions within the basement) and deep sources (crustal
thinning producing a mantle anomaly) Separation of these component responses is the regionalresidual problem
which we solve using spectral analysis and differential upward continuation-based separation filtering
Regional setting and interpretation overview
The area studied includes parts of BALFOUR DOWNS (SF51-9) RUDALL (SF51-10) ROBERTSON (SF51-13) GUNANYA
(SF51-14) COLLIER (SG50-4) BULLEN (SG51-1) TRAINOR (SG51-2) MADLEY (SG51-3) NABBERU (SG50-5)
STANLEY (SG51-6) and HERBERT (SG51-7) 1250 000 sheets Broadly the area lies between latitudes 22deg00rsquondash25deg30rsquoS
and longitudes 119deg30rsquondash123deg30rsquoE
51
Regional gravity
The AGSO regional gravity data (at nominal 11 km spacing) was gridded at a 4 km mesh spacing using a minimum-
curvature algorithm Bouguer gravity values in the area are negative reflecting mass deficiency at depth and range
from -84 mgals to -25 mgals
A Bouguer gravity colour image is shown as Figure 41 A residual grid was produced by removing a fifth-order
orthogonal polynomial from the Bouguer data but did not add to the interpretation
120deg 121deg 122deg 123deg
23deg
24deg
25deg
-25
-84
50 km
MKS46 180598
mgal
Figure 41 Regional Bouguer gravity (BMRAGSO data) gridded at 4 km
52
The data show a complex pattern of positive and negative anomalies with no clearly defined trends Correlations
with aeromagnetic data and known basin structures are poor A vague north-northwest linear trend appears to coincide
with the Marloo Fault (Figure 42) A prominent negative anomaly appears to coincide with the Blake Fold and Fault
Belt depocentre and continues as a narrower negative anomaly to the east until it widens out again near the edge of the
basin Elsewhere the gravity data show little correlation with known basin structures and it is likely that especially in
the north of the area gravity anomalies are due to density changes in the basement rather than changes in basement
topography
Production of wavelength-filtered residual gravity plots and vertical gradient plots showed very patchy aliased
data reflecting poor sampling in much of the area
Regional magnetics
The AGSO regional aeromagnetic data were gridded at a 400 m mesh spacing using a minimum-curvature algorithm
(Figure 43) Most of the data has a line spacing of 1600 m with small areas of 1 km spacing The quality of the data is
acceptable for regional interpretation but is not adequate for detailed analysis The accuracy of the flight path is rather
variable reflecting the vintage of the data and the noise envelope of the data is poor by modern standards Problems
were also encountered in joining different map sheets
The magnetic anomaly pattern over the south and west part of the area shows a strong high frequency signature
reflecting the presence of widespread basic sills and dykes Some of the major north-northeasterly trending dykes can
be traced over considerable distances
Discontinuous high-frequency anomalies extend as a northwest-trending zone through the centre of the area and
this zone includes a conspicuous circular magnetic anomaly which is probably a ring complex
The northern and eastern parts of the area are characterized by long-wavelength deep-seated basement magnetic
anomalies with 120deg and 150deg trends dominant The Marloo and Perentie Faults (Figure 42) appear as distinct linear
zones and offsets A prominent easterly trending negative anomaly in the northwest of the area appears to swing round
to the southeast and may separate different basement blocks One possible interpretation is that this very deep seated
anomaly separates areas of Archaean and Proterozoic basement
Regional geology
The regional geology is described in Williams (1992) The GSWA provided a digitized version of Plate 2 from this
Bulletin the structural interpretation map to use as an overlay (Figure 42)
53
Pp
Pp
PSd
PSd
PSd
PSd
PSd
PSo
PSt
PSt
PSf
PSf
PSf
PSb
PSb
PSb
PSsPSs
PSs
PSb
PSm
PSp
PSc
PSc
PSw
PSw
PSw
PSg
PSr
PSj
PSg
PM
Pk
PY
PY
PSd
L
L
L
L
L
L
L
LL
L
L
L
LL
L
LL
L L
LL
L L
L
L
L
L
L
L
L
LL
L
L
BLAKEDEPOCENTRE
MA
RLO
O
FAU
LT
PERENTIEFAULT
50 km
MKS39120598
120deg 121deg 122deg 123deg
25deg
24deg
23deg
Approximate boundaryof aeromagnetic interpretation
PML
PSgL
PSjL
PML
PSpL
PML
PML
PSfL
PSfL
PSpL
LPc
LPcLPcPSrL
LPA
Durba Sandstone
Woora Woora Formation
McFadden Formation
Tchukardine Formation
Boondawari Formation
Skates Hills Formation
Mundadjini Formation
Coondra Formation
Spearhole Formation
Watch Point Formation
Jilyili Formation
Brassey Range Formation
Glass Spring Formation
Paterson Formation
Yeneena Group
Karara Formation
Cornelia Formation
Kahrban Subgroup
Bangemall Group
Fault
Formation boundary
PSdL
PSoL
PSfL
PStL
PSbL
PSsL
PSmL
PScL
PSpL
PSwL
PSjL
PSrL
PSgL
Pp
PYL
PkL
LPc
LPA
PML
Savory Group Other Units
PYL
Figure 42 Regional geology and structure map (after Williams 1992)
54
120deg 121deg 122deg 123deg
23deg
24deg
25deg
5820
3750
MKS47 180598
nT
50 km
Figure 43 Regional aeromagnetic data total magnetic intensity (BMRAGSO data) gridded at 400 m
Analysis
3D analysis
3D Euler deconvolution was used as the primary depth-determination method The advantage of this approach is that
consistent solutions can be obtained over the entire area with minimal assumptions about source geometries Euler
deconvolution of gridded data is used for positional information and estimation of depth to top of source Euler
55
deconvolution yields a large number of depth solutions which have to be screened to reject spurious solutions Results
are plotted as circles in eight depth ranges with radius proportional to depth and colour coded
The 400 m total magnetic intensity grid was used for the analysis Horizontal gradients in x and y and the vertical
gradient were calculated 3D Euler deconvolution was tested on the 400 m gridded data using windows of 9 times 9 and
11 times 11 and 16 times 16 data points and structural indices 05 (fault) and 10 (sill or dyke) It was concluded that the
16 times 16 window produced the best results overall and final plots were produced for the 16 times 16 window and structural
index 05 (Fig 44) Results were very good over the northern and central parts of the area showing magnetic sources
Figure 44 Depth to magnetic source 3D Euler deconvolution 16 times 16 window of 400 m gridded data structural index 05
56
at several different levels Unfortunately in the extreme south of the area shallow intrasedimentary magnetic sources
(sills and dykes) dominated the inversion and the results contained few basement solutions
In order to reduce these problems the 400 m gridded data were filtered using a separation filter based on
interpretation of the log-energy spectrum The 3D Euler method was run on the filtered data in order to generate more
basement-depth solutions Results for the deep-separation filter data were gridded and presented as a colour image in
Cowan (1995) Attempts to grid the Euler output were unsatisfactory and it is considered safer to interpret the 3D
Euler depth plots The 3D Euler depth results from the separation-filter run should be analysed with care as perfect
separation of the basement can never be achieved and there will always be some contamination from sources at
different levels
The results of original total magnetic intensity 3D Euler depth estimation for structural index 05 using a 16 point
window have been plotted at 1500 000 scale (not included in this publication but available in Cowan (1995) from the
GSWA Library as S10331) and as reduced A4 colour circle plots (Figure 44)
The results of deep-basement 3D Euler depth estimation for structural index 05 using a 16 point window have
been plotted as a colour image at 1500 000 scale and as an A4 image (not included in this publication)
2D analysis
Two equispaced profiles were interpolated with a 50 m station interval from the AGSO-located data profiles for the
BULLEN 1250 000 sheet The interpolated profiles were analysed using 2D Euler deconvolution and Werner
deconvolution Results are included in Cowan (1995) and show the use of these methods for more detailed analysis
Filtered data
In order to reconcile 3D Euler results from shallow basement and intrasedimentary magnetic sources we produced
several separation-filtered maps and images We found the shallow-layer double-separation filter (Figure 45) to be
very effective for shallow sources and the deep-layer standard-separation filter (Figure 46) for the basement layer
Gravity and magnetic data correlation
Both lsquoreduced to the polersquo (RTP) magnetics (Figure 47) and pseudo-gravity data (Figure 48) were produced as part of
the reconciliation of gravity and magnetic signatures In both cases the filtering operations assumed magnetization by
induction in the present Earths field The RTP data are fairly similar to the total magnetic intensity The pseudo-
57
gravity data are dominated by a northwest-trending strong positive anomaly and there is little correlation with the
Bouguer gravity data
The poor magneticgravity correlation is confirmed by cross-correlation of the RTP magnetics and the gravity
gradient The correlation plot in Figure 49 shows little coherent response with numerous zones of positive and
negative correlation
Figure 45 Regional aeromagnetic data shallow layer separation filter (BMRAGSO data) gridded at 400 m
Results
In the north and east of the area on the Wells Foreland Sub-basin trend (refer to Figure 1 main text) we see a range
of quite deep 3D Euler depths and several trend directions with north-northwesterly dominant There are relatively few
shallow intrasedimentary solutions in this zone
The second area of deep 3D Euler solutions lies over the Blake depocentre (Figure 43) with several trend
directions
Elsewhere the 3D Euler results are dominated by shallow intrasedimentary depth solutions reflecting mainly the
dolerite sills dykes and the ring complex However where we do see basement-related solutions in the south and
west of the area they appear to be shallower than those noted for the Wells Foreland Sub-basin and the Blake
depocentre
58
Figure 46 Regional aeromagnetic data deep-layer separation filter (BMRAGSO data) gridded at 400 m
Figure 48 Regional aeromagnetic data pseudo-gravity transform (BMRAGSO data) gridded at 400 m
Figure 47 Regional aeromagnetic data reduced-to-pole (BMRAGSO data) gridded at 400 m
Figure 49 Regional aeromagnetic and gravity data gravitymagnetic correlation using RTP magnetics and gravity gradient (BMRAGSO data) gridded at 4 km
59
This subdivision of the area into two zones of deep solutions is consistent with interpreted depocentres
However the interference between sources at different levels and the complexity of the magnetic response of the
basement rocks precludes more refined interpretation at this stage
The area of deep 3D Euler solutions over the Blake depocentre correlates with the pronounced negative gravity
anomaly discussed in the gravity interpretation section Using a density contrast of -015 gcc the negative gravity
anomaly could indicate up to 6ndash8 km of low-density sedimentary rocks depending on assumptions about the regional
field
The area of deep 3D Euler solutions over the Wells Foreland Sub-basin has a complex gravity expression and no
clear basin structure emerges from inversion of these data As noted previously it is likely that observed gravity
anomalies reflect contrasts in basement density rather than basement topography
Separation filtering applied to the magnetic data helps to enhance the intrasedimentary magnetic signature and to
give a better impression of the basement magnetic signature even though separation of the basement response is not
perfect
Conclusions
Quantitative aeromagnetic interpretation using 3D Euler deconvolution supported by wavenumber filtering and image
processing has been successful in providing structural trend and depth information for the Savory Sub-basin
Quantitative magnetic interpretation has revealed two zones of relatively deep magnetic basement beneath the
Wells Foreland Sub-basin and the Blake depocentre
This analysis of the magnetic data supports interpreted depocentres but the complexity of the basement magnetic
signature and interference from sources at different depths precludes further refinement to a map of basement
topography
Regional gravity proved to be very useful in understanding the regional setting of the area and in providing
support for aspects of the interpretation The gravity data support the interpretation of the Blake depocentre
suggesting up to 6ndash8 km of low-density sedimentary rocks
The deep structure of the Savory Sub-basin area is obviously complex with different areas underlain by
Archaean and Proterozoic basement and with the Capricorn suture occurring in the centre of the area
60
Recommendations
The quantitative magnetic interpretation needs to be reconciled with geological models available for the area
In particular the zones tentatively identified as areas with thick sedimentary rocks the Wells Foreland Sub-
basin and the Blake depocentre need to be investigated
Cross sections should be prepared across the basin for joint magneticgravity modelling especially for the Blake
depocentre It is important to be able to explain the strong negative gravity anomaly in this area
In view of the effects of basement density contrasts on the gravity field for the northern part of the area we think
that additional gravity interpretation and acquisition of new gravity data may not be justified as they will not
contribute significantly to understanding basin evolution and structure
It is recommended that GSWA try to get access to company confidential high-resolution aeromagnetic data
rather than flying new surveys The GSWA might offer to fund flying of new infill areas as a bargaining point
References
The original text of this report by Cowan (1995) and 1500 000 scale maps are filed in the GSWA Library under
S10331
COWAN D 1995 Savory Basin quantitative magnetic interpretation Western Australia Geological Survey S-series
S10331 (unpublished)
VACQUIER V STEENLAND N C HENDERSON R G and ZIETZ I 1951 Interpretation of aeromagnetic
maps The Geological Society of America Memoir 47 151p
WILLIAMS I R 1992 Geology of the Savory Basin Western Australia Western Australia Geological Survey
Bulletin 141 115p
61
Appendix 5
Geochemistry
MKS38 250398
Saturate FractionC12+ GLC
1217
Pr18
Ph
22
31CSR WELL-13 315m Cuttings
Figure 51 Canning Stock Route Well 13 gas chromatograph of extract of auger drill sample
12
17
18
22
31
Pr Ph
LDDH 1 6623m CoreSaturate FractionC12+ GLC
MKS35 240398
Figure 52 Gas chromatograph of extract from core sample at 6623 m LDDH1
62
Table 51 Canning Stock Route Well 13 auger drill samples
GSWA sample Drill depth (m)(a) Comments
135601 150 At watertable 135602 203 (all samples consist 135603 310 of sand mud and water) 135604 315 At total depth
NOTE (a) Datum for drill depth is the top of sediment fill in the well which is 155 m below ground level (ie the total depth of 315 m is 47 m below ground level)
Table 52 Canning Stock Route Well 13 gas chromatography data for 315 m depth sediment sample
Parameter Value
Weight of rock extracted (grams) 945 Total extract (ppm) 519 n-Alkane distribution n-C12 07 n-C13 23 n-C14 26 n-C15 22 n-C16 19 n-C17 14 i-C19 23 n-C18 14 i-C20 08 n-C19 11 n-C20 16 n-C21 25 n-C22 29 n-C23 70 n-C24 42 n-C25 95 n-C26 43 n-C27 83 n-C28 38 n-C29 87 n-C30 31 n-C31 273 Alkane compositional data Pristane phytane ratio 279 Pristane n-C17 ratio 161 Phytane n-C18 ratio 059 CPI (1)(a) 284 CPI (2) 209 (C21 + C22) (C28 + C29) 043
NOTE (a) CPI= Carbon preference index
63
Table 53 LDDH1 extract liquid chromatography data for 6623 m concentration
Rock extracted Total extract (grams) (ppm)
702 313
NOTE ppm= parts per million
Table 54 LDDH1 saturate gas chromatography data of core for 6623 m alkane composition
Pristane Pristane Phytane (a) CPI (1) CPI (2) (C21+C22) Phytane n-C17 n-C18 (C28+C29)
103 026 024 103 102 325
NOTE (a)CPI = carbon preference index
Table 55 LDDH1 saturate gas chromatography data of core for 6623 m n-alkane distributions
Parameter Value
n-C12 17 n-C13 38 n-C14 55 n-C15 60 n-C16 65 n-C17 74 i-C19 19 n-C18 78 i-C20 19 n-C19 80 n-C20 79 n-C21 71 n-C22 64 n-C23 57 n-C25 43 n-C24 38 n-C27 31 n-C28 23 n-C29 19 n-C30 12 n-C31 10
64
Appendix 6
Table 61 Summary of data from Trainor waterbores (TWB) and Bullen waterbores (BWB)
Well AMG Elevation TD Status(b) Completion details Water Salinity Water level Flow rate Depth to consolidated AGD84 GL (m) (m) struck mgl(c) (m) (LHr) lithology aquifer(e) Z51(a) Interval (m) (100 mm PVC) (m) (mgl)(d)
TWB 1 473660E 453 122 comp 0ndash75 plain 63 7 300 24 2 880 12 m 7287404N 75ndash93 slotted (9 260) McFadden Fm 93ndash99 plain TWB 2 472 977E 475 23 abd nil 15 m 7285877N Skates Hills Fm dry TWB 3 473259E 475 50 abd nil 7 m 7285849N Skates Hills Fm dry TWB 4 463225 E 445 50 comp 0ndash22 plain 35 7 200 55 3 600 0 m 7286143N 22ndash34 slotted (8 140) Tertiary sand and gravel 23ndash60 plain TWB 5 463095E 445 31 comp 0ndash19 plain 13 26 000 655 3 600 Tertiary sand and gravel 7277721N 19ndash25 slotted (36 700) 25ndash31 plain TWB 6 457013E 455 50 comp 0ndash42 plain 38 920 119 600 0 m 7274352N 42ndash48 slotted (1 030) Cornelia Fm ss TWB 7 453739E 475 26 susp 0ndash2 plain 11 9 300 48 4 500 0 m 7263891N (10 500) Tertiary sand TWB 8 433893E 535 60 susp 0ndash2 plain 47 8 500 gt46 1 200 0 m 7245991N (10 900) Tertiary sand and Brassey Range Fm ss TWB 9 437219E 505 51 comp 0ndash47 plain 45 1 000 58 600 1 m 7235905N 47ndash51 slotted (990) Brassey Range Fm ss TWB 10 434927E 495 32 susp 0ndash2 plain 235 450 120 0 m 7225875N (500) Dolerite
65
BWB 1 287337E 580 122 abd Nil 1 m 7245861N Jilyili Fm dry BWB 2 288346E 545 50 comp 0ndash26 plain 15 630 3 29 000 0 m 7240423N 26ndash38 slotted (730) Tertiary sand and gravel 38ndash50 plain BWB 3 305637E 545 50 abd 19 8 800 43 7 200 0 m 7240423N (10 550) Tertiary ss BWB 4 320167E 515 445 comp 0ndash20 plain 9 980 445 24 000 0 m 7248097N 20ndash32 slotted (1 190) Tertiary ss 32ndash44 plain BWB 5 353393E 545 20 susp 0ndash2 plain 45 (970) 1 m 7238934N Basalt
NOTES (a) GPS accuracy ~ 150 m (b) Comp = completed abd = abandoned susp = suspended (c) Salinity from conductivity (d) Analysis total dissolved solids (e) Fm = Formation ss = sandstone
4
During 1994 in consultation with the Petroleum Industry the Department of Minerals and
Energy received State Government funding for a Petroleum Exploration Initiative to be
undertaken by the Geological Survey of Western Australia (GSWA) with a view to identifying
prospective onshore areas for oil and gas thus increasing the level of onshore exploration in
Western Australia This initiative was originally funded for the first three years of a five-year work
program Two teams of specialists were formed to investigate the prospectivity of both the western
margin and interior onshore sedimentary basins
The Petroleum Exploration Initiative teams seek to enhance the prospectivity of onshore
basins by reducing through focused investigations the risks perceived by industry to be factors
limiting exploration activity Comprehensive petroleum system reports of the onshore Western
Australian basins are to be completed as a result of the projects undertaken during the five-year
Initiative The objective of the Initiative will be achieved through both the analysis of open-file
exploration data and the acquisition of new data New data will include but not be limited to
geophysical surveys and stratigraphic drilling Project results are to be reported to the industry
through GSWA publications external publications conference reports and oral presentations
This Record is the third in a series of comprehensive reviews by the GSWA of the
hydrocarbon prospectivity of some of Western Australiarsquos interior onshore sedimentary basins
The first Record of this series covered the Canning Basin (Apak and Carlsen 1997) The second
Record reviewed the Western Australian Officer Basin (Perincek 1998) but excluded the Savory
Sub-basin
This study assesses the potential for hydrocarbon exploration within the Savory Sub-basin
based on available geological and geophysical data and defines the scope for future studies
Publications relevant to this investigation but which are not specifically referred to are listed in
Appendix 1
Access and climate
The Savory Sub-basin lies east and southeast of the mining town of Newman in the Pilbara region
(Fig 2) The area is largely uninhabited the only settlement being an outcamp at Poondawari on
the GUNANYA 1250 000 map sheet The outcamp is linked by a graded track to the Jigalong
Community 90 km to the west just outside the northwest margin of the sub-basin A few pastoral
leases lie along the margins of the sub-basin but the majority of the region is Vacant Crown Land
Capitalized names refer to standard map sheets
5
Sealed road
Gravel road
Track
Town
Homestead
Locality
STANLEYSavory Sub-basin boundary 1250 000 map sheet
CornerTrack
Talawana - Windy
Route
Watch Point
NEWMAN
JigalongCommunity
RobertsonRange (abd)
Wokalba
Poondawari
Balfour Downs
Billinnooka
Weelarrana
Beyondie(abd)
Kumarina
Marymia
Glen-ayle
White Lake
Hanging RockBoorabee Hill
WellsRa
EmuRa
Robertson
Ra McFadden R
a
DiebillHills
DurbaHills
Calvert Ra
WardHills
Cornelia Ra
KellyRaBlakeHills
HillsDean
ROBERTSON GUNANYA
TRAINORBULLEN
BALFOUR DOWNS RUDALL
NABBERU STANLEY HERBERT
50 km
Woora Woora Hills
120deg 121deg30 123deg
25deg
24deg
23deg
22deg
Goldfieldsnatural gaspipeline
GR
EA
TN
OR
TH
ER
NH
IGH
WA
Y
Mar
ble
Bar
Nul
lagi
ne-
Rd
MADLEY
Can
ning
Stoc
k
MKS31120598
Goldfields natural gas pipeline
Figure 2 Localities and access routes of the Savory Sub-basin
6
The sealed Great Northern Highway lies west of the Savory Sub-basin and links Meekatharra
to Newman The TalawanandashWindy Corner graded track crosses the northern part of the sub-basin
and graded pastoral station tracks on Balfour Downs Weelarrana Kumarina Marymia and Glen-
Ayle give access to the western and southern margins The Canning Stock Route traverses the sub-
basin from north to south and is a well travelled four-wheel-drive track allowing access to the
eastern half of the sub-basin Additional minor tracks also provide access to other parts of the area
(Williams 1992) Recently flown monochrome aerial photography at 150 000 and Landsat TM
imagery covering the sub-basin is available from the Department of Land Administration
Cross-country access is similar to that in the Canning Basin with the average height of sand
dunes being lower in the Savory Sub-basin Potable water has been found in water bores in the
south of the sub-basin and is inferred to be present throughout the region Fuel and supplies are
available at Wiluna Meekatharra and Newman A good working relationship with the Western
Desert Community who hold native title claims over most of the sub-basin has been established
by GSWA
There are no meteorological stations within the Savory Sub-basin but estimates based on data
from nearby Bureau of Meteorology Stations indicate that the area is arid and has its maximum
rainfall in summer from monsoonal rains The sub-basin has reasonable access and a tolerable
working climate for all exploration activities Meteorological data for the town of Wiluna which
lies about 180 km to the south of the sub-basin are included as Appendix 2
Regional geology
Stratigraphy
Thirteen formations were recognized by Williams (1992) in the Savory Sub-basin and these are
summarized in Table 1 Although unconformities were recognized between some of the
formations and they reflect a wide range of depositional environments provenance and climatic
conditions these formations were defined by Williams (1992) as constituting the Savory Group
Five depositional sequences that are generally unconformity-bounded were recognized by
Williams (1992) (Fig 3) The correlation of significant formations within the sub-basin with other
parts of the Centralian Superbasin is shown in Figure 4 with the four Neoproterozoic
Supersequences having been defined by Walter et al (1995)
7
Durba Ss
McFadden
Woora Woora400
Tchukardine700
Skates Hills
Mundadjini1800
B
Coondra
(B)
Watch Point
Spearhole1100Jilyili
1000(A)
Glass Spring1600(A)
Brassey Range1700(A)
Abs
ent
Absent Absent
Absent
Absent
Absent
A
B
C
D
E
1A
1B
3
4A
4B
1000
2000
3000
4000
5000
6000
Max
imum
thic
knes
s
Sup
erse
quen
ce
AG
EN
EO
PR
OT
ER
OZ
OIC
NE
OP
RO
TE
RO
ZO
ICT
O
CA
MB
RIA
NM
AR
I-N
OA
N
NW SE
Savory Sub-basin Stratigraphy
MKS30 120598
Fault boundary
Unconformity
Disconformity
Conglomerate
Sandstone Mudstone
Siltstone
Evaporite
Dolomite
Boondawari800 Boondawari
Supersequence 2 is not represented in the Savory Sub-basin Total thicknesses are estimated from air photo interpretation Thicknesses of recessive units are unknown
Diamictite
Dep
ositi
onal
seq
uenc
e
Figure 3 Formations lithology and depositional sequences AndashE of the Savory Sub-basin
8
Table 1 Summary of formations in the Savory Sub-basin
Formation Super Depo Lithology Thickness Depositional Savoy Comments Seq(a) Seq(b) (m) environment Group(c)
Durba Sandstone 4 E Quartz sandstone with minor 100 Fluvial lacustrine Y Excellent reservoir basal conglomerate lenses Woora Woora 4 D Medium-grained ferruginous 400 Shallow marine deltaic Y Formation sandstone lithic sandstone quartz wacke siltstone McFadden 4 D Laminated fine- to coarse-grained 1 500 Shallow marine deltaic Y Possible reservoir Formation quartz sandstone feldspathic sandstone quartz wacke minor conglomerate siltstone Tchukardine 4 D Medium- to coarse-grained sandstone 700 Shallow marine Y Formation lithic sandstone quartz wacke conglomerate lenses siltstone minor shale Boondawari 3 C Glacigene diamictite sandstone siltstone Formation shale conglomerate minor dolomite (some stromatolitic and oolitic) rhythmite 800 Glacial shallow marine Y Possible source rock Skates Hills 1 B Thin-bedded dolomite (some stromatolitic) 200 Shallow marine sabkha Y Possible source rock Formation chert evaporites fine- to medium-grained sandstone siltstone shale patchy basal conglomerate Mundadjini 1 B Fine- to coarse-grained sandstone 1 800 Deltaic sabkha Y Possible source rock Formation conglomerate siltstone minor shale shallow marine mudstone dolomite (some stromatolitic) and evaporites Coondra 1 B Coarse- to medium-grained sandstone 1 000 Fan delta Y Possible reservoir Formation poorly sorted conglomerate pebbly sandstone Spearhole 1 B Coarse- to medium-grained sandstone 1 100 Braided fluvial deltaic Y Possible reservoir Formation pebbly sandstone siltstone and oil shows in conglomerate lenses Mundadjini 1 Boondawari 1
9
Watch Point 1 B Shale siltstone fine- to medium-grained 400 Shallow marine deltaic Y Formation sandstone glauconitic sandstone Jilyili Formation 1 A Fine-grained sandstone siltstone minor shale mudstone conglomerate lenses 1 000 Deltaic Y Brassey Range 1 A Fine- to medium-grained sandstone 1 700 Fluvial deltaic Y Formation siltstone shale minor mudstone Glass Spring 1 A Medium- to coarse-grained sandstone 1 600 Shallow marine fluvial Y Formation minor conglomerate and siltstone Tarcunyah Group 1 AampB Quartz sandstone feldspathic sandstone Shallow marine sabkha N Bitumen in LDDH1 quartz wacke shale siltstone fluvial lacustrine conglomerate evaporites dolomite Cornelia 1 A Sandstone siltstone shale mudstone Shallow marine N Overmature source rocks Formation minor glauconitic sandstone deep marine in Trainor 1 Kahrban 1 A Sandstone siltstone shale 1 700 Shallow marine deltaic N Subgroup
NOTES (a) Supersequences of Walter et al (1995) (b) Depositional sequences of Williams (1992) (c) Y= assigned to Savory Group in Williams (1992) N= previously considered to be older than the Savory Group but now included in the greater Officer Basin
10
SAVORY SUB-BASIN GIBSON SUB-BASINCENTRAL OFFICERBASIN
AMADEUS BASIN
PETERMANN RANGES OROGENY
NE
OP
RO
TE
RO
ZO
IC
ST
UR
TIA
NM
AR
INO
AN
ED
IAC
AR
IAN
CAMBRIANTO
NEOPRO-TEROZOIC
AG
E (
Ma)
SOUTHS RANGE MOVEMENT
AREYONGA MOVEMENT
Steptoe
MILES OROGENY
Mission Group
Cassidy Group
Rudall Complex
Bangemall Group
unnamed
Tar
cuny
ah G
roup
4
3
2
1
MKS12a 180598
500
550
600
650
700
750
800
850
900
SU
PE
R
SE
QU
EN
CE
unnamed
Tchukardine Fm
McFadden Fm
ArumberaSst
Julie Fm
Pertatataka Fm
Olympic FmPioneer Sst
Boondawari Fm
Turkey Hill FmLupton Fm
Kanpa Fm
Neale FmBabbagoola
FmHussar
Fm
Browne Fm
Woolnough Fm
Madley Fm
Bitt
er S
prin
gs F
m
LovesCreek M
Gillen M
Heavitree Fm
Arunta Complex
Throssell Group
TownsendQuartzite
Earaheedy Group
olderCornelia Fm
Jilyili Fm
SpearholeFm
MundadjiniFm
Skates Hills Fm
Lefroy Fm
Areyonga Fm
Aralka Fm
ME
SO
-P
RO
TE
RO
ZO
IC
Waters Fm
youngerCornelia Fm
Brassey RangeFormationKahrban
Subgroup
GlassSpring
Fm
Durba Sst
LP1ALP1B EVENT
Figure 4 Correlation of Savory Sub-basin formations with the western Officer and Amadeus Basins Fm = Formation Sst = Sandstone M = Member
11
The depositional sequences recognized in the sub-basin are an order of magnitude thicker than
those described from Phanerozoic passive-margin settings (Payton 1977 Posamentier et al 1988)
and are broadly comparable in scale to the second-order cycles of Vail et al (1977) and to the
megasequences of Hubbard et al (1985) The main subsurface data available to reveal the
unweathered nature of these rocks are Trainor-1 and the three-well diamond coring program in
Petroleum Permit EP 380 (Akubra 1 Boondawari 1 Mundadjini 1) completed in late 1997 in the
central west of the sub-basin (Figs 5 and 6)
The ages of all formations in the Savory Sub-basin are poorly constrained The only fossils
known are stromatolites and palynomorphs (acid-insoluble microfossils) Palynology from
available wells is summarized in Appendix 3 from Grey and Stevens (1997) and Grey and Cotter
(1996) and correlations using stromatolite biostratigraphy (Stevens and Grey 1997 Grey 1995f
Walter et al 1994 1995) are consistent with a Neoproterozoic age for the formations for which
data are available
A dolerite within the Boondawari Formation gave a poorly constrained RbndashSr age of about
640 Ma (Williams 1992) SHRIMP UndashPb dating of sedimentary zircons from the McFadden and
Cornelia Formations in stratigraphic drillhole Trainor 1 are discussed in Stevens and Adamides (in
prep) and Nelson (1997) The youngest ages from these analyses indicate that the maximum age
of the Cornelia Formation is Early Cambrian or Sturtian but these ages are inconsistent with
previous tectonic interpretations (Williams 1992) and current stratigraphic correlations which
suggest the Cornelia Formation is of Supersequence 1 age or older (Fig 4)
Depositional Sequence A Supersequence 1
Depositional Sequence A includes the Glass Spring Jilyili and Brassey Range Formations (Fig
3) All of these units are predominantly quartzose sandstones some of which are friable and have
significant visible porosity in outcrop Conglomerates are present in the Glass Spring and Jilyili
Formations
Depositional Sequence B Supersequence 1
Depositional Sequence B consists of the Watch Point Coondra Mundadjini Spearhole and
Skates Hills Formations (Fig 3) All of these formations contain beds of quartzose sandstone and
some also contain conglomerates The porosity of dolomites in the Skates Hills Formation appears
poor in surface exposures but its subsurface characteristics are unknown
12
50 km
120deg 121deg30 123deg
25deg
24deg
23deg
22deg
Greater Officer Basin
PNCEXP CA11PNCEXP CA12
PNCEXP CA13PNCEXP CA19
PNCEXP CA05
PNCEXP CA09
BD134589
GSWA Trainor 1 and TWB123
Fortescue River 1A
Mundadjini 1
Akubra 1Boondawari 1
TWB4TWB5
TWB6
TWB7
TWB8
TWB9
TWB10
BWB1
BWB2 BWB3
BWB4
BWB5
OD23
Mineral exploration drillhole
Stratigraphic drillhole
Waterbores and wells(TWB and BWB serieswaterbores identified)
MKS33270398
LDDH 1
Savory Sub-basin
Canning SR Well 13
EP380
Petroleum Exploration permit
Petroleum exploration well
Figure 5 Locations of petroleum exploration wells mineral exploration and stratigraphic drillholes water bores and wells and petroleum exploration permit EP380 in the Savory Sub-basin
13
TD=600m
TD=1367m
TD=701m
TD=709m
TD=50m
SS
1S
S1
SS1
SS
1S
S1
SS
1
SS
1
SS1
SS4 SS1
Pha
nero
zoic
or
SS
2
Cz
CzCz
Karst Bitumen
SS1
TD=181m
Mundadjini 1 Akubra 1 Boondawari 1 LDDH 1 Trainor 1 TWB 6
Munda-djini Fm
Spear-hole Fm
Munda-djini Fm
Munda-djini Fm
Spear-hole Fm
Spear-hole Fm
Waters Fm
McFadden Fm
Cornelia Fm
Cornelia Fm
Cornelia Fm
511 plusmn 13Maor 696 plusmn 20Ma(maximum)
779 plusmn 10Ma(maximum)
Mundadjini 1
Akubra 1 Boondawari 1
LDDH 1
Trainor 1TWB 6100 km
N
LOCATION
NW SE
Sea level
0m AHD
Dolerite basalt
Conglomerate
Sandstone
Mudstone
Dolomite
Limestone
Evaporite
TOC gt08
Permeability gt100md
Oil fluorescence
Sedimentary zircon U-Pb age
Identifiable polymorphs
Cainozoic
Supersequence 1 age
Unconformity
Formation contact
Cz
SS1
r
r
0
100
200
metres
VerticalScale
MKS36 120598
LEGEND
Figure 6 Geological cross section through significant drillholes in the Savory Sub-basin
14
Depositional Sequence C Supersequence 3
Depositional Sequence C consists of the Boondawari Formation (Fig 3) and although it contains
sandstone conglomerate and dolomite the sandstones contain significant amounts of feldspar and
clay and hence are likely to be poorer reservoirs than older sandstones
Depositional Sequence D Supersequence 4
Depositional Sequence D includes the McFadden Tchukardine and Woora Woora Formations
(Fig 3) The McFadden Formation is poorly sorted and sandstones contain significant amounts of
feldspathic clasts in the north of the basin but are significantly coarser and cleaner in the northeast
of the sub-basin (Williams 1992)
Sandstones of the Tchukardine and Woora Woora Formations are generally cleaner than those
of the McFadden Formation and are expected to have fair to good porosity although the
Tchukardine Formation has a higher clay content in parts
Depositional Sequence E Supersequence 4
Depositional Sequence E consists of the Durba Sandstone (Fig 3) a coarse sandstone with minor
conglomerate which has good to excellent visible porosity in surface exposures
Other depositional sequences and regional correlations
Sedimentary rocks which were not included in the Savory Group by Williams (1992) but which
are likely to be of Neoproterozoic age and hence part of the greater Officer Basin include the
Tarcunyah Group the Cornelia Formation and the Kahrban Subgroup
As discussed in the Introduction all of the strata in the Karara Basin and the younger strata
of the Yeneena Basin were redefined to form the Tarcunyah Group of the greater Officer Basin
(Bagas et al 1995) (Fig 7) In outcrop the Tarcunyah Group consists predominantly of quartzose
feldspathic and arkosic sandstone shale which is carbonaceous in parts and carbonate which
includes stromatolitic dolomite Mineral hole LDDH1 drilled on GUNANYA intersected the
15
120598
122deg
123deg
21deg
22deg
23deg
24deg
23deg
22deg
21deg
122deg
123deg
Fault
Thrust
Reverse thrust
CANNINGBASIN
OFFICERBASIN
GROUP
PILBARACRATON
TARCUNYAH
SAVORY GROUP
BANGEMALL
GROUP
THROSSELL
GROUP
LAMIL
GROUP
ConnaughtonTerrane
TerraneTalbot
complexTabletop granitic
Tabletop Terrane
Permian
Neoproterozoicgranitoid
50 km
FormationWaltha Woora
McKay Fault
South west Thrust
Vines
Fault
24deg
120deg
YENEENA CANNINGBASIN
ARUNTAINLIERRUDALL
COMPLEX
AMADEUSBASIN
MUSGRAVEBLOCK
OFFICERBASINYILGARN
CRATON
GROUP
GROUP
GROUP
PILBARACRATON
GROUP
EARAHEEDY
GLENGARRY
BANGEMALL
WYLOO GROUP
SAVORY
WA
CARNARVONBASIN
GASCOYNECOMPLEX
GROUPTARCUNYAH
400 kmGROUP
SA
N
T
CamelndashTabletopfault zone
KAHRBANSUBGROUP
CORNELIAFORMATION
MKS37
Figure 7 Regional geological setting of the Savory Group and western Officer Basin The dashed line on the inset map marks the interpreted margin of the greater Officer Basin
16
Tarcunyah Group and consists predominantly of mudstone with minor sandstone limestone
dolomite and anhydrite (Fig 6)
The age of the Tarcunyah Group is uncertain although limited palynological and stromatolite
evidence suggests that it is probably coeval with Supersequence 1 of the Centralian Superbasin
Drillhole LDDH1 contains palynomorphs equivalent to assemblages in the Browne and Bitter
Springs Formations of the Officer and Amadeus Basins respectively and from the Cornelia
Formation in TWB 6 (Grey and Stevens 1997) (Figs 4 and 6) Stromatolite specimens tentatively
assigned to Acaciella australica (Howchin 1914) Walter 1972 occur in the lower Tarcunyah
Group (Bagas et al 1995) The stromatolite Baicalia burra Preiss 1972 and a conical
stromatolite were reported from the upper part of the Tarcunyah Group (Stevens and Grey 1997)
The recognition of two stromatolite assemblages interpreted to have age significance in
Supersequence 1 sedimentary rocks of the Centralian Superbasin has permitted biostratigraphic
correlations between outcrop and well data The Acaciella australica assemblage appears to be
slightly older than 800 Ma and is restricted to the middle part of Supersequence 1 The Baicalia
burra assemblage is considered to be slightly younger than 800 Ma and occurs in the upper part
of Supersequence 1 (Grey 1996b Stevens and Grey 1997) The older A australica assemblage
is recognized in the Skates Hills Formation in the Savory Sub-basin and the stromatolite A
australica itself has been tentatively identified in the lower Tarcunyah Group The occurrence of
the A australica assemblage in the Woolnough Madley and Browne Formations of the Officer
Basin and in the Loves Creek Member of the Bitter Springs Formation of the Amadeus Basin
allows correlations throughout the Centralian Superbasin (Fig 4)
The younger B burra assemblage has not been recognized in sedimentary rocks of the
Savory Group as defined by Williams (1992) but it occurs in the upper parts of the Tarcunyah
Group and allows correlation of this group with outcrops of the Neale Formation and with the
Kanpa Formation in petroleum exploration well Hussar 1 both located in the central Officer Basin
of Western Australia (Fig 4) (Grey 1996b Stevens and Grey 1997) The occurrence of the B
burra assemblage in these units permits their correlation with the Burra Group in the Adelaide
Geosyncline of South Australia (K Grey unpublished data)
The Cornelia Formation and Kahrban Subgroup outcrop in the southeast of the sub-basin and
were considered by Williams (1992) to be part of the Mesoproterozoic Bangemall Basin Limited
evidence suggests that all or parts of these two units are of Neoproterozoic age The Ward and
Oldham Inliers consist of outcrops of the Cornelia Formation Waterbore TWB 6 which was
drilled on TRAINOR in the Cornelia Formation contains palynomorphs consistent with a
Supersequence 1 age (Grey and Stevens 1997) (Figs 5 and 6) In outcrop the Cornelia Formation
17
consists predominantly of sandstone and quartzite with lesser siltstone shale mudstone and chert
In Trainor 1 this formation consists predominantly of indurated mudstone with minor sandstone
chert and dolomite A major erosional unconformity separates the Cornelia Formation from
overlying formations and parts of the Cornelia Formation have been folded with dips exceeding
70deg In contrast the majority of the Savory Sub-basin sedimentary rocks have dips of less than 30deg
except where they are adjacent to faults The Cornelia Formation apparently consists of an older
unit of steeply dipping quartzites cherts and well-indurated mudstones and a younger unit of
shallower dipping sandstones which are sub-friable in parts However caution should be used in
interpreting the age of units based on their structural deformation and additional mapping and age
dating of this formation is required
It is proposed here that the Kahrban Subgroup is likely to be of early Neoproterozoic age and
hence should be considered as part of the greater Officer Basin This proposal is based largely on
the relatively low dip of the strata (generally less than 20deg) and their west-northwest strike which
is parallel with strikes in the overlying Brassey Range Formation of the Savory Group The lower
contact of the Kahrban Subgroup is obscured but is thought to be an unconfirmity on the
Earaheedy Basin on the southeast of STANLEY (Muhling and Brakel 1985)
Structural setting
The Savory Sub-basin forms the most northwesterly sub-basin of the Neoproterozoic to
Phanerozoic Officer Basin The western boundary of the sub-basin with the Mesoproterozoic
Bangemall Basin consists of steep-reverse and strike-slip faults The northeastern boundary of the
Savory Sub-basin was mapped where Supersequence 4 formations of the Savory Group
unconformably overlie sedimentary rocks of the Karara and Yeneena Basins with the two older
units considered to be part of the Paterson Orogen (Williams 1992) This contact was defined as a
series of steeply dipping reverse faults in the northernmost parts of the sub-basin on BALFOUR
DOWNS and RUDALL and was extrapolated as an inferred reverse fault farther along strike to the
southeast on GUNANYA and MADLEY where the contact is obscured by Cainozoic sediments It is
now recognized that all the sedimentary rocks in the Karara Basin and younger sedimentary rocks
of the Yeneena Basin are from the Supersequence 1 Tarcunyah Group and part of the greater
Officer Basin (Bagas et al 1995) The northern boundary of the Tarcunyah Group and the greater
Officer Basin is in thrust-and reverse-faulted contact with the Rudall Complex and other parts of
the Paterson Orogen (Fig 7)
To the south the sub-basin unconformably overlies the Bangemall Basin The eastern
boundary of the sub-basin used in this study is where Permian and younger strata of the Officer
Basin unconformably overlie Neoproterozoic strata although there are no significant structural or
stratigraphic differences between the Neoproterozoic units
18
The sub-basin is subdivided into three principal structural areas (Fig 1) Trainor Platform
Blake Fault and Fold Belt and Wells Foreland Sub-basin (Williams 1992) A major review of
these boundaries is beyond the scope of this report but the processing of regional aeromagnetic
data (Appendix 4) and acquisition of a semi-detailed gravity survey by the GSWA in the east of
the sub-basin has enabled these tectonic units to be reassessed and some modifications are
proposed
The Wells Foreland Sub-basin (originally termed the Wells Foreland Basin in Williams 1992)
and sedimentary rocks of the Tarcunyah Group are both considered to be the northwest
continuation of the Gibson Sub-basin of the Officer Basin Aeromagnetic gravity and outcrop
data suggest that the Blake Fault and Fold Belt is significantly faulted and folded in the west but
is less deformed in the east where the thickest sedimentary section in is located on BULLEN
(Appendix 4) The Trainor Platform is reinterpreted to represent an area of the sub-basin that has
undergone major compression during the Petermann Ranges Orogeny resulting in folding and
faulting with a northwest strike This interpretation contrasts with that proposed by Williams
(1992) who envisaged that only a thin section of the Savory Group was present on the platform
Perincek (1998) has recognized nine periods of tectonic activity in the Officer Basin from the
beginning of the Neoproterozoic to the end of the Cretaceous Three major tectonic episodes are
recognized in the Centralian Superbasin The oldest event is the Areyonga Movement which is
pre-Sturtian and forms the boundary between Supersequences 1 and 2 (Fig 4) The Souths Range
Movement occurred at the end of the Sturtian at the boundary between Supersequences 2 and 3
The youngest major event is the Petermann Ranges Orogeny which occured at the end of the
Marinoan and forms the boundary between Supersequences 3 and 4
One minor and two major tectonic episodes are recognized in the Savory Sub-basin the
LP1ALP1B structural event and the Areyonga Movement and the Petermann Ranges Orogeny
respectively The LP1ALP1B structural event is revealed where the Spearhole Formations rests
disconformably and locally unconformably on the Brassey Range Jilyili and Glass Spring
Formations The Neoproterozoic Areyonga Movement (equivalent to the Blake Movement of
Williams 1992) produced folds and faults with a general northeast strike in the western and
southern parts of the region The Souths Range Movement has not been recognized in the sub-
basin This may be due to the fact that no Sturtian glacial rocks have been identified and hence it
is possible that structures attributed to the Areyonga Movement could be the result of the Souths
Range Movement or a combination of the two movements
The major tectonic event recorded in the sub-basin is the latest Neoproterozoic to Cambrian
Petermann Ranges Orogeny (equivalent to the Paterson Orogeny) which produced large reverse
19
faults thrusts strike-slip faults and folds with a general northwest strike The McFadden
Formation and other Supersequence 4 strata are considered to be at least partially coeval with this
orogeny (Williams 1992) We also interpret the Durba Sandstone as having been deposited during
the later stages of the Petermann Ranges Orogeny as this unit mildly deformed with fold axes
parallel to the strike of other structures attributed to the Petermann Ranges Orogeny
Quantitative aeromagnetic interpretation of the Savory Sub-basin utilizing the 3D Euler
deconvolution method supported by wave-number filtering and image processing has provided
structural trends and depth to magnetic source within the sub-basin (Cowan 1995) Gravity data
are interpreted by Cowan (1995) as changes in both the density of the basement rocks andor
basement topography depending on local conditions Part of Cowanrsquos report is reproduced in
Appendix 4
Exploration history
The only petroleum exploration conducted in the sub-basin has been the recent drilling in the
western part of three diamond drillholes of which two have minor oil shows (Table 2) There has
been some mineral exploration the results of which are stored in the GSWA Western Australian
Mineral Exploration (WAMEX) database system Much of the mineral exploration was in the
southwest and west where the sub-basin is in contact with the Bangemall Basin and along the
northern margin of the sub-basin Many of these mineral exploration programs included
aeromagnetic surveys and surface geochemical sampling (Fig 8)
Hydrocarbon potential
The sub-basin contains a sedimentary succession up to 8 km thick which is generally gently
folded and faulted and apparently unmetamorphosed Limited drilling has shown that thick
mudstones are present in the sub-basin with some mudstones in Trainor 1 having high Total
Organic Carbon (TOC) values Outcrops of sub-friable sandstones in many of the formations
within the sub-basin suggests widespread reservoir potential Mudstone and inferred thick
evaporite sequences are likely to form seals Maturity data suggest that near-surface samples are
approximately at the base of the oil window and top of the gas window in parts of the north and
southeast of the sub-basin However parts of the southwest of the sub-basin and the mudstones in
Trainor 1 have very high levels of maturity Numerous faults and folds have been identified from
surface mapping suggesting good potential for large structural traps Minor oil shows in
20
Table 2 Neoproterozoic formations and hydrocarbon shows in diamond drillholes in the Savory Sub-basin
Drillhole AMG Core TD (m) Approx Formation Depth Formation Depth Formation Depth Shows (AGD84) start (m) GL (m) (m) (m) (m)
LDDH 1 431148E 112 701 350 Tarcunyah 68ndash701 ndash ndash bitumen at 6623 m 7443826N Group Trainor 1 473640E 6 709 455 McFadden 9ndash83 Cornelia Fm 83ndash709 possible bitumen at 4537 m 7287400N Fm Mundadjini 1 319056E 170 600 500 Mundadjini 16ndash361 Spearhole Fm 361ndash600 10 fluorescence at 36102 m 7404844N Fm Boondawari 1 348959E 299 1 367 490 Mundadjini Fm 15ndash312 Spearhole Fm 312ndash1 283 Intrusive 1 283ndash1 367 40 fluorescence at 35364 m 5 7398174N fluorescence at 4963 m Akubra 1 334249E 15 181 530 Mundadjini 15ndash42 Intrusive 42ndash181 None 7401252N Fm
21
50 km
120deg 121deg30 123deg
25deg
24deg
23deg
22deg
Greater Officer Basin
Savory Sub-basin
1
2
3
4
6
8
3 Seismic line (prefixed N83-00)
Aeromagnetic survey
GS
WA
Sav
ory
1995
gra
vity
sur
vey
Gravity survey
MKS34270398
Figure 8 Locations of aeromagnetic and gravity surveys (other than regional BMRAGSO data)
22
sandstones in two petroleum wells in the northwest of the sub-basin and bitumen and oil shows
elsewhere in the region indicate that oil has been generated and migrated through the sub-basin
Source rocks
Source potential is considered to be the major exploration risk in the Savory Sub-basin although
minor oil shows in Mundadjini 1 and Boondawari 1 indicate that at least some oil has been
generated and migrated into potential reservoirs within the sub-basin Sandstone is the
predominant lithology observed in outcrop Outcrops of fine-grained lithologies in the basin are
rare because of intense surface weathering and erosion Only about 8 of the surface area of the
sub-basin is exposed bedrock and recessive lithologies (such as shale evaporite and friable
sandstone) may be present although they rarely outcrop
Outcrops of stromatolitic dolomite with associated cauliflower chert and cubic pseudomorphs
interpreted as being after halite indicate that evaporitic environments are present within the
Mundadjini Skates Hills and Boondawari Formations Evaporitic minerals are also present in
drillhole LDDH1 in the Tarcunyah Group
In 1995 GSWA drilled a continuous-core diamond drillhole (Trainor 1) in the sub-basin on
TRAINOR to a depth of 709 m to test for source rocks thus providing the first such data for the sub-
basin The drillhole intersected flat-lying clastics and carbonates of the McFadden Formation (9ndash
83 m) overlying indurated mudstones of the Cornelia Formation (83ndash709 m total depth) dipping at
about 40deg Of the six samples analysed from the Cornelia Formation in this drillhole the five
located between 375 and 6032 m depth have TOC values exceeding 05 (range 066ndash365)
Rock-Eval pyrolysis of these five samples indicates that they are at best in the dry-gas thermal
stage and as a result of their high level of maturation (Stevens and Adamides in prep) have poor
remaining hydrocarbon-generating potential Although the Cornelia Formation is overmature at
Trainor 1 the high TOC values are encouraging as it is likely that this sequence is less mature
elsewhere in the sub-basin
The Mundadjini Formation contains potential source rocks that comprise marine mudstones
with evaporitic minerals present in parts Thin dark mudstones were intersected in the Mundadjini
Formation in Akubra 1 In Mundadjini 1 and Boondawari 1 however the mudstones appear to be
too oxidized to have source potential
The Boondawari Formation also may be a source rock as it contains black mudstones The
unit is laterally equivalent to the Pertatataka Formation of the Amadeus Basin and the Ungoolya
23
Group of the Officer Basin in South Australia both of which have some source potential
(Summons and Powell 1991 Morton and Drexel 1997) Samples from the Dey Dey Mudstone of
the Ungoolya Group generally have poor TOC values (average 011 range 003ndash081)
moderate hydrogen index (HI) values (100ndash382) and poor to fair genetic potential with a
maximum of 292 kg hydrocarbon per tonne of source rock (Morton and Drexel 1997)
Stromatolitic dolomites and mudstones at the top of the Boondawari Formation and within the
Skates Hills Formation are potential source rocks Stromatolitic dolomite and evaporitic rocks
deposited in a marginal marine to sabkha environment are considered to have good potential to
generate and preserve organic carbon without requiring a deep-water setting (Stevens and Grey
1997) Such conditions are recognized in the Skates Hills Formation and in the upper parts of the
Tarcunyah Group
Maturity
Knowledge of the maturity of sedimentary rocks within the Savory Sub-basin is still limited From
a review of palynological studies Grey and Stevens (1997) report that the thermal maturity
inferred from the Thermal Alteration Index (TAI) of 3+ from Supersequence 1 age palynomorphs
in TWB 6 TWB 9 and LDDH1 is within the hydrocarbon window (Appendix 3) In Phanerozoic
spores and pollen a TAI of 3+ approximately equates to the end of liquid petroleum generation
and the start of dry gas generation and to a vitrinite reflectance of about 13 (Traverse 1988)
However the use of TAI for estimating thermal maturity from Neoproterozoic palynomorphs
requires calibration
In Trainor 1 the Cornelia Formation contains organically rich claystones between 375 and
6032 m depth Based on Rock-Eval maturity data (Stevens and Adamides in prep) and the dark
colour of poorly preserved organic material (Grey 1995de 1996) with TAI 4- to 5 all samples
had a high level of maturation with at best dry-gas generating potential remaining In contrast
drillhole LDDH1 on GUNANYA recorded lower levels of maturity (TAI values of 3+) with two of
sixteen samples from the Tarcunyah Group having greater than 1 TOC (Grey 1995abc Grey
and Cotter 1996) Organic petrology and Rock-Eval maturity data for samples from LDDH1
indicate that the section above 500 m is within the oil-generative window whereas below 500 m
the rocks are within the gas window (Ghori in prep Fig 9 Appendix 5)
Waterbores TWB 1 2 6 and 9 which are located on TRAINOR in the southeast of the sub-
basin all had organic matter with TAI values of 3+ from the McFadden Skates Hills Cornelia
and Brassey Range Formations respectively
24
100
200
300
400
500
600
700
Oil
gene
ratin
g
Gas
gene
ratin
g
Fai
r
Fai
r
Poo
r
Poo
r
Goo
d
Imm
atur
e
Oil
win
dow
Oil
win
dow
Imm
atur
e
01 0110 10 0 150 300 440 480 1
Neo
prot
eroz
oic
TOC S1+S2 mgg Hydrogen Index Tmax degC
Depth(m)
Organicrichness
Generatingpotential
Kerogentype Maturity Maturity
TD=701m
Sandstone
Mudstone
Dolomite
Limestone
Evaporite
Source rock
MKS40 070498
Ro equivalent
Figure 9 Petroleum source potential of rocks in Normandy LDDH1
Small amounts of organic matter associated with basalt and dolerite in cuttings from
waterbore BWB 1 on BULLEN showed high levels of thermal maturity (Grey 1995a Libby 1995)
It is unclear whether all sedimentary rocks on BULLEN are overmature for hydrocarbon generation
or the results from BWB 1 are related to local heating events associated with the volcanic bodies
that are common in the Jilyili Formation
25
Reservoirs
Each of the five depositional sequences of the Savory Group (Table 1) are inferred to contain
significant sandstone reservoirs with the possible exception of depositional sequence C as
discussed above in Stratigraphy The Spearhole Formation was cored in Mundadjini 1 and
Boondawari 1 and visual estimates of porosity vary from generally poor (less than 5) to fair
(approximately 5ndash15) The McFadden Formation in Trainor 1 has porosity values of up to 232
and a maximum permeability of 195 md (Stevens and Adamides in prep) Sandstones from
Neoproterozoic formations form the acquifers in the following waterbores the McFadden
Formation in TWB 1 the Cornelia Formation in TWB 6 and the Brassey Range Formation in
TWB 8 and TWB 9 (Appendix 6 Table 61)
Based on outcrop observations the Durba Sandstone is considered to be the best reservoir of
the Savory Group Similarly some sandstones from the Tarcunyah Group also have good visible
porosity in outcrop
Dolomites occur in several formations in the sub-basin Reservoir potential may exist
particularly where the dolomites are stromatolitic and oolitic However dolomites have not been
drilled in the sub-basin and porosity can only be inferred from the preferential silicification of
some stromatolite bioherms observed in outcrop (Stevens and Grey 1997) Elsewhere in the
Officer Basin porosities of up to10 have been measured in dolomites A limestone breccia
(karst) is described from 663 to 677 m in drillhole LDDH1 (Fig 6 Busbridge 1994)
Seals
Indications of evaporitic environments in the Mundadjini Skates Hills and Boondawari
Formations are described by Williams (1992) In Mundadjini 1 from 287 to 337 m anhydrite and
chert occurs as nodules beds and veins in mudstone of the Mundadjini Formation Evaporitic
minerals (predominantly gypsum) are described in the Tarcunyah Group in LDDH1 The presence
of the Woolnough and Madley salt diapirs in the Officer Basin (approximately 110 km east of the
sub-basin) and halite beds over 25 m thick in the well Hussar 1 (130 km east of the sub-basin)
provide further evidence that evaporite seals may be present in the Savory Sub-basin
Mudstones and shales form only a small proportion of the limited Neoproterozoic outcrop in
the sub-basin but significant thicknesses of mudstone were encountered in the Mundadjini
Formation in Mundadjini 1 and Boondawari 1 the Tarcunyah Group in LDDH1 and in the
26
Cornelia Formation in Trainor 1 These data suggest that mudstones form a significant proportion
of strata in the sub-basin despite their limited outcrop
Traps
Potential structural closures including folds and faults occur at various scales throughout the
Savory Sub-basin However the region has only been mapped at 1250 000 scale and
independently closed structures such as domes have yet to be confirmed The western margin of
the basin contains abundant faults (with a northeast strike) but elsewhere faults are less common
Some anticlines are recognized in outcrop including one with a strike length of up to 45 km
inferred from surface bedding dips in the Mundadjini and Spearhole Formations at approximately
24deg15rsquoS 121deg10rsquoE on BULLEN (Fig 1)
Salt diapirs and other halokinetic structures are recognized in outcrop well and seismic data
in the Officer Basin to the west of the Savory Sub-basin and it is probable that there are
significant thicknesses of evaporitic sedimentary rocks in the sub-basin The gravity field data
suggest there is good potential for salt diapirs and traps related to halokinesis
Although there is potential for stratigraphic traps to be present in the sub-basin insufficient
data are available to assess them
Preservation of hydrocarbons
The range of thermal maturities measured to date and the large periods of time envisaged for
deposition of sediments implies hydrocarbon generation may have occurred a number of times
during the evolution of the Savory Sub-basin Any hydrocarbons that were generated early may
have been trapped in palaeostructures and remigration to younger traps could have taken place
later The Petermann Ranges Orogeny which has been equated with the Paterson Orogeny (Myers
1990) is believed to have occurred in the latest Neoproterozoic to early Cambrian This is the last
major tectonic event recognized in the sub-basin suggesting that it is reasonable to expect that trap
integrity will have been preserved
If the inference of the presence of thick halite beds in the sub-basin is correct the preservation
potential of sub-salt traps should be excellent
27
Reported hydrocarbon shows and oil seep
Amadeus Petroleum recorded minor oil shows in cores from Mundadjini 1 and Boondawari 1 In
Mundadjini 1 at 36102 m (top of the Spearhole Formation) a 3 mm thick zone had 10 moderate
white fluorescence with slow solvent cut This show was in a granular sandstone with visually
estimated porosity of about 10 In Boondawari 1 at 35364 m (within the Spearhole Formation) a
broken surface of sandstone had 40 moderate yellow-white fluorescence with slow solvent cut
Visually estimated porosity is about 5 Because the fluorescing surface was broken during the
drilling process this show could have resulted from contamination A second show occurs in
Boondawari 1 at 4963 m (within the Spearhole Formation) where a 1 cm-thick zone had 5 dull
yellow fluorescence with slow solvent cut in a conglomerate with visually estimated porosity of
about 10 The company intends to further investigate the nature of these occurrences
Minor bitumen is present at 6623 m in drillhole LDDH1 on GUNANYA (Figs 5 and 6) as a
vein in mudstones of the Tarcunyah Group A sample was analysed by gas chromatography
(Ghori in prep) and confirmed that it is natural bitumen (Appendix 5)
Mineral hole OD 23 drilled by Jubilee Gold Mines NL on NABBERU in the Bangemall Basin
immediately to the south of the Savory Sub-basin (Fig 5) encountered bitumen and trace oil in
vugs in dolomite (M Stevens unpublished data) but no further data are available at present
In their popular guide to the Canning Stock Route Gard and Gard (1990 p 218) refer to an
oil seep at Well 13 on TRAINOR (Fig 5) They reported that between 1977 and 1984 lsquonatural oilrsquo
was seen in the well Although the well is now largely filled with sediment four auger drill
samples were collected by the GSWA in 1995 and all four were analysed for oil shows One
sample from 315 m total depth (GSWA sample 135604) yielded just enough extract (519 ppm)
for saturate gas chromatography analysis The gas chromatograph (Appendix 5) shows that the
extract does contain some hydrocarbons probably from recent plant material Because the depth to
the oil was not quoted in Gard and Gard (1990) the hand-augered well may not have been deep
enough to properly test this reported seep
Geological and geophysical databases
Geological and geophysical data available for the Savory Sub-basin are limited The most recently
completed geological maps for the sub-basin were published by the GSWA between 1991 and
1995 (Williams and Tyler 1991 Williams 1992 1995ab)
28
The cores from the five drillholes listed in Table 2 believed to be all of the core available
from the sub-basin are available for inspection at GSWA Mineral exploration reports submitted
to GSWA may be searched using the WAMEX database and open-file reports are available on
microfiche Geophysical data acquired by the mining industry is not required to be filed with
GSWA if acquired over Vacant Crown Land which is the case for much of the sub-basin
Geophysical survey data submitted in mining tenement reports and which extend into Vacant
Crown Land remain confidential to the companies Original regional aeromagnetic and gravity
datasets are available from the Australian Geological Survey Organisation (AGSO)
Data pertinent to oil exploration in the sub-basin such as structural style and salt diapirism
are presented in a review of the hydrocarbon prospectivity of the Officer Basin (Perincek 1998)
Drilling
Significant drillholes in the sub-basin are summarized in Table 2
Petroleum industry data
Amadeus Petroleum drilled three petroleum exploration wells in the central west of the Savory
Sub-basin in late 1997 These wells Mundadjini 1 Boondawari 1 and Akubra 1 were drilled by
continuous diamond coring (Figs 5 and 6) All targeted potential reservoirs within the Spearhole
Formation with the Mundadjini Formation as the proposed seal The wells were located on
structures interpreted from Landsat images and limited geological investigations Both Mundadjini
1 and Boondawari 1 had minor oil shows as discussed above (Reported hydrocarbon shows)
Government data
Stratigraphic drillhole Trainor 1 was drilled by GSWA in 1995 (Stevens and Adamides in prep)
and the main results are discussed above (Source rocks and Maturity)
Mineral industry data
Normandy Exploration drillhole LDDH1 was cored in the Tarcunyah Group to a total depth of
701 m and provided source-rock and maturity data as discussed above
29
Oilmin NL drilled six percussion drillholes (BD 1 3 4 5 8 and 9) through sandstones and
shales in the northern part of the Savory Sub-basin to a maximum depth of 198 m (Fig 5
WAMEX Microfiche File M 26811 I 2610) but only brief geological descriptions are available
Hydrogeological data
Hydrogeological data within the Savory Sub-basin are limited although a long history of water
exploration extends back to the construction of the Canning Stock Route early this century No
detailed geological or wireline logs are available for the older wells along this route A few station
wells have been drilled by various methods on the south and west margins of the basin but data
are unavailable as reports are not required to be filed with the government Depth to watertable
throughout the basin is largely controlled by porosity of the bedrock
The GSWA drilled fifteen waterbores in the winter of 1995 in the southern part of the sub-
basin in preparation for the drilling of Trainor 1 and the proposed Bullen 1 Twelve bores found
water and six of these bores have salinities of less than 1000 mgL (Fig 5 Appendix 6 Table 61)
One waterbore TWB 6 has gamma ray and neutron logs run through PVC casing and these are
available from the GSWA with the digital log data included herein
Seismic data
No geophysical data have been acquired by the petroleum industry in the Savory Sub-basin
Seismic data acquired in the Officer Basin to the east particularly in the Gibson and Yowalga
Sub-basins is pertinent to structural interpretation in the Savory Sub-basin (Perincek 1996a
1998)
Aeromagnetic surveys
Government data
There are over 95 277 line kilometres of aeromagnetic data included in the AGSO dataset There
are three regional aeromagnetic surveys covering the Savory Sub-basin These were flown by the
Bureau of Mineral Resources (BMR now AGSO) in 1984 at a line spacing of 1500 m with 36 740
and 52 587 line kilometres flown and by Aerodata in 1984 at a line spacing of 1000m with 5950
line kilometres flown These data were reprocessed and interpreted for GSWA by Cowan (1995)
An edited copy of this report is included as Appendix 4 and the original report is filed in the
GSWA Library under S-series reports item 10331
30
Mineral industry data
The approximate locations of non-AGSO aeromagnetic surveys are shown in Figure 8 More
detailed information regarding the location of these surveys may be obtained using the GSWA
MAGCAT II database Additional information such as contours of aeromagnetic values may be
obtained by inspecting items on file with the GSWA
Gravity surveys
Government data
The average spacing for gravity data in the Savory Sub-basin is one station per 121 km2 (11 times 11
km grid) These data were principally collected by BMR in the early 1960s There are a few
additional regional gravity traverses across the sub-basin which are also included in the
BMRAGSO dataset These data were reprocessed and interpreted for GSWA (Fig 10) and a
report on this work is also included in Appendix 4
The GSWA completed a large semi-detailed gravity survey in the eastern Savory Sub-basin
utilizing helicopter support and Differential Global Positioning Survey (DGPS) techniques (Fig
8) This gravity survey completed in August 1995 consists of 2300 gravity stations on a 2 times 3 km
grid All stations were acquired by helicopter using Scintrex gravimeters and Ashtek dual
frequency DGPS equipment for determining location This highly efficient system allowed the
acquisition of more than 100 gravity stations per day in remote areas The resolution of this survey
is +30 cm and +05 microms-2 (Daishsat 1995) These data (Fig 11) represent a significant
improvement on the previous regional survey data and are available from GSWA (GSWA
1996ab) The results of the interpretation of these data were presented at the 1997 ASEG
Convention (Carlsen and Shevchenko 1997)
Mineral industry data
Three small gravity surveys were conducted by Oilmin NL (Fig 8) and the relevant WAMEX
reports are M 2681I 2610 I 2435 I 2567 These three surveys are of limited value because height
control was provided by barometers only and the surveys were not tied to the national gravity grid
31
23deg
25deg
120deg 122deg
Trainor 1
SAVORY
SUB-BASIN
MKS54 160498
100 km
1995 SavoryGravity Survey
254
-1056
micromsec2
Figure 10 Regional Bouguer gravity map of the Savory Sub-basin
23deg
24deg
25deg
122deg30 123deg
TRAINOR 1
123deg30
50 km
MKS53 160498
-116
-626
micro msec2
Figure11 Detailed Bouguer gravity map of the
Savory 1995 Gravity Survey from the eastern Savory Sub-basin
32
Government and academic reports
Chronostratigraphy and geochemistry
The understanding of Neoproterozoic organic chemistry palynology and structural evolution is
essential to the interpretation of hydrocarbon prospectivity Pertinent reports are included in the
bibliography (Appendix 1) Unpublished palaeontology reports describe the palynology of wells in
the Savory Sub-basin (Grey 1995andashe 1996a) Grey and Cotter (1996) discussed the potential for
Neoproterozoic palynomorphs to provide a biostratigraphic framework and palaeoenvironmental
interpretation Grey and Stevens (1997) reviewed the results of palynological studies of wells
drilled in the sub-basin and reported that Supersequence 1 palynomorphs are present in TWB 6
TWB 9 and LDDH1 (Appendix 3) Grey (1996b) reported on the use of stromatolites for
correlation in the Neoproterozoic and Stevens and Grey (1997) discussed the application of
stromatolite biostratigraphy in correlating isolated dolomite outcrops in the sub-basin with well
and seismic data in the Officer Basin and Centralian Superbasin
Although geochemical data from the Savory Sub-basin are very limited results mostly
confirm thermal maturities inferred from TAI for LDDH1 and Trainor 1 (Ghori in prep Stevens
and Adamides in prep) Those parts of the Officer Basin in Western Australia which lie to the
east of the Savory Sub-basin are sparsely drilled but Ghori (in prep) reports that most of the
Neoproterozoic succession presently lies within the oil-generative window However his study
has been unable to identify effective source-rock units and the source for oil shows Thin source
rocks are present in the Neoproterozoic in LDDH1 (Fig 9) and in three wells which lie to the east
and southeast of the Savory Sub-basin namely NJD 1 Kanpa 1A and Yowalga 3
Proposed work program
From the above limited information it is concluded that additional research on the hydrocarbon
potential of the sub-basin is justified and proposals are outlined below
bull Additional modelling of gravity and aeromagnetic data from the Savory Sub-basin is required
in light of the results from Trainor 1 and Boondawari 1 Trainor 1 showed that what appeared
to be a structurally simple area based on outcrop aeromagnetic and gravity data was in fact an
area of major structuring Boondawari 1 intersected a dolerite which is in good depth
agreement with aeromagnetic depth to source results showing this technique is useful in
detecting the depth to intrusive bodies
33
bull Additional data from mineral and petroleum exploration bores may become available and
analysis of samples from these wells should be undertaken and interpreted in the context of
their relevance to the Officer Basin
bull Stratigraphic coring in the Blake Fault and Fold Belt and in the Wells Foreland Sub-basin (Fig
1) targeting source rocks is considered essential to the continuing evaluation of the
hydrocarbon prospectivity of the Savory Sub-basin
bull Correlations using at least outcrop well and potential-field data should be prepared to link the
sub-basin with the better known parts of the Officer Basin to the east
bull Remapping is required to clarify boundary positions within the Cornelia Formation this may
resolve some of the current problems of the relationship between this unit and the rest of the
Savory Sub-basin
bull Further work is required to explain the Early Cambrian or Sturtian ages interpreted for the
Cornelia Formation from sedimentary zircon UndashPb dating in drillhole Trainor 1 The
determination of the age of the organically rich but overmature claystones in this well is
critical to assessing the hydrocarbon potential of the region
bull The thin dark mudstones intersected by Akubra 1 in the Mundadjini Formation warrant
geochemical analysis Analyses of the oil shows in Mundadjini 1 and Boondawari 1 are
currently being undertaken by Amadeus Petroleum
bull Geochemical analysis of hydrocarbons in the Bangemall Basin drillhole OD23 has been
performed by Jubilee Gold and the results will be reviewed when they are submitted to
GSWA The possibility of source rocks within the Bangemall Basin charging traps within the
Bangemall Basin and the overlying Savory Sub-basin requires further investigation
Conclusions
The Savory Sub-basin is a frontier region with only three recently drilled petroleum exploration
wells and no seismic data Based on existing geological and geophysical data it is considered too
early to draw conclusions about the hydrocarbon prospectivity of the sub-basin at this stage and
there are several reasons why the area warrants further investigation
34
1 Thick accumulations of sedimentary rocks are present (up to 8 km thickness inferred) which
may contain source reservoir and sealing strata
2 Minor oil shows occur in Mundadjini 1 and Boondawari 1 and bitumen is present in mineral
exploration drillhole LDDH1 suggesting that hydrocarbons have migrated within the
Neoproterozoic sequence of the Savory Sub-basin Oil and bitumen are present in mineral
exploration drillhole OD23 in the Bangemall Basin immediately to the south of the Savory
Sub-basin and it is possible that source rocks from the Bangemall Basin could charge traps in
the overlying Savory Sub-basin
3 The age of sedimentary rocks in the sub-basin is still poorly constrained but some of the
Neoproterozoic sedimentary rocks located on GUNANYA and TRAINOR are within the
hydrocarbon-generation window It is possible that a significant thickness of Phanerozoic
sedimentary rocks may also be present
4 Friable sandstones with visible porosity outcrop extensively suggesting numerous potential
reservoirs
5 Significant but not intense faulting and folding has been mapped implying large structural
traps may be present
6 Evaporitic sedimentary rocks occur in several formations and may provide good source rocks
and excellent seals
35
References
APAK S N and CARLSEN G M 1997 A compilation and review of data pertaining to the
hydrocarbon prospectivity of the Canning Basin Western Australia Geological Survey
Record 199610 103p
BAGAS L GREY K and WILLIAMS I R 1995 Reappraisal of the Paterson Orogen and
Savory Basin Western Australia Geological Survey Annual Review 1994ndash95 p 55ndash63
BUSBRIDGE M 1994 Lake Disappointment Exploration Licence 451064 Third Annual
Report Lake Disappointment Diamond Drill Hole LDDH1 Normandy Exploration Limited
Western Australia Geological Survey M-series Item 7567 A41358 (unpublished)
CARLSEN G M and SHEVCHENKO S I 1997 Petroleum exploration in Proterozoic basins
using potential fields data and stratigraphic coring Australian Society of Exploration
Geophysicists 12th Geophysical Conference Handbook Sydney 1997 Preview no 66 p 83
(abstract only)
COWAN D 1995 Savory Basin quantitative magnetic interpretation Western Australia
Geological Survey S-series S10331 (unpublished)
DAISHSAT PTY LTD 1995 Operational and processing report Savory Basin gravity survey
Western Australia Geological Survey S-series S10332 (unpublished)
GARD E and GARD R 1990 Canning Stock Route a travellerrsquos guide for a journey through
history Perth Western Australia Western Desert Guides 448p
GEOLOGICAL SURVEY OF WESTERN AUSTRALIA 1996a Savory Basin first vertical
derivative of Bouguer gravity image 1250 000 Western Australia Geological Survey
GEOLOGICAL SURVEY OF WESTERN AUSTRALIA 1996b Savory Basin Bouguer gravity
image 1250 000 Western Australia Geological Survey
GHORI K A R in prep Petroleum source rock potential and thermal history Officer Basin
Western Australia Western Australia Geological Survey Record
36
GREY K 1995a Savory Basin drillhole BWB 1 (Bullen waterbore) palynology and thermal
maturation GSWA Palaeontology Report no 199512 (unpublished)
GREY K 1995b Savory Basin drillholes TWB 1 2 6 9 (Trainor waterbores) palynology and
thermal maturation GSWA Palaeontology Report no 199520 (unpublished)
GREY K 1995c Palynology of Normandy-Poseidon Lake Disappointment-1 corehole
Tarcunyah Group Paterson Orogen GSWA Palaeontology Report no 199521 (unpublished)
GREY K 1995d Savory Basin drillhole Trainor 1 (Trainor diamond drilling) palynology and
thermal maturity GSWA Palaeontology Report no 199524 (unpublished)
GREY K 1995e Savory Basin drillhole Trainor 1 (Trainor diamond drilling) Additional
Preparation of two samples GSWA Palaeontology Report no 199528 (unpublished)
GREY K 1995f Neoproterozoic stromatolites from the Skates Hills Formation Savory Basin
Western Australia and a review of the distribution of Acaciella australica Australian Journal
of Earth Sciences v 42 p 123ndash132
GREY K 1996a Savory Basin drillhole Trainor 1 (Trainor diamond drilling) Additional
samples palynology and thermal maturation GSWA Palaeontology Report no 199615
(unpublished)
GREY K 1996b Preliminary stromatolite correlations for the Neoproterozoic of the Officer
Basin and a review of Australia-wide correlations GSWA Palaeontology Report no 199615
(unpublished)
GREY K and COTTER K L 1996 Palynology in the search for Proterozoic hydrocarbons
Western Australia Geological Survey Annual Review for 1995ndash96 p 70ndash80
GREY K and STEVENS M K 1997 Neoproterozoic palynomorphs of the Savory Sub-basin
Western Australia and their relevance to petroleum exploration Western Australia
Geological Survey Annual Review for 1996ndash97 p 49ndash54
HUBBARD R J PAPE J and ROBERTS D G 1985 Depositional sequence mapping as a
technique to establish tectonic and stratigraphic framework and evaluate hydrocarbon
potential on a passive continental margin in Seismic stratigraphy II an integrated approach
37
edited by O R BERG and D G WOOLVERTON American Association of Petroleum
Geologists Memoir 39 p 79ndash91
LIBBY WG 1995 A petrological report on six samples of bore cuttings from the Savory Basin
Western Australia Western Australia Geological Survey S-series S31307 (unpublished)
MORTON JGG and DREXEL JF 1997 The petroleum geology of South Australia Vol 3
Officer Basin South Australia Department of Mines and Energy Resources Report Book
9719
MUHLING P C and BRAKEL A T 1985 Geology of the Bangemall Group mdash the evolution
of an intracratonic Proterozoic basin Western Australia Geological Survey Bulletin 128
219p
MYERS J S 1990 Precambrian tectonic evolution of part of Gondwana southwestern Australia
Geology v18 p 537ndash540
NELSON D R 1997 Compilation of SHRIMP UndashPb zircon data Western Australia Geological
Survey Record 19972 196p
PAYTON C E 1977 Seismic stratigraphy mdash applications to hydrocarbon exploration
American Association of Petroleum Geologists Memoir 26 516p
PERINCEK D 1996a The age of NeoproterozoicndashPalaeozoic sediments within the Officer Basin
of the Centralian Super-basin can be constrained by major sequence-bounding unconformities
APPEA Journal v 36 pt 1 p 350ndash368
PERINCEK D 1996b The stratigraphic and structural development of the Officer Basin
Western Australia a review Western Australia Geological Survey Annual Review 1995ndash
1996 p 135ndash148
PERINCEK D 1998 A compilation and review of data pertaining to the hydrocarbon
prospectivity of the Officer Basin Western Australia Geological Survey Record 19976
POSAMENTIER H W JERSEY M T and VAIL P R 1988 Eustatic controls on clastic
deposition 1 mdash Conceptual framework in Sea-level changes an integrated approach edited by
C K WILGUS B S HASTINGS C G St C KENDALL H W POSAMENTIER
38
C A ROSS and J C VAN WAGONER Society of Economic Paleontologists and
Mineralogists Special Publication no 42
STEVENS M K and ADAMIDES N G in prep GSWA Trainor 1 well completion report
Savory Sub-basin Officer Basin Western Australia with notes on petroleum and mineral
potential Western Australia Geological Survey Record 199612
STEVENS M K and GREY K 1997 Skates Hills Formation and Tarcunyah Group Officer
Basin mdash carbonate cycles stratigraphic position and hydrocarbon prospectivity Western
Australia Geological Survey Annual Review for 1996ndash97 p 55ndash60
SUMMONS RE and POWELL C McA 1991 Petroleum source rocks of the Amadeus Basin
in Geological and geophysical studies in the Amadeus Basin central Australia edited by R J
KORSCH and JM KENNARD Australia BMR Geology and Geophysics Bulletin 236
TRAVERSE A 1988 Palaeopalynology Boston Unwin Hyman 600p
VAIL P R MITCHUM R M Jr TODD R G WIDMIER J M THOMPSON S III
SANGREE J B BUBB J N and HATLELID W G 1977 Seismic stratigraphy and
global changes of sea level in Seismic stratigraphy mdash applications to hydrocarbon
exploration edited by C E PAYTON American Association of Petroleum Geologists
Memoir 26 516p
WALTER M R and GORTER J 1994 The Neoproterozoic Centralian Superbasin in Western
Australia the Savory and Officer Basins in The sedimentary basins of Western Australia
edited by P G PURCELL and R R PURCELL Petroleum Exploration Society of Australia
Symposium Perth WA 1994 Proceedings p851ndash864
WALTER M R GREY K WILLIAMS I R and CALVER C R 1994 Stratigraphy of the
Neoproterozoic to early Palaeozoic Savory Basin and correlation with the Amadeus and
Officer Basins Australian Journal of Earth Sciences v 41 p 533ndash546
WALTER M R VEEVERS J J CALVER C R and GREY K 1995 Neoproterozoic
stratigraphy of the Centralian Superbasin Australia Precambrian Research v 73 p 173ndash195
WILLIAMS I R 1992 Geology of the Savory Basin Western Australia Western Australia
Geological Survey Bulletin 141 115p
39
WILLIAMS I R 1995a Bullen WA (2nd Edition) Western Australia Geological Survey
1250 000 Geological Series Explanatory Notes 23p
WILLIAMS I R 1995b Trainor WA (2nd Edition) Western Australia Geological Survey
1250 000 Geological Series Explanatory Notes 31p
WILLIAMS I R and TYLER I M 1991 Robertson WA (2nd edition) Western Australia
Geological Survey 1250 000 Geological Series Explanatory Notes 36p
40
41
Appendix 1
Bibliography
Reports which are relevant to this investigation but which are not specifically cited are listed
below
BAILLIE P W POWELL C McA LI Z X and RYALL A M 1994 The tectonic
framework of Western Australiarsquos Neoproterozoic to recent sedimentary basins in The
sedimentary basins of Western Australia edited by P G PURCELL and R R PURCELL
Petroleum Exploration Society of Australia Symposium Perth WA 1994 Proceedings p
45ndash62
BRADSHAW M T BRADSHAW J MURRAY A P NEEDHAM D J SPENCER L
SUMMONS R E WILMOT J and WINN S 1994 Petroleum systems in West Australian
basins in The sedimentary basins of Western Australia edited by P G PURCELL and R R
PURCELL Petroleum Exploration Society of Australia Symposium Perth WA 1994
Proceedings p 93ndash118
CLARKE G L 1991 Proterozoic tectonic reworking in the Rudall Complex Western Australia
Australian Journal of Earth Science v38 p 31ndash44
COCKBAIN A E and HOCKING R M 1990 Phanerozoic in Geology and mineral resources
of Western Australia Western Australia Geological Survey Memoir 3 p 750ndash755
ETHERIDGE M and WALL V 1994 Tectonic and structural evolution of the Australian
Proterozoic 12th Australian Geological Convention Geological Society of Australia
Abstracts no 37 p 102ndash103
GOODE A D T 1981 Proterozoic geology of Western Australia in Precambrian of the
Southern Hemisphere Developments in Precambrian geology 2 edited by I R HUNTER
Amsterdam Elsevier p 105ndash203
GREY K and JACKSON M J 1983 A re-assessment of stromatolite evidence for the
correlation of the Late Proterozoic Neale and Ilma Beds Officer Basin Western Australia
Australia BMR Journal of Australian Geology and Geophysics v 8 p 359
42
HICKMAN A H WILLIAMS I R and BAGAS L 1994 Proterozoic geology and
mineralization of the TelferndashRudall region Paterson Orogen Geological Society of Australia
(WA Division) Excursion Guidebook no 5 56p
HOCKING R M MORY A J and WILLIAMS I R 1994 An atlas of Neoproterozoic and
Phanerozoic basins of Western Australia in The sedimentary basins of Western Australia
edited by P G PURCELL and R R PURCELL Petroleum Exploration Society of Australia
Symposium Perth WA 1994 Proceedings p 21ndash 44
JACKSON P R 1966 Geology and review of exploration Officer Basin Western Australia
Hunt Oil Company Western Australia Geological Survey S-series S26 (unpublished)
JACKSON M J 1971 Notes on a geological reconnaissance of the Officer Basin Western
Australia Australia BMR Geology and Geophysics Record 19715 30p
JACKSON M J and van de GRAAFF W J E 1981 Geology of the Officer Basin Western
Australia Australia BMR Geology and Geophysics Bulletin 206 102 p
LOWRY D C JACKSON M J van de GRAAFF W J E and KENNEWELL P J 1971
Preliminary result of geological mapping in the Officer Basin Western Australia Western
Australia Geological Survey Annual Report for 1971 p 50ndash56
MYERS J S 1990 Precambrian in Geology and mineral resources of Western Australia
Western Australia Geological Survey Memoir 3 p 737ndash750
MYERS J S SHAW R D and TYLER I M 1994 Proterozoic tectonic evolution of
Australia 12th Australian Geological Convention Geological Society of Australia Abstracts
no 37 p 312
NEDIN C and JENKINS R J F 1991 Re-evaluation of unconformities separating the
lsquoEdiacaranrsquo and Cambrian systems South Australia Palaios v 6 p 102ndash108
PHILLIPS B J JAMES A W and PHILIP G M 1985 The geology and hydrocarbon
potential of the north-western Officer Basin APEA Journal 25 (1) p 52ndash61
POWELL C McA LI Z X McELHINNY M W MEERT J G and PARK J K 1993
Paleomagnetic constraints on timing of the Neoproterozoic breakup of Rodinia and Cambrian
formation of Gondwana Geology v 21 p 889ndash892
43
POWELL C McA PREISS W V GATEHOUSE C G KRAPEZ B and LI Z X 1994
South Australian record of a Rodinian epicontinental basin and its mid-Neoproterozoic
breakup to form the Palaeo-Pacific Ocean Tectonophysics v 237 no 3ndash4 p 113ndash140
PREISS W V 1976 Proterozoic stromatolites from the Nabberu and Officer Basins Western
Australia and their biostratigraphic significance South Australia Geological Survey Report
of Investigations no 47 p 1ndash51
TOWNSON W G 1985 The subsurface geology of the western Officer Basin mdash results of
Shellrsquos 1980ndash1984 petroleum exploration campaign APEA Journal v 25 (1) p 34ndash51
WATTS K J 1982 The geology of the Townsend Quartzite Upper Proterozoic shallow water
deposit of the Northern Officer Basin Western Australia Perth University of Western
Australia BSc honours thesis (unpublished)
WELLS A T and KENNEWELL P J 1974 Evaporite exploration in the Officer Basin
Western Australia at the Madley Diapirs Australia BMR Record 1974194 (unpublished)
WILLIAMS I R and MYERS J S 1990 Paterson Orogen in Geology and mineral resources
of Western Australia Western Australia Geological Survey Memoir 3 p 274ndash286
WILLIAMS I R 1990 Savory Basin in Geology and mineral resources of Western Australia
Western Australia Geological Survey Memoir 3 p 329ndash334
WILLIAMS I R 1994 The Neoproterozoic Savory Basin Western Australia in The
sedimentary basins of Western Australia edited by P G PURCELL and R R PURCELL
Petroleum Exploration Society of Australia Symposium Perth WA 1994 Proceedings p
841ndash850
WILSON R B 1967 Woolnough Hills and Madley diapiric structures Gibson Desert WA
APEA Journal v 7 p 94ndash102
44
Appendix 2
Meteorological data (from Bureau of Meteorology Perth 1994)
Table 21 Wiluna rainfall (mm)
Year Jan Feb Mar Apr May Jun Jul Aug Sept Oct Nov Dec
1975 0 45 446 309 306 59 276 4 34 886 638 164 1976 16 154 12 138 53 16 34 62 12 238 0 2 1977 44 0 66 74 68 95 24 363 1 58 12 727 1978 234 522 94 16 0 96 367 24 16 353 185 45 1979 19 173 122 88 91 4 0 246 58 0 169 114 1980 148 764 68 1081 259 626 629 06 56 02 174 0 1981 123 476 192 32 196 118 44 74 14 0 28 312 1982 374 705 206 244 1079 92 02 143 368 526 368 118 1983 1 112 928 248 0 212 56 32 5 1 42 496 1984 149 7 342 84 836 0 348 132 224 04 16 172 1985 596 483 0 166 556 0 514 56 0 0 4 0 1986 0 154 35 0 0 1085 23 01 239 137 0 04 1987 1204 119 19 89 17 575 154 126 07 1 0 398 1988 46 202 164 13 388 0 202 104 0 0 224 1309 1989 207 234 26 703 278 536 57 0 01 0 144 02 1990 1035 23 281 46 126 53 94 218 44 9 42 0 1991 48 0 41 45 0 472 297 12 0 1 0 7 1992 112 96 1025 1227 323 65 04 174 0 132 48 4 1993 0 697 0 202 445 0 12 306 18 05 14 33 Mean 25 35 22 27 27 25 18 12 6 13 13 21
JAN FEB MAR APR MAY JUN JUL AUG SEP OCT NOV DEC0
10
20
30
40
Mea
n R
ain
fall
(mm
)
Month
Mean monthly rainfall in Wiluna
MKS41 140498
45
Table 22 Wiluna minimum temperature (degC)
Year Jan Feb Mar Apr May Jun Jul Aug Sept Oct Nov Dec
1975 ndash 23 203 15 94 63 71 62 103 124 169 205 1976 242 229 194 15 10 63 59 73 95 143 16 228 1977 243 25 197 148 96 95 56 86 102 ndash 188 23 1978 241 232 203 18 102 64 76 8 9 152 19 205 1979 255 226 216 167 83 6 59 79 97 145 198 223 1980 255 226 231 155 134 83 68 75 121 108 193 223 1981 245 216 19 182 119 6 54 78 138 159 163 218 1982 232 224 177 16 ndash ndash 37 111 112 164 209 225 1983 235 24 197 147 112 88 39 88 121 162 189 219 1984 241 243 191 156 ndash 72 66 7 95 161 182 211 1985 244 231 ndash 159 98 65 71 73 117 147 205 ndash 1986 ndash 229 226 155 93 96 43 49 10 122 ndash 219 1987 ndash 217 183 175 85 77 68 68 112 ndash ndash 221 1988 238 214 209 178 111 ndash ndash 86 104 157 171 195 1989 ndash 237 199 165 107 67 44 61 107 131 187 ndash 1990 232 ndash 211 155 118 62 57 87 102 149 195 22 1991 26 256 217 168 122 101 78 ndash 113 18 168 219 1992 227 227 214 169 102 98 59 69 ndash 125 159 196 1993 241 218 196 171 103 ndash 49 68 88 128 192 211 Mean 24 23 20 16 10 8 6 8 11 14 18 21
NOTE Dashes indicate data unavailable
JAN FEB MAR APR MAY JUN JUL AUG SEP OCT NOV DEC0
10
20
30
40
Month
MKS43 140498
50
Mean monthly minimum temperatures at Wiluna
Mea
n T
emp
erat
ure
(degC
)
46
Table 23 Wiluna maximum temperature (degC)
Year Jan Feb Mar Apr May Jun Jul Aug Sept Oct Nov Dec
1975 ndash 349 326 281 247 201 197 212 256 248 31 344 1976 374 369 346 297 248 206 208 225 265 287 313 388 1977 397 392 352 296 234 212 222 244 ndash 308 337 383 1978 378 345 346 316 242 195 176 205 231 295 334 356 1979 403 36 364 295 ndash ndash ndash 193 242 318 359 373 1980 392 342 377 275 24 176 179 233 292 288 349 391 1981 385 346 337 342 242 178 201 224 30 326 326 369 1982 372 359 315 307 ndash ndash 196 253 252 305 353 379 1983 381 389 327 272 263 222 187 248 287 321 336 366 1984 378 393 322 299 226 215 178 214 234 ndash 336 364 1985 40 366 ndash 294 224 216 205 212 284 307 355 ndash 1986 ndash 383 372 307 ndash 193 166 196 261 277 ndash 382 1987 ndash 339 328 305 21 202 214 218 275 ndash ndash 374 1988 388 365 353 301 23 ndash ndash 228 283 334 31 33 1989 ndash 375 339 285 238 179 181 219 275 298 336 ndash 1990 368 ndash 36 309 268 19 188 205 274 309 373 393 1991 414 416 363 315 268 206 21 ndash 279 338 332 368 1992 363 383 336 263 213 178 213 197 ndash 285 313 359 1993 396 357 344 301 221 ndash 197 215 253 294 347 362 Mean 39 37 34 30 24 20 20 22 27 30 34 37 NOTE Dashes indicate data unavailable
JAN FEB MAR APR MAY JUN JUL AUG SEP OCT NOV DEC0
10
20
30
40
Month
MKS42 140498
50
Mean monthly maximum temperatures at Wiluna
Mea
n T
emp
erat
ure
(degC
)
47
Appendix 3
Table 31 Summary of palynological results
Drillhole Depth (m) F no(a) GSWA no Lithology Formation Assemblage TAI(b)
BWB 1 74ndash75 F49668 135741 dark-grey siltstone basalt Jilyilli gt5 BWB 1 98ndash100 F49669 135742 dark-grey siltstone basalt Jilyilli gt5 BWB 1 121ndash122 F49670 135743 dark-grey siltstone basalt Jilyilli gt5 TWB 1 86ndash87 F49671 135631 dark-grey siltstone McFadden 3+ TWB 1 104ndash105 F49672 135632 dark-grey siltstone Cornelia 3+ TWB 1 121ndash122 F49673 135633 dark-grey siltstone Cornelia 4 TWB 2 14ndash15 F49674 135634 dark-grey siltstone Skates Hills 3+ TWB 6 49ndash50 F49675 135675 dark-grey siltstone Cornelia 1 3+ TWB 9 49ndash51 F49676 135704 dark-grey siltstone Brassey Range 1 3+ Trainor 1 37497- F49733 138939 black mudstone with Cornelia 5 37509 light-grey siltstone Trainor 1 3809 F49734 138940 dark-grey and black Cornelia 4- laminated mudstone Trainor 1 4170 F49735 138941 black unlaminated mudstone Cornelia 4- Trainor 1 4950 F49851 139501 dark-grey indurated siltstone Cornelia 5 Trainor 1 6032 F49852 139502 dark- and light-grey Cornelia 5 indurated siltstone Trainor 1 6434 F49853 139503 greenish indurated finely Cornelia 5 laminated siltstone LDDH 1 270 F49678 138934 dark-grey siltstone interbeds Waters 1 3+ in enterolithic evaporite Tarcunyah Gp LDDH 1 277 F49679 138935 dark-grey siltstone in cavity Waters 1 3+ in enterolithic evaporite Tarcunyah Gp
NOTES (a) GSWA Fossil Catalogue number (b) TAI = Thermal Alteration Index of Traverse (1988 plate 1)
48
Appendix 4
Savory Sub-basin quantitative magnetic and gravity interpretation (extracted from Cowan 1995)
Summary
A program of quantitative aeromagnetic interpretation has been completed on BMRAGSO data from the Savory Sub-
basin Western Australia Quantitative aeromagnetic interpretation utilized the 3D Euler deconvolution method
supported by wavenumber filtering and image processing The results have provided useful information on structural
trends and depth to magnetic sources in a structurally complex area Depth to magnetic source analysis has provided
information on intra-sedimentary magnetic sources as well as basement rocks
The results of the interpretation support previously identified depocentres However the presence of magnetic
sources at several levels makes it very difficult to produce a reliable magnetic basement depth contour map It is
considered more productive to work with the 3D Euler colour circle plots and images rather than trying to contour the
results It would be necessary to carry out a full-scale interpretation of the BMRAGSO profile data to improve on the
3D Euler results The regional gravity was found to be useful in interpreting the regional setting of the area although
the very wide data spacing limits quantitative use of the data The gravity data show quite a complex picture with
limited consistent correlation between gravity features and basin structures This suggests that gravity anomalies
reflect changes in density of the basement rocks rather than basement topography especially in the northern part of the
basin
It is recommended that the GSWA investigate access to company confidential high-resolution aeromagnetic data
prior to planning further aeromagnetic surveys Private companies have flown large parts of the northern half of the
area as part of their diamond exploration program Additional gravity coverage of the area may be more cost effective
than magnetic surveys as the gravity data provides more information on changes within the sedimentary section
Introduction
The main use of aeromagnetic data in petroleum exploration has been the determination of magnetic basement
topography although there has been increasing interest in analysis of intra-sedimentary magnetic anomalies
intrabasement and suprabasement magnetic anomalies These anomalies are used to determine depth to magnetic
basement rocks and hence determine the thickness of the sedimentary sequence Unfortunately interpretation of the
intrabasement and suprabasement magnetic anomalies is non-unique in terms of position and size of causative sources
because of the inherent ambiguity of potential-field methods However this ambiguity can be reduced by placing
49
constraints on source geometry and magnetization and by using geological and other geophysical data to constrain
the solution
Before 1970 most depth-determination techniques involved graphical determination of slopes of selected
magnetic anomalies and application of various empirical factors to convert the slopes into depth estimates Geological
Society of America Memoir 47 Interpretation of Aeromagnetic Maps by Vacquier et al (1951) was a landmark for
this type of interpretation
Automated interpretation procedures have played an increasingly important role in depth interpretation and a
wide range of techniques have been developed Many of these techniques are designed for application to located data
profiles and assume a two-dimensional geometry However there has been renewed interest in techniques applicable
to gridded data
Two distinct types of method can be recognized In the first case often described as discrete methods individual
isolated magnetic anomalies are interpreted and the results used to produce a map of basement relief In the second
case often described as continuous methods areas of data containing a number of anomalies are interpreted
statistically to produce direct output of basement depths
The discrete methods usually involve a semiautomatic initial phase which generates a large number of possible
depth solutions and an interactive second phase to screen and select acceptable solutions The advantage of this
approach is that the interpreter can select features that are relatively free from interference from adjacent anomalies
and consider all aspects of a particular magnetic anomaly The disadvantage is that interpretation can be very time
consuming as a wide range of depths are usually possible depending on the initial model chosen and a significant
amount of effort is needed to select the correct model In the case of the Savory Sub-basin dataset we encountered
problems in separating basement related effects from the effects of shallower intrasedimentary magnetic sources
Because of these problems we have concentrated on displaying the Euler results accompanied by separation filter
images of the data to show the shallower effects and deeper effects rather than trying to refine a 3D Euler
deconvolution depth-to-crystalline-basement contour
The continuous methods are very direct provided that the rather restrictive assumption can be made that all
anomalies are due to lateral magnetization changes due to basement topography This means that shallow effects and
large intrabasement anomalies must be removed from the data This involves judgement and skill as it is necessary to
distinguish between the lower amplitude suprabasement anomalies due to basement topography and the larger
intrabasement anomalies reflecting magnetization changes within the basement These methods were not considered
suitable for the Savory Sub-basin magnetic dataset but were used to invert the gravity data
50
Limitations of magnetic and gravity interpretation
Interpretation of the area is limited by a shortage of information on the nature and physical properties of the deeper
sedimentary sequence and the underlying basement rocks However using techniques such as cross-correlation of
gravity and pseudo-gravity data it is possible to try to differentiate between anomalies relating to basement and those
related to the sedimentary sequence
Gravity anomalies reflect changes within the sedimentary sequence as well as basement condition These
changes in density of sedimentary rocks produce gravity anomalies without a corresponding magnetic anomaly hence
the complementary nature of gravity and magnetic surveys The main use of magnetics is to determine depth to
magnetic basement and any intra-sedimentary volcanic rocks or intrusives whereas gravity provides much more
general information on the sedimentary sequence
Unfortunately interpretation of gravity anomalies is complicated since they can be due to a number of geological
features including
bull major basement faults
bull basement highs
bull igneous intrusions within the basement
bull sedimentary basins which may or may not be isostatically compensated
bull intra-sedimentary volcanics and associated plutonic centres
Two major problems affect the interpretation of both magnetic and gravity data
1 The inherent ambiguity of potential-field data There is no unique solution to any measured gravity or magnetic
anomaly and theoretically there will be an infinite number of source geometry and magnetizationdensity
combinations which will fit the observed data This means that any a priori information which helps to select a
suitable model is very useful
2 Measured anomalies are the summation of effects from different depths For example an observed gravity profile
may contain contributions from shallow sources (density variations within the sedimentary basin) intermediate
depth sources (density variations due to large igneous intrusions within the basement) and deep sources (crustal
thinning producing a mantle anomaly) Separation of these component responses is the regionalresidual problem
which we solve using spectral analysis and differential upward continuation-based separation filtering
Regional setting and interpretation overview
The area studied includes parts of BALFOUR DOWNS (SF51-9) RUDALL (SF51-10) ROBERTSON (SF51-13) GUNANYA
(SF51-14) COLLIER (SG50-4) BULLEN (SG51-1) TRAINOR (SG51-2) MADLEY (SG51-3) NABBERU (SG50-5)
STANLEY (SG51-6) and HERBERT (SG51-7) 1250 000 sheets Broadly the area lies between latitudes 22deg00rsquondash25deg30rsquoS
and longitudes 119deg30rsquondash123deg30rsquoE
51
Regional gravity
The AGSO regional gravity data (at nominal 11 km spacing) was gridded at a 4 km mesh spacing using a minimum-
curvature algorithm Bouguer gravity values in the area are negative reflecting mass deficiency at depth and range
from -84 mgals to -25 mgals
A Bouguer gravity colour image is shown as Figure 41 A residual grid was produced by removing a fifth-order
orthogonal polynomial from the Bouguer data but did not add to the interpretation
120deg 121deg 122deg 123deg
23deg
24deg
25deg
-25
-84
50 km
MKS46 180598
mgal
Figure 41 Regional Bouguer gravity (BMRAGSO data) gridded at 4 km
52
The data show a complex pattern of positive and negative anomalies with no clearly defined trends Correlations
with aeromagnetic data and known basin structures are poor A vague north-northwest linear trend appears to coincide
with the Marloo Fault (Figure 42) A prominent negative anomaly appears to coincide with the Blake Fold and Fault
Belt depocentre and continues as a narrower negative anomaly to the east until it widens out again near the edge of the
basin Elsewhere the gravity data show little correlation with known basin structures and it is likely that especially in
the north of the area gravity anomalies are due to density changes in the basement rather than changes in basement
topography
Production of wavelength-filtered residual gravity plots and vertical gradient plots showed very patchy aliased
data reflecting poor sampling in much of the area
Regional magnetics
The AGSO regional aeromagnetic data were gridded at a 400 m mesh spacing using a minimum-curvature algorithm
(Figure 43) Most of the data has a line spacing of 1600 m with small areas of 1 km spacing The quality of the data is
acceptable for regional interpretation but is not adequate for detailed analysis The accuracy of the flight path is rather
variable reflecting the vintage of the data and the noise envelope of the data is poor by modern standards Problems
were also encountered in joining different map sheets
The magnetic anomaly pattern over the south and west part of the area shows a strong high frequency signature
reflecting the presence of widespread basic sills and dykes Some of the major north-northeasterly trending dykes can
be traced over considerable distances
Discontinuous high-frequency anomalies extend as a northwest-trending zone through the centre of the area and
this zone includes a conspicuous circular magnetic anomaly which is probably a ring complex
The northern and eastern parts of the area are characterized by long-wavelength deep-seated basement magnetic
anomalies with 120deg and 150deg trends dominant The Marloo and Perentie Faults (Figure 42) appear as distinct linear
zones and offsets A prominent easterly trending negative anomaly in the northwest of the area appears to swing round
to the southeast and may separate different basement blocks One possible interpretation is that this very deep seated
anomaly separates areas of Archaean and Proterozoic basement
Regional geology
The regional geology is described in Williams (1992) The GSWA provided a digitized version of Plate 2 from this
Bulletin the structural interpretation map to use as an overlay (Figure 42)
53
Pp
Pp
PSd
PSd
PSd
PSd
PSd
PSo
PSt
PSt
PSf
PSf
PSf
PSb
PSb
PSb
PSsPSs
PSs
PSb
PSm
PSp
PSc
PSc
PSw
PSw
PSw
PSg
PSr
PSj
PSg
PM
Pk
PY
PY
PSd
L
L
L
L
L
L
L
LL
L
L
L
LL
L
LL
L L
LL
L L
L
L
L
L
L
L
L
LL
L
L
BLAKEDEPOCENTRE
MA
RLO
O
FAU
LT
PERENTIEFAULT
50 km
MKS39120598
120deg 121deg 122deg 123deg
25deg
24deg
23deg
Approximate boundaryof aeromagnetic interpretation
PML
PSgL
PSjL
PML
PSpL
PML
PML
PSfL
PSfL
PSpL
LPc
LPcLPcPSrL
LPA
Durba Sandstone
Woora Woora Formation
McFadden Formation
Tchukardine Formation
Boondawari Formation
Skates Hills Formation
Mundadjini Formation
Coondra Formation
Spearhole Formation
Watch Point Formation
Jilyili Formation
Brassey Range Formation
Glass Spring Formation
Paterson Formation
Yeneena Group
Karara Formation
Cornelia Formation
Kahrban Subgroup
Bangemall Group
Fault
Formation boundary
PSdL
PSoL
PSfL
PStL
PSbL
PSsL
PSmL
PScL
PSpL
PSwL
PSjL
PSrL
PSgL
Pp
PYL
PkL
LPc
LPA
PML
Savory Group Other Units
PYL
Figure 42 Regional geology and structure map (after Williams 1992)
54
120deg 121deg 122deg 123deg
23deg
24deg
25deg
5820
3750
MKS47 180598
nT
50 km
Figure 43 Regional aeromagnetic data total magnetic intensity (BMRAGSO data) gridded at 400 m
Analysis
3D analysis
3D Euler deconvolution was used as the primary depth-determination method The advantage of this approach is that
consistent solutions can be obtained over the entire area with minimal assumptions about source geometries Euler
deconvolution of gridded data is used for positional information and estimation of depth to top of source Euler
55
deconvolution yields a large number of depth solutions which have to be screened to reject spurious solutions Results
are plotted as circles in eight depth ranges with radius proportional to depth and colour coded
The 400 m total magnetic intensity grid was used for the analysis Horizontal gradients in x and y and the vertical
gradient were calculated 3D Euler deconvolution was tested on the 400 m gridded data using windows of 9 times 9 and
11 times 11 and 16 times 16 data points and structural indices 05 (fault) and 10 (sill or dyke) It was concluded that the
16 times 16 window produced the best results overall and final plots were produced for the 16 times 16 window and structural
index 05 (Fig 44) Results were very good over the northern and central parts of the area showing magnetic sources
Figure 44 Depth to magnetic source 3D Euler deconvolution 16 times 16 window of 400 m gridded data structural index 05
56
at several different levels Unfortunately in the extreme south of the area shallow intrasedimentary magnetic sources
(sills and dykes) dominated the inversion and the results contained few basement solutions
In order to reduce these problems the 400 m gridded data were filtered using a separation filter based on
interpretation of the log-energy spectrum The 3D Euler method was run on the filtered data in order to generate more
basement-depth solutions Results for the deep-separation filter data were gridded and presented as a colour image in
Cowan (1995) Attempts to grid the Euler output were unsatisfactory and it is considered safer to interpret the 3D
Euler depth plots The 3D Euler depth results from the separation-filter run should be analysed with care as perfect
separation of the basement can never be achieved and there will always be some contamination from sources at
different levels
The results of original total magnetic intensity 3D Euler depth estimation for structural index 05 using a 16 point
window have been plotted at 1500 000 scale (not included in this publication but available in Cowan (1995) from the
GSWA Library as S10331) and as reduced A4 colour circle plots (Figure 44)
The results of deep-basement 3D Euler depth estimation for structural index 05 using a 16 point window have
been plotted as a colour image at 1500 000 scale and as an A4 image (not included in this publication)
2D analysis
Two equispaced profiles were interpolated with a 50 m station interval from the AGSO-located data profiles for the
BULLEN 1250 000 sheet The interpolated profiles were analysed using 2D Euler deconvolution and Werner
deconvolution Results are included in Cowan (1995) and show the use of these methods for more detailed analysis
Filtered data
In order to reconcile 3D Euler results from shallow basement and intrasedimentary magnetic sources we produced
several separation-filtered maps and images We found the shallow-layer double-separation filter (Figure 45) to be
very effective for shallow sources and the deep-layer standard-separation filter (Figure 46) for the basement layer
Gravity and magnetic data correlation
Both lsquoreduced to the polersquo (RTP) magnetics (Figure 47) and pseudo-gravity data (Figure 48) were produced as part of
the reconciliation of gravity and magnetic signatures In both cases the filtering operations assumed magnetization by
induction in the present Earths field The RTP data are fairly similar to the total magnetic intensity The pseudo-
57
gravity data are dominated by a northwest-trending strong positive anomaly and there is little correlation with the
Bouguer gravity data
The poor magneticgravity correlation is confirmed by cross-correlation of the RTP magnetics and the gravity
gradient The correlation plot in Figure 49 shows little coherent response with numerous zones of positive and
negative correlation
Figure 45 Regional aeromagnetic data shallow layer separation filter (BMRAGSO data) gridded at 400 m
Results
In the north and east of the area on the Wells Foreland Sub-basin trend (refer to Figure 1 main text) we see a range
of quite deep 3D Euler depths and several trend directions with north-northwesterly dominant There are relatively few
shallow intrasedimentary solutions in this zone
The second area of deep 3D Euler solutions lies over the Blake depocentre (Figure 43) with several trend
directions
Elsewhere the 3D Euler results are dominated by shallow intrasedimentary depth solutions reflecting mainly the
dolerite sills dykes and the ring complex However where we do see basement-related solutions in the south and
west of the area they appear to be shallower than those noted for the Wells Foreland Sub-basin and the Blake
depocentre
58
Figure 46 Regional aeromagnetic data deep-layer separation filter (BMRAGSO data) gridded at 400 m
Figure 48 Regional aeromagnetic data pseudo-gravity transform (BMRAGSO data) gridded at 400 m
Figure 47 Regional aeromagnetic data reduced-to-pole (BMRAGSO data) gridded at 400 m
Figure 49 Regional aeromagnetic and gravity data gravitymagnetic correlation using RTP magnetics and gravity gradient (BMRAGSO data) gridded at 4 km
59
This subdivision of the area into two zones of deep solutions is consistent with interpreted depocentres
However the interference between sources at different levels and the complexity of the magnetic response of the
basement rocks precludes more refined interpretation at this stage
The area of deep 3D Euler solutions over the Blake depocentre correlates with the pronounced negative gravity
anomaly discussed in the gravity interpretation section Using a density contrast of -015 gcc the negative gravity
anomaly could indicate up to 6ndash8 km of low-density sedimentary rocks depending on assumptions about the regional
field
The area of deep 3D Euler solutions over the Wells Foreland Sub-basin has a complex gravity expression and no
clear basin structure emerges from inversion of these data As noted previously it is likely that observed gravity
anomalies reflect contrasts in basement density rather than basement topography
Separation filtering applied to the magnetic data helps to enhance the intrasedimentary magnetic signature and to
give a better impression of the basement magnetic signature even though separation of the basement response is not
perfect
Conclusions
Quantitative aeromagnetic interpretation using 3D Euler deconvolution supported by wavenumber filtering and image
processing has been successful in providing structural trend and depth information for the Savory Sub-basin
Quantitative magnetic interpretation has revealed two zones of relatively deep magnetic basement beneath the
Wells Foreland Sub-basin and the Blake depocentre
This analysis of the magnetic data supports interpreted depocentres but the complexity of the basement magnetic
signature and interference from sources at different depths precludes further refinement to a map of basement
topography
Regional gravity proved to be very useful in understanding the regional setting of the area and in providing
support for aspects of the interpretation The gravity data support the interpretation of the Blake depocentre
suggesting up to 6ndash8 km of low-density sedimentary rocks
The deep structure of the Savory Sub-basin area is obviously complex with different areas underlain by
Archaean and Proterozoic basement and with the Capricorn suture occurring in the centre of the area
60
Recommendations
The quantitative magnetic interpretation needs to be reconciled with geological models available for the area
In particular the zones tentatively identified as areas with thick sedimentary rocks the Wells Foreland Sub-
basin and the Blake depocentre need to be investigated
Cross sections should be prepared across the basin for joint magneticgravity modelling especially for the Blake
depocentre It is important to be able to explain the strong negative gravity anomaly in this area
In view of the effects of basement density contrasts on the gravity field for the northern part of the area we think
that additional gravity interpretation and acquisition of new gravity data may not be justified as they will not
contribute significantly to understanding basin evolution and structure
It is recommended that GSWA try to get access to company confidential high-resolution aeromagnetic data
rather than flying new surveys The GSWA might offer to fund flying of new infill areas as a bargaining point
References
The original text of this report by Cowan (1995) and 1500 000 scale maps are filed in the GSWA Library under
S10331
COWAN D 1995 Savory Basin quantitative magnetic interpretation Western Australia Geological Survey S-series
S10331 (unpublished)
VACQUIER V STEENLAND N C HENDERSON R G and ZIETZ I 1951 Interpretation of aeromagnetic
maps The Geological Society of America Memoir 47 151p
WILLIAMS I R 1992 Geology of the Savory Basin Western Australia Western Australia Geological Survey
Bulletin 141 115p
61
Appendix 5
Geochemistry
MKS38 250398
Saturate FractionC12+ GLC
1217
Pr18
Ph
22
31CSR WELL-13 315m Cuttings
Figure 51 Canning Stock Route Well 13 gas chromatograph of extract of auger drill sample
12
17
18
22
31
Pr Ph
LDDH 1 6623m CoreSaturate FractionC12+ GLC
MKS35 240398
Figure 52 Gas chromatograph of extract from core sample at 6623 m LDDH1
62
Table 51 Canning Stock Route Well 13 auger drill samples
GSWA sample Drill depth (m)(a) Comments
135601 150 At watertable 135602 203 (all samples consist 135603 310 of sand mud and water) 135604 315 At total depth
NOTE (a) Datum for drill depth is the top of sediment fill in the well which is 155 m below ground level (ie the total depth of 315 m is 47 m below ground level)
Table 52 Canning Stock Route Well 13 gas chromatography data for 315 m depth sediment sample
Parameter Value
Weight of rock extracted (grams) 945 Total extract (ppm) 519 n-Alkane distribution n-C12 07 n-C13 23 n-C14 26 n-C15 22 n-C16 19 n-C17 14 i-C19 23 n-C18 14 i-C20 08 n-C19 11 n-C20 16 n-C21 25 n-C22 29 n-C23 70 n-C24 42 n-C25 95 n-C26 43 n-C27 83 n-C28 38 n-C29 87 n-C30 31 n-C31 273 Alkane compositional data Pristane phytane ratio 279 Pristane n-C17 ratio 161 Phytane n-C18 ratio 059 CPI (1)(a) 284 CPI (2) 209 (C21 + C22) (C28 + C29) 043
NOTE (a) CPI= Carbon preference index
63
Table 53 LDDH1 extract liquid chromatography data for 6623 m concentration
Rock extracted Total extract (grams) (ppm)
702 313
NOTE ppm= parts per million
Table 54 LDDH1 saturate gas chromatography data of core for 6623 m alkane composition
Pristane Pristane Phytane (a) CPI (1) CPI (2) (C21+C22) Phytane n-C17 n-C18 (C28+C29)
103 026 024 103 102 325
NOTE (a)CPI = carbon preference index
Table 55 LDDH1 saturate gas chromatography data of core for 6623 m n-alkane distributions
Parameter Value
n-C12 17 n-C13 38 n-C14 55 n-C15 60 n-C16 65 n-C17 74 i-C19 19 n-C18 78 i-C20 19 n-C19 80 n-C20 79 n-C21 71 n-C22 64 n-C23 57 n-C25 43 n-C24 38 n-C27 31 n-C28 23 n-C29 19 n-C30 12 n-C31 10
64
Appendix 6
Table 61 Summary of data from Trainor waterbores (TWB) and Bullen waterbores (BWB)
Well AMG Elevation TD Status(b) Completion details Water Salinity Water level Flow rate Depth to consolidated AGD84 GL (m) (m) struck mgl(c) (m) (LHr) lithology aquifer(e) Z51(a) Interval (m) (100 mm PVC) (m) (mgl)(d)
TWB 1 473660E 453 122 comp 0ndash75 plain 63 7 300 24 2 880 12 m 7287404N 75ndash93 slotted (9 260) McFadden Fm 93ndash99 plain TWB 2 472 977E 475 23 abd nil 15 m 7285877N Skates Hills Fm dry TWB 3 473259E 475 50 abd nil 7 m 7285849N Skates Hills Fm dry TWB 4 463225 E 445 50 comp 0ndash22 plain 35 7 200 55 3 600 0 m 7286143N 22ndash34 slotted (8 140) Tertiary sand and gravel 23ndash60 plain TWB 5 463095E 445 31 comp 0ndash19 plain 13 26 000 655 3 600 Tertiary sand and gravel 7277721N 19ndash25 slotted (36 700) 25ndash31 plain TWB 6 457013E 455 50 comp 0ndash42 plain 38 920 119 600 0 m 7274352N 42ndash48 slotted (1 030) Cornelia Fm ss TWB 7 453739E 475 26 susp 0ndash2 plain 11 9 300 48 4 500 0 m 7263891N (10 500) Tertiary sand TWB 8 433893E 535 60 susp 0ndash2 plain 47 8 500 gt46 1 200 0 m 7245991N (10 900) Tertiary sand and Brassey Range Fm ss TWB 9 437219E 505 51 comp 0ndash47 plain 45 1 000 58 600 1 m 7235905N 47ndash51 slotted (990) Brassey Range Fm ss TWB 10 434927E 495 32 susp 0ndash2 plain 235 450 120 0 m 7225875N (500) Dolerite
65
BWB 1 287337E 580 122 abd Nil 1 m 7245861N Jilyili Fm dry BWB 2 288346E 545 50 comp 0ndash26 plain 15 630 3 29 000 0 m 7240423N 26ndash38 slotted (730) Tertiary sand and gravel 38ndash50 plain BWB 3 305637E 545 50 abd 19 8 800 43 7 200 0 m 7240423N (10 550) Tertiary ss BWB 4 320167E 515 445 comp 0ndash20 plain 9 980 445 24 000 0 m 7248097N 20ndash32 slotted (1 190) Tertiary ss 32ndash44 plain BWB 5 353393E 545 20 susp 0ndash2 plain 45 (970) 1 m 7238934N Basalt
NOTES (a) GPS accuracy ~ 150 m (b) Comp = completed abd = abandoned susp = suspended (c) Salinity from conductivity (d) Analysis total dissolved solids (e) Fm = Formation ss = sandstone
5
Sealed road
Gravel road
Track
Town
Homestead
Locality
STANLEYSavory Sub-basin boundary 1250 000 map sheet
CornerTrack
Talawana - Windy
Route
Watch Point
NEWMAN
JigalongCommunity
RobertsonRange (abd)
Wokalba
Poondawari
Balfour Downs
Billinnooka
Weelarrana
Beyondie(abd)
Kumarina
Marymia
Glen-ayle
White Lake
Hanging RockBoorabee Hill
WellsRa
EmuRa
Robertson
Ra McFadden R
a
DiebillHills
DurbaHills
Calvert Ra
WardHills
Cornelia Ra
KellyRaBlakeHills
HillsDean
ROBERTSON GUNANYA
TRAINORBULLEN
BALFOUR DOWNS RUDALL
NABBERU STANLEY HERBERT
50 km
Woora Woora Hills
120deg 121deg30 123deg
25deg
24deg
23deg
22deg
Goldfieldsnatural gaspipeline
GR
EA
TN
OR
TH
ER
NH
IGH
WA
Y
Mar
ble
Bar
Nul
lagi
ne-
Rd
MADLEY
Can
ning
Stoc
k
MKS31120598
Goldfields natural gas pipeline
Figure 2 Localities and access routes of the Savory Sub-basin
6
The sealed Great Northern Highway lies west of the Savory Sub-basin and links Meekatharra
to Newman The TalawanandashWindy Corner graded track crosses the northern part of the sub-basin
and graded pastoral station tracks on Balfour Downs Weelarrana Kumarina Marymia and Glen-
Ayle give access to the western and southern margins The Canning Stock Route traverses the sub-
basin from north to south and is a well travelled four-wheel-drive track allowing access to the
eastern half of the sub-basin Additional minor tracks also provide access to other parts of the area
(Williams 1992) Recently flown monochrome aerial photography at 150 000 and Landsat TM
imagery covering the sub-basin is available from the Department of Land Administration
Cross-country access is similar to that in the Canning Basin with the average height of sand
dunes being lower in the Savory Sub-basin Potable water has been found in water bores in the
south of the sub-basin and is inferred to be present throughout the region Fuel and supplies are
available at Wiluna Meekatharra and Newman A good working relationship with the Western
Desert Community who hold native title claims over most of the sub-basin has been established
by GSWA
There are no meteorological stations within the Savory Sub-basin but estimates based on data
from nearby Bureau of Meteorology Stations indicate that the area is arid and has its maximum
rainfall in summer from monsoonal rains The sub-basin has reasonable access and a tolerable
working climate for all exploration activities Meteorological data for the town of Wiluna which
lies about 180 km to the south of the sub-basin are included as Appendix 2
Regional geology
Stratigraphy
Thirteen formations were recognized by Williams (1992) in the Savory Sub-basin and these are
summarized in Table 1 Although unconformities were recognized between some of the
formations and they reflect a wide range of depositional environments provenance and climatic
conditions these formations were defined by Williams (1992) as constituting the Savory Group
Five depositional sequences that are generally unconformity-bounded were recognized by
Williams (1992) (Fig 3) The correlation of significant formations within the sub-basin with other
parts of the Centralian Superbasin is shown in Figure 4 with the four Neoproterozoic
Supersequences having been defined by Walter et al (1995)
7
Durba Ss
McFadden
Woora Woora400
Tchukardine700
Skates Hills
Mundadjini1800
B
Coondra
(B)
Watch Point
Spearhole1100Jilyili
1000(A)
Glass Spring1600(A)
Brassey Range1700(A)
Abs
ent
Absent Absent
Absent
Absent
Absent
A
B
C
D
E
1A
1B
3
4A
4B
1000
2000
3000
4000
5000
6000
Max
imum
thic
knes
s
Sup
erse
quen
ce
AG
EN
EO
PR
OT
ER
OZ
OIC
NE
OP
RO
TE
RO
ZO
ICT
O
CA
MB
RIA
NM
AR
I-N
OA
N
NW SE
Savory Sub-basin Stratigraphy
MKS30 120598
Fault boundary
Unconformity
Disconformity
Conglomerate
Sandstone Mudstone
Siltstone
Evaporite
Dolomite
Boondawari800 Boondawari
Supersequence 2 is not represented in the Savory Sub-basin Total thicknesses are estimated from air photo interpretation Thicknesses of recessive units are unknown
Diamictite
Dep
ositi
onal
seq
uenc
e
Figure 3 Formations lithology and depositional sequences AndashE of the Savory Sub-basin
8
Table 1 Summary of formations in the Savory Sub-basin
Formation Super Depo Lithology Thickness Depositional Savoy Comments Seq(a) Seq(b) (m) environment Group(c)
Durba Sandstone 4 E Quartz sandstone with minor 100 Fluvial lacustrine Y Excellent reservoir basal conglomerate lenses Woora Woora 4 D Medium-grained ferruginous 400 Shallow marine deltaic Y Formation sandstone lithic sandstone quartz wacke siltstone McFadden 4 D Laminated fine- to coarse-grained 1 500 Shallow marine deltaic Y Possible reservoir Formation quartz sandstone feldspathic sandstone quartz wacke minor conglomerate siltstone Tchukardine 4 D Medium- to coarse-grained sandstone 700 Shallow marine Y Formation lithic sandstone quartz wacke conglomerate lenses siltstone minor shale Boondawari 3 C Glacigene diamictite sandstone siltstone Formation shale conglomerate minor dolomite (some stromatolitic and oolitic) rhythmite 800 Glacial shallow marine Y Possible source rock Skates Hills 1 B Thin-bedded dolomite (some stromatolitic) 200 Shallow marine sabkha Y Possible source rock Formation chert evaporites fine- to medium-grained sandstone siltstone shale patchy basal conglomerate Mundadjini 1 B Fine- to coarse-grained sandstone 1 800 Deltaic sabkha Y Possible source rock Formation conglomerate siltstone minor shale shallow marine mudstone dolomite (some stromatolitic) and evaporites Coondra 1 B Coarse- to medium-grained sandstone 1 000 Fan delta Y Possible reservoir Formation poorly sorted conglomerate pebbly sandstone Spearhole 1 B Coarse- to medium-grained sandstone 1 100 Braided fluvial deltaic Y Possible reservoir Formation pebbly sandstone siltstone and oil shows in conglomerate lenses Mundadjini 1 Boondawari 1
9
Watch Point 1 B Shale siltstone fine- to medium-grained 400 Shallow marine deltaic Y Formation sandstone glauconitic sandstone Jilyili Formation 1 A Fine-grained sandstone siltstone minor shale mudstone conglomerate lenses 1 000 Deltaic Y Brassey Range 1 A Fine- to medium-grained sandstone 1 700 Fluvial deltaic Y Formation siltstone shale minor mudstone Glass Spring 1 A Medium- to coarse-grained sandstone 1 600 Shallow marine fluvial Y Formation minor conglomerate and siltstone Tarcunyah Group 1 AampB Quartz sandstone feldspathic sandstone Shallow marine sabkha N Bitumen in LDDH1 quartz wacke shale siltstone fluvial lacustrine conglomerate evaporites dolomite Cornelia 1 A Sandstone siltstone shale mudstone Shallow marine N Overmature source rocks Formation minor glauconitic sandstone deep marine in Trainor 1 Kahrban 1 A Sandstone siltstone shale 1 700 Shallow marine deltaic N Subgroup
NOTES (a) Supersequences of Walter et al (1995) (b) Depositional sequences of Williams (1992) (c) Y= assigned to Savory Group in Williams (1992) N= previously considered to be older than the Savory Group but now included in the greater Officer Basin
10
SAVORY SUB-BASIN GIBSON SUB-BASINCENTRAL OFFICERBASIN
AMADEUS BASIN
PETERMANN RANGES OROGENY
NE
OP
RO
TE
RO
ZO
IC
ST
UR
TIA
NM
AR
INO
AN
ED
IAC
AR
IAN
CAMBRIANTO
NEOPRO-TEROZOIC
AG
E (
Ma)
SOUTHS RANGE MOVEMENT
AREYONGA MOVEMENT
Steptoe
MILES OROGENY
Mission Group
Cassidy Group
Rudall Complex
Bangemall Group
unnamed
Tar
cuny
ah G
roup
4
3
2
1
MKS12a 180598
500
550
600
650
700
750
800
850
900
SU
PE
R
SE
QU
EN
CE
unnamed
Tchukardine Fm
McFadden Fm
ArumberaSst
Julie Fm
Pertatataka Fm
Olympic FmPioneer Sst
Boondawari Fm
Turkey Hill FmLupton Fm
Kanpa Fm
Neale FmBabbagoola
FmHussar
Fm
Browne Fm
Woolnough Fm
Madley Fm
Bitt
er S
prin
gs F
m
LovesCreek M
Gillen M
Heavitree Fm
Arunta Complex
Throssell Group
TownsendQuartzite
Earaheedy Group
olderCornelia Fm
Jilyili Fm
SpearholeFm
MundadjiniFm
Skates Hills Fm
Lefroy Fm
Areyonga Fm
Aralka Fm
ME
SO
-P
RO
TE
RO
ZO
IC
Waters Fm
youngerCornelia Fm
Brassey RangeFormationKahrban
Subgroup
GlassSpring
Fm
Durba Sst
LP1ALP1B EVENT
Figure 4 Correlation of Savory Sub-basin formations with the western Officer and Amadeus Basins Fm = Formation Sst = Sandstone M = Member
11
The depositional sequences recognized in the sub-basin are an order of magnitude thicker than
those described from Phanerozoic passive-margin settings (Payton 1977 Posamentier et al 1988)
and are broadly comparable in scale to the second-order cycles of Vail et al (1977) and to the
megasequences of Hubbard et al (1985) The main subsurface data available to reveal the
unweathered nature of these rocks are Trainor-1 and the three-well diamond coring program in
Petroleum Permit EP 380 (Akubra 1 Boondawari 1 Mundadjini 1) completed in late 1997 in the
central west of the sub-basin (Figs 5 and 6)
The ages of all formations in the Savory Sub-basin are poorly constrained The only fossils
known are stromatolites and palynomorphs (acid-insoluble microfossils) Palynology from
available wells is summarized in Appendix 3 from Grey and Stevens (1997) and Grey and Cotter
(1996) and correlations using stromatolite biostratigraphy (Stevens and Grey 1997 Grey 1995f
Walter et al 1994 1995) are consistent with a Neoproterozoic age for the formations for which
data are available
A dolerite within the Boondawari Formation gave a poorly constrained RbndashSr age of about
640 Ma (Williams 1992) SHRIMP UndashPb dating of sedimentary zircons from the McFadden and
Cornelia Formations in stratigraphic drillhole Trainor 1 are discussed in Stevens and Adamides (in
prep) and Nelson (1997) The youngest ages from these analyses indicate that the maximum age
of the Cornelia Formation is Early Cambrian or Sturtian but these ages are inconsistent with
previous tectonic interpretations (Williams 1992) and current stratigraphic correlations which
suggest the Cornelia Formation is of Supersequence 1 age or older (Fig 4)
Depositional Sequence A Supersequence 1
Depositional Sequence A includes the Glass Spring Jilyili and Brassey Range Formations (Fig
3) All of these units are predominantly quartzose sandstones some of which are friable and have
significant visible porosity in outcrop Conglomerates are present in the Glass Spring and Jilyili
Formations
Depositional Sequence B Supersequence 1
Depositional Sequence B consists of the Watch Point Coondra Mundadjini Spearhole and
Skates Hills Formations (Fig 3) All of these formations contain beds of quartzose sandstone and
some also contain conglomerates The porosity of dolomites in the Skates Hills Formation appears
poor in surface exposures but its subsurface characteristics are unknown
12
50 km
120deg 121deg30 123deg
25deg
24deg
23deg
22deg
Greater Officer Basin
PNCEXP CA11PNCEXP CA12
PNCEXP CA13PNCEXP CA19
PNCEXP CA05
PNCEXP CA09
BD134589
GSWA Trainor 1 and TWB123
Fortescue River 1A
Mundadjini 1
Akubra 1Boondawari 1
TWB4TWB5
TWB6
TWB7
TWB8
TWB9
TWB10
BWB1
BWB2 BWB3
BWB4
BWB5
OD23
Mineral exploration drillhole
Stratigraphic drillhole
Waterbores and wells(TWB and BWB serieswaterbores identified)
MKS33270398
LDDH 1
Savory Sub-basin
Canning SR Well 13
EP380
Petroleum Exploration permit
Petroleum exploration well
Figure 5 Locations of petroleum exploration wells mineral exploration and stratigraphic drillholes water bores and wells and petroleum exploration permit EP380 in the Savory Sub-basin
13
TD=600m
TD=1367m
TD=701m
TD=709m
TD=50m
SS
1S
S1
SS1
SS
1S
S1
SS
1
SS
1
SS1
SS4 SS1
Pha
nero
zoic
or
SS
2
Cz
CzCz
Karst Bitumen
SS1
TD=181m
Mundadjini 1 Akubra 1 Boondawari 1 LDDH 1 Trainor 1 TWB 6
Munda-djini Fm
Spear-hole Fm
Munda-djini Fm
Munda-djini Fm
Spear-hole Fm
Spear-hole Fm
Waters Fm
McFadden Fm
Cornelia Fm
Cornelia Fm
Cornelia Fm
511 plusmn 13Maor 696 plusmn 20Ma(maximum)
779 plusmn 10Ma(maximum)
Mundadjini 1
Akubra 1 Boondawari 1
LDDH 1
Trainor 1TWB 6100 km
N
LOCATION
NW SE
Sea level
0m AHD
Dolerite basalt
Conglomerate
Sandstone
Mudstone
Dolomite
Limestone
Evaporite
TOC gt08
Permeability gt100md
Oil fluorescence
Sedimentary zircon U-Pb age
Identifiable polymorphs
Cainozoic
Supersequence 1 age
Unconformity
Formation contact
Cz
SS1
r
r
0
100
200
metres
VerticalScale
MKS36 120598
LEGEND
Figure 6 Geological cross section through significant drillholes in the Savory Sub-basin
14
Depositional Sequence C Supersequence 3
Depositional Sequence C consists of the Boondawari Formation (Fig 3) and although it contains
sandstone conglomerate and dolomite the sandstones contain significant amounts of feldspar and
clay and hence are likely to be poorer reservoirs than older sandstones
Depositional Sequence D Supersequence 4
Depositional Sequence D includes the McFadden Tchukardine and Woora Woora Formations
(Fig 3) The McFadden Formation is poorly sorted and sandstones contain significant amounts of
feldspathic clasts in the north of the basin but are significantly coarser and cleaner in the northeast
of the sub-basin (Williams 1992)
Sandstones of the Tchukardine and Woora Woora Formations are generally cleaner than those
of the McFadden Formation and are expected to have fair to good porosity although the
Tchukardine Formation has a higher clay content in parts
Depositional Sequence E Supersequence 4
Depositional Sequence E consists of the Durba Sandstone (Fig 3) a coarse sandstone with minor
conglomerate which has good to excellent visible porosity in surface exposures
Other depositional sequences and regional correlations
Sedimentary rocks which were not included in the Savory Group by Williams (1992) but which
are likely to be of Neoproterozoic age and hence part of the greater Officer Basin include the
Tarcunyah Group the Cornelia Formation and the Kahrban Subgroup
As discussed in the Introduction all of the strata in the Karara Basin and the younger strata
of the Yeneena Basin were redefined to form the Tarcunyah Group of the greater Officer Basin
(Bagas et al 1995) (Fig 7) In outcrop the Tarcunyah Group consists predominantly of quartzose
feldspathic and arkosic sandstone shale which is carbonaceous in parts and carbonate which
includes stromatolitic dolomite Mineral hole LDDH1 drilled on GUNANYA intersected the
15
120598
122deg
123deg
21deg
22deg
23deg
24deg
23deg
22deg
21deg
122deg
123deg
Fault
Thrust
Reverse thrust
CANNINGBASIN
OFFICERBASIN
GROUP
PILBARACRATON
TARCUNYAH
SAVORY GROUP
BANGEMALL
GROUP
THROSSELL
GROUP
LAMIL
GROUP
ConnaughtonTerrane
TerraneTalbot
complexTabletop granitic
Tabletop Terrane
Permian
Neoproterozoicgranitoid
50 km
FormationWaltha Woora
McKay Fault
South west Thrust
Vines
Fault
24deg
120deg
YENEENA CANNINGBASIN
ARUNTAINLIERRUDALL
COMPLEX
AMADEUSBASIN
MUSGRAVEBLOCK
OFFICERBASINYILGARN
CRATON
GROUP
GROUP
GROUP
PILBARACRATON
GROUP
EARAHEEDY
GLENGARRY
BANGEMALL
WYLOO GROUP
SAVORY
WA
CARNARVONBASIN
GASCOYNECOMPLEX
GROUPTARCUNYAH
400 kmGROUP
SA
N
T
CamelndashTabletopfault zone
KAHRBANSUBGROUP
CORNELIAFORMATION
MKS37
Figure 7 Regional geological setting of the Savory Group and western Officer Basin The dashed line on the inset map marks the interpreted margin of the greater Officer Basin
16
Tarcunyah Group and consists predominantly of mudstone with minor sandstone limestone
dolomite and anhydrite (Fig 6)
The age of the Tarcunyah Group is uncertain although limited palynological and stromatolite
evidence suggests that it is probably coeval with Supersequence 1 of the Centralian Superbasin
Drillhole LDDH1 contains palynomorphs equivalent to assemblages in the Browne and Bitter
Springs Formations of the Officer and Amadeus Basins respectively and from the Cornelia
Formation in TWB 6 (Grey and Stevens 1997) (Figs 4 and 6) Stromatolite specimens tentatively
assigned to Acaciella australica (Howchin 1914) Walter 1972 occur in the lower Tarcunyah
Group (Bagas et al 1995) The stromatolite Baicalia burra Preiss 1972 and a conical
stromatolite were reported from the upper part of the Tarcunyah Group (Stevens and Grey 1997)
The recognition of two stromatolite assemblages interpreted to have age significance in
Supersequence 1 sedimentary rocks of the Centralian Superbasin has permitted biostratigraphic
correlations between outcrop and well data The Acaciella australica assemblage appears to be
slightly older than 800 Ma and is restricted to the middle part of Supersequence 1 The Baicalia
burra assemblage is considered to be slightly younger than 800 Ma and occurs in the upper part
of Supersequence 1 (Grey 1996b Stevens and Grey 1997) The older A australica assemblage
is recognized in the Skates Hills Formation in the Savory Sub-basin and the stromatolite A
australica itself has been tentatively identified in the lower Tarcunyah Group The occurrence of
the A australica assemblage in the Woolnough Madley and Browne Formations of the Officer
Basin and in the Loves Creek Member of the Bitter Springs Formation of the Amadeus Basin
allows correlations throughout the Centralian Superbasin (Fig 4)
The younger B burra assemblage has not been recognized in sedimentary rocks of the
Savory Group as defined by Williams (1992) but it occurs in the upper parts of the Tarcunyah
Group and allows correlation of this group with outcrops of the Neale Formation and with the
Kanpa Formation in petroleum exploration well Hussar 1 both located in the central Officer Basin
of Western Australia (Fig 4) (Grey 1996b Stevens and Grey 1997) The occurrence of the B
burra assemblage in these units permits their correlation with the Burra Group in the Adelaide
Geosyncline of South Australia (K Grey unpublished data)
The Cornelia Formation and Kahrban Subgroup outcrop in the southeast of the sub-basin and
were considered by Williams (1992) to be part of the Mesoproterozoic Bangemall Basin Limited
evidence suggests that all or parts of these two units are of Neoproterozoic age The Ward and
Oldham Inliers consist of outcrops of the Cornelia Formation Waterbore TWB 6 which was
drilled on TRAINOR in the Cornelia Formation contains palynomorphs consistent with a
Supersequence 1 age (Grey and Stevens 1997) (Figs 5 and 6) In outcrop the Cornelia Formation
17
consists predominantly of sandstone and quartzite with lesser siltstone shale mudstone and chert
In Trainor 1 this formation consists predominantly of indurated mudstone with minor sandstone
chert and dolomite A major erosional unconformity separates the Cornelia Formation from
overlying formations and parts of the Cornelia Formation have been folded with dips exceeding
70deg In contrast the majority of the Savory Sub-basin sedimentary rocks have dips of less than 30deg
except where they are adjacent to faults The Cornelia Formation apparently consists of an older
unit of steeply dipping quartzites cherts and well-indurated mudstones and a younger unit of
shallower dipping sandstones which are sub-friable in parts However caution should be used in
interpreting the age of units based on their structural deformation and additional mapping and age
dating of this formation is required
It is proposed here that the Kahrban Subgroup is likely to be of early Neoproterozoic age and
hence should be considered as part of the greater Officer Basin This proposal is based largely on
the relatively low dip of the strata (generally less than 20deg) and their west-northwest strike which
is parallel with strikes in the overlying Brassey Range Formation of the Savory Group The lower
contact of the Kahrban Subgroup is obscured but is thought to be an unconfirmity on the
Earaheedy Basin on the southeast of STANLEY (Muhling and Brakel 1985)
Structural setting
The Savory Sub-basin forms the most northwesterly sub-basin of the Neoproterozoic to
Phanerozoic Officer Basin The western boundary of the sub-basin with the Mesoproterozoic
Bangemall Basin consists of steep-reverse and strike-slip faults The northeastern boundary of the
Savory Sub-basin was mapped where Supersequence 4 formations of the Savory Group
unconformably overlie sedimentary rocks of the Karara and Yeneena Basins with the two older
units considered to be part of the Paterson Orogen (Williams 1992) This contact was defined as a
series of steeply dipping reverse faults in the northernmost parts of the sub-basin on BALFOUR
DOWNS and RUDALL and was extrapolated as an inferred reverse fault farther along strike to the
southeast on GUNANYA and MADLEY where the contact is obscured by Cainozoic sediments It is
now recognized that all the sedimentary rocks in the Karara Basin and younger sedimentary rocks
of the Yeneena Basin are from the Supersequence 1 Tarcunyah Group and part of the greater
Officer Basin (Bagas et al 1995) The northern boundary of the Tarcunyah Group and the greater
Officer Basin is in thrust-and reverse-faulted contact with the Rudall Complex and other parts of
the Paterson Orogen (Fig 7)
To the south the sub-basin unconformably overlies the Bangemall Basin The eastern
boundary of the sub-basin used in this study is where Permian and younger strata of the Officer
Basin unconformably overlie Neoproterozoic strata although there are no significant structural or
stratigraphic differences between the Neoproterozoic units
18
The sub-basin is subdivided into three principal structural areas (Fig 1) Trainor Platform
Blake Fault and Fold Belt and Wells Foreland Sub-basin (Williams 1992) A major review of
these boundaries is beyond the scope of this report but the processing of regional aeromagnetic
data (Appendix 4) and acquisition of a semi-detailed gravity survey by the GSWA in the east of
the sub-basin has enabled these tectonic units to be reassessed and some modifications are
proposed
The Wells Foreland Sub-basin (originally termed the Wells Foreland Basin in Williams 1992)
and sedimentary rocks of the Tarcunyah Group are both considered to be the northwest
continuation of the Gibson Sub-basin of the Officer Basin Aeromagnetic gravity and outcrop
data suggest that the Blake Fault and Fold Belt is significantly faulted and folded in the west but
is less deformed in the east where the thickest sedimentary section in is located on BULLEN
(Appendix 4) The Trainor Platform is reinterpreted to represent an area of the sub-basin that has
undergone major compression during the Petermann Ranges Orogeny resulting in folding and
faulting with a northwest strike This interpretation contrasts with that proposed by Williams
(1992) who envisaged that only a thin section of the Savory Group was present on the platform
Perincek (1998) has recognized nine periods of tectonic activity in the Officer Basin from the
beginning of the Neoproterozoic to the end of the Cretaceous Three major tectonic episodes are
recognized in the Centralian Superbasin The oldest event is the Areyonga Movement which is
pre-Sturtian and forms the boundary between Supersequences 1 and 2 (Fig 4) The Souths Range
Movement occurred at the end of the Sturtian at the boundary between Supersequences 2 and 3
The youngest major event is the Petermann Ranges Orogeny which occured at the end of the
Marinoan and forms the boundary between Supersequences 3 and 4
One minor and two major tectonic episodes are recognized in the Savory Sub-basin the
LP1ALP1B structural event and the Areyonga Movement and the Petermann Ranges Orogeny
respectively The LP1ALP1B structural event is revealed where the Spearhole Formations rests
disconformably and locally unconformably on the Brassey Range Jilyili and Glass Spring
Formations The Neoproterozoic Areyonga Movement (equivalent to the Blake Movement of
Williams 1992) produced folds and faults with a general northeast strike in the western and
southern parts of the region The Souths Range Movement has not been recognized in the sub-
basin This may be due to the fact that no Sturtian glacial rocks have been identified and hence it
is possible that structures attributed to the Areyonga Movement could be the result of the Souths
Range Movement or a combination of the two movements
The major tectonic event recorded in the sub-basin is the latest Neoproterozoic to Cambrian
Petermann Ranges Orogeny (equivalent to the Paterson Orogeny) which produced large reverse
19
faults thrusts strike-slip faults and folds with a general northwest strike The McFadden
Formation and other Supersequence 4 strata are considered to be at least partially coeval with this
orogeny (Williams 1992) We also interpret the Durba Sandstone as having been deposited during
the later stages of the Petermann Ranges Orogeny as this unit mildly deformed with fold axes
parallel to the strike of other structures attributed to the Petermann Ranges Orogeny
Quantitative aeromagnetic interpretation of the Savory Sub-basin utilizing the 3D Euler
deconvolution method supported by wave-number filtering and image processing has provided
structural trends and depth to magnetic source within the sub-basin (Cowan 1995) Gravity data
are interpreted by Cowan (1995) as changes in both the density of the basement rocks andor
basement topography depending on local conditions Part of Cowanrsquos report is reproduced in
Appendix 4
Exploration history
The only petroleum exploration conducted in the sub-basin has been the recent drilling in the
western part of three diamond drillholes of which two have minor oil shows (Table 2) There has
been some mineral exploration the results of which are stored in the GSWA Western Australian
Mineral Exploration (WAMEX) database system Much of the mineral exploration was in the
southwest and west where the sub-basin is in contact with the Bangemall Basin and along the
northern margin of the sub-basin Many of these mineral exploration programs included
aeromagnetic surveys and surface geochemical sampling (Fig 8)
Hydrocarbon potential
The sub-basin contains a sedimentary succession up to 8 km thick which is generally gently
folded and faulted and apparently unmetamorphosed Limited drilling has shown that thick
mudstones are present in the sub-basin with some mudstones in Trainor 1 having high Total
Organic Carbon (TOC) values Outcrops of sub-friable sandstones in many of the formations
within the sub-basin suggests widespread reservoir potential Mudstone and inferred thick
evaporite sequences are likely to form seals Maturity data suggest that near-surface samples are
approximately at the base of the oil window and top of the gas window in parts of the north and
southeast of the sub-basin However parts of the southwest of the sub-basin and the mudstones in
Trainor 1 have very high levels of maturity Numerous faults and folds have been identified from
surface mapping suggesting good potential for large structural traps Minor oil shows in
20
Table 2 Neoproterozoic formations and hydrocarbon shows in diamond drillholes in the Savory Sub-basin
Drillhole AMG Core TD (m) Approx Formation Depth Formation Depth Formation Depth Shows (AGD84) start (m) GL (m) (m) (m) (m)
LDDH 1 431148E 112 701 350 Tarcunyah 68ndash701 ndash ndash bitumen at 6623 m 7443826N Group Trainor 1 473640E 6 709 455 McFadden 9ndash83 Cornelia Fm 83ndash709 possible bitumen at 4537 m 7287400N Fm Mundadjini 1 319056E 170 600 500 Mundadjini 16ndash361 Spearhole Fm 361ndash600 10 fluorescence at 36102 m 7404844N Fm Boondawari 1 348959E 299 1 367 490 Mundadjini Fm 15ndash312 Spearhole Fm 312ndash1 283 Intrusive 1 283ndash1 367 40 fluorescence at 35364 m 5 7398174N fluorescence at 4963 m Akubra 1 334249E 15 181 530 Mundadjini 15ndash42 Intrusive 42ndash181 None 7401252N Fm
21
50 km
120deg 121deg30 123deg
25deg
24deg
23deg
22deg
Greater Officer Basin
Savory Sub-basin
1
2
3
4
6
8
3 Seismic line (prefixed N83-00)
Aeromagnetic survey
GS
WA
Sav
ory
1995
gra
vity
sur
vey
Gravity survey
MKS34270398
Figure 8 Locations of aeromagnetic and gravity surveys (other than regional BMRAGSO data)
22
sandstones in two petroleum wells in the northwest of the sub-basin and bitumen and oil shows
elsewhere in the region indicate that oil has been generated and migrated through the sub-basin
Source rocks
Source potential is considered to be the major exploration risk in the Savory Sub-basin although
minor oil shows in Mundadjini 1 and Boondawari 1 indicate that at least some oil has been
generated and migrated into potential reservoirs within the sub-basin Sandstone is the
predominant lithology observed in outcrop Outcrops of fine-grained lithologies in the basin are
rare because of intense surface weathering and erosion Only about 8 of the surface area of the
sub-basin is exposed bedrock and recessive lithologies (such as shale evaporite and friable
sandstone) may be present although they rarely outcrop
Outcrops of stromatolitic dolomite with associated cauliflower chert and cubic pseudomorphs
interpreted as being after halite indicate that evaporitic environments are present within the
Mundadjini Skates Hills and Boondawari Formations Evaporitic minerals are also present in
drillhole LDDH1 in the Tarcunyah Group
In 1995 GSWA drilled a continuous-core diamond drillhole (Trainor 1) in the sub-basin on
TRAINOR to a depth of 709 m to test for source rocks thus providing the first such data for the sub-
basin The drillhole intersected flat-lying clastics and carbonates of the McFadden Formation (9ndash
83 m) overlying indurated mudstones of the Cornelia Formation (83ndash709 m total depth) dipping at
about 40deg Of the six samples analysed from the Cornelia Formation in this drillhole the five
located between 375 and 6032 m depth have TOC values exceeding 05 (range 066ndash365)
Rock-Eval pyrolysis of these five samples indicates that they are at best in the dry-gas thermal
stage and as a result of their high level of maturation (Stevens and Adamides in prep) have poor
remaining hydrocarbon-generating potential Although the Cornelia Formation is overmature at
Trainor 1 the high TOC values are encouraging as it is likely that this sequence is less mature
elsewhere in the sub-basin
The Mundadjini Formation contains potential source rocks that comprise marine mudstones
with evaporitic minerals present in parts Thin dark mudstones were intersected in the Mundadjini
Formation in Akubra 1 In Mundadjini 1 and Boondawari 1 however the mudstones appear to be
too oxidized to have source potential
The Boondawari Formation also may be a source rock as it contains black mudstones The
unit is laterally equivalent to the Pertatataka Formation of the Amadeus Basin and the Ungoolya
23
Group of the Officer Basin in South Australia both of which have some source potential
(Summons and Powell 1991 Morton and Drexel 1997) Samples from the Dey Dey Mudstone of
the Ungoolya Group generally have poor TOC values (average 011 range 003ndash081)
moderate hydrogen index (HI) values (100ndash382) and poor to fair genetic potential with a
maximum of 292 kg hydrocarbon per tonne of source rock (Morton and Drexel 1997)
Stromatolitic dolomites and mudstones at the top of the Boondawari Formation and within the
Skates Hills Formation are potential source rocks Stromatolitic dolomite and evaporitic rocks
deposited in a marginal marine to sabkha environment are considered to have good potential to
generate and preserve organic carbon without requiring a deep-water setting (Stevens and Grey
1997) Such conditions are recognized in the Skates Hills Formation and in the upper parts of the
Tarcunyah Group
Maturity
Knowledge of the maturity of sedimentary rocks within the Savory Sub-basin is still limited From
a review of palynological studies Grey and Stevens (1997) report that the thermal maturity
inferred from the Thermal Alteration Index (TAI) of 3+ from Supersequence 1 age palynomorphs
in TWB 6 TWB 9 and LDDH1 is within the hydrocarbon window (Appendix 3) In Phanerozoic
spores and pollen a TAI of 3+ approximately equates to the end of liquid petroleum generation
and the start of dry gas generation and to a vitrinite reflectance of about 13 (Traverse 1988)
However the use of TAI for estimating thermal maturity from Neoproterozoic palynomorphs
requires calibration
In Trainor 1 the Cornelia Formation contains organically rich claystones between 375 and
6032 m depth Based on Rock-Eval maturity data (Stevens and Adamides in prep) and the dark
colour of poorly preserved organic material (Grey 1995de 1996) with TAI 4- to 5 all samples
had a high level of maturation with at best dry-gas generating potential remaining In contrast
drillhole LDDH1 on GUNANYA recorded lower levels of maturity (TAI values of 3+) with two of
sixteen samples from the Tarcunyah Group having greater than 1 TOC (Grey 1995abc Grey
and Cotter 1996) Organic petrology and Rock-Eval maturity data for samples from LDDH1
indicate that the section above 500 m is within the oil-generative window whereas below 500 m
the rocks are within the gas window (Ghori in prep Fig 9 Appendix 5)
Waterbores TWB 1 2 6 and 9 which are located on TRAINOR in the southeast of the sub-
basin all had organic matter with TAI values of 3+ from the McFadden Skates Hills Cornelia
and Brassey Range Formations respectively
24
100
200
300
400
500
600
700
Oil
gene
ratin
g
Gas
gene
ratin
g
Fai
r
Fai
r
Poo
r
Poo
r
Goo
d
Imm
atur
e
Oil
win
dow
Oil
win
dow
Imm
atur
e
01 0110 10 0 150 300 440 480 1
Neo
prot
eroz
oic
TOC S1+S2 mgg Hydrogen Index Tmax degC
Depth(m)
Organicrichness
Generatingpotential
Kerogentype Maturity Maturity
TD=701m
Sandstone
Mudstone
Dolomite
Limestone
Evaporite
Source rock
MKS40 070498
Ro equivalent
Figure 9 Petroleum source potential of rocks in Normandy LDDH1
Small amounts of organic matter associated with basalt and dolerite in cuttings from
waterbore BWB 1 on BULLEN showed high levels of thermal maturity (Grey 1995a Libby 1995)
It is unclear whether all sedimentary rocks on BULLEN are overmature for hydrocarbon generation
or the results from BWB 1 are related to local heating events associated with the volcanic bodies
that are common in the Jilyili Formation
25
Reservoirs
Each of the five depositional sequences of the Savory Group (Table 1) are inferred to contain
significant sandstone reservoirs with the possible exception of depositional sequence C as
discussed above in Stratigraphy The Spearhole Formation was cored in Mundadjini 1 and
Boondawari 1 and visual estimates of porosity vary from generally poor (less than 5) to fair
(approximately 5ndash15) The McFadden Formation in Trainor 1 has porosity values of up to 232
and a maximum permeability of 195 md (Stevens and Adamides in prep) Sandstones from
Neoproterozoic formations form the acquifers in the following waterbores the McFadden
Formation in TWB 1 the Cornelia Formation in TWB 6 and the Brassey Range Formation in
TWB 8 and TWB 9 (Appendix 6 Table 61)
Based on outcrop observations the Durba Sandstone is considered to be the best reservoir of
the Savory Group Similarly some sandstones from the Tarcunyah Group also have good visible
porosity in outcrop
Dolomites occur in several formations in the sub-basin Reservoir potential may exist
particularly where the dolomites are stromatolitic and oolitic However dolomites have not been
drilled in the sub-basin and porosity can only be inferred from the preferential silicification of
some stromatolite bioherms observed in outcrop (Stevens and Grey 1997) Elsewhere in the
Officer Basin porosities of up to10 have been measured in dolomites A limestone breccia
(karst) is described from 663 to 677 m in drillhole LDDH1 (Fig 6 Busbridge 1994)
Seals
Indications of evaporitic environments in the Mundadjini Skates Hills and Boondawari
Formations are described by Williams (1992) In Mundadjini 1 from 287 to 337 m anhydrite and
chert occurs as nodules beds and veins in mudstone of the Mundadjini Formation Evaporitic
minerals (predominantly gypsum) are described in the Tarcunyah Group in LDDH1 The presence
of the Woolnough and Madley salt diapirs in the Officer Basin (approximately 110 km east of the
sub-basin) and halite beds over 25 m thick in the well Hussar 1 (130 km east of the sub-basin)
provide further evidence that evaporite seals may be present in the Savory Sub-basin
Mudstones and shales form only a small proportion of the limited Neoproterozoic outcrop in
the sub-basin but significant thicknesses of mudstone were encountered in the Mundadjini
Formation in Mundadjini 1 and Boondawari 1 the Tarcunyah Group in LDDH1 and in the
26
Cornelia Formation in Trainor 1 These data suggest that mudstones form a significant proportion
of strata in the sub-basin despite their limited outcrop
Traps
Potential structural closures including folds and faults occur at various scales throughout the
Savory Sub-basin However the region has only been mapped at 1250 000 scale and
independently closed structures such as domes have yet to be confirmed The western margin of
the basin contains abundant faults (with a northeast strike) but elsewhere faults are less common
Some anticlines are recognized in outcrop including one with a strike length of up to 45 km
inferred from surface bedding dips in the Mundadjini and Spearhole Formations at approximately
24deg15rsquoS 121deg10rsquoE on BULLEN (Fig 1)
Salt diapirs and other halokinetic structures are recognized in outcrop well and seismic data
in the Officer Basin to the west of the Savory Sub-basin and it is probable that there are
significant thicknesses of evaporitic sedimentary rocks in the sub-basin The gravity field data
suggest there is good potential for salt diapirs and traps related to halokinesis
Although there is potential for stratigraphic traps to be present in the sub-basin insufficient
data are available to assess them
Preservation of hydrocarbons
The range of thermal maturities measured to date and the large periods of time envisaged for
deposition of sediments implies hydrocarbon generation may have occurred a number of times
during the evolution of the Savory Sub-basin Any hydrocarbons that were generated early may
have been trapped in palaeostructures and remigration to younger traps could have taken place
later The Petermann Ranges Orogeny which has been equated with the Paterson Orogeny (Myers
1990) is believed to have occurred in the latest Neoproterozoic to early Cambrian This is the last
major tectonic event recognized in the sub-basin suggesting that it is reasonable to expect that trap
integrity will have been preserved
If the inference of the presence of thick halite beds in the sub-basin is correct the preservation
potential of sub-salt traps should be excellent
27
Reported hydrocarbon shows and oil seep
Amadeus Petroleum recorded minor oil shows in cores from Mundadjini 1 and Boondawari 1 In
Mundadjini 1 at 36102 m (top of the Spearhole Formation) a 3 mm thick zone had 10 moderate
white fluorescence with slow solvent cut This show was in a granular sandstone with visually
estimated porosity of about 10 In Boondawari 1 at 35364 m (within the Spearhole Formation) a
broken surface of sandstone had 40 moderate yellow-white fluorescence with slow solvent cut
Visually estimated porosity is about 5 Because the fluorescing surface was broken during the
drilling process this show could have resulted from contamination A second show occurs in
Boondawari 1 at 4963 m (within the Spearhole Formation) where a 1 cm-thick zone had 5 dull
yellow fluorescence with slow solvent cut in a conglomerate with visually estimated porosity of
about 10 The company intends to further investigate the nature of these occurrences
Minor bitumen is present at 6623 m in drillhole LDDH1 on GUNANYA (Figs 5 and 6) as a
vein in mudstones of the Tarcunyah Group A sample was analysed by gas chromatography
(Ghori in prep) and confirmed that it is natural bitumen (Appendix 5)
Mineral hole OD 23 drilled by Jubilee Gold Mines NL on NABBERU in the Bangemall Basin
immediately to the south of the Savory Sub-basin (Fig 5) encountered bitumen and trace oil in
vugs in dolomite (M Stevens unpublished data) but no further data are available at present
In their popular guide to the Canning Stock Route Gard and Gard (1990 p 218) refer to an
oil seep at Well 13 on TRAINOR (Fig 5) They reported that between 1977 and 1984 lsquonatural oilrsquo
was seen in the well Although the well is now largely filled with sediment four auger drill
samples were collected by the GSWA in 1995 and all four were analysed for oil shows One
sample from 315 m total depth (GSWA sample 135604) yielded just enough extract (519 ppm)
for saturate gas chromatography analysis The gas chromatograph (Appendix 5) shows that the
extract does contain some hydrocarbons probably from recent plant material Because the depth to
the oil was not quoted in Gard and Gard (1990) the hand-augered well may not have been deep
enough to properly test this reported seep
Geological and geophysical databases
Geological and geophysical data available for the Savory Sub-basin are limited The most recently
completed geological maps for the sub-basin were published by the GSWA between 1991 and
1995 (Williams and Tyler 1991 Williams 1992 1995ab)
28
The cores from the five drillholes listed in Table 2 believed to be all of the core available
from the sub-basin are available for inspection at GSWA Mineral exploration reports submitted
to GSWA may be searched using the WAMEX database and open-file reports are available on
microfiche Geophysical data acquired by the mining industry is not required to be filed with
GSWA if acquired over Vacant Crown Land which is the case for much of the sub-basin
Geophysical survey data submitted in mining tenement reports and which extend into Vacant
Crown Land remain confidential to the companies Original regional aeromagnetic and gravity
datasets are available from the Australian Geological Survey Organisation (AGSO)
Data pertinent to oil exploration in the sub-basin such as structural style and salt diapirism
are presented in a review of the hydrocarbon prospectivity of the Officer Basin (Perincek 1998)
Drilling
Significant drillholes in the sub-basin are summarized in Table 2
Petroleum industry data
Amadeus Petroleum drilled three petroleum exploration wells in the central west of the Savory
Sub-basin in late 1997 These wells Mundadjini 1 Boondawari 1 and Akubra 1 were drilled by
continuous diamond coring (Figs 5 and 6) All targeted potential reservoirs within the Spearhole
Formation with the Mundadjini Formation as the proposed seal The wells were located on
structures interpreted from Landsat images and limited geological investigations Both Mundadjini
1 and Boondawari 1 had minor oil shows as discussed above (Reported hydrocarbon shows)
Government data
Stratigraphic drillhole Trainor 1 was drilled by GSWA in 1995 (Stevens and Adamides in prep)
and the main results are discussed above (Source rocks and Maturity)
Mineral industry data
Normandy Exploration drillhole LDDH1 was cored in the Tarcunyah Group to a total depth of
701 m and provided source-rock and maturity data as discussed above
29
Oilmin NL drilled six percussion drillholes (BD 1 3 4 5 8 and 9) through sandstones and
shales in the northern part of the Savory Sub-basin to a maximum depth of 198 m (Fig 5
WAMEX Microfiche File M 26811 I 2610) but only brief geological descriptions are available
Hydrogeological data
Hydrogeological data within the Savory Sub-basin are limited although a long history of water
exploration extends back to the construction of the Canning Stock Route early this century No
detailed geological or wireline logs are available for the older wells along this route A few station
wells have been drilled by various methods on the south and west margins of the basin but data
are unavailable as reports are not required to be filed with the government Depth to watertable
throughout the basin is largely controlled by porosity of the bedrock
The GSWA drilled fifteen waterbores in the winter of 1995 in the southern part of the sub-
basin in preparation for the drilling of Trainor 1 and the proposed Bullen 1 Twelve bores found
water and six of these bores have salinities of less than 1000 mgL (Fig 5 Appendix 6 Table 61)
One waterbore TWB 6 has gamma ray and neutron logs run through PVC casing and these are
available from the GSWA with the digital log data included herein
Seismic data
No geophysical data have been acquired by the petroleum industry in the Savory Sub-basin
Seismic data acquired in the Officer Basin to the east particularly in the Gibson and Yowalga
Sub-basins is pertinent to structural interpretation in the Savory Sub-basin (Perincek 1996a
1998)
Aeromagnetic surveys
Government data
There are over 95 277 line kilometres of aeromagnetic data included in the AGSO dataset There
are three regional aeromagnetic surveys covering the Savory Sub-basin These were flown by the
Bureau of Mineral Resources (BMR now AGSO) in 1984 at a line spacing of 1500 m with 36 740
and 52 587 line kilometres flown and by Aerodata in 1984 at a line spacing of 1000m with 5950
line kilometres flown These data were reprocessed and interpreted for GSWA by Cowan (1995)
An edited copy of this report is included as Appendix 4 and the original report is filed in the
GSWA Library under S-series reports item 10331
30
Mineral industry data
The approximate locations of non-AGSO aeromagnetic surveys are shown in Figure 8 More
detailed information regarding the location of these surveys may be obtained using the GSWA
MAGCAT II database Additional information such as contours of aeromagnetic values may be
obtained by inspecting items on file with the GSWA
Gravity surveys
Government data
The average spacing for gravity data in the Savory Sub-basin is one station per 121 km2 (11 times 11
km grid) These data were principally collected by BMR in the early 1960s There are a few
additional regional gravity traverses across the sub-basin which are also included in the
BMRAGSO dataset These data were reprocessed and interpreted for GSWA (Fig 10) and a
report on this work is also included in Appendix 4
The GSWA completed a large semi-detailed gravity survey in the eastern Savory Sub-basin
utilizing helicopter support and Differential Global Positioning Survey (DGPS) techniques (Fig
8) This gravity survey completed in August 1995 consists of 2300 gravity stations on a 2 times 3 km
grid All stations were acquired by helicopter using Scintrex gravimeters and Ashtek dual
frequency DGPS equipment for determining location This highly efficient system allowed the
acquisition of more than 100 gravity stations per day in remote areas The resolution of this survey
is +30 cm and +05 microms-2 (Daishsat 1995) These data (Fig 11) represent a significant
improvement on the previous regional survey data and are available from GSWA (GSWA
1996ab) The results of the interpretation of these data were presented at the 1997 ASEG
Convention (Carlsen and Shevchenko 1997)
Mineral industry data
Three small gravity surveys were conducted by Oilmin NL (Fig 8) and the relevant WAMEX
reports are M 2681I 2610 I 2435 I 2567 These three surveys are of limited value because height
control was provided by barometers only and the surveys were not tied to the national gravity grid
31
23deg
25deg
120deg 122deg
Trainor 1
SAVORY
SUB-BASIN
MKS54 160498
100 km
1995 SavoryGravity Survey
254
-1056
micromsec2
Figure 10 Regional Bouguer gravity map of the Savory Sub-basin
23deg
24deg
25deg
122deg30 123deg
TRAINOR 1
123deg30
50 km
MKS53 160498
-116
-626
micro msec2
Figure11 Detailed Bouguer gravity map of the
Savory 1995 Gravity Survey from the eastern Savory Sub-basin
32
Government and academic reports
Chronostratigraphy and geochemistry
The understanding of Neoproterozoic organic chemistry palynology and structural evolution is
essential to the interpretation of hydrocarbon prospectivity Pertinent reports are included in the
bibliography (Appendix 1) Unpublished palaeontology reports describe the palynology of wells in
the Savory Sub-basin (Grey 1995andashe 1996a) Grey and Cotter (1996) discussed the potential for
Neoproterozoic palynomorphs to provide a biostratigraphic framework and palaeoenvironmental
interpretation Grey and Stevens (1997) reviewed the results of palynological studies of wells
drilled in the sub-basin and reported that Supersequence 1 palynomorphs are present in TWB 6
TWB 9 and LDDH1 (Appendix 3) Grey (1996b) reported on the use of stromatolites for
correlation in the Neoproterozoic and Stevens and Grey (1997) discussed the application of
stromatolite biostratigraphy in correlating isolated dolomite outcrops in the sub-basin with well
and seismic data in the Officer Basin and Centralian Superbasin
Although geochemical data from the Savory Sub-basin are very limited results mostly
confirm thermal maturities inferred from TAI for LDDH1 and Trainor 1 (Ghori in prep Stevens
and Adamides in prep) Those parts of the Officer Basin in Western Australia which lie to the
east of the Savory Sub-basin are sparsely drilled but Ghori (in prep) reports that most of the
Neoproterozoic succession presently lies within the oil-generative window However his study
has been unable to identify effective source-rock units and the source for oil shows Thin source
rocks are present in the Neoproterozoic in LDDH1 (Fig 9) and in three wells which lie to the east
and southeast of the Savory Sub-basin namely NJD 1 Kanpa 1A and Yowalga 3
Proposed work program
From the above limited information it is concluded that additional research on the hydrocarbon
potential of the sub-basin is justified and proposals are outlined below
bull Additional modelling of gravity and aeromagnetic data from the Savory Sub-basin is required
in light of the results from Trainor 1 and Boondawari 1 Trainor 1 showed that what appeared
to be a structurally simple area based on outcrop aeromagnetic and gravity data was in fact an
area of major structuring Boondawari 1 intersected a dolerite which is in good depth
agreement with aeromagnetic depth to source results showing this technique is useful in
detecting the depth to intrusive bodies
33
bull Additional data from mineral and petroleum exploration bores may become available and
analysis of samples from these wells should be undertaken and interpreted in the context of
their relevance to the Officer Basin
bull Stratigraphic coring in the Blake Fault and Fold Belt and in the Wells Foreland Sub-basin (Fig
1) targeting source rocks is considered essential to the continuing evaluation of the
hydrocarbon prospectivity of the Savory Sub-basin
bull Correlations using at least outcrop well and potential-field data should be prepared to link the
sub-basin with the better known parts of the Officer Basin to the east
bull Remapping is required to clarify boundary positions within the Cornelia Formation this may
resolve some of the current problems of the relationship between this unit and the rest of the
Savory Sub-basin
bull Further work is required to explain the Early Cambrian or Sturtian ages interpreted for the
Cornelia Formation from sedimentary zircon UndashPb dating in drillhole Trainor 1 The
determination of the age of the organically rich but overmature claystones in this well is
critical to assessing the hydrocarbon potential of the region
bull The thin dark mudstones intersected by Akubra 1 in the Mundadjini Formation warrant
geochemical analysis Analyses of the oil shows in Mundadjini 1 and Boondawari 1 are
currently being undertaken by Amadeus Petroleum
bull Geochemical analysis of hydrocarbons in the Bangemall Basin drillhole OD23 has been
performed by Jubilee Gold and the results will be reviewed when they are submitted to
GSWA The possibility of source rocks within the Bangemall Basin charging traps within the
Bangemall Basin and the overlying Savory Sub-basin requires further investigation
Conclusions
The Savory Sub-basin is a frontier region with only three recently drilled petroleum exploration
wells and no seismic data Based on existing geological and geophysical data it is considered too
early to draw conclusions about the hydrocarbon prospectivity of the sub-basin at this stage and
there are several reasons why the area warrants further investigation
34
1 Thick accumulations of sedimentary rocks are present (up to 8 km thickness inferred) which
may contain source reservoir and sealing strata
2 Minor oil shows occur in Mundadjini 1 and Boondawari 1 and bitumen is present in mineral
exploration drillhole LDDH1 suggesting that hydrocarbons have migrated within the
Neoproterozoic sequence of the Savory Sub-basin Oil and bitumen are present in mineral
exploration drillhole OD23 in the Bangemall Basin immediately to the south of the Savory
Sub-basin and it is possible that source rocks from the Bangemall Basin could charge traps in
the overlying Savory Sub-basin
3 The age of sedimentary rocks in the sub-basin is still poorly constrained but some of the
Neoproterozoic sedimentary rocks located on GUNANYA and TRAINOR are within the
hydrocarbon-generation window It is possible that a significant thickness of Phanerozoic
sedimentary rocks may also be present
4 Friable sandstones with visible porosity outcrop extensively suggesting numerous potential
reservoirs
5 Significant but not intense faulting and folding has been mapped implying large structural
traps may be present
6 Evaporitic sedimentary rocks occur in several formations and may provide good source rocks
and excellent seals
35
References
APAK S N and CARLSEN G M 1997 A compilation and review of data pertaining to the
hydrocarbon prospectivity of the Canning Basin Western Australia Geological Survey
Record 199610 103p
BAGAS L GREY K and WILLIAMS I R 1995 Reappraisal of the Paterson Orogen and
Savory Basin Western Australia Geological Survey Annual Review 1994ndash95 p 55ndash63
BUSBRIDGE M 1994 Lake Disappointment Exploration Licence 451064 Third Annual
Report Lake Disappointment Diamond Drill Hole LDDH1 Normandy Exploration Limited
Western Australia Geological Survey M-series Item 7567 A41358 (unpublished)
CARLSEN G M and SHEVCHENKO S I 1997 Petroleum exploration in Proterozoic basins
using potential fields data and stratigraphic coring Australian Society of Exploration
Geophysicists 12th Geophysical Conference Handbook Sydney 1997 Preview no 66 p 83
(abstract only)
COWAN D 1995 Savory Basin quantitative magnetic interpretation Western Australia
Geological Survey S-series S10331 (unpublished)
DAISHSAT PTY LTD 1995 Operational and processing report Savory Basin gravity survey
Western Australia Geological Survey S-series S10332 (unpublished)
GARD E and GARD R 1990 Canning Stock Route a travellerrsquos guide for a journey through
history Perth Western Australia Western Desert Guides 448p
GEOLOGICAL SURVEY OF WESTERN AUSTRALIA 1996a Savory Basin first vertical
derivative of Bouguer gravity image 1250 000 Western Australia Geological Survey
GEOLOGICAL SURVEY OF WESTERN AUSTRALIA 1996b Savory Basin Bouguer gravity
image 1250 000 Western Australia Geological Survey
GHORI K A R in prep Petroleum source rock potential and thermal history Officer Basin
Western Australia Western Australia Geological Survey Record
36
GREY K 1995a Savory Basin drillhole BWB 1 (Bullen waterbore) palynology and thermal
maturation GSWA Palaeontology Report no 199512 (unpublished)
GREY K 1995b Savory Basin drillholes TWB 1 2 6 9 (Trainor waterbores) palynology and
thermal maturation GSWA Palaeontology Report no 199520 (unpublished)
GREY K 1995c Palynology of Normandy-Poseidon Lake Disappointment-1 corehole
Tarcunyah Group Paterson Orogen GSWA Palaeontology Report no 199521 (unpublished)
GREY K 1995d Savory Basin drillhole Trainor 1 (Trainor diamond drilling) palynology and
thermal maturity GSWA Palaeontology Report no 199524 (unpublished)
GREY K 1995e Savory Basin drillhole Trainor 1 (Trainor diamond drilling) Additional
Preparation of two samples GSWA Palaeontology Report no 199528 (unpublished)
GREY K 1995f Neoproterozoic stromatolites from the Skates Hills Formation Savory Basin
Western Australia and a review of the distribution of Acaciella australica Australian Journal
of Earth Sciences v 42 p 123ndash132
GREY K 1996a Savory Basin drillhole Trainor 1 (Trainor diamond drilling) Additional
samples palynology and thermal maturation GSWA Palaeontology Report no 199615
(unpublished)
GREY K 1996b Preliminary stromatolite correlations for the Neoproterozoic of the Officer
Basin and a review of Australia-wide correlations GSWA Palaeontology Report no 199615
(unpublished)
GREY K and COTTER K L 1996 Palynology in the search for Proterozoic hydrocarbons
Western Australia Geological Survey Annual Review for 1995ndash96 p 70ndash80
GREY K and STEVENS M K 1997 Neoproterozoic palynomorphs of the Savory Sub-basin
Western Australia and their relevance to petroleum exploration Western Australia
Geological Survey Annual Review for 1996ndash97 p 49ndash54
HUBBARD R J PAPE J and ROBERTS D G 1985 Depositional sequence mapping as a
technique to establish tectonic and stratigraphic framework and evaluate hydrocarbon
potential on a passive continental margin in Seismic stratigraphy II an integrated approach
37
edited by O R BERG and D G WOOLVERTON American Association of Petroleum
Geologists Memoir 39 p 79ndash91
LIBBY WG 1995 A petrological report on six samples of bore cuttings from the Savory Basin
Western Australia Western Australia Geological Survey S-series S31307 (unpublished)
MORTON JGG and DREXEL JF 1997 The petroleum geology of South Australia Vol 3
Officer Basin South Australia Department of Mines and Energy Resources Report Book
9719
MUHLING P C and BRAKEL A T 1985 Geology of the Bangemall Group mdash the evolution
of an intracratonic Proterozoic basin Western Australia Geological Survey Bulletin 128
219p
MYERS J S 1990 Precambrian tectonic evolution of part of Gondwana southwestern Australia
Geology v18 p 537ndash540
NELSON D R 1997 Compilation of SHRIMP UndashPb zircon data Western Australia Geological
Survey Record 19972 196p
PAYTON C E 1977 Seismic stratigraphy mdash applications to hydrocarbon exploration
American Association of Petroleum Geologists Memoir 26 516p
PERINCEK D 1996a The age of NeoproterozoicndashPalaeozoic sediments within the Officer Basin
of the Centralian Super-basin can be constrained by major sequence-bounding unconformities
APPEA Journal v 36 pt 1 p 350ndash368
PERINCEK D 1996b The stratigraphic and structural development of the Officer Basin
Western Australia a review Western Australia Geological Survey Annual Review 1995ndash
1996 p 135ndash148
PERINCEK D 1998 A compilation and review of data pertaining to the hydrocarbon
prospectivity of the Officer Basin Western Australia Geological Survey Record 19976
POSAMENTIER H W JERSEY M T and VAIL P R 1988 Eustatic controls on clastic
deposition 1 mdash Conceptual framework in Sea-level changes an integrated approach edited by
C K WILGUS B S HASTINGS C G St C KENDALL H W POSAMENTIER
38
C A ROSS and J C VAN WAGONER Society of Economic Paleontologists and
Mineralogists Special Publication no 42
STEVENS M K and ADAMIDES N G in prep GSWA Trainor 1 well completion report
Savory Sub-basin Officer Basin Western Australia with notes on petroleum and mineral
potential Western Australia Geological Survey Record 199612
STEVENS M K and GREY K 1997 Skates Hills Formation and Tarcunyah Group Officer
Basin mdash carbonate cycles stratigraphic position and hydrocarbon prospectivity Western
Australia Geological Survey Annual Review for 1996ndash97 p 55ndash60
SUMMONS RE and POWELL C McA 1991 Petroleum source rocks of the Amadeus Basin
in Geological and geophysical studies in the Amadeus Basin central Australia edited by R J
KORSCH and JM KENNARD Australia BMR Geology and Geophysics Bulletin 236
TRAVERSE A 1988 Palaeopalynology Boston Unwin Hyman 600p
VAIL P R MITCHUM R M Jr TODD R G WIDMIER J M THOMPSON S III
SANGREE J B BUBB J N and HATLELID W G 1977 Seismic stratigraphy and
global changes of sea level in Seismic stratigraphy mdash applications to hydrocarbon
exploration edited by C E PAYTON American Association of Petroleum Geologists
Memoir 26 516p
WALTER M R and GORTER J 1994 The Neoproterozoic Centralian Superbasin in Western
Australia the Savory and Officer Basins in The sedimentary basins of Western Australia
edited by P G PURCELL and R R PURCELL Petroleum Exploration Society of Australia
Symposium Perth WA 1994 Proceedings p851ndash864
WALTER M R GREY K WILLIAMS I R and CALVER C R 1994 Stratigraphy of the
Neoproterozoic to early Palaeozoic Savory Basin and correlation with the Amadeus and
Officer Basins Australian Journal of Earth Sciences v 41 p 533ndash546
WALTER M R VEEVERS J J CALVER C R and GREY K 1995 Neoproterozoic
stratigraphy of the Centralian Superbasin Australia Precambrian Research v 73 p 173ndash195
WILLIAMS I R 1992 Geology of the Savory Basin Western Australia Western Australia
Geological Survey Bulletin 141 115p
39
WILLIAMS I R 1995a Bullen WA (2nd Edition) Western Australia Geological Survey
1250 000 Geological Series Explanatory Notes 23p
WILLIAMS I R 1995b Trainor WA (2nd Edition) Western Australia Geological Survey
1250 000 Geological Series Explanatory Notes 31p
WILLIAMS I R and TYLER I M 1991 Robertson WA (2nd edition) Western Australia
Geological Survey 1250 000 Geological Series Explanatory Notes 36p
40
41
Appendix 1
Bibliography
Reports which are relevant to this investigation but which are not specifically cited are listed
below
BAILLIE P W POWELL C McA LI Z X and RYALL A M 1994 The tectonic
framework of Western Australiarsquos Neoproterozoic to recent sedimentary basins in The
sedimentary basins of Western Australia edited by P G PURCELL and R R PURCELL
Petroleum Exploration Society of Australia Symposium Perth WA 1994 Proceedings p
45ndash62
BRADSHAW M T BRADSHAW J MURRAY A P NEEDHAM D J SPENCER L
SUMMONS R E WILMOT J and WINN S 1994 Petroleum systems in West Australian
basins in The sedimentary basins of Western Australia edited by P G PURCELL and R R
PURCELL Petroleum Exploration Society of Australia Symposium Perth WA 1994
Proceedings p 93ndash118
CLARKE G L 1991 Proterozoic tectonic reworking in the Rudall Complex Western Australia
Australian Journal of Earth Science v38 p 31ndash44
COCKBAIN A E and HOCKING R M 1990 Phanerozoic in Geology and mineral resources
of Western Australia Western Australia Geological Survey Memoir 3 p 750ndash755
ETHERIDGE M and WALL V 1994 Tectonic and structural evolution of the Australian
Proterozoic 12th Australian Geological Convention Geological Society of Australia
Abstracts no 37 p 102ndash103
GOODE A D T 1981 Proterozoic geology of Western Australia in Precambrian of the
Southern Hemisphere Developments in Precambrian geology 2 edited by I R HUNTER
Amsterdam Elsevier p 105ndash203
GREY K and JACKSON M J 1983 A re-assessment of stromatolite evidence for the
correlation of the Late Proterozoic Neale and Ilma Beds Officer Basin Western Australia
Australia BMR Journal of Australian Geology and Geophysics v 8 p 359
42
HICKMAN A H WILLIAMS I R and BAGAS L 1994 Proterozoic geology and
mineralization of the TelferndashRudall region Paterson Orogen Geological Society of Australia
(WA Division) Excursion Guidebook no 5 56p
HOCKING R M MORY A J and WILLIAMS I R 1994 An atlas of Neoproterozoic and
Phanerozoic basins of Western Australia in The sedimentary basins of Western Australia
edited by P G PURCELL and R R PURCELL Petroleum Exploration Society of Australia
Symposium Perth WA 1994 Proceedings p 21ndash 44
JACKSON P R 1966 Geology and review of exploration Officer Basin Western Australia
Hunt Oil Company Western Australia Geological Survey S-series S26 (unpublished)
JACKSON M J 1971 Notes on a geological reconnaissance of the Officer Basin Western
Australia Australia BMR Geology and Geophysics Record 19715 30p
JACKSON M J and van de GRAAFF W J E 1981 Geology of the Officer Basin Western
Australia Australia BMR Geology and Geophysics Bulletin 206 102 p
LOWRY D C JACKSON M J van de GRAAFF W J E and KENNEWELL P J 1971
Preliminary result of geological mapping in the Officer Basin Western Australia Western
Australia Geological Survey Annual Report for 1971 p 50ndash56
MYERS J S 1990 Precambrian in Geology and mineral resources of Western Australia
Western Australia Geological Survey Memoir 3 p 737ndash750
MYERS J S SHAW R D and TYLER I M 1994 Proterozoic tectonic evolution of
Australia 12th Australian Geological Convention Geological Society of Australia Abstracts
no 37 p 312
NEDIN C and JENKINS R J F 1991 Re-evaluation of unconformities separating the
lsquoEdiacaranrsquo and Cambrian systems South Australia Palaios v 6 p 102ndash108
PHILLIPS B J JAMES A W and PHILIP G M 1985 The geology and hydrocarbon
potential of the north-western Officer Basin APEA Journal 25 (1) p 52ndash61
POWELL C McA LI Z X McELHINNY M W MEERT J G and PARK J K 1993
Paleomagnetic constraints on timing of the Neoproterozoic breakup of Rodinia and Cambrian
formation of Gondwana Geology v 21 p 889ndash892
43
POWELL C McA PREISS W V GATEHOUSE C G KRAPEZ B and LI Z X 1994
South Australian record of a Rodinian epicontinental basin and its mid-Neoproterozoic
breakup to form the Palaeo-Pacific Ocean Tectonophysics v 237 no 3ndash4 p 113ndash140
PREISS W V 1976 Proterozoic stromatolites from the Nabberu and Officer Basins Western
Australia and their biostratigraphic significance South Australia Geological Survey Report
of Investigations no 47 p 1ndash51
TOWNSON W G 1985 The subsurface geology of the western Officer Basin mdash results of
Shellrsquos 1980ndash1984 petroleum exploration campaign APEA Journal v 25 (1) p 34ndash51
WATTS K J 1982 The geology of the Townsend Quartzite Upper Proterozoic shallow water
deposit of the Northern Officer Basin Western Australia Perth University of Western
Australia BSc honours thesis (unpublished)
WELLS A T and KENNEWELL P J 1974 Evaporite exploration in the Officer Basin
Western Australia at the Madley Diapirs Australia BMR Record 1974194 (unpublished)
WILLIAMS I R and MYERS J S 1990 Paterson Orogen in Geology and mineral resources
of Western Australia Western Australia Geological Survey Memoir 3 p 274ndash286
WILLIAMS I R 1990 Savory Basin in Geology and mineral resources of Western Australia
Western Australia Geological Survey Memoir 3 p 329ndash334
WILLIAMS I R 1994 The Neoproterozoic Savory Basin Western Australia in The
sedimentary basins of Western Australia edited by P G PURCELL and R R PURCELL
Petroleum Exploration Society of Australia Symposium Perth WA 1994 Proceedings p
841ndash850
WILSON R B 1967 Woolnough Hills and Madley diapiric structures Gibson Desert WA
APEA Journal v 7 p 94ndash102
44
Appendix 2
Meteorological data (from Bureau of Meteorology Perth 1994)
Table 21 Wiluna rainfall (mm)
Year Jan Feb Mar Apr May Jun Jul Aug Sept Oct Nov Dec
1975 0 45 446 309 306 59 276 4 34 886 638 164 1976 16 154 12 138 53 16 34 62 12 238 0 2 1977 44 0 66 74 68 95 24 363 1 58 12 727 1978 234 522 94 16 0 96 367 24 16 353 185 45 1979 19 173 122 88 91 4 0 246 58 0 169 114 1980 148 764 68 1081 259 626 629 06 56 02 174 0 1981 123 476 192 32 196 118 44 74 14 0 28 312 1982 374 705 206 244 1079 92 02 143 368 526 368 118 1983 1 112 928 248 0 212 56 32 5 1 42 496 1984 149 7 342 84 836 0 348 132 224 04 16 172 1985 596 483 0 166 556 0 514 56 0 0 4 0 1986 0 154 35 0 0 1085 23 01 239 137 0 04 1987 1204 119 19 89 17 575 154 126 07 1 0 398 1988 46 202 164 13 388 0 202 104 0 0 224 1309 1989 207 234 26 703 278 536 57 0 01 0 144 02 1990 1035 23 281 46 126 53 94 218 44 9 42 0 1991 48 0 41 45 0 472 297 12 0 1 0 7 1992 112 96 1025 1227 323 65 04 174 0 132 48 4 1993 0 697 0 202 445 0 12 306 18 05 14 33 Mean 25 35 22 27 27 25 18 12 6 13 13 21
JAN FEB MAR APR MAY JUN JUL AUG SEP OCT NOV DEC0
10
20
30
40
Mea
n R
ain
fall
(mm
)
Month
Mean monthly rainfall in Wiluna
MKS41 140498
45
Table 22 Wiluna minimum temperature (degC)
Year Jan Feb Mar Apr May Jun Jul Aug Sept Oct Nov Dec
1975 ndash 23 203 15 94 63 71 62 103 124 169 205 1976 242 229 194 15 10 63 59 73 95 143 16 228 1977 243 25 197 148 96 95 56 86 102 ndash 188 23 1978 241 232 203 18 102 64 76 8 9 152 19 205 1979 255 226 216 167 83 6 59 79 97 145 198 223 1980 255 226 231 155 134 83 68 75 121 108 193 223 1981 245 216 19 182 119 6 54 78 138 159 163 218 1982 232 224 177 16 ndash ndash 37 111 112 164 209 225 1983 235 24 197 147 112 88 39 88 121 162 189 219 1984 241 243 191 156 ndash 72 66 7 95 161 182 211 1985 244 231 ndash 159 98 65 71 73 117 147 205 ndash 1986 ndash 229 226 155 93 96 43 49 10 122 ndash 219 1987 ndash 217 183 175 85 77 68 68 112 ndash ndash 221 1988 238 214 209 178 111 ndash ndash 86 104 157 171 195 1989 ndash 237 199 165 107 67 44 61 107 131 187 ndash 1990 232 ndash 211 155 118 62 57 87 102 149 195 22 1991 26 256 217 168 122 101 78 ndash 113 18 168 219 1992 227 227 214 169 102 98 59 69 ndash 125 159 196 1993 241 218 196 171 103 ndash 49 68 88 128 192 211 Mean 24 23 20 16 10 8 6 8 11 14 18 21
NOTE Dashes indicate data unavailable
JAN FEB MAR APR MAY JUN JUL AUG SEP OCT NOV DEC0
10
20
30
40
Month
MKS43 140498
50
Mean monthly minimum temperatures at Wiluna
Mea
n T
emp
erat
ure
(degC
)
46
Table 23 Wiluna maximum temperature (degC)
Year Jan Feb Mar Apr May Jun Jul Aug Sept Oct Nov Dec
1975 ndash 349 326 281 247 201 197 212 256 248 31 344 1976 374 369 346 297 248 206 208 225 265 287 313 388 1977 397 392 352 296 234 212 222 244 ndash 308 337 383 1978 378 345 346 316 242 195 176 205 231 295 334 356 1979 403 36 364 295 ndash ndash ndash 193 242 318 359 373 1980 392 342 377 275 24 176 179 233 292 288 349 391 1981 385 346 337 342 242 178 201 224 30 326 326 369 1982 372 359 315 307 ndash ndash 196 253 252 305 353 379 1983 381 389 327 272 263 222 187 248 287 321 336 366 1984 378 393 322 299 226 215 178 214 234 ndash 336 364 1985 40 366 ndash 294 224 216 205 212 284 307 355 ndash 1986 ndash 383 372 307 ndash 193 166 196 261 277 ndash 382 1987 ndash 339 328 305 21 202 214 218 275 ndash ndash 374 1988 388 365 353 301 23 ndash ndash 228 283 334 31 33 1989 ndash 375 339 285 238 179 181 219 275 298 336 ndash 1990 368 ndash 36 309 268 19 188 205 274 309 373 393 1991 414 416 363 315 268 206 21 ndash 279 338 332 368 1992 363 383 336 263 213 178 213 197 ndash 285 313 359 1993 396 357 344 301 221 ndash 197 215 253 294 347 362 Mean 39 37 34 30 24 20 20 22 27 30 34 37 NOTE Dashes indicate data unavailable
JAN FEB MAR APR MAY JUN JUL AUG SEP OCT NOV DEC0
10
20
30
40
Month
MKS42 140498
50
Mean monthly maximum temperatures at Wiluna
Mea
n T
emp
erat
ure
(degC
)
47
Appendix 3
Table 31 Summary of palynological results
Drillhole Depth (m) F no(a) GSWA no Lithology Formation Assemblage TAI(b)
BWB 1 74ndash75 F49668 135741 dark-grey siltstone basalt Jilyilli gt5 BWB 1 98ndash100 F49669 135742 dark-grey siltstone basalt Jilyilli gt5 BWB 1 121ndash122 F49670 135743 dark-grey siltstone basalt Jilyilli gt5 TWB 1 86ndash87 F49671 135631 dark-grey siltstone McFadden 3+ TWB 1 104ndash105 F49672 135632 dark-grey siltstone Cornelia 3+ TWB 1 121ndash122 F49673 135633 dark-grey siltstone Cornelia 4 TWB 2 14ndash15 F49674 135634 dark-grey siltstone Skates Hills 3+ TWB 6 49ndash50 F49675 135675 dark-grey siltstone Cornelia 1 3+ TWB 9 49ndash51 F49676 135704 dark-grey siltstone Brassey Range 1 3+ Trainor 1 37497- F49733 138939 black mudstone with Cornelia 5 37509 light-grey siltstone Trainor 1 3809 F49734 138940 dark-grey and black Cornelia 4- laminated mudstone Trainor 1 4170 F49735 138941 black unlaminated mudstone Cornelia 4- Trainor 1 4950 F49851 139501 dark-grey indurated siltstone Cornelia 5 Trainor 1 6032 F49852 139502 dark- and light-grey Cornelia 5 indurated siltstone Trainor 1 6434 F49853 139503 greenish indurated finely Cornelia 5 laminated siltstone LDDH 1 270 F49678 138934 dark-grey siltstone interbeds Waters 1 3+ in enterolithic evaporite Tarcunyah Gp LDDH 1 277 F49679 138935 dark-grey siltstone in cavity Waters 1 3+ in enterolithic evaporite Tarcunyah Gp
NOTES (a) GSWA Fossil Catalogue number (b) TAI = Thermal Alteration Index of Traverse (1988 plate 1)
48
Appendix 4
Savory Sub-basin quantitative magnetic and gravity interpretation (extracted from Cowan 1995)
Summary
A program of quantitative aeromagnetic interpretation has been completed on BMRAGSO data from the Savory Sub-
basin Western Australia Quantitative aeromagnetic interpretation utilized the 3D Euler deconvolution method
supported by wavenumber filtering and image processing The results have provided useful information on structural
trends and depth to magnetic sources in a structurally complex area Depth to magnetic source analysis has provided
information on intra-sedimentary magnetic sources as well as basement rocks
The results of the interpretation support previously identified depocentres However the presence of magnetic
sources at several levels makes it very difficult to produce a reliable magnetic basement depth contour map It is
considered more productive to work with the 3D Euler colour circle plots and images rather than trying to contour the
results It would be necessary to carry out a full-scale interpretation of the BMRAGSO profile data to improve on the
3D Euler results The regional gravity was found to be useful in interpreting the regional setting of the area although
the very wide data spacing limits quantitative use of the data The gravity data show quite a complex picture with
limited consistent correlation between gravity features and basin structures This suggests that gravity anomalies
reflect changes in density of the basement rocks rather than basement topography especially in the northern part of the
basin
It is recommended that the GSWA investigate access to company confidential high-resolution aeromagnetic data
prior to planning further aeromagnetic surveys Private companies have flown large parts of the northern half of the
area as part of their diamond exploration program Additional gravity coverage of the area may be more cost effective
than magnetic surveys as the gravity data provides more information on changes within the sedimentary section
Introduction
The main use of aeromagnetic data in petroleum exploration has been the determination of magnetic basement
topography although there has been increasing interest in analysis of intra-sedimentary magnetic anomalies
intrabasement and suprabasement magnetic anomalies These anomalies are used to determine depth to magnetic
basement rocks and hence determine the thickness of the sedimentary sequence Unfortunately interpretation of the
intrabasement and suprabasement magnetic anomalies is non-unique in terms of position and size of causative sources
because of the inherent ambiguity of potential-field methods However this ambiguity can be reduced by placing
49
constraints on source geometry and magnetization and by using geological and other geophysical data to constrain
the solution
Before 1970 most depth-determination techniques involved graphical determination of slopes of selected
magnetic anomalies and application of various empirical factors to convert the slopes into depth estimates Geological
Society of America Memoir 47 Interpretation of Aeromagnetic Maps by Vacquier et al (1951) was a landmark for
this type of interpretation
Automated interpretation procedures have played an increasingly important role in depth interpretation and a
wide range of techniques have been developed Many of these techniques are designed for application to located data
profiles and assume a two-dimensional geometry However there has been renewed interest in techniques applicable
to gridded data
Two distinct types of method can be recognized In the first case often described as discrete methods individual
isolated magnetic anomalies are interpreted and the results used to produce a map of basement relief In the second
case often described as continuous methods areas of data containing a number of anomalies are interpreted
statistically to produce direct output of basement depths
The discrete methods usually involve a semiautomatic initial phase which generates a large number of possible
depth solutions and an interactive second phase to screen and select acceptable solutions The advantage of this
approach is that the interpreter can select features that are relatively free from interference from adjacent anomalies
and consider all aspects of a particular magnetic anomaly The disadvantage is that interpretation can be very time
consuming as a wide range of depths are usually possible depending on the initial model chosen and a significant
amount of effort is needed to select the correct model In the case of the Savory Sub-basin dataset we encountered
problems in separating basement related effects from the effects of shallower intrasedimentary magnetic sources
Because of these problems we have concentrated on displaying the Euler results accompanied by separation filter
images of the data to show the shallower effects and deeper effects rather than trying to refine a 3D Euler
deconvolution depth-to-crystalline-basement contour
The continuous methods are very direct provided that the rather restrictive assumption can be made that all
anomalies are due to lateral magnetization changes due to basement topography This means that shallow effects and
large intrabasement anomalies must be removed from the data This involves judgement and skill as it is necessary to
distinguish between the lower amplitude suprabasement anomalies due to basement topography and the larger
intrabasement anomalies reflecting magnetization changes within the basement These methods were not considered
suitable for the Savory Sub-basin magnetic dataset but were used to invert the gravity data
50
Limitations of magnetic and gravity interpretation
Interpretation of the area is limited by a shortage of information on the nature and physical properties of the deeper
sedimentary sequence and the underlying basement rocks However using techniques such as cross-correlation of
gravity and pseudo-gravity data it is possible to try to differentiate between anomalies relating to basement and those
related to the sedimentary sequence
Gravity anomalies reflect changes within the sedimentary sequence as well as basement condition These
changes in density of sedimentary rocks produce gravity anomalies without a corresponding magnetic anomaly hence
the complementary nature of gravity and magnetic surveys The main use of magnetics is to determine depth to
magnetic basement and any intra-sedimentary volcanic rocks or intrusives whereas gravity provides much more
general information on the sedimentary sequence
Unfortunately interpretation of gravity anomalies is complicated since they can be due to a number of geological
features including
bull major basement faults
bull basement highs
bull igneous intrusions within the basement
bull sedimentary basins which may or may not be isostatically compensated
bull intra-sedimentary volcanics and associated plutonic centres
Two major problems affect the interpretation of both magnetic and gravity data
1 The inherent ambiguity of potential-field data There is no unique solution to any measured gravity or magnetic
anomaly and theoretically there will be an infinite number of source geometry and magnetizationdensity
combinations which will fit the observed data This means that any a priori information which helps to select a
suitable model is very useful
2 Measured anomalies are the summation of effects from different depths For example an observed gravity profile
may contain contributions from shallow sources (density variations within the sedimentary basin) intermediate
depth sources (density variations due to large igneous intrusions within the basement) and deep sources (crustal
thinning producing a mantle anomaly) Separation of these component responses is the regionalresidual problem
which we solve using spectral analysis and differential upward continuation-based separation filtering
Regional setting and interpretation overview
The area studied includes parts of BALFOUR DOWNS (SF51-9) RUDALL (SF51-10) ROBERTSON (SF51-13) GUNANYA
(SF51-14) COLLIER (SG50-4) BULLEN (SG51-1) TRAINOR (SG51-2) MADLEY (SG51-3) NABBERU (SG50-5)
STANLEY (SG51-6) and HERBERT (SG51-7) 1250 000 sheets Broadly the area lies between latitudes 22deg00rsquondash25deg30rsquoS
and longitudes 119deg30rsquondash123deg30rsquoE
51
Regional gravity
The AGSO regional gravity data (at nominal 11 km spacing) was gridded at a 4 km mesh spacing using a minimum-
curvature algorithm Bouguer gravity values in the area are negative reflecting mass deficiency at depth and range
from -84 mgals to -25 mgals
A Bouguer gravity colour image is shown as Figure 41 A residual grid was produced by removing a fifth-order
orthogonal polynomial from the Bouguer data but did not add to the interpretation
120deg 121deg 122deg 123deg
23deg
24deg
25deg
-25
-84
50 km
MKS46 180598
mgal
Figure 41 Regional Bouguer gravity (BMRAGSO data) gridded at 4 km
52
The data show a complex pattern of positive and negative anomalies with no clearly defined trends Correlations
with aeromagnetic data and known basin structures are poor A vague north-northwest linear trend appears to coincide
with the Marloo Fault (Figure 42) A prominent negative anomaly appears to coincide with the Blake Fold and Fault
Belt depocentre and continues as a narrower negative anomaly to the east until it widens out again near the edge of the
basin Elsewhere the gravity data show little correlation with known basin structures and it is likely that especially in
the north of the area gravity anomalies are due to density changes in the basement rather than changes in basement
topography
Production of wavelength-filtered residual gravity plots and vertical gradient plots showed very patchy aliased
data reflecting poor sampling in much of the area
Regional magnetics
The AGSO regional aeromagnetic data were gridded at a 400 m mesh spacing using a minimum-curvature algorithm
(Figure 43) Most of the data has a line spacing of 1600 m with small areas of 1 km spacing The quality of the data is
acceptable for regional interpretation but is not adequate for detailed analysis The accuracy of the flight path is rather
variable reflecting the vintage of the data and the noise envelope of the data is poor by modern standards Problems
were also encountered in joining different map sheets
The magnetic anomaly pattern over the south and west part of the area shows a strong high frequency signature
reflecting the presence of widespread basic sills and dykes Some of the major north-northeasterly trending dykes can
be traced over considerable distances
Discontinuous high-frequency anomalies extend as a northwest-trending zone through the centre of the area and
this zone includes a conspicuous circular magnetic anomaly which is probably a ring complex
The northern and eastern parts of the area are characterized by long-wavelength deep-seated basement magnetic
anomalies with 120deg and 150deg trends dominant The Marloo and Perentie Faults (Figure 42) appear as distinct linear
zones and offsets A prominent easterly trending negative anomaly in the northwest of the area appears to swing round
to the southeast and may separate different basement blocks One possible interpretation is that this very deep seated
anomaly separates areas of Archaean and Proterozoic basement
Regional geology
The regional geology is described in Williams (1992) The GSWA provided a digitized version of Plate 2 from this
Bulletin the structural interpretation map to use as an overlay (Figure 42)
53
Pp
Pp
PSd
PSd
PSd
PSd
PSd
PSo
PSt
PSt
PSf
PSf
PSf
PSb
PSb
PSb
PSsPSs
PSs
PSb
PSm
PSp
PSc
PSc
PSw
PSw
PSw
PSg
PSr
PSj
PSg
PM
Pk
PY
PY
PSd
L
L
L
L
L
L
L
LL
L
L
L
LL
L
LL
L L
LL
L L
L
L
L
L
L
L
L
LL
L
L
BLAKEDEPOCENTRE
MA
RLO
O
FAU
LT
PERENTIEFAULT
50 km
MKS39120598
120deg 121deg 122deg 123deg
25deg
24deg
23deg
Approximate boundaryof aeromagnetic interpretation
PML
PSgL
PSjL
PML
PSpL
PML
PML
PSfL
PSfL
PSpL
LPc
LPcLPcPSrL
LPA
Durba Sandstone
Woora Woora Formation
McFadden Formation
Tchukardine Formation
Boondawari Formation
Skates Hills Formation
Mundadjini Formation
Coondra Formation
Spearhole Formation
Watch Point Formation
Jilyili Formation
Brassey Range Formation
Glass Spring Formation
Paterson Formation
Yeneena Group
Karara Formation
Cornelia Formation
Kahrban Subgroup
Bangemall Group
Fault
Formation boundary
PSdL
PSoL
PSfL
PStL
PSbL
PSsL
PSmL
PScL
PSpL
PSwL
PSjL
PSrL
PSgL
Pp
PYL
PkL
LPc
LPA
PML
Savory Group Other Units
PYL
Figure 42 Regional geology and structure map (after Williams 1992)
54
120deg 121deg 122deg 123deg
23deg
24deg
25deg
5820
3750
MKS47 180598
nT
50 km
Figure 43 Regional aeromagnetic data total magnetic intensity (BMRAGSO data) gridded at 400 m
Analysis
3D analysis
3D Euler deconvolution was used as the primary depth-determination method The advantage of this approach is that
consistent solutions can be obtained over the entire area with minimal assumptions about source geometries Euler
deconvolution of gridded data is used for positional information and estimation of depth to top of source Euler
55
deconvolution yields a large number of depth solutions which have to be screened to reject spurious solutions Results
are plotted as circles in eight depth ranges with radius proportional to depth and colour coded
The 400 m total magnetic intensity grid was used for the analysis Horizontal gradients in x and y and the vertical
gradient were calculated 3D Euler deconvolution was tested on the 400 m gridded data using windows of 9 times 9 and
11 times 11 and 16 times 16 data points and structural indices 05 (fault) and 10 (sill or dyke) It was concluded that the
16 times 16 window produced the best results overall and final plots were produced for the 16 times 16 window and structural
index 05 (Fig 44) Results were very good over the northern and central parts of the area showing magnetic sources
Figure 44 Depth to magnetic source 3D Euler deconvolution 16 times 16 window of 400 m gridded data structural index 05
56
at several different levels Unfortunately in the extreme south of the area shallow intrasedimentary magnetic sources
(sills and dykes) dominated the inversion and the results contained few basement solutions
In order to reduce these problems the 400 m gridded data were filtered using a separation filter based on
interpretation of the log-energy spectrum The 3D Euler method was run on the filtered data in order to generate more
basement-depth solutions Results for the deep-separation filter data were gridded and presented as a colour image in
Cowan (1995) Attempts to grid the Euler output were unsatisfactory and it is considered safer to interpret the 3D
Euler depth plots The 3D Euler depth results from the separation-filter run should be analysed with care as perfect
separation of the basement can never be achieved and there will always be some contamination from sources at
different levels
The results of original total magnetic intensity 3D Euler depth estimation for structural index 05 using a 16 point
window have been plotted at 1500 000 scale (not included in this publication but available in Cowan (1995) from the
GSWA Library as S10331) and as reduced A4 colour circle plots (Figure 44)
The results of deep-basement 3D Euler depth estimation for structural index 05 using a 16 point window have
been plotted as a colour image at 1500 000 scale and as an A4 image (not included in this publication)
2D analysis
Two equispaced profiles were interpolated with a 50 m station interval from the AGSO-located data profiles for the
BULLEN 1250 000 sheet The interpolated profiles were analysed using 2D Euler deconvolution and Werner
deconvolution Results are included in Cowan (1995) and show the use of these methods for more detailed analysis
Filtered data
In order to reconcile 3D Euler results from shallow basement and intrasedimentary magnetic sources we produced
several separation-filtered maps and images We found the shallow-layer double-separation filter (Figure 45) to be
very effective for shallow sources and the deep-layer standard-separation filter (Figure 46) for the basement layer
Gravity and magnetic data correlation
Both lsquoreduced to the polersquo (RTP) magnetics (Figure 47) and pseudo-gravity data (Figure 48) were produced as part of
the reconciliation of gravity and magnetic signatures In both cases the filtering operations assumed magnetization by
induction in the present Earths field The RTP data are fairly similar to the total magnetic intensity The pseudo-
57
gravity data are dominated by a northwest-trending strong positive anomaly and there is little correlation with the
Bouguer gravity data
The poor magneticgravity correlation is confirmed by cross-correlation of the RTP magnetics and the gravity
gradient The correlation plot in Figure 49 shows little coherent response with numerous zones of positive and
negative correlation
Figure 45 Regional aeromagnetic data shallow layer separation filter (BMRAGSO data) gridded at 400 m
Results
In the north and east of the area on the Wells Foreland Sub-basin trend (refer to Figure 1 main text) we see a range
of quite deep 3D Euler depths and several trend directions with north-northwesterly dominant There are relatively few
shallow intrasedimentary solutions in this zone
The second area of deep 3D Euler solutions lies over the Blake depocentre (Figure 43) with several trend
directions
Elsewhere the 3D Euler results are dominated by shallow intrasedimentary depth solutions reflecting mainly the
dolerite sills dykes and the ring complex However where we do see basement-related solutions in the south and
west of the area they appear to be shallower than those noted for the Wells Foreland Sub-basin and the Blake
depocentre
58
Figure 46 Regional aeromagnetic data deep-layer separation filter (BMRAGSO data) gridded at 400 m
Figure 48 Regional aeromagnetic data pseudo-gravity transform (BMRAGSO data) gridded at 400 m
Figure 47 Regional aeromagnetic data reduced-to-pole (BMRAGSO data) gridded at 400 m
Figure 49 Regional aeromagnetic and gravity data gravitymagnetic correlation using RTP magnetics and gravity gradient (BMRAGSO data) gridded at 4 km
59
This subdivision of the area into two zones of deep solutions is consistent with interpreted depocentres
However the interference between sources at different levels and the complexity of the magnetic response of the
basement rocks precludes more refined interpretation at this stage
The area of deep 3D Euler solutions over the Blake depocentre correlates with the pronounced negative gravity
anomaly discussed in the gravity interpretation section Using a density contrast of -015 gcc the negative gravity
anomaly could indicate up to 6ndash8 km of low-density sedimentary rocks depending on assumptions about the regional
field
The area of deep 3D Euler solutions over the Wells Foreland Sub-basin has a complex gravity expression and no
clear basin structure emerges from inversion of these data As noted previously it is likely that observed gravity
anomalies reflect contrasts in basement density rather than basement topography
Separation filtering applied to the magnetic data helps to enhance the intrasedimentary magnetic signature and to
give a better impression of the basement magnetic signature even though separation of the basement response is not
perfect
Conclusions
Quantitative aeromagnetic interpretation using 3D Euler deconvolution supported by wavenumber filtering and image
processing has been successful in providing structural trend and depth information for the Savory Sub-basin
Quantitative magnetic interpretation has revealed two zones of relatively deep magnetic basement beneath the
Wells Foreland Sub-basin and the Blake depocentre
This analysis of the magnetic data supports interpreted depocentres but the complexity of the basement magnetic
signature and interference from sources at different depths precludes further refinement to a map of basement
topography
Regional gravity proved to be very useful in understanding the regional setting of the area and in providing
support for aspects of the interpretation The gravity data support the interpretation of the Blake depocentre
suggesting up to 6ndash8 km of low-density sedimentary rocks
The deep structure of the Savory Sub-basin area is obviously complex with different areas underlain by
Archaean and Proterozoic basement and with the Capricorn suture occurring in the centre of the area
60
Recommendations
The quantitative magnetic interpretation needs to be reconciled with geological models available for the area
In particular the zones tentatively identified as areas with thick sedimentary rocks the Wells Foreland Sub-
basin and the Blake depocentre need to be investigated
Cross sections should be prepared across the basin for joint magneticgravity modelling especially for the Blake
depocentre It is important to be able to explain the strong negative gravity anomaly in this area
In view of the effects of basement density contrasts on the gravity field for the northern part of the area we think
that additional gravity interpretation and acquisition of new gravity data may not be justified as they will not
contribute significantly to understanding basin evolution and structure
It is recommended that GSWA try to get access to company confidential high-resolution aeromagnetic data
rather than flying new surveys The GSWA might offer to fund flying of new infill areas as a bargaining point
References
The original text of this report by Cowan (1995) and 1500 000 scale maps are filed in the GSWA Library under
S10331
COWAN D 1995 Savory Basin quantitative magnetic interpretation Western Australia Geological Survey S-series
S10331 (unpublished)
VACQUIER V STEENLAND N C HENDERSON R G and ZIETZ I 1951 Interpretation of aeromagnetic
maps The Geological Society of America Memoir 47 151p
WILLIAMS I R 1992 Geology of the Savory Basin Western Australia Western Australia Geological Survey
Bulletin 141 115p
61
Appendix 5
Geochemistry
MKS38 250398
Saturate FractionC12+ GLC
1217
Pr18
Ph
22
31CSR WELL-13 315m Cuttings
Figure 51 Canning Stock Route Well 13 gas chromatograph of extract of auger drill sample
12
17
18
22
31
Pr Ph
LDDH 1 6623m CoreSaturate FractionC12+ GLC
MKS35 240398
Figure 52 Gas chromatograph of extract from core sample at 6623 m LDDH1
62
Table 51 Canning Stock Route Well 13 auger drill samples
GSWA sample Drill depth (m)(a) Comments
135601 150 At watertable 135602 203 (all samples consist 135603 310 of sand mud and water) 135604 315 At total depth
NOTE (a) Datum for drill depth is the top of sediment fill in the well which is 155 m below ground level (ie the total depth of 315 m is 47 m below ground level)
Table 52 Canning Stock Route Well 13 gas chromatography data for 315 m depth sediment sample
Parameter Value
Weight of rock extracted (grams) 945 Total extract (ppm) 519 n-Alkane distribution n-C12 07 n-C13 23 n-C14 26 n-C15 22 n-C16 19 n-C17 14 i-C19 23 n-C18 14 i-C20 08 n-C19 11 n-C20 16 n-C21 25 n-C22 29 n-C23 70 n-C24 42 n-C25 95 n-C26 43 n-C27 83 n-C28 38 n-C29 87 n-C30 31 n-C31 273 Alkane compositional data Pristane phytane ratio 279 Pristane n-C17 ratio 161 Phytane n-C18 ratio 059 CPI (1)(a) 284 CPI (2) 209 (C21 + C22) (C28 + C29) 043
NOTE (a) CPI= Carbon preference index
63
Table 53 LDDH1 extract liquid chromatography data for 6623 m concentration
Rock extracted Total extract (grams) (ppm)
702 313
NOTE ppm= parts per million
Table 54 LDDH1 saturate gas chromatography data of core for 6623 m alkane composition
Pristane Pristane Phytane (a) CPI (1) CPI (2) (C21+C22) Phytane n-C17 n-C18 (C28+C29)
103 026 024 103 102 325
NOTE (a)CPI = carbon preference index
Table 55 LDDH1 saturate gas chromatography data of core for 6623 m n-alkane distributions
Parameter Value
n-C12 17 n-C13 38 n-C14 55 n-C15 60 n-C16 65 n-C17 74 i-C19 19 n-C18 78 i-C20 19 n-C19 80 n-C20 79 n-C21 71 n-C22 64 n-C23 57 n-C25 43 n-C24 38 n-C27 31 n-C28 23 n-C29 19 n-C30 12 n-C31 10
64
Appendix 6
Table 61 Summary of data from Trainor waterbores (TWB) and Bullen waterbores (BWB)
Well AMG Elevation TD Status(b) Completion details Water Salinity Water level Flow rate Depth to consolidated AGD84 GL (m) (m) struck mgl(c) (m) (LHr) lithology aquifer(e) Z51(a) Interval (m) (100 mm PVC) (m) (mgl)(d)
TWB 1 473660E 453 122 comp 0ndash75 plain 63 7 300 24 2 880 12 m 7287404N 75ndash93 slotted (9 260) McFadden Fm 93ndash99 plain TWB 2 472 977E 475 23 abd nil 15 m 7285877N Skates Hills Fm dry TWB 3 473259E 475 50 abd nil 7 m 7285849N Skates Hills Fm dry TWB 4 463225 E 445 50 comp 0ndash22 plain 35 7 200 55 3 600 0 m 7286143N 22ndash34 slotted (8 140) Tertiary sand and gravel 23ndash60 plain TWB 5 463095E 445 31 comp 0ndash19 plain 13 26 000 655 3 600 Tertiary sand and gravel 7277721N 19ndash25 slotted (36 700) 25ndash31 plain TWB 6 457013E 455 50 comp 0ndash42 plain 38 920 119 600 0 m 7274352N 42ndash48 slotted (1 030) Cornelia Fm ss TWB 7 453739E 475 26 susp 0ndash2 plain 11 9 300 48 4 500 0 m 7263891N (10 500) Tertiary sand TWB 8 433893E 535 60 susp 0ndash2 plain 47 8 500 gt46 1 200 0 m 7245991N (10 900) Tertiary sand and Brassey Range Fm ss TWB 9 437219E 505 51 comp 0ndash47 plain 45 1 000 58 600 1 m 7235905N 47ndash51 slotted (990) Brassey Range Fm ss TWB 10 434927E 495 32 susp 0ndash2 plain 235 450 120 0 m 7225875N (500) Dolerite
65
BWB 1 287337E 580 122 abd Nil 1 m 7245861N Jilyili Fm dry BWB 2 288346E 545 50 comp 0ndash26 plain 15 630 3 29 000 0 m 7240423N 26ndash38 slotted (730) Tertiary sand and gravel 38ndash50 plain BWB 3 305637E 545 50 abd 19 8 800 43 7 200 0 m 7240423N (10 550) Tertiary ss BWB 4 320167E 515 445 comp 0ndash20 plain 9 980 445 24 000 0 m 7248097N 20ndash32 slotted (1 190) Tertiary ss 32ndash44 plain BWB 5 353393E 545 20 susp 0ndash2 plain 45 (970) 1 m 7238934N Basalt
NOTES (a) GPS accuracy ~ 150 m (b) Comp = completed abd = abandoned susp = suspended (c) Salinity from conductivity (d) Analysis total dissolved solids (e) Fm = Formation ss = sandstone
6
The sealed Great Northern Highway lies west of the Savory Sub-basin and links Meekatharra
to Newman The TalawanandashWindy Corner graded track crosses the northern part of the sub-basin
and graded pastoral station tracks on Balfour Downs Weelarrana Kumarina Marymia and Glen-
Ayle give access to the western and southern margins The Canning Stock Route traverses the sub-
basin from north to south and is a well travelled four-wheel-drive track allowing access to the
eastern half of the sub-basin Additional minor tracks also provide access to other parts of the area
(Williams 1992) Recently flown monochrome aerial photography at 150 000 and Landsat TM
imagery covering the sub-basin is available from the Department of Land Administration
Cross-country access is similar to that in the Canning Basin with the average height of sand
dunes being lower in the Savory Sub-basin Potable water has been found in water bores in the
south of the sub-basin and is inferred to be present throughout the region Fuel and supplies are
available at Wiluna Meekatharra and Newman A good working relationship with the Western
Desert Community who hold native title claims over most of the sub-basin has been established
by GSWA
There are no meteorological stations within the Savory Sub-basin but estimates based on data
from nearby Bureau of Meteorology Stations indicate that the area is arid and has its maximum
rainfall in summer from monsoonal rains The sub-basin has reasonable access and a tolerable
working climate for all exploration activities Meteorological data for the town of Wiluna which
lies about 180 km to the south of the sub-basin are included as Appendix 2
Regional geology
Stratigraphy
Thirteen formations were recognized by Williams (1992) in the Savory Sub-basin and these are
summarized in Table 1 Although unconformities were recognized between some of the
formations and they reflect a wide range of depositional environments provenance and climatic
conditions these formations were defined by Williams (1992) as constituting the Savory Group
Five depositional sequences that are generally unconformity-bounded were recognized by
Williams (1992) (Fig 3) The correlation of significant formations within the sub-basin with other
parts of the Centralian Superbasin is shown in Figure 4 with the four Neoproterozoic
Supersequences having been defined by Walter et al (1995)
7
Durba Ss
McFadden
Woora Woora400
Tchukardine700
Skates Hills
Mundadjini1800
B
Coondra
(B)
Watch Point
Spearhole1100Jilyili
1000(A)
Glass Spring1600(A)
Brassey Range1700(A)
Abs
ent
Absent Absent
Absent
Absent
Absent
A
B
C
D
E
1A
1B
3
4A
4B
1000
2000
3000
4000
5000
6000
Max
imum
thic
knes
s
Sup
erse
quen
ce
AG
EN
EO
PR
OT
ER
OZ
OIC
NE
OP
RO
TE
RO
ZO
ICT
O
CA
MB
RIA
NM
AR
I-N
OA
N
NW SE
Savory Sub-basin Stratigraphy
MKS30 120598
Fault boundary
Unconformity
Disconformity
Conglomerate
Sandstone Mudstone
Siltstone
Evaporite
Dolomite
Boondawari800 Boondawari
Supersequence 2 is not represented in the Savory Sub-basin Total thicknesses are estimated from air photo interpretation Thicknesses of recessive units are unknown
Diamictite
Dep
ositi
onal
seq
uenc
e
Figure 3 Formations lithology and depositional sequences AndashE of the Savory Sub-basin
8
Table 1 Summary of formations in the Savory Sub-basin
Formation Super Depo Lithology Thickness Depositional Savoy Comments Seq(a) Seq(b) (m) environment Group(c)
Durba Sandstone 4 E Quartz sandstone with minor 100 Fluvial lacustrine Y Excellent reservoir basal conglomerate lenses Woora Woora 4 D Medium-grained ferruginous 400 Shallow marine deltaic Y Formation sandstone lithic sandstone quartz wacke siltstone McFadden 4 D Laminated fine- to coarse-grained 1 500 Shallow marine deltaic Y Possible reservoir Formation quartz sandstone feldspathic sandstone quartz wacke minor conglomerate siltstone Tchukardine 4 D Medium- to coarse-grained sandstone 700 Shallow marine Y Formation lithic sandstone quartz wacke conglomerate lenses siltstone minor shale Boondawari 3 C Glacigene diamictite sandstone siltstone Formation shale conglomerate minor dolomite (some stromatolitic and oolitic) rhythmite 800 Glacial shallow marine Y Possible source rock Skates Hills 1 B Thin-bedded dolomite (some stromatolitic) 200 Shallow marine sabkha Y Possible source rock Formation chert evaporites fine- to medium-grained sandstone siltstone shale patchy basal conglomerate Mundadjini 1 B Fine- to coarse-grained sandstone 1 800 Deltaic sabkha Y Possible source rock Formation conglomerate siltstone minor shale shallow marine mudstone dolomite (some stromatolitic) and evaporites Coondra 1 B Coarse- to medium-grained sandstone 1 000 Fan delta Y Possible reservoir Formation poorly sorted conglomerate pebbly sandstone Spearhole 1 B Coarse- to medium-grained sandstone 1 100 Braided fluvial deltaic Y Possible reservoir Formation pebbly sandstone siltstone and oil shows in conglomerate lenses Mundadjini 1 Boondawari 1
9
Watch Point 1 B Shale siltstone fine- to medium-grained 400 Shallow marine deltaic Y Formation sandstone glauconitic sandstone Jilyili Formation 1 A Fine-grained sandstone siltstone minor shale mudstone conglomerate lenses 1 000 Deltaic Y Brassey Range 1 A Fine- to medium-grained sandstone 1 700 Fluvial deltaic Y Formation siltstone shale minor mudstone Glass Spring 1 A Medium- to coarse-grained sandstone 1 600 Shallow marine fluvial Y Formation minor conglomerate and siltstone Tarcunyah Group 1 AampB Quartz sandstone feldspathic sandstone Shallow marine sabkha N Bitumen in LDDH1 quartz wacke shale siltstone fluvial lacustrine conglomerate evaporites dolomite Cornelia 1 A Sandstone siltstone shale mudstone Shallow marine N Overmature source rocks Formation minor glauconitic sandstone deep marine in Trainor 1 Kahrban 1 A Sandstone siltstone shale 1 700 Shallow marine deltaic N Subgroup
NOTES (a) Supersequences of Walter et al (1995) (b) Depositional sequences of Williams (1992) (c) Y= assigned to Savory Group in Williams (1992) N= previously considered to be older than the Savory Group but now included in the greater Officer Basin
10
SAVORY SUB-BASIN GIBSON SUB-BASINCENTRAL OFFICERBASIN
AMADEUS BASIN
PETERMANN RANGES OROGENY
NE
OP
RO
TE
RO
ZO
IC
ST
UR
TIA
NM
AR
INO
AN
ED
IAC
AR
IAN
CAMBRIANTO
NEOPRO-TEROZOIC
AG
E (
Ma)
SOUTHS RANGE MOVEMENT
AREYONGA MOVEMENT
Steptoe
MILES OROGENY
Mission Group
Cassidy Group
Rudall Complex
Bangemall Group
unnamed
Tar
cuny
ah G
roup
4
3
2
1
MKS12a 180598
500
550
600
650
700
750
800
850
900
SU
PE
R
SE
QU
EN
CE
unnamed
Tchukardine Fm
McFadden Fm
ArumberaSst
Julie Fm
Pertatataka Fm
Olympic FmPioneer Sst
Boondawari Fm
Turkey Hill FmLupton Fm
Kanpa Fm
Neale FmBabbagoola
FmHussar
Fm
Browne Fm
Woolnough Fm
Madley Fm
Bitt
er S
prin
gs F
m
LovesCreek M
Gillen M
Heavitree Fm
Arunta Complex
Throssell Group
TownsendQuartzite
Earaheedy Group
olderCornelia Fm
Jilyili Fm
SpearholeFm
MundadjiniFm
Skates Hills Fm
Lefroy Fm
Areyonga Fm
Aralka Fm
ME
SO
-P
RO
TE
RO
ZO
IC
Waters Fm
youngerCornelia Fm
Brassey RangeFormationKahrban
Subgroup
GlassSpring
Fm
Durba Sst
LP1ALP1B EVENT
Figure 4 Correlation of Savory Sub-basin formations with the western Officer and Amadeus Basins Fm = Formation Sst = Sandstone M = Member
11
The depositional sequences recognized in the sub-basin are an order of magnitude thicker than
those described from Phanerozoic passive-margin settings (Payton 1977 Posamentier et al 1988)
and are broadly comparable in scale to the second-order cycles of Vail et al (1977) and to the
megasequences of Hubbard et al (1985) The main subsurface data available to reveal the
unweathered nature of these rocks are Trainor-1 and the three-well diamond coring program in
Petroleum Permit EP 380 (Akubra 1 Boondawari 1 Mundadjini 1) completed in late 1997 in the
central west of the sub-basin (Figs 5 and 6)
The ages of all formations in the Savory Sub-basin are poorly constrained The only fossils
known are stromatolites and palynomorphs (acid-insoluble microfossils) Palynology from
available wells is summarized in Appendix 3 from Grey and Stevens (1997) and Grey and Cotter
(1996) and correlations using stromatolite biostratigraphy (Stevens and Grey 1997 Grey 1995f
Walter et al 1994 1995) are consistent with a Neoproterozoic age for the formations for which
data are available
A dolerite within the Boondawari Formation gave a poorly constrained RbndashSr age of about
640 Ma (Williams 1992) SHRIMP UndashPb dating of sedimentary zircons from the McFadden and
Cornelia Formations in stratigraphic drillhole Trainor 1 are discussed in Stevens and Adamides (in
prep) and Nelson (1997) The youngest ages from these analyses indicate that the maximum age
of the Cornelia Formation is Early Cambrian or Sturtian but these ages are inconsistent with
previous tectonic interpretations (Williams 1992) and current stratigraphic correlations which
suggest the Cornelia Formation is of Supersequence 1 age or older (Fig 4)
Depositional Sequence A Supersequence 1
Depositional Sequence A includes the Glass Spring Jilyili and Brassey Range Formations (Fig
3) All of these units are predominantly quartzose sandstones some of which are friable and have
significant visible porosity in outcrop Conglomerates are present in the Glass Spring and Jilyili
Formations
Depositional Sequence B Supersequence 1
Depositional Sequence B consists of the Watch Point Coondra Mundadjini Spearhole and
Skates Hills Formations (Fig 3) All of these formations contain beds of quartzose sandstone and
some also contain conglomerates The porosity of dolomites in the Skates Hills Formation appears
poor in surface exposures but its subsurface characteristics are unknown
12
50 km
120deg 121deg30 123deg
25deg
24deg
23deg
22deg
Greater Officer Basin
PNCEXP CA11PNCEXP CA12
PNCEXP CA13PNCEXP CA19
PNCEXP CA05
PNCEXP CA09
BD134589
GSWA Trainor 1 and TWB123
Fortescue River 1A
Mundadjini 1
Akubra 1Boondawari 1
TWB4TWB5
TWB6
TWB7
TWB8
TWB9
TWB10
BWB1
BWB2 BWB3
BWB4
BWB5
OD23
Mineral exploration drillhole
Stratigraphic drillhole
Waterbores and wells(TWB and BWB serieswaterbores identified)
MKS33270398
LDDH 1
Savory Sub-basin
Canning SR Well 13
EP380
Petroleum Exploration permit
Petroleum exploration well
Figure 5 Locations of petroleum exploration wells mineral exploration and stratigraphic drillholes water bores and wells and petroleum exploration permit EP380 in the Savory Sub-basin
13
TD=600m
TD=1367m
TD=701m
TD=709m
TD=50m
SS
1S
S1
SS1
SS
1S
S1
SS
1
SS
1
SS1
SS4 SS1
Pha
nero
zoic
or
SS
2
Cz
CzCz
Karst Bitumen
SS1
TD=181m
Mundadjini 1 Akubra 1 Boondawari 1 LDDH 1 Trainor 1 TWB 6
Munda-djini Fm
Spear-hole Fm
Munda-djini Fm
Munda-djini Fm
Spear-hole Fm
Spear-hole Fm
Waters Fm
McFadden Fm
Cornelia Fm
Cornelia Fm
Cornelia Fm
511 plusmn 13Maor 696 plusmn 20Ma(maximum)
779 plusmn 10Ma(maximum)
Mundadjini 1
Akubra 1 Boondawari 1
LDDH 1
Trainor 1TWB 6100 km
N
LOCATION
NW SE
Sea level
0m AHD
Dolerite basalt
Conglomerate
Sandstone
Mudstone
Dolomite
Limestone
Evaporite
TOC gt08
Permeability gt100md
Oil fluorescence
Sedimentary zircon U-Pb age
Identifiable polymorphs
Cainozoic
Supersequence 1 age
Unconformity
Formation contact
Cz
SS1
r
r
0
100
200
metres
VerticalScale
MKS36 120598
LEGEND
Figure 6 Geological cross section through significant drillholes in the Savory Sub-basin
14
Depositional Sequence C Supersequence 3
Depositional Sequence C consists of the Boondawari Formation (Fig 3) and although it contains
sandstone conglomerate and dolomite the sandstones contain significant amounts of feldspar and
clay and hence are likely to be poorer reservoirs than older sandstones
Depositional Sequence D Supersequence 4
Depositional Sequence D includes the McFadden Tchukardine and Woora Woora Formations
(Fig 3) The McFadden Formation is poorly sorted and sandstones contain significant amounts of
feldspathic clasts in the north of the basin but are significantly coarser and cleaner in the northeast
of the sub-basin (Williams 1992)
Sandstones of the Tchukardine and Woora Woora Formations are generally cleaner than those
of the McFadden Formation and are expected to have fair to good porosity although the
Tchukardine Formation has a higher clay content in parts
Depositional Sequence E Supersequence 4
Depositional Sequence E consists of the Durba Sandstone (Fig 3) a coarse sandstone with minor
conglomerate which has good to excellent visible porosity in surface exposures
Other depositional sequences and regional correlations
Sedimentary rocks which were not included in the Savory Group by Williams (1992) but which
are likely to be of Neoproterozoic age and hence part of the greater Officer Basin include the
Tarcunyah Group the Cornelia Formation and the Kahrban Subgroup
As discussed in the Introduction all of the strata in the Karara Basin and the younger strata
of the Yeneena Basin were redefined to form the Tarcunyah Group of the greater Officer Basin
(Bagas et al 1995) (Fig 7) In outcrop the Tarcunyah Group consists predominantly of quartzose
feldspathic and arkosic sandstone shale which is carbonaceous in parts and carbonate which
includes stromatolitic dolomite Mineral hole LDDH1 drilled on GUNANYA intersected the
15
120598
122deg
123deg
21deg
22deg
23deg
24deg
23deg
22deg
21deg
122deg
123deg
Fault
Thrust
Reverse thrust
CANNINGBASIN
OFFICERBASIN
GROUP
PILBARACRATON
TARCUNYAH
SAVORY GROUP
BANGEMALL
GROUP
THROSSELL
GROUP
LAMIL
GROUP
ConnaughtonTerrane
TerraneTalbot
complexTabletop granitic
Tabletop Terrane
Permian
Neoproterozoicgranitoid
50 km
FormationWaltha Woora
McKay Fault
South west Thrust
Vines
Fault
24deg
120deg
YENEENA CANNINGBASIN
ARUNTAINLIERRUDALL
COMPLEX
AMADEUSBASIN
MUSGRAVEBLOCK
OFFICERBASINYILGARN
CRATON
GROUP
GROUP
GROUP
PILBARACRATON
GROUP
EARAHEEDY
GLENGARRY
BANGEMALL
WYLOO GROUP
SAVORY
WA
CARNARVONBASIN
GASCOYNECOMPLEX
GROUPTARCUNYAH
400 kmGROUP
SA
N
T
CamelndashTabletopfault zone
KAHRBANSUBGROUP
CORNELIAFORMATION
MKS37
Figure 7 Regional geological setting of the Savory Group and western Officer Basin The dashed line on the inset map marks the interpreted margin of the greater Officer Basin
16
Tarcunyah Group and consists predominantly of mudstone with minor sandstone limestone
dolomite and anhydrite (Fig 6)
The age of the Tarcunyah Group is uncertain although limited palynological and stromatolite
evidence suggests that it is probably coeval with Supersequence 1 of the Centralian Superbasin
Drillhole LDDH1 contains palynomorphs equivalent to assemblages in the Browne and Bitter
Springs Formations of the Officer and Amadeus Basins respectively and from the Cornelia
Formation in TWB 6 (Grey and Stevens 1997) (Figs 4 and 6) Stromatolite specimens tentatively
assigned to Acaciella australica (Howchin 1914) Walter 1972 occur in the lower Tarcunyah
Group (Bagas et al 1995) The stromatolite Baicalia burra Preiss 1972 and a conical
stromatolite were reported from the upper part of the Tarcunyah Group (Stevens and Grey 1997)
The recognition of two stromatolite assemblages interpreted to have age significance in
Supersequence 1 sedimentary rocks of the Centralian Superbasin has permitted biostratigraphic
correlations between outcrop and well data The Acaciella australica assemblage appears to be
slightly older than 800 Ma and is restricted to the middle part of Supersequence 1 The Baicalia
burra assemblage is considered to be slightly younger than 800 Ma and occurs in the upper part
of Supersequence 1 (Grey 1996b Stevens and Grey 1997) The older A australica assemblage
is recognized in the Skates Hills Formation in the Savory Sub-basin and the stromatolite A
australica itself has been tentatively identified in the lower Tarcunyah Group The occurrence of
the A australica assemblage in the Woolnough Madley and Browne Formations of the Officer
Basin and in the Loves Creek Member of the Bitter Springs Formation of the Amadeus Basin
allows correlations throughout the Centralian Superbasin (Fig 4)
The younger B burra assemblage has not been recognized in sedimentary rocks of the
Savory Group as defined by Williams (1992) but it occurs in the upper parts of the Tarcunyah
Group and allows correlation of this group with outcrops of the Neale Formation and with the
Kanpa Formation in petroleum exploration well Hussar 1 both located in the central Officer Basin
of Western Australia (Fig 4) (Grey 1996b Stevens and Grey 1997) The occurrence of the B
burra assemblage in these units permits their correlation with the Burra Group in the Adelaide
Geosyncline of South Australia (K Grey unpublished data)
The Cornelia Formation and Kahrban Subgroup outcrop in the southeast of the sub-basin and
were considered by Williams (1992) to be part of the Mesoproterozoic Bangemall Basin Limited
evidence suggests that all or parts of these two units are of Neoproterozoic age The Ward and
Oldham Inliers consist of outcrops of the Cornelia Formation Waterbore TWB 6 which was
drilled on TRAINOR in the Cornelia Formation contains palynomorphs consistent with a
Supersequence 1 age (Grey and Stevens 1997) (Figs 5 and 6) In outcrop the Cornelia Formation
17
consists predominantly of sandstone and quartzite with lesser siltstone shale mudstone and chert
In Trainor 1 this formation consists predominantly of indurated mudstone with minor sandstone
chert and dolomite A major erosional unconformity separates the Cornelia Formation from
overlying formations and parts of the Cornelia Formation have been folded with dips exceeding
70deg In contrast the majority of the Savory Sub-basin sedimentary rocks have dips of less than 30deg
except where they are adjacent to faults The Cornelia Formation apparently consists of an older
unit of steeply dipping quartzites cherts and well-indurated mudstones and a younger unit of
shallower dipping sandstones which are sub-friable in parts However caution should be used in
interpreting the age of units based on their structural deformation and additional mapping and age
dating of this formation is required
It is proposed here that the Kahrban Subgroup is likely to be of early Neoproterozoic age and
hence should be considered as part of the greater Officer Basin This proposal is based largely on
the relatively low dip of the strata (generally less than 20deg) and their west-northwest strike which
is parallel with strikes in the overlying Brassey Range Formation of the Savory Group The lower
contact of the Kahrban Subgroup is obscured but is thought to be an unconfirmity on the
Earaheedy Basin on the southeast of STANLEY (Muhling and Brakel 1985)
Structural setting
The Savory Sub-basin forms the most northwesterly sub-basin of the Neoproterozoic to
Phanerozoic Officer Basin The western boundary of the sub-basin with the Mesoproterozoic
Bangemall Basin consists of steep-reverse and strike-slip faults The northeastern boundary of the
Savory Sub-basin was mapped where Supersequence 4 formations of the Savory Group
unconformably overlie sedimentary rocks of the Karara and Yeneena Basins with the two older
units considered to be part of the Paterson Orogen (Williams 1992) This contact was defined as a
series of steeply dipping reverse faults in the northernmost parts of the sub-basin on BALFOUR
DOWNS and RUDALL and was extrapolated as an inferred reverse fault farther along strike to the
southeast on GUNANYA and MADLEY where the contact is obscured by Cainozoic sediments It is
now recognized that all the sedimentary rocks in the Karara Basin and younger sedimentary rocks
of the Yeneena Basin are from the Supersequence 1 Tarcunyah Group and part of the greater
Officer Basin (Bagas et al 1995) The northern boundary of the Tarcunyah Group and the greater
Officer Basin is in thrust-and reverse-faulted contact with the Rudall Complex and other parts of
the Paterson Orogen (Fig 7)
To the south the sub-basin unconformably overlies the Bangemall Basin The eastern
boundary of the sub-basin used in this study is where Permian and younger strata of the Officer
Basin unconformably overlie Neoproterozoic strata although there are no significant structural or
stratigraphic differences between the Neoproterozoic units
18
The sub-basin is subdivided into three principal structural areas (Fig 1) Trainor Platform
Blake Fault and Fold Belt and Wells Foreland Sub-basin (Williams 1992) A major review of
these boundaries is beyond the scope of this report but the processing of regional aeromagnetic
data (Appendix 4) and acquisition of a semi-detailed gravity survey by the GSWA in the east of
the sub-basin has enabled these tectonic units to be reassessed and some modifications are
proposed
The Wells Foreland Sub-basin (originally termed the Wells Foreland Basin in Williams 1992)
and sedimentary rocks of the Tarcunyah Group are both considered to be the northwest
continuation of the Gibson Sub-basin of the Officer Basin Aeromagnetic gravity and outcrop
data suggest that the Blake Fault and Fold Belt is significantly faulted and folded in the west but
is less deformed in the east where the thickest sedimentary section in is located on BULLEN
(Appendix 4) The Trainor Platform is reinterpreted to represent an area of the sub-basin that has
undergone major compression during the Petermann Ranges Orogeny resulting in folding and
faulting with a northwest strike This interpretation contrasts with that proposed by Williams
(1992) who envisaged that only a thin section of the Savory Group was present on the platform
Perincek (1998) has recognized nine periods of tectonic activity in the Officer Basin from the
beginning of the Neoproterozoic to the end of the Cretaceous Three major tectonic episodes are
recognized in the Centralian Superbasin The oldest event is the Areyonga Movement which is
pre-Sturtian and forms the boundary between Supersequences 1 and 2 (Fig 4) The Souths Range
Movement occurred at the end of the Sturtian at the boundary between Supersequences 2 and 3
The youngest major event is the Petermann Ranges Orogeny which occured at the end of the
Marinoan and forms the boundary between Supersequences 3 and 4
One minor and two major tectonic episodes are recognized in the Savory Sub-basin the
LP1ALP1B structural event and the Areyonga Movement and the Petermann Ranges Orogeny
respectively The LP1ALP1B structural event is revealed where the Spearhole Formations rests
disconformably and locally unconformably on the Brassey Range Jilyili and Glass Spring
Formations The Neoproterozoic Areyonga Movement (equivalent to the Blake Movement of
Williams 1992) produced folds and faults with a general northeast strike in the western and
southern parts of the region The Souths Range Movement has not been recognized in the sub-
basin This may be due to the fact that no Sturtian glacial rocks have been identified and hence it
is possible that structures attributed to the Areyonga Movement could be the result of the Souths
Range Movement or a combination of the two movements
The major tectonic event recorded in the sub-basin is the latest Neoproterozoic to Cambrian
Petermann Ranges Orogeny (equivalent to the Paterson Orogeny) which produced large reverse
19
faults thrusts strike-slip faults and folds with a general northwest strike The McFadden
Formation and other Supersequence 4 strata are considered to be at least partially coeval with this
orogeny (Williams 1992) We also interpret the Durba Sandstone as having been deposited during
the later stages of the Petermann Ranges Orogeny as this unit mildly deformed with fold axes
parallel to the strike of other structures attributed to the Petermann Ranges Orogeny
Quantitative aeromagnetic interpretation of the Savory Sub-basin utilizing the 3D Euler
deconvolution method supported by wave-number filtering and image processing has provided
structural trends and depth to magnetic source within the sub-basin (Cowan 1995) Gravity data
are interpreted by Cowan (1995) as changes in both the density of the basement rocks andor
basement topography depending on local conditions Part of Cowanrsquos report is reproduced in
Appendix 4
Exploration history
The only petroleum exploration conducted in the sub-basin has been the recent drilling in the
western part of three diamond drillholes of which two have minor oil shows (Table 2) There has
been some mineral exploration the results of which are stored in the GSWA Western Australian
Mineral Exploration (WAMEX) database system Much of the mineral exploration was in the
southwest and west where the sub-basin is in contact with the Bangemall Basin and along the
northern margin of the sub-basin Many of these mineral exploration programs included
aeromagnetic surveys and surface geochemical sampling (Fig 8)
Hydrocarbon potential
The sub-basin contains a sedimentary succession up to 8 km thick which is generally gently
folded and faulted and apparently unmetamorphosed Limited drilling has shown that thick
mudstones are present in the sub-basin with some mudstones in Trainor 1 having high Total
Organic Carbon (TOC) values Outcrops of sub-friable sandstones in many of the formations
within the sub-basin suggests widespread reservoir potential Mudstone and inferred thick
evaporite sequences are likely to form seals Maturity data suggest that near-surface samples are
approximately at the base of the oil window and top of the gas window in parts of the north and
southeast of the sub-basin However parts of the southwest of the sub-basin and the mudstones in
Trainor 1 have very high levels of maturity Numerous faults and folds have been identified from
surface mapping suggesting good potential for large structural traps Minor oil shows in
20
Table 2 Neoproterozoic formations and hydrocarbon shows in diamond drillholes in the Savory Sub-basin
Drillhole AMG Core TD (m) Approx Formation Depth Formation Depth Formation Depth Shows (AGD84) start (m) GL (m) (m) (m) (m)
LDDH 1 431148E 112 701 350 Tarcunyah 68ndash701 ndash ndash bitumen at 6623 m 7443826N Group Trainor 1 473640E 6 709 455 McFadden 9ndash83 Cornelia Fm 83ndash709 possible bitumen at 4537 m 7287400N Fm Mundadjini 1 319056E 170 600 500 Mundadjini 16ndash361 Spearhole Fm 361ndash600 10 fluorescence at 36102 m 7404844N Fm Boondawari 1 348959E 299 1 367 490 Mundadjini Fm 15ndash312 Spearhole Fm 312ndash1 283 Intrusive 1 283ndash1 367 40 fluorescence at 35364 m 5 7398174N fluorescence at 4963 m Akubra 1 334249E 15 181 530 Mundadjini 15ndash42 Intrusive 42ndash181 None 7401252N Fm
21
50 km
120deg 121deg30 123deg
25deg
24deg
23deg
22deg
Greater Officer Basin
Savory Sub-basin
1
2
3
4
6
8
3 Seismic line (prefixed N83-00)
Aeromagnetic survey
GS
WA
Sav
ory
1995
gra
vity
sur
vey
Gravity survey
MKS34270398
Figure 8 Locations of aeromagnetic and gravity surveys (other than regional BMRAGSO data)
22
sandstones in two petroleum wells in the northwest of the sub-basin and bitumen and oil shows
elsewhere in the region indicate that oil has been generated and migrated through the sub-basin
Source rocks
Source potential is considered to be the major exploration risk in the Savory Sub-basin although
minor oil shows in Mundadjini 1 and Boondawari 1 indicate that at least some oil has been
generated and migrated into potential reservoirs within the sub-basin Sandstone is the
predominant lithology observed in outcrop Outcrops of fine-grained lithologies in the basin are
rare because of intense surface weathering and erosion Only about 8 of the surface area of the
sub-basin is exposed bedrock and recessive lithologies (such as shale evaporite and friable
sandstone) may be present although they rarely outcrop
Outcrops of stromatolitic dolomite with associated cauliflower chert and cubic pseudomorphs
interpreted as being after halite indicate that evaporitic environments are present within the
Mundadjini Skates Hills and Boondawari Formations Evaporitic minerals are also present in
drillhole LDDH1 in the Tarcunyah Group
In 1995 GSWA drilled a continuous-core diamond drillhole (Trainor 1) in the sub-basin on
TRAINOR to a depth of 709 m to test for source rocks thus providing the first such data for the sub-
basin The drillhole intersected flat-lying clastics and carbonates of the McFadden Formation (9ndash
83 m) overlying indurated mudstones of the Cornelia Formation (83ndash709 m total depth) dipping at
about 40deg Of the six samples analysed from the Cornelia Formation in this drillhole the five
located between 375 and 6032 m depth have TOC values exceeding 05 (range 066ndash365)
Rock-Eval pyrolysis of these five samples indicates that they are at best in the dry-gas thermal
stage and as a result of their high level of maturation (Stevens and Adamides in prep) have poor
remaining hydrocarbon-generating potential Although the Cornelia Formation is overmature at
Trainor 1 the high TOC values are encouraging as it is likely that this sequence is less mature
elsewhere in the sub-basin
The Mundadjini Formation contains potential source rocks that comprise marine mudstones
with evaporitic minerals present in parts Thin dark mudstones were intersected in the Mundadjini
Formation in Akubra 1 In Mundadjini 1 and Boondawari 1 however the mudstones appear to be
too oxidized to have source potential
The Boondawari Formation also may be a source rock as it contains black mudstones The
unit is laterally equivalent to the Pertatataka Formation of the Amadeus Basin and the Ungoolya
23
Group of the Officer Basin in South Australia both of which have some source potential
(Summons and Powell 1991 Morton and Drexel 1997) Samples from the Dey Dey Mudstone of
the Ungoolya Group generally have poor TOC values (average 011 range 003ndash081)
moderate hydrogen index (HI) values (100ndash382) and poor to fair genetic potential with a
maximum of 292 kg hydrocarbon per tonne of source rock (Morton and Drexel 1997)
Stromatolitic dolomites and mudstones at the top of the Boondawari Formation and within the
Skates Hills Formation are potential source rocks Stromatolitic dolomite and evaporitic rocks
deposited in a marginal marine to sabkha environment are considered to have good potential to
generate and preserve organic carbon without requiring a deep-water setting (Stevens and Grey
1997) Such conditions are recognized in the Skates Hills Formation and in the upper parts of the
Tarcunyah Group
Maturity
Knowledge of the maturity of sedimentary rocks within the Savory Sub-basin is still limited From
a review of palynological studies Grey and Stevens (1997) report that the thermal maturity
inferred from the Thermal Alteration Index (TAI) of 3+ from Supersequence 1 age palynomorphs
in TWB 6 TWB 9 and LDDH1 is within the hydrocarbon window (Appendix 3) In Phanerozoic
spores and pollen a TAI of 3+ approximately equates to the end of liquid petroleum generation
and the start of dry gas generation and to a vitrinite reflectance of about 13 (Traverse 1988)
However the use of TAI for estimating thermal maturity from Neoproterozoic palynomorphs
requires calibration
In Trainor 1 the Cornelia Formation contains organically rich claystones between 375 and
6032 m depth Based on Rock-Eval maturity data (Stevens and Adamides in prep) and the dark
colour of poorly preserved organic material (Grey 1995de 1996) with TAI 4- to 5 all samples
had a high level of maturation with at best dry-gas generating potential remaining In contrast
drillhole LDDH1 on GUNANYA recorded lower levels of maturity (TAI values of 3+) with two of
sixteen samples from the Tarcunyah Group having greater than 1 TOC (Grey 1995abc Grey
and Cotter 1996) Organic petrology and Rock-Eval maturity data for samples from LDDH1
indicate that the section above 500 m is within the oil-generative window whereas below 500 m
the rocks are within the gas window (Ghori in prep Fig 9 Appendix 5)
Waterbores TWB 1 2 6 and 9 which are located on TRAINOR in the southeast of the sub-
basin all had organic matter with TAI values of 3+ from the McFadden Skates Hills Cornelia
and Brassey Range Formations respectively
24
100
200
300
400
500
600
700
Oil
gene
ratin
g
Gas
gene
ratin
g
Fai
r
Fai
r
Poo
r
Poo
r
Goo
d
Imm
atur
e
Oil
win
dow
Oil
win
dow
Imm
atur
e
01 0110 10 0 150 300 440 480 1
Neo
prot
eroz
oic
TOC S1+S2 mgg Hydrogen Index Tmax degC
Depth(m)
Organicrichness
Generatingpotential
Kerogentype Maturity Maturity
TD=701m
Sandstone
Mudstone
Dolomite
Limestone
Evaporite
Source rock
MKS40 070498
Ro equivalent
Figure 9 Petroleum source potential of rocks in Normandy LDDH1
Small amounts of organic matter associated with basalt and dolerite in cuttings from
waterbore BWB 1 on BULLEN showed high levels of thermal maturity (Grey 1995a Libby 1995)
It is unclear whether all sedimentary rocks on BULLEN are overmature for hydrocarbon generation
or the results from BWB 1 are related to local heating events associated with the volcanic bodies
that are common in the Jilyili Formation
25
Reservoirs
Each of the five depositional sequences of the Savory Group (Table 1) are inferred to contain
significant sandstone reservoirs with the possible exception of depositional sequence C as
discussed above in Stratigraphy The Spearhole Formation was cored in Mundadjini 1 and
Boondawari 1 and visual estimates of porosity vary from generally poor (less than 5) to fair
(approximately 5ndash15) The McFadden Formation in Trainor 1 has porosity values of up to 232
and a maximum permeability of 195 md (Stevens and Adamides in prep) Sandstones from
Neoproterozoic formations form the acquifers in the following waterbores the McFadden
Formation in TWB 1 the Cornelia Formation in TWB 6 and the Brassey Range Formation in
TWB 8 and TWB 9 (Appendix 6 Table 61)
Based on outcrop observations the Durba Sandstone is considered to be the best reservoir of
the Savory Group Similarly some sandstones from the Tarcunyah Group also have good visible
porosity in outcrop
Dolomites occur in several formations in the sub-basin Reservoir potential may exist
particularly where the dolomites are stromatolitic and oolitic However dolomites have not been
drilled in the sub-basin and porosity can only be inferred from the preferential silicification of
some stromatolite bioherms observed in outcrop (Stevens and Grey 1997) Elsewhere in the
Officer Basin porosities of up to10 have been measured in dolomites A limestone breccia
(karst) is described from 663 to 677 m in drillhole LDDH1 (Fig 6 Busbridge 1994)
Seals
Indications of evaporitic environments in the Mundadjini Skates Hills and Boondawari
Formations are described by Williams (1992) In Mundadjini 1 from 287 to 337 m anhydrite and
chert occurs as nodules beds and veins in mudstone of the Mundadjini Formation Evaporitic
minerals (predominantly gypsum) are described in the Tarcunyah Group in LDDH1 The presence
of the Woolnough and Madley salt diapirs in the Officer Basin (approximately 110 km east of the
sub-basin) and halite beds over 25 m thick in the well Hussar 1 (130 km east of the sub-basin)
provide further evidence that evaporite seals may be present in the Savory Sub-basin
Mudstones and shales form only a small proportion of the limited Neoproterozoic outcrop in
the sub-basin but significant thicknesses of mudstone were encountered in the Mundadjini
Formation in Mundadjini 1 and Boondawari 1 the Tarcunyah Group in LDDH1 and in the
26
Cornelia Formation in Trainor 1 These data suggest that mudstones form a significant proportion
of strata in the sub-basin despite their limited outcrop
Traps
Potential structural closures including folds and faults occur at various scales throughout the
Savory Sub-basin However the region has only been mapped at 1250 000 scale and
independently closed structures such as domes have yet to be confirmed The western margin of
the basin contains abundant faults (with a northeast strike) but elsewhere faults are less common
Some anticlines are recognized in outcrop including one with a strike length of up to 45 km
inferred from surface bedding dips in the Mundadjini and Spearhole Formations at approximately
24deg15rsquoS 121deg10rsquoE on BULLEN (Fig 1)
Salt diapirs and other halokinetic structures are recognized in outcrop well and seismic data
in the Officer Basin to the west of the Savory Sub-basin and it is probable that there are
significant thicknesses of evaporitic sedimentary rocks in the sub-basin The gravity field data
suggest there is good potential for salt diapirs and traps related to halokinesis
Although there is potential for stratigraphic traps to be present in the sub-basin insufficient
data are available to assess them
Preservation of hydrocarbons
The range of thermal maturities measured to date and the large periods of time envisaged for
deposition of sediments implies hydrocarbon generation may have occurred a number of times
during the evolution of the Savory Sub-basin Any hydrocarbons that were generated early may
have been trapped in palaeostructures and remigration to younger traps could have taken place
later The Petermann Ranges Orogeny which has been equated with the Paterson Orogeny (Myers
1990) is believed to have occurred in the latest Neoproterozoic to early Cambrian This is the last
major tectonic event recognized in the sub-basin suggesting that it is reasonable to expect that trap
integrity will have been preserved
If the inference of the presence of thick halite beds in the sub-basin is correct the preservation
potential of sub-salt traps should be excellent
27
Reported hydrocarbon shows and oil seep
Amadeus Petroleum recorded minor oil shows in cores from Mundadjini 1 and Boondawari 1 In
Mundadjini 1 at 36102 m (top of the Spearhole Formation) a 3 mm thick zone had 10 moderate
white fluorescence with slow solvent cut This show was in a granular sandstone with visually
estimated porosity of about 10 In Boondawari 1 at 35364 m (within the Spearhole Formation) a
broken surface of sandstone had 40 moderate yellow-white fluorescence with slow solvent cut
Visually estimated porosity is about 5 Because the fluorescing surface was broken during the
drilling process this show could have resulted from contamination A second show occurs in
Boondawari 1 at 4963 m (within the Spearhole Formation) where a 1 cm-thick zone had 5 dull
yellow fluorescence with slow solvent cut in a conglomerate with visually estimated porosity of
about 10 The company intends to further investigate the nature of these occurrences
Minor bitumen is present at 6623 m in drillhole LDDH1 on GUNANYA (Figs 5 and 6) as a
vein in mudstones of the Tarcunyah Group A sample was analysed by gas chromatography
(Ghori in prep) and confirmed that it is natural bitumen (Appendix 5)
Mineral hole OD 23 drilled by Jubilee Gold Mines NL on NABBERU in the Bangemall Basin
immediately to the south of the Savory Sub-basin (Fig 5) encountered bitumen and trace oil in
vugs in dolomite (M Stevens unpublished data) but no further data are available at present
In their popular guide to the Canning Stock Route Gard and Gard (1990 p 218) refer to an
oil seep at Well 13 on TRAINOR (Fig 5) They reported that between 1977 and 1984 lsquonatural oilrsquo
was seen in the well Although the well is now largely filled with sediment four auger drill
samples were collected by the GSWA in 1995 and all four were analysed for oil shows One
sample from 315 m total depth (GSWA sample 135604) yielded just enough extract (519 ppm)
for saturate gas chromatography analysis The gas chromatograph (Appendix 5) shows that the
extract does contain some hydrocarbons probably from recent plant material Because the depth to
the oil was not quoted in Gard and Gard (1990) the hand-augered well may not have been deep
enough to properly test this reported seep
Geological and geophysical databases
Geological and geophysical data available for the Savory Sub-basin are limited The most recently
completed geological maps for the sub-basin were published by the GSWA between 1991 and
1995 (Williams and Tyler 1991 Williams 1992 1995ab)
28
The cores from the five drillholes listed in Table 2 believed to be all of the core available
from the sub-basin are available for inspection at GSWA Mineral exploration reports submitted
to GSWA may be searched using the WAMEX database and open-file reports are available on
microfiche Geophysical data acquired by the mining industry is not required to be filed with
GSWA if acquired over Vacant Crown Land which is the case for much of the sub-basin
Geophysical survey data submitted in mining tenement reports and which extend into Vacant
Crown Land remain confidential to the companies Original regional aeromagnetic and gravity
datasets are available from the Australian Geological Survey Organisation (AGSO)
Data pertinent to oil exploration in the sub-basin such as structural style and salt diapirism
are presented in a review of the hydrocarbon prospectivity of the Officer Basin (Perincek 1998)
Drilling
Significant drillholes in the sub-basin are summarized in Table 2
Petroleum industry data
Amadeus Petroleum drilled three petroleum exploration wells in the central west of the Savory
Sub-basin in late 1997 These wells Mundadjini 1 Boondawari 1 and Akubra 1 were drilled by
continuous diamond coring (Figs 5 and 6) All targeted potential reservoirs within the Spearhole
Formation with the Mundadjini Formation as the proposed seal The wells were located on
structures interpreted from Landsat images and limited geological investigations Both Mundadjini
1 and Boondawari 1 had minor oil shows as discussed above (Reported hydrocarbon shows)
Government data
Stratigraphic drillhole Trainor 1 was drilled by GSWA in 1995 (Stevens and Adamides in prep)
and the main results are discussed above (Source rocks and Maturity)
Mineral industry data
Normandy Exploration drillhole LDDH1 was cored in the Tarcunyah Group to a total depth of
701 m and provided source-rock and maturity data as discussed above
29
Oilmin NL drilled six percussion drillholes (BD 1 3 4 5 8 and 9) through sandstones and
shales in the northern part of the Savory Sub-basin to a maximum depth of 198 m (Fig 5
WAMEX Microfiche File M 26811 I 2610) but only brief geological descriptions are available
Hydrogeological data
Hydrogeological data within the Savory Sub-basin are limited although a long history of water
exploration extends back to the construction of the Canning Stock Route early this century No
detailed geological or wireline logs are available for the older wells along this route A few station
wells have been drilled by various methods on the south and west margins of the basin but data
are unavailable as reports are not required to be filed with the government Depth to watertable
throughout the basin is largely controlled by porosity of the bedrock
The GSWA drilled fifteen waterbores in the winter of 1995 in the southern part of the sub-
basin in preparation for the drilling of Trainor 1 and the proposed Bullen 1 Twelve bores found
water and six of these bores have salinities of less than 1000 mgL (Fig 5 Appendix 6 Table 61)
One waterbore TWB 6 has gamma ray and neutron logs run through PVC casing and these are
available from the GSWA with the digital log data included herein
Seismic data
No geophysical data have been acquired by the petroleum industry in the Savory Sub-basin
Seismic data acquired in the Officer Basin to the east particularly in the Gibson and Yowalga
Sub-basins is pertinent to structural interpretation in the Savory Sub-basin (Perincek 1996a
1998)
Aeromagnetic surveys
Government data
There are over 95 277 line kilometres of aeromagnetic data included in the AGSO dataset There
are three regional aeromagnetic surveys covering the Savory Sub-basin These were flown by the
Bureau of Mineral Resources (BMR now AGSO) in 1984 at a line spacing of 1500 m with 36 740
and 52 587 line kilometres flown and by Aerodata in 1984 at a line spacing of 1000m with 5950
line kilometres flown These data were reprocessed and interpreted for GSWA by Cowan (1995)
An edited copy of this report is included as Appendix 4 and the original report is filed in the
GSWA Library under S-series reports item 10331
30
Mineral industry data
The approximate locations of non-AGSO aeromagnetic surveys are shown in Figure 8 More
detailed information regarding the location of these surveys may be obtained using the GSWA
MAGCAT II database Additional information such as contours of aeromagnetic values may be
obtained by inspecting items on file with the GSWA
Gravity surveys
Government data
The average spacing for gravity data in the Savory Sub-basin is one station per 121 km2 (11 times 11
km grid) These data were principally collected by BMR in the early 1960s There are a few
additional regional gravity traverses across the sub-basin which are also included in the
BMRAGSO dataset These data were reprocessed and interpreted for GSWA (Fig 10) and a
report on this work is also included in Appendix 4
The GSWA completed a large semi-detailed gravity survey in the eastern Savory Sub-basin
utilizing helicopter support and Differential Global Positioning Survey (DGPS) techniques (Fig
8) This gravity survey completed in August 1995 consists of 2300 gravity stations on a 2 times 3 km
grid All stations were acquired by helicopter using Scintrex gravimeters and Ashtek dual
frequency DGPS equipment for determining location This highly efficient system allowed the
acquisition of more than 100 gravity stations per day in remote areas The resolution of this survey
is +30 cm and +05 microms-2 (Daishsat 1995) These data (Fig 11) represent a significant
improvement on the previous regional survey data and are available from GSWA (GSWA
1996ab) The results of the interpretation of these data were presented at the 1997 ASEG
Convention (Carlsen and Shevchenko 1997)
Mineral industry data
Three small gravity surveys were conducted by Oilmin NL (Fig 8) and the relevant WAMEX
reports are M 2681I 2610 I 2435 I 2567 These three surveys are of limited value because height
control was provided by barometers only and the surveys were not tied to the national gravity grid
31
23deg
25deg
120deg 122deg
Trainor 1
SAVORY
SUB-BASIN
MKS54 160498
100 km
1995 SavoryGravity Survey
254
-1056
micromsec2
Figure 10 Regional Bouguer gravity map of the Savory Sub-basin
23deg
24deg
25deg
122deg30 123deg
TRAINOR 1
123deg30
50 km
MKS53 160498
-116
-626
micro msec2
Figure11 Detailed Bouguer gravity map of the
Savory 1995 Gravity Survey from the eastern Savory Sub-basin
32
Government and academic reports
Chronostratigraphy and geochemistry
The understanding of Neoproterozoic organic chemistry palynology and structural evolution is
essential to the interpretation of hydrocarbon prospectivity Pertinent reports are included in the
bibliography (Appendix 1) Unpublished palaeontology reports describe the palynology of wells in
the Savory Sub-basin (Grey 1995andashe 1996a) Grey and Cotter (1996) discussed the potential for
Neoproterozoic palynomorphs to provide a biostratigraphic framework and palaeoenvironmental
interpretation Grey and Stevens (1997) reviewed the results of palynological studies of wells
drilled in the sub-basin and reported that Supersequence 1 palynomorphs are present in TWB 6
TWB 9 and LDDH1 (Appendix 3) Grey (1996b) reported on the use of stromatolites for
correlation in the Neoproterozoic and Stevens and Grey (1997) discussed the application of
stromatolite biostratigraphy in correlating isolated dolomite outcrops in the sub-basin with well
and seismic data in the Officer Basin and Centralian Superbasin
Although geochemical data from the Savory Sub-basin are very limited results mostly
confirm thermal maturities inferred from TAI for LDDH1 and Trainor 1 (Ghori in prep Stevens
and Adamides in prep) Those parts of the Officer Basin in Western Australia which lie to the
east of the Savory Sub-basin are sparsely drilled but Ghori (in prep) reports that most of the
Neoproterozoic succession presently lies within the oil-generative window However his study
has been unable to identify effective source-rock units and the source for oil shows Thin source
rocks are present in the Neoproterozoic in LDDH1 (Fig 9) and in three wells which lie to the east
and southeast of the Savory Sub-basin namely NJD 1 Kanpa 1A and Yowalga 3
Proposed work program
From the above limited information it is concluded that additional research on the hydrocarbon
potential of the sub-basin is justified and proposals are outlined below
bull Additional modelling of gravity and aeromagnetic data from the Savory Sub-basin is required
in light of the results from Trainor 1 and Boondawari 1 Trainor 1 showed that what appeared
to be a structurally simple area based on outcrop aeromagnetic and gravity data was in fact an
area of major structuring Boondawari 1 intersected a dolerite which is in good depth
agreement with aeromagnetic depth to source results showing this technique is useful in
detecting the depth to intrusive bodies
33
bull Additional data from mineral and petroleum exploration bores may become available and
analysis of samples from these wells should be undertaken and interpreted in the context of
their relevance to the Officer Basin
bull Stratigraphic coring in the Blake Fault and Fold Belt and in the Wells Foreland Sub-basin (Fig
1) targeting source rocks is considered essential to the continuing evaluation of the
hydrocarbon prospectivity of the Savory Sub-basin
bull Correlations using at least outcrop well and potential-field data should be prepared to link the
sub-basin with the better known parts of the Officer Basin to the east
bull Remapping is required to clarify boundary positions within the Cornelia Formation this may
resolve some of the current problems of the relationship between this unit and the rest of the
Savory Sub-basin
bull Further work is required to explain the Early Cambrian or Sturtian ages interpreted for the
Cornelia Formation from sedimentary zircon UndashPb dating in drillhole Trainor 1 The
determination of the age of the organically rich but overmature claystones in this well is
critical to assessing the hydrocarbon potential of the region
bull The thin dark mudstones intersected by Akubra 1 in the Mundadjini Formation warrant
geochemical analysis Analyses of the oil shows in Mundadjini 1 and Boondawari 1 are
currently being undertaken by Amadeus Petroleum
bull Geochemical analysis of hydrocarbons in the Bangemall Basin drillhole OD23 has been
performed by Jubilee Gold and the results will be reviewed when they are submitted to
GSWA The possibility of source rocks within the Bangemall Basin charging traps within the
Bangemall Basin and the overlying Savory Sub-basin requires further investigation
Conclusions
The Savory Sub-basin is a frontier region with only three recently drilled petroleum exploration
wells and no seismic data Based on existing geological and geophysical data it is considered too
early to draw conclusions about the hydrocarbon prospectivity of the sub-basin at this stage and
there are several reasons why the area warrants further investigation
34
1 Thick accumulations of sedimentary rocks are present (up to 8 km thickness inferred) which
may contain source reservoir and sealing strata
2 Minor oil shows occur in Mundadjini 1 and Boondawari 1 and bitumen is present in mineral
exploration drillhole LDDH1 suggesting that hydrocarbons have migrated within the
Neoproterozoic sequence of the Savory Sub-basin Oil and bitumen are present in mineral
exploration drillhole OD23 in the Bangemall Basin immediately to the south of the Savory
Sub-basin and it is possible that source rocks from the Bangemall Basin could charge traps in
the overlying Savory Sub-basin
3 The age of sedimentary rocks in the sub-basin is still poorly constrained but some of the
Neoproterozoic sedimentary rocks located on GUNANYA and TRAINOR are within the
hydrocarbon-generation window It is possible that a significant thickness of Phanerozoic
sedimentary rocks may also be present
4 Friable sandstones with visible porosity outcrop extensively suggesting numerous potential
reservoirs
5 Significant but not intense faulting and folding has been mapped implying large structural
traps may be present
6 Evaporitic sedimentary rocks occur in several formations and may provide good source rocks
and excellent seals
35
References
APAK S N and CARLSEN G M 1997 A compilation and review of data pertaining to the
hydrocarbon prospectivity of the Canning Basin Western Australia Geological Survey
Record 199610 103p
BAGAS L GREY K and WILLIAMS I R 1995 Reappraisal of the Paterson Orogen and
Savory Basin Western Australia Geological Survey Annual Review 1994ndash95 p 55ndash63
BUSBRIDGE M 1994 Lake Disappointment Exploration Licence 451064 Third Annual
Report Lake Disappointment Diamond Drill Hole LDDH1 Normandy Exploration Limited
Western Australia Geological Survey M-series Item 7567 A41358 (unpublished)
CARLSEN G M and SHEVCHENKO S I 1997 Petroleum exploration in Proterozoic basins
using potential fields data and stratigraphic coring Australian Society of Exploration
Geophysicists 12th Geophysical Conference Handbook Sydney 1997 Preview no 66 p 83
(abstract only)
COWAN D 1995 Savory Basin quantitative magnetic interpretation Western Australia
Geological Survey S-series S10331 (unpublished)
DAISHSAT PTY LTD 1995 Operational and processing report Savory Basin gravity survey
Western Australia Geological Survey S-series S10332 (unpublished)
GARD E and GARD R 1990 Canning Stock Route a travellerrsquos guide for a journey through
history Perth Western Australia Western Desert Guides 448p
GEOLOGICAL SURVEY OF WESTERN AUSTRALIA 1996a Savory Basin first vertical
derivative of Bouguer gravity image 1250 000 Western Australia Geological Survey
GEOLOGICAL SURVEY OF WESTERN AUSTRALIA 1996b Savory Basin Bouguer gravity
image 1250 000 Western Australia Geological Survey
GHORI K A R in prep Petroleum source rock potential and thermal history Officer Basin
Western Australia Western Australia Geological Survey Record
36
GREY K 1995a Savory Basin drillhole BWB 1 (Bullen waterbore) palynology and thermal
maturation GSWA Palaeontology Report no 199512 (unpublished)
GREY K 1995b Savory Basin drillholes TWB 1 2 6 9 (Trainor waterbores) palynology and
thermal maturation GSWA Palaeontology Report no 199520 (unpublished)
GREY K 1995c Palynology of Normandy-Poseidon Lake Disappointment-1 corehole
Tarcunyah Group Paterson Orogen GSWA Palaeontology Report no 199521 (unpublished)
GREY K 1995d Savory Basin drillhole Trainor 1 (Trainor diamond drilling) palynology and
thermal maturity GSWA Palaeontology Report no 199524 (unpublished)
GREY K 1995e Savory Basin drillhole Trainor 1 (Trainor diamond drilling) Additional
Preparation of two samples GSWA Palaeontology Report no 199528 (unpublished)
GREY K 1995f Neoproterozoic stromatolites from the Skates Hills Formation Savory Basin
Western Australia and a review of the distribution of Acaciella australica Australian Journal
of Earth Sciences v 42 p 123ndash132
GREY K 1996a Savory Basin drillhole Trainor 1 (Trainor diamond drilling) Additional
samples palynology and thermal maturation GSWA Palaeontology Report no 199615
(unpublished)
GREY K 1996b Preliminary stromatolite correlations for the Neoproterozoic of the Officer
Basin and a review of Australia-wide correlations GSWA Palaeontology Report no 199615
(unpublished)
GREY K and COTTER K L 1996 Palynology in the search for Proterozoic hydrocarbons
Western Australia Geological Survey Annual Review for 1995ndash96 p 70ndash80
GREY K and STEVENS M K 1997 Neoproterozoic palynomorphs of the Savory Sub-basin
Western Australia and their relevance to petroleum exploration Western Australia
Geological Survey Annual Review for 1996ndash97 p 49ndash54
HUBBARD R J PAPE J and ROBERTS D G 1985 Depositional sequence mapping as a
technique to establish tectonic and stratigraphic framework and evaluate hydrocarbon
potential on a passive continental margin in Seismic stratigraphy II an integrated approach
37
edited by O R BERG and D G WOOLVERTON American Association of Petroleum
Geologists Memoir 39 p 79ndash91
LIBBY WG 1995 A petrological report on six samples of bore cuttings from the Savory Basin
Western Australia Western Australia Geological Survey S-series S31307 (unpublished)
MORTON JGG and DREXEL JF 1997 The petroleum geology of South Australia Vol 3
Officer Basin South Australia Department of Mines and Energy Resources Report Book
9719
MUHLING P C and BRAKEL A T 1985 Geology of the Bangemall Group mdash the evolution
of an intracratonic Proterozoic basin Western Australia Geological Survey Bulletin 128
219p
MYERS J S 1990 Precambrian tectonic evolution of part of Gondwana southwestern Australia
Geology v18 p 537ndash540
NELSON D R 1997 Compilation of SHRIMP UndashPb zircon data Western Australia Geological
Survey Record 19972 196p
PAYTON C E 1977 Seismic stratigraphy mdash applications to hydrocarbon exploration
American Association of Petroleum Geologists Memoir 26 516p
PERINCEK D 1996a The age of NeoproterozoicndashPalaeozoic sediments within the Officer Basin
of the Centralian Super-basin can be constrained by major sequence-bounding unconformities
APPEA Journal v 36 pt 1 p 350ndash368
PERINCEK D 1996b The stratigraphic and structural development of the Officer Basin
Western Australia a review Western Australia Geological Survey Annual Review 1995ndash
1996 p 135ndash148
PERINCEK D 1998 A compilation and review of data pertaining to the hydrocarbon
prospectivity of the Officer Basin Western Australia Geological Survey Record 19976
POSAMENTIER H W JERSEY M T and VAIL P R 1988 Eustatic controls on clastic
deposition 1 mdash Conceptual framework in Sea-level changes an integrated approach edited by
C K WILGUS B S HASTINGS C G St C KENDALL H W POSAMENTIER
38
C A ROSS and J C VAN WAGONER Society of Economic Paleontologists and
Mineralogists Special Publication no 42
STEVENS M K and ADAMIDES N G in prep GSWA Trainor 1 well completion report
Savory Sub-basin Officer Basin Western Australia with notes on petroleum and mineral
potential Western Australia Geological Survey Record 199612
STEVENS M K and GREY K 1997 Skates Hills Formation and Tarcunyah Group Officer
Basin mdash carbonate cycles stratigraphic position and hydrocarbon prospectivity Western
Australia Geological Survey Annual Review for 1996ndash97 p 55ndash60
SUMMONS RE and POWELL C McA 1991 Petroleum source rocks of the Amadeus Basin
in Geological and geophysical studies in the Amadeus Basin central Australia edited by R J
KORSCH and JM KENNARD Australia BMR Geology and Geophysics Bulletin 236
TRAVERSE A 1988 Palaeopalynology Boston Unwin Hyman 600p
VAIL P R MITCHUM R M Jr TODD R G WIDMIER J M THOMPSON S III
SANGREE J B BUBB J N and HATLELID W G 1977 Seismic stratigraphy and
global changes of sea level in Seismic stratigraphy mdash applications to hydrocarbon
exploration edited by C E PAYTON American Association of Petroleum Geologists
Memoir 26 516p
WALTER M R and GORTER J 1994 The Neoproterozoic Centralian Superbasin in Western
Australia the Savory and Officer Basins in The sedimentary basins of Western Australia
edited by P G PURCELL and R R PURCELL Petroleum Exploration Society of Australia
Symposium Perth WA 1994 Proceedings p851ndash864
WALTER M R GREY K WILLIAMS I R and CALVER C R 1994 Stratigraphy of the
Neoproterozoic to early Palaeozoic Savory Basin and correlation with the Amadeus and
Officer Basins Australian Journal of Earth Sciences v 41 p 533ndash546
WALTER M R VEEVERS J J CALVER C R and GREY K 1995 Neoproterozoic
stratigraphy of the Centralian Superbasin Australia Precambrian Research v 73 p 173ndash195
WILLIAMS I R 1992 Geology of the Savory Basin Western Australia Western Australia
Geological Survey Bulletin 141 115p
39
WILLIAMS I R 1995a Bullen WA (2nd Edition) Western Australia Geological Survey
1250 000 Geological Series Explanatory Notes 23p
WILLIAMS I R 1995b Trainor WA (2nd Edition) Western Australia Geological Survey
1250 000 Geological Series Explanatory Notes 31p
WILLIAMS I R and TYLER I M 1991 Robertson WA (2nd edition) Western Australia
Geological Survey 1250 000 Geological Series Explanatory Notes 36p
40
41
Appendix 1
Bibliography
Reports which are relevant to this investigation but which are not specifically cited are listed
below
BAILLIE P W POWELL C McA LI Z X and RYALL A M 1994 The tectonic
framework of Western Australiarsquos Neoproterozoic to recent sedimentary basins in The
sedimentary basins of Western Australia edited by P G PURCELL and R R PURCELL
Petroleum Exploration Society of Australia Symposium Perth WA 1994 Proceedings p
45ndash62
BRADSHAW M T BRADSHAW J MURRAY A P NEEDHAM D J SPENCER L
SUMMONS R E WILMOT J and WINN S 1994 Petroleum systems in West Australian
basins in The sedimentary basins of Western Australia edited by P G PURCELL and R R
PURCELL Petroleum Exploration Society of Australia Symposium Perth WA 1994
Proceedings p 93ndash118
CLARKE G L 1991 Proterozoic tectonic reworking in the Rudall Complex Western Australia
Australian Journal of Earth Science v38 p 31ndash44
COCKBAIN A E and HOCKING R M 1990 Phanerozoic in Geology and mineral resources
of Western Australia Western Australia Geological Survey Memoir 3 p 750ndash755
ETHERIDGE M and WALL V 1994 Tectonic and structural evolution of the Australian
Proterozoic 12th Australian Geological Convention Geological Society of Australia
Abstracts no 37 p 102ndash103
GOODE A D T 1981 Proterozoic geology of Western Australia in Precambrian of the
Southern Hemisphere Developments in Precambrian geology 2 edited by I R HUNTER
Amsterdam Elsevier p 105ndash203
GREY K and JACKSON M J 1983 A re-assessment of stromatolite evidence for the
correlation of the Late Proterozoic Neale and Ilma Beds Officer Basin Western Australia
Australia BMR Journal of Australian Geology and Geophysics v 8 p 359
42
HICKMAN A H WILLIAMS I R and BAGAS L 1994 Proterozoic geology and
mineralization of the TelferndashRudall region Paterson Orogen Geological Society of Australia
(WA Division) Excursion Guidebook no 5 56p
HOCKING R M MORY A J and WILLIAMS I R 1994 An atlas of Neoproterozoic and
Phanerozoic basins of Western Australia in The sedimentary basins of Western Australia
edited by P G PURCELL and R R PURCELL Petroleum Exploration Society of Australia
Symposium Perth WA 1994 Proceedings p 21ndash 44
JACKSON P R 1966 Geology and review of exploration Officer Basin Western Australia
Hunt Oil Company Western Australia Geological Survey S-series S26 (unpublished)
JACKSON M J 1971 Notes on a geological reconnaissance of the Officer Basin Western
Australia Australia BMR Geology and Geophysics Record 19715 30p
JACKSON M J and van de GRAAFF W J E 1981 Geology of the Officer Basin Western
Australia Australia BMR Geology and Geophysics Bulletin 206 102 p
LOWRY D C JACKSON M J van de GRAAFF W J E and KENNEWELL P J 1971
Preliminary result of geological mapping in the Officer Basin Western Australia Western
Australia Geological Survey Annual Report for 1971 p 50ndash56
MYERS J S 1990 Precambrian in Geology and mineral resources of Western Australia
Western Australia Geological Survey Memoir 3 p 737ndash750
MYERS J S SHAW R D and TYLER I M 1994 Proterozoic tectonic evolution of
Australia 12th Australian Geological Convention Geological Society of Australia Abstracts
no 37 p 312
NEDIN C and JENKINS R J F 1991 Re-evaluation of unconformities separating the
lsquoEdiacaranrsquo and Cambrian systems South Australia Palaios v 6 p 102ndash108
PHILLIPS B J JAMES A W and PHILIP G M 1985 The geology and hydrocarbon
potential of the north-western Officer Basin APEA Journal 25 (1) p 52ndash61
POWELL C McA LI Z X McELHINNY M W MEERT J G and PARK J K 1993
Paleomagnetic constraints on timing of the Neoproterozoic breakup of Rodinia and Cambrian
formation of Gondwana Geology v 21 p 889ndash892
43
POWELL C McA PREISS W V GATEHOUSE C G KRAPEZ B and LI Z X 1994
South Australian record of a Rodinian epicontinental basin and its mid-Neoproterozoic
breakup to form the Palaeo-Pacific Ocean Tectonophysics v 237 no 3ndash4 p 113ndash140
PREISS W V 1976 Proterozoic stromatolites from the Nabberu and Officer Basins Western
Australia and their biostratigraphic significance South Australia Geological Survey Report
of Investigations no 47 p 1ndash51
TOWNSON W G 1985 The subsurface geology of the western Officer Basin mdash results of
Shellrsquos 1980ndash1984 petroleum exploration campaign APEA Journal v 25 (1) p 34ndash51
WATTS K J 1982 The geology of the Townsend Quartzite Upper Proterozoic shallow water
deposit of the Northern Officer Basin Western Australia Perth University of Western
Australia BSc honours thesis (unpublished)
WELLS A T and KENNEWELL P J 1974 Evaporite exploration in the Officer Basin
Western Australia at the Madley Diapirs Australia BMR Record 1974194 (unpublished)
WILLIAMS I R and MYERS J S 1990 Paterson Orogen in Geology and mineral resources
of Western Australia Western Australia Geological Survey Memoir 3 p 274ndash286
WILLIAMS I R 1990 Savory Basin in Geology and mineral resources of Western Australia
Western Australia Geological Survey Memoir 3 p 329ndash334
WILLIAMS I R 1994 The Neoproterozoic Savory Basin Western Australia in The
sedimentary basins of Western Australia edited by P G PURCELL and R R PURCELL
Petroleum Exploration Society of Australia Symposium Perth WA 1994 Proceedings p
841ndash850
WILSON R B 1967 Woolnough Hills and Madley diapiric structures Gibson Desert WA
APEA Journal v 7 p 94ndash102
44
Appendix 2
Meteorological data (from Bureau of Meteorology Perth 1994)
Table 21 Wiluna rainfall (mm)
Year Jan Feb Mar Apr May Jun Jul Aug Sept Oct Nov Dec
1975 0 45 446 309 306 59 276 4 34 886 638 164 1976 16 154 12 138 53 16 34 62 12 238 0 2 1977 44 0 66 74 68 95 24 363 1 58 12 727 1978 234 522 94 16 0 96 367 24 16 353 185 45 1979 19 173 122 88 91 4 0 246 58 0 169 114 1980 148 764 68 1081 259 626 629 06 56 02 174 0 1981 123 476 192 32 196 118 44 74 14 0 28 312 1982 374 705 206 244 1079 92 02 143 368 526 368 118 1983 1 112 928 248 0 212 56 32 5 1 42 496 1984 149 7 342 84 836 0 348 132 224 04 16 172 1985 596 483 0 166 556 0 514 56 0 0 4 0 1986 0 154 35 0 0 1085 23 01 239 137 0 04 1987 1204 119 19 89 17 575 154 126 07 1 0 398 1988 46 202 164 13 388 0 202 104 0 0 224 1309 1989 207 234 26 703 278 536 57 0 01 0 144 02 1990 1035 23 281 46 126 53 94 218 44 9 42 0 1991 48 0 41 45 0 472 297 12 0 1 0 7 1992 112 96 1025 1227 323 65 04 174 0 132 48 4 1993 0 697 0 202 445 0 12 306 18 05 14 33 Mean 25 35 22 27 27 25 18 12 6 13 13 21
JAN FEB MAR APR MAY JUN JUL AUG SEP OCT NOV DEC0
10
20
30
40
Mea
n R
ain
fall
(mm
)
Month
Mean monthly rainfall in Wiluna
MKS41 140498
45
Table 22 Wiluna minimum temperature (degC)
Year Jan Feb Mar Apr May Jun Jul Aug Sept Oct Nov Dec
1975 ndash 23 203 15 94 63 71 62 103 124 169 205 1976 242 229 194 15 10 63 59 73 95 143 16 228 1977 243 25 197 148 96 95 56 86 102 ndash 188 23 1978 241 232 203 18 102 64 76 8 9 152 19 205 1979 255 226 216 167 83 6 59 79 97 145 198 223 1980 255 226 231 155 134 83 68 75 121 108 193 223 1981 245 216 19 182 119 6 54 78 138 159 163 218 1982 232 224 177 16 ndash ndash 37 111 112 164 209 225 1983 235 24 197 147 112 88 39 88 121 162 189 219 1984 241 243 191 156 ndash 72 66 7 95 161 182 211 1985 244 231 ndash 159 98 65 71 73 117 147 205 ndash 1986 ndash 229 226 155 93 96 43 49 10 122 ndash 219 1987 ndash 217 183 175 85 77 68 68 112 ndash ndash 221 1988 238 214 209 178 111 ndash ndash 86 104 157 171 195 1989 ndash 237 199 165 107 67 44 61 107 131 187 ndash 1990 232 ndash 211 155 118 62 57 87 102 149 195 22 1991 26 256 217 168 122 101 78 ndash 113 18 168 219 1992 227 227 214 169 102 98 59 69 ndash 125 159 196 1993 241 218 196 171 103 ndash 49 68 88 128 192 211 Mean 24 23 20 16 10 8 6 8 11 14 18 21
NOTE Dashes indicate data unavailable
JAN FEB MAR APR MAY JUN JUL AUG SEP OCT NOV DEC0
10
20
30
40
Month
MKS43 140498
50
Mean monthly minimum temperatures at Wiluna
Mea
n T
emp
erat
ure
(degC
)
46
Table 23 Wiluna maximum temperature (degC)
Year Jan Feb Mar Apr May Jun Jul Aug Sept Oct Nov Dec
1975 ndash 349 326 281 247 201 197 212 256 248 31 344 1976 374 369 346 297 248 206 208 225 265 287 313 388 1977 397 392 352 296 234 212 222 244 ndash 308 337 383 1978 378 345 346 316 242 195 176 205 231 295 334 356 1979 403 36 364 295 ndash ndash ndash 193 242 318 359 373 1980 392 342 377 275 24 176 179 233 292 288 349 391 1981 385 346 337 342 242 178 201 224 30 326 326 369 1982 372 359 315 307 ndash ndash 196 253 252 305 353 379 1983 381 389 327 272 263 222 187 248 287 321 336 366 1984 378 393 322 299 226 215 178 214 234 ndash 336 364 1985 40 366 ndash 294 224 216 205 212 284 307 355 ndash 1986 ndash 383 372 307 ndash 193 166 196 261 277 ndash 382 1987 ndash 339 328 305 21 202 214 218 275 ndash ndash 374 1988 388 365 353 301 23 ndash ndash 228 283 334 31 33 1989 ndash 375 339 285 238 179 181 219 275 298 336 ndash 1990 368 ndash 36 309 268 19 188 205 274 309 373 393 1991 414 416 363 315 268 206 21 ndash 279 338 332 368 1992 363 383 336 263 213 178 213 197 ndash 285 313 359 1993 396 357 344 301 221 ndash 197 215 253 294 347 362 Mean 39 37 34 30 24 20 20 22 27 30 34 37 NOTE Dashes indicate data unavailable
JAN FEB MAR APR MAY JUN JUL AUG SEP OCT NOV DEC0
10
20
30
40
Month
MKS42 140498
50
Mean monthly maximum temperatures at Wiluna
Mea
n T
emp
erat
ure
(degC
)
47
Appendix 3
Table 31 Summary of palynological results
Drillhole Depth (m) F no(a) GSWA no Lithology Formation Assemblage TAI(b)
BWB 1 74ndash75 F49668 135741 dark-grey siltstone basalt Jilyilli gt5 BWB 1 98ndash100 F49669 135742 dark-grey siltstone basalt Jilyilli gt5 BWB 1 121ndash122 F49670 135743 dark-grey siltstone basalt Jilyilli gt5 TWB 1 86ndash87 F49671 135631 dark-grey siltstone McFadden 3+ TWB 1 104ndash105 F49672 135632 dark-grey siltstone Cornelia 3+ TWB 1 121ndash122 F49673 135633 dark-grey siltstone Cornelia 4 TWB 2 14ndash15 F49674 135634 dark-grey siltstone Skates Hills 3+ TWB 6 49ndash50 F49675 135675 dark-grey siltstone Cornelia 1 3+ TWB 9 49ndash51 F49676 135704 dark-grey siltstone Brassey Range 1 3+ Trainor 1 37497- F49733 138939 black mudstone with Cornelia 5 37509 light-grey siltstone Trainor 1 3809 F49734 138940 dark-grey and black Cornelia 4- laminated mudstone Trainor 1 4170 F49735 138941 black unlaminated mudstone Cornelia 4- Trainor 1 4950 F49851 139501 dark-grey indurated siltstone Cornelia 5 Trainor 1 6032 F49852 139502 dark- and light-grey Cornelia 5 indurated siltstone Trainor 1 6434 F49853 139503 greenish indurated finely Cornelia 5 laminated siltstone LDDH 1 270 F49678 138934 dark-grey siltstone interbeds Waters 1 3+ in enterolithic evaporite Tarcunyah Gp LDDH 1 277 F49679 138935 dark-grey siltstone in cavity Waters 1 3+ in enterolithic evaporite Tarcunyah Gp
NOTES (a) GSWA Fossil Catalogue number (b) TAI = Thermal Alteration Index of Traverse (1988 plate 1)
48
Appendix 4
Savory Sub-basin quantitative magnetic and gravity interpretation (extracted from Cowan 1995)
Summary
A program of quantitative aeromagnetic interpretation has been completed on BMRAGSO data from the Savory Sub-
basin Western Australia Quantitative aeromagnetic interpretation utilized the 3D Euler deconvolution method
supported by wavenumber filtering and image processing The results have provided useful information on structural
trends and depth to magnetic sources in a structurally complex area Depth to magnetic source analysis has provided
information on intra-sedimentary magnetic sources as well as basement rocks
The results of the interpretation support previously identified depocentres However the presence of magnetic
sources at several levels makes it very difficult to produce a reliable magnetic basement depth contour map It is
considered more productive to work with the 3D Euler colour circle plots and images rather than trying to contour the
results It would be necessary to carry out a full-scale interpretation of the BMRAGSO profile data to improve on the
3D Euler results The regional gravity was found to be useful in interpreting the regional setting of the area although
the very wide data spacing limits quantitative use of the data The gravity data show quite a complex picture with
limited consistent correlation between gravity features and basin structures This suggests that gravity anomalies
reflect changes in density of the basement rocks rather than basement topography especially in the northern part of the
basin
It is recommended that the GSWA investigate access to company confidential high-resolution aeromagnetic data
prior to planning further aeromagnetic surveys Private companies have flown large parts of the northern half of the
area as part of their diamond exploration program Additional gravity coverage of the area may be more cost effective
than magnetic surveys as the gravity data provides more information on changes within the sedimentary section
Introduction
The main use of aeromagnetic data in petroleum exploration has been the determination of magnetic basement
topography although there has been increasing interest in analysis of intra-sedimentary magnetic anomalies
intrabasement and suprabasement magnetic anomalies These anomalies are used to determine depth to magnetic
basement rocks and hence determine the thickness of the sedimentary sequence Unfortunately interpretation of the
intrabasement and suprabasement magnetic anomalies is non-unique in terms of position and size of causative sources
because of the inherent ambiguity of potential-field methods However this ambiguity can be reduced by placing
49
constraints on source geometry and magnetization and by using geological and other geophysical data to constrain
the solution
Before 1970 most depth-determination techniques involved graphical determination of slopes of selected
magnetic anomalies and application of various empirical factors to convert the slopes into depth estimates Geological
Society of America Memoir 47 Interpretation of Aeromagnetic Maps by Vacquier et al (1951) was a landmark for
this type of interpretation
Automated interpretation procedures have played an increasingly important role in depth interpretation and a
wide range of techniques have been developed Many of these techniques are designed for application to located data
profiles and assume a two-dimensional geometry However there has been renewed interest in techniques applicable
to gridded data
Two distinct types of method can be recognized In the first case often described as discrete methods individual
isolated magnetic anomalies are interpreted and the results used to produce a map of basement relief In the second
case often described as continuous methods areas of data containing a number of anomalies are interpreted
statistically to produce direct output of basement depths
The discrete methods usually involve a semiautomatic initial phase which generates a large number of possible
depth solutions and an interactive second phase to screen and select acceptable solutions The advantage of this
approach is that the interpreter can select features that are relatively free from interference from adjacent anomalies
and consider all aspects of a particular magnetic anomaly The disadvantage is that interpretation can be very time
consuming as a wide range of depths are usually possible depending on the initial model chosen and a significant
amount of effort is needed to select the correct model In the case of the Savory Sub-basin dataset we encountered
problems in separating basement related effects from the effects of shallower intrasedimentary magnetic sources
Because of these problems we have concentrated on displaying the Euler results accompanied by separation filter
images of the data to show the shallower effects and deeper effects rather than trying to refine a 3D Euler
deconvolution depth-to-crystalline-basement contour
The continuous methods are very direct provided that the rather restrictive assumption can be made that all
anomalies are due to lateral magnetization changes due to basement topography This means that shallow effects and
large intrabasement anomalies must be removed from the data This involves judgement and skill as it is necessary to
distinguish between the lower amplitude suprabasement anomalies due to basement topography and the larger
intrabasement anomalies reflecting magnetization changes within the basement These methods were not considered
suitable for the Savory Sub-basin magnetic dataset but were used to invert the gravity data
50
Limitations of magnetic and gravity interpretation
Interpretation of the area is limited by a shortage of information on the nature and physical properties of the deeper
sedimentary sequence and the underlying basement rocks However using techniques such as cross-correlation of
gravity and pseudo-gravity data it is possible to try to differentiate between anomalies relating to basement and those
related to the sedimentary sequence
Gravity anomalies reflect changes within the sedimentary sequence as well as basement condition These
changes in density of sedimentary rocks produce gravity anomalies without a corresponding magnetic anomaly hence
the complementary nature of gravity and magnetic surveys The main use of magnetics is to determine depth to
magnetic basement and any intra-sedimentary volcanic rocks or intrusives whereas gravity provides much more
general information on the sedimentary sequence
Unfortunately interpretation of gravity anomalies is complicated since they can be due to a number of geological
features including
bull major basement faults
bull basement highs
bull igneous intrusions within the basement
bull sedimentary basins which may or may not be isostatically compensated
bull intra-sedimentary volcanics and associated plutonic centres
Two major problems affect the interpretation of both magnetic and gravity data
1 The inherent ambiguity of potential-field data There is no unique solution to any measured gravity or magnetic
anomaly and theoretically there will be an infinite number of source geometry and magnetizationdensity
combinations which will fit the observed data This means that any a priori information which helps to select a
suitable model is very useful
2 Measured anomalies are the summation of effects from different depths For example an observed gravity profile
may contain contributions from shallow sources (density variations within the sedimentary basin) intermediate
depth sources (density variations due to large igneous intrusions within the basement) and deep sources (crustal
thinning producing a mantle anomaly) Separation of these component responses is the regionalresidual problem
which we solve using spectral analysis and differential upward continuation-based separation filtering
Regional setting and interpretation overview
The area studied includes parts of BALFOUR DOWNS (SF51-9) RUDALL (SF51-10) ROBERTSON (SF51-13) GUNANYA
(SF51-14) COLLIER (SG50-4) BULLEN (SG51-1) TRAINOR (SG51-2) MADLEY (SG51-3) NABBERU (SG50-5)
STANLEY (SG51-6) and HERBERT (SG51-7) 1250 000 sheets Broadly the area lies between latitudes 22deg00rsquondash25deg30rsquoS
and longitudes 119deg30rsquondash123deg30rsquoE
51
Regional gravity
The AGSO regional gravity data (at nominal 11 km spacing) was gridded at a 4 km mesh spacing using a minimum-
curvature algorithm Bouguer gravity values in the area are negative reflecting mass deficiency at depth and range
from -84 mgals to -25 mgals
A Bouguer gravity colour image is shown as Figure 41 A residual grid was produced by removing a fifth-order
orthogonal polynomial from the Bouguer data but did not add to the interpretation
120deg 121deg 122deg 123deg
23deg
24deg
25deg
-25
-84
50 km
MKS46 180598
mgal
Figure 41 Regional Bouguer gravity (BMRAGSO data) gridded at 4 km
52
The data show a complex pattern of positive and negative anomalies with no clearly defined trends Correlations
with aeromagnetic data and known basin structures are poor A vague north-northwest linear trend appears to coincide
with the Marloo Fault (Figure 42) A prominent negative anomaly appears to coincide with the Blake Fold and Fault
Belt depocentre and continues as a narrower negative anomaly to the east until it widens out again near the edge of the
basin Elsewhere the gravity data show little correlation with known basin structures and it is likely that especially in
the north of the area gravity anomalies are due to density changes in the basement rather than changes in basement
topography
Production of wavelength-filtered residual gravity plots and vertical gradient plots showed very patchy aliased
data reflecting poor sampling in much of the area
Regional magnetics
The AGSO regional aeromagnetic data were gridded at a 400 m mesh spacing using a minimum-curvature algorithm
(Figure 43) Most of the data has a line spacing of 1600 m with small areas of 1 km spacing The quality of the data is
acceptable for regional interpretation but is not adequate for detailed analysis The accuracy of the flight path is rather
variable reflecting the vintage of the data and the noise envelope of the data is poor by modern standards Problems
were also encountered in joining different map sheets
The magnetic anomaly pattern over the south and west part of the area shows a strong high frequency signature
reflecting the presence of widespread basic sills and dykes Some of the major north-northeasterly trending dykes can
be traced over considerable distances
Discontinuous high-frequency anomalies extend as a northwest-trending zone through the centre of the area and
this zone includes a conspicuous circular magnetic anomaly which is probably a ring complex
The northern and eastern parts of the area are characterized by long-wavelength deep-seated basement magnetic
anomalies with 120deg and 150deg trends dominant The Marloo and Perentie Faults (Figure 42) appear as distinct linear
zones and offsets A prominent easterly trending negative anomaly in the northwest of the area appears to swing round
to the southeast and may separate different basement blocks One possible interpretation is that this very deep seated
anomaly separates areas of Archaean and Proterozoic basement
Regional geology
The regional geology is described in Williams (1992) The GSWA provided a digitized version of Plate 2 from this
Bulletin the structural interpretation map to use as an overlay (Figure 42)
53
Pp
Pp
PSd
PSd
PSd
PSd
PSd
PSo
PSt
PSt
PSf
PSf
PSf
PSb
PSb
PSb
PSsPSs
PSs
PSb
PSm
PSp
PSc
PSc
PSw
PSw
PSw
PSg
PSr
PSj
PSg
PM
Pk
PY
PY
PSd
L
L
L
L
L
L
L
LL
L
L
L
LL
L
LL
L L
LL
L L
L
L
L
L
L
L
L
LL
L
L
BLAKEDEPOCENTRE
MA
RLO
O
FAU
LT
PERENTIEFAULT
50 km
MKS39120598
120deg 121deg 122deg 123deg
25deg
24deg
23deg
Approximate boundaryof aeromagnetic interpretation
PML
PSgL
PSjL
PML
PSpL
PML
PML
PSfL
PSfL
PSpL
LPc
LPcLPcPSrL
LPA
Durba Sandstone
Woora Woora Formation
McFadden Formation
Tchukardine Formation
Boondawari Formation
Skates Hills Formation
Mundadjini Formation
Coondra Formation
Spearhole Formation
Watch Point Formation
Jilyili Formation
Brassey Range Formation
Glass Spring Formation
Paterson Formation
Yeneena Group
Karara Formation
Cornelia Formation
Kahrban Subgroup
Bangemall Group
Fault
Formation boundary
PSdL
PSoL
PSfL
PStL
PSbL
PSsL
PSmL
PScL
PSpL
PSwL
PSjL
PSrL
PSgL
Pp
PYL
PkL
LPc
LPA
PML
Savory Group Other Units
PYL
Figure 42 Regional geology and structure map (after Williams 1992)
54
120deg 121deg 122deg 123deg
23deg
24deg
25deg
5820
3750
MKS47 180598
nT
50 km
Figure 43 Regional aeromagnetic data total magnetic intensity (BMRAGSO data) gridded at 400 m
Analysis
3D analysis
3D Euler deconvolution was used as the primary depth-determination method The advantage of this approach is that
consistent solutions can be obtained over the entire area with minimal assumptions about source geometries Euler
deconvolution of gridded data is used for positional information and estimation of depth to top of source Euler
55
deconvolution yields a large number of depth solutions which have to be screened to reject spurious solutions Results
are plotted as circles in eight depth ranges with radius proportional to depth and colour coded
The 400 m total magnetic intensity grid was used for the analysis Horizontal gradients in x and y and the vertical
gradient were calculated 3D Euler deconvolution was tested on the 400 m gridded data using windows of 9 times 9 and
11 times 11 and 16 times 16 data points and structural indices 05 (fault) and 10 (sill or dyke) It was concluded that the
16 times 16 window produced the best results overall and final plots were produced for the 16 times 16 window and structural
index 05 (Fig 44) Results were very good over the northern and central parts of the area showing magnetic sources
Figure 44 Depth to magnetic source 3D Euler deconvolution 16 times 16 window of 400 m gridded data structural index 05
56
at several different levels Unfortunately in the extreme south of the area shallow intrasedimentary magnetic sources
(sills and dykes) dominated the inversion and the results contained few basement solutions
In order to reduce these problems the 400 m gridded data were filtered using a separation filter based on
interpretation of the log-energy spectrum The 3D Euler method was run on the filtered data in order to generate more
basement-depth solutions Results for the deep-separation filter data were gridded and presented as a colour image in
Cowan (1995) Attempts to grid the Euler output were unsatisfactory and it is considered safer to interpret the 3D
Euler depth plots The 3D Euler depth results from the separation-filter run should be analysed with care as perfect
separation of the basement can never be achieved and there will always be some contamination from sources at
different levels
The results of original total magnetic intensity 3D Euler depth estimation for structural index 05 using a 16 point
window have been plotted at 1500 000 scale (not included in this publication but available in Cowan (1995) from the
GSWA Library as S10331) and as reduced A4 colour circle plots (Figure 44)
The results of deep-basement 3D Euler depth estimation for structural index 05 using a 16 point window have
been plotted as a colour image at 1500 000 scale and as an A4 image (not included in this publication)
2D analysis
Two equispaced profiles were interpolated with a 50 m station interval from the AGSO-located data profiles for the
BULLEN 1250 000 sheet The interpolated profiles were analysed using 2D Euler deconvolution and Werner
deconvolution Results are included in Cowan (1995) and show the use of these methods for more detailed analysis
Filtered data
In order to reconcile 3D Euler results from shallow basement and intrasedimentary magnetic sources we produced
several separation-filtered maps and images We found the shallow-layer double-separation filter (Figure 45) to be
very effective for shallow sources and the deep-layer standard-separation filter (Figure 46) for the basement layer
Gravity and magnetic data correlation
Both lsquoreduced to the polersquo (RTP) magnetics (Figure 47) and pseudo-gravity data (Figure 48) were produced as part of
the reconciliation of gravity and magnetic signatures In both cases the filtering operations assumed magnetization by
induction in the present Earths field The RTP data are fairly similar to the total magnetic intensity The pseudo-
57
gravity data are dominated by a northwest-trending strong positive anomaly and there is little correlation with the
Bouguer gravity data
The poor magneticgravity correlation is confirmed by cross-correlation of the RTP magnetics and the gravity
gradient The correlation plot in Figure 49 shows little coherent response with numerous zones of positive and
negative correlation
Figure 45 Regional aeromagnetic data shallow layer separation filter (BMRAGSO data) gridded at 400 m
Results
In the north and east of the area on the Wells Foreland Sub-basin trend (refer to Figure 1 main text) we see a range
of quite deep 3D Euler depths and several trend directions with north-northwesterly dominant There are relatively few
shallow intrasedimentary solutions in this zone
The second area of deep 3D Euler solutions lies over the Blake depocentre (Figure 43) with several trend
directions
Elsewhere the 3D Euler results are dominated by shallow intrasedimentary depth solutions reflecting mainly the
dolerite sills dykes and the ring complex However where we do see basement-related solutions in the south and
west of the area they appear to be shallower than those noted for the Wells Foreland Sub-basin and the Blake
depocentre
58
Figure 46 Regional aeromagnetic data deep-layer separation filter (BMRAGSO data) gridded at 400 m
Figure 48 Regional aeromagnetic data pseudo-gravity transform (BMRAGSO data) gridded at 400 m
Figure 47 Regional aeromagnetic data reduced-to-pole (BMRAGSO data) gridded at 400 m
Figure 49 Regional aeromagnetic and gravity data gravitymagnetic correlation using RTP magnetics and gravity gradient (BMRAGSO data) gridded at 4 km
59
This subdivision of the area into two zones of deep solutions is consistent with interpreted depocentres
However the interference between sources at different levels and the complexity of the magnetic response of the
basement rocks precludes more refined interpretation at this stage
The area of deep 3D Euler solutions over the Blake depocentre correlates with the pronounced negative gravity
anomaly discussed in the gravity interpretation section Using a density contrast of -015 gcc the negative gravity
anomaly could indicate up to 6ndash8 km of low-density sedimentary rocks depending on assumptions about the regional
field
The area of deep 3D Euler solutions over the Wells Foreland Sub-basin has a complex gravity expression and no
clear basin structure emerges from inversion of these data As noted previously it is likely that observed gravity
anomalies reflect contrasts in basement density rather than basement topography
Separation filtering applied to the magnetic data helps to enhance the intrasedimentary magnetic signature and to
give a better impression of the basement magnetic signature even though separation of the basement response is not
perfect
Conclusions
Quantitative aeromagnetic interpretation using 3D Euler deconvolution supported by wavenumber filtering and image
processing has been successful in providing structural trend and depth information for the Savory Sub-basin
Quantitative magnetic interpretation has revealed two zones of relatively deep magnetic basement beneath the
Wells Foreland Sub-basin and the Blake depocentre
This analysis of the magnetic data supports interpreted depocentres but the complexity of the basement magnetic
signature and interference from sources at different depths precludes further refinement to a map of basement
topography
Regional gravity proved to be very useful in understanding the regional setting of the area and in providing
support for aspects of the interpretation The gravity data support the interpretation of the Blake depocentre
suggesting up to 6ndash8 km of low-density sedimentary rocks
The deep structure of the Savory Sub-basin area is obviously complex with different areas underlain by
Archaean and Proterozoic basement and with the Capricorn suture occurring in the centre of the area
60
Recommendations
The quantitative magnetic interpretation needs to be reconciled with geological models available for the area
In particular the zones tentatively identified as areas with thick sedimentary rocks the Wells Foreland Sub-
basin and the Blake depocentre need to be investigated
Cross sections should be prepared across the basin for joint magneticgravity modelling especially for the Blake
depocentre It is important to be able to explain the strong negative gravity anomaly in this area
In view of the effects of basement density contrasts on the gravity field for the northern part of the area we think
that additional gravity interpretation and acquisition of new gravity data may not be justified as they will not
contribute significantly to understanding basin evolution and structure
It is recommended that GSWA try to get access to company confidential high-resolution aeromagnetic data
rather than flying new surveys The GSWA might offer to fund flying of new infill areas as a bargaining point
References
The original text of this report by Cowan (1995) and 1500 000 scale maps are filed in the GSWA Library under
S10331
COWAN D 1995 Savory Basin quantitative magnetic interpretation Western Australia Geological Survey S-series
S10331 (unpublished)
VACQUIER V STEENLAND N C HENDERSON R G and ZIETZ I 1951 Interpretation of aeromagnetic
maps The Geological Society of America Memoir 47 151p
WILLIAMS I R 1992 Geology of the Savory Basin Western Australia Western Australia Geological Survey
Bulletin 141 115p
61
Appendix 5
Geochemistry
MKS38 250398
Saturate FractionC12+ GLC
1217
Pr18
Ph
22
31CSR WELL-13 315m Cuttings
Figure 51 Canning Stock Route Well 13 gas chromatograph of extract of auger drill sample
12
17
18
22
31
Pr Ph
LDDH 1 6623m CoreSaturate FractionC12+ GLC
MKS35 240398
Figure 52 Gas chromatograph of extract from core sample at 6623 m LDDH1
62
Table 51 Canning Stock Route Well 13 auger drill samples
GSWA sample Drill depth (m)(a) Comments
135601 150 At watertable 135602 203 (all samples consist 135603 310 of sand mud and water) 135604 315 At total depth
NOTE (a) Datum for drill depth is the top of sediment fill in the well which is 155 m below ground level (ie the total depth of 315 m is 47 m below ground level)
Table 52 Canning Stock Route Well 13 gas chromatography data for 315 m depth sediment sample
Parameter Value
Weight of rock extracted (grams) 945 Total extract (ppm) 519 n-Alkane distribution n-C12 07 n-C13 23 n-C14 26 n-C15 22 n-C16 19 n-C17 14 i-C19 23 n-C18 14 i-C20 08 n-C19 11 n-C20 16 n-C21 25 n-C22 29 n-C23 70 n-C24 42 n-C25 95 n-C26 43 n-C27 83 n-C28 38 n-C29 87 n-C30 31 n-C31 273 Alkane compositional data Pristane phytane ratio 279 Pristane n-C17 ratio 161 Phytane n-C18 ratio 059 CPI (1)(a) 284 CPI (2) 209 (C21 + C22) (C28 + C29) 043
NOTE (a) CPI= Carbon preference index
63
Table 53 LDDH1 extract liquid chromatography data for 6623 m concentration
Rock extracted Total extract (grams) (ppm)
702 313
NOTE ppm= parts per million
Table 54 LDDH1 saturate gas chromatography data of core for 6623 m alkane composition
Pristane Pristane Phytane (a) CPI (1) CPI (2) (C21+C22) Phytane n-C17 n-C18 (C28+C29)
103 026 024 103 102 325
NOTE (a)CPI = carbon preference index
Table 55 LDDH1 saturate gas chromatography data of core for 6623 m n-alkane distributions
Parameter Value
n-C12 17 n-C13 38 n-C14 55 n-C15 60 n-C16 65 n-C17 74 i-C19 19 n-C18 78 i-C20 19 n-C19 80 n-C20 79 n-C21 71 n-C22 64 n-C23 57 n-C25 43 n-C24 38 n-C27 31 n-C28 23 n-C29 19 n-C30 12 n-C31 10
64
Appendix 6
Table 61 Summary of data from Trainor waterbores (TWB) and Bullen waterbores (BWB)
Well AMG Elevation TD Status(b) Completion details Water Salinity Water level Flow rate Depth to consolidated AGD84 GL (m) (m) struck mgl(c) (m) (LHr) lithology aquifer(e) Z51(a) Interval (m) (100 mm PVC) (m) (mgl)(d)
TWB 1 473660E 453 122 comp 0ndash75 plain 63 7 300 24 2 880 12 m 7287404N 75ndash93 slotted (9 260) McFadden Fm 93ndash99 plain TWB 2 472 977E 475 23 abd nil 15 m 7285877N Skates Hills Fm dry TWB 3 473259E 475 50 abd nil 7 m 7285849N Skates Hills Fm dry TWB 4 463225 E 445 50 comp 0ndash22 plain 35 7 200 55 3 600 0 m 7286143N 22ndash34 slotted (8 140) Tertiary sand and gravel 23ndash60 plain TWB 5 463095E 445 31 comp 0ndash19 plain 13 26 000 655 3 600 Tertiary sand and gravel 7277721N 19ndash25 slotted (36 700) 25ndash31 plain TWB 6 457013E 455 50 comp 0ndash42 plain 38 920 119 600 0 m 7274352N 42ndash48 slotted (1 030) Cornelia Fm ss TWB 7 453739E 475 26 susp 0ndash2 plain 11 9 300 48 4 500 0 m 7263891N (10 500) Tertiary sand TWB 8 433893E 535 60 susp 0ndash2 plain 47 8 500 gt46 1 200 0 m 7245991N (10 900) Tertiary sand and Brassey Range Fm ss TWB 9 437219E 505 51 comp 0ndash47 plain 45 1 000 58 600 1 m 7235905N 47ndash51 slotted (990) Brassey Range Fm ss TWB 10 434927E 495 32 susp 0ndash2 plain 235 450 120 0 m 7225875N (500) Dolerite
65
BWB 1 287337E 580 122 abd Nil 1 m 7245861N Jilyili Fm dry BWB 2 288346E 545 50 comp 0ndash26 plain 15 630 3 29 000 0 m 7240423N 26ndash38 slotted (730) Tertiary sand and gravel 38ndash50 plain BWB 3 305637E 545 50 abd 19 8 800 43 7 200 0 m 7240423N (10 550) Tertiary ss BWB 4 320167E 515 445 comp 0ndash20 plain 9 980 445 24 000 0 m 7248097N 20ndash32 slotted (1 190) Tertiary ss 32ndash44 plain BWB 5 353393E 545 20 susp 0ndash2 plain 45 (970) 1 m 7238934N Basalt
NOTES (a) GPS accuracy ~ 150 m (b) Comp = completed abd = abandoned susp = suspended (c) Salinity from conductivity (d) Analysis total dissolved solids (e) Fm = Formation ss = sandstone
7
Durba Ss
McFadden
Woora Woora400
Tchukardine700
Skates Hills
Mundadjini1800
B
Coondra
(B)
Watch Point
Spearhole1100Jilyili
1000(A)
Glass Spring1600(A)
Brassey Range1700(A)
Abs
ent
Absent Absent
Absent
Absent
Absent
A
B
C
D
E
1A
1B
3
4A
4B
1000
2000
3000
4000
5000
6000
Max
imum
thic
knes
s
Sup
erse
quen
ce
AG
EN
EO
PR
OT
ER
OZ
OIC
NE
OP
RO
TE
RO
ZO
ICT
O
CA
MB
RIA
NM
AR
I-N
OA
N
NW SE
Savory Sub-basin Stratigraphy
MKS30 120598
Fault boundary
Unconformity
Disconformity
Conglomerate
Sandstone Mudstone
Siltstone
Evaporite
Dolomite
Boondawari800 Boondawari
Supersequence 2 is not represented in the Savory Sub-basin Total thicknesses are estimated from air photo interpretation Thicknesses of recessive units are unknown
Diamictite
Dep
ositi
onal
seq
uenc
e
Figure 3 Formations lithology and depositional sequences AndashE of the Savory Sub-basin
8
Table 1 Summary of formations in the Savory Sub-basin
Formation Super Depo Lithology Thickness Depositional Savoy Comments Seq(a) Seq(b) (m) environment Group(c)
Durba Sandstone 4 E Quartz sandstone with minor 100 Fluvial lacustrine Y Excellent reservoir basal conglomerate lenses Woora Woora 4 D Medium-grained ferruginous 400 Shallow marine deltaic Y Formation sandstone lithic sandstone quartz wacke siltstone McFadden 4 D Laminated fine- to coarse-grained 1 500 Shallow marine deltaic Y Possible reservoir Formation quartz sandstone feldspathic sandstone quartz wacke minor conglomerate siltstone Tchukardine 4 D Medium- to coarse-grained sandstone 700 Shallow marine Y Formation lithic sandstone quartz wacke conglomerate lenses siltstone minor shale Boondawari 3 C Glacigene diamictite sandstone siltstone Formation shale conglomerate minor dolomite (some stromatolitic and oolitic) rhythmite 800 Glacial shallow marine Y Possible source rock Skates Hills 1 B Thin-bedded dolomite (some stromatolitic) 200 Shallow marine sabkha Y Possible source rock Formation chert evaporites fine- to medium-grained sandstone siltstone shale patchy basal conglomerate Mundadjini 1 B Fine- to coarse-grained sandstone 1 800 Deltaic sabkha Y Possible source rock Formation conglomerate siltstone minor shale shallow marine mudstone dolomite (some stromatolitic) and evaporites Coondra 1 B Coarse- to medium-grained sandstone 1 000 Fan delta Y Possible reservoir Formation poorly sorted conglomerate pebbly sandstone Spearhole 1 B Coarse- to medium-grained sandstone 1 100 Braided fluvial deltaic Y Possible reservoir Formation pebbly sandstone siltstone and oil shows in conglomerate lenses Mundadjini 1 Boondawari 1
9
Watch Point 1 B Shale siltstone fine- to medium-grained 400 Shallow marine deltaic Y Formation sandstone glauconitic sandstone Jilyili Formation 1 A Fine-grained sandstone siltstone minor shale mudstone conglomerate lenses 1 000 Deltaic Y Brassey Range 1 A Fine- to medium-grained sandstone 1 700 Fluvial deltaic Y Formation siltstone shale minor mudstone Glass Spring 1 A Medium- to coarse-grained sandstone 1 600 Shallow marine fluvial Y Formation minor conglomerate and siltstone Tarcunyah Group 1 AampB Quartz sandstone feldspathic sandstone Shallow marine sabkha N Bitumen in LDDH1 quartz wacke shale siltstone fluvial lacustrine conglomerate evaporites dolomite Cornelia 1 A Sandstone siltstone shale mudstone Shallow marine N Overmature source rocks Formation minor glauconitic sandstone deep marine in Trainor 1 Kahrban 1 A Sandstone siltstone shale 1 700 Shallow marine deltaic N Subgroup
NOTES (a) Supersequences of Walter et al (1995) (b) Depositional sequences of Williams (1992) (c) Y= assigned to Savory Group in Williams (1992) N= previously considered to be older than the Savory Group but now included in the greater Officer Basin
10
SAVORY SUB-BASIN GIBSON SUB-BASINCENTRAL OFFICERBASIN
AMADEUS BASIN
PETERMANN RANGES OROGENY
NE
OP
RO
TE
RO
ZO
IC
ST
UR
TIA
NM
AR
INO
AN
ED
IAC
AR
IAN
CAMBRIANTO
NEOPRO-TEROZOIC
AG
E (
Ma)
SOUTHS RANGE MOVEMENT
AREYONGA MOVEMENT
Steptoe
MILES OROGENY
Mission Group
Cassidy Group
Rudall Complex
Bangemall Group
unnamed
Tar
cuny
ah G
roup
4
3
2
1
MKS12a 180598
500
550
600
650
700
750
800
850
900
SU
PE
R
SE
QU
EN
CE
unnamed
Tchukardine Fm
McFadden Fm
ArumberaSst
Julie Fm
Pertatataka Fm
Olympic FmPioneer Sst
Boondawari Fm
Turkey Hill FmLupton Fm
Kanpa Fm
Neale FmBabbagoola
FmHussar
Fm
Browne Fm
Woolnough Fm
Madley Fm
Bitt
er S
prin
gs F
m
LovesCreek M
Gillen M
Heavitree Fm
Arunta Complex
Throssell Group
TownsendQuartzite
Earaheedy Group
olderCornelia Fm
Jilyili Fm
SpearholeFm
MundadjiniFm
Skates Hills Fm
Lefroy Fm
Areyonga Fm
Aralka Fm
ME
SO
-P
RO
TE
RO
ZO
IC
Waters Fm
youngerCornelia Fm
Brassey RangeFormationKahrban
Subgroup
GlassSpring
Fm
Durba Sst
LP1ALP1B EVENT
Figure 4 Correlation of Savory Sub-basin formations with the western Officer and Amadeus Basins Fm = Formation Sst = Sandstone M = Member
11
The depositional sequences recognized in the sub-basin are an order of magnitude thicker than
those described from Phanerozoic passive-margin settings (Payton 1977 Posamentier et al 1988)
and are broadly comparable in scale to the second-order cycles of Vail et al (1977) and to the
megasequences of Hubbard et al (1985) The main subsurface data available to reveal the
unweathered nature of these rocks are Trainor-1 and the three-well diamond coring program in
Petroleum Permit EP 380 (Akubra 1 Boondawari 1 Mundadjini 1) completed in late 1997 in the
central west of the sub-basin (Figs 5 and 6)
The ages of all formations in the Savory Sub-basin are poorly constrained The only fossils
known are stromatolites and palynomorphs (acid-insoluble microfossils) Palynology from
available wells is summarized in Appendix 3 from Grey and Stevens (1997) and Grey and Cotter
(1996) and correlations using stromatolite biostratigraphy (Stevens and Grey 1997 Grey 1995f
Walter et al 1994 1995) are consistent with a Neoproterozoic age for the formations for which
data are available
A dolerite within the Boondawari Formation gave a poorly constrained RbndashSr age of about
640 Ma (Williams 1992) SHRIMP UndashPb dating of sedimentary zircons from the McFadden and
Cornelia Formations in stratigraphic drillhole Trainor 1 are discussed in Stevens and Adamides (in
prep) and Nelson (1997) The youngest ages from these analyses indicate that the maximum age
of the Cornelia Formation is Early Cambrian or Sturtian but these ages are inconsistent with
previous tectonic interpretations (Williams 1992) and current stratigraphic correlations which
suggest the Cornelia Formation is of Supersequence 1 age or older (Fig 4)
Depositional Sequence A Supersequence 1
Depositional Sequence A includes the Glass Spring Jilyili and Brassey Range Formations (Fig
3) All of these units are predominantly quartzose sandstones some of which are friable and have
significant visible porosity in outcrop Conglomerates are present in the Glass Spring and Jilyili
Formations
Depositional Sequence B Supersequence 1
Depositional Sequence B consists of the Watch Point Coondra Mundadjini Spearhole and
Skates Hills Formations (Fig 3) All of these formations contain beds of quartzose sandstone and
some also contain conglomerates The porosity of dolomites in the Skates Hills Formation appears
poor in surface exposures but its subsurface characteristics are unknown
12
50 km
120deg 121deg30 123deg
25deg
24deg
23deg
22deg
Greater Officer Basin
PNCEXP CA11PNCEXP CA12
PNCEXP CA13PNCEXP CA19
PNCEXP CA05
PNCEXP CA09
BD134589
GSWA Trainor 1 and TWB123
Fortescue River 1A
Mundadjini 1
Akubra 1Boondawari 1
TWB4TWB5
TWB6
TWB7
TWB8
TWB9
TWB10
BWB1
BWB2 BWB3
BWB4
BWB5
OD23
Mineral exploration drillhole
Stratigraphic drillhole
Waterbores and wells(TWB and BWB serieswaterbores identified)
MKS33270398
LDDH 1
Savory Sub-basin
Canning SR Well 13
EP380
Petroleum Exploration permit
Petroleum exploration well
Figure 5 Locations of petroleum exploration wells mineral exploration and stratigraphic drillholes water bores and wells and petroleum exploration permit EP380 in the Savory Sub-basin
13
TD=600m
TD=1367m
TD=701m
TD=709m
TD=50m
SS
1S
S1
SS1
SS
1S
S1
SS
1
SS
1
SS1
SS4 SS1
Pha
nero
zoic
or
SS
2
Cz
CzCz
Karst Bitumen
SS1
TD=181m
Mundadjini 1 Akubra 1 Boondawari 1 LDDH 1 Trainor 1 TWB 6
Munda-djini Fm
Spear-hole Fm
Munda-djini Fm
Munda-djini Fm
Spear-hole Fm
Spear-hole Fm
Waters Fm
McFadden Fm
Cornelia Fm
Cornelia Fm
Cornelia Fm
511 plusmn 13Maor 696 plusmn 20Ma(maximum)
779 plusmn 10Ma(maximum)
Mundadjini 1
Akubra 1 Boondawari 1
LDDH 1
Trainor 1TWB 6100 km
N
LOCATION
NW SE
Sea level
0m AHD
Dolerite basalt
Conglomerate
Sandstone
Mudstone
Dolomite
Limestone
Evaporite
TOC gt08
Permeability gt100md
Oil fluorescence
Sedimentary zircon U-Pb age
Identifiable polymorphs
Cainozoic
Supersequence 1 age
Unconformity
Formation contact
Cz
SS1
r
r
0
100
200
metres
VerticalScale
MKS36 120598
LEGEND
Figure 6 Geological cross section through significant drillholes in the Savory Sub-basin
14
Depositional Sequence C Supersequence 3
Depositional Sequence C consists of the Boondawari Formation (Fig 3) and although it contains
sandstone conglomerate and dolomite the sandstones contain significant amounts of feldspar and
clay and hence are likely to be poorer reservoirs than older sandstones
Depositional Sequence D Supersequence 4
Depositional Sequence D includes the McFadden Tchukardine and Woora Woora Formations
(Fig 3) The McFadden Formation is poorly sorted and sandstones contain significant amounts of
feldspathic clasts in the north of the basin but are significantly coarser and cleaner in the northeast
of the sub-basin (Williams 1992)
Sandstones of the Tchukardine and Woora Woora Formations are generally cleaner than those
of the McFadden Formation and are expected to have fair to good porosity although the
Tchukardine Formation has a higher clay content in parts
Depositional Sequence E Supersequence 4
Depositional Sequence E consists of the Durba Sandstone (Fig 3) a coarse sandstone with minor
conglomerate which has good to excellent visible porosity in surface exposures
Other depositional sequences and regional correlations
Sedimentary rocks which were not included in the Savory Group by Williams (1992) but which
are likely to be of Neoproterozoic age and hence part of the greater Officer Basin include the
Tarcunyah Group the Cornelia Formation and the Kahrban Subgroup
As discussed in the Introduction all of the strata in the Karara Basin and the younger strata
of the Yeneena Basin were redefined to form the Tarcunyah Group of the greater Officer Basin
(Bagas et al 1995) (Fig 7) In outcrop the Tarcunyah Group consists predominantly of quartzose
feldspathic and arkosic sandstone shale which is carbonaceous in parts and carbonate which
includes stromatolitic dolomite Mineral hole LDDH1 drilled on GUNANYA intersected the
15
120598
122deg
123deg
21deg
22deg
23deg
24deg
23deg
22deg
21deg
122deg
123deg
Fault
Thrust
Reverse thrust
CANNINGBASIN
OFFICERBASIN
GROUP
PILBARACRATON
TARCUNYAH
SAVORY GROUP
BANGEMALL
GROUP
THROSSELL
GROUP
LAMIL
GROUP
ConnaughtonTerrane
TerraneTalbot
complexTabletop granitic
Tabletop Terrane
Permian
Neoproterozoicgranitoid
50 km
FormationWaltha Woora
McKay Fault
South west Thrust
Vines
Fault
24deg
120deg
YENEENA CANNINGBASIN
ARUNTAINLIERRUDALL
COMPLEX
AMADEUSBASIN
MUSGRAVEBLOCK
OFFICERBASINYILGARN
CRATON
GROUP
GROUP
GROUP
PILBARACRATON
GROUP
EARAHEEDY
GLENGARRY
BANGEMALL
WYLOO GROUP
SAVORY
WA
CARNARVONBASIN
GASCOYNECOMPLEX
GROUPTARCUNYAH
400 kmGROUP
SA
N
T
CamelndashTabletopfault zone
KAHRBANSUBGROUP
CORNELIAFORMATION
MKS37
Figure 7 Regional geological setting of the Savory Group and western Officer Basin The dashed line on the inset map marks the interpreted margin of the greater Officer Basin
16
Tarcunyah Group and consists predominantly of mudstone with minor sandstone limestone
dolomite and anhydrite (Fig 6)
The age of the Tarcunyah Group is uncertain although limited palynological and stromatolite
evidence suggests that it is probably coeval with Supersequence 1 of the Centralian Superbasin
Drillhole LDDH1 contains palynomorphs equivalent to assemblages in the Browne and Bitter
Springs Formations of the Officer and Amadeus Basins respectively and from the Cornelia
Formation in TWB 6 (Grey and Stevens 1997) (Figs 4 and 6) Stromatolite specimens tentatively
assigned to Acaciella australica (Howchin 1914) Walter 1972 occur in the lower Tarcunyah
Group (Bagas et al 1995) The stromatolite Baicalia burra Preiss 1972 and a conical
stromatolite were reported from the upper part of the Tarcunyah Group (Stevens and Grey 1997)
The recognition of two stromatolite assemblages interpreted to have age significance in
Supersequence 1 sedimentary rocks of the Centralian Superbasin has permitted biostratigraphic
correlations between outcrop and well data The Acaciella australica assemblage appears to be
slightly older than 800 Ma and is restricted to the middle part of Supersequence 1 The Baicalia
burra assemblage is considered to be slightly younger than 800 Ma and occurs in the upper part
of Supersequence 1 (Grey 1996b Stevens and Grey 1997) The older A australica assemblage
is recognized in the Skates Hills Formation in the Savory Sub-basin and the stromatolite A
australica itself has been tentatively identified in the lower Tarcunyah Group The occurrence of
the A australica assemblage in the Woolnough Madley and Browne Formations of the Officer
Basin and in the Loves Creek Member of the Bitter Springs Formation of the Amadeus Basin
allows correlations throughout the Centralian Superbasin (Fig 4)
The younger B burra assemblage has not been recognized in sedimentary rocks of the
Savory Group as defined by Williams (1992) but it occurs in the upper parts of the Tarcunyah
Group and allows correlation of this group with outcrops of the Neale Formation and with the
Kanpa Formation in petroleum exploration well Hussar 1 both located in the central Officer Basin
of Western Australia (Fig 4) (Grey 1996b Stevens and Grey 1997) The occurrence of the B
burra assemblage in these units permits their correlation with the Burra Group in the Adelaide
Geosyncline of South Australia (K Grey unpublished data)
The Cornelia Formation and Kahrban Subgroup outcrop in the southeast of the sub-basin and
were considered by Williams (1992) to be part of the Mesoproterozoic Bangemall Basin Limited
evidence suggests that all or parts of these two units are of Neoproterozoic age The Ward and
Oldham Inliers consist of outcrops of the Cornelia Formation Waterbore TWB 6 which was
drilled on TRAINOR in the Cornelia Formation contains palynomorphs consistent with a
Supersequence 1 age (Grey and Stevens 1997) (Figs 5 and 6) In outcrop the Cornelia Formation
17
consists predominantly of sandstone and quartzite with lesser siltstone shale mudstone and chert
In Trainor 1 this formation consists predominantly of indurated mudstone with minor sandstone
chert and dolomite A major erosional unconformity separates the Cornelia Formation from
overlying formations and parts of the Cornelia Formation have been folded with dips exceeding
70deg In contrast the majority of the Savory Sub-basin sedimentary rocks have dips of less than 30deg
except where they are adjacent to faults The Cornelia Formation apparently consists of an older
unit of steeply dipping quartzites cherts and well-indurated mudstones and a younger unit of
shallower dipping sandstones which are sub-friable in parts However caution should be used in
interpreting the age of units based on their structural deformation and additional mapping and age
dating of this formation is required
It is proposed here that the Kahrban Subgroup is likely to be of early Neoproterozoic age and
hence should be considered as part of the greater Officer Basin This proposal is based largely on
the relatively low dip of the strata (generally less than 20deg) and their west-northwest strike which
is parallel with strikes in the overlying Brassey Range Formation of the Savory Group The lower
contact of the Kahrban Subgroup is obscured but is thought to be an unconfirmity on the
Earaheedy Basin on the southeast of STANLEY (Muhling and Brakel 1985)
Structural setting
The Savory Sub-basin forms the most northwesterly sub-basin of the Neoproterozoic to
Phanerozoic Officer Basin The western boundary of the sub-basin with the Mesoproterozoic
Bangemall Basin consists of steep-reverse and strike-slip faults The northeastern boundary of the
Savory Sub-basin was mapped where Supersequence 4 formations of the Savory Group
unconformably overlie sedimentary rocks of the Karara and Yeneena Basins with the two older
units considered to be part of the Paterson Orogen (Williams 1992) This contact was defined as a
series of steeply dipping reverse faults in the northernmost parts of the sub-basin on BALFOUR
DOWNS and RUDALL and was extrapolated as an inferred reverse fault farther along strike to the
southeast on GUNANYA and MADLEY where the contact is obscured by Cainozoic sediments It is
now recognized that all the sedimentary rocks in the Karara Basin and younger sedimentary rocks
of the Yeneena Basin are from the Supersequence 1 Tarcunyah Group and part of the greater
Officer Basin (Bagas et al 1995) The northern boundary of the Tarcunyah Group and the greater
Officer Basin is in thrust-and reverse-faulted contact with the Rudall Complex and other parts of
the Paterson Orogen (Fig 7)
To the south the sub-basin unconformably overlies the Bangemall Basin The eastern
boundary of the sub-basin used in this study is where Permian and younger strata of the Officer
Basin unconformably overlie Neoproterozoic strata although there are no significant structural or
stratigraphic differences between the Neoproterozoic units
18
The sub-basin is subdivided into three principal structural areas (Fig 1) Trainor Platform
Blake Fault and Fold Belt and Wells Foreland Sub-basin (Williams 1992) A major review of
these boundaries is beyond the scope of this report but the processing of regional aeromagnetic
data (Appendix 4) and acquisition of a semi-detailed gravity survey by the GSWA in the east of
the sub-basin has enabled these tectonic units to be reassessed and some modifications are
proposed
The Wells Foreland Sub-basin (originally termed the Wells Foreland Basin in Williams 1992)
and sedimentary rocks of the Tarcunyah Group are both considered to be the northwest
continuation of the Gibson Sub-basin of the Officer Basin Aeromagnetic gravity and outcrop
data suggest that the Blake Fault and Fold Belt is significantly faulted and folded in the west but
is less deformed in the east where the thickest sedimentary section in is located on BULLEN
(Appendix 4) The Trainor Platform is reinterpreted to represent an area of the sub-basin that has
undergone major compression during the Petermann Ranges Orogeny resulting in folding and
faulting with a northwest strike This interpretation contrasts with that proposed by Williams
(1992) who envisaged that only a thin section of the Savory Group was present on the platform
Perincek (1998) has recognized nine periods of tectonic activity in the Officer Basin from the
beginning of the Neoproterozoic to the end of the Cretaceous Three major tectonic episodes are
recognized in the Centralian Superbasin The oldest event is the Areyonga Movement which is
pre-Sturtian and forms the boundary between Supersequences 1 and 2 (Fig 4) The Souths Range
Movement occurred at the end of the Sturtian at the boundary between Supersequences 2 and 3
The youngest major event is the Petermann Ranges Orogeny which occured at the end of the
Marinoan and forms the boundary between Supersequences 3 and 4
One minor and two major tectonic episodes are recognized in the Savory Sub-basin the
LP1ALP1B structural event and the Areyonga Movement and the Petermann Ranges Orogeny
respectively The LP1ALP1B structural event is revealed where the Spearhole Formations rests
disconformably and locally unconformably on the Brassey Range Jilyili and Glass Spring
Formations The Neoproterozoic Areyonga Movement (equivalent to the Blake Movement of
Williams 1992) produced folds and faults with a general northeast strike in the western and
southern parts of the region The Souths Range Movement has not been recognized in the sub-
basin This may be due to the fact that no Sturtian glacial rocks have been identified and hence it
is possible that structures attributed to the Areyonga Movement could be the result of the Souths
Range Movement or a combination of the two movements
The major tectonic event recorded in the sub-basin is the latest Neoproterozoic to Cambrian
Petermann Ranges Orogeny (equivalent to the Paterson Orogeny) which produced large reverse
19
faults thrusts strike-slip faults and folds with a general northwest strike The McFadden
Formation and other Supersequence 4 strata are considered to be at least partially coeval with this
orogeny (Williams 1992) We also interpret the Durba Sandstone as having been deposited during
the later stages of the Petermann Ranges Orogeny as this unit mildly deformed with fold axes
parallel to the strike of other structures attributed to the Petermann Ranges Orogeny
Quantitative aeromagnetic interpretation of the Savory Sub-basin utilizing the 3D Euler
deconvolution method supported by wave-number filtering and image processing has provided
structural trends and depth to magnetic source within the sub-basin (Cowan 1995) Gravity data
are interpreted by Cowan (1995) as changes in both the density of the basement rocks andor
basement topography depending on local conditions Part of Cowanrsquos report is reproduced in
Appendix 4
Exploration history
The only petroleum exploration conducted in the sub-basin has been the recent drilling in the
western part of three diamond drillholes of which two have minor oil shows (Table 2) There has
been some mineral exploration the results of which are stored in the GSWA Western Australian
Mineral Exploration (WAMEX) database system Much of the mineral exploration was in the
southwest and west where the sub-basin is in contact with the Bangemall Basin and along the
northern margin of the sub-basin Many of these mineral exploration programs included
aeromagnetic surveys and surface geochemical sampling (Fig 8)
Hydrocarbon potential
The sub-basin contains a sedimentary succession up to 8 km thick which is generally gently
folded and faulted and apparently unmetamorphosed Limited drilling has shown that thick
mudstones are present in the sub-basin with some mudstones in Trainor 1 having high Total
Organic Carbon (TOC) values Outcrops of sub-friable sandstones in many of the formations
within the sub-basin suggests widespread reservoir potential Mudstone and inferred thick
evaporite sequences are likely to form seals Maturity data suggest that near-surface samples are
approximately at the base of the oil window and top of the gas window in parts of the north and
southeast of the sub-basin However parts of the southwest of the sub-basin and the mudstones in
Trainor 1 have very high levels of maturity Numerous faults and folds have been identified from
surface mapping suggesting good potential for large structural traps Minor oil shows in
20
Table 2 Neoproterozoic formations and hydrocarbon shows in diamond drillholes in the Savory Sub-basin
Drillhole AMG Core TD (m) Approx Formation Depth Formation Depth Formation Depth Shows (AGD84) start (m) GL (m) (m) (m) (m)
LDDH 1 431148E 112 701 350 Tarcunyah 68ndash701 ndash ndash bitumen at 6623 m 7443826N Group Trainor 1 473640E 6 709 455 McFadden 9ndash83 Cornelia Fm 83ndash709 possible bitumen at 4537 m 7287400N Fm Mundadjini 1 319056E 170 600 500 Mundadjini 16ndash361 Spearhole Fm 361ndash600 10 fluorescence at 36102 m 7404844N Fm Boondawari 1 348959E 299 1 367 490 Mundadjini Fm 15ndash312 Spearhole Fm 312ndash1 283 Intrusive 1 283ndash1 367 40 fluorescence at 35364 m 5 7398174N fluorescence at 4963 m Akubra 1 334249E 15 181 530 Mundadjini 15ndash42 Intrusive 42ndash181 None 7401252N Fm
21
50 km
120deg 121deg30 123deg
25deg
24deg
23deg
22deg
Greater Officer Basin
Savory Sub-basin
1
2
3
4
6
8
3 Seismic line (prefixed N83-00)
Aeromagnetic survey
GS
WA
Sav
ory
1995
gra
vity
sur
vey
Gravity survey
MKS34270398
Figure 8 Locations of aeromagnetic and gravity surveys (other than regional BMRAGSO data)
22
sandstones in two petroleum wells in the northwest of the sub-basin and bitumen and oil shows
elsewhere in the region indicate that oil has been generated and migrated through the sub-basin
Source rocks
Source potential is considered to be the major exploration risk in the Savory Sub-basin although
minor oil shows in Mundadjini 1 and Boondawari 1 indicate that at least some oil has been
generated and migrated into potential reservoirs within the sub-basin Sandstone is the
predominant lithology observed in outcrop Outcrops of fine-grained lithologies in the basin are
rare because of intense surface weathering and erosion Only about 8 of the surface area of the
sub-basin is exposed bedrock and recessive lithologies (such as shale evaporite and friable
sandstone) may be present although they rarely outcrop
Outcrops of stromatolitic dolomite with associated cauliflower chert and cubic pseudomorphs
interpreted as being after halite indicate that evaporitic environments are present within the
Mundadjini Skates Hills and Boondawari Formations Evaporitic minerals are also present in
drillhole LDDH1 in the Tarcunyah Group
In 1995 GSWA drilled a continuous-core diamond drillhole (Trainor 1) in the sub-basin on
TRAINOR to a depth of 709 m to test for source rocks thus providing the first such data for the sub-
basin The drillhole intersected flat-lying clastics and carbonates of the McFadden Formation (9ndash
83 m) overlying indurated mudstones of the Cornelia Formation (83ndash709 m total depth) dipping at
about 40deg Of the six samples analysed from the Cornelia Formation in this drillhole the five
located between 375 and 6032 m depth have TOC values exceeding 05 (range 066ndash365)
Rock-Eval pyrolysis of these five samples indicates that they are at best in the dry-gas thermal
stage and as a result of their high level of maturation (Stevens and Adamides in prep) have poor
remaining hydrocarbon-generating potential Although the Cornelia Formation is overmature at
Trainor 1 the high TOC values are encouraging as it is likely that this sequence is less mature
elsewhere in the sub-basin
The Mundadjini Formation contains potential source rocks that comprise marine mudstones
with evaporitic minerals present in parts Thin dark mudstones were intersected in the Mundadjini
Formation in Akubra 1 In Mundadjini 1 and Boondawari 1 however the mudstones appear to be
too oxidized to have source potential
The Boondawari Formation also may be a source rock as it contains black mudstones The
unit is laterally equivalent to the Pertatataka Formation of the Amadeus Basin and the Ungoolya
23
Group of the Officer Basin in South Australia both of which have some source potential
(Summons and Powell 1991 Morton and Drexel 1997) Samples from the Dey Dey Mudstone of
the Ungoolya Group generally have poor TOC values (average 011 range 003ndash081)
moderate hydrogen index (HI) values (100ndash382) and poor to fair genetic potential with a
maximum of 292 kg hydrocarbon per tonne of source rock (Morton and Drexel 1997)
Stromatolitic dolomites and mudstones at the top of the Boondawari Formation and within the
Skates Hills Formation are potential source rocks Stromatolitic dolomite and evaporitic rocks
deposited in a marginal marine to sabkha environment are considered to have good potential to
generate and preserve organic carbon without requiring a deep-water setting (Stevens and Grey
1997) Such conditions are recognized in the Skates Hills Formation and in the upper parts of the
Tarcunyah Group
Maturity
Knowledge of the maturity of sedimentary rocks within the Savory Sub-basin is still limited From
a review of palynological studies Grey and Stevens (1997) report that the thermal maturity
inferred from the Thermal Alteration Index (TAI) of 3+ from Supersequence 1 age palynomorphs
in TWB 6 TWB 9 and LDDH1 is within the hydrocarbon window (Appendix 3) In Phanerozoic
spores and pollen a TAI of 3+ approximately equates to the end of liquid petroleum generation
and the start of dry gas generation and to a vitrinite reflectance of about 13 (Traverse 1988)
However the use of TAI for estimating thermal maturity from Neoproterozoic palynomorphs
requires calibration
In Trainor 1 the Cornelia Formation contains organically rich claystones between 375 and
6032 m depth Based on Rock-Eval maturity data (Stevens and Adamides in prep) and the dark
colour of poorly preserved organic material (Grey 1995de 1996) with TAI 4- to 5 all samples
had a high level of maturation with at best dry-gas generating potential remaining In contrast
drillhole LDDH1 on GUNANYA recorded lower levels of maturity (TAI values of 3+) with two of
sixteen samples from the Tarcunyah Group having greater than 1 TOC (Grey 1995abc Grey
and Cotter 1996) Organic petrology and Rock-Eval maturity data for samples from LDDH1
indicate that the section above 500 m is within the oil-generative window whereas below 500 m
the rocks are within the gas window (Ghori in prep Fig 9 Appendix 5)
Waterbores TWB 1 2 6 and 9 which are located on TRAINOR in the southeast of the sub-
basin all had organic matter with TAI values of 3+ from the McFadden Skates Hills Cornelia
and Brassey Range Formations respectively
24
100
200
300
400
500
600
700
Oil
gene
ratin
g
Gas
gene
ratin
g
Fai
r
Fai
r
Poo
r
Poo
r
Goo
d
Imm
atur
e
Oil
win
dow
Oil
win
dow
Imm
atur
e
01 0110 10 0 150 300 440 480 1
Neo
prot
eroz
oic
TOC S1+S2 mgg Hydrogen Index Tmax degC
Depth(m)
Organicrichness
Generatingpotential
Kerogentype Maturity Maturity
TD=701m
Sandstone
Mudstone
Dolomite
Limestone
Evaporite
Source rock
MKS40 070498
Ro equivalent
Figure 9 Petroleum source potential of rocks in Normandy LDDH1
Small amounts of organic matter associated with basalt and dolerite in cuttings from
waterbore BWB 1 on BULLEN showed high levels of thermal maturity (Grey 1995a Libby 1995)
It is unclear whether all sedimentary rocks on BULLEN are overmature for hydrocarbon generation
or the results from BWB 1 are related to local heating events associated with the volcanic bodies
that are common in the Jilyili Formation
25
Reservoirs
Each of the five depositional sequences of the Savory Group (Table 1) are inferred to contain
significant sandstone reservoirs with the possible exception of depositional sequence C as
discussed above in Stratigraphy The Spearhole Formation was cored in Mundadjini 1 and
Boondawari 1 and visual estimates of porosity vary from generally poor (less than 5) to fair
(approximately 5ndash15) The McFadden Formation in Trainor 1 has porosity values of up to 232
and a maximum permeability of 195 md (Stevens and Adamides in prep) Sandstones from
Neoproterozoic formations form the acquifers in the following waterbores the McFadden
Formation in TWB 1 the Cornelia Formation in TWB 6 and the Brassey Range Formation in
TWB 8 and TWB 9 (Appendix 6 Table 61)
Based on outcrop observations the Durba Sandstone is considered to be the best reservoir of
the Savory Group Similarly some sandstones from the Tarcunyah Group also have good visible
porosity in outcrop
Dolomites occur in several formations in the sub-basin Reservoir potential may exist
particularly where the dolomites are stromatolitic and oolitic However dolomites have not been
drilled in the sub-basin and porosity can only be inferred from the preferential silicification of
some stromatolite bioherms observed in outcrop (Stevens and Grey 1997) Elsewhere in the
Officer Basin porosities of up to10 have been measured in dolomites A limestone breccia
(karst) is described from 663 to 677 m in drillhole LDDH1 (Fig 6 Busbridge 1994)
Seals
Indications of evaporitic environments in the Mundadjini Skates Hills and Boondawari
Formations are described by Williams (1992) In Mundadjini 1 from 287 to 337 m anhydrite and
chert occurs as nodules beds and veins in mudstone of the Mundadjini Formation Evaporitic
minerals (predominantly gypsum) are described in the Tarcunyah Group in LDDH1 The presence
of the Woolnough and Madley salt diapirs in the Officer Basin (approximately 110 km east of the
sub-basin) and halite beds over 25 m thick in the well Hussar 1 (130 km east of the sub-basin)
provide further evidence that evaporite seals may be present in the Savory Sub-basin
Mudstones and shales form only a small proportion of the limited Neoproterozoic outcrop in
the sub-basin but significant thicknesses of mudstone were encountered in the Mundadjini
Formation in Mundadjini 1 and Boondawari 1 the Tarcunyah Group in LDDH1 and in the
26
Cornelia Formation in Trainor 1 These data suggest that mudstones form a significant proportion
of strata in the sub-basin despite their limited outcrop
Traps
Potential structural closures including folds and faults occur at various scales throughout the
Savory Sub-basin However the region has only been mapped at 1250 000 scale and
independently closed structures such as domes have yet to be confirmed The western margin of
the basin contains abundant faults (with a northeast strike) but elsewhere faults are less common
Some anticlines are recognized in outcrop including one with a strike length of up to 45 km
inferred from surface bedding dips in the Mundadjini and Spearhole Formations at approximately
24deg15rsquoS 121deg10rsquoE on BULLEN (Fig 1)
Salt diapirs and other halokinetic structures are recognized in outcrop well and seismic data
in the Officer Basin to the west of the Savory Sub-basin and it is probable that there are
significant thicknesses of evaporitic sedimentary rocks in the sub-basin The gravity field data
suggest there is good potential for salt diapirs and traps related to halokinesis
Although there is potential for stratigraphic traps to be present in the sub-basin insufficient
data are available to assess them
Preservation of hydrocarbons
The range of thermal maturities measured to date and the large periods of time envisaged for
deposition of sediments implies hydrocarbon generation may have occurred a number of times
during the evolution of the Savory Sub-basin Any hydrocarbons that were generated early may
have been trapped in palaeostructures and remigration to younger traps could have taken place
later The Petermann Ranges Orogeny which has been equated with the Paterson Orogeny (Myers
1990) is believed to have occurred in the latest Neoproterozoic to early Cambrian This is the last
major tectonic event recognized in the sub-basin suggesting that it is reasonable to expect that trap
integrity will have been preserved
If the inference of the presence of thick halite beds in the sub-basin is correct the preservation
potential of sub-salt traps should be excellent
27
Reported hydrocarbon shows and oil seep
Amadeus Petroleum recorded minor oil shows in cores from Mundadjini 1 and Boondawari 1 In
Mundadjini 1 at 36102 m (top of the Spearhole Formation) a 3 mm thick zone had 10 moderate
white fluorescence with slow solvent cut This show was in a granular sandstone with visually
estimated porosity of about 10 In Boondawari 1 at 35364 m (within the Spearhole Formation) a
broken surface of sandstone had 40 moderate yellow-white fluorescence with slow solvent cut
Visually estimated porosity is about 5 Because the fluorescing surface was broken during the
drilling process this show could have resulted from contamination A second show occurs in
Boondawari 1 at 4963 m (within the Spearhole Formation) where a 1 cm-thick zone had 5 dull
yellow fluorescence with slow solvent cut in a conglomerate with visually estimated porosity of
about 10 The company intends to further investigate the nature of these occurrences
Minor bitumen is present at 6623 m in drillhole LDDH1 on GUNANYA (Figs 5 and 6) as a
vein in mudstones of the Tarcunyah Group A sample was analysed by gas chromatography
(Ghori in prep) and confirmed that it is natural bitumen (Appendix 5)
Mineral hole OD 23 drilled by Jubilee Gold Mines NL on NABBERU in the Bangemall Basin
immediately to the south of the Savory Sub-basin (Fig 5) encountered bitumen and trace oil in
vugs in dolomite (M Stevens unpublished data) but no further data are available at present
In their popular guide to the Canning Stock Route Gard and Gard (1990 p 218) refer to an
oil seep at Well 13 on TRAINOR (Fig 5) They reported that between 1977 and 1984 lsquonatural oilrsquo
was seen in the well Although the well is now largely filled with sediment four auger drill
samples were collected by the GSWA in 1995 and all four were analysed for oil shows One
sample from 315 m total depth (GSWA sample 135604) yielded just enough extract (519 ppm)
for saturate gas chromatography analysis The gas chromatograph (Appendix 5) shows that the
extract does contain some hydrocarbons probably from recent plant material Because the depth to
the oil was not quoted in Gard and Gard (1990) the hand-augered well may not have been deep
enough to properly test this reported seep
Geological and geophysical databases
Geological and geophysical data available for the Savory Sub-basin are limited The most recently
completed geological maps for the sub-basin were published by the GSWA between 1991 and
1995 (Williams and Tyler 1991 Williams 1992 1995ab)
28
The cores from the five drillholes listed in Table 2 believed to be all of the core available
from the sub-basin are available for inspection at GSWA Mineral exploration reports submitted
to GSWA may be searched using the WAMEX database and open-file reports are available on
microfiche Geophysical data acquired by the mining industry is not required to be filed with
GSWA if acquired over Vacant Crown Land which is the case for much of the sub-basin
Geophysical survey data submitted in mining tenement reports and which extend into Vacant
Crown Land remain confidential to the companies Original regional aeromagnetic and gravity
datasets are available from the Australian Geological Survey Organisation (AGSO)
Data pertinent to oil exploration in the sub-basin such as structural style and salt diapirism
are presented in a review of the hydrocarbon prospectivity of the Officer Basin (Perincek 1998)
Drilling
Significant drillholes in the sub-basin are summarized in Table 2
Petroleum industry data
Amadeus Petroleum drilled three petroleum exploration wells in the central west of the Savory
Sub-basin in late 1997 These wells Mundadjini 1 Boondawari 1 and Akubra 1 were drilled by
continuous diamond coring (Figs 5 and 6) All targeted potential reservoirs within the Spearhole
Formation with the Mundadjini Formation as the proposed seal The wells were located on
structures interpreted from Landsat images and limited geological investigations Both Mundadjini
1 and Boondawari 1 had minor oil shows as discussed above (Reported hydrocarbon shows)
Government data
Stratigraphic drillhole Trainor 1 was drilled by GSWA in 1995 (Stevens and Adamides in prep)
and the main results are discussed above (Source rocks and Maturity)
Mineral industry data
Normandy Exploration drillhole LDDH1 was cored in the Tarcunyah Group to a total depth of
701 m and provided source-rock and maturity data as discussed above
29
Oilmin NL drilled six percussion drillholes (BD 1 3 4 5 8 and 9) through sandstones and
shales in the northern part of the Savory Sub-basin to a maximum depth of 198 m (Fig 5
WAMEX Microfiche File M 26811 I 2610) but only brief geological descriptions are available
Hydrogeological data
Hydrogeological data within the Savory Sub-basin are limited although a long history of water
exploration extends back to the construction of the Canning Stock Route early this century No
detailed geological or wireline logs are available for the older wells along this route A few station
wells have been drilled by various methods on the south and west margins of the basin but data
are unavailable as reports are not required to be filed with the government Depth to watertable
throughout the basin is largely controlled by porosity of the bedrock
The GSWA drilled fifteen waterbores in the winter of 1995 in the southern part of the sub-
basin in preparation for the drilling of Trainor 1 and the proposed Bullen 1 Twelve bores found
water and six of these bores have salinities of less than 1000 mgL (Fig 5 Appendix 6 Table 61)
One waterbore TWB 6 has gamma ray and neutron logs run through PVC casing and these are
available from the GSWA with the digital log data included herein
Seismic data
No geophysical data have been acquired by the petroleum industry in the Savory Sub-basin
Seismic data acquired in the Officer Basin to the east particularly in the Gibson and Yowalga
Sub-basins is pertinent to structural interpretation in the Savory Sub-basin (Perincek 1996a
1998)
Aeromagnetic surveys
Government data
There are over 95 277 line kilometres of aeromagnetic data included in the AGSO dataset There
are three regional aeromagnetic surveys covering the Savory Sub-basin These were flown by the
Bureau of Mineral Resources (BMR now AGSO) in 1984 at a line spacing of 1500 m with 36 740
and 52 587 line kilometres flown and by Aerodata in 1984 at a line spacing of 1000m with 5950
line kilometres flown These data were reprocessed and interpreted for GSWA by Cowan (1995)
An edited copy of this report is included as Appendix 4 and the original report is filed in the
GSWA Library under S-series reports item 10331
30
Mineral industry data
The approximate locations of non-AGSO aeromagnetic surveys are shown in Figure 8 More
detailed information regarding the location of these surveys may be obtained using the GSWA
MAGCAT II database Additional information such as contours of aeromagnetic values may be
obtained by inspecting items on file with the GSWA
Gravity surveys
Government data
The average spacing for gravity data in the Savory Sub-basin is one station per 121 km2 (11 times 11
km grid) These data were principally collected by BMR in the early 1960s There are a few
additional regional gravity traverses across the sub-basin which are also included in the
BMRAGSO dataset These data were reprocessed and interpreted for GSWA (Fig 10) and a
report on this work is also included in Appendix 4
The GSWA completed a large semi-detailed gravity survey in the eastern Savory Sub-basin
utilizing helicopter support and Differential Global Positioning Survey (DGPS) techniques (Fig
8) This gravity survey completed in August 1995 consists of 2300 gravity stations on a 2 times 3 km
grid All stations were acquired by helicopter using Scintrex gravimeters and Ashtek dual
frequency DGPS equipment for determining location This highly efficient system allowed the
acquisition of more than 100 gravity stations per day in remote areas The resolution of this survey
is +30 cm and +05 microms-2 (Daishsat 1995) These data (Fig 11) represent a significant
improvement on the previous regional survey data and are available from GSWA (GSWA
1996ab) The results of the interpretation of these data were presented at the 1997 ASEG
Convention (Carlsen and Shevchenko 1997)
Mineral industry data
Three small gravity surveys were conducted by Oilmin NL (Fig 8) and the relevant WAMEX
reports are M 2681I 2610 I 2435 I 2567 These three surveys are of limited value because height
control was provided by barometers only and the surveys were not tied to the national gravity grid
31
23deg
25deg
120deg 122deg
Trainor 1
SAVORY
SUB-BASIN
MKS54 160498
100 km
1995 SavoryGravity Survey
254
-1056
micromsec2
Figure 10 Regional Bouguer gravity map of the Savory Sub-basin
23deg
24deg
25deg
122deg30 123deg
TRAINOR 1
123deg30
50 km
MKS53 160498
-116
-626
micro msec2
Figure11 Detailed Bouguer gravity map of the
Savory 1995 Gravity Survey from the eastern Savory Sub-basin
32
Government and academic reports
Chronostratigraphy and geochemistry
The understanding of Neoproterozoic organic chemistry palynology and structural evolution is
essential to the interpretation of hydrocarbon prospectivity Pertinent reports are included in the
bibliography (Appendix 1) Unpublished palaeontology reports describe the palynology of wells in
the Savory Sub-basin (Grey 1995andashe 1996a) Grey and Cotter (1996) discussed the potential for
Neoproterozoic palynomorphs to provide a biostratigraphic framework and palaeoenvironmental
interpretation Grey and Stevens (1997) reviewed the results of palynological studies of wells
drilled in the sub-basin and reported that Supersequence 1 palynomorphs are present in TWB 6
TWB 9 and LDDH1 (Appendix 3) Grey (1996b) reported on the use of stromatolites for
correlation in the Neoproterozoic and Stevens and Grey (1997) discussed the application of
stromatolite biostratigraphy in correlating isolated dolomite outcrops in the sub-basin with well
and seismic data in the Officer Basin and Centralian Superbasin
Although geochemical data from the Savory Sub-basin are very limited results mostly
confirm thermal maturities inferred from TAI for LDDH1 and Trainor 1 (Ghori in prep Stevens
and Adamides in prep) Those parts of the Officer Basin in Western Australia which lie to the
east of the Savory Sub-basin are sparsely drilled but Ghori (in prep) reports that most of the
Neoproterozoic succession presently lies within the oil-generative window However his study
has been unable to identify effective source-rock units and the source for oil shows Thin source
rocks are present in the Neoproterozoic in LDDH1 (Fig 9) and in three wells which lie to the east
and southeast of the Savory Sub-basin namely NJD 1 Kanpa 1A and Yowalga 3
Proposed work program
From the above limited information it is concluded that additional research on the hydrocarbon
potential of the sub-basin is justified and proposals are outlined below
bull Additional modelling of gravity and aeromagnetic data from the Savory Sub-basin is required
in light of the results from Trainor 1 and Boondawari 1 Trainor 1 showed that what appeared
to be a structurally simple area based on outcrop aeromagnetic and gravity data was in fact an
area of major structuring Boondawari 1 intersected a dolerite which is in good depth
agreement with aeromagnetic depth to source results showing this technique is useful in
detecting the depth to intrusive bodies
33
bull Additional data from mineral and petroleum exploration bores may become available and
analysis of samples from these wells should be undertaken and interpreted in the context of
their relevance to the Officer Basin
bull Stratigraphic coring in the Blake Fault and Fold Belt and in the Wells Foreland Sub-basin (Fig
1) targeting source rocks is considered essential to the continuing evaluation of the
hydrocarbon prospectivity of the Savory Sub-basin
bull Correlations using at least outcrop well and potential-field data should be prepared to link the
sub-basin with the better known parts of the Officer Basin to the east
bull Remapping is required to clarify boundary positions within the Cornelia Formation this may
resolve some of the current problems of the relationship between this unit and the rest of the
Savory Sub-basin
bull Further work is required to explain the Early Cambrian or Sturtian ages interpreted for the
Cornelia Formation from sedimentary zircon UndashPb dating in drillhole Trainor 1 The
determination of the age of the organically rich but overmature claystones in this well is
critical to assessing the hydrocarbon potential of the region
bull The thin dark mudstones intersected by Akubra 1 in the Mundadjini Formation warrant
geochemical analysis Analyses of the oil shows in Mundadjini 1 and Boondawari 1 are
currently being undertaken by Amadeus Petroleum
bull Geochemical analysis of hydrocarbons in the Bangemall Basin drillhole OD23 has been
performed by Jubilee Gold and the results will be reviewed when they are submitted to
GSWA The possibility of source rocks within the Bangemall Basin charging traps within the
Bangemall Basin and the overlying Savory Sub-basin requires further investigation
Conclusions
The Savory Sub-basin is a frontier region with only three recently drilled petroleum exploration
wells and no seismic data Based on existing geological and geophysical data it is considered too
early to draw conclusions about the hydrocarbon prospectivity of the sub-basin at this stage and
there are several reasons why the area warrants further investigation
34
1 Thick accumulations of sedimentary rocks are present (up to 8 km thickness inferred) which
may contain source reservoir and sealing strata
2 Minor oil shows occur in Mundadjini 1 and Boondawari 1 and bitumen is present in mineral
exploration drillhole LDDH1 suggesting that hydrocarbons have migrated within the
Neoproterozoic sequence of the Savory Sub-basin Oil and bitumen are present in mineral
exploration drillhole OD23 in the Bangemall Basin immediately to the south of the Savory
Sub-basin and it is possible that source rocks from the Bangemall Basin could charge traps in
the overlying Savory Sub-basin
3 The age of sedimentary rocks in the sub-basin is still poorly constrained but some of the
Neoproterozoic sedimentary rocks located on GUNANYA and TRAINOR are within the
hydrocarbon-generation window It is possible that a significant thickness of Phanerozoic
sedimentary rocks may also be present
4 Friable sandstones with visible porosity outcrop extensively suggesting numerous potential
reservoirs
5 Significant but not intense faulting and folding has been mapped implying large structural
traps may be present
6 Evaporitic sedimentary rocks occur in several formations and may provide good source rocks
and excellent seals
35
References
APAK S N and CARLSEN G M 1997 A compilation and review of data pertaining to the
hydrocarbon prospectivity of the Canning Basin Western Australia Geological Survey
Record 199610 103p
BAGAS L GREY K and WILLIAMS I R 1995 Reappraisal of the Paterson Orogen and
Savory Basin Western Australia Geological Survey Annual Review 1994ndash95 p 55ndash63
BUSBRIDGE M 1994 Lake Disappointment Exploration Licence 451064 Third Annual
Report Lake Disappointment Diamond Drill Hole LDDH1 Normandy Exploration Limited
Western Australia Geological Survey M-series Item 7567 A41358 (unpublished)
CARLSEN G M and SHEVCHENKO S I 1997 Petroleum exploration in Proterozoic basins
using potential fields data and stratigraphic coring Australian Society of Exploration
Geophysicists 12th Geophysical Conference Handbook Sydney 1997 Preview no 66 p 83
(abstract only)
COWAN D 1995 Savory Basin quantitative magnetic interpretation Western Australia
Geological Survey S-series S10331 (unpublished)
DAISHSAT PTY LTD 1995 Operational and processing report Savory Basin gravity survey
Western Australia Geological Survey S-series S10332 (unpublished)
GARD E and GARD R 1990 Canning Stock Route a travellerrsquos guide for a journey through
history Perth Western Australia Western Desert Guides 448p
GEOLOGICAL SURVEY OF WESTERN AUSTRALIA 1996a Savory Basin first vertical
derivative of Bouguer gravity image 1250 000 Western Australia Geological Survey
GEOLOGICAL SURVEY OF WESTERN AUSTRALIA 1996b Savory Basin Bouguer gravity
image 1250 000 Western Australia Geological Survey
GHORI K A R in prep Petroleum source rock potential and thermal history Officer Basin
Western Australia Western Australia Geological Survey Record
36
GREY K 1995a Savory Basin drillhole BWB 1 (Bullen waterbore) palynology and thermal
maturation GSWA Palaeontology Report no 199512 (unpublished)
GREY K 1995b Savory Basin drillholes TWB 1 2 6 9 (Trainor waterbores) palynology and
thermal maturation GSWA Palaeontology Report no 199520 (unpublished)
GREY K 1995c Palynology of Normandy-Poseidon Lake Disappointment-1 corehole
Tarcunyah Group Paterson Orogen GSWA Palaeontology Report no 199521 (unpublished)
GREY K 1995d Savory Basin drillhole Trainor 1 (Trainor diamond drilling) palynology and
thermal maturity GSWA Palaeontology Report no 199524 (unpublished)
GREY K 1995e Savory Basin drillhole Trainor 1 (Trainor diamond drilling) Additional
Preparation of two samples GSWA Palaeontology Report no 199528 (unpublished)
GREY K 1995f Neoproterozoic stromatolites from the Skates Hills Formation Savory Basin
Western Australia and a review of the distribution of Acaciella australica Australian Journal
of Earth Sciences v 42 p 123ndash132
GREY K 1996a Savory Basin drillhole Trainor 1 (Trainor diamond drilling) Additional
samples palynology and thermal maturation GSWA Palaeontology Report no 199615
(unpublished)
GREY K 1996b Preliminary stromatolite correlations for the Neoproterozoic of the Officer
Basin and a review of Australia-wide correlations GSWA Palaeontology Report no 199615
(unpublished)
GREY K and COTTER K L 1996 Palynology in the search for Proterozoic hydrocarbons
Western Australia Geological Survey Annual Review for 1995ndash96 p 70ndash80
GREY K and STEVENS M K 1997 Neoproterozoic palynomorphs of the Savory Sub-basin
Western Australia and their relevance to petroleum exploration Western Australia
Geological Survey Annual Review for 1996ndash97 p 49ndash54
HUBBARD R J PAPE J and ROBERTS D G 1985 Depositional sequence mapping as a
technique to establish tectonic and stratigraphic framework and evaluate hydrocarbon
potential on a passive continental margin in Seismic stratigraphy II an integrated approach
37
edited by O R BERG and D G WOOLVERTON American Association of Petroleum
Geologists Memoir 39 p 79ndash91
LIBBY WG 1995 A petrological report on six samples of bore cuttings from the Savory Basin
Western Australia Western Australia Geological Survey S-series S31307 (unpublished)
MORTON JGG and DREXEL JF 1997 The petroleum geology of South Australia Vol 3
Officer Basin South Australia Department of Mines and Energy Resources Report Book
9719
MUHLING P C and BRAKEL A T 1985 Geology of the Bangemall Group mdash the evolution
of an intracratonic Proterozoic basin Western Australia Geological Survey Bulletin 128
219p
MYERS J S 1990 Precambrian tectonic evolution of part of Gondwana southwestern Australia
Geology v18 p 537ndash540
NELSON D R 1997 Compilation of SHRIMP UndashPb zircon data Western Australia Geological
Survey Record 19972 196p
PAYTON C E 1977 Seismic stratigraphy mdash applications to hydrocarbon exploration
American Association of Petroleum Geologists Memoir 26 516p
PERINCEK D 1996a The age of NeoproterozoicndashPalaeozoic sediments within the Officer Basin
of the Centralian Super-basin can be constrained by major sequence-bounding unconformities
APPEA Journal v 36 pt 1 p 350ndash368
PERINCEK D 1996b The stratigraphic and structural development of the Officer Basin
Western Australia a review Western Australia Geological Survey Annual Review 1995ndash
1996 p 135ndash148
PERINCEK D 1998 A compilation and review of data pertaining to the hydrocarbon
prospectivity of the Officer Basin Western Australia Geological Survey Record 19976
POSAMENTIER H W JERSEY M T and VAIL P R 1988 Eustatic controls on clastic
deposition 1 mdash Conceptual framework in Sea-level changes an integrated approach edited by
C K WILGUS B S HASTINGS C G St C KENDALL H W POSAMENTIER
38
C A ROSS and J C VAN WAGONER Society of Economic Paleontologists and
Mineralogists Special Publication no 42
STEVENS M K and ADAMIDES N G in prep GSWA Trainor 1 well completion report
Savory Sub-basin Officer Basin Western Australia with notes on petroleum and mineral
potential Western Australia Geological Survey Record 199612
STEVENS M K and GREY K 1997 Skates Hills Formation and Tarcunyah Group Officer
Basin mdash carbonate cycles stratigraphic position and hydrocarbon prospectivity Western
Australia Geological Survey Annual Review for 1996ndash97 p 55ndash60
SUMMONS RE and POWELL C McA 1991 Petroleum source rocks of the Amadeus Basin
in Geological and geophysical studies in the Amadeus Basin central Australia edited by R J
KORSCH and JM KENNARD Australia BMR Geology and Geophysics Bulletin 236
TRAVERSE A 1988 Palaeopalynology Boston Unwin Hyman 600p
VAIL P R MITCHUM R M Jr TODD R G WIDMIER J M THOMPSON S III
SANGREE J B BUBB J N and HATLELID W G 1977 Seismic stratigraphy and
global changes of sea level in Seismic stratigraphy mdash applications to hydrocarbon
exploration edited by C E PAYTON American Association of Petroleum Geologists
Memoir 26 516p
WALTER M R and GORTER J 1994 The Neoproterozoic Centralian Superbasin in Western
Australia the Savory and Officer Basins in The sedimentary basins of Western Australia
edited by P G PURCELL and R R PURCELL Petroleum Exploration Society of Australia
Symposium Perth WA 1994 Proceedings p851ndash864
WALTER M R GREY K WILLIAMS I R and CALVER C R 1994 Stratigraphy of the
Neoproterozoic to early Palaeozoic Savory Basin and correlation with the Amadeus and
Officer Basins Australian Journal of Earth Sciences v 41 p 533ndash546
WALTER M R VEEVERS J J CALVER C R and GREY K 1995 Neoproterozoic
stratigraphy of the Centralian Superbasin Australia Precambrian Research v 73 p 173ndash195
WILLIAMS I R 1992 Geology of the Savory Basin Western Australia Western Australia
Geological Survey Bulletin 141 115p
39
WILLIAMS I R 1995a Bullen WA (2nd Edition) Western Australia Geological Survey
1250 000 Geological Series Explanatory Notes 23p
WILLIAMS I R 1995b Trainor WA (2nd Edition) Western Australia Geological Survey
1250 000 Geological Series Explanatory Notes 31p
WILLIAMS I R and TYLER I M 1991 Robertson WA (2nd edition) Western Australia
Geological Survey 1250 000 Geological Series Explanatory Notes 36p
40
41
Appendix 1
Bibliography
Reports which are relevant to this investigation but which are not specifically cited are listed
below
BAILLIE P W POWELL C McA LI Z X and RYALL A M 1994 The tectonic
framework of Western Australiarsquos Neoproterozoic to recent sedimentary basins in The
sedimentary basins of Western Australia edited by P G PURCELL and R R PURCELL
Petroleum Exploration Society of Australia Symposium Perth WA 1994 Proceedings p
45ndash62
BRADSHAW M T BRADSHAW J MURRAY A P NEEDHAM D J SPENCER L
SUMMONS R E WILMOT J and WINN S 1994 Petroleum systems in West Australian
basins in The sedimentary basins of Western Australia edited by P G PURCELL and R R
PURCELL Petroleum Exploration Society of Australia Symposium Perth WA 1994
Proceedings p 93ndash118
CLARKE G L 1991 Proterozoic tectonic reworking in the Rudall Complex Western Australia
Australian Journal of Earth Science v38 p 31ndash44
COCKBAIN A E and HOCKING R M 1990 Phanerozoic in Geology and mineral resources
of Western Australia Western Australia Geological Survey Memoir 3 p 750ndash755
ETHERIDGE M and WALL V 1994 Tectonic and structural evolution of the Australian
Proterozoic 12th Australian Geological Convention Geological Society of Australia
Abstracts no 37 p 102ndash103
GOODE A D T 1981 Proterozoic geology of Western Australia in Precambrian of the
Southern Hemisphere Developments in Precambrian geology 2 edited by I R HUNTER
Amsterdam Elsevier p 105ndash203
GREY K and JACKSON M J 1983 A re-assessment of stromatolite evidence for the
correlation of the Late Proterozoic Neale and Ilma Beds Officer Basin Western Australia
Australia BMR Journal of Australian Geology and Geophysics v 8 p 359
42
HICKMAN A H WILLIAMS I R and BAGAS L 1994 Proterozoic geology and
mineralization of the TelferndashRudall region Paterson Orogen Geological Society of Australia
(WA Division) Excursion Guidebook no 5 56p
HOCKING R M MORY A J and WILLIAMS I R 1994 An atlas of Neoproterozoic and
Phanerozoic basins of Western Australia in The sedimentary basins of Western Australia
edited by P G PURCELL and R R PURCELL Petroleum Exploration Society of Australia
Symposium Perth WA 1994 Proceedings p 21ndash 44
JACKSON P R 1966 Geology and review of exploration Officer Basin Western Australia
Hunt Oil Company Western Australia Geological Survey S-series S26 (unpublished)
JACKSON M J 1971 Notes on a geological reconnaissance of the Officer Basin Western
Australia Australia BMR Geology and Geophysics Record 19715 30p
JACKSON M J and van de GRAAFF W J E 1981 Geology of the Officer Basin Western
Australia Australia BMR Geology and Geophysics Bulletin 206 102 p
LOWRY D C JACKSON M J van de GRAAFF W J E and KENNEWELL P J 1971
Preliminary result of geological mapping in the Officer Basin Western Australia Western
Australia Geological Survey Annual Report for 1971 p 50ndash56
MYERS J S 1990 Precambrian in Geology and mineral resources of Western Australia
Western Australia Geological Survey Memoir 3 p 737ndash750
MYERS J S SHAW R D and TYLER I M 1994 Proterozoic tectonic evolution of
Australia 12th Australian Geological Convention Geological Society of Australia Abstracts
no 37 p 312
NEDIN C and JENKINS R J F 1991 Re-evaluation of unconformities separating the
lsquoEdiacaranrsquo and Cambrian systems South Australia Palaios v 6 p 102ndash108
PHILLIPS B J JAMES A W and PHILIP G M 1985 The geology and hydrocarbon
potential of the north-western Officer Basin APEA Journal 25 (1) p 52ndash61
POWELL C McA LI Z X McELHINNY M W MEERT J G and PARK J K 1993
Paleomagnetic constraints on timing of the Neoproterozoic breakup of Rodinia and Cambrian
formation of Gondwana Geology v 21 p 889ndash892
43
POWELL C McA PREISS W V GATEHOUSE C G KRAPEZ B and LI Z X 1994
South Australian record of a Rodinian epicontinental basin and its mid-Neoproterozoic
breakup to form the Palaeo-Pacific Ocean Tectonophysics v 237 no 3ndash4 p 113ndash140
PREISS W V 1976 Proterozoic stromatolites from the Nabberu and Officer Basins Western
Australia and their biostratigraphic significance South Australia Geological Survey Report
of Investigations no 47 p 1ndash51
TOWNSON W G 1985 The subsurface geology of the western Officer Basin mdash results of
Shellrsquos 1980ndash1984 petroleum exploration campaign APEA Journal v 25 (1) p 34ndash51
WATTS K J 1982 The geology of the Townsend Quartzite Upper Proterozoic shallow water
deposit of the Northern Officer Basin Western Australia Perth University of Western
Australia BSc honours thesis (unpublished)
WELLS A T and KENNEWELL P J 1974 Evaporite exploration in the Officer Basin
Western Australia at the Madley Diapirs Australia BMR Record 1974194 (unpublished)
WILLIAMS I R and MYERS J S 1990 Paterson Orogen in Geology and mineral resources
of Western Australia Western Australia Geological Survey Memoir 3 p 274ndash286
WILLIAMS I R 1990 Savory Basin in Geology and mineral resources of Western Australia
Western Australia Geological Survey Memoir 3 p 329ndash334
WILLIAMS I R 1994 The Neoproterozoic Savory Basin Western Australia in The
sedimentary basins of Western Australia edited by P G PURCELL and R R PURCELL
Petroleum Exploration Society of Australia Symposium Perth WA 1994 Proceedings p
841ndash850
WILSON R B 1967 Woolnough Hills and Madley diapiric structures Gibson Desert WA
APEA Journal v 7 p 94ndash102
44
Appendix 2
Meteorological data (from Bureau of Meteorology Perth 1994)
Table 21 Wiluna rainfall (mm)
Year Jan Feb Mar Apr May Jun Jul Aug Sept Oct Nov Dec
1975 0 45 446 309 306 59 276 4 34 886 638 164 1976 16 154 12 138 53 16 34 62 12 238 0 2 1977 44 0 66 74 68 95 24 363 1 58 12 727 1978 234 522 94 16 0 96 367 24 16 353 185 45 1979 19 173 122 88 91 4 0 246 58 0 169 114 1980 148 764 68 1081 259 626 629 06 56 02 174 0 1981 123 476 192 32 196 118 44 74 14 0 28 312 1982 374 705 206 244 1079 92 02 143 368 526 368 118 1983 1 112 928 248 0 212 56 32 5 1 42 496 1984 149 7 342 84 836 0 348 132 224 04 16 172 1985 596 483 0 166 556 0 514 56 0 0 4 0 1986 0 154 35 0 0 1085 23 01 239 137 0 04 1987 1204 119 19 89 17 575 154 126 07 1 0 398 1988 46 202 164 13 388 0 202 104 0 0 224 1309 1989 207 234 26 703 278 536 57 0 01 0 144 02 1990 1035 23 281 46 126 53 94 218 44 9 42 0 1991 48 0 41 45 0 472 297 12 0 1 0 7 1992 112 96 1025 1227 323 65 04 174 0 132 48 4 1993 0 697 0 202 445 0 12 306 18 05 14 33 Mean 25 35 22 27 27 25 18 12 6 13 13 21
JAN FEB MAR APR MAY JUN JUL AUG SEP OCT NOV DEC0
10
20
30
40
Mea
n R
ain
fall
(mm
)
Month
Mean monthly rainfall in Wiluna
MKS41 140498
45
Table 22 Wiluna minimum temperature (degC)
Year Jan Feb Mar Apr May Jun Jul Aug Sept Oct Nov Dec
1975 ndash 23 203 15 94 63 71 62 103 124 169 205 1976 242 229 194 15 10 63 59 73 95 143 16 228 1977 243 25 197 148 96 95 56 86 102 ndash 188 23 1978 241 232 203 18 102 64 76 8 9 152 19 205 1979 255 226 216 167 83 6 59 79 97 145 198 223 1980 255 226 231 155 134 83 68 75 121 108 193 223 1981 245 216 19 182 119 6 54 78 138 159 163 218 1982 232 224 177 16 ndash ndash 37 111 112 164 209 225 1983 235 24 197 147 112 88 39 88 121 162 189 219 1984 241 243 191 156 ndash 72 66 7 95 161 182 211 1985 244 231 ndash 159 98 65 71 73 117 147 205 ndash 1986 ndash 229 226 155 93 96 43 49 10 122 ndash 219 1987 ndash 217 183 175 85 77 68 68 112 ndash ndash 221 1988 238 214 209 178 111 ndash ndash 86 104 157 171 195 1989 ndash 237 199 165 107 67 44 61 107 131 187 ndash 1990 232 ndash 211 155 118 62 57 87 102 149 195 22 1991 26 256 217 168 122 101 78 ndash 113 18 168 219 1992 227 227 214 169 102 98 59 69 ndash 125 159 196 1993 241 218 196 171 103 ndash 49 68 88 128 192 211 Mean 24 23 20 16 10 8 6 8 11 14 18 21
NOTE Dashes indicate data unavailable
JAN FEB MAR APR MAY JUN JUL AUG SEP OCT NOV DEC0
10
20
30
40
Month
MKS43 140498
50
Mean monthly minimum temperatures at Wiluna
Mea
n T
emp
erat
ure
(degC
)
46
Table 23 Wiluna maximum temperature (degC)
Year Jan Feb Mar Apr May Jun Jul Aug Sept Oct Nov Dec
1975 ndash 349 326 281 247 201 197 212 256 248 31 344 1976 374 369 346 297 248 206 208 225 265 287 313 388 1977 397 392 352 296 234 212 222 244 ndash 308 337 383 1978 378 345 346 316 242 195 176 205 231 295 334 356 1979 403 36 364 295 ndash ndash ndash 193 242 318 359 373 1980 392 342 377 275 24 176 179 233 292 288 349 391 1981 385 346 337 342 242 178 201 224 30 326 326 369 1982 372 359 315 307 ndash ndash 196 253 252 305 353 379 1983 381 389 327 272 263 222 187 248 287 321 336 366 1984 378 393 322 299 226 215 178 214 234 ndash 336 364 1985 40 366 ndash 294 224 216 205 212 284 307 355 ndash 1986 ndash 383 372 307 ndash 193 166 196 261 277 ndash 382 1987 ndash 339 328 305 21 202 214 218 275 ndash ndash 374 1988 388 365 353 301 23 ndash ndash 228 283 334 31 33 1989 ndash 375 339 285 238 179 181 219 275 298 336 ndash 1990 368 ndash 36 309 268 19 188 205 274 309 373 393 1991 414 416 363 315 268 206 21 ndash 279 338 332 368 1992 363 383 336 263 213 178 213 197 ndash 285 313 359 1993 396 357 344 301 221 ndash 197 215 253 294 347 362 Mean 39 37 34 30 24 20 20 22 27 30 34 37 NOTE Dashes indicate data unavailable
JAN FEB MAR APR MAY JUN JUL AUG SEP OCT NOV DEC0
10
20
30
40
Month
MKS42 140498
50
Mean monthly maximum temperatures at Wiluna
Mea
n T
emp
erat
ure
(degC
)
47
Appendix 3
Table 31 Summary of palynological results
Drillhole Depth (m) F no(a) GSWA no Lithology Formation Assemblage TAI(b)
BWB 1 74ndash75 F49668 135741 dark-grey siltstone basalt Jilyilli gt5 BWB 1 98ndash100 F49669 135742 dark-grey siltstone basalt Jilyilli gt5 BWB 1 121ndash122 F49670 135743 dark-grey siltstone basalt Jilyilli gt5 TWB 1 86ndash87 F49671 135631 dark-grey siltstone McFadden 3+ TWB 1 104ndash105 F49672 135632 dark-grey siltstone Cornelia 3+ TWB 1 121ndash122 F49673 135633 dark-grey siltstone Cornelia 4 TWB 2 14ndash15 F49674 135634 dark-grey siltstone Skates Hills 3+ TWB 6 49ndash50 F49675 135675 dark-grey siltstone Cornelia 1 3+ TWB 9 49ndash51 F49676 135704 dark-grey siltstone Brassey Range 1 3+ Trainor 1 37497- F49733 138939 black mudstone with Cornelia 5 37509 light-grey siltstone Trainor 1 3809 F49734 138940 dark-grey and black Cornelia 4- laminated mudstone Trainor 1 4170 F49735 138941 black unlaminated mudstone Cornelia 4- Trainor 1 4950 F49851 139501 dark-grey indurated siltstone Cornelia 5 Trainor 1 6032 F49852 139502 dark- and light-grey Cornelia 5 indurated siltstone Trainor 1 6434 F49853 139503 greenish indurated finely Cornelia 5 laminated siltstone LDDH 1 270 F49678 138934 dark-grey siltstone interbeds Waters 1 3+ in enterolithic evaporite Tarcunyah Gp LDDH 1 277 F49679 138935 dark-grey siltstone in cavity Waters 1 3+ in enterolithic evaporite Tarcunyah Gp
NOTES (a) GSWA Fossil Catalogue number (b) TAI = Thermal Alteration Index of Traverse (1988 plate 1)
48
Appendix 4
Savory Sub-basin quantitative magnetic and gravity interpretation (extracted from Cowan 1995)
Summary
A program of quantitative aeromagnetic interpretation has been completed on BMRAGSO data from the Savory Sub-
basin Western Australia Quantitative aeromagnetic interpretation utilized the 3D Euler deconvolution method
supported by wavenumber filtering and image processing The results have provided useful information on structural
trends and depth to magnetic sources in a structurally complex area Depth to magnetic source analysis has provided
information on intra-sedimentary magnetic sources as well as basement rocks
The results of the interpretation support previously identified depocentres However the presence of magnetic
sources at several levels makes it very difficult to produce a reliable magnetic basement depth contour map It is
considered more productive to work with the 3D Euler colour circle plots and images rather than trying to contour the
results It would be necessary to carry out a full-scale interpretation of the BMRAGSO profile data to improve on the
3D Euler results The regional gravity was found to be useful in interpreting the regional setting of the area although
the very wide data spacing limits quantitative use of the data The gravity data show quite a complex picture with
limited consistent correlation between gravity features and basin structures This suggests that gravity anomalies
reflect changes in density of the basement rocks rather than basement topography especially in the northern part of the
basin
It is recommended that the GSWA investigate access to company confidential high-resolution aeromagnetic data
prior to planning further aeromagnetic surveys Private companies have flown large parts of the northern half of the
area as part of their diamond exploration program Additional gravity coverage of the area may be more cost effective
than magnetic surveys as the gravity data provides more information on changes within the sedimentary section
Introduction
The main use of aeromagnetic data in petroleum exploration has been the determination of magnetic basement
topography although there has been increasing interest in analysis of intra-sedimentary magnetic anomalies
intrabasement and suprabasement magnetic anomalies These anomalies are used to determine depth to magnetic
basement rocks and hence determine the thickness of the sedimentary sequence Unfortunately interpretation of the
intrabasement and suprabasement magnetic anomalies is non-unique in terms of position and size of causative sources
because of the inherent ambiguity of potential-field methods However this ambiguity can be reduced by placing
49
constraints on source geometry and magnetization and by using geological and other geophysical data to constrain
the solution
Before 1970 most depth-determination techniques involved graphical determination of slopes of selected
magnetic anomalies and application of various empirical factors to convert the slopes into depth estimates Geological
Society of America Memoir 47 Interpretation of Aeromagnetic Maps by Vacquier et al (1951) was a landmark for
this type of interpretation
Automated interpretation procedures have played an increasingly important role in depth interpretation and a
wide range of techniques have been developed Many of these techniques are designed for application to located data
profiles and assume a two-dimensional geometry However there has been renewed interest in techniques applicable
to gridded data
Two distinct types of method can be recognized In the first case often described as discrete methods individual
isolated magnetic anomalies are interpreted and the results used to produce a map of basement relief In the second
case often described as continuous methods areas of data containing a number of anomalies are interpreted
statistically to produce direct output of basement depths
The discrete methods usually involve a semiautomatic initial phase which generates a large number of possible
depth solutions and an interactive second phase to screen and select acceptable solutions The advantage of this
approach is that the interpreter can select features that are relatively free from interference from adjacent anomalies
and consider all aspects of a particular magnetic anomaly The disadvantage is that interpretation can be very time
consuming as a wide range of depths are usually possible depending on the initial model chosen and a significant
amount of effort is needed to select the correct model In the case of the Savory Sub-basin dataset we encountered
problems in separating basement related effects from the effects of shallower intrasedimentary magnetic sources
Because of these problems we have concentrated on displaying the Euler results accompanied by separation filter
images of the data to show the shallower effects and deeper effects rather than trying to refine a 3D Euler
deconvolution depth-to-crystalline-basement contour
The continuous methods are very direct provided that the rather restrictive assumption can be made that all
anomalies are due to lateral magnetization changes due to basement topography This means that shallow effects and
large intrabasement anomalies must be removed from the data This involves judgement and skill as it is necessary to
distinguish between the lower amplitude suprabasement anomalies due to basement topography and the larger
intrabasement anomalies reflecting magnetization changes within the basement These methods were not considered
suitable for the Savory Sub-basin magnetic dataset but were used to invert the gravity data
50
Limitations of magnetic and gravity interpretation
Interpretation of the area is limited by a shortage of information on the nature and physical properties of the deeper
sedimentary sequence and the underlying basement rocks However using techniques such as cross-correlation of
gravity and pseudo-gravity data it is possible to try to differentiate between anomalies relating to basement and those
related to the sedimentary sequence
Gravity anomalies reflect changes within the sedimentary sequence as well as basement condition These
changes in density of sedimentary rocks produce gravity anomalies without a corresponding magnetic anomaly hence
the complementary nature of gravity and magnetic surveys The main use of magnetics is to determine depth to
magnetic basement and any intra-sedimentary volcanic rocks or intrusives whereas gravity provides much more
general information on the sedimentary sequence
Unfortunately interpretation of gravity anomalies is complicated since they can be due to a number of geological
features including
bull major basement faults
bull basement highs
bull igneous intrusions within the basement
bull sedimentary basins which may or may not be isostatically compensated
bull intra-sedimentary volcanics and associated plutonic centres
Two major problems affect the interpretation of both magnetic and gravity data
1 The inherent ambiguity of potential-field data There is no unique solution to any measured gravity or magnetic
anomaly and theoretically there will be an infinite number of source geometry and magnetizationdensity
combinations which will fit the observed data This means that any a priori information which helps to select a
suitable model is very useful
2 Measured anomalies are the summation of effects from different depths For example an observed gravity profile
may contain contributions from shallow sources (density variations within the sedimentary basin) intermediate
depth sources (density variations due to large igneous intrusions within the basement) and deep sources (crustal
thinning producing a mantle anomaly) Separation of these component responses is the regionalresidual problem
which we solve using spectral analysis and differential upward continuation-based separation filtering
Regional setting and interpretation overview
The area studied includes parts of BALFOUR DOWNS (SF51-9) RUDALL (SF51-10) ROBERTSON (SF51-13) GUNANYA
(SF51-14) COLLIER (SG50-4) BULLEN (SG51-1) TRAINOR (SG51-2) MADLEY (SG51-3) NABBERU (SG50-5)
STANLEY (SG51-6) and HERBERT (SG51-7) 1250 000 sheets Broadly the area lies between latitudes 22deg00rsquondash25deg30rsquoS
and longitudes 119deg30rsquondash123deg30rsquoE
51
Regional gravity
The AGSO regional gravity data (at nominal 11 km spacing) was gridded at a 4 km mesh spacing using a minimum-
curvature algorithm Bouguer gravity values in the area are negative reflecting mass deficiency at depth and range
from -84 mgals to -25 mgals
A Bouguer gravity colour image is shown as Figure 41 A residual grid was produced by removing a fifth-order
orthogonal polynomial from the Bouguer data but did not add to the interpretation
120deg 121deg 122deg 123deg
23deg
24deg
25deg
-25
-84
50 km
MKS46 180598
mgal
Figure 41 Regional Bouguer gravity (BMRAGSO data) gridded at 4 km
52
The data show a complex pattern of positive and negative anomalies with no clearly defined trends Correlations
with aeromagnetic data and known basin structures are poor A vague north-northwest linear trend appears to coincide
with the Marloo Fault (Figure 42) A prominent negative anomaly appears to coincide with the Blake Fold and Fault
Belt depocentre and continues as a narrower negative anomaly to the east until it widens out again near the edge of the
basin Elsewhere the gravity data show little correlation with known basin structures and it is likely that especially in
the north of the area gravity anomalies are due to density changes in the basement rather than changes in basement
topography
Production of wavelength-filtered residual gravity plots and vertical gradient plots showed very patchy aliased
data reflecting poor sampling in much of the area
Regional magnetics
The AGSO regional aeromagnetic data were gridded at a 400 m mesh spacing using a minimum-curvature algorithm
(Figure 43) Most of the data has a line spacing of 1600 m with small areas of 1 km spacing The quality of the data is
acceptable for regional interpretation but is not adequate for detailed analysis The accuracy of the flight path is rather
variable reflecting the vintage of the data and the noise envelope of the data is poor by modern standards Problems
were also encountered in joining different map sheets
The magnetic anomaly pattern over the south and west part of the area shows a strong high frequency signature
reflecting the presence of widespread basic sills and dykes Some of the major north-northeasterly trending dykes can
be traced over considerable distances
Discontinuous high-frequency anomalies extend as a northwest-trending zone through the centre of the area and
this zone includes a conspicuous circular magnetic anomaly which is probably a ring complex
The northern and eastern parts of the area are characterized by long-wavelength deep-seated basement magnetic
anomalies with 120deg and 150deg trends dominant The Marloo and Perentie Faults (Figure 42) appear as distinct linear
zones and offsets A prominent easterly trending negative anomaly in the northwest of the area appears to swing round
to the southeast and may separate different basement blocks One possible interpretation is that this very deep seated
anomaly separates areas of Archaean and Proterozoic basement
Regional geology
The regional geology is described in Williams (1992) The GSWA provided a digitized version of Plate 2 from this
Bulletin the structural interpretation map to use as an overlay (Figure 42)
53
Pp
Pp
PSd
PSd
PSd
PSd
PSd
PSo
PSt
PSt
PSf
PSf
PSf
PSb
PSb
PSb
PSsPSs
PSs
PSb
PSm
PSp
PSc
PSc
PSw
PSw
PSw
PSg
PSr
PSj
PSg
PM
Pk
PY
PY
PSd
L
L
L
L
L
L
L
LL
L
L
L
LL
L
LL
L L
LL
L L
L
L
L
L
L
L
L
LL
L
L
BLAKEDEPOCENTRE
MA
RLO
O
FAU
LT
PERENTIEFAULT
50 km
MKS39120598
120deg 121deg 122deg 123deg
25deg
24deg
23deg
Approximate boundaryof aeromagnetic interpretation
PML
PSgL
PSjL
PML
PSpL
PML
PML
PSfL
PSfL
PSpL
LPc
LPcLPcPSrL
LPA
Durba Sandstone
Woora Woora Formation
McFadden Formation
Tchukardine Formation
Boondawari Formation
Skates Hills Formation
Mundadjini Formation
Coondra Formation
Spearhole Formation
Watch Point Formation
Jilyili Formation
Brassey Range Formation
Glass Spring Formation
Paterson Formation
Yeneena Group
Karara Formation
Cornelia Formation
Kahrban Subgroup
Bangemall Group
Fault
Formation boundary
PSdL
PSoL
PSfL
PStL
PSbL
PSsL
PSmL
PScL
PSpL
PSwL
PSjL
PSrL
PSgL
Pp
PYL
PkL
LPc
LPA
PML
Savory Group Other Units
PYL
Figure 42 Regional geology and structure map (after Williams 1992)
54
120deg 121deg 122deg 123deg
23deg
24deg
25deg
5820
3750
MKS47 180598
nT
50 km
Figure 43 Regional aeromagnetic data total magnetic intensity (BMRAGSO data) gridded at 400 m
Analysis
3D analysis
3D Euler deconvolution was used as the primary depth-determination method The advantage of this approach is that
consistent solutions can be obtained over the entire area with minimal assumptions about source geometries Euler
deconvolution of gridded data is used for positional information and estimation of depth to top of source Euler
55
deconvolution yields a large number of depth solutions which have to be screened to reject spurious solutions Results
are plotted as circles in eight depth ranges with radius proportional to depth and colour coded
The 400 m total magnetic intensity grid was used for the analysis Horizontal gradients in x and y and the vertical
gradient were calculated 3D Euler deconvolution was tested on the 400 m gridded data using windows of 9 times 9 and
11 times 11 and 16 times 16 data points and structural indices 05 (fault) and 10 (sill or dyke) It was concluded that the
16 times 16 window produced the best results overall and final plots were produced for the 16 times 16 window and structural
index 05 (Fig 44) Results were very good over the northern and central parts of the area showing magnetic sources
Figure 44 Depth to magnetic source 3D Euler deconvolution 16 times 16 window of 400 m gridded data structural index 05
56
at several different levels Unfortunately in the extreme south of the area shallow intrasedimentary magnetic sources
(sills and dykes) dominated the inversion and the results contained few basement solutions
In order to reduce these problems the 400 m gridded data were filtered using a separation filter based on
interpretation of the log-energy spectrum The 3D Euler method was run on the filtered data in order to generate more
basement-depth solutions Results for the deep-separation filter data were gridded and presented as a colour image in
Cowan (1995) Attempts to grid the Euler output were unsatisfactory and it is considered safer to interpret the 3D
Euler depth plots The 3D Euler depth results from the separation-filter run should be analysed with care as perfect
separation of the basement can never be achieved and there will always be some contamination from sources at
different levels
The results of original total magnetic intensity 3D Euler depth estimation for structural index 05 using a 16 point
window have been plotted at 1500 000 scale (not included in this publication but available in Cowan (1995) from the
GSWA Library as S10331) and as reduced A4 colour circle plots (Figure 44)
The results of deep-basement 3D Euler depth estimation for structural index 05 using a 16 point window have
been plotted as a colour image at 1500 000 scale and as an A4 image (not included in this publication)
2D analysis
Two equispaced profiles were interpolated with a 50 m station interval from the AGSO-located data profiles for the
BULLEN 1250 000 sheet The interpolated profiles were analysed using 2D Euler deconvolution and Werner
deconvolution Results are included in Cowan (1995) and show the use of these methods for more detailed analysis
Filtered data
In order to reconcile 3D Euler results from shallow basement and intrasedimentary magnetic sources we produced
several separation-filtered maps and images We found the shallow-layer double-separation filter (Figure 45) to be
very effective for shallow sources and the deep-layer standard-separation filter (Figure 46) for the basement layer
Gravity and magnetic data correlation
Both lsquoreduced to the polersquo (RTP) magnetics (Figure 47) and pseudo-gravity data (Figure 48) were produced as part of
the reconciliation of gravity and magnetic signatures In both cases the filtering operations assumed magnetization by
induction in the present Earths field The RTP data are fairly similar to the total magnetic intensity The pseudo-
57
gravity data are dominated by a northwest-trending strong positive anomaly and there is little correlation with the
Bouguer gravity data
The poor magneticgravity correlation is confirmed by cross-correlation of the RTP magnetics and the gravity
gradient The correlation plot in Figure 49 shows little coherent response with numerous zones of positive and
negative correlation
Figure 45 Regional aeromagnetic data shallow layer separation filter (BMRAGSO data) gridded at 400 m
Results
In the north and east of the area on the Wells Foreland Sub-basin trend (refer to Figure 1 main text) we see a range
of quite deep 3D Euler depths and several trend directions with north-northwesterly dominant There are relatively few
shallow intrasedimentary solutions in this zone
The second area of deep 3D Euler solutions lies over the Blake depocentre (Figure 43) with several trend
directions
Elsewhere the 3D Euler results are dominated by shallow intrasedimentary depth solutions reflecting mainly the
dolerite sills dykes and the ring complex However where we do see basement-related solutions in the south and
west of the area they appear to be shallower than those noted for the Wells Foreland Sub-basin and the Blake
depocentre
58
Figure 46 Regional aeromagnetic data deep-layer separation filter (BMRAGSO data) gridded at 400 m
Figure 48 Regional aeromagnetic data pseudo-gravity transform (BMRAGSO data) gridded at 400 m
Figure 47 Regional aeromagnetic data reduced-to-pole (BMRAGSO data) gridded at 400 m
Figure 49 Regional aeromagnetic and gravity data gravitymagnetic correlation using RTP magnetics and gravity gradient (BMRAGSO data) gridded at 4 km
59
This subdivision of the area into two zones of deep solutions is consistent with interpreted depocentres
However the interference between sources at different levels and the complexity of the magnetic response of the
basement rocks precludes more refined interpretation at this stage
The area of deep 3D Euler solutions over the Blake depocentre correlates with the pronounced negative gravity
anomaly discussed in the gravity interpretation section Using a density contrast of -015 gcc the negative gravity
anomaly could indicate up to 6ndash8 km of low-density sedimentary rocks depending on assumptions about the regional
field
The area of deep 3D Euler solutions over the Wells Foreland Sub-basin has a complex gravity expression and no
clear basin structure emerges from inversion of these data As noted previously it is likely that observed gravity
anomalies reflect contrasts in basement density rather than basement topography
Separation filtering applied to the magnetic data helps to enhance the intrasedimentary magnetic signature and to
give a better impression of the basement magnetic signature even though separation of the basement response is not
perfect
Conclusions
Quantitative aeromagnetic interpretation using 3D Euler deconvolution supported by wavenumber filtering and image
processing has been successful in providing structural trend and depth information for the Savory Sub-basin
Quantitative magnetic interpretation has revealed two zones of relatively deep magnetic basement beneath the
Wells Foreland Sub-basin and the Blake depocentre
This analysis of the magnetic data supports interpreted depocentres but the complexity of the basement magnetic
signature and interference from sources at different depths precludes further refinement to a map of basement
topography
Regional gravity proved to be very useful in understanding the regional setting of the area and in providing
support for aspects of the interpretation The gravity data support the interpretation of the Blake depocentre
suggesting up to 6ndash8 km of low-density sedimentary rocks
The deep structure of the Savory Sub-basin area is obviously complex with different areas underlain by
Archaean and Proterozoic basement and with the Capricorn suture occurring in the centre of the area
60
Recommendations
The quantitative magnetic interpretation needs to be reconciled with geological models available for the area
In particular the zones tentatively identified as areas with thick sedimentary rocks the Wells Foreland Sub-
basin and the Blake depocentre need to be investigated
Cross sections should be prepared across the basin for joint magneticgravity modelling especially for the Blake
depocentre It is important to be able to explain the strong negative gravity anomaly in this area
In view of the effects of basement density contrasts on the gravity field for the northern part of the area we think
that additional gravity interpretation and acquisition of new gravity data may not be justified as they will not
contribute significantly to understanding basin evolution and structure
It is recommended that GSWA try to get access to company confidential high-resolution aeromagnetic data
rather than flying new surveys The GSWA might offer to fund flying of new infill areas as a bargaining point
References
The original text of this report by Cowan (1995) and 1500 000 scale maps are filed in the GSWA Library under
S10331
COWAN D 1995 Savory Basin quantitative magnetic interpretation Western Australia Geological Survey S-series
S10331 (unpublished)
VACQUIER V STEENLAND N C HENDERSON R G and ZIETZ I 1951 Interpretation of aeromagnetic
maps The Geological Society of America Memoir 47 151p
WILLIAMS I R 1992 Geology of the Savory Basin Western Australia Western Australia Geological Survey
Bulletin 141 115p
61
Appendix 5
Geochemistry
MKS38 250398
Saturate FractionC12+ GLC
1217
Pr18
Ph
22
31CSR WELL-13 315m Cuttings
Figure 51 Canning Stock Route Well 13 gas chromatograph of extract of auger drill sample
12
17
18
22
31
Pr Ph
LDDH 1 6623m CoreSaturate FractionC12+ GLC
MKS35 240398
Figure 52 Gas chromatograph of extract from core sample at 6623 m LDDH1
62
Table 51 Canning Stock Route Well 13 auger drill samples
GSWA sample Drill depth (m)(a) Comments
135601 150 At watertable 135602 203 (all samples consist 135603 310 of sand mud and water) 135604 315 At total depth
NOTE (a) Datum for drill depth is the top of sediment fill in the well which is 155 m below ground level (ie the total depth of 315 m is 47 m below ground level)
Table 52 Canning Stock Route Well 13 gas chromatography data for 315 m depth sediment sample
Parameter Value
Weight of rock extracted (grams) 945 Total extract (ppm) 519 n-Alkane distribution n-C12 07 n-C13 23 n-C14 26 n-C15 22 n-C16 19 n-C17 14 i-C19 23 n-C18 14 i-C20 08 n-C19 11 n-C20 16 n-C21 25 n-C22 29 n-C23 70 n-C24 42 n-C25 95 n-C26 43 n-C27 83 n-C28 38 n-C29 87 n-C30 31 n-C31 273 Alkane compositional data Pristane phytane ratio 279 Pristane n-C17 ratio 161 Phytane n-C18 ratio 059 CPI (1)(a) 284 CPI (2) 209 (C21 + C22) (C28 + C29) 043
NOTE (a) CPI= Carbon preference index
63
Table 53 LDDH1 extract liquid chromatography data for 6623 m concentration
Rock extracted Total extract (grams) (ppm)
702 313
NOTE ppm= parts per million
Table 54 LDDH1 saturate gas chromatography data of core for 6623 m alkane composition
Pristane Pristane Phytane (a) CPI (1) CPI (2) (C21+C22) Phytane n-C17 n-C18 (C28+C29)
103 026 024 103 102 325
NOTE (a)CPI = carbon preference index
Table 55 LDDH1 saturate gas chromatography data of core for 6623 m n-alkane distributions
Parameter Value
n-C12 17 n-C13 38 n-C14 55 n-C15 60 n-C16 65 n-C17 74 i-C19 19 n-C18 78 i-C20 19 n-C19 80 n-C20 79 n-C21 71 n-C22 64 n-C23 57 n-C25 43 n-C24 38 n-C27 31 n-C28 23 n-C29 19 n-C30 12 n-C31 10
64
Appendix 6
Table 61 Summary of data from Trainor waterbores (TWB) and Bullen waterbores (BWB)
Well AMG Elevation TD Status(b) Completion details Water Salinity Water level Flow rate Depth to consolidated AGD84 GL (m) (m) struck mgl(c) (m) (LHr) lithology aquifer(e) Z51(a) Interval (m) (100 mm PVC) (m) (mgl)(d)
TWB 1 473660E 453 122 comp 0ndash75 plain 63 7 300 24 2 880 12 m 7287404N 75ndash93 slotted (9 260) McFadden Fm 93ndash99 plain TWB 2 472 977E 475 23 abd nil 15 m 7285877N Skates Hills Fm dry TWB 3 473259E 475 50 abd nil 7 m 7285849N Skates Hills Fm dry TWB 4 463225 E 445 50 comp 0ndash22 plain 35 7 200 55 3 600 0 m 7286143N 22ndash34 slotted (8 140) Tertiary sand and gravel 23ndash60 plain TWB 5 463095E 445 31 comp 0ndash19 plain 13 26 000 655 3 600 Tertiary sand and gravel 7277721N 19ndash25 slotted (36 700) 25ndash31 plain TWB 6 457013E 455 50 comp 0ndash42 plain 38 920 119 600 0 m 7274352N 42ndash48 slotted (1 030) Cornelia Fm ss TWB 7 453739E 475 26 susp 0ndash2 plain 11 9 300 48 4 500 0 m 7263891N (10 500) Tertiary sand TWB 8 433893E 535 60 susp 0ndash2 plain 47 8 500 gt46 1 200 0 m 7245991N (10 900) Tertiary sand and Brassey Range Fm ss TWB 9 437219E 505 51 comp 0ndash47 plain 45 1 000 58 600 1 m 7235905N 47ndash51 slotted (990) Brassey Range Fm ss TWB 10 434927E 495 32 susp 0ndash2 plain 235 450 120 0 m 7225875N (500) Dolerite
65
BWB 1 287337E 580 122 abd Nil 1 m 7245861N Jilyili Fm dry BWB 2 288346E 545 50 comp 0ndash26 plain 15 630 3 29 000 0 m 7240423N 26ndash38 slotted (730) Tertiary sand and gravel 38ndash50 plain BWB 3 305637E 545 50 abd 19 8 800 43 7 200 0 m 7240423N (10 550) Tertiary ss BWB 4 320167E 515 445 comp 0ndash20 plain 9 980 445 24 000 0 m 7248097N 20ndash32 slotted (1 190) Tertiary ss 32ndash44 plain BWB 5 353393E 545 20 susp 0ndash2 plain 45 (970) 1 m 7238934N Basalt
NOTES (a) GPS accuracy ~ 150 m (b) Comp = completed abd = abandoned susp = suspended (c) Salinity from conductivity (d) Analysis total dissolved solids (e) Fm = Formation ss = sandstone
8
Table 1 Summary of formations in the Savory Sub-basin
Formation Super Depo Lithology Thickness Depositional Savoy Comments Seq(a) Seq(b) (m) environment Group(c)
Durba Sandstone 4 E Quartz sandstone with minor 100 Fluvial lacustrine Y Excellent reservoir basal conglomerate lenses Woora Woora 4 D Medium-grained ferruginous 400 Shallow marine deltaic Y Formation sandstone lithic sandstone quartz wacke siltstone McFadden 4 D Laminated fine- to coarse-grained 1 500 Shallow marine deltaic Y Possible reservoir Formation quartz sandstone feldspathic sandstone quartz wacke minor conglomerate siltstone Tchukardine 4 D Medium- to coarse-grained sandstone 700 Shallow marine Y Formation lithic sandstone quartz wacke conglomerate lenses siltstone minor shale Boondawari 3 C Glacigene diamictite sandstone siltstone Formation shale conglomerate minor dolomite (some stromatolitic and oolitic) rhythmite 800 Glacial shallow marine Y Possible source rock Skates Hills 1 B Thin-bedded dolomite (some stromatolitic) 200 Shallow marine sabkha Y Possible source rock Formation chert evaporites fine- to medium-grained sandstone siltstone shale patchy basal conglomerate Mundadjini 1 B Fine- to coarse-grained sandstone 1 800 Deltaic sabkha Y Possible source rock Formation conglomerate siltstone minor shale shallow marine mudstone dolomite (some stromatolitic) and evaporites Coondra 1 B Coarse- to medium-grained sandstone 1 000 Fan delta Y Possible reservoir Formation poorly sorted conglomerate pebbly sandstone Spearhole 1 B Coarse- to medium-grained sandstone 1 100 Braided fluvial deltaic Y Possible reservoir Formation pebbly sandstone siltstone and oil shows in conglomerate lenses Mundadjini 1 Boondawari 1
9
Watch Point 1 B Shale siltstone fine- to medium-grained 400 Shallow marine deltaic Y Formation sandstone glauconitic sandstone Jilyili Formation 1 A Fine-grained sandstone siltstone minor shale mudstone conglomerate lenses 1 000 Deltaic Y Brassey Range 1 A Fine- to medium-grained sandstone 1 700 Fluvial deltaic Y Formation siltstone shale minor mudstone Glass Spring 1 A Medium- to coarse-grained sandstone 1 600 Shallow marine fluvial Y Formation minor conglomerate and siltstone Tarcunyah Group 1 AampB Quartz sandstone feldspathic sandstone Shallow marine sabkha N Bitumen in LDDH1 quartz wacke shale siltstone fluvial lacustrine conglomerate evaporites dolomite Cornelia 1 A Sandstone siltstone shale mudstone Shallow marine N Overmature source rocks Formation minor glauconitic sandstone deep marine in Trainor 1 Kahrban 1 A Sandstone siltstone shale 1 700 Shallow marine deltaic N Subgroup
NOTES (a) Supersequences of Walter et al (1995) (b) Depositional sequences of Williams (1992) (c) Y= assigned to Savory Group in Williams (1992) N= previously considered to be older than the Savory Group but now included in the greater Officer Basin
10
SAVORY SUB-BASIN GIBSON SUB-BASINCENTRAL OFFICERBASIN
AMADEUS BASIN
PETERMANN RANGES OROGENY
NE
OP
RO
TE
RO
ZO
IC
ST
UR
TIA
NM
AR
INO
AN
ED
IAC
AR
IAN
CAMBRIANTO
NEOPRO-TEROZOIC
AG
E (
Ma)
SOUTHS RANGE MOVEMENT
AREYONGA MOVEMENT
Steptoe
MILES OROGENY
Mission Group
Cassidy Group
Rudall Complex
Bangemall Group
unnamed
Tar
cuny
ah G
roup
4
3
2
1
MKS12a 180598
500
550
600
650
700
750
800
850
900
SU
PE
R
SE
QU
EN
CE
unnamed
Tchukardine Fm
McFadden Fm
ArumberaSst
Julie Fm
Pertatataka Fm
Olympic FmPioneer Sst
Boondawari Fm
Turkey Hill FmLupton Fm
Kanpa Fm
Neale FmBabbagoola
FmHussar
Fm
Browne Fm
Woolnough Fm
Madley Fm
Bitt
er S
prin
gs F
m
LovesCreek M
Gillen M
Heavitree Fm
Arunta Complex
Throssell Group
TownsendQuartzite
Earaheedy Group
olderCornelia Fm
Jilyili Fm
SpearholeFm
MundadjiniFm
Skates Hills Fm
Lefroy Fm
Areyonga Fm
Aralka Fm
ME
SO
-P
RO
TE
RO
ZO
IC
Waters Fm
youngerCornelia Fm
Brassey RangeFormationKahrban
Subgroup
GlassSpring
Fm
Durba Sst
LP1ALP1B EVENT
Figure 4 Correlation of Savory Sub-basin formations with the western Officer and Amadeus Basins Fm = Formation Sst = Sandstone M = Member
11
The depositional sequences recognized in the sub-basin are an order of magnitude thicker than
those described from Phanerozoic passive-margin settings (Payton 1977 Posamentier et al 1988)
and are broadly comparable in scale to the second-order cycles of Vail et al (1977) and to the
megasequences of Hubbard et al (1985) The main subsurface data available to reveal the
unweathered nature of these rocks are Trainor-1 and the three-well diamond coring program in
Petroleum Permit EP 380 (Akubra 1 Boondawari 1 Mundadjini 1) completed in late 1997 in the
central west of the sub-basin (Figs 5 and 6)
The ages of all formations in the Savory Sub-basin are poorly constrained The only fossils
known are stromatolites and palynomorphs (acid-insoluble microfossils) Palynology from
available wells is summarized in Appendix 3 from Grey and Stevens (1997) and Grey and Cotter
(1996) and correlations using stromatolite biostratigraphy (Stevens and Grey 1997 Grey 1995f
Walter et al 1994 1995) are consistent with a Neoproterozoic age for the formations for which
data are available
A dolerite within the Boondawari Formation gave a poorly constrained RbndashSr age of about
640 Ma (Williams 1992) SHRIMP UndashPb dating of sedimentary zircons from the McFadden and
Cornelia Formations in stratigraphic drillhole Trainor 1 are discussed in Stevens and Adamides (in
prep) and Nelson (1997) The youngest ages from these analyses indicate that the maximum age
of the Cornelia Formation is Early Cambrian or Sturtian but these ages are inconsistent with
previous tectonic interpretations (Williams 1992) and current stratigraphic correlations which
suggest the Cornelia Formation is of Supersequence 1 age or older (Fig 4)
Depositional Sequence A Supersequence 1
Depositional Sequence A includes the Glass Spring Jilyili and Brassey Range Formations (Fig
3) All of these units are predominantly quartzose sandstones some of which are friable and have
significant visible porosity in outcrop Conglomerates are present in the Glass Spring and Jilyili
Formations
Depositional Sequence B Supersequence 1
Depositional Sequence B consists of the Watch Point Coondra Mundadjini Spearhole and
Skates Hills Formations (Fig 3) All of these formations contain beds of quartzose sandstone and
some also contain conglomerates The porosity of dolomites in the Skates Hills Formation appears
poor in surface exposures but its subsurface characteristics are unknown
12
50 km
120deg 121deg30 123deg
25deg
24deg
23deg
22deg
Greater Officer Basin
PNCEXP CA11PNCEXP CA12
PNCEXP CA13PNCEXP CA19
PNCEXP CA05
PNCEXP CA09
BD134589
GSWA Trainor 1 and TWB123
Fortescue River 1A
Mundadjini 1
Akubra 1Boondawari 1
TWB4TWB5
TWB6
TWB7
TWB8
TWB9
TWB10
BWB1
BWB2 BWB3
BWB4
BWB5
OD23
Mineral exploration drillhole
Stratigraphic drillhole
Waterbores and wells(TWB and BWB serieswaterbores identified)
MKS33270398
LDDH 1
Savory Sub-basin
Canning SR Well 13
EP380
Petroleum Exploration permit
Petroleum exploration well
Figure 5 Locations of petroleum exploration wells mineral exploration and stratigraphic drillholes water bores and wells and petroleum exploration permit EP380 in the Savory Sub-basin
13
TD=600m
TD=1367m
TD=701m
TD=709m
TD=50m
SS
1S
S1
SS1
SS
1S
S1
SS
1
SS
1
SS1
SS4 SS1
Pha
nero
zoic
or
SS
2
Cz
CzCz
Karst Bitumen
SS1
TD=181m
Mundadjini 1 Akubra 1 Boondawari 1 LDDH 1 Trainor 1 TWB 6
Munda-djini Fm
Spear-hole Fm
Munda-djini Fm
Munda-djini Fm
Spear-hole Fm
Spear-hole Fm
Waters Fm
McFadden Fm
Cornelia Fm
Cornelia Fm
Cornelia Fm
511 plusmn 13Maor 696 plusmn 20Ma(maximum)
779 plusmn 10Ma(maximum)
Mundadjini 1
Akubra 1 Boondawari 1
LDDH 1
Trainor 1TWB 6100 km
N
LOCATION
NW SE
Sea level
0m AHD
Dolerite basalt
Conglomerate
Sandstone
Mudstone
Dolomite
Limestone
Evaporite
TOC gt08
Permeability gt100md
Oil fluorescence
Sedimentary zircon U-Pb age
Identifiable polymorphs
Cainozoic
Supersequence 1 age
Unconformity
Formation contact
Cz
SS1
r
r
0
100
200
metres
VerticalScale
MKS36 120598
LEGEND
Figure 6 Geological cross section through significant drillholes in the Savory Sub-basin
14
Depositional Sequence C Supersequence 3
Depositional Sequence C consists of the Boondawari Formation (Fig 3) and although it contains
sandstone conglomerate and dolomite the sandstones contain significant amounts of feldspar and
clay and hence are likely to be poorer reservoirs than older sandstones
Depositional Sequence D Supersequence 4
Depositional Sequence D includes the McFadden Tchukardine and Woora Woora Formations
(Fig 3) The McFadden Formation is poorly sorted and sandstones contain significant amounts of
feldspathic clasts in the north of the basin but are significantly coarser and cleaner in the northeast
of the sub-basin (Williams 1992)
Sandstones of the Tchukardine and Woora Woora Formations are generally cleaner than those
of the McFadden Formation and are expected to have fair to good porosity although the
Tchukardine Formation has a higher clay content in parts
Depositional Sequence E Supersequence 4
Depositional Sequence E consists of the Durba Sandstone (Fig 3) a coarse sandstone with minor
conglomerate which has good to excellent visible porosity in surface exposures
Other depositional sequences and regional correlations
Sedimentary rocks which were not included in the Savory Group by Williams (1992) but which
are likely to be of Neoproterozoic age and hence part of the greater Officer Basin include the
Tarcunyah Group the Cornelia Formation and the Kahrban Subgroup
As discussed in the Introduction all of the strata in the Karara Basin and the younger strata
of the Yeneena Basin were redefined to form the Tarcunyah Group of the greater Officer Basin
(Bagas et al 1995) (Fig 7) In outcrop the Tarcunyah Group consists predominantly of quartzose
feldspathic and arkosic sandstone shale which is carbonaceous in parts and carbonate which
includes stromatolitic dolomite Mineral hole LDDH1 drilled on GUNANYA intersected the
15
120598
122deg
123deg
21deg
22deg
23deg
24deg
23deg
22deg
21deg
122deg
123deg
Fault
Thrust
Reverse thrust
CANNINGBASIN
OFFICERBASIN
GROUP
PILBARACRATON
TARCUNYAH
SAVORY GROUP
BANGEMALL
GROUP
THROSSELL
GROUP
LAMIL
GROUP
ConnaughtonTerrane
TerraneTalbot
complexTabletop granitic
Tabletop Terrane
Permian
Neoproterozoicgranitoid
50 km
FormationWaltha Woora
McKay Fault
South west Thrust
Vines
Fault
24deg
120deg
YENEENA CANNINGBASIN
ARUNTAINLIERRUDALL
COMPLEX
AMADEUSBASIN
MUSGRAVEBLOCK
OFFICERBASINYILGARN
CRATON
GROUP
GROUP
GROUP
PILBARACRATON
GROUP
EARAHEEDY
GLENGARRY
BANGEMALL
WYLOO GROUP
SAVORY
WA
CARNARVONBASIN
GASCOYNECOMPLEX
GROUPTARCUNYAH
400 kmGROUP
SA
N
T
CamelndashTabletopfault zone
KAHRBANSUBGROUP
CORNELIAFORMATION
MKS37
Figure 7 Regional geological setting of the Savory Group and western Officer Basin The dashed line on the inset map marks the interpreted margin of the greater Officer Basin
16
Tarcunyah Group and consists predominantly of mudstone with minor sandstone limestone
dolomite and anhydrite (Fig 6)
The age of the Tarcunyah Group is uncertain although limited palynological and stromatolite
evidence suggests that it is probably coeval with Supersequence 1 of the Centralian Superbasin
Drillhole LDDH1 contains palynomorphs equivalent to assemblages in the Browne and Bitter
Springs Formations of the Officer and Amadeus Basins respectively and from the Cornelia
Formation in TWB 6 (Grey and Stevens 1997) (Figs 4 and 6) Stromatolite specimens tentatively
assigned to Acaciella australica (Howchin 1914) Walter 1972 occur in the lower Tarcunyah
Group (Bagas et al 1995) The stromatolite Baicalia burra Preiss 1972 and a conical
stromatolite were reported from the upper part of the Tarcunyah Group (Stevens and Grey 1997)
The recognition of two stromatolite assemblages interpreted to have age significance in
Supersequence 1 sedimentary rocks of the Centralian Superbasin has permitted biostratigraphic
correlations between outcrop and well data The Acaciella australica assemblage appears to be
slightly older than 800 Ma and is restricted to the middle part of Supersequence 1 The Baicalia
burra assemblage is considered to be slightly younger than 800 Ma and occurs in the upper part
of Supersequence 1 (Grey 1996b Stevens and Grey 1997) The older A australica assemblage
is recognized in the Skates Hills Formation in the Savory Sub-basin and the stromatolite A
australica itself has been tentatively identified in the lower Tarcunyah Group The occurrence of
the A australica assemblage in the Woolnough Madley and Browne Formations of the Officer
Basin and in the Loves Creek Member of the Bitter Springs Formation of the Amadeus Basin
allows correlations throughout the Centralian Superbasin (Fig 4)
The younger B burra assemblage has not been recognized in sedimentary rocks of the
Savory Group as defined by Williams (1992) but it occurs in the upper parts of the Tarcunyah
Group and allows correlation of this group with outcrops of the Neale Formation and with the
Kanpa Formation in petroleum exploration well Hussar 1 both located in the central Officer Basin
of Western Australia (Fig 4) (Grey 1996b Stevens and Grey 1997) The occurrence of the B
burra assemblage in these units permits their correlation with the Burra Group in the Adelaide
Geosyncline of South Australia (K Grey unpublished data)
The Cornelia Formation and Kahrban Subgroup outcrop in the southeast of the sub-basin and
were considered by Williams (1992) to be part of the Mesoproterozoic Bangemall Basin Limited
evidence suggests that all or parts of these two units are of Neoproterozoic age The Ward and
Oldham Inliers consist of outcrops of the Cornelia Formation Waterbore TWB 6 which was
drilled on TRAINOR in the Cornelia Formation contains palynomorphs consistent with a
Supersequence 1 age (Grey and Stevens 1997) (Figs 5 and 6) In outcrop the Cornelia Formation
17
consists predominantly of sandstone and quartzite with lesser siltstone shale mudstone and chert
In Trainor 1 this formation consists predominantly of indurated mudstone with minor sandstone
chert and dolomite A major erosional unconformity separates the Cornelia Formation from
overlying formations and parts of the Cornelia Formation have been folded with dips exceeding
70deg In contrast the majority of the Savory Sub-basin sedimentary rocks have dips of less than 30deg
except where they are adjacent to faults The Cornelia Formation apparently consists of an older
unit of steeply dipping quartzites cherts and well-indurated mudstones and a younger unit of
shallower dipping sandstones which are sub-friable in parts However caution should be used in
interpreting the age of units based on their structural deformation and additional mapping and age
dating of this formation is required
It is proposed here that the Kahrban Subgroup is likely to be of early Neoproterozoic age and
hence should be considered as part of the greater Officer Basin This proposal is based largely on
the relatively low dip of the strata (generally less than 20deg) and their west-northwest strike which
is parallel with strikes in the overlying Brassey Range Formation of the Savory Group The lower
contact of the Kahrban Subgroup is obscured but is thought to be an unconfirmity on the
Earaheedy Basin on the southeast of STANLEY (Muhling and Brakel 1985)
Structural setting
The Savory Sub-basin forms the most northwesterly sub-basin of the Neoproterozoic to
Phanerozoic Officer Basin The western boundary of the sub-basin with the Mesoproterozoic
Bangemall Basin consists of steep-reverse and strike-slip faults The northeastern boundary of the
Savory Sub-basin was mapped where Supersequence 4 formations of the Savory Group
unconformably overlie sedimentary rocks of the Karara and Yeneena Basins with the two older
units considered to be part of the Paterson Orogen (Williams 1992) This contact was defined as a
series of steeply dipping reverse faults in the northernmost parts of the sub-basin on BALFOUR
DOWNS and RUDALL and was extrapolated as an inferred reverse fault farther along strike to the
southeast on GUNANYA and MADLEY where the contact is obscured by Cainozoic sediments It is
now recognized that all the sedimentary rocks in the Karara Basin and younger sedimentary rocks
of the Yeneena Basin are from the Supersequence 1 Tarcunyah Group and part of the greater
Officer Basin (Bagas et al 1995) The northern boundary of the Tarcunyah Group and the greater
Officer Basin is in thrust-and reverse-faulted contact with the Rudall Complex and other parts of
the Paterson Orogen (Fig 7)
To the south the sub-basin unconformably overlies the Bangemall Basin The eastern
boundary of the sub-basin used in this study is where Permian and younger strata of the Officer
Basin unconformably overlie Neoproterozoic strata although there are no significant structural or
stratigraphic differences between the Neoproterozoic units
18
The sub-basin is subdivided into three principal structural areas (Fig 1) Trainor Platform
Blake Fault and Fold Belt and Wells Foreland Sub-basin (Williams 1992) A major review of
these boundaries is beyond the scope of this report but the processing of regional aeromagnetic
data (Appendix 4) and acquisition of a semi-detailed gravity survey by the GSWA in the east of
the sub-basin has enabled these tectonic units to be reassessed and some modifications are
proposed
The Wells Foreland Sub-basin (originally termed the Wells Foreland Basin in Williams 1992)
and sedimentary rocks of the Tarcunyah Group are both considered to be the northwest
continuation of the Gibson Sub-basin of the Officer Basin Aeromagnetic gravity and outcrop
data suggest that the Blake Fault and Fold Belt is significantly faulted and folded in the west but
is less deformed in the east where the thickest sedimentary section in is located on BULLEN
(Appendix 4) The Trainor Platform is reinterpreted to represent an area of the sub-basin that has
undergone major compression during the Petermann Ranges Orogeny resulting in folding and
faulting with a northwest strike This interpretation contrasts with that proposed by Williams
(1992) who envisaged that only a thin section of the Savory Group was present on the platform
Perincek (1998) has recognized nine periods of tectonic activity in the Officer Basin from the
beginning of the Neoproterozoic to the end of the Cretaceous Three major tectonic episodes are
recognized in the Centralian Superbasin The oldest event is the Areyonga Movement which is
pre-Sturtian and forms the boundary between Supersequences 1 and 2 (Fig 4) The Souths Range
Movement occurred at the end of the Sturtian at the boundary between Supersequences 2 and 3
The youngest major event is the Petermann Ranges Orogeny which occured at the end of the
Marinoan and forms the boundary between Supersequences 3 and 4
One minor and two major tectonic episodes are recognized in the Savory Sub-basin the
LP1ALP1B structural event and the Areyonga Movement and the Petermann Ranges Orogeny
respectively The LP1ALP1B structural event is revealed where the Spearhole Formations rests
disconformably and locally unconformably on the Brassey Range Jilyili and Glass Spring
Formations The Neoproterozoic Areyonga Movement (equivalent to the Blake Movement of
Williams 1992) produced folds and faults with a general northeast strike in the western and
southern parts of the region The Souths Range Movement has not been recognized in the sub-
basin This may be due to the fact that no Sturtian glacial rocks have been identified and hence it
is possible that structures attributed to the Areyonga Movement could be the result of the Souths
Range Movement or a combination of the two movements
The major tectonic event recorded in the sub-basin is the latest Neoproterozoic to Cambrian
Petermann Ranges Orogeny (equivalent to the Paterson Orogeny) which produced large reverse
19
faults thrusts strike-slip faults and folds with a general northwest strike The McFadden
Formation and other Supersequence 4 strata are considered to be at least partially coeval with this
orogeny (Williams 1992) We also interpret the Durba Sandstone as having been deposited during
the later stages of the Petermann Ranges Orogeny as this unit mildly deformed with fold axes
parallel to the strike of other structures attributed to the Petermann Ranges Orogeny
Quantitative aeromagnetic interpretation of the Savory Sub-basin utilizing the 3D Euler
deconvolution method supported by wave-number filtering and image processing has provided
structural trends and depth to magnetic source within the sub-basin (Cowan 1995) Gravity data
are interpreted by Cowan (1995) as changes in both the density of the basement rocks andor
basement topography depending on local conditions Part of Cowanrsquos report is reproduced in
Appendix 4
Exploration history
The only petroleum exploration conducted in the sub-basin has been the recent drilling in the
western part of three diamond drillholes of which two have minor oil shows (Table 2) There has
been some mineral exploration the results of which are stored in the GSWA Western Australian
Mineral Exploration (WAMEX) database system Much of the mineral exploration was in the
southwest and west where the sub-basin is in contact with the Bangemall Basin and along the
northern margin of the sub-basin Many of these mineral exploration programs included
aeromagnetic surveys and surface geochemical sampling (Fig 8)
Hydrocarbon potential
The sub-basin contains a sedimentary succession up to 8 km thick which is generally gently
folded and faulted and apparently unmetamorphosed Limited drilling has shown that thick
mudstones are present in the sub-basin with some mudstones in Trainor 1 having high Total
Organic Carbon (TOC) values Outcrops of sub-friable sandstones in many of the formations
within the sub-basin suggests widespread reservoir potential Mudstone and inferred thick
evaporite sequences are likely to form seals Maturity data suggest that near-surface samples are
approximately at the base of the oil window and top of the gas window in parts of the north and
southeast of the sub-basin However parts of the southwest of the sub-basin and the mudstones in
Trainor 1 have very high levels of maturity Numerous faults and folds have been identified from
surface mapping suggesting good potential for large structural traps Minor oil shows in
20
Table 2 Neoproterozoic formations and hydrocarbon shows in diamond drillholes in the Savory Sub-basin
Drillhole AMG Core TD (m) Approx Formation Depth Formation Depth Formation Depth Shows (AGD84) start (m) GL (m) (m) (m) (m)
LDDH 1 431148E 112 701 350 Tarcunyah 68ndash701 ndash ndash bitumen at 6623 m 7443826N Group Trainor 1 473640E 6 709 455 McFadden 9ndash83 Cornelia Fm 83ndash709 possible bitumen at 4537 m 7287400N Fm Mundadjini 1 319056E 170 600 500 Mundadjini 16ndash361 Spearhole Fm 361ndash600 10 fluorescence at 36102 m 7404844N Fm Boondawari 1 348959E 299 1 367 490 Mundadjini Fm 15ndash312 Spearhole Fm 312ndash1 283 Intrusive 1 283ndash1 367 40 fluorescence at 35364 m 5 7398174N fluorescence at 4963 m Akubra 1 334249E 15 181 530 Mundadjini 15ndash42 Intrusive 42ndash181 None 7401252N Fm
21
50 km
120deg 121deg30 123deg
25deg
24deg
23deg
22deg
Greater Officer Basin
Savory Sub-basin
1
2
3
4
6
8
3 Seismic line (prefixed N83-00)
Aeromagnetic survey
GS
WA
Sav
ory
1995
gra
vity
sur
vey
Gravity survey
MKS34270398
Figure 8 Locations of aeromagnetic and gravity surveys (other than regional BMRAGSO data)
22
sandstones in two petroleum wells in the northwest of the sub-basin and bitumen and oil shows
elsewhere in the region indicate that oil has been generated and migrated through the sub-basin
Source rocks
Source potential is considered to be the major exploration risk in the Savory Sub-basin although
minor oil shows in Mundadjini 1 and Boondawari 1 indicate that at least some oil has been
generated and migrated into potential reservoirs within the sub-basin Sandstone is the
predominant lithology observed in outcrop Outcrops of fine-grained lithologies in the basin are
rare because of intense surface weathering and erosion Only about 8 of the surface area of the
sub-basin is exposed bedrock and recessive lithologies (such as shale evaporite and friable
sandstone) may be present although they rarely outcrop
Outcrops of stromatolitic dolomite with associated cauliflower chert and cubic pseudomorphs
interpreted as being after halite indicate that evaporitic environments are present within the
Mundadjini Skates Hills and Boondawari Formations Evaporitic minerals are also present in
drillhole LDDH1 in the Tarcunyah Group
In 1995 GSWA drilled a continuous-core diamond drillhole (Trainor 1) in the sub-basin on
TRAINOR to a depth of 709 m to test for source rocks thus providing the first such data for the sub-
basin The drillhole intersected flat-lying clastics and carbonates of the McFadden Formation (9ndash
83 m) overlying indurated mudstones of the Cornelia Formation (83ndash709 m total depth) dipping at
about 40deg Of the six samples analysed from the Cornelia Formation in this drillhole the five
located between 375 and 6032 m depth have TOC values exceeding 05 (range 066ndash365)
Rock-Eval pyrolysis of these five samples indicates that they are at best in the dry-gas thermal
stage and as a result of their high level of maturation (Stevens and Adamides in prep) have poor
remaining hydrocarbon-generating potential Although the Cornelia Formation is overmature at
Trainor 1 the high TOC values are encouraging as it is likely that this sequence is less mature
elsewhere in the sub-basin
The Mundadjini Formation contains potential source rocks that comprise marine mudstones
with evaporitic minerals present in parts Thin dark mudstones were intersected in the Mundadjini
Formation in Akubra 1 In Mundadjini 1 and Boondawari 1 however the mudstones appear to be
too oxidized to have source potential
The Boondawari Formation also may be a source rock as it contains black mudstones The
unit is laterally equivalent to the Pertatataka Formation of the Amadeus Basin and the Ungoolya
23
Group of the Officer Basin in South Australia both of which have some source potential
(Summons and Powell 1991 Morton and Drexel 1997) Samples from the Dey Dey Mudstone of
the Ungoolya Group generally have poor TOC values (average 011 range 003ndash081)
moderate hydrogen index (HI) values (100ndash382) and poor to fair genetic potential with a
maximum of 292 kg hydrocarbon per tonne of source rock (Morton and Drexel 1997)
Stromatolitic dolomites and mudstones at the top of the Boondawari Formation and within the
Skates Hills Formation are potential source rocks Stromatolitic dolomite and evaporitic rocks
deposited in a marginal marine to sabkha environment are considered to have good potential to
generate and preserve organic carbon without requiring a deep-water setting (Stevens and Grey
1997) Such conditions are recognized in the Skates Hills Formation and in the upper parts of the
Tarcunyah Group
Maturity
Knowledge of the maturity of sedimentary rocks within the Savory Sub-basin is still limited From
a review of palynological studies Grey and Stevens (1997) report that the thermal maturity
inferred from the Thermal Alteration Index (TAI) of 3+ from Supersequence 1 age palynomorphs
in TWB 6 TWB 9 and LDDH1 is within the hydrocarbon window (Appendix 3) In Phanerozoic
spores and pollen a TAI of 3+ approximately equates to the end of liquid petroleum generation
and the start of dry gas generation and to a vitrinite reflectance of about 13 (Traverse 1988)
However the use of TAI for estimating thermal maturity from Neoproterozoic palynomorphs
requires calibration
In Trainor 1 the Cornelia Formation contains organically rich claystones between 375 and
6032 m depth Based on Rock-Eval maturity data (Stevens and Adamides in prep) and the dark
colour of poorly preserved organic material (Grey 1995de 1996) with TAI 4- to 5 all samples
had a high level of maturation with at best dry-gas generating potential remaining In contrast
drillhole LDDH1 on GUNANYA recorded lower levels of maturity (TAI values of 3+) with two of
sixteen samples from the Tarcunyah Group having greater than 1 TOC (Grey 1995abc Grey
and Cotter 1996) Organic petrology and Rock-Eval maturity data for samples from LDDH1
indicate that the section above 500 m is within the oil-generative window whereas below 500 m
the rocks are within the gas window (Ghori in prep Fig 9 Appendix 5)
Waterbores TWB 1 2 6 and 9 which are located on TRAINOR in the southeast of the sub-
basin all had organic matter with TAI values of 3+ from the McFadden Skates Hills Cornelia
and Brassey Range Formations respectively
24
100
200
300
400
500
600
700
Oil
gene
ratin
g
Gas
gene
ratin
g
Fai
r
Fai
r
Poo
r
Poo
r
Goo
d
Imm
atur
e
Oil
win
dow
Oil
win
dow
Imm
atur
e
01 0110 10 0 150 300 440 480 1
Neo
prot
eroz
oic
TOC S1+S2 mgg Hydrogen Index Tmax degC
Depth(m)
Organicrichness
Generatingpotential
Kerogentype Maturity Maturity
TD=701m
Sandstone
Mudstone
Dolomite
Limestone
Evaporite
Source rock
MKS40 070498
Ro equivalent
Figure 9 Petroleum source potential of rocks in Normandy LDDH1
Small amounts of organic matter associated with basalt and dolerite in cuttings from
waterbore BWB 1 on BULLEN showed high levels of thermal maturity (Grey 1995a Libby 1995)
It is unclear whether all sedimentary rocks on BULLEN are overmature for hydrocarbon generation
or the results from BWB 1 are related to local heating events associated with the volcanic bodies
that are common in the Jilyili Formation
25
Reservoirs
Each of the five depositional sequences of the Savory Group (Table 1) are inferred to contain
significant sandstone reservoirs with the possible exception of depositional sequence C as
discussed above in Stratigraphy The Spearhole Formation was cored in Mundadjini 1 and
Boondawari 1 and visual estimates of porosity vary from generally poor (less than 5) to fair
(approximately 5ndash15) The McFadden Formation in Trainor 1 has porosity values of up to 232
and a maximum permeability of 195 md (Stevens and Adamides in prep) Sandstones from
Neoproterozoic formations form the acquifers in the following waterbores the McFadden
Formation in TWB 1 the Cornelia Formation in TWB 6 and the Brassey Range Formation in
TWB 8 and TWB 9 (Appendix 6 Table 61)
Based on outcrop observations the Durba Sandstone is considered to be the best reservoir of
the Savory Group Similarly some sandstones from the Tarcunyah Group also have good visible
porosity in outcrop
Dolomites occur in several formations in the sub-basin Reservoir potential may exist
particularly where the dolomites are stromatolitic and oolitic However dolomites have not been
drilled in the sub-basin and porosity can only be inferred from the preferential silicification of
some stromatolite bioherms observed in outcrop (Stevens and Grey 1997) Elsewhere in the
Officer Basin porosities of up to10 have been measured in dolomites A limestone breccia
(karst) is described from 663 to 677 m in drillhole LDDH1 (Fig 6 Busbridge 1994)
Seals
Indications of evaporitic environments in the Mundadjini Skates Hills and Boondawari
Formations are described by Williams (1992) In Mundadjini 1 from 287 to 337 m anhydrite and
chert occurs as nodules beds and veins in mudstone of the Mundadjini Formation Evaporitic
minerals (predominantly gypsum) are described in the Tarcunyah Group in LDDH1 The presence
of the Woolnough and Madley salt diapirs in the Officer Basin (approximately 110 km east of the
sub-basin) and halite beds over 25 m thick in the well Hussar 1 (130 km east of the sub-basin)
provide further evidence that evaporite seals may be present in the Savory Sub-basin
Mudstones and shales form only a small proportion of the limited Neoproterozoic outcrop in
the sub-basin but significant thicknesses of mudstone were encountered in the Mundadjini
Formation in Mundadjini 1 and Boondawari 1 the Tarcunyah Group in LDDH1 and in the
26
Cornelia Formation in Trainor 1 These data suggest that mudstones form a significant proportion
of strata in the sub-basin despite their limited outcrop
Traps
Potential structural closures including folds and faults occur at various scales throughout the
Savory Sub-basin However the region has only been mapped at 1250 000 scale and
independently closed structures such as domes have yet to be confirmed The western margin of
the basin contains abundant faults (with a northeast strike) but elsewhere faults are less common
Some anticlines are recognized in outcrop including one with a strike length of up to 45 km
inferred from surface bedding dips in the Mundadjini and Spearhole Formations at approximately
24deg15rsquoS 121deg10rsquoE on BULLEN (Fig 1)
Salt diapirs and other halokinetic structures are recognized in outcrop well and seismic data
in the Officer Basin to the west of the Savory Sub-basin and it is probable that there are
significant thicknesses of evaporitic sedimentary rocks in the sub-basin The gravity field data
suggest there is good potential for salt diapirs and traps related to halokinesis
Although there is potential for stratigraphic traps to be present in the sub-basin insufficient
data are available to assess them
Preservation of hydrocarbons
The range of thermal maturities measured to date and the large periods of time envisaged for
deposition of sediments implies hydrocarbon generation may have occurred a number of times
during the evolution of the Savory Sub-basin Any hydrocarbons that were generated early may
have been trapped in palaeostructures and remigration to younger traps could have taken place
later The Petermann Ranges Orogeny which has been equated with the Paterson Orogeny (Myers
1990) is believed to have occurred in the latest Neoproterozoic to early Cambrian This is the last
major tectonic event recognized in the sub-basin suggesting that it is reasonable to expect that trap
integrity will have been preserved
If the inference of the presence of thick halite beds in the sub-basin is correct the preservation
potential of sub-salt traps should be excellent
27
Reported hydrocarbon shows and oil seep
Amadeus Petroleum recorded minor oil shows in cores from Mundadjini 1 and Boondawari 1 In
Mundadjini 1 at 36102 m (top of the Spearhole Formation) a 3 mm thick zone had 10 moderate
white fluorescence with slow solvent cut This show was in a granular sandstone with visually
estimated porosity of about 10 In Boondawari 1 at 35364 m (within the Spearhole Formation) a
broken surface of sandstone had 40 moderate yellow-white fluorescence with slow solvent cut
Visually estimated porosity is about 5 Because the fluorescing surface was broken during the
drilling process this show could have resulted from contamination A second show occurs in
Boondawari 1 at 4963 m (within the Spearhole Formation) where a 1 cm-thick zone had 5 dull
yellow fluorescence with slow solvent cut in a conglomerate with visually estimated porosity of
about 10 The company intends to further investigate the nature of these occurrences
Minor bitumen is present at 6623 m in drillhole LDDH1 on GUNANYA (Figs 5 and 6) as a
vein in mudstones of the Tarcunyah Group A sample was analysed by gas chromatography
(Ghori in prep) and confirmed that it is natural bitumen (Appendix 5)
Mineral hole OD 23 drilled by Jubilee Gold Mines NL on NABBERU in the Bangemall Basin
immediately to the south of the Savory Sub-basin (Fig 5) encountered bitumen and trace oil in
vugs in dolomite (M Stevens unpublished data) but no further data are available at present
In their popular guide to the Canning Stock Route Gard and Gard (1990 p 218) refer to an
oil seep at Well 13 on TRAINOR (Fig 5) They reported that between 1977 and 1984 lsquonatural oilrsquo
was seen in the well Although the well is now largely filled with sediment four auger drill
samples were collected by the GSWA in 1995 and all four were analysed for oil shows One
sample from 315 m total depth (GSWA sample 135604) yielded just enough extract (519 ppm)
for saturate gas chromatography analysis The gas chromatograph (Appendix 5) shows that the
extract does contain some hydrocarbons probably from recent plant material Because the depth to
the oil was not quoted in Gard and Gard (1990) the hand-augered well may not have been deep
enough to properly test this reported seep
Geological and geophysical databases
Geological and geophysical data available for the Savory Sub-basin are limited The most recently
completed geological maps for the sub-basin were published by the GSWA between 1991 and
1995 (Williams and Tyler 1991 Williams 1992 1995ab)
28
The cores from the five drillholes listed in Table 2 believed to be all of the core available
from the sub-basin are available for inspection at GSWA Mineral exploration reports submitted
to GSWA may be searched using the WAMEX database and open-file reports are available on
microfiche Geophysical data acquired by the mining industry is not required to be filed with
GSWA if acquired over Vacant Crown Land which is the case for much of the sub-basin
Geophysical survey data submitted in mining tenement reports and which extend into Vacant
Crown Land remain confidential to the companies Original regional aeromagnetic and gravity
datasets are available from the Australian Geological Survey Organisation (AGSO)
Data pertinent to oil exploration in the sub-basin such as structural style and salt diapirism
are presented in a review of the hydrocarbon prospectivity of the Officer Basin (Perincek 1998)
Drilling
Significant drillholes in the sub-basin are summarized in Table 2
Petroleum industry data
Amadeus Petroleum drilled three petroleum exploration wells in the central west of the Savory
Sub-basin in late 1997 These wells Mundadjini 1 Boondawari 1 and Akubra 1 were drilled by
continuous diamond coring (Figs 5 and 6) All targeted potential reservoirs within the Spearhole
Formation with the Mundadjini Formation as the proposed seal The wells were located on
structures interpreted from Landsat images and limited geological investigations Both Mundadjini
1 and Boondawari 1 had minor oil shows as discussed above (Reported hydrocarbon shows)
Government data
Stratigraphic drillhole Trainor 1 was drilled by GSWA in 1995 (Stevens and Adamides in prep)
and the main results are discussed above (Source rocks and Maturity)
Mineral industry data
Normandy Exploration drillhole LDDH1 was cored in the Tarcunyah Group to a total depth of
701 m and provided source-rock and maturity data as discussed above
29
Oilmin NL drilled six percussion drillholes (BD 1 3 4 5 8 and 9) through sandstones and
shales in the northern part of the Savory Sub-basin to a maximum depth of 198 m (Fig 5
WAMEX Microfiche File M 26811 I 2610) but only brief geological descriptions are available
Hydrogeological data
Hydrogeological data within the Savory Sub-basin are limited although a long history of water
exploration extends back to the construction of the Canning Stock Route early this century No
detailed geological or wireline logs are available for the older wells along this route A few station
wells have been drilled by various methods on the south and west margins of the basin but data
are unavailable as reports are not required to be filed with the government Depth to watertable
throughout the basin is largely controlled by porosity of the bedrock
The GSWA drilled fifteen waterbores in the winter of 1995 in the southern part of the sub-
basin in preparation for the drilling of Trainor 1 and the proposed Bullen 1 Twelve bores found
water and six of these bores have salinities of less than 1000 mgL (Fig 5 Appendix 6 Table 61)
One waterbore TWB 6 has gamma ray and neutron logs run through PVC casing and these are
available from the GSWA with the digital log data included herein
Seismic data
No geophysical data have been acquired by the petroleum industry in the Savory Sub-basin
Seismic data acquired in the Officer Basin to the east particularly in the Gibson and Yowalga
Sub-basins is pertinent to structural interpretation in the Savory Sub-basin (Perincek 1996a
1998)
Aeromagnetic surveys
Government data
There are over 95 277 line kilometres of aeromagnetic data included in the AGSO dataset There
are three regional aeromagnetic surveys covering the Savory Sub-basin These were flown by the
Bureau of Mineral Resources (BMR now AGSO) in 1984 at a line spacing of 1500 m with 36 740
and 52 587 line kilometres flown and by Aerodata in 1984 at a line spacing of 1000m with 5950
line kilometres flown These data were reprocessed and interpreted for GSWA by Cowan (1995)
An edited copy of this report is included as Appendix 4 and the original report is filed in the
GSWA Library under S-series reports item 10331
30
Mineral industry data
The approximate locations of non-AGSO aeromagnetic surveys are shown in Figure 8 More
detailed information regarding the location of these surveys may be obtained using the GSWA
MAGCAT II database Additional information such as contours of aeromagnetic values may be
obtained by inspecting items on file with the GSWA
Gravity surveys
Government data
The average spacing for gravity data in the Savory Sub-basin is one station per 121 km2 (11 times 11
km grid) These data were principally collected by BMR in the early 1960s There are a few
additional regional gravity traverses across the sub-basin which are also included in the
BMRAGSO dataset These data were reprocessed and interpreted for GSWA (Fig 10) and a
report on this work is also included in Appendix 4
The GSWA completed a large semi-detailed gravity survey in the eastern Savory Sub-basin
utilizing helicopter support and Differential Global Positioning Survey (DGPS) techniques (Fig
8) This gravity survey completed in August 1995 consists of 2300 gravity stations on a 2 times 3 km
grid All stations were acquired by helicopter using Scintrex gravimeters and Ashtek dual
frequency DGPS equipment for determining location This highly efficient system allowed the
acquisition of more than 100 gravity stations per day in remote areas The resolution of this survey
is +30 cm and +05 microms-2 (Daishsat 1995) These data (Fig 11) represent a significant
improvement on the previous regional survey data and are available from GSWA (GSWA
1996ab) The results of the interpretation of these data were presented at the 1997 ASEG
Convention (Carlsen and Shevchenko 1997)
Mineral industry data
Three small gravity surveys were conducted by Oilmin NL (Fig 8) and the relevant WAMEX
reports are M 2681I 2610 I 2435 I 2567 These three surveys are of limited value because height
control was provided by barometers only and the surveys were not tied to the national gravity grid
31
23deg
25deg
120deg 122deg
Trainor 1
SAVORY
SUB-BASIN
MKS54 160498
100 km
1995 SavoryGravity Survey
254
-1056
micromsec2
Figure 10 Regional Bouguer gravity map of the Savory Sub-basin
23deg
24deg
25deg
122deg30 123deg
TRAINOR 1
123deg30
50 km
MKS53 160498
-116
-626
micro msec2
Figure11 Detailed Bouguer gravity map of the
Savory 1995 Gravity Survey from the eastern Savory Sub-basin
32
Government and academic reports
Chronostratigraphy and geochemistry
The understanding of Neoproterozoic organic chemistry palynology and structural evolution is
essential to the interpretation of hydrocarbon prospectivity Pertinent reports are included in the
bibliography (Appendix 1) Unpublished palaeontology reports describe the palynology of wells in
the Savory Sub-basin (Grey 1995andashe 1996a) Grey and Cotter (1996) discussed the potential for
Neoproterozoic palynomorphs to provide a biostratigraphic framework and palaeoenvironmental
interpretation Grey and Stevens (1997) reviewed the results of palynological studies of wells
drilled in the sub-basin and reported that Supersequence 1 palynomorphs are present in TWB 6
TWB 9 and LDDH1 (Appendix 3) Grey (1996b) reported on the use of stromatolites for
correlation in the Neoproterozoic and Stevens and Grey (1997) discussed the application of
stromatolite biostratigraphy in correlating isolated dolomite outcrops in the sub-basin with well
and seismic data in the Officer Basin and Centralian Superbasin
Although geochemical data from the Savory Sub-basin are very limited results mostly
confirm thermal maturities inferred from TAI for LDDH1 and Trainor 1 (Ghori in prep Stevens
and Adamides in prep) Those parts of the Officer Basin in Western Australia which lie to the
east of the Savory Sub-basin are sparsely drilled but Ghori (in prep) reports that most of the
Neoproterozoic succession presently lies within the oil-generative window However his study
has been unable to identify effective source-rock units and the source for oil shows Thin source
rocks are present in the Neoproterozoic in LDDH1 (Fig 9) and in three wells which lie to the east
and southeast of the Savory Sub-basin namely NJD 1 Kanpa 1A and Yowalga 3
Proposed work program
From the above limited information it is concluded that additional research on the hydrocarbon
potential of the sub-basin is justified and proposals are outlined below
bull Additional modelling of gravity and aeromagnetic data from the Savory Sub-basin is required
in light of the results from Trainor 1 and Boondawari 1 Trainor 1 showed that what appeared
to be a structurally simple area based on outcrop aeromagnetic and gravity data was in fact an
area of major structuring Boondawari 1 intersected a dolerite which is in good depth
agreement with aeromagnetic depth to source results showing this technique is useful in
detecting the depth to intrusive bodies
33
bull Additional data from mineral and petroleum exploration bores may become available and
analysis of samples from these wells should be undertaken and interpreted in the context of
their relevance to the Officer Basin
bull Stratigraphic coring in the Blake Fault and Fold Belt and in the Wells Foreland Sub-basin (Fig
1) targeting source rocks is considered essential to the continuing evaluation of the
hydrocarbon prospectivity of the Savory Sub-basin
bull Correlations using at least outcrop well and potential-field data should be prepared to link the
sub-basin with the better known parts of the Officer Basin to the east
bull Remapping is required to clarify boundary positions within the Cornelia Formation this may
resolve some of the current problems of the relationship between this unit and the rest of the
Savory Sub-basin
bull Further work is required to explain the Early Cambrian or Sturtian ages interpreted for the
Cornelia Formation from sedimentary zircon UndashPb dating in drillhole Trainor 1 The
determination of the age of the organically rich but overmature claystones in this well is
critical to assessing the hydrocarbon potential of the region
bull The thin dark mudstones intersected by Akubra 1 in the Mundadjini Formation warrant
geochemical analysis Analyses of the oil shows in Mundadjini 1 and Boondawari 1 are
currently being undertaken by Amadeus Petroleum
bull Geochemical analysis of hydrocarbons in the Bangemall Basin drillhole OD23 has been
performed by Jubilee Gold and the results will be reviewed when they are submitted to
GSWA The possibility of source rocks within the Bangemall Basin charging traps within the
Bangemall Basin and the overlying Savory Sub-basin requires further investigation
Conclusions
The Savory Sub-basin is a frontier region with only three recently drilled petroleum exploration
wells and no seismic data Based on existing geological and geophysical data it is considered too
early to draw conclusions about the hydrocarbon prospectivity of the sub-basin at this stage and
there are several reasons why the area warrants further investigation
34
1 Thick accumulations of sedimentary rocks are present (up to 8 km thickness inferred) which
may contain source reservoir and sealing strata
2 Minor oil shows occur in Mundadjini 1 and Boondawari 1 and bitumen is present in mineral
exploration drillhole LDDH1 suggesting that hydrocarbons have migrated within the
Neoproterozoic sequence of the Savory Sub-basin Oil and bitumen are present in mineral
exploration drillhole OD23 in the Bangemall Basin immediately to the south of the Savory
Sub-basin and it is possible that source rocks from the Bangemall Basin could charge traps in
the overlying Savory Sub-basin
3 The age of sedimentary rocks in the sub-basin is still poorly constrained but some of the
Neoproterozoic sedimentary rocks located on GUNANYA and TRAINOR are within the
hydrocarbon-generation window It is possible that a significant thickness of Phanerozoic
sedimentary rocks may also be present
4 Friable sandstones with visible porosity outcrop extensively suggesting numerous potential
reservoirs
5 Significant but not intense faulting and folding has been mapped implying large structural
traps may be present
6 Evaporitic sedimentary rocks occur in several formations and may provide good source rocks
and excellent seals
35
References
APAK S N and CARLSEN G M 1997 A compilation and review of data pertaining to the
hydrocarbon prospectivity of the Canning Basin Western Australia Geological Survey
Record 199610 103p
BAGAS L GREY K and WILLIAMS I R 1995 Reappraisal of the Paterson Orogen and
Savory Basin Western Australia Geological Survey Annual Review 1994ndash95 p 55ndash63
BUSBRIDGE M 1994 Lake Disappointment Exploration Licence 451064 Third Annual
Report Lake Disappointment Diamond Drill Hole LDDH1 Normandy Exploration Limited
Western Australia Geological Survey M-series Item 7567 A41358 (unpublished)
CARLSEN G M and SHEVCHENKO S I 1997 Petroleum exploration in Proterozoic basins
using potential fields data and stratigraphic coring Australian Society of Exploration
Geophysicists 12th Geophysical Conference Handbook Sydney 1997 Preview no 66 p 83
(abstract only)
COWAN D 1995 Savory Basin quantitative magnetic interpretation Western Australia
Geological Survey S-series S10331 (unpublished)
DAISHSAT PTY LTD 1995 Operational and processing report Savory Basin gravity survey
Western Australia Geological Survey S-series S10332 (unpublished)
GARD E and GARD R 1990 Canning Stock Route a travellerrsquos guide for a journey through
history Perth Western Australia Western Desert Guides 448p
GEOLOGICAL SURVEY OF WESTERN AUSTRALIA 1996a Savory Basin first vertical
derivative of Bouguer gravity image 1250 000 Western Australia Geological Survey
GEOLOGICAL SURVEY OF WESTERN AUSTRALIA 1996b Savory Basin Bouguer gravity
image 1250 000 Western Australia Geological Survey
GHORI K A R in prep Petroleum source rock potential and thermal history Officer Basin
Western Australia Western Australia Geological Survey Record
36
GREY K 1995a Savory Basin drillhole BWB 1 (Bullen waterbore) palynology and thermal
maturation GSWA Palaeontology Report no 199512 (unpublished)
GREY K 1995b Savory Basin drillholes TWB 1 2 6 9 (Trainor waterbores) palynology and
thermal maturation GSWA Palaeontology Report no 199520 (unpublished)
GREY K 1995c Palynology of Normandy-Poseidon Lake Disappointment-1 corehole
Tarcunyah Group Paterson Orogen GSWA Palaeontology Report no 199521 (unpublished)
GREY K 1995d Savory Basin drillhole Trainor 1 (Trainor diamond drilling) palynology and
thermal maturity GSWA Palaeontology Report no 199524 (unpublished)
GREY K 1995e Savory Basin drillhole Trainor 1 (Trainor diamond drilling) Additional
Preparation of two samples GSWA Palaeontology Report no 199528 (unpublished)
GREY K 1995f Neoproterozoic stromatolites from the Skates Hills Formation Savory Basin
Western Australia and a review of the distribution of Acaciella australica Australian Journal
of Earth Sciences v 42 p 123ndash132
GREY K 1996a Savory Basin drillhole Trainor 1 (Trainor diamond drilling) Additional
samples palynology and thermal maturation GSWA Palaeontology Report no 199615
(unpublished)
GREY K 1996b Preliminary stromatolite correlations for the Neoproterozoic of the Officer
Basin and a review of Australia-wide correlations GSWA Palaeontology Report no 199615
(unpublished)
GREY K and COTTER K L 1996 Palynology in the search for Proterozoic hydrocarbons
Western Australia Geological Survey Annual Review for 1995ndash96 p 70ndash80
GREY K and STEVENS M K 1997 Neoproterozoic palynomorphs of the Savory Sub-basin
Western Australia and their relevance to petroleum exploration Western Australia
Geological Survey Annual Review for 1996ndash97 p 49ndash54
HUBBARD R J PAPE J and ROBERTS D G 1985 Depositional sequence mapping as a
technique to establish tectonic and stratigraphic framework and evaluate hydrocarbon
potential on a passive continental margin in Seismic stratigraphy II an integrated approach
37
edited by O R BERG and D G WOOLVERTON American Association of Petroleum
Geologists Memoir 39 p 79ndash91
LIBBY WG 1995 A petrological report on six samples of bore cuttings from the Savory Basin
Western Australia Western Australia Geological Survey S-series S31307 (unpublished)
MORTON JGG and DREXEL JF 1997 The petroleum geology of South Australia Vol 3
Officer Basin South Australia Department of Mines and Energy Resources Report Book
9719
MUHLING P C and BRAKEL A T 1985 Geology of the Bangemall Group mdash the evolution
of an intracratonic Proterozoic basin Western Australia Geological Survey Bulletin 128
219p
MYERS J S 1990 Precambrian tectonic evolution of part of Gondwana southwestern Australia
Geology v18 p 537ndash540
NELSON D R 1997 Compilation of SHRIMP UndashPb zircon data Western Australia Geological
Survey Record 19972 196p
PAYTON C E 1977 Seismic stratigraphy mdash applications to hydrocarbon exploration
American Association of Petroleum Geologists Memoir 26 516p
PERINCEK D 1996a The age of NeoproterozoicndashPalaeozoic sediments within the Officer Basin
of the Centralian Super-basin can be constrained by major sequence-bounding unconformities
APPEA Journal v 36 pt 1 p 350ndash368
PERINCEK D 1996b The stratigraphic and structural development of the Officer Basin
Western Australia a review Western Australia Geological Survey Annual Review 1995ndash
1996 p 135ndash148
PERINCEK D 1998 A compilation and review of data pertaining to the hydrocarbon
prospectivity of the Officer Basin Western Australia Geological Survey Record 19976
POSAMENTIER H W JERSEY M T and VAIL P R 1988 Eustatic controls on clastic
deposition 1 mdash Conceptual framework in Sea-level changes an integrated approach edited by
C K WILGUS B S HASTINGS C G St C KENDALL H W POSAMENTIER
38
C A ROSS and J C VAN WAGONER Society of Economic Paleontologists and
Mineralogists Special Publication no 42
STEVENS M K and ADAMIDES N G in prep GSWA Trainor 1 well completion report
Savory Sub-basin Officer Basin Western Australia with notes on petroleum and mineral
potential Western Australia Geological Survey Record 199612
STEVENS M K and GREY K 1997 Skates Hills Formation and Tarcunyah Group Officer
Basin mdash carbonate cycles stratigraphic position and hydrocarbon prospectivity Western
Australia Geological Survey Annual Review for 1996ndash97 p 55ndash60
SUMMONS RE and POWELL C McA 1991 Petroleum source rocks of the Amadeus Basin
in Geological and geophysical studies in the Amadeus Basin central Australia edited by R J
KORSCH and JM KENNARD Australia BMR Geology and Geophysics Bulletin 236
TRAVERSE A 1988 Palaeopalynology Boston Unwin Hyman 600p
VAIL P R MITCHUM R M Jr TODD R G WIDMIER J M THOMPSON S III
SANGREE J B BUBB J N and HATLELID W G 1977 Seismic stratigraphy and
global changes of sea level in Seismic stratigraphy mdash applications to hydrocarbon
exploration edited by C E PAYTON American Association of Petroleum Geologists
Memoir 26 516p
WALTER M R and GORTER J 1994 The Neoproterozoic Centralian Superbasin in Western
Australia the Savory and Officer Basins in The sedimentary basins of Western Australia
edited by P G PURCELL and R R PURCELL Petroleum Exploration Society of Australia
Symposium Perth WA 1994 Proceedings p851ndash864
WALTER M R GREY K WILLIAMS I R and CALVER C R 1994 Stratigraphy of the
Neoproterozoic to early Palaeozoic Savory Basin and correlation with the Amadeus and
Officer Basins Australian Journal of Earth Sciences v 41 p 533ndash546
WALTER M R VEEVERS J J CALVER C R and GREY K 1995 Neoproterozoic
stratigraphy of the Centralian Superbasin Australia Precambrian Research v 73 p 173ndash195
WILLIAMS I R 1992 Geology of the Savory Basin Western Australia Western Australia
Geological Survey Bulletin 141 115p
39
WILLIAMS I R 1995a Bullen WA (2nd Edition) Western Australia Geological Survey
1250 000 Geological Series Explanatory Notes 23p
WILLIAMS I R 1995b Trainor WA (2nd Edition) Western Australia Geological Survey
1250 000 Geological Series Explanatory Notes 31p
WILLIAMS I R and TYLER I M 1991 Robertson WA (2nd edition) Western Australia
Geological Survey 1250 000 Geological Series Explanatory Notes 36p
40
41
Appendix 1
Bibliography
Reports which are relevant to this investigation but which are not specifically cited are listed
below
BAILLIE P W POWELL C McA LI Z X and RYALL A M 1994 The tectonic
framework of Western Australiarsquos Neoproterozoic to recent sedimentary basins in The
sedimentary basins of Western Australia edited by P G PURCELL and R R PURCELL
Petroleum Exploration Society of Australia Symposium Perth WA 1994 Proceedings p
45ndash62
BRADSHAW M T BRADSHAW J MURRAY A P NEEDHAM D J SPENCER L
SUMMONS R E WILMOT J and WINN S 1994 Petroleum systems in West Australian
basins in The sedimentary basins of Western Australia edited by P G PURCELL and R R
PURCELL Petroleum Exploration Society of Australia Symposium Perth WA 1994
Proceedings p 93ndash118
CLARKE G L 1991 Proterozoic tectonic reworking in the Rudall Complex Western Australia
Australian Journal of Earth Science v38 p 31ndash44
COCKBAIN A E and HOCKING R M 1990 Phanerozoic in Geology and mineral resources
of Western Australia Western Australia Geological Survey Memoir 3 p 750ndash755
ETHERIDGE M and WALL V 1994 Tectonic and structural evolution of the Australian
Proterozoic 12th Australian Geological Convention Geological Society of Australia
Abstracts no 37 p 102ndash103
GOODE A D T 1981 Proterozoic geology of Western Australia in Precambrian of the
Southern Hemisphere Developments in Precambrian geology 2 edited by I R HUNTER
Amsterdam Elsevier p 105ndash203
GREY K and JACKSON M J 1983 A re-assessment of stromatolite evidence for the
correlation of the Late Proterozoic Neale and Ilma Beds Officer Basin Western Australia
Australia BMR Journal of Australian Geology and Geophysics v 8 p 359
42
HICKMAN A H WILLIAMS I R and BAGAS L 1994 Proterozoic geology and
mineralization of the TelferndashRudall region Paterson Orogen Geological Society of Australia
(WA Division) Excursion Guidebook no 5 56p
HOCKING R M MORY A J and WILLIAMS I R 1994 An atlas of Neoproterozoic and
Phanerozoic basins of Western Australia in The sedimentary basins of Western Australia
edited by P G PURCELL and R R PURCELL Petroleum Exploration Society of Australia
Symposium Perth WA 1994 Proceedings p 21ndash 44
JACKSON P R 1966 Geology and review of exploration Officer Basin Western Australia
Hunt Oil Company Western Australia Geological Survey S-series S26 (unpublished)
JACKSON M J 1971 Notes on a geological reconnaissance of the Officer Basin Western
Australia Australia BMR Geology and Geophysics Record 19715 30p
JACKSON M J and van de GRAAFF W J E 1981 Geology of the Officer Basin Western
Australia Australia BMR Geology and Geophysics Bulletin 206 102 p
LOWRY D C JACKSON M J van de GRAAFF W J E and KENNEWELL P J 1971
Preliminary result of geological mapping in the Officer Basin Western Australia Western
Australia Geological Survey Annual Report for 1971 p 50ndash56
MYERS J S 1990 Precambrian in Geology and mineral resources of Western Australia
Western Australia Geological Survey Memoir 3 p 737ndash750
MYERS J S SHAW R D and TYLER I M 1994 Proterozoic tectonic evolution of
Australia 12th Australian Geological Convention Geological Society of Australia Abstracts
no 37 p 312
NEDIN C and JENKINS R J F 1991 Re-evaluation of unconformities separating the
lsquoEdiacaranrsquo and Cambrian systems South Australia Palaios v 6 p 102ndash108
PHILLIPS B J JAMES A W and PHILIP G M 1985 The geology and hydrocarbon
potential of the north-western Officer Basin APEA Journal 25 (1) p 52ndash61
POWELL C McA LI Z X McELHINNY M W MEERT J G and PARK J K 1993
Paleomagnetic constraints on timing of the Neoproterozoic breakup of Rodinia and Cambrian
formation of Gondwana Geology v 21 p 889ndash892
43
POWELL C McA PREISS W V GATEHOUSE C G KRAPEZ B and LI Z X 1994
South Australian record of a Rodinian epicontinental basin and its mid-Neoproterozoic
breakup to form the Palaeo-Pacific Ocean Tectonophysics v 237 no 3ndash4 p 113ndash140
PREISS W V 1976 Proterozoic stromatolites from the Nabberu and Officer Basins Western
Australia and their biostratigraphic significance South Australia Geological Survey Report
of Investigations no 47 p 1ndash51
TOWNSON W G 1985 The subsurface geology of the western Officer Basin mdash results of
Shellrsquos 1980ndash1984 petroleum exploration campaign APEA Journal v 25 (1) p 34ndash51
WATTS K J 1982 The geology of the Townsend Quartzite Upper Proterozoic shallow water
deposit of the Northern Officer Basin Western Australia Perth University of Western
Australia BSc honours thesis (unpublished)
WELLS A T and KENNEWELL P J 1974 Evaporite exploration in the Officer Basin
Western Australia at the Madley Diapirs Australia BMR Record 1974194 (unpublished)
WILLIAMS I R and MYERS J S 1990 Paterson Orogen in Geology and mineral resources
of Western Australia Western Australia Geological Survey Memoir 3 p 274ndash286
WILLIAMS I R 1990 Savory Basin in Geology and mineral resources of Western Australia
Western Australia Geological Survey Memoir 3 p 329ndash334
WILLIAMS I R 1994 The Neoproterozoic Savory Basin Western Australia in The
sedimentary basins of Western Australia edited by P G PURCELL and R R PURCELL
Petroleum Exploration Society of Australia Symposium Perth WA 1994 Proceedings p
841ndash850
WILSON R B 1967 Woolnough Hills and Madley diapiric structures Gibson Desert WA
APEA Journal v 7 p 94ndash102
44
Appendix 2
Meteorological data (from Bureau of Meteorology Perth 1994)
Table 21 Wiluna rainfall (mm)
Year Jan Feb Mar Apr May Jun Jul Aug Sept Oct Nov Dec
1975 0 45 446 309 306 59 276 4 34 886 638 164 1976 16 154 12 138 53 16 34 62 12 238 0 2 1977 44 0 66 74 68 95 24 363 1 58 12 727 1978 234 522 94 16 0 96 367 24 16 353 185 45 1979 19 173 122 88 91 4 0 246 58 0 169 114 1980 148 764 68 1081 259 626 629 06 56 02 174 0 1981 123 476 192 32 196 118 44 74 14 0 28 312 1982 374 705 206 244 1079 92 02 143 368 526 368 118 1983 1 112 928 248 0 212 56 32 5 1 42 496 1984 149 7 342 84 836 0 348 132 224 04 16 172 1985 596 483 0 166 556 0 514 56 0 0 4 0 1986 0 154 35 0 0 1085 23 01 239 137 0 04 1987 1204 119 19 89 17 575 154 126 07 1 0 398 1988 46 202 164 13 388 0 202 104 0 0 224 1309 1989 207 234 26 703 278 536 57 0 01 0 144 02 1990 1035 23 281 46 126 53 94 218 44 9 42 0 1991 48 0 41 45 0 472 297 12 0 1 0 7 1992 112 96 1025 1227 323 65 04 174 0 132 48 4 1993 0 697 0 202 445 0 12 306 18 05 14 33 Mean 25 35 22 27 27 25 18 12 6 13 13 21
JAN FEB MAR APR MAY JUN JUL AUG SEP OCT NOV DEC0
10
20
30
40
Mea
n R
ain
fall
(mm
)
Month
Mean monthly rainfall in Wiluna
MKS41 140498
45
Table 22 Wiluna minimum temperature (degC)
Year Jan Feb Mar Apr May Jun Jul Aug Sept Oct Nov Dec
1975 ndash 23 203 15 94 63 71 62 103 124 169 205 1976 242 229 194 15 10 63 59 73 95 143 16 228 1977 243 25 197 148 96 95 56 86 102 ndash 188 23 1978 241 232 203 18 102 64 76 8 9 152 19 205 1979 255 226 216 167 83 6 59 79 97 145 198 223 1980 255 226 231 155 134 83 68 75 121 108 193 223 1981 245 216 19 182 119 6 54 78 138 159 163 218 1982 232 224 177 16 ndash ndash 37 111 112 164 209 225 1983 235 24 197 147 112 88 39 88 121 162 189 219 1984 241 243 191 156 ndash 72 66 7 95 161 182 211 1985 244 231 ndash 159 98 65 71 73 117 147 205 ndash 1986 ndash 229 226 155 93 96 43 49 10 122 ndash 219 1987 ndash 217 183 175 85 77 68 68 112 ndash ndash 221 1988 238 214 209 178 111 ndash ndash 86 104 157 171 195 1989 ndash 237 199 165 107 67 44 61 107 131 187 ndash 1990 232 ndash 211 155 118 62 57 87 102 149 195 22 1991 26 256 217 168 122 101 78 ndash 113 18 168 219 1992 227 227 214 169 102 98 59 69 ndash 125 159 196 1993 241 218 196 171 103 ndash 49 68 88 128 192 211 Mean 24 23 20 16 10 8 6 8 11 14 18 21
NOTE Dashes indicate data unavailable
JAN FEB MAR APR MAY JUN JUL AUG SEP OCT NOV DEC0
10
20
30
40
Month
MKS43 140498
50
Mean monthly minimum temperatures at Wiluna
Mea
n T
emp
erat
ure
(degC
)
46
Table 23 Wiluna maximum temperature (degC)
Year Jan Feb Mar Apr May Jun Jul Aug Sept Oct Nov Dec
1975 ndash 349 326 281 247 201 197 212 256 248 31 344 1976 374 369 346 297 248 206 208 225 265 287 313 388 1977 397 392 352 296 234 212 222 244 ndash 308 337 383 1978 378 345 346 316 242 195 176 205 231 295 334 356 1979 403 36 364 295 ndash ndash ndash 193 242 318 359 373 1980 392 342 377 275 24 176 179 233 292 288 349 391 1981 385 346 337 342 242 178 201 224 30 326 326 369 1982 372 359 315 307 ndash ndash 196 253 252 305 353 379 1983 381 389 327 272 263 222 187 248 287 321 336 366 1984 378 393 322 299 226 215 178 214 234 ndash 336 364 1985 40 366 ndash 294 224 216 205 212 284 307 355 ndash 1986 ndash 383 372 307 ndash 193 166 196 261 277 ndash 382 1987 ndash 339 328 305 21 202 214 218 275 ndash ndash 374 1988 388 365 353 301 23 ndash ndash 228 283 334 31 33 1989 ndash 375 339 285 238 179 181 219 275 298 336 ndash 1990 368 ndash 36 309 268 19 188 205 274 309 373 393 1991 414 416 363 315 268 206 21 ndash 279 338 332 368 1992 363 383 336 263 213 178 213 197 ndash 285 313 359 1993 396 357 344 301 221 ndash 197 215 253 294 347 362 Mean 39 37 34 30 24 20 20 22 27 30 34 37 NOTE Dashes indicate data unavailable
JAN FEB MAR APR MAY JUN JUL AUG SEP OCT NOV DEC0
10
20
30
40
Month
MKS42 140498
50
Mean monthly maximum temperatures at Wiluna
Mea
n T
emp
erat
ure
(degC
)
47
Appendix 3
Table 31 Summary of palynological results
Drillhole Depth (m) F no(a) GSWA no Lithology Formation Assemblage TAI(b)
BWB 1 74ndash75 F49668 135741 dark-grey siltstone basalt Jilyilli gt5 BWB 1 98ndash100 F49669 135742 dark-grey siltstone basalt Jilyilli gt5 BWB 1 121ndash122 F49670 135743 dark-grey siltstone basalt Jilyilli gt5 TWB 1 86ndash87 F49671 135631 dark-grey siltstone McFadden 3+ TWB 1 104ndash105 F49672 135632 dark-grey siltstone Cornelia 3+ TWB 1 121ndash122 F49673 135633 dark-grey siltstone Cornelia 4 TWB 2 14ndash15 F49674 135634 dark-grey siltstone Skates Hills 3+ TWB 6 49ndash50 F49675 135675 dark-grey siltstone Cornelia 1 3+ TWB 9 49ndash51 F49676 135704 dark-grey siltstone Brassey Range 1 3+ Trainor 1 37497- F49733 138939 black mudstone with Cornelia 5 37509 light-grey siltstone Trainor 1 3809 F49734 138940 dark-grey and black Cornelia 4- laminated mudstone Trainor 1 4170 F49735 138941 black unlaminated mudstone Cornelia 4- Trainor 1 4950 F49851 139501 dark-grey indurated siltstone Cornelia 5 Trainor 1 6032 F49852 139502 dark- and light-grey Cornelia 5 indurated siltstone Trainor 1 6434 F49853 139503 greenish indurated finely Cornelia 5 laminated siltstone LDDH 1 270 F49678 138934 dark-grey siltstone interbeds Waters 1 3+ in enterolithic evaporite Tarcunyah Gp LDDH 1 277 F49679 138935 dark-grey siltstone in cavity Waters 1 3+ in enterolithic evaporite Tarcunyah Gp
NOTES (a) GSWA Fossil Catalogue number (b) TAI = Thermal Alteration Index of Traverse (1988 plate 1)
48
Appendix 4
Savory Sub-basin quantitative magnetic and gravity interpretation (extracted from Cowan 1995)
Summary
A program of quantitative aeromagnetic interpretation has been completed on BMRAGSO data from the Savory Sub-
basin Western Australia Quantitative aeromagnetic interpretation utilized the 3D Euler deconvolution method
supported by wavenumber filtering and image processing The results have provided useful information on structural
trends and depth to magnetic sources in a structurally complex area Depth to magnetic source analysis has provided
information on intra-sedimentary magnetic sources as well as basement rocks
The results of the interpretation support previously identified depocentres However the presence of magnetic
sources at several levels makes it very difficult to produce a reliable magnetic basement depth contour map It is
considered more productive to work with the 3D Euler colour circle plots and images rather than trying to contour the
results It would be necessary to carry out a full-scale interpretation of the BMRAGSO profile data to improve on the
3D Euler results The regional gravity was found to be useful in interpreting the regional setting of the area although
the very wide data spacing limits quantitative use of the data The gravity data show quite a complex picture with
limited consistent correlation between gravity features and basin structures This suggests that gravity anomalies
reflect changes in density of the basement rocks rather than basement topography especially in the northern part of the
basin
It is recommended that the GSWA investigate access to company confidential high-resolution aeromagnetic data
prior to planning further aeromagnetic surveys Private companies have flown large parts of the northern half of the
area as part of their diamond exploration program Additional gravity coverage of the area may be more cost effective
than magnetic surveys as the gravity data provides more information on changes within the sedimentary section
Introduction
The main use of aeromagnetic data in petroleum exploration has been the determination of magnetic basement
topography although there has been increasing interest in analysis of intra-sedimentary magnetic anomalies
intrabasement and suprabasement magnetic anomalies These anomalies are used to determine depth to magnetic
basement rocks and hence determine the thickness of the sedimentary sequence Unfortunately interpretation of the
intrabasement and suprabasement magnetic anomalies is non-unique in terms of position and size of causative sources
because of the inherent ambiguity of potential-field methods However this ambiguity can be reduced by placing
49
constraints on source geometry and magnetization and by using geological and other geophysical data to constrain
the solution
Before 1970 most depth-determination techniques involved graphical determination of slopes of selected
magnetic anomalies and application of various empirical factors to convert the slopes into depth estimates Geological
Society of America Memoir 47 Interpretation of Aeromagnetic Maps by Vacquier et al (1951) was a landmark for
this type of interpretation
Automated interpretation procedures have played an increasingly important role in depth interpretation and a
wide range of techniques have been developed Many of these techniques are designed for application to located data
profiles and assume a two-dimensional geometry However there has been renewed interest in techniques applicable
to gridded data
Two distinct types of method can be recognized In the first case often described as discrete methods individual
isolated magnetic anomalies are interpreted and the results used to produce a map of basement relief In the second
case often described as continuous methods areas of data containing a number of anomalies are interpreted
statistically to produce direct output of basement depths
The discrete methods usually involve a semiautomatic initial phase which generates a large number of possible
depth solutions and an interactive second phase to screen and select acceptable solutions The advantage of this
approach is that the interpreter can select features that are relatively free from interference from adjacent anomalies
and consider all aspects of a particular magnetic anomaly The disadvantage is that interpretation can be very time
consuming as a wide range of depths are usually possible depending on the initial model chosen and a significant
amount of effort is needed to select the correct model In the case of the Savory Sub-basin dataset we encountered
problems in separating basement related effects from the effects of shallower intrasedimentary magnetic sources
Because of these problems we have concentrated on displaying the Euler results accompanied by separation filter
images of the data to show the shallower effects and deeper effects rather than trying to refine a 3D Euler
deconvolution depth-to-crystalline-basement contour
The continuous methods are very direct provided that the rather restrictive assumption can be made that all
anomalies are due to lateral magnetization changes due to basement topography This means that shallow effects and
large intrabasement anomalies must be removed from the data This involves judgement and skill as it is necessary to
distinguish between the lower amplitude suprabasement anomalies due to basement topography and the larger
intrabasement anomalies reflecting magnetization changes within the basement These methods were not considered
suitable for the Savory Sub-basin magnetic dataset but were used to invert the gravity data
50
Limitations of magnetic and gravity interpretation
Interpretation of the area is limited by a shortage of information on the nature and physical properties of the deeper
sedimentary sequence and the underlying basement rocks However using techniques such as cross-correlation of
gravity and pseudo-gravity data it is possible to try to differentiate between anomalies relating to basement and those
related to the sedimentary sequence
Gravity anomalies reflect changes within the sedimentary sequence as well as basement condition These
changes in density of sedimentary rocks produce gravity anomalies without a corresponding magnetic anomaly hence
the complementary nature of gravity and magnetic surveys The main use of magnetics is to determine depth to
magnetic basement and any intra-sedimentary volcanic rocks or intrusives whereas gravity provides much more
general information on the sedimentary sequence
Unfortunately interpretation of gravity anomalies is complicated since they can be due to a number of geological
features including
bull major basement faults
bull basement highs
bull igneous intrusions within the basement
bull sedimentary basins which may or may not be isostatically compensated
bull intra-sedimentary volcanics and associated plutonic centres
Two major problems affect the interpretation of both magnetic and gravity data
1 The inherent ambiguity of potential-field data There is no unique solution to any measured gravity or magnetic
anomaly and theoretically there will be an infinite number of source geometry and magnetizationdensity
combinations which will fit the observed data This means that any a priori information which helps to select a
suitable model is very useful
2 Measured anomalies are the summation of effects from different depths For example an observed gravity profile
may contain contributions from shallow sources (density variations within the sedimentary basin) intermediate
depth sources (density variations due to large igneous intrusions within the basement) and deep sources (crustal
thinning producing a mantle anomaly) Separation of these component responses is the regionalresidual problem
which we solve using spectral analysis and differential upward continuation-based separation filtering
Regional setting and interpretation overview
The area studied includes parts of BALFOUR DOWNS (SF51-9) RUDALL (SF51-10) ROBERTSON (SF51-13) GUNANYA
(SF51-14) COLLIER (SG50-4) BULLEN (SG51-1) TRAINOR (SG51-2) MADLEY (SG51-3) NABBERU (SG50-5)
STANLEY (SG51-6) and HERBERT (SG51-7) 1250 000 sheets Broadly the area lies between latitudes 22deg00rsquondash25deg30rsquoS
and longitudes 119deg30rsquondash123deg30rsquoE
51
Regional gravity
The AGSO regional gravity data (at nominal 11 km spacing) was gridded at a 4 km mesh spacing using a minimum-
curvature algorithm Bouguer gravity values in the area are negative reflecting mass deficiency at depth and range
from -84 mgals to -25 mgals
A Bouguer gravity colour image is shown as Figure 41 A residual grid was produced by removing a fifth-order
orthogonal polynomial from the Bouguer data but did not add to the interpretation
120deg 121deg 122deg 123deg
23deg
24deg
25deg
-25
-84
50 km
MKS46 180598
mgal
Figure 41 Regional Bouguer gravity (BMRAGSO data) gridded at 4 km
52
The data show a complex pattern of positive and negative anomalies with no clearly defined trends Correlations
with aeromagnetic data and known basin structures are poor A vague north-northwest linear trend appears to coincide
with the Marloo Fault (Figure 42) A prominent negative anomaly appears to coincide with the Blake Fold and Fault
Belt depocentre and continues as a narrower negative anomaly to the east until it widens out again near the edge of the
basin Elsewhere the gravity data show little correlation with known basin structures and it is likely that especially in
the north of the area gravity anomalies are due to density changes in the basement rather than changes in basement
topography
Production of wavelength-filtered residual gravity plots and vertical gradient plots showed very patchy aliased
data reflecting poor sampling in much of the area
Regional magnetics
The AGSO regional aeromagnetic data were gridded at a 400 m mesh spacing using a minimum-curvature algorithm
(Figure 43) Most of the data has a line spacing of 1600 m with small areas of 1 km spacing The quality of the data is
acceptable for regional interpretation but is not adequate for detailed analysis The accuracy of the flight path is rather
variable reflecting the vintage of the data and the noise envelope of the data is poor by modern standards Problems
were also encountered in joining different map sheets
The magnetic anomaly pattern over the south and west part of the area shows a strong high frequency signature
reflecting the presence of widespread basic sills and dykes Some of the major north-northeasterly trending dykes can
be traced over considerable distances
Discontinuous high-frequency anomalies extend as a northwest-trending zone through the centre of the area and
this zone includes a conspicuous circular magnetic anomaly which is probably a ring complex
The northern and eastern parts of the area are characterized by long-wavelength deep-seated basement magnetic
anomalies with 120deg and 150deg trends dominant The Marloo and Perentie Faults (Figure 42) appear as distinct linear
zones and offsets A prominent easterly trending negative anomaly in the northwest of the area appears to swing round
to the southeast and may separate different basement blocks One possible interpretation is that this very deep seated
anomaly separates areas of Archaean and Proterozoic basement
Regional geology
The regional geology is described in Williams (1992) The GSWA provided a digitized version of Plate 2 from this
Bulletin the structural interpretation map to use as an overlay (Figure 42)
53
Pp
Pp
PSd
PSd
PSd
PSd
PSd
PSo
PSt
PSt
PSf
PSf
PSf
PSb
PSb
PSb
PSsPSs
PSs
PSb
PSm
PSp
PSc
PSc
PSw
PSw
PSw
PSg
PSr
PSj
PSg
PM
Pk
PY
PY
PSd
L
L
L
L
L
L
L
LL
L
L
L
LL
L
LL
L L
LL
L L
L
L
L
L
L
L
L
LL
L
L
BLAKEDEPOCENTRE
MA
RLO
O
FAU
LT
PERENTIEFAULT
50 km
MKS39120598
120deg 121deg 122deg 123deg
25deg
24deg
23deg
Approximate boundaryof aeromagnetic interpretation
PML
PSgL
PSjL
PML
PSpL
PML
PML
PSfL
PSfL
PSpL
LPc
LPcLPcPSrL
LPA
Durba Sandstone
Woora Woora Formation
McFadden Formation
Tchukardine Formation
Boondawari Formation
Skates Hills Formation
Mundadjini Formation
Coondra Formation
Spearhole Formation
Watch Point Formation
Jilyili Formation
Brassey Range Formation
Glass Spring Formation
Paterson Formation
Yeneena Group
Karara Formation
Cornelia Formation
Kahrban Subgroup
Bangemall Group
Fault
Formation boundary
PSdL
PSoL
PSfL
PStL
PSbL
PSsL
PSmL
PScL
PSpL
PSwL
PSjL
PSrL
PSgL
Pp
PYL
PkL
LPc
LPA
PML
Savory Group Other Units
PYL
Figure 42 Regional geology and structure map (after Williams 1992)
54
120deg 121deg 122deg 123deg
23deg
24deg
25deg
5820
3750
MKS47 180598
nT
50 km
Figure 43 Regional aeromagnetic data total magnetic intensity (BMRAGSO data) gridded at 400 m
Analysis
3D analysis
3D Euler deconvolution was used as the primary depth-determination method The advantage of this approach is that
consistent solutions can be obtained over the entire area with minimal assumptions about source geometries Euler
deconvolution of gridded data is used for positional information and estimation of depth to top of source Euler
55
deconvolution yields a large number of depth solutions which have to be screened to reject spurious solutions Results
are plotted as circles in eight depth ranges with radius proportional to depth and colour coded
The 400 m total magnetic intensity grid was used for the analysis Horizontal gradients in x and y and the vertical
gradient were calculated 3D Euler deconvolution was tested on the 400 m gridded data using windows of 9 times 9 and
11 times 11 and 16 times 16 data points and structural indices 05 (fault) and 10 (sill or dyke) It was concluded that the
16 times 16 window produced the best results overall and final plots were produced for the 16 times 16 window and structural
index 05 (Fig 44) Results were very good over the northern and central parts of the area showing magnetic sources
Figure 44 Depth to magnetic source 3D Euler deconvolution 16 times 16 window of 400 m gridded data structural index 05
56
at several different levels Unfortunately in the extreme south of the area shallow intrasedimentary magnetic sources
(sills and dykes) dominated the inversion and the results contained few basement solutions
In order to reduce these problems the 400 m gridded data were filtered using a separation filter based on
interpretation of the log-energy spectrum The 3D Euler method was run on the filtered data in order to generate more
basement-depth solutions Results for the deep-separation filter data were gridded and presented as a colour image in
Cowan (1995) Attempts to grid the Euler output were unsatisfactory and it is considered safer to interpret the 3D
Euler depth plots The 3D Euler depth results from the separation-filter run should be analysed with care as perfect
separation of the basement can never be achieved and there will always be some contamination from sources at
different levels
The results of original total magnetic intensity 3D Euler depth estimation for structural index 05 using a 16 point
window have been plotted at 1500 000 scale (not included in this publication but available in Cowan (1995) from the
GSWA Library as S10331) and as reduced A4 colour circle plots (Figure 44)
The results of deep-basement 3D Euler depth estimation for structural index 05 using a 16 point window have
been plotted as a colour image at 1500 000 scale and as an A4 image (not included in this publication)
2D analysis
Two equispaced profiles were interpolated with a 50 m station interval from the AGSO-located data profiles for the
BULLEN 1250 000 sheet The interpolated profiles were analysed using 2D Euler deconvolution and Werner
deconvolution Results are included in Cowan (1995) and show the use of these methods for more detailed analysis
Filtered data
In order to reconcile 3D Euler results from shallow basement and intrasedimentary magnetic sources we produced
several separation-filtered maps and images We found the shallow-layer double-separation filter (Figure 45) to be
very effective for shallow sources and the deep-layer standard-separation filter (Figure 46) for the basement layer
Gravity and magnetic data correlation
Both lsquoreduced to the polersquo (RTP) magnetics (Figure 47) and pseudo-gravity data (Figure 48) were produced as part of
the reconciliation of gravity and magnetic signatures In both cases the filtering operations assumed magnetization by
induction in the present Earths field The RTP data are fairly similar to the total magnetic intensity The pseudo-
57
gravity data are dominated by a northwest-trending strong positive anomaly and there is little correlation with the
Bouguer gravity data
The poor magneticgravity correlation is confirmed by cross-correlation of the RTP magnetics and the gravity
gradient The correlation plot in Figure 49 shows little coherent response with numerous zones of positive and
negative correlation
Figure 45 Regional aeromagnetic data shallow layer separation filter (BMRAGSO data) gridded at 400 m
Results
In the north and east of the area on the Wells Foreland Sub-basin trend (refer to Figure 1 main text) we see a range
of quite deep 3D Euler depths and several trend directions with north-northwesterly dominant There are relatively few
shallow intrasedimentary solutions in this zone
The second area of deep 3D Euler solutions lies over the Blake depocentre (Figure 43) with several trend
directions
Elsewhere the 3D Euler results are dominated by shallow intrasedimentary depth solutions reflecting mainly the
dolerite sills dykes and the ring complex However where we do see basement-related solutions in the south and
west of the area they appear to be shallower than those noted for the Wells Foreland Sub-basin and the Blake
depocentre
58
Figure 46 Regional aeromagnetic data deep-layer separation filter (BMRAGSO data) gridded at 400 m
Figure 48 Regional aeromagnetic data pseudo-gravity transform (BMRAGSO data) gridded at 400 m
Figure 47 Regional aeromagnetic data reduced-to-pole (BMRAGSO data) gridded at 400 m
Figure 49 Regional aeromagnetic and gravity data gravitymagnetic correlation using RTP magnetics and gravity gradient (BMRAGSO data) gridded at 4 km
59
This subdivision of the area into two zones of deep solutions is consistent with interpreted depocentres
However the interference between sources at different levels and the complexity of the magnetic response of the
basement rocks precludes more refined interpretation at this stage
The area of deep 3D Euler solutions over the Blake depocentre correlates with the pronounced negative gravity
anomaly discussed in the gravity interpretation section Using a density contrast of -015 gcc the negative gravity
anomaly could indicate up to 6ndash8 km of low-density sedimentary rocks depending on assumptions about the regional
field
The area of deep 3D Euler solutions over the Wells Foreland Sub-basin has a complex gravity expression and no
clear basin structure emerges from inversion of these data As noted previously it is likely that observed gravity
anomalies reflect contrasts in basement density rather than basement topography
Separation filtering applied to the magnetic data helps to enhance the intrasedimentary magnetic signature and to
give a better impression of the basement magnetic signature even though separation of the basement response is not
perfect
Conclusions
Quantitative aeromagnetic interpretation using 3D Euler deconvolution supported by wavenumber filtering and image
processing has been successful in providing structural trend and depth information for the Savory Sub-basin
Quantitative magnetic interpretation has revealed two zones of relatively deep magnetic basement beneath the
Wells Foreland Sub-basin and the Blake depocentre
This analysis of the magnetic data supports interpreted depocentres but the complexity of the basement magnetic
signature and interference from sources at different depths precludes further refinement to a map of basement
topography
Regional gravity proved to be very useful in understanding the regional setting of the area and in providing
support for aspects of the interpretation The gravity data support the interpretation of the Blake depocentre
suggesting up to 6ndash8 km of low-density sedimentary rocks
The deep structure of the Savory Sub-basin area is obviously complex with different areas underlain by
Archaean and Proterozoic basement and with the Capricorn suture occurring in the centre of the area
60
Recommendations
The quantitative magnetic interpretation needs to be reconciled with geological models available for the area
In particular the zones tentatively identified as areas with thick sedimentary rocks the Wells Foreland Sub-
basin and the Blake depocentre need to be investigated
Cross sections should be prepared across the basin for joint magneticgravity modelling especially for the Blake
depocentre It is important to be able to explain the strong negative gravity anomaly in this area
In view of the effects of basement density contrasts on the gravity field for the northern part of the area we think
that additional gravity interpretation and acquisition of new gravity data may not be justified as they will not
contribute significantly to understanding basin evolution and structure
It is recommended that GSWA try to get access to company confidential high-resolution aeromagnetic data
rather than flying new surveys The GSWA might offer to fund flying of new infill areas as a bargaining point
References
The original text of this report by Cowan (1995) and 1500 000 scale maps are filed in the GSWA Library under
S10331
COWAN D 1995 Savory Basin quantitative magnetic interpretation Western Australia Geological Survey S-series
S10331 (unpublished)
VACQUIER V STEENLAND N C HENDERSON R G and ZIETZ I 1951 Interpretation of aeromagnetic
maps The Geological Society of America Memoir 47 151p
WILLIAMS I R 1992 Geology of the Savory Basin Western Australia Western Australia Geological Survey
Bulletin 141 115p
61
Appendix 5
Geochemistry
MKS38 250398
Saturate FractionC12+ GLC
1217
Pr18
Ph
22
31CSR WELL-13 315m Cuttings
Figure 51 Canning Stock Route Well 13 gas chromatograph of extract of auger drill sample
12
17
18
22
31
Pr Ph
LDDH 1 6623m CoreSaturate FractionC12+ GLC
MKS35 240398
Figure 52 Gas chromatograph of extract from core sample at 6623 m LDDH1
62
Table 51 Canning Stock Route Well 13 auger drill samples
GSWA sample Drill depth (m)(a) Comments
135601 150 At watertable 135602 203 (all samples consist 135603 310 of sand mud and water) 135604 315 At total depth
NOTE (a) Datum for drill depth is the top of sediment fill in the well which is 155 m below ground level (ie the total depth of 315 m is 47 m below ground level)
Table 52 Canning Stock Route Well 13 gas chromatography data for 315 m depth sediment sample
Parameter Value
Weight of rock extracted (grams) 945 Total extract (ppm) 519 n-Alkane distribution n-C12 07 n-C13 23 n-C14 26 n-C15 22 n-C16 19 n-C17 14 i-C19 23 n-C18 14 i-C20 08 n-C19 11 n-C20 16 n-C21 25 n-C22 29 n-C23 70 n-C24 42 n-C25 95 n-C26 43 n-C27 83 n-C28 38 n-C29 87 n-C30 31 n-C31 273 Alkane compositional data Pristane phytane ratio 279 Pristane n-C17 ratio 161 Phytane n-C18 ratio 059 CPI (1)(a) 284 CPI (2) 209 (C21 + C22) (C28 + C29) 043
NOTE (a) CPI= Carbon preference index
63
Table 53 LDDH1 extract liquid chromatography data for 6623 m concentration
Rock extracted Total extract (grams) (ppm)
702 313
NOTE ppm= parts per million
Table 54 LDDH1 saturate gas chromatography data of core for 6623 m alkane composition
Pristane Pristane Phytane (a) CPI (1) CPI (2) (C21+C22) Phytane n-C17 n-C18 (C28+C29)
103 026 024 103 102 325
NOTE (a)CPI = carbon preference index
Table 55 LDDH1 saturate gas chromatography data of core for 6623 m n-alkane distributions
Parameter Value
n-C12 17 n-C13 38 n-C14 55 n-C15 60 n-C16 65 n-C17 74 i-C19 19 n-C18 78 i-C20 19 n-C19 80 n-C20 79 n-C21 71 n-C22 64 n-C23 57 n-C25 43 n-C24 38 n-C27 31 n-C28 23 n-C29 19 n-C30 12 n-C31 10
64
Appendix 6
Table 61 Summary of data from Trainor waterbores (TWB) and Bullen waterbores (BWB)
Well AMG Elevation TD Status(b) Completion details Water Salinity Water level Flow rate Depth to consolidated AGD84 GL (m) (m) struck mgl(c) (m) (LHr) lithology aquifer(e) Z51(a) Interval (m) (100 mm PVC) (m) (mgl)(d)
TWB 1 473660E 453 122 comp 0ndash75 plain 63 7 300 24 2 880 12 m 7287404N 75ndash93 slotted (9 260) McFadden Fm 93ndash99 plain TWB 2 472 977E 475 23 abd nil 15 m 7285877N Skates Hills Fm dry TWB 3 473259E 475 50 abd nil 7 m 7285849N Skates Hills Fm dry TWB 4 463225 E 445 50 comp 0ndash22 plain 35 7 200 55 3 600 0 m 7286143N 22ndash34 slotted (8 140) Tertiary sand and gravel 23ndash60 plain TWB 5 463095E 445 31 comp 0ndash19 plain 13 26 000 655 3 600 Tertiary sand and gravel 7277721N 19ndash25 slotted (36 700) 25ndash31 plain TWB 6 457013E 455 50 comp 0ndash42 plain 38 920 119 600 0 m 7274352N 42ndash48 slotted (1 030) Cornelia Fm ss TWB 7 453739E 475 26 susp 0ndash2 plain 11 9 300 48 4 500 0 m 7263891N (10 500) Tertiary sand TWB 8 433893E 535 60 susp 0ndash2 plain 47 8 500 gt46 1 200 0 m 7245991N (10 900) Tertiary sand and Brassey Range Fm ss TWB 9 437219E 505 51 comp 0ndash47 plain 45 1 000 58 600 1 m 7235905N 47ndash51 slotted (990) Brassey Range Fm ss TWB 10 434927E 495 32 susp 0ndash2 plain 235 450 120 0 m 7225875N (500) Dolerite
65
BWB 1 287337E 580 122 abd Nil 1 m 7245861N Jilyili Fm dry BWB 2 288346E 545 50 comp 0ndash26 plain 15 630 3 29 000 0 m 7240423N 26ndash38 slotted (730) Tertiary sand and gravel 38ndash50 plain BWB 3 305637E 545 50 abd 19 8 800 43 7 200 0 m 7240423N (10 550) Tertiary ss BWB 4 320167E 515 445 comp 0ndash20 plain 9 980 445 24 000 0 m 7248097N 20ndash32 slotted (1 190) Tertiary ss 32ndash44 plain BWB 5 353393E 545 20 susp 0ndash2 plain 45 (970) 1 m 7238934N Basalt
NOTES (a) GPS accuracy ~ 150 m (b) Comp = completed abd = abandoned susp = suspended (c) Salinity from conductivity (d) Analysis total dissolved solids (e) Fm = Formation ss = sandstone
9
Watch Point 1 B Shale siltstone fine- to medium-grained 400 Shallow marine deltaic Y Formation sandstone glauconitic sandstone Jilyili Formation 1 A Fine-grained sandstone siltstone minor shale mudstone conglomerate lenses 1 000 Deltaic Y Brassey Range 1 A Fine- to medium-grained sandstone 1 700 Fluvial deltaic Y Formation siltstone shale minor mudstone Glass Spring 1 A Medium- to coarse-grained sandstone 1 600 Shallow marine fluvial Y Formation minor conglomerate and siltstone Tarcunyah Group 1 AampB Quartz sandstone feldspathic sandstone Shallow marine sabkha N Bitumen in LDDH1 quartz wacke shale siltstone fluvial lacustrine conglomerate evaporites dolomite Cornelia 1 A Sandstone siltstone shale mudstone Shallow marine N Overmature source rocks Formation minor glauconitic sandstone deep marine in Trainor 1 Kahrban 1 A Sandstone siltstone shale 1 700 Shallow marine deltaic N Subgroup
NOTES (a) Supersequences of Walter et al (1995) (b) Depositional sequences of Williams (1992) (c) Y= assigned to Savory Group in Williams (1992) N= previously considered to be older than the Savory Group but now included in the greater Officer Basin
10
SAVORY SUB-BASIN GIBSON SUB-BASINCENTRAL OFFICERBASIN
AMADEUS BASIN
PETERMANN RANGES OROGENY
NE
OP
RO
TE
RO
ZO
IC
ST
UR
TIA
NM
AR
INO
AN
ED
IAC
AR
IAN
CAMBRIANTO
NEOPRO-TEROZOIC
AG
E (
Ma)
SOUTHS RANGE MOVEMENT
AREYONGA MOVEMENT
Steptoe
MILES OROGENY
Mission Group
Cassidy Group
Rudall Complex
Bangemall Group
unnamed
Tar
cuny
ah G
roup
4
3
2
1
MKS12a 180598
500
550
600
650
700
750
800
850
900
SU
PE
R
SE
QU
EN
CE
unnamed
Tchukardine Fm
McFadden Fm
ArumberaSst
Julie Fm
Pertatataka Fm
Olympic FmPioneer Sst
Boondawari Fm
Turkey Hill FmLupton Fm
Kanpa Fm
Neale FmBabbagoola
FmHussar
Fm
Browne Fm
Woolnough Fm
Madley Fm
Bitt
er S
prin
gs F
m
LovesCreek M
Gillen M
Heavitree Fm
Arunta Complex
Throssell Group
TownsendQuartzite
Earaheedy Group
olderCornelia Fm
Jilyili Fm
SpearholeFm
MundadjiniFm
Skates Hills Fm
Lefroy Fm
Areyonga Fm
Aralka Fm
ME
SO
-P
RO
TE
RO
ZO
IC
Waters Fm
youngerCornelia Fm
Brassey RangeFormationKahrban
Subgroup
GlassSpring
Fm
Durba Sst
LP1ALP1B EVENT
Figure 4 Correlation of Savory Sub-basin formations with the western Officer and Amadeus Basins Fm = Formation Sst = Sandstone M = Member
11
The depositional sequences recognized in the sub-basin are an order of magnitude thicker than
those described from Phanerozoic passive-margin settings (Payton 1977 Posamentier et al 1988)
and are broadly comparable in scale to the second-order cycles of Vail et al (1977) and to the
megasequences of Hubbard et al (1985) The main subsurface data available to reveal the
unweathered nature of these rocks are Trainor-1 and the three-well diamond coring program in
Petroleum Permit EP 380 (Akubra 1 Boondawari 1 Mundadjini 1) completed in late 1997 in the
central west of the sub-basin (Figs 5 and 6)
The ages of all formations in the Savory Sub-basin are poorly constrained The only fossils
known are stromatolites and palynomorphs (acid-insoluble microfossils) Palynology from
available wells is summarized in Appendix 3 from Grey and Stevens (1997) and Grey and Cotter
(1996) and correlations using stromatolite biostratigraphy (Stevens and Grey 1997 Grey 1995f
Walter et al 1994 1995) are consistent with a Neoproterozoic age for the formations for which
data are available
A dolerite within the Boondawari Formation gave a poorly constrained RbndashSr age of about
640 Ma (Williams 1992) SHRIMP UndashPb dating of sedimentary zircons from the McFadden and
Cornelia Formations in stratigraphic drillhole Trainor 1 are discussed in Stevens and Adamides (in
prep) and Nelson (1997) The youngest ages from these analyses indicate that the maximum age
of the Cornelia Formation is Early Cambrian or Sturtian but these ages are inconsistent with
previous tectonic interpretations (Williams 1992) and current stratigraphic correlations which
suggest the Cornelia Formation is of Supersequence 1 age or older (Fig 4)
Depositional Sequence A Supersequence 1
Depositional Sequence A includes the Glass Spring Jilyili and Brassey Range Formations (Fig
3) All of these units are predominantly quartzose sandstones some of which are friable and have
significant visible porosity in outcrop Conglomerates are present in the Glass Spring and Jilyili
Formations
Depositional Sequence B Supersequence 1
Depositional Sequence B consists of the Watch Point Coondra Mundadjini Spearhole and
Skates Hills Formations (Fig 3) All of these formations contain beds of quartzose sandstone and
some also contain conglomerates The porosity of dolomites in the Skates Hills Formation appears
poor in surface exposures but its subsurface characteristics are unknown
12
50 km
120deg 121deg30 123deg
25deg
24deg
23deg
22deg
Greater Officer Basin
PNCEXP CA11PNCEXP CA12
PNCEXP CA13PNCEXP CA19
PNCEXP CA05
PNCEXP CA09
BD134589
GSWA Trainor 1 and TWB123
Fortescue River 1A
Mundadjini 1
Akubra 1Boondawari 1
TWB4TWB5
TWB6
TWB7
TWB8
TWB9
TWB10
BWB1
BWB2 BWB3
BWB4
BWB5
OD23
Mineral exploration drillhole
Stratigraphic drillhole
Waterbores and wells(TWB and BWB serieswaterbores identified)
MKS33270398
LDDH 1
Savory Sub-basin
Canning SR Well 13
EP380
Petroleum Exploration permit
Petroleum exploration well
Figure 5 Locations of petroleum exploration wells mineral exploration and stratigraphic drillholes water bores and wells and petroleum exploration permit EP380 in the Savory Sub-basin
13
TD=600m
TD=1367m
TD=701m
TD=709m
TD=50m
SS
1S
S1
SS1
SS
1S
S1
SS
1
SS
1
SS1
SS4 SS1
Pha
nero
zoic
or
SS
2
Cz
CzCz
Karst Bitumen
SS1
TD=181m
Mundadjini 1 Akubra 1 Boondawari 1 LDDH 1 Trainor 1 TWB 6
Munda-djini Fm
Spear-hole Fm
Munda-djini Fm
Munda-djini Fm
Spear-hole Fm
Spear-hole Fm
Waters Fm
McFadden Fm
Cornelia Fm
Cornelia Fm
Cornelia Fm
511 plusmn 13Maor 696 plusmn 20Ma(maximum)
779 plusmn 10Ma(maximum)
Mundadjini 1
Akubra 1 Boondawari 1
LDDH 1
Trainor 1TWB 6100 km
N
LOCATION
NW SE
Sea level
0m AHD
Dolerite basalt
Conglomerate
Sandstone
Mudstone
Dolomite
Limestone
Evaporite
TOC gt08
Permeability gt100md
Oil fluorescence
Sedimentary zircon U-Pb age
Identifiable polymorphs
Cainozoic
Supersequence 1 age
Unconformity
Formation contact
Cz
SS1
r
r
0
100
200
metres
VerticalScale
MKS36 120598
LEGEND
Figure 6 Geological cross section through significant drillholes in the Savory Sub-basin
14
Depositional Sequence C Supersequence 3
Depositional Sequence C consists of the Boondawari Formation (Fig 3) and although it contains
sandstone conglomerate and dolomite the sandstones contain significant amounts of feldspar and
clay and hence are likely to be poorer reservoirs than older sandstones
Depositional Sequence D Supersequence 4
Depositional Sequence D includes the McFadden Tchukardine and Woora Woora Formations
(Fig 3) The McFadden Formation is poorly sorted and sandstones contain significant amounts of
feldspathic clasts in the north of the basin but are significantly coarser and cleaner in the northeast
of the sub-basin (Williams 1992)
Sandstones of the Tchukardine and Woora Woora Formations are generally cleaner than those
of the McFadden Formation and are expected to have fair to good porosity although the
Tchukardine Formation has a higher clay content in parts
Depositional Sequence E Supersequence 4
Depositional Sequence E consists of the Durba Sandstone (Fig 3) a coarse sandstone with minor
conglomerate which has good to excellent visible porosity in surface exposures
Other depositional sequences and regional correlations
Sedimentary rocks which were not included in the Savory Group by Williams (1992) but which
are likely to be of Neoproterozoic age and hence part of the greater Officer Basin include the
Tarcunyah Group the Cornelia Formation and the Kahrban Subgroup
As discussed in the Introduction all of the strata in the Karara Basin and the younger strata
of the Yeneena Basin were redefined to form the Tarcunyah Group of the greater Officer Basin
(Bagas et al 1995) (Fig 7) In outcrop the Tarcunyah Group consists predominantly of quartzose
feldspathic and arkosic sandstone shale which is carbonaceous in parts and carbonate which
includes stromatolitic dolomite Mineral hole LDDH1 drilled on GUNANYA intersected the
15
120598
122deg
123deg
21deg
22deg
23deg
24deg
23deg
22deg
21deg
122deg
123deg
Fault
Thrust
Reverse thrust
CANNINGBASIN
OFFICERBASIN
GROUP
PILBARACRATON
TARCUNYAH
SAVORY GROUP
BANGEMALL
GROUP
THROSSELL
GROUP
LAMIL
GROUP
ConnaughtonTerrane
TerraneTalbot
complexTabletop granitic
Tabletop Terrane
Permian
Neoproterozoicgranitoid
50 km
FormationWaltha Woora
McKay Fault
South west Thrust
Vines
Fault
24deg
120deg
YENEENA CANNINGBASIN
ARUNTAINLIERRUDALL
COMPLEX
AMADEUSBASIN
MUSGRAVEBLOCK
OFFICERBASINYILGARN
CRATON
GROUP
GROUP
GROUP
PILBARACRATON
GROUP
EARAHEEDY
GLENGARRY
BANGEMALL
WYLOO GROUP
SAVORY
WA
CARNARVONBASIN
GASCOYNECOMPLEX
GROUPTARCUNYAH
400 kmGROUP
SA
N
T
CamelndashTabletopfault zone
KAHRBANSUBGROUP
CORNELIAFORMATION
MKS37
Figure 7 Regional geological setting of the Savory Group and western Officer Basin The dashed line on the inset map marks the interpreted margin of the greater Officer Basin
16
Tarcunyah Group and consists predominantly of mudstone with minor sandstone limestone
dolomite and anhydrite (Fig 6)
The age of the Tarcunyah Group is uncertain although limited palynological and stromatolite
evidence suggests that it is probably coeval with Supersequence 1 of the Centralian Superbasin
Drillhole LDDH1 contains palynomorphs equivalent to assemblages in the Browne and Bitter
Springs Formations of the Officer and Amadeus Basins respectively and from the Cornelia
Formation in TWB 6 (Grey and Stevens 1997) (Figs 4 and 6) Stromatolite specimens tentatively
assigned to Acaciella australica (Howchin 1914) Walter 1972 occur in the lower Tarcunyah
Group (Bagas et al 1995) The stromatolite Baicalia burra Preiss 1972 and a conical
stromatolite were reported from the upper part of the Tarcunyah Group (Stevens and Grey 1997)
The recognition of two stromatolite assemblages interpreted to have age significance in
Supersequence 1 sedimentary rocks of the Centralian Superbasin has permitted biostratigraphic
correlations between outcrop and well data The Acaciella australica assemblage appears to be
slightly older than 800 Ma and is restricted to the middle part of Supersequence 1 The Baicalia
burra assemblage is considered to be slightly younger than 800 Ma and occurs in the upper part
of Supersequence 1 (Grey 1996b Stevens and Grey 1997) The older A australica assemblage
is recognized in the Skates Hills Formation in the Savory Sub-basin and the stromatolite A
australica itself has been tentatively identified in the lower Tarcunyah Group The occurrence of
the A australica assemblage in the Woolnough Madley and Browne Formations of the Officer
Basin and in the Loves Creek Member of the Bitter Springs Formation of the Amadeus Basin
allows correlations throughout the Centralian Superbasin (Fig 4)
The younger B burra assemblage has not been recognized in sedimentary rocks of the
Savory Group as defined by Williams (1992) but it occurs in the upper parts of the Tarcunyah
Group and allows correlation of this group with outcrops of the Neale Formation and with the
Kanpa Formation in petroleum exploration well Hussar 1 both located in the central Officer Basin
of Western Australia (Fig 4) (Grey 1996b Stevens and Grey 1997) The occurrence of the B
burra assemblage in these units permits their correlation with the Burra Group in the Adelaide
Geosyncline of South Australia (K Grey unpublished data)
The Cornelia Formation and Kahrban Subgroup outcrop in the southeast of the sub-basin and
were considered by Williams (1992) to be part of the Mesoproterozoic Bangemall Basin Limited
evidence suggests that all or parts of these two units are of Neoproterozoic age The Ward and
Oldham Inliers consist of outcrops of the Cornelia Formation Waterbore TWB 6 which was
drilled on TRAINOR in the Cornelia Formation contains palynomorphs consistent with a
Supersequence 1 age (Grey and Stevens 1997) (Figs 5 and 6) In outcrop the Cornelia Formation
17
consists predominantly of sandstone and quartzite with lesser siltstone shale mudstone and chert
In Trainor 1 this formation consists predominantly of indurated mudstone with minor sandstone
chert and dolomite A major erosional unconformity separates the Cornelia Formation from
overlying formations and parts of the Cornelia Formation have been folded with dips exceeding
70deg In contrast the majority of the Savory Sub-basin sedimentary rocks have dips of less than 30deg
except where they are adjacent to faults The Cornelia Formation apparently consists of an older
unit of steeply dipping quartzites cherts and well-indurated mudstones and a younger unit of
shallower dipping sandstones which are sub-friable in parts However caution should be used in
interpreting the age of units based on their structural deformation and additional mapping and age
dating of this formation is required
It is proposed here that the Kahrban Subgroup is likely to be of early Neoproterozoic age and
hence should be considered as part of the greater Officer Basin This proposal is based largely on
the relatively low dip of the strata (generally less than 20deg) and their west-northwest strike which
is parallel with strikes in the overlying Brassey Range Formation of the Savory Group The lower
contact of the Kahrban Subgroup is obscured but is thought to be an unconfirmity on the
Earaheedy Basin on the southeast of STANLEY (Muhling and Brakel 1985)
Structural setting
The Savory Sub-basin forms the most northwesterly sub-basin of the Neoproterozoic to
Phanerozoic Officer Basin The western boundary of the sub-basin with the Mesoproterozoic
Bangemall Basin consists of steep-reverse and strike-slip faults The northeastern boundary of the
Savory Sub-basin was mapped where Supersequence 4 formations of the Savory Group
unconformably overlie sedimentary rocks of the Karara and Yeneena Basins with the two older
units considered to be part of the Paterson Orogen (Williams 1992) This contact was defined as a
series of steeply dipping reverse faults in the northernmost parts of the sub-basin on BALFOUR
DOWNS and RUDALL and was extrapolated as an inferred reverse fault farther along strike to the
southeast on GUNANYA and MADLEY where the contact is obscured by Cainozoic sediments It is
now recognized that all the sedimentary rocks in the Karara Basin and younger sedimentary rocks
of the Yeneena Basin are from the Supersequence 1 Tarcunyah Group and part of the greater
Officer Basin (Bagas et al 1995) The northern boundary of the Tarcunyah Group and the greater
Officer Basin is in thrust-and reverse-faulted contact with the Rudall Complex and other parts of
the Paterson Orogen (Fig 7)
To the south the sub-basin unconformably overlies the Bangemall Basin The eastern
boundary of the sub-basin used in this study is where Permian and younger strata of the Officer
Basin unconformably overlie Neoproterozoic strata although there are no significant structural or
stratigraphic differences between the Neoproterozoic units
18
The sub-basin is subdivided into three principal structural areas (Fig 1) Trainor Platform
Blake Fault and Fold Belt and Wells Foreland Sub-basin (Williams 1992) A major review of
these boundaries is beyond the scope of this report but the processing of regional aeromagnetic
data (Appendix 4) and acquisition of a semi-detailed gravity survey by the GSWA in the east of
the sub-basin has enabled these tectonic units to be reassessed and some modifications are
proposed
The Wells Foreland Sub-basin (originally termed the Wells Foreland Basin in Williams 1992)
and sedimentary rocks of the Tarcunyah Group are both considered to be the northwest
continuation of the Gibson Sub-basin of the Officer Basin Aeromagnetic gravity and outcrop
data suggest that the Blake Fault and Fold Belt is significantly faulted and folded in the west but
is less deformed in the east where the thickest sedimentary section in is located on BULLEN
(Appendix 4) The Trainor Platform is reinterpreted to represent an area of the sub-basin that has
undergone major compression during the Petermann Ranges Orogeny resulting in folding and
faulting with a northwest strike This interpretation contrasts with that proposed by Williams
(1992) who envisaged that only a thin section of the Savory Group was present on the platform
Perincek (1998) has recognized nine periods of tectonic activity in the Officer Basin from the
beginning of the Neoproterozoic to the end of the Cretaceous Three major tectonic episodes are
recognized in the Centralian Superbasin The oldest event is the Areyonga Movement which is
pre-Sturtian and forms the boundary between Supersequences 1 and 2 (Fig 4) The Souths Range
Movement occurred at the end of the Sturtian at the boundary between Supersequences 2 and 3
The youngest major event is the Petermann Ranges Orogeny which occured at the end of the
Marinoan and forms the boundary between Supersequences 3 and 4
One minor and two major tectonic episodes are recognized in the Savory Sub-basin the
LP1ALP1B structural event and the Areyonga Movement and the Petermann Ranges Orogeny
respectively The LP1ALP1B structural event is revealed where the Spearhole Formations rests
disconformably and locally unconformably on the Brassey Range Jilyili and Glass Spring
Formations The Neoproterozoic Areyonga Movement (equivalent to the Blake Movement of
Williams 1992) produced folds and faults with a general northeast strike in the western and
southern parts of the region The Souths Range Movement has not been recognized in the sub-
basin This may be due to the fact that no Sturtian glacial rocks have been identified and hence it
is possible that structures attributed to the Areyonga Movement could be the result of the Souths
Range Movement or a combination of the two movements
The major tectonic event recorded in the sub-basin is the latest Neoproterozoic to Cambrian
Petermann Ranges Orogeny (equivalent to the Paterson Orogeny) which produced large reverse
19
faults thrusts strike-slip faults and folds with a general northwest strike The McFadden
Formation and other Supersequence 4 strata are considered to be at least partially coeval with this
orogeny (Williams 1992) We also interpret the Durba Sandstone as having been deposited during
the later stages of the Petermann Ranges Orogeny as this unit mildly deformed with fold axes
parallel to the strike of other structures attributed to the Petermann Ranges Orogeny
Quantitative aeromagnetic interpretation of the Savory Sub-basin utilizing the 3D Euler
deconvolution method supported by wave-number filtering and image processing has provided
structural trends and depth to magnetic source within the sub-basin (Cowan 1995) Gravity data
are interpreted by Cowan (1995) as changes in both the density of the basement rocks andor
basement topography depending on local conditions Part of Cowanrsquos report is reproduced in
Appendix 4
Exploration history
The only petroleum exploration conducted in the sub-basin has been the recent drilling in the
western part of three diamond drillholes of which two have minor oil shows (Table 2) There has
been some mineral exploration the results of which are stored in the GSWA Western Australian
Mineral Exploration (WAMEX) database system Much of the mineral exploration was in the
southwest and west where the sub-basin is in contact with the Bangemall Basin and along the
northern margin of the sub-basin Many of these mineral exploration programs included
aeromagnetic surveys and surface geochemical sampling (Fig 8)
Hydrocarbon potential
The sub-basin contains a sedimentary succession up to 8 km thick which is generally gently
folded and faulted and apparently unmetamorphosed Limited drilling has shown that thick
mudstones are present in the sub-basin with some mudstones in Trainor 1 having high Total
Organic Carbon (TOC) values Outcrops of sub-friable sandstones in many of the formations
within the sub-basin suggests widespread reservoir potential Mudstone and inferred thick
evaporite sequences are likely to form seals Maturity data suggest that near-surface samples are
approximately at the base of the oil window and top of the gas window in parts of the north and
southeast of the sub-basin However parts of the southwest of the sub-basin and the mudstones in
Trainor 1 have very high levels of maturity Numerous faults and folds have been identified from
surface mapping suggesting good potential for large structural traps Minor oil shows in
20
Table 2 Neoproterozoic formations and hydrocarbon shows in diamond drillholes in the Savory Sub-basin
Drillhole AMG Core TD (m) Approx Formation Depth Formation Depth Formation Depth Shows (AGD84) start (m) GL (m) (m) (m) (m)
LDDH 1 431148E 112 701 350 Tarcunyah 68ndash701 ndash ndash bitumen at 6623 m 7443826N Group Trainor 1 473640E 6 709 455 McFadden 9ndash83 Cornelia Fm 83ndash709 possible bitumen at 4537 m 7287400N Fm Mundadjini 1 319056E 170 600 500 Mundadjini 16ndash361 Spearhole Fm 361ndash600 10 fluorescence at 36102 m 7404844N Fm Boondawari 1 348959E 299 1 367 490 Mundadjini Fm 15ndash312 Spearhole Fm 312ndash1 283 Intrusive 1 283ndash1 367 40 fluorescence at 35364 m 5 7398174N fluorescence at 4963 m Akubra 1 334249E 15 181 530 Mundadjini 15ndash42 Intrusive 42ndash181 None 7401252N Fm
21
50 km
120deg 121deg30 123deg
25deg
24deg
23deg
22deg
Greater Officer Basin
Savory Sub-basin
1
2
3
4
6
8
3 Seismic line (prefixed N83-00)
Aeromagnetic survey
GS
WA
Sav
ory
1995
gra
vity
sur
vey
Gravity survey
MKS34270398
Figure 8 Locations of aeromagnetic and gravity surveys (other than regional BMRAGSO data)
22
sandstones in two petroleum wells in the northwest of the sub-basin and bitumen and oil shows
elsewhere in the region indicate that oil has been generated and migrated through the sub-basin
Source rocks
Source potential is considered to be the major exploration risk in the Savory Sub-basin although
minor oil shows in Mundadjini 1 and Boondawari 1 indicate that at least some oil has been
generated and migrated into potential reservoirs within the sub-basin Sandstone is the
predominant lithology observed in outcrop Outcrops of fine-grained lithologies in the basin are
rare because of intense surface weathering and erosion Only about 8 of the surface area of the
sub-basin is exposed bedrock and recessive lithologies (such as shale evaporite and friable
sandstone) may be present although they rarely outcrop
Outcrops of stromatolitic dolomite with associated cauliflower chert and cubic pseudomorphs
interpreted as being after halite indicate that evaporitic environments are present within the
Mundadjini Skates Hills and Boondawari Formations Evaporitic minerals are also present in
drillhole LDDH1 in the Tarcunyah Group
In 1995 GSWA drilled a continuous-core diamond drillhole (Trainor 1) in the sub-basin on
TRAINOR to a depth of 709 m to test for source rocks thus providing the first such data for the sub-
basin The drillhole intersected flat-lying clastics and carbonates of the McFadden Formation (9ndash
83 m) overlying indurated mudstones of the Cornelia Formation (83ndash709 m total depth) dipping at
about 40deg Of the six samples analysed from the Cornelia Formation in this drillhole the five
located between 375 and 6032 m depth have TOC values exceeding 05 (range 066ndash365)
Rock-Eval pyrolysis of these five samples indicates that they are at best in the dry-gas thermal
stage and as a result of their high level of maturation (Stevens and Adamides in prep) have poor
remaining hydrocarbon-generating potential Although the Cornelia Formation is overmature at
Trainor 1 the high TOC values are encouraging as it is likely that this sequence is less mature
elsewhere in the sub-basin
The Mundadjini Formation contains potential source rocks that comprise marine mudstones
with evaporitic minerals present in parts Thin dark mudstones were intersected in the Mundadjini
Formation in Akubra 1 In Mundadjini 1 and Boondawari 1 however the mudstones appear to be
too oxidized to have source potential
The Boondawari Formation also may be a source rock as it contains black mudstones The
unit is laterally equivalent to the Pertatataka Formation of the Amadeus Basin and the Ungoolya
23
Group of the Officer Basin in South Australia both of which have some source potential
(Summons and Powell 1991 Morton and Drexel 1997) Samples from the Dey Dey Mudstone of
the Ungoolya Group generally have poor TOC values (average 011 range 003ndash081)
moderate hydrogen index (HI) values (100ndash382) and poor to fair genetic potential with a
maximum of 292 kg hydrocarbon per tonne of source rock (Morton and Drexel 1997)
Stromatolitic dolomites and mudstones at the top of the Boondawari Formation and within the
Skates Hills Formation are potential source rocks Stromatolitic dolomite and evaporitic rocks
deposited in a marginal marine to sabkha environment are considered to have good potential to
generate and preserve organic carbon without requiring a deep-water setting (Stevens and Grey
1997) Such conditions are recognized in the Skates Hills Formation and in the upper parts of the
Tarcunyah Group
Maturity
Knowledge of the maturity of sedimentary rocks within the Savory Sub-basin is still limited From
a review of palynological studies Grey and Stevens (1997) report that the thermal maturity
inferred from the Thermal Alteration Index (TAI) of 3+ from Supersequence 1 age palynomorphs
in TWB 6 TWB 9 and LDDH1 is within the hydrocarbon window (Appendix 3) In Phanerozoic
spores and pollen a TAI of 3+ approximately equates to the end of liquid petroleum generation
and the start of dry gas generation and to a vitrinite reflectance of about 13 (Traverse 1988)
However the use of TAI for estimating thermal maturity from Neoproterozoic palynomorphs
requires calibration
In Trainor 1 the Cornelia Formation contains organically rich claystones between 375 and
6032 m depth Based on Rock-Eval maturity data (Stevens and Adamides in prep) and the dark
colour of poorly preserved organic material (Grey 1995de 1996) with TAI 4- to 5 all samples
had a high level of maturation with at best dry-gas generating potential remaining In contrast
drillhole LDDH1 on GUNANYA recorded lower levels of maturity (TAI values of 3+) with two of
sixteen samples from the Tarcunyah Group having greater than 1 TOC (Grey 1995abc Grey
and Cotter 1996) Organic petrology and Rock-Eval maturity data for samples from LDDH1
indicate that the section above 500 m is within the oil-generative window whereas below 500 m
the rocks are within the gas window (Ghori in prep Fig 9 Appendix 5)
Waterbores TWB 1 2 6 and 9 which are located on TRAINOR in the southeast of the sub-
basin all had organic matter with TAI values of 3+ from the McFadden Skates Hills Cornelia
and Brassey Range Formations respectively
24
100
200
300
400
500
600
700
Oil
gene
ratin
g
Gas
gene
ratin
g
Fai
r
Fai
r
Poo
r
Poo
r
Goo
d
Imm
atur
e
Oil
win
dow
Oil
win
dow
Imm
atur
e
01 0110 10 0 150 300 440 480 1
Neo
prot
eroz
oic
TOC S1+S2 mgg Hydrogen Index Tmax degC
Depth(m)
Organicrichness
Generatingpotential
Kerogentype Maturity Maturity
TD=701m
Sandstone
Mudstone
Dolomite
Limestone
Evaporite
Source rock
MKS40 070498
Ro equivalent
Figure 9 Petroleum source potential of rocks in Normandy LDDH1
Small amounts of organic matter associated with basalt and dolerite in cuttings from
waterbore BWB 1 on BULLEN showed high levels of thermal maturity (Grey 1995a Libby 1995)
It is unclear whether all sedimentary rocks on BULLEN are overmature for hydrocarbon generation
or the results from BWB 1 are related to local heating events associated with the volcanic bodies
that are common in the Jilyili Formation
25
Reservoirs
Each of the five depositional sequences of the Savory Group (Table 1) are inferred to contain
significant sandstone reservoirs with the possible exception of depositional sequence C as
discussed above in Stratigraphy The Spearhole Formation was cored in Mundadjini 1 and
Boondawari 1 and visual estimates of porosity vary from generally poor (less than 5) to fair
(approximately 5ndash15) The McFadden Formation in Trainor 1 has porosity values of up to 232
and a maximum permeability of 195 md (Stevens and Adamides in prep) Sandstones from
Neoproterozoic formations form the acquifers in the following waterbores the McFadden
Formation in TWB 1 the Cornelia Formation in TWB 6 and the Brassey Range Formation in
TWB 8 and TWB 9 (Appendix 6 Table 61)
Based on outcrop observations the Durba Sandstone is considered to be the best reservoir of
the Savory Group Similarly some sandstones from the Tarcunyah Group also have good visible
porosity in outcrop
Dolomites occur in several formations in the sub-basin Reservoir potential may exist
particularly where the dolomites are stromatolitic and oolitic However dolomites have not been
drilled in the sub-basin and porosity can only be inferred from the preferential silicification of
some stromatolite bioherms observed in outcrop (Stevens and Grey 1997) Elsewhere in the
Officer Basin porosities of up to10 have been measured in dolomites A limestone breccia
(karst) is described from 663 to 677 m in drillhole LDDH1 (Fig 6 Busbridge 1994)
Seals
Indications of evaporitic environments in the Mundadjini Skates Hills and Boondawari
Formations are described by Williams (1992) In Mundadjini 1 from 287 to 337 m anhydrite and
chert occurs as nodules beds and veins in mudstone of the Mundadjini Formation Evaporitic
minerals (predominantly gypsum) are described in the Tarcunyah Group in LDDH1 The presence
of the Woolnough and Madley salt diapirs in the Officer Basin (approximately 110 km east of the
sub-basin) and halite beds over 25 m thick in the well Hussar 1 (130 km east of the sub-basin)
provide further evidence that evaporite seals may be present in the Savory Sub-basin
Mudstones and shales form only a small proportion of the limited Neoproterozoic outcrop in
the sub-basin but significant thicknesses of mudstone were encountered in the Mundadjini
Formation in Mundadjini 1 and Boondawari 1 the Tarcunyah Group in LDDH1 and in the
26
Cornelia Formation in Trainor 1 These data suggest that mudstones form a significant proportion
of strata in the sub-basin despite their limited outcrop
Traps
Potential structural closures including folds and faults occur at various scales throughout the
Savory Sub-basin However the region has only been mapped at 1250 000 scale and
independently closed structures such as domes have yet to be confirmed The western margin of
the basin contains abundant faults (with a northeast strike) but elsewhere faults are less common
Some anticlines are recognized in outcrop including one with a strike length of up to 45 km
inferred from surface bedding dips in the Mundadjini and Spearhole Formations at approximately
24deg15rsquoS 121deg10rsquoE on BULLEN (Fig 1)
Salt diapirs and other halokinetic structures are recognized in outcrop well and seismic data
in the Officer Basin to the west of the Savory Sub-basin and it is probable that there are
significant thicknesses of evaporitic sedimentary rocks in the sub-basin The gravity field data
suggest there is good potential for salt diapirs and traps related to halokinesis
Although there is potential for stratigraphic traps to be present in the sub-basin insufficient
data are available to assess them
Preservation of hydrocarbons
The range of thermal maturities measured to date and the large periods of time envisaged for
deposition of sediments implies hydrocarbon generation may have occurred a number of times
during the evolution of the Savory Sub-basin Any hydrocarbons that were generated early may
have been trapped in palaeostructures and remigration to younger traps could have taken place
later The Petermann Ranges Orogeny which has been equated with the Paterson Orogeny (Myers
1990) is believed to have occurred in the latest Neoproterozoic to early Cambrian This is the last
major tectonic event recognized in the sub-basin suggesting that it is reasonable to expect that trap
integrity will have been preserved
If the inference of the presence of thick halite beds in the sub-basin is correct the preservation
potential of sub-salt traps should be excellent
27
Reported hydrocarbon shows and oil seep
Amadeus Petroleum recorded minor oil shows in cores from Mundadjini 1 and Boondawari 1 In
Mundadjini 1 at 36102 m (top of the Spearhole Formation) a 3 mm thick zone had 10 moderate
white fluorescence with slow solvent cut This show was in a granular sandstone with visually
estimated porosity of about 10 In Boondawari 1 at 35364 m (within the Spearhole Formation) a
broken surface of sandstone had 40 moderate yellow-white fluorescence with slow solvent cut
Visually estimated porosity is about 5 Because the fluorescing surface was broken during the
drilling process this show could have resulted from contamination A second show occurs in
Boondawari 1 at 4963 m (within the Spearhole Formation) where a 1 cm-thick zone had 5 dull
yellow fluorescence with slow solvent cut in a conglomerate with visually estimated porosity of
about 10 The company intends to further investigate the nature of these occurrences
Minor bitumen is present at 6623 m in drillhole LDDH1 on GUNANYA (Figs 5 and 6) as a
vein in mudstones of the Tarcunyah Group A sample was analysed by gas chromatography
(Ghori in prep) and confirmed that it is natural bitumen (Appendix 5)
Mineral hole OD 23 drilled by Jubilee Gold Mines NL on NABBERU in the Bangemall Basin
immediately to the south of the Savory Sub-basin (Fig 5) encountered bitumen and trace oil in
vugs in dolomite (M Stevens unpublished data) but no further data are available at present
In their popular guide to the Canning Stock Route Gard and Gard (1990 p 218) refer to an
oil seep at Well 13 on TRAINOR (Fig 5) They reported that between 1977 and 1984 lsquonatural oilrsquo
was seen in the well Although the well is now largely filled with sediment four auger drill
samples were collected by the GSWA in 1995 and all four were analysed for oil shows One
sample from 315 m total depth (GSWA sample 135604) yielded just enough extract (519 ppm)
for saturate gas chromatography analysis The gas chromatograph (Appendix 5) shows that the
extract does contain some hydrocarbons probably from recent plant material Because the depth to
the oil was not quoted in Gard and Gard (1990) the hand-augered well may not have been deep
enough to properly test this reported seep
Geological and geophysical databases
Geological and geophysical data available for the Savory Sub-basin are limited The most recently
completed geological maps for the sub-basin were published by the GSWA between 1991 and
1995 (Williams and Tyler 1991 Williams 1992 1995ab)
28
The cores from the five drillholes listed in Table 2 believed to be all of the core available
from the sub-basin are available for inspection at GSWA Mineral exploration reports submitted
to GSWA may be searched using the WAMEX database and open-file reports are available on
microfiche Geophysical data acquired by the mining industry is not required to be filed with
GSWA if acquired over Vacant Crown Land which is the case for much of the sub-basin
Geophysical survey data submitted in mining tenement reports and which extend into Vacant
Crown Land remain confidential to the companies Original regional aeromagnetic and gravity
datasets are available from the Australian Geological Survey Organisation (AGSO)
Data pertinent to oil exploration in the sub-basin such as structural style and salt diapirism
are presented in a review of the hydrocarbon prospectivity of the Officer Basin (Perincek 1998)
Drilling
Significant drillholes in the sub-basin are summarized in Table 2
Petroleum industry data
Amadeus Petroleum drilled three petroleum exploration wells in the central west of the Savory
Sub-basin in late 1997 These wells Mundadjini 1 Boondawari 1 and Akubra 1 were drilled by
continuous diamond coring (Figs 5 and 6) All targeted potential reservoirs within the Spearhole
Formation with the Mundadjini Formation as the proposed seal The wells were located on
structures interpreted from Landsat images and limited geological investigations Both Mundadjini
1 and Boondawari 1 had minor oil shows as discussed above (Reported hydrocarbon shows)
Government data
Stratigraphic drillhole Trainor 1 was drilled by GSWA in 1995 (Stevens and Adamides in prep)
and the main results are discussed above (Source rocks and Maturity)
Mineral industry data
Normandy Exploration drillhole LDDH1 was cored in the Tarcunyah Group to a total depth of
701 m and provided source-rock and maturity data as discussed above
29
Oilmin NL drilled six percussion drillholes (BD 1 3 4 5 8 and 9) through sandstones and
shales in the northern part of the Savory Sub-basin to a maximum depth of 198 m (Fig 5
WAMEX Microfiche File M 26811 I 2610) but only brief geological descriptions are available
Hydrogeological data
Hydrogeological data within the Savory Sub-basin are limited although a long history of water
exploration extends back to the construction of the Canning Stock Route early this century No
detailed geological or wireline logs are available for the older wells along this route A few station
wells have been drilled by various methods on the south and west margins of the basin but data
are unavailable as reports are not required to be filed with the government Depth to watertable
throughout the basin is largely controlled by porosity of the bedrock
The GSWA drilled fifteen waterbores in the winter of 1995 in the southern part of the sub-
basin in preparation for the drilling of Trainor 1 and the proposed Bullen 1 Twelve bores found
water and six of these bores have salinities of less than 1000 mgL (Fig 5 Appendix 6 Table 61)
One waterbore TWB 6 has gamma ray and neutron logs run through PVC casing and these are
available from the GSWA with the digital log data included herein
Seismic data
No geophysical data have been acquired by the petroleum industry in the Savory Sub-basin
Seismic data acquired in the Officer Basin to the east particularly in the Gibson and Yowalga
Sub-basins is pertinent to structural interpretation in the Savory Sub-basin (Perincek 1996a
1998)
Aeromagnetic surveys
Government data
There are over 95 277 line kilometres of aeromagnetic data included in the AGSO dataset There
are three regional aeromagnetic surveys covering the Savory Sub-basin These were flown by the
Bureau of Mineral Resources (BMR now AGSO) in 1984 at a line spacing of 1500 m with 36 740
and 52 587 line kilometres flown and by Aerodata in 1984 at a line spacing of 1000m with 5950
line kilometres flown These data were reprocessed and interpreted for GSWA by Cowan (1995)
An edited copy of this report is included as Appendix 4 and the original report is filed in the
GSWA Library under S-series reports item 10331
30
Mineral industry data
The approximate locations of non-AGSO aeromagnetic surveys are shown in Figure 8 More
detailed information regarding the location of these surveys may be obtained using the GSWA
MAGCAT II database Additional information such as contours of aeromagnetic values may be
obtained by inspecting items on file with the GSWA
Gravity surveys
Government data
The average spacing for gravity data in the Savory Sub-basin is one station per 121 km2 (11 times 11
km grid) These data were principally collected by BMR in the early 1960s There are a few
additional regional gravity traverses across the sub-basin which are also included in the
BMRAGSO dataset These data were reprocessed and interpreted for GSWA (Fig 10) and a
report on this work is also included in Appendix 4
The GSWA completed a large semi-detailed gravity survey in the eastern Savory Sub-basin
utilizing helicopter support and Differential Global Positioning Survey (DGPS) techniques (Fig
8) This gravity survey completed in August 1995 consists of 2300 gravity stations on a 2 times 3 km
grid All stations were acquired by helicopter using Scintrex gravimeters and Ashtek dual
frequency DGPS equipment for determining location This highly efficient system allowed the
acquisition of more than 100 gravity stations per day in remote areas The resolution of this survey
is +30 cm and +05 microms-2 (Daishsat 1995) These data (Fig 11) represent a significant
improvement on the previous regional survey data and are available from GSWA (GSWA
1996ab) The results of the interpretation of these data were presented at the 1997 ASEG
Convention (Carlsen and Shevchenko 1997)
Mineral industry data
Three small gravity surveys were conducted by Oilmin NL (Fig 8) and the relevant WAMEX
reports are M 2681I 2610 I 2435 I 2567 These three surveys are of limited value because height
control was provided by barometers only and the surveys were not tied to the national gravity grid
31
23deg
25deg
120deg 122deg
Trainor 1
SAVORY
SUB-BASIN
MKS54 160498
100 km
1995 SavoryGravity Survey
254
-1056
micromsec2
Figure 10 Regional Bouguer gravity map of the Savory Sub-basin
23deg
24deg
25deg
122deg30 123deg
TRAINOR 1
123deg30
50 km
MKS53 160498
-116
-626
micro msec2
Figure11 Detailed Bouguer gravity map of the
Savory 1995 Gravity Survey from the eastern Savory Sub-basin
32
Government and academic reports
Chronostratigraphy and geochemistry
The understanding of Neoproterozoic organic chemistry palynology and structural evolution is
essential to the interpretation of hydrocarbon prospectivity Pertinent reports are included in the
bibliography (Appendix 1) Unpublished palaeontology reports describe the palynology of wells in
the Savory Sub-basin (Grey 1995andashe 1996a) Grey and Cotter (1996) discussed the potential for
Neoproterozoic palynomorphs to provide a biostratigraphic framework and palaeoenvironmental
interpretation Grey and Stevens (1997) reviewed the results of palynological studies of wells
drilled in the sub-basin and reported that Supersequence 1 palynomorphs are present in TWB 6
TWB 9 and LDDH1 (Appendix 3) Grey (1996b) reported on the use of stromatolites for
correlation in the Neoproterozoic and Stevens and Grey (1997) discussed the application of
stromatolite biostratigraphy in correlating isolated dolomite outcrops in the sub-basin with well
and seismic data in the Officer Basin and Centralian Superbasin
Although geochemical data from the Savory Sub-basin are very limited results mostly
confirm thermal maturities inferred from TAI for LDDH1 and Trainor 1 (Ghori in prep Stevens
and Adamides in prep) Those parts of the Officer Basin in Western Australia which lie to the
east of the Savory Sub-basin are sparsely drilled but Ghori (in prep) reports that most of the
Neoproterozoic succession presently lies within the oil-generative window However his study
has been unable to identify effective source-rock units and the source for oil shows Thin source
rocks are present in the Neoproterozoic in LDDH1 (Fig 9) and in three wells which lie to the east
and southeast of the Savory Sub-basin namely NJD 1 Kanpa 1A and Yowalga 3
Proposed work program
From the above limited information it is concluded that additional research on the hydrocarbon
potential of the sub-basin is justified and proposals are outlined below
bull Additional modelling of gravity and aeromagnetic data from the Savory Sub-basin is required
in light of the results from Trainor 1 and Boondawari 1 Trainor 1 showed that what appeared
to be a structurally simple area based on outcrop aeromagnetic and gravity data was in fact an
area of major structuring Boondawari 1 intersected a dolerite which is in good depth
agreement with aeromagnetic depth to source results showing this technique is useful in
detecting the depth to intrusive bodies
33
bull Additional data from mineral and petroleum exploration bores may become available and
analysis of samples from these wells should be undertaken and interpreted in the context of
their relevance to the Officer Basin
bull Stratigraphic coring in the Blake Fault and Fold Belt and in the Wells Foreland Sub-basin (Fig
1) targeting source rocks is considered essential to the continuing evaluation of the
hydrocarbon prospectivity of the Savory Sub-basin
bull Correlations using at least outcrop well and potential-field data should be prepared to link the
sub-basin with the better known parts of the Officer Basin to the east
bull Remapping is required to clarify boundary positions within the Cornelia Formation this may
resolve some of the current problems of the relationship between this unit and the rest of the
Savory Sub-basin
bull Further work is required to explain the Early Cambrian or Sturtian ages interpreted for the
Cornelia Formation from sedimentary zircon UndashPb dating in drillhole Trainor 1 The
determination of the age of the organically rich but overmature claystones in this well is
critical to assessing the hydrocarbon potential of the region
bull The thin dark mudstones intersected by Akubra 1 in the Mundadjini Formation warrant
geochemical analysis Analyses of the oil shows in Mundadjini 1 and Boondawari 1 are
currently being undertaken by Amadeus Petroleum
bull Geochemical analysis of hydrocarbons in the Bangemall Basin drillhole OD23 has been
performed by Jubilee Gold and the results will be reviewed when they are submitted to
GSWA The possibility of source rocks within the Bangemall Basin charging traps within the
Bangemall Basin and the overlying Savory Sub-basin requires further investigation
Conclusions
The Savory Sub-basin is a frontier region with only three recently drilled petroleum exploration
wells and no seismic data Based on existing geological and geophysical data it is considered too
early to draw conclusions about the hydrocarbon prospectivity of the sub-basin at this stage and
there are several reasons why the area warrants further investigation
34
1 Thick accumulations of sedimentary rocks are present (up to 8 km thickness inferred) which
may contain source reservoir and sealing strata
2 Minor oil shows occur in Mundadjini 1 and Boondawari 1 and bitumen is present in mineral
exploration drillhole LDDH1 suggesting that hydrocarbons have migrated within the
Neoproterozoic sequence of the Savory Sub-basin Oil and bitumen are present in mineral
exploration drillhole OD23 in the Bangemall Basin immediately to the south of the Savory
Sub-basin and it is possible that source rocks from the Bangemall Basin could charge traps in
the overlying Savory Sub-basin
3 The age of sedimentary rocks in the sub-basin is still poorly constrained but some of the
Neoproterozoic sedimentary rocks located on GUNANYA and TRAINOR are within the
hydrocarbon-generation window It is possible that a significant thickness of Phanerozoic
sedimentary rocks may also be present
4 Friable sandstones with visible porosity outcrop extensively suggesting numerous potential
reservoirs
5 Significant but not intense faulting and folding has been mapped implying large structural
traps may be present
6 Evaporitic sedimentary rocks occur in several formations and may provide good source rocks
and excellent seals
35
References
APAK S N and CARLSEN G M 1997 A compilation and review of data pertaining to the
hydrocarbon prospectivity of the Canning Basin Western Australia Geological Survey
Record 199610 103p
BAGAS L GREY K and WILLIAMS I R 1995 Reappraisal of the Paterson Orogen and
Savory Basin Western Australia Geological Survey Annual Review 1994ndash95 p 55ndash63
BUSBRIDGE M 1994 Lake Disappointment Exploration Licence 451064 Third Annual
Report Lake Disappointment Diamond Drill Hole LDDH1 Normandy Exploration Limited
Western Australia Geological Survey M-series Item 7567 A41358 (unpublished)
CARLSEN G M and SHEVCHENKO S I 1997 Petroleum exploration in Proterozoic basins
using potential fields data and stratigraphic coring Australian Society of Exploration
Geophysicists 12th Geophysical Conference Handbook Sydney 1997 Preview no 66 p 83
(abstract only)
COWAN D 1995 Savory Basin quantitative magnetic interpretation Western Australia
Geological Survey S-series S10331 (unpublished)
DAISHSAT PTY LTD 1995 Operational and processing report Savory Basin gravity survey
Western Australia Geological Survey S-series S10332 (unpublished)
GARD E and GARD R 1990 Canning Stock Route a travellerrsquos guide for a journey through
history Perth Western Australia Western Desert Guides 448p
GEOLOGICAL SURVEY OF WESTERN AUSTRALIA 1996a Savory Basin first vertical
derivative of Bouguer gravity image 1250 000 Western Australia Geological Survey
GEOLOGICAL SURVEY OF WESTERN AUSTRALIA 1996b Savory Basin Bouguer gravity
image 1250 000 Western Australia Geological Survey
GHORI K A R in prep Petroleum source rock potential and thermal history Officer Basin
Western Australia Western Australia Geological Survey Record
36
GREY K 1995a Savory Basin drillhole BWB 1 (Bullen waterbore) palynology and thermal
maturation GSWA Palaeontology Report no 199512 (unpublished)
GREY K 1995b Savory Basin drillholes TWB 1 2 6 9 (Trainor waterbores) palynology and
thermal maturation GSWA Palaeontology Report no 199520 (unpublished)
GREY K 1995c Palynology of Normandy-Poseidon Lake Disappointment-1 corehole
Tarcunyah Group Paterson Orogen GSWA Palaeontology Report no 199521 (unpublished)
GREY K 1995d Savory Basin drillhole Trainor 1 (Trainor diamond drilling) palynology and
thermal maturity GSWA Palaeontology Report no 199524 (unpublished)
GREY K 1995e Savory Basin drillhole Trainor 1 (Trainor diamond drilling) Additional
Preparation of two samples GSWA Palaeontology Report no 199528 (unpublished)
GREY K 1995f Neoproterozoic stromatolites from the Skates Hills Formation Savory Basin
Western Australia and a review of the distribution of Acaciella australica Australian Journal
of Earth Sciences v 42 p 123ndash132
GREY K 1996a Savory Basin drillhole Trainor 1 (Trainor diamond drilling) Additional
samples palynology and thermal maturation GSWA Palaeontology Report no 199615
(unpublished)
GREY K 1996b Preliminary stromatolite correlations for the Neoproterozoic of the Officer
Basin and a review of Australia-wide correlations GSWA Palaeontology Report no 199615
(unpublished)
GREY K and COTTER K L 1996 Palynology in the search for Proterozoic hydrocarbons
Western Australia Geological Survey Annual Review for 1995ndash96 p 70ndash80
GREY K and STEVENS M K 1997 Neoproterozoic palynomorphs of the Savory Sub-basin
Western Australia and their relevance to petroleum exploration Western Australia
Geological Survey Annual Review for 1996ndash97 p 49ndash54
HUBBARD R J PAPE J and ROBERTS D G 1985 Depositional sequence mapping as a
technique to establish tectonic and stratigraphic framework and evaluate hydrocarbon
potential on a passive continental margin in Seismic stratigraphy II an integrated approach
37
edited by O R BERG and D G WOOLVERTON American Association of Petroleum
Geologists Memoir 39 p 79ndash91
LIBBY WG 1995 A petrological report on six samples of bore cuttings from the Savory Basin
Western Australia Western Australia Geological Survey S-series S31307 (unpublished)
MORTON JGG and DREXEL JF 1997 The petroleum geology of South Australia Vol 3
Officer Basin South Australia Department of Mines and Energy Resources Report Book
9719
MUHLING P C and BRAKEL A T 1985 Geology of the Bangemall Group mdash the evolution
of an intracratonic Proterozoic basin Western Australia Geological Survey Bulletin 128
219p
MYERS J S 1990 Precambrian tectonic evolution of part of Gondwana southwestern Australia
Geology v18 p 537ndash540
NELSON D R 1997 Compilation of SHRIMP UndashPb zircon data Western Australia Geological
Survey Record 19972 196p
PAYTON C E 1977 Seismic stratigraphy mdash applications to hydrocarbon exploration
American Association of Petroleum Geologists Memoir 26 516p
PERINCEK D 1996a The age of NeoproterozoicndashPalaeozoic sediments within the Officer Basin
of the Centralian Super-basin can be constrained by major sequence-bounding unconformities
APPEA Journal v 36 pt 1 p 350ndash368
PERINCEK D 1996b The stratigraphic and structural development of the Officer Basin
Western Australia a review Western Australia Geological Survey Annual Review 1995ndash
1996 p 135ndash148
PERINCEK D 1998 A compilation and review of data pertaining to the hydrocarbon
prospectivity of the Officer Basin Western Australia Geological Survey Record 19976
POSAMENTIER H W JERSEY M T and VAIL P R 1988 Eustatic controls on clastic
deposition 1 mdash Conceptual framework in Sea-level changes an integrated approach edited by
C K WILGUS B S HASTINGS C G St C KENDALL H W POSAMENTIER
38
C A ROSS and J C VAN WAGONER Society of Economic Paleontologists and
Mineralogists Special Publication no 42
STEVENS M K and ADAMIDES N G in prep GSWA Trainor 1 well completion report
Savory Sub-basin Officer Basin Western Australia with notes on petroleum and mineral
potential Western Australia Geological Survey Record 199612
STEVENS M K and GREY K 1997 Skates Hills Formation and Tarcunyah Group Officer
Basin mdash carbonate cycles stratigraphic position and hydrocarbon prospectivity Western
Australia Geological Survey Annual Review for 1996ndash97 p 55ndash60
SUMMONS RE and POWELL C McA 1991 Petroleum source rocks of the Amadeus Basin
in Geological and geophysical studies in the Amadeus Basin central Australia edited by R J
KORSCH and JM KENNARD Australia BMR Geology and Geophysics Bulletin 236
TRAVERSE A 1988 Palaeopalynology Boston Unwin Hyman 600p
VAIL P R MITCHUM R M Jr TODD R G WIDMIER J M THOMPSON S III
SANGREE J B BUBB J N and HATLELID W G 1977 Seismic stratigraphy and
global changes of sea level in Seismic stratigraphy mdash applications to hydrocarbon
exploration edited by C E PAYTON American Association of Petroleum Geologists
Memoir 26 516p
WALTER M R and GORTER J 1994 The Neoproterozoic Centralian Superbasin in Western
Australia the Savory and Officer Basins in The sedimentary basins of Western Australia
edited by P G PURCELL and R R PURCELL Petroleum Exploration Society of Australia
Symposium Perth WA 1994 Proceedings p851ndash864
WALTER M R GREY K WILLIAMS I R and CALVER C R 1994 Stratigraphy of the
Neoproterozoic to early Palaeozoic Savory Basin and correlation with the Amadeus and
Officer Basins Australian Journal of Earth Sciences v 41 p 533ndash546
WALTER M R VEEVERS J J CALVER C R and GREY K 1995 Neoproterozoic
stratigraphy of the Centralian Superbasin Australia Precambrian Research v 73 p 173ndash195
WILLIAMS I R 1992 Geology of the Savory Basin Western Australia Western Australia
Geological Survey Bulletin 141 115p
39
WILLIAMS I R 1995a Bullen WA (2nd Edition) Western Australia Geological Survey
1250 000 Geological Series Explanatory Notes 23p
WILLIAMS I R 1995b Trainor WA (2nd Edition) Western Australia Geological Survey
1250 000 Geological Series Explanatory Notes 31p
WILLIAMS I R and TYLER I M 1991 Robertson WA (2nd edition) Western Australia
Geological Survey 1250 000 Geological Series Explanatory Notes 36p
40
41
Appendix 1
Bibliography
Reports which are relevant to this investigation but which are not specifically cited are listed
below
BAILLIE P W POWELL C McA LI Z X and RYALL A M 1994 The tectonic
framework of Western Australiarsquos Neoproterozoic to recent sedimentary basins in The
sedimentary basins of Western Australia edited by P G PURCELL and R R PURCELL
Petroleum Exploration Society of Australia Symposium Perth WA 1994 Proceedings p
45ndash62
BRADSHAW M T BRADSHAW J MURRAY A P NEEDHAM D J SPENCER L
SUMMONS R E WILMOT J and WINN S 1994 Petroleum systems in West Australian
basins in The sedimentary basins of Western Australia edited by P G PURCELL and R R
PURCELL Petroleum Exploration Society of Australia Symposium Perth WA 1994
Proceedings p 93ndash118
CLARKE G L 1991 Proterozoic tectonic reworking in the Rudall Complex Western Australia
Australian Journal of Earth Science v38 p 31ndash44
COCKBAIN A E and HOCKING R M 1990 Phanerozoic in Geology and mineral resources
of Western Australia Western Australia Geological Survey Memoir 3 p 750ndash755
ETHERIDGE M and WALL V 1994 Tectonic and structural evolution of the Australian
Proterozoic 12th Australian Geological Convention Geological Society of Australia
Abstracts no 37 p 102ndash103
GOODE A D T 1981 Proterozoic geology of Western Australia in Precambrian of the
Southern Hemisphere Developments in Precambrian geology 2 edited by I R HUNTER
Amsterdam Elsevier p 105ndash203
GREY K and JACKSON M J 1983 A re-assessment of stromatolite evidence for the
correlation of the Late Proterozoic Neale and Ilma Beds Officer Basin Western Australia
Australia BMR Journal of Australian Geology and Geophysics v 8 p 359
42
HICKMAN A H WILLIAMS I R and BAGAS L 1994 Proterozoic geology and
mineralization of the TelferndashRudall region Paterson Orogen Geological Society of Australia
(WA Division) Excursion Guidebook no 5 56p
HOCKING R M MORY A J and WILLIAMS I R 1994 An atlas of Neoproterozoic and
Phanerozoic basins of Western Australia in The sedimentary basins of Western Australia
edited by P G PURCELL and R R PURCELL Petroleum Exploration Society of Australia
Symposium Perth WA 1994 Proceedings p 21ndash 44
JACKSON P R 1966 Geology and review of exploration Officer Basin Western Australia
Hunt Oil Company Western Australia Geological Survey S-series S26 (unpublished)
JACKSON M J 1971 Notes on a geological reconnaissance of the Officer Basin Western
Australia Australia BMR Geology and Geophysics Record 19715 30p
JACKSON M J and van de GRAAFF W J E 1981 Geology of the Officer Basin Western
Australia Australia BMR Geology and Geophysics Bulletin 206 102 p
LOWRY D C JACKSON M J van de GRAAFF W J E and KENNEWELL P J 1971
Preliminary result of geological mapping in the Officer Basin Western Australia Western
Australia Geological Survey Annual Report for 1971 p 50ndash56
MYERS J S 1990 Precambrian in Geology and mineral resources of Western Australia
Western Australia Geological Survey Memoir 3 p 737ndash750
MYERS J S SHAW R D and TYLER I M 1994 Proterozoic tectonic evolution of
Australia 12th Australian Geological Convention Geological Society of Australia Abstracts
no 37 p 312
NEDIN C and JENKINS R J F 1991 Re-evaluation of unconformities separating the
lsquoEdiacaranrsquo and Cambrian systems South Australia Palaios v 6 p 102ndash108
PHILLIPS B J JAMES A W and PHILIP G M 1985 The geology and hydrocarbon
potential of the north-western Officer Basin APEA Journal 25 (1) p 52ndash61
POWELL C McA LI Z X McELHINNY M W MEERT J G and PARK J K 1993
Paleomagnetic constraints on timing of the Neoproterozoic breakup of Rodinia and Cambrian
formation of Gondwana Geology v 21 p 889ndash892
43
POWELL C McA PREISS W V GATEHOUSE C G KRAPEZ B and LI Z X 1994
South Australian record of a Rodinian epicontinental basin and its mid-Neoproterozoic
breakup to form the Palaeo-Pacific Ocean Tectonophysics v 237 no 3ndash4 p 113ndash140
PREISS W V 1976 Proterozoic stromatolites from the Nabberu and Officer Basins Western
Australia and their biostratigraphic significance South Australia Geological Survey Report
of Investigations no 47 p 1ndash51
TOWNSON W G 1985 The subsurface geology of the western Officer Basin mdash results of
Shellrsquos 1980ndash1984 petroleum exploration campaign APEA Journal v 25 (1) p 34ndash51
WATTS K J 1982 The geology of the Townsend Quartzite Upper Proterozoic shallow water
deposit of the Northern Officer Basin Western Australia Perth University of Western
Australia BSc honours thesis (unpublished)
WELLS A T and KENNEWELL P J 1974 Evaporite exploration in the Officer Basin
Western Australia at the Madley Diapirs Australia BMR Record 1974194 (unpublished)
WILLIAMS I R and MYERS J S 1990 Paterson Orogen in Geology and mineral resources
of Western Australia Western Australia Geological Survey Memoir 3 p 274ndash286
WILLIAMS I R 1990 Savory Basin in Geology and mineral resources of Western Australia
Western Australia Geological Survey Memoir 3 p 329ndash334
WILLIAMS I R 1994 The Neoproterozoic Savory Basin Western Australia in The
sedimentary basins of Western Australia edited by P G PURCELL and R R PURCELL
Petroleum Exploration Society of Australia Symposium Perth WA 1994 Proceedings p
841ndash850
WILSON R B 1967 Woolnough Hills and Madley diapiric structures Gibson Desert WA
APEA Journal v 7 p 94ndash102
44
Appendix 2
Meteorological data (from Bureau of Meteorology Perth 1994)
Table 21 Wiluna rainfall (mm)
Year Jan Feb Mar Apr May Jun Jul Aug Sept Oct Nov Dec
1975 0 45 446 309 306 59 276 4 34 886 638 164 1976 16 154 12 138 53 16 34 62 12 238 0 2 1977 44 0 66 74 68 95 24 363 1 58 12 727 1978 234 522 94 16 0 96 367 24 16 353 185 45 1979 19 173 122 88 91 4 0 246 58 0 169 114 1980 148 764 68 1081 259 626 629 06 56 02 174 0 1981 123 476 192 32 196 118 44 74 14 0 28 312 1982 374 705 206 244 1079 92 02 143 368 526 368 118 1983 1 112 928 248 0 212 56 32 5 1 42 496 1984 149 7 342 84 836 0 348 132 224 04 16 172 1985 596 483 0 166 556 0 514 56 0 0 4 0 1986 0 154 35 0 0 1085 23 01 239 137 0 04 1987 1204 119 19 89 17 575 154 126 07 1 0 398 1988 46 202 164 13 388 0 202 104 0 0 224 1309 1989 207 234 26 703 278 536 57 0 01 0 144 02 1990 1035 23 281 46 126 53 94 218 44 9 42 0 1991 48 0 41 45 0 472 297 12 0 1 0 7 1992 112 96 1025 1227 323 65 04 174 0 132 48 4 1993 0 697 0 202 445 0 12 306 18 05 14 33 Mean 25 35 22 27 27 25 18 12 6 13 13 21
JAN FEB MAR APR MAY JUN JUL AUG SEP OCT NOV DEC0
10
20
30
40
Mea
n R
ain
fall
(mm
)
Month
Mean monthly rainfall in Wiluna
MKS41 140498
45
Table 22 Wiluna minimum temperature (degC)
Year Jan Feb Mar Apr May Jun Jul Aug Sept Oct Nov Dec
1975 ndash 23 203 15 94 63 71 62 103 124 169 205 1976 242 229 194 15 10 63 59 73 95 143 16 228 1977 243 25 197 148 96 95 56 86 102 ndash 188 23 1978 241 232 203 18 102 64 76 8 9 152 19 205 1979 255 226 216 167 83 6 59 79 97 145 198 223 1980 255 226 231 155 134 83 68 75 121 108 193 223 1981 245 216 19 182 119 6 54 78 138 159 163 218 1982 232 224 177 16 ndash ndash 37 111 112 164 209 225 1983 235 24 197 147 112 88 39 88 121 162 189 219 1984 241 243 191 156 ndash 72 66 7 95 161 182 211 1985 244 231 ndash 159 98 65 71 73 117 147 205 ndash 1986 ndash 229 226 155 93 96 43 49 10 122 ndash 219 1987 ndash 217 183 175 85 77 68 68 112 ndash ndash 221 1988 238 214 209 178 111 ndash ndash 86 104 157 171 195 1989 ndash 237 199 165 107 67 44 61 107 131 187 ndash 1990 232 ndash 211 155 118 62 57 87 102 149 195 22 1991 26 256 217 168 122 101 78 ndash 113 18 168 219 1992 227 227 214 169 102 98 59 69 ndash 125 159 196 1993 241 218 196 171 103 ndash 49 68 88 128 192 211 Mean 24 23 20 16 10 8 6 8 11 14 18 21
NOTE Dashes indicate data unavailable
JAN FEB MAR APR MAY JUN JUL AUG SEP OCT NOV DEC0
10
20
30
40
Month
MKS43 140498
50
Mean monthly minimum temperatures at Wiluna
Mea
n T
emp
erat
ure
(degC
)
46
Table 23 Wiluna maximum temperature (degC)
Year Jan Feb Mar Apr May Jun Jul Aug Sept Oct Nov Dec
1975 ndash 349 326 281 247 201 197 212 256 248 31 344 1976 374 369 346 297 248 206 208 225 265 287 313 388 1977 397 392 352 296 234 212 222 244 ndash 308 337 383 1978 378 345 346 316 242 195 176 205 231 295 334 356 1979 403 36 364 295 ndash ndash ndash 193 242 318 359 373 1980 392 342 377 275 24 176 179 233 292 288 349 391 1981 385 346 337 342 242 178 201 224 30 326 326 369 1982 372 359 315 307 ndash ndash 196 253 252 305 353 379 1983 381 389 327 272 263 222 187 248 287 321 336 366 1984 378 393 322 299 226 215 178 214 234 ndash 336 364 1985 40 366 ndash 294 224 216 205 212 284 307 355 ndash 1986 ndash 383 372 307 ndash 193 166 196 261 277 ndash 382 1987 ndash 339 328 305 21 202 214 218 275 ndash ndash 374 1988 388 365 353 301 23 ndash ndash 228 283 334 31 33 1989 ndash 375 339 285 238 179 181 219 275 298 336 ndash 1990 368 ndash 36 309 268 19 188 205 274 309 373 393 1991 414 416 363 315 268 206 21 ndash 279 338 332 368 1992 363 383 336 263 213 178 213 197 ndash 285 313 359 1993 396 357 344 301 221 ndash 197 215 253 294 347 362 Mean 39 37 34 30 24 20 20 22 27 30 34 37 NOTE Dashes indicate data unavailable
JAN FEB MAR APR MAY JUN JUL AUG SEP OCT NOV DEC0
10
20
30
40
Month
MKS42 140498
50
Mean monthly maximum temperatures at Wiluna
Mea
n T
emp
erat
ure
(degC
)
47
Appendix 3
Table 31 Summary of palynological results
Drillhole Depth (m) F no(a) GSWA no Lithology Formation Assemblage TAI(b)
BWB 1 74ndash75 F49668 135741 dark-grey siltstone basalt Jilyilli gt5 BWB 1 98ndash100 F49669 135742 dark-grey siltstone basalt Jilyilli gt5 BWB 1 121ndash122 F49670 135743 dark-grey siltstone basalt Jilyilli gt5 TWB 1 86ndash87 F49671 135631 dark-grey siltstone McFadden 3+ TWB 1 104ndash105 F49672 135632 dark-grey siltstone Cornelia 3+ TWB 1 121ndash122 F49673 135633 dark-grey siltstone Cornelia 4 TWB 2 14ndash15 F49674 135634 dark-grey siltstone Skates Hills 3+ TWB 6 49ndash50 F49675 135675 dark-grey siltstone Cornelia 1 3+ TWB 9 49ndash51 F49676 135704 dark-grey siltstone Brassey Range 1 3+ Trainor 1 37497- F49733 138939 black mudstone with Cornelia 5 37509 light-grey siltstone Trainor 1 3809 F49734 138940 dark-grey and black Cornelia 4- laminated mudstone Trainor 1 4170 F49735 138941 black unlaminated mudstone Cornelia 4- Trainor 1 4950 F49851 139501 dark-grey indurated siltstone Cornelia 5 Trainor 1 6032 F49852 139502 dark- and light-grey Cornelia 5 indurated siltstone Trainor 1 6434 F49853 139503 greenish indurated finely Cornelia 5 laminated siltstone LDDH 1 270 F49678 138934 dark-grey siltstone interbeds Waters 1 3+ in enterolithic evaporite Tarcunyah Gp LDDH 1 277 F49679 138935 dark-grey siltstone in cavity Waters 1 3+ in enterolithic evaporite Tarcunyah Gp
NOTES (a) GSWA Fossil Catalogue number (b) TAI = Thermal Alteration Index of Traverse (1988 plate 1)
48
Appendix 4
Savory Sub-basin quantitative magnetic and gravity interpretation (extracted from Cowan 1995)
Summary
A program of quantitative aeromagnetic interpretation has been completed on BMRAGSO data from the Savory Sub-
basin Western Australia Quantitative aeromagnetic interpretation utilized the 3D Euler deconvolution method
supported by wavenumber filtering and image processing The results have provided useful information on structural
trends and depth to magnetic sources in a structurally complex area Depth to magnetic source analysis has provided
information on intra-sedimentary magnetic sources as well as basement rocks
The results of the interpretation support previously identified depocentres However the presence of magnetic
sources at several levels makes it very difficult to produce a reliable magnetic basement depth contour map It is
considered more productive to work with the 3D Euler colour circle plots and images rather than trying to contour the
results It would be necessary to carry out a full-scale interpretation of the BMRAGSO profile data to improve on the
3D Euler results The regional gravity was found to be useful in interpreting the regional setting of the area although
the very wide data spacing limits quantitative use of the data The gravity data show quite a complex picture with
limited consistent correlation between gravity features and basin structures This suggests that gravity anomalies
reflect changes in density of the basement rocks rather than basement topography especially in the northern part of the
basin
It is recommended that the GSWA investigate access to company confidential high-resolution aeromagnetic data
prior to planning further aeromagnetic surveys Private companies have flown large parts of the northern half of the
area as part of their diamond exploration program Additional gravity coverage of the area may be more cost effective
than magnetic surveys as the gravity data provides more information on changes within the sedimentary section
Introduction
The main use of aeromagnetic data in petroleum exploration has been the determination of magnetic basement
topography although there has been increasing interest in analysis of intra-sedimentary magnetic anomalies
intrabasement and suprabasement magnetic anomalies These anomalies are used to determine depth to magnetic
basement rocks and hence determine the thickness of the sedimentary sequence Unfortunately interpretation of the
intrabasement and suprabasement magnetic anomalies is non-unique in terms of position and size of causative sources
because of the inherent ambiguity of potential-field methods However this ambiguity can be reduced by placing
49
constraints on source geometry and magnetization and by using geological and other geophysical data to constrain
the solution
Before 1970 most depth-determination techniques involved graphical determination of slopes of selected
magnetic anomalies and application of various empirical factors to convert the slopes into depth estimates Geological
Society of America Memoir 47 Interpretation of Aeromagnetic Maps by Vacquier et al (1951) was a landmark for
this type of interpretation
Automated interpretation procedures have played an increasingly important role in depth interpretation and a
wide range of techniques have been developed Many of these techniques are designed for application to located data
profiles and assume a two-dimensional geometry However there has been renewed interest in techniques applicable
to gridded data
Two distinct types of method can be recognized In the first case often described as discrete methods individual
isolated magnetic anomalies are interpreted and the results used to produce a map of basement relief In the second
case often described as continuous methods areas of data containing a number of anomalies are interpreted
statistically to produce direct output of basement depths
The discrete methods usually involve a semiautomatic initial phase which generates a large number of possible
depth solutions and an interactive second phase to screen and select acceptable solutions The advantage of this
approach is that the interpreter can select features that are relatively free from interference from adjacent anomalies
and consider all aspects of a particular magnetic anomaly The disadvantage is that interpretation can be very time
consuming as a wide range of depths are usually possible depending on the initial model chosen and a significant
amount of effort is needed to select the correct model In the case of the Savory Sub-basin dataset we encountered
problems in separating basement related effects from the effects of shallower intrasedimentary magnetic sources
Because of these problems we have concentrated on displaying the Euler results accompanied by separation filter
images of the data to show the shallower effects and deeper effects rather than trying to refine a 3D Euler
deconvolution depth-to-crystalline-basement contour
The continuous methods are very direct provided that the rather restrictive assumption can be made that all
anomalies are due to lateral magnetization changes due to basement topography This means that shallow effects and
large intrabasement anomalies must be removed from the data This involves judgement and skill as it is necessary to
distinguish between the lower amplitude suprabasement anomalies due to basement topography and the larger
intrabasement anomalies reflecting magnetization changes within the basement These methods were not considered
suitable for the Savory Sub-basin magnetic dataset but were used to invert the gravity data
50
Limitations of magnetic and gravity interpretation
Interpretation of the area is limited by a shortage of information on the nature and physical properties of the deeper
sedimentary sequence and the underlying basement rocks However using techniques such as cross-correlation of
gravity and pseudo-gravity data it is possible to try to differentiate between anomalies relating to basement and those
related to the sedimentary sequence
Gravity anomalies reflect changes within the sedimentary sequence as well as basement condition These
changes in density of sedimentary rocks produce gravity anomalies without a corresponding magnetic anomaly hence
the complementary nature of gravity and magnetic surveys The main use of magnetics is to determine depth to
magnetic basement and any intra-sedimentary volcanic rocks or intrusives whereas gravity provides much more
general information on the sedimentary sequence
Unfortunately interpretation of gravity anomalies is complicated since they can be due to a number of geological
features including
bull major basement faults
bull basement highs
bull igneous intrusions within the basement
bull sedimentary basins which may or may not be isostatically compensated
bull intra-sedimentary volcanics and associated plutonic centres
Two major problems affect the interpretation of both magnetic and gravity data
1 The inherent ambiguity of potential-field data There is no unique solution to any measured gravity or magnetic
anomaly and theoretically there will be an infinite number of source geometry and magnetizationdensity
combinations which will fit the observed data This means that any a priori information which helps to select a
suitable model is very useful
2 Measured anomalies are the summation of effects from different depths For example an observed gravity profile
may contain contributions from shallow sources (density variations within the sedimentary basin) intermediate
depth sources (density variations due to large igneous intrusions within the basement) and deep sources (crustal
thinning producing a mantle anomaly) Separation of these component responses is the regionalresidual problem
which we solve using spectral analysis and differential upward continuation-based separation filtering
Regional setting and interpretation overview
The area studied includes parts of BALFOUR DOWNS (SF51-9) RUDALL (SF51-10) ROBERTSON (SF51-13) GUNANYA
(SF51-14) COLLIER (SG50-4) BULLEN (SG51-1) TRAINOR (SG51-2) MADLEY (SG51-3) NABBERU (SG50-5)
STANLEY (SG51-6) and HERBERT (SG51-7) 1250 000 sheets Broadly the area lies between latitudes 22deg00rsquondash25deg30rsquoS
and longitudes 119deg30rsquondash123deg30rsquoE
51
Regional gravity
The AGSO regional gravity data (at nominal 11 km spacing) was gridded at a 4 km mesh spacing using a minimum-
curvature algorithm Bouguer gravity values in the area are negative reflecting mass deficiency at depth and range
from -84 mgals to -25 mgals
A Bouguer gravity colour image is shown as Figure 41 A residual grid was produced by removing a fifth-order
orthogonal polynomial from the Bouguer data but did not add to the interpretation
120deg 121deg 122deg 123deg
23deg
24deg
25deg
-25
-84
50 km
MKS46 180598
mgal
Figure 41 Regional Bouguer gravity (BMRAGSO data) gridded at 4 km
52
The data show a complex pattern of positive and negative anomalies with no clearly defined trends Correlations
with aeromagnetic data and known basin structures are poor A vague north-northwest linear trend appears to coincide
with the Marloo Fault (Figure 42) A prominent negative anomaly appears to coincide with the Blake Fold and Fault
Belt depocentre and continues as a narrower negative anomaly to the east until it widens out again near the edge of the
basin Elsewhere the gravity data show little correlation with known basin structures and it is likely that especially in
the north of the area gravity anomalies are due to density changes in the basement rather than changes in basement
topography
Production of wavelength-filtered residual gravity plots and vertical gradient plots showed very patchy aliased
data reflecting poor sampling in much of the area
Regional magnetics
The AGSO regional aeromagnetic data were gridded at a 400 m mesh spacing using a minimum-curvature algorithm
(Figure 43) Most of the data has a line spacing of 1600 m with small areas of 1 km spacing The quality of the data is
acceptable for regional interpretation but is not adequate for detailed analysis The accuracy of the flight path is rather
variable reflecting the vintage of the data and the noise envelope of the data is poor by modern standards Problems
were also encountered in joining different map sheets
The magnetic anomaly pattern over the south and west part of the area shows a strong high frequency signature
reflecting the presence of widespread basic sills and dykes Some of the major north-northeasterly trending dykes can
be traced over considerable distances
Discontinuous high-frequency anomalies extend as a northwest-trending zone through the centre of the area and
this zone includes a conspicuous circular magnetic anomaly which is probably a ring complex
The northern and eastern parts of the area are characterized by long-wavelength deep-seated basement magnetic
anomalies with 120deg and 150deg trends dominant The Marloo and Perentie Faults (Figure 42) appear as distinct linear
zones and offsets A prominent easterly trending negative anomaly in the northwest of the area appears to swing round
to the southeast and may separate different basement blocks One possible interpretation is that this very deep seated
anomaly separates areas of Archaean and Proterozoic basement
Regional geology
The regional geology is described in Williams (1992) The GSWA provided a digitized version of Plate 2 from this
Bulletin the structural interpretation map to use as an overlay (Figure 42)
53
Pp
Pp
PSd
PSd
PSd
PSd
PSd
PSo
PSt
PSt
PSf
PSf
PSf
PSb
PSb
PSb
PSsPSs
PSs
PSb
PSm
PSp
PSc
PSc
PSw
PSw
PSw
PSg
PSr
PSj
PSg
PM
Pk
PY
PY
PSd
L
L
L
L
L
L
L
LL
L
L
L
LL
L
LL
L L
LL
L L
L
L
L
L
L
L
L
LL
L
L
BLAKEDEPOCENTRE
MA
RLO
O
FAU
LT
PERENTIEFAULT
50 km
MKS39120598
120deg 121deg 122deg 123deg
25deg
24deg
23deg
Approximate boundaryof aeromagnetic interpretation
PML
PSgL
PSjL
PML
PSpL
PML
PML
PSfL
PSfL
PSpL
LPc
LPcLPcPSrL
LPA
Durba Sandstone
Woora Woora Formation
McFadden Formation
Tchukardine Formation
Boondawari Formation
Skates Hills Formation
Mundadjini Formation
Coondra Formation
Spearhole Formation
Watch Point Formation
Jilyili Formation
Brassey Range Formation
Glass Spring Formation
Paterson Formation
Yeneena Group
Karara Formation
Cornelia Formation
Kahrban Subgroup
Bangemall Group
Fault
Formation boundary
PSdL
PSoL
PSfL
PStL
PSbL
PSsL
PSmL
PScL
PSpL
PSwL
PSjL
PSrL
PSgL
Pp
PYL
PkL
LPc
LPA
PML
Savory Group Other Units
PYL
Figure 42 Regional geology and structure map (after Williams 1992)
54
120deg 121deg 122deg 123deg
23deg
24deg
25deg
5820
3750
MKS47 180598
nT
50 km
Figure 43 Regional aeromagnetic data total magnetic intensity (BMRAGSO data) gridded at 400 m
Analysis
3D analysis
3D Euler deconvolution was used as the primary depth-determination method The advantage of this approach is that
consistent solutions can be obtained over the entire area with minimal assumptions about source geometries Euler
deconvolution of gridded data is used for positional information and estimation of depth to top of source Euler
55
deconvolution yields a large number of depth solutions which have to be screened to reject spurious solutions Results
are plotted as circles in eight depth ranges with radius proportional to depth and colour coded
The 400 m total magnetic intensity grid was used for the analysis Horizontal gradients in x and y and the vertical
gradient were calculated 3D Euler deconvolution was tested on the 400 m gridded data using windows of 9 times 9 and
11 times 11 and 16 times 16 data points and structural indices 05 (fault) and 10 (sill or dyke) It was concluded that the
16 times 16 window produced the best results overall and final plots were produced for the 16 times 16 window and structural
index 05 (Fig 44) Results were very good over the northern and central parts of the area showing magnetic sources
Figure 44 Depth to magnetic source 3D Euler deconvolution 16 times 16 window of 400 m gridded data structural index 05
56
at several different levels Unfortunately in the extreme south of the area shallow intrasedimentary magnetic sources
(sills and dykes) dominated the inversion and the results contained few basement solutions
In order to reduce these problems the 400 m gridded data were filtered using a separation filter based on
interpretation of the log-energy spectrum The 3D Euler method was run on the filtered data in order to generate more
basement-depth solutions Results for the deep-separation filter data were gridded and presented as a colour image in
Cowan (1995) Attempts to grid the Euler output were unsatisfactory and it is considered safer to interpret the 3D
Euler depth plots The 3D Euler depth results from the separation-filter run should be analysed with care as perfect
separation of the basement can never be achieved and there will always be some contamination from sources at
different levels
The results of original total magnetic intensity 3D Euler depth estimation for structural index 05 using a 16 point
window have been plotted at 1500 000 scale (not included in this publication but available in Cowan (1995) from the
GSWA Library as S10331) and as reduced A4 colour circle plots (Figure 44)
The results of deep-basement 3D Euler depth estimation for structural index 05 using a 16 point window have
been plotted as a colour image at 1500 000 scale and as an A4 image (not included in this publication)
2D analysis
Two equispaced profiles were interpolated with a 50 m station interval from the AGSO-located data profiles for the
BULLEN 1250 000 sheet The interpolated profiles were analysed using 2D Euler deconvolution and Werner
deconvolution Results are included in Cowan (1995) and show the use of these methods for more detailed analysis
Filtered data
In order to reconcile 3D Euler results from shallow basement and intrasedimentary magnetic sources we produced
several separation-filtered maps and images We found the shallow-layer double-separation filter (Figure 45) to be
very effective for shallow sources and the deep-layer standard-separation filter (Figure 46) for the basement layer
Gravity and magnetic data correlation
Both lsquoreduced to the polersquo (RTP) magnetics (Figure 47) and pseudo-gravity data (Figure 48) were produced as part of
the reconciliation of gravity and magnetic signatures In both cases the filtering operations assumed magnetization by
induction in the present Earths field The RTP data are fairly similar to the total magnetic intensity The pseudo-
57
gravity data are dominated by a northwest-trending strong positive anomaly and there is little correlation with the
Bouguer gravity data
The poor magneticgravity correlation is confirmed by cross-correlation of the RTP magnetics and the gravity
gradient The correlation plot in Figure 49 shows little coherent response with numerous zones of positive and
negative correlation
Figure 45 Regional aeromagnetic data shallow layer separation filter (BMRAGSO data) gridded at 400 m
Results
In the north and east of the area on the Wells Foreland Sub-basin trend (refer to Figure 1 main text) we see a range
of quite deep 3D Euler depths and several trend directions with north-northwesterly dominant There are relatively few
shallow intrasedimentary solutions in this zone
The second area of deep 3D Euler solutions lies over the Blake depocentre (Figure 43) with several trend
directions
Elsewhere the 3D Euler results are dominated by shallow intrasedimentary depth solutions reflecting mainly the
dolerite sills dykes and the ring complex However where we do see basement-related solutions in the south and
west of the area they appear to be shallower than those noted for the Wells Foreland Sub-basin and the Blake
depocentre
58
Figure 46 Regional aeromagnetic data deep-layer separation filter (BMRAGSO data) gridded at 400 m
Figure 48 Regional aeromagnetic data pseudo-gravity transform (BMRAGSO data) gridded at 400 m
Figure 47 Regional aeromagnetic data reduced-to-pole (BMRAGSO data) gridded at 400 m
Figure 49 Regional aeromagnetic and gravity data gravitymagnetic correlation using RTP magnetics and gravity gradient (BMRAGSO data) gridded at 4 km
59
This subdivision of the area into two zones of deep solutions is consistent with interpreted depocentres
However the interference between sources at different levels and the complexity of the magnetic response of the
basement rocks precludes more refined interpretation at this stage
The area of deep 3D Euler solutions over the Blake depocentre correlates with the pronounced negative gravity
anomaly discussed in the gravity interpretation section Using a density contrast of -015 gcc the negative gravity
anomaly could indicate up to 6ndash8 km of low-density sedimentary rocks depending on assumptions about the regional
field
The area of deep 3D Euler solutions over the Wells Foreland Sub-basin has a complex gravity expression and no
clear basin structure emerges from inversion of these data As noted previously it is likely that observed gravity
anomalies reflect contrasts in basement density rather than basement topography
Separation filtering applied to the magnetic data helps to enhance the intrasedimentary magnetic signature and to
give a better impression of the basement magnetic signature even though separation of the basement response is not
perfect
Conclusions
Quantitative aeromagnetic interpretation using 3D Euler deconvolution supported by wavenumber filtering and image
processing has been successful in providing structural trend and depth information for the Savory Sub-basin
Quantitative magnetic interpretation has revealed two zones of relatively deep magnetic basement beneath the
Wells Foreland Sub-basin and the Blake depocentre
This analysis of the magnetic data supports interpreted depocentres but the complexity of the basement magnetic
signature and interference from sources at different depths precludes further refinement to a map of basement
topography
Regional gravity proved to be very useful in understanding the regional setting of the area and in providing
support for aspects of the interpretation The gravity data support the interpretation of the Blake depocentre
suggesting up to 6ndash8 km of low-density sedimentary rocks
The deep structure of the Savory Sub-basin area is obviously complex with different areas underlain by
Archaean and Proterozoic basement and with the Capricorn suture occurring in the centre of the area
60
Recommendations
The quantitative magnetic interpretation needs to be reconciled with geological models available for the area
In particular the zones tentatively identified as areas with thick sedimentary rocks the Wells Foreland Sub-
basin and the Blake depocentre need to be investigated
Cross sections should be prepared across the basin for joint magneticgravity modelling especially for the Blake
depocentre It is important to be able to explain the strong negative gravity anomaly in this area
In view of the effects of basement density contrasts on the gravity field for the northern part of the area we think
that additional gravity interpretation and acquisition of new gravity data may not be justified as they will not
contribute significantly to understanding basin evolution and structure
It is recommended that GSWA try to get access to company confidential high-resolution aeromagnetic data
rather than flying new surveys The GSWA might offer to fund flying of new infill areas as a bargaining point
References
The original text of this report by Cowan (1995) and 1500 000 scale maps are filed in the GSWA Library under
S10331
COWAN D 1995 Savory Basin quantitative magnetic interpretation Western Australia Geological Survey S-series
S10331 (unpublished)
VACQUIER V STEENLAND N C HENDERSON R G and ZIETZ I 1951 Interpretation of aeromagnetic
maps The Geological Society of America Memoir 47 151p
WILLIAMS I R 1992 Geology of the Savory Basin Western Australia Western Australia Geological Survey
Bulletin 141 115p
61
Appendix 5
Geochemistry
MKS38 250398
Saturate FractionC12+ GLC
1217
Pr18
Ph
22
31CSR WELL-13 315m Cuttings
Figure 51 Canning Stock Route Well 13 gas chromatograph of extract of auger drill sample
12
17
18
22
31
Pr Ph
LDDH 1 6623m CoreSaturate FractionC12+ GLC
MKS35 240398
Figure 52 Gas chromatograph of extract from core sample at 6623 m LDDH1
62
Table 51 Canning Stock Route Well 13 auger drill samples
GSWA sample Drill depth (m)(a) Comments
135601 150 At watertable 135602 203 (all samples consist 135603 310 of sand mud and water) 135604 315 At total depth
NOTE (a) Datum for drill depth is the top of sediment fill in the well which is 155 m below ground level (ie the total depth of 315 m is 47 m below ground level)
Table 52 Canning Stock Route Well 13 gas chromatography data for 315 m depth sediment sample
Parameter Value
Weight of rock extracted (grams) 945 Total extract (ppm) 519 n-Alkane distribution n-C12 07 n-C13 23 n-C14 26 n-C15 22 n-C16 19 n-C17 14 i-C19 23 n-C18 14 i-C20 08 n-C19 11 n-C20 16 n-C21 25 n-C22 29 n-C23 70 n-C24 42 n-C25 95 n-C26 43 n-C27 83 n-C28 38 n-C29 87 n-C30 31 n-C31 273 Alkane compositional data Pristane phytane ratio 279 Pristane n-C17 ratio 161 Phytane n-C18 ratio 059 CPI (1)(a) 284 CPI (2) 209 (C21 + C22) (C28 + C29) 043
NOTE (a) CPI= Carbon preference index
63
Table 53 LDDH1 extract liquid chromatography data for 6623 m concentration
Rock extracted Total extract (grams) (ppm)
702 313
NOTE ppm= parts per million
Table 54 LDDH1 saturate gas chromatography data of core for 6623 m alkane composition
Pristane Pristane Phytane (a) CPI (1) CPI (2) (C21+C22) Phytane n-C17 n-C18 (C28+C29)
103 026 024 103 102 325
NOTE (a)CPI = carbon preference index
Table 55 LDDH1 saturate gas chromatography data of core for 6623 m n-alkane distributions
Parameter Value
n-C12 17 n-C13 38 n-C14 55 n-C15 60 n-C16 65 n-C17 74 i-C19 19 n-C18 78 i-C20 19 n-C19 80 n-C20 79 n-C21 71 n-C22 64 n-C23 57 n-C25 43 n-C24 38 n-C27 31 n-C28 23 n-C29 19 n-C30 12 n-C31 10
64
Appendix 6
Table 61 Summary of data from Trainor waterbores (TWB) and Bullen waterbores (BWB)
Well AMG Elevation TD Status(b) Completion details Water Salinity Water level Flow rate Depth to consolidated AGD84 GL (m) (m) struck mgl(c) (m) (LHr) lithology aquifer(e) Z51(a) Interval (m) (100 mm PVC) (m) (mgl)(d)
TWB 1 473660E 453 122 comp 0ndash75 plain 63 7 300 24 2 880 12 m 7287404N 75ndash93 slotted (9 260) McFadden Fm 93ndash99 plain TWB 2 472 977E 475 23 abd nil 15 m 7285877N Skates Hills Fm dry TWB 3 473259E 475 50 abd nil 7 m 7285849N Skates Hills Fm dry TWB 4 463225 E 445 50 comp 0ndash22 plain 35 7 200 55 3 600 0 m 7286143N 22ndash34 slotted (8 140) Tertiary sand and gravel 23ndash60 plain TWB 5 463095E 445 31 comp 0ndash19 plain 13 26 000 655 3 600 Tertiary sand and gravel 7277721N 19ndash25 slotted (36 700) 25ndash31 plain TWB 6 457013E 455 50 comp 0ndash42 plain 38 920 119 600 0 m 7274352N 42ndash48 slotted (1 030) Cornelia Fm ss TWB 7 453739E 475 26 susp 0ndash2 plain 11 9 300 48 4 500 0 m 7263891N (10 500) Tertiary sand TWB 8 433893E 535 60 susp 0ndash2 plain 47 8 500 gt46 1 200 0 m 7245991N (10 900) Tertiary sand and Brassey Range Fm ss TWB 9 437219E 505 51 comp 0ndash47 plain 45 1 000 58 600 1 m 7235905N 47ndash51 slotted (990) Brassey Range Fm ss TWB 10 434927E 495 32 susp 0ndash2 plain 235 450 120 0 m 7225875N (500) Dolerite
65
BWB 1 287337E 580 122 abd Nil 1 m 7245861N Jilyili Fm dry BWB 2 288346E 545 50 comp 0ndash26 plain 15 630 3 29 000 0 m 7240423N 26ndash38 slotted (730) Tertiary sand and gravel 38ndash50 plain BWB 3 305637E 545 50 abd 19 8 800 43 7 200 0 m 7240423N (10 550) Tertiary ss BWB 4 320167E 515 445 comp 0ndash20 plain 9 980 445 24 000 0 m 7248097N 20ndash32 slotted (1 190) Tertiary ss 32ndash44 plain BWB 5 353393E 545 20 susp 0ndash2 plain 45 (970) 1 m 7238934N Basalt
NOTES (a) GPS accuracy ~ 150 m (b) Comp = completed abd = abandoned susp = suspended (c) Salinity from conductivity (d) Analysis total dissolved solids (e) Fm = Formation ss = sandstone
10
SAVORY SUB-BASIN GIBSON SUB-BASINCENTRAL OFFICERBASIN
AMADEUS BASIN
PETERMANN RANGES OROGENY
NE
OP
RO
TE
RO
ZO
IC
ST
UR
TIA
NM
AR
INO
AN
ED
IAC
AR
IAN
CAMBRIANTO
NEOPRO-TEROZOIC
AG
E (
Ma)
SOUTHS RANGE MOVEMENT
AREYONGA MOVEMENT
Steptoe
MILES OROGENY
Mission Group
Cassidy Group
Rudall Complex
Bangemall Group
unnamed
Tar
cuny
ah G
roup
4
3
2
1
MKS12a 180598
500
550
600
650
700
750
800
850
900
SU
PE
R
SE
QU
EN
CE
unnamed
Tchukardine Fm
McFadden Fm
ArumberaSst
Julie Fm
Pertatataka Fm
Olympic FmPioneer Sst
Boondawari Fm
Turkey Hill FmLupton Fm
Kanpa Fm
Neale FmBabbagoola
FmHussar
Fm
Browne Fm
Woolnough Fm
Madley Fm
Bitt
er S
prin
gs F
m
LovesCreek M
Gillen M
Heavitree Fm
Arunta Complex
Throssell Group
TownsendQuartzite
Earaheedy Group
olderCornelia Fm
Jilyili Fm
SpearholeFm
MundadjiniFm
Skates Hills Fm
Lefroy Fm
Areyonga Fm
Aralka Fm
ME
SO
-P
RO
TE
RO
ZO
IC
Waters Fm
youngerCornelia Fm
Brassey RangeFormationKahrban
Subgroup
GlassSpring
Fm
Durba Sst
LP1ALP1B EVENT
Figure 4 Correlation of Savory Sub-basin formations with the western Officer and Amadeus Basins Fm = Formation Sst = Sandstone M = Member
11
The depositional sequences recognized in the sub-basin are an order of magnitude thicker than
those described from Phanerozoic passive-margin settings (Payton 1977 Posamentier et al 1988)
and are broadly comparable in scale to the second-order cycles of Vail et al (1977) and to the
megasequences of Hubbard et al (1985) The main subsurface data available to reveal the
unweathered nature of these rocks are Trainor-1 and the three-well diamond coring program in
Petroleum Permit EP 380 (Akubra 1 Boondawari 1 Mundadjini 1) completed in late 1997 in the
central west of the sub-basin (Figs 5 and 6)
The ages of all formations in the Savory Sub-basin are poorly constrained The only fossils
known are stromatolites and palynomorphs (acid-insoluble microfossils) Palynology from
available wells is summarized in Appendix 3 from Grey and Stevens (1997) and Grey and Cotter
(1996) and correlations using stromatolite biostratigraphy (Stevens and Grey 1997 Grey 1995f
Walter et al 1994 1995) are consistent with a Neoproterozoic age for the formations for which
data are available
A dolerite within the Boondawari Formation gave a poorly constrained RbndashSr age of about
640 Ma (Williams 1992) SHRIMP UndashPb dating of sedimentary zircons from the McFadden and
Cornelia Formations in stratigraphic drillhole Trainor 1 are discussed in Stevens and Adamides (in
prep) and Nelson (1997) The youngest ages from these analyses indicate that the maximum age
of the Cornelia Formation is Early Cambrian or Sturtian but these ages are inconsistent with
previous tectonic interpretations (Williams 1992) and current stratigraphic correlations which
suggest the Cornelia Formation is of Supersequence 1 age or older (Fig 4)
Depositional Sequence A Supersequence 1
Depositional Sequence A includes the Glass Spring Jilyili and Brassey Range Formations (Fig
3) All of these units are predominantly quartzose sandstones some of which are friable and have
significant visible porosity in outcrop Conglomerates are present in the Glass Spring and Jilyili
Formations
Depositional Sequence B Supersequence 1
Depositional Sequence B consists of the Watch Point Coondra Mundadjini Spearhole and
Skates Hills Formations (Fig 3) All of these formations contain beds of quartzose sandstone and
some also contain conglomerates The porosity of dolomites in the Skates Hills Formation appears
poor in surface exposures but its subsurface characteristics are unknown
12
50 km
120deg 121deg30 123deg
25deg
24deg
23deg
22deg
Greater Officer Basin
PNCEXP CA11PNCEXP CA12
PNCEXP CA13PNCEXP CA19
PNCEXP CA05
PNCEXP CA09
BD134589
GSWA Trainor 1 and TWB123
Fortescue River 1A
Mundadjini 1
Akubra 1Boondawari 1
TWB4TWB5
TWB6
TWB7
TWB8
TWB9
TWB10
BWB1
BWB2 BWB3
BWB4
BWB5
OD23
Mineral exploration drillhole
Stratigraphic drillhole
Waterbores and wells(TWB and BWB serieswaterbores identified)
MKS33270398
LDDH 1
Savory Sub-basin
Canning SR Well 13
EP380
Petroleum Exploration permit
Petroleum exploration well
Figure 5 Locations of petroleum exploration wells mineral exploration and stratigraphic drillholes water bores and wells and petroleum exploration permit EP380 in the Savory Sub-basin
13
TD=600m
TD=1367m
TD=701m
TD=709m
TD=50m
SS
1S
S1
SS1
SS
1S
S1
SS
1
SS
1
SS1
SS4 SS1
Pha
nero
zoic
or
SS
2
Cz
CzCz
Karst Bitumen
SS1
TD=181m
Mundadjini 1 Akubra 1 Boondawari 1 LDDH 1 Trainor 1 TWB 6
Munda-djini Fm
Spear-hole Fm
Munda-djini Fm
Munda-djini Fm
Spear-hole Fm
Spear-hole Fm
Waters Fm
McFadden Fm
Cornelia Fm
Cornelia Fm
Cornelia Fm
511 plusmn 13Maor 696 plusmn 20Ma(maximum)
779 plusmn 10Ma(maximum)
Mundadjini 1
Akubra 1 Boondawari 1
LDDH 1
Trainor 1TWB 6100 km
N
LOCATION
NW SE
Sea level
0m AHD
Dolerite basalt
Conglomerate
Sandstone
Mudstone
Dolomite
Limestone
Evaporite
TOC gt08
Permeability gt100md
Oil fluorescence
Sedimentary zircon U-Pb age
Identifiable polymorphs
Cainozoic
Supersequence 1 age
Unconformity
Formation contact
Cz
SS1
r
r
0
100
200
metres
VerticalScale
MKS36 120598
LEGEND
Figure 6 Geological cross section through significant drillholes in the Savory Sub-basin
14
Depositional Sequence C Supersequence 3
Depositional Sequence C consists of the Boondawari Formation (Fig 3) and although it contains
sandstone conglomerate and dolomite the sandstones contain significant amounts of feldspar and
clay and hence are likely to be poorer reservoirs than older sandstones
Depositional Sequence D Supersequence 4
Depositional Sequence D includes the McFadden Tchukardine and Woora Woora Formations
(Fig 3) The McFadden Formation is poorly sorted and sandstones contain significant amounts of
feldspathic clasts in the north of the basin but are significantly coarser and cleaner in the northeast
of the sub-basin (Williams 1992)
Sandstones of the Tchukardine and Woora Woora Formations are generally cleaner than those
of the McFadden Formation and are expected to have fair to good porosity although the
Tchukardine Formation has a higher clay content in parts
Depositional Sequence E Supersequence 4
Depositional Sequence E consists of the Durba Sandstone (Fig 3) a coarse sandstone with minor
conglomerate which has good to excellent visible porosity in surface exposures
Other depositional sequences and regional correlations
Sedimentary rocks which were not included in the Savory Group by Williams (1992) but which
are likely to be of Neoproterozoic age and hence part of the greater Officer Basin include the
Tarcunyah Group the Cornelia Formation and the Kahrban Subgroup
As discussed in the Introduction all of the strata in the Karara Basin and the younger strata
of the Yeneena Basin were redefined to form the Tarcunyah Group of the greater Officer Basin
(Bagas et al 1995) (Fig 7) In outcrop the Tarcunyah Group consists predominantly of quartzose
feldspathic and arkosic sandstone shale which is carbonaceous in parts and carbonate which
includes stromatolitic dolomite Mineral hole LDDH1 drilled on GUNANYA intersected the
15
120598
122deg
123deg
21deg
22deg
23deg
24deg
23deg
22deg
21deg
122deg
123deg
Fault
Thrust
Reverse thrust
CANNINGBASIN
OFFICERBASIN
GROUP
PILBARACRATON
TARCUNYAH
SAVORY GROUP
BANGEMALL
GROUP
THROSSELL
GROUP
LAMIL
GROUP
ConnaughtonTerrane
TerraneTalbot
complexTabletop granitic
Tabletop Terrane
Permian
Neoproterozoicgranitoid
50 km
FormationWaltha Woora
McKay Fault
South west Thrust
Vines
Fault
24deg
120deg
YENEENA CANNINGBASIN
ARUNTAINLIERRUDALL
COMPLEX
AMADEUSBASIN
MUSGRAVEBLOCK
OFFICERBASINYILGARN
CRATON
GROUP
GROUP
GROUP
PILBARACRATON
GROUP
EARAHEEDY
GLENGARRY
BANGEMALL
WYLOO GROUP
SAVORY
WA
CARNARVONBASIN
GASCOYNECOMPLEX
GROUPTARCUNYAH
400 kmGROUP
SA
N
T
CamelndashTabletopfault zone
KAHRBANSUBGROUP
CORNELIAFORMATION
MKS37
Figure 7 Regional geological setting of the Savory Group and western Officer Basin The dashed line on the inset map marks the interpreted margin of the greater Officer Basin
16
Tarcunyah Group and consists predominantly of mudstone with minor sandstone limestone
dolomite and anhydrite (Fig 6)
The age of the Tarcunyah Group is uncertain although limited palynological and stromatolite
evidence suggests that it is probably coeval with Supersequence 1 of the Centralian Superbasin
Drillhole LDDH1 contains palynomorphs equivalent to assemblages in the Browne and Bitter
Springs Formations of the Officer and Amadeus Basins respectively and from the Cornelia
Formation in TWB 6 (Grey and Stevens 1997) (Figs 4 and 6) Stromatolite specimens tentatively
assigned to Acaciella australica (Howchin 1914) Walter 1972 occur in the lower Tarcunyah
Group (Bagas et al 1995) The stromatolite Baicalia burra Preiss 1972 and a conical
stromatolite were reported from the upper part of the Tarcunyah Group (Stevens and Grey 1997)
The recognition of two stromatolite assemblages interpreted to have age significance in
Supersequence 1 sedimentary rocks of the Centralian Superbasin has permitted biostratigraphic
correlations between outcrop and well data The Acaciella australica assemblage appears to be
slightly older than 800 Ma and is restricted to the middle part of Supersequence 1 The Baicalia
burra assemblage is considered to be slightly younger than 800 Ma and occurs in the upper part
of Supersequence 1 (Grey 1996b Stevens and Grey 1997) The older A australica assemblage
is recognized in the Skates Hills Formation in the Savory Sub-basin and the stromatolite A
australica itself has been tentatively identified in the lower Tarcunyah Group The occurrence of
the A australica assemblage in the Woolnough Madley and Browne Formations of the Officer
Basin and in the Loves Creek Member of the Bitter Springs Formation of the Amadeus Basin
allows correlations throughout the Centralian Superbasin (Fig 4)
The younger B burra assemblage has not been recognized in sedimentary rocks of the
Savory Group as defined by Williams (1992) but it occurs in the upper parts of the Tarcunyah
Group and allows correlation of this group with outcrops of the Neale Formation and with the
Kanpa Formation in petroleum exploration well Hussar 1 both located in the central Officer Basin
of Western Australia (Fig 4) (Grey 1996b Stevens and Grey 1997) The occurrence of the B
burra assemblage in these units permits their correlation with the Burra Group in the Adelaide
Geosyncline of South Australia (K Grey unpublished data)
The Cornelia Formation and Kahrban Subgroup outcrop in the southeast of the sub-basin and
were considered by Williams (1992) to be part of the Mesoproterozoic Bangemall Basin Limited
evidence suggests that all or parts of these two units are of Neoproterozoic age The Ward and
Oldham Inliers consist of outcrops of the Cornelia Formation Waterbore TWB 6 which was
drilled on TRAINOR in the Cornelia Formation contains palynomorphs consistent with a
Supersequence 1 age (Grey and Stevens 1997) (Figs 5 and 6) In outcrop the Cornelia Formation
17
consists predominantly of sandstone and quartzite with lesser siltstone shale mudstone and chert
In Trainor 1 this formation consists predominantly of indurated mudstone with minor sandstone
chert and dolomite A major erosional unconformity separates the Cornelia Formation from
overlying formations and parts of the Cornelia Formation have been folded with dips exceeding
70deg In contrast the majority of the Savory Sub-basin sedimentary rocks have dips of less than 30deg
except where they are adjacent to faults The Cornelia Formation apparently consists of an older
unit of steeply dipping quartzites cherts and well-indurated mudstones and a younger unit of
shallower dipping sandstones which are sub-friable in parts However caution should be used in
interpreting the age of units based on their structural deformation and additional mapping and age
dating of this formation is required
It is proposed here that the Kahrban Subgroup is likely to be of early Neoproterozoic age and
hence should be considered as part of the greater Officer Basin This proposal is based largely on
the relatively low dip of the strata (generally less than 20deg) and their west-northwest strike which
is parallel with strikes in the overlying Brassey Range Formation of the Savory Group The lower
contact of the Kahrban Subgroup is obscured but is thought to be an unconfirmity on the
Earaheedy Basin on the southeast of STANLEY (Muhling and Brakel 1985)
Structural setting
The Savory Sub-basin forms the most northwesterly sub-basin of the Neoproterozoic to
Phanerozoic Officer Basin The western boundary of the sub-basin with the Mesoproterozoic
Bangemall Basin consists of steep-reverse and strike-slip faults The northeastern boundary of the
Savory Sub-basin was mapped where Supersequence 4 formations of the Savory Group
unconformably overlie sedimentary rocks of the Karara and Yeneena Basins with the two older
units considered to be part of the Paterson Orogen (Williams 1992) This contact was defined as a
series of steeply dipping reverse faults in the northernmost parts of the sub-basin on BALFOUR
DOWNS and RUDALL and was extrapolated as an inferred reverse fault farther along strike to the
southeast on GUNANYA and MADLEY where the contact is obscured by Cainozoic sediments It is
now recognized that all the sedimentary rocks in the Karara Basin and younger sedimentary rocks
of the Yeneena Basin are from the Supersequence 1 Tarcunyah Group and part of the greater
Officer Basin (Bagas et al 1995) The northern boundary of the Tarcunyah Group and the greater
Officer Basin is in thrust-and reverse-faulted contact with the Rudall Complex and other parts of
the Paterson Orogen (Fig 7)
To the south the sub-basin unconformably overlies the Bangemall Basin The eastern
boundary of the sub-basin used in this study is where Permian and younger strata of the Officer
Basin unconformably overlie Neoproterozoic strata although there are no significant structural or
stratigraphic differences between the Neoproterozoic units
18
The sub-basin is subdivided into three principal structural areas (Fig 1) Trainor Platform
Blake Fault and Fold Belt and Wells Foreland Sub-basin (Williams 1992) A major review of
these boundaries is beyond the scope of this report but the processing of regional aeromagnetic
data (Appendix 4) and acquisition of a semi-detailed gravity survey by the GSWA in the east of
the sub-basin has enabled these tectonic units to be reassessed and some modifications are
proposed
The Wells Foreland Sub-basin (originally termed the Wells Foreland Basin in Williams 1992)
and sedimentary rocks of the Tarcunyah Group are both considered to be the northwest
continuation of the Gibson Sub-basin of the Officer Basin Aeromagnetic gravity and outcrop
data suggest that the Blake Fault and Fold Belt is significantly faulted and folded in the west but
is less deformed in the east where the thickest sedimentary section in is located on BULLEN
(Appendix 4) The Trainor Platform is reinterpreted to represent an area of the sub-basin that has
undergone major compression during the Petermann Ranges Orogeny resulting in folding and
faulting with a northwest strike This interpretation contrasts with that proposed by Williams
(1992) who envisaged that only a thin section of the Savory Group was present on the platform
Perincek (1998) has recognized nine periods of tectonic activity in the Officer Basin from the
beginning of the Neoproterozoic to the end of the Cretaceous Three major tectonic episodes are
recognized in the Centralian Superbasin The oldest event is the Areyonga Movement which is
pre-Sturtian and forms the boundary between Supersequences 1 and 2 (Fig 4) The Souths Range
Movement occurred at the end of the Sturtian at the boundary between Supersequences 2 and 3
The youngest major event is the Petermann Ranges Orogeny which occured at the end of the
Marinoan and forms the boundary between Supersequences 3 and 4
One minor and two major tectonic episodes are recognized in the Savory Sub-basin the
LP1ALP1B structural event and the Areyonga Movement and the Petermann Ranges Orogeny
respectively The LP1ALP1B structural event is revealed where the Spearhole Formations rests
disconformably and locally unconformably on the Brassey Range Jilyili and Glass Spring
Formations The Neoproterozoic Areyonga Movement (equivalent to the Blake Movement of
Williams 1992) produced folds and faults with a general northeast strike in the western and
southern parts of the region The Souths Range Movement has not been recognized in the sub-
basin This may be due to the fact that no Sturtian glacial rocks have been identified and hence it
is possible that structures attributed to the Areyonga Movement could be the result of the Souths
Range Movement or a combination of the two movements
The major tectonic event recorded in the sub-basin is the latest Neoproterozoic to Cambrian
Petermann Ranges Orogeny (equivalent to the Paterson Orogeny) which produced large reverse
19
faults thrusts strike-slip faults and folds with a general northwest strike The McFadden
Formation and other Supersequence 4 strata are considered to be at least partially coeval with this
orogeny (Williams 1992) We also interpret the Durba Sandstone as having been deposited during
the later stages of the Petermann Ranges Orogeny as this unit mildly deformed with fold axes
parallel to the strike of other structures attributed to the Petermann Ranges Orogeny
Quantitative aeromagnetic interpretation of the Savory Sub-basin utilizing the 3D Euler
deconvolution method supported by wave-number filtering and image processing has provided
structural trends and depth to magnetic source within the sub-basin (Cowan 1995) Gravity data
are interpreted by Cowan (1995) as changes in both the density of the basement rocks andor
basement topography depending on local conditions Part of Cowanrsquos report is reproduced in
Appendix 4
Exploration history
The only petroleum exploration conducted in the sub-basin has been the recent drilling in the
western part of three diamond drillholes of which two have minor oil shows (Table 2) There has
been some mineral exploration the results of which are stored in the GSWA Western Australian
Mineral Exploration (WAMEX) database system Much of the mineral exploration was in the
southwest and west where the sub-basin is in contact with the Bangemall Basin and along the
northern margin of the sub-basin Many of these mineral exploration programs included
aeromagnetic surveys and surface geochemical sampling (Fig 8)
Hydrocarbon potential
The sub-basin contains a sedimentary succession up to 8 km thick which is generally gently
folded and faulted and apparently unmetamorphosed Limited drilling has shown that thick
mudstones are present in the sub-basin with some mudstones in Trainor 1 having high Total
Organic Carbon (TOC) values Outcrops of sub-friable sandstones in many of the formations
within the sub-basin suggests widespread reservoir potential Mudstone and inferred thick
evaporite sequences are likely to form seals Maturity data suggest that near-surface samples are
approximately at the base of the oil window and top of the gas window in parts of the north and
southeast of the sub-basin However parts of the southwest of the sub-basin and the mudstones in
Trainor 1 have very high levels of maturity Numerous faults and folds have been identified from
surface mapping suggesting good potential for large structural traps Minor oil shows in
20
Table 2 Neoproterozoic formations and hydrocarbon shows in diamond drillholes in the Savory Sub-basin
Drillhole AMG Core TD (m) Approx Formation Depth Formation Depth Formation Depth Shows (AGD84) start (m) GL (m) (m) (m) (m)
LDDH 1 431148E 112 701 350 Tarcunyah 68ndash701 ndash ndash bitumen at 6623 m 7443826N Group Trainor 1 473640E 6 709 455 McFadden 9ndash83 Cornelia Fm 83ndash709 possible bitumen at 4537 m 7287400N Fm Mundadjini 1 319056E 170 600 500 Mundadjini 16ndash361 Spearhole Fm 361ndash600 10 fluorescence at 36102 m 7404844N Fm Boondawari 1 348959E 299 1 367 490 Mundadjini Fm 15ndash312 Spearhole Fm 312ndash1 283 Intrusive 1 283ndash1 367 40 fluorescence at 35364 m 5 7398174N fluorescence at 4963 m Akubra 1 334249E 15 181 530 Mundadjini 15ndash42 Intrusive 42ndash181 None 7401252N Fm
21
50 km
120deg 121deg30 123deg
25deg
24deg
23deg
22deg
Greater Officer Basin
Savory Sub-basin
1
2
3
4
6
8
3 Seismic line (prefixed N83-00)
Aeromagnetic survey
GS
WA
Sav
ory
1995
gra
vity
sur
vey
Gravity survey
MKS34270398
Figure 8 Locations of aeromagnetic and gravity surveys (other than regional BMRAGSO data)
22
sandstones in two petroleum wells in the northwest of the sub-basin and bitumen and oil shows
elsewhere in the region indicate that oil has been generated and migrated through the sub-basin
Source rocks
Source potential is considered to be the major exploration risk in the Savory Sub-basin although
minor oil shows in Mundadjini 1 and Boondawari 1 indicate that at least some oil has been
generated and migrated into potential reservoirs within the sub-basin Sandstone is the
predominant lithology observed in outcrop Outcrops of fine-grained lithologies in the basin are
rare because of intense surface weathering and erosion Only about 8 of the surface area of the
sub-basin is exposed bedrock and recessive lithologies (such as shale evaporite and friable
sandstone) may be present although they rarely outcrop
Outcrops of stromatolitic dolomite with associated cauliflower chert and cubic pseudomorphs
interpreted as being after halite indicate that evaporitic environments are present within the
Mundadjini Skates Hills and Boondawari Formations Evaporitic minerals are also present in
drillhole LDDH1 in the Tarcunyah Group
In 1995 GSWA drilled a continuous-core diamond drillhole (Trainor 1) in the sub-basin on
TRAINOR to a depth of 709 m to test for source rocks thus providing the first such data for the sub-
basin The drillhole intersected flat-lying clastics and carbonates of the McFadden Formation (9ndash
83 m) overlying indurated mudstones of the Cornelia Formation (83ndash709 m total depth) dipping at
about 40deg Of the six samples analysed from the Cornelia Formation in this drillhole the five
located between 375 and 6032 m depth have TOC values exceeding 05 (range 066ndash365)
Rock-Eval pyrolysis of these five samples indicates that they are at best in the dry-gas thermal
stage and as a result of their high level of maturation (Stevens and Adamides in prep) have poor
remaining hydrocarbon-generating potential Although the Cornelia Formation is overmature at
Trainor 1 the high TOC values are encouraging as it is likely that this sequence is less mature
elsewhere in the sub-basin
The Mundadjini Formation contains potential source rocks that comprise marine mudstones
with evaporitic minerals present in parts Thin dark mudstones were intersected in the Mundadjini
Formation in Akubra 1 In Mundadjini 1 and Boondawari 1 however the mudstones appear to be
too oxidized to have source potential
The Boondawari Formation also may be a source rock as it contains black mudstones The
unit is laterally equivalent to the Pertatataka Formation of the Amadeus Basin and the Ungoolya
23
Group of the Officer Basin in South Australia both of which have some source potential
(Summons and Powell 1991 Morton and Drexel 1997) Samples from the Dey Dey Mudstone of
the Ungoolya Group generally have poor TOC values (average 011 range 003ndash081)
moderate hydrogen index (HI) values (100ndash382) and poor to fair genetic potential with a
maximum of 292 kg hydrocarbon per tonne of source rock (Morton and Drexel 1997)
Stromatolitic dolomites and mudstones at the top of the Boondawari Formation and within the
Skates Hills Formation are potential source rocks Stromatolitic dolomite and evaporitic rocks
deposited in a marginal marine to sabkha environment are considered to have good potential to
generate and preserve organic carbon without requiring a deep-water setting (Stevens and Grey
1997) Such conditions are recognized in the Skates Hills Formation and in the upper parts of the
Tarcunyah Group
Maturity
Knowledge of the maturity of sedimentary rocks within the Savory Sub-basin is still limited From
a review of palynological studies Grey and Stevens (1997) report that the thermal maturity
inferred from the Thermal Alteration Index (TAI) of 3+ from Supersequence 1 age palynomorphs
in TWB 6 TWB 9 and LDDH1 is within the hydrocarbon window (Appendix 3) In Phanerozoic
spores and pollen a TAI of 3+ approximately equates to the end of liquid petroleum generation
and the start of dry gas generation and to a vitrinite reflectance of about 13 (Traverse 1988)
However the use of TAI for estimating thermal maturity from Neoproterozoic palynomorphs
requires calibration
In Trainor 1 the Cornelia Formation contains organically rich claystones between 375 and
6032 m depth Based on Rock-Eval maturity data (Stevens and Adamides in prep) and the dark
colour of poorly preserved organic material (Grey 1995de 1996) with TAI 4- to 5 all samples
had a high level of maturation with at best dry-gas generating potential remaining In contrast
drillhole LDDH1 on GUNANYA recorded lower levels of maturity (TAI values of 3+) with two of
sixteen samples from the Tarcunyah Group having greater than 1 TOC (Grey 1995abc Grey
and Cotter 1996) Organic petrology and Rock-Eval maturity data for samples from LDDH1
indicate that the section above 500 m is within the oil-generative window whereas below 500 m
the rocks are within the gas window (Ghori in prep Fig 9 Appendix 5)
Waterbores TWB 1 2 6 and 9 which are located on TRAINOR in the southeast of the sub-
basin all had organic matter with TAI values of 3+ from the McFadden Skates Hills Cornelia
and Brassey Range Formations respectively
24
100
200
300
400
500
600
700
Oil
gene
ratin
g
Gas
gene
ratin
g
Fai
r
Fai
r
Poo
r
Poo
r
Goo
d
Imm
atur
e
Oil
win
dow
Oil
win
dow
Imm
atur
e
01 0110 10 0 150 300 440 480 1
Neo
prot
eroz
oic
TOC S1+S2 mgg Hydrogen Index Tmax degC
Depth(m)
Organicrichness
Generatingpotential
Kerogentype Maturity Maturity
TD=701m
Sandstone
Mudstone
Dolomite
Limestone
Evaporite
Source rock
MKS40 070498
Ro equivalent
Figure 9 Petroleum source potential of rocks in Normandy LDDH1
Small amounts of organic matter associated with basalt and dolerite in cuttings from
waterbore BWB 1 on BULLEN showed high levels of thermal maturity (Grey 1995a Libby 1995)
It is unclear whether all sedimentary rocks on BULLEN are overmature for hydrocarbon generation
or the results from BWB 1 are related to local heating events associated with the volcanic bodies
that are common in the Jilyili Formation
25
Reservoirs
Each of the five depositional sequences of the Savory Group (Table 1) are inferred to contain
significant sandstone reservoirs with the possible exception of depositional sequence C as
discussed above in Stratigraphy The Spearhole Formation was cored in Mundadjini 1 and
Boondawari 1 and visual estimates of porosity vary from generally poor (less than 5) to fair
(approximately 5ndash15) The McFadden Formation in Trainor 1 has porosity values of up to 232
and a maximum permeability of 195 md (Stevens and Adamides in prep) Sandstones from
Neoproterozoic formations form the acquifers in the following waterbores the McFadden
Formation in TWB 1 the Cornelia Formation in TWB 6 and the Brassey Range Formation in
TWB 8 and TWB 9 (Appendix 6 Table 61)
Based on outcrop observations the Durba Sandstone is considered to be the best reservoir of
the Savory Group Similarly some sandstones from the Tarcunyah Group also have good visible
porosity in outcrop
Dolomites occur in several formations in the sub-basin Reservoir potential may exist
particularly where the dolomites are stromatolitic and oolitic However dolomites have not been
drilled in the sub-basin and porosity can only be inferred from the preferential silicification of
some stromatolite bioherms observed in outcrop (Stevens and Grey 1997) Elsewhere in the
Officer Basin porosities of up to10 have been measured in dolomites A limestone breccia
(karst) is described from 663 to 677 m in drillhole LDDH1 (Fig 6 Busbridge 1994)
Seals
Indications of evaporitic environments in the Mundadjini Skates Hills and Boondawari
Formations are described by Williams (1992) In Mundadjini 1 from 287 to 337 m anhydrite and
chert occurs as nodules beds and veins in mudstone of the Mundadjini Formation Evaporitic
minerals (predominantly gypsum) are described in the Tarcunyah Group in LDDH1 The presence
of the Woolnough and Madley salt diapirs in the Officer Basin (approximately 110 km east of the
sub-basin) and halite beds over 25 m thick in the well Hussar 1 (130 km east of the sub-basin)
provide further evidence that evaporite seals may be present in the Savory Sub-basin
Mudstones and shales form only a small proportion of the limited Neoproterozoic outcrop in
the sub-basin but significant thicknesses of mudstone were encountered in the Mundadjini
Formation in Mundadjini 1 and Boondawari 1 the Tarcunyah Group in LDDH1 and in the
26
Cornelia Formation in Trainor 1 These data suggest that mudstones form a significant proportion
of strata in the sub-basin despite their limited outcrop
Traps
Potential structural closures including folds and faults occur at various scales throughout the
Savory Sub-basin However the region has only been mapped at 1250 000 scale and
independently closed structures such as domes have yet to be confirmed The western margin of
the basin contains abundant faults (with a northeast strike) but elsewhere faults are less common
Some anticlines are recognized in outcrop including one with a strike length of up to 45 km
inferred from surface bedding dips in the Mundadjini and Spearhole Formations at approximately
24deg15rsquoS 121deg10rsquoE on BULLEN (Fig 1)
Salt diapirs and other halokinetic structures are recognized in outcrop well and seismic data
in the Officer Basin to the west of the Savory Sub-basin and it is probable that there are
significant thicknesses of evaporitic sedimentary rocks in the sub-basin The gravity field data
suggest there is good potential for salt diapirs and traps related to halokinesis
Although there is potential for stratigraphic traps to be present in the sub-basin insufficient
data are available to assess them
Preservation of hydrocarbons
The range of thermal maturities measured to date and the large periods of time envisaged for
deposition of sediments implies hydrocarbon generation may have occurred a number of times
during the evolution of the Savory Sub-basin Any hydrocarbons that were generated early may
have been trapped in palaeostructures and remigration to younger traps could have taken place
later The Petermann Ranges Orogeny which has been equated with the Paterson Orogeny (Myers
1990) is believed to have occurred in the latest Neoproterozoic to early Cambrian This is the last
major tectonic event recognized in the sub-basin suggesting that it is reasonable to expect that trap
integrity will have been preserved
If the inference of the presence of thick halite beds in the sub-basin is correct the preservation
potential of sub-salt traps should be excellent
27
Reported hydrocarbon shows and oil seep
Amadeus Petroleum recorded minor oil shows in cores from Mundadjini 1 and Boondawari 1 In
Mundadjini 1 at 36102 m (top of the Spearhole Formation) a 3 mm thick zone had 10 moderate
white fluorescence with slow solvent cut This show was in a granular sandstone with visually
estimated porosity of about 10 In Boondawari 1 at 35364 m (within the Spearhole Formation) a
broken surface of sandstone had 40 moderate yellow-white fluorescence with slow solvent cut
Visually estimated porosity is about 5 Because the fluorescing surface was broken during the
drilling process this show could have resulted from contamination A second show occurs in
Boondawari 1 at 4963 m (within the Spearhole Formation) where a 1 cm-thick zone had 5 dull
yellow fluorescence with slow solvent cut in a conglomerate with visually estimated porosity of
about 10 The company intends to further investigate the nature of these occurrences
Minor bitumen is present at 6623 m in drillhole LDDH1 on GUNANYA (Figs 5 and 6) as a
vein in mudstones of the Tarcunyah Group A sample was analysed by gas chromatography
(Ghori in prep) and confirmed that it is natural bitumen (Appendix 5)
Mineral hole OD 23 drilled by Jubilee Gold Mines NL on NABBERU in the Bangemall Basin
immediately to the south of the Savory Sub-basin (Fig 5) encountered bitumen and trace oil in
vugs in dolomite (M Stevens unpublished data) but no further data are available at present
In their popular guide to the Canning Stock Route Gard and Gard (1990 p 218) refer to an
oil seep at Well 13 on TRAINOR (Fig 5) They reported that between 1977 and 1984 lsquonatural oilrsquo
was seen in the well Although the well is now largely filled with sediment four auger drill
samples were collected by the GSWA in 1995 and all four were analysed for oil shows One
sample from 315 m total depth (GSWA sample 135604) yielded just enough extract (519 ppm)
for saturate gas chromatography analysis The gas chromatograph (Appendix 5) shows that the
extract does contain some hydrocarbons probably from recent plant material Because the depth to
the oil was not quoted in Gard and Gard (1990) the hand-augered well may not have been deep
enough to properly test this reported seep
Geological and geophysical databases
Geological and geophysical data available for the Savory Sub-basin are limited The most recently
completed geological maps for the sub-basin were published by the GSWA between 1991 and
1995 (Williams and Tyler 1991 Williams 1992 1995ab)
28
The cores from the five drillholes listed in Table 2 believed to be all of the core available
from the sub-basin are available for inspection at GSWA Mineral exploration reports submitted
to GSWA may be searched using the WAMEX database and open-file reports are available on
microfiche Geophysical data acquired by the mining industry is not required to be filed with
GSWA if acquired over Vacant Crown Land which is the case for much of the sub-basin
Geophysical survey data submitted in mining tenement reports and which extend into Vacant
Crown Land remain confidential to the companies Original regional aeromagnetic and gravity
datasets are available from the Australian Geological Survey Organisation (AGSO)
Data pertinent to oil exploration in the sub-basin such as structural style and salt diapirism
are presented in a review of the hydrocarbon prospectivity of the Officer Basin (Perincek 1998)
Drilling
Significant drillholes in the sub-basin are summarized in Table 2
Petroleum industry data
Amadeus Petroleum drilled three petroleum exploration wells in the central west of the Savory
Sub-basin in late 1997 These wells Mundadjini 1 Boondawari 1 and Akubra 1 were drilled by
continuous diamond coring (Figs 5 and 6) All targeted potential reservoirs within the Spearhole
Formation with the Mundadjini Formation as the proposed seal The wells were located on
structures interpreted from Landsat images and limited geological investigations Both Mundadjini
1 and Boondawari 1 had minor oil shows as discussed above (Reported hydrocarbon shows)
Government data
Stratigraphic drillhole Trainor 1 was drilled by GSWA in 1995 (Stevens and Adamides in prep)
and the main results are discussed above (Source rocks and Maturity)
Mineral industry data
Normandy Exploration drillhole LDDH1 was cored in the Tarcunyah Group to a total depth of
701 m and provided source-rock and maturity data as discussed above
29
Oilmin NL drilled six percussion drillholes (BD 1 3 4 5 8 and 9) through sandstones and
shales in the northern part of the Savory Sub-basin to a maximum depth of 198 m (Fig 5
WAMEX Microfiche File M 26811 I 2610) but only brief geological descriptions are available
Hydrogeological data
Hydrogeological data within the Savory Sub-basin are limited although a long history of water
exploration extends back to the construction of the Canning Stock Route early this century No
detailed geological or wireline logs are available for the older wells along this route A few station
wells have been drilled by various methods on the south and west margins of the basin but data
are unavailable as reports are not required to be filed with the government Depth to watertable
throughout the basin is largely controlled by porosity of the bedrock
The GSWA drilled fifteen waterbores in the winter of 1995 in the southern part of the sub-
basin in preparation for the drilling of Trainor 1 and the proposed Bullen 1 Twelve bores found
water and six of these bores have salinities of less than 1000 mgL (Fig 5 Appendix 6 Table 61)
One waterbore TWB 6 has gamma ray and neutron logs run through PVC casing and these are
available from the GSWA with the digital log data included herein
Seismic data
No geophysical data have been acquired by the petroleum industry in the Savory Sub-basin
Seismic data acquired in the Officer Basin to the east particularly in the Gibson and Yowalga
Sub-basins is pertinent to structural interpretation in the Savory Sub-basin (Perincek 1996a
1998)
Aeromagnetic surveys
Government data
There are over 95 277 line kilometres of aeromagnetic data included in the AGSO dataset There
are three regional aeromagnetic surveys covering the Savory Sub-basin These were flown by the
Bureau of Mineral Resources (BMR now AGSO) in 1984 at a line spacing of 1500 m with 36 740
and 52 587 line kilometres flown and by Aerodata in 1984 at a line spacing of 1000m with 5950
line kilometres flown These data were reprocessed and interpreted for GSWA by Cowan (1995)
An edited copy of this report is included as Appendix 4 and the original report is filed in the
GSWA Library under S-series reports item 10331
30
Mineral industry data
The approximate locations of non-AGSO aeromagnetic surveys are shown in Figure 8 More
detailed information regarding the location of these surveys may be obtained using the GSWA
MAGCAT II database Additional information such as contours of aeromagnetic values may be
obtained by inspecting items on file with the GSWA
Gravity surveys
Government data
The average spacing for gravity data in the Savory Sub-basin is one station per 121 km2 (11 times 11
km grid) These data were principally collected by BMR in the early 1960s There are a few
additional regional gravity traverses across the sub-basin which are also included in the
BMRAGSO dataset These data were reprocessed and interpreted for GSWA (Fig 10) and a
report on this work is also included in Appendix 4
The GSWA completed a large semi-detailed gravity survey in the eastern Savory Sub-basin
utilizing helicopter support and Differential Global Positioning Survey (DGPS) techniques (Fig
8) This gravity survey completed in August 1995 consists of 2300 gravity stations on a 2 times 3 km
grid All stations were acquired by helicopter using Scintrex gravimeters and Ashtek dual
frequency DGPS equipment for determining location This highly efficient system allowed the
acquisition of more than 100 gravity stations per day in remote areas The resolution of this survey
is +30 cm and +05 microms-2 (Daishsat 1995) These data (Fig 11) represent a significant
improvement on the previous regional survey data and are available from GSWA (GSWA
1996ab) The results of the interpretation of these data were presented at the 1997 ASEG
Convention (Carlsen and Shevchenko 1997)
Mineral industry data
Three small gravity surveys were conducted by Oilmin NL (Fig 8) and the relevant WAMEX
reports are M 2681I 2610 I 2435 I 2567 These three surveys are of limited value because height
control was provided by barometers only and the surveys were not tied to the national gravity grid
31
23deg
25deg
120deg 122deg
Trainor 1
SAVORY
SUB-BASIN
MKS54 160498
100 km
1995 SavoryGravity Survey
254
-1056
micromsec2
Figure 10 Regional Bouguer gravity map of the Savory Sub-basin
23deg
24deg
25deg
122deg30 123deg
TRAINOR 1
123deg30
50 km
MKS53 160498
-116
-626
micro msec2
Figure11 Detailed Bouguer gravity map of the
Savory 1995 Gravity Survey from the eastern Savory Sub-basin
32
Government and academic reports
Chronostratigraphy and geochemistry
The understanding of Neoproterozoic organic chemistry palynology and structural evolution is
essential to the interpretation of hydrocarbon prospectivity Pertinent reports are included in the
bibliography (Appendix 1) Unpublished palaeontology reports describe the palynology of wells in
the Savory Sub-basin (Grey 1995andashe 1996a) Grey and Cotter (1996) discussed the potential for
Neoproterozoic palynomorphs to provide a biostratigraphic framework and palaeoenvironmental
interpretation Grey and Stevens (1997) reviewed the results of palynological studies of wells
drilled in the sub-basin and reported that Supersequence 1 palynomorphs are present in TWB 6
TWB 9 and LDDH1 (Appendix 3) Grey (1996b) reported on the use of stromatolites for
correlation in the Neoproterozoic and Stevens and Grey (1997) discussed the application of
stromatolite biostratigraphy in correlating isolated dolomite outcrops in the sub-basin with well
and seismic data in the Officer Basin and Centralian Superbasin
Although geochemical data from the Savory Sub-basin are very limited results mostly
confirm thermal maturities inferred from TAI for LDDH1 and Trainor 1 (Ghori in prep Stevens
and Adamides in prep) Those parts of the Officer Basin in Western Australia which lie to the
east of the Savory Sub-basin are sparsely drilled but Ghori (in prep) reports that most of the
Neoproterozoic succession presently lies within the oil-generative window However his study
has been unable to identify effective source-rock units and the source for oil shows Thin source
rocks are present in the Neoproterozoic in LDDH1 (Fig 9) and in three wells which lie to the east
and southeast of the Savory Sub-basin namely NJD 1 Kanpa 1A and Yowalga 3
Proposed work program
From the above limited information it is concluded that additional research on the hydrocarbon
potential of the sub-basin is justified and proposals are outlined below
bull Additional modelling of gravity and aeromagnetic data from the Savory Sub-basin is required
in light of the results from Trainor 1 and Boondawari 1 Trainor 1 showed that what appeared
to be a structurally simple area based on outcrop aeromagnetic and gravity data was in fact an
area of major structuring Boondawari 1 intersected a dolerite which is in good depth
agreement with aeromagnetic depth to source results showing this technique is useful in
detecting the depth to intrusive bodies
33
bull Additional data from mineral and petroleum exploration bores may become available and
analysis of samples from these wells should be undertaken and interpreted in the context of
their relevance to the Officer Basin
bull Stratigraphic coring in the Blake Fault and Fold Belt and in the Wells Foreland Sub-basin (Fig
1) targeting source rocks is considered essential to the continuing evaluation of the
hydrocarbon prospectivity of the Savory Sub-basin
bull Correlations using at least outcrop well and potential-field data should be prepared to link the
sub-basin with the better known parts of the Officer Basin to the east
bull Remapping is required to clarify boundary positions within the Cornelia Formation this may
resolve some of the current problems of the relationship between this unit and the rest of the
Savory Sub-basin
bull Further work is required to explain the Early Cambrian or Sturtian ages interpreted for the
Cornelia Formation from sedimentary zircon UndashPb dating in drillhole Trainor 1 The
determination of the age of the organically rich but overmature claystones in this well is
critical to assessing the hydrocarbon potential of the region
bull The thin dark mudstones intersected by Akubra 1 in the Mundadjini Formation warrant
geochemical analysis Analyses of the oil shows in Mundadjini 1 and Boondawari 1 are
currently being undertaken by Amadeus Petroleum
bull Geochemical analysis of hydrocarbons in the Bangemall Basin drillhole OD23 has been
performed by Jubilee Gold and the results will be reviewed when they are submitted to
GSWA The possibility of source rocks within the Bangemall Basin charging traps within the
Bangemall Basin and the overlying Savory Sub-basin requires further investigation
Conclusions
The Savory Sub-basin is a frontier region with only three recently drilled petroleum exploration
wells and no seismic data Based on existing geological and geophysical data it is considered too
early to draw conclusions about the hydrocarbon prospectivity of the sub-basin at this stage and
there are several reasons why the area warrants further investigation
34
1 Thick accumulations of sedimentary rocks are present (up to 8 km thickness inferred) which
may contain source reservoir and sealing strata
2 Minor oil shows occur in Mundadjini 1 and Boondawari 1 and bitumen is present in mineral
exploration drillhole LDDH1 suggesting that hydrocarbons have migrated within the
Neoproterozoic sequence of the Savory Sub-basin Oil and bitumen are present in mineral
exploration drillhole OD23 in the Bangemall Basin immediately to the south of the Savory
Sub-basin and it is possible that source rocks from the Bangemall Basin could charge traps in
the overlying Savory Sub-basin
3 The age of sedimentary rocks in the sub-basin is still poorly constrained but some of the
Neoproterozoic sedimentary rocks located on GUNANYA and TRAINOR are within the
hydrocarbon-generation window It is possible that a significant thickness of Phanerozoic
sedimentary rocks may also be present
4 Friable sandstones with visible porosity outcrop extensively suggesting numerous potential
reservoirs
5 Significant but not intense faulting and folding has been mapped implying large structural
traps may be present
6 Evaporitic sedimentary rocks occur in several formations and may provide good source rocks
and excellent seals
35
References
APAK S N and CARLSEN G M 1997 A compilation and review of data pertaining to the
hydrocarbon prospectivity of the Canning Basin Western Australia Geological Survey
Record 199610 103p
BAGAS L GREY K and WILLIAMS I R 1995 Reappraisal of the Paterson Orogen and
Savory Basin Western Australia Geological Survey Annual Review 1994ndash95 p 55ndash63
BUSBRIDGE M 1994 Lake Disappointment Exploration Licence 451064 Third Annual
Report Lake Disappointment Diamond Drill Hole LDDH1 Normandy Exploration Limited
Western Australia Geological Survey M-series Item 7567 A41358 (unpublished)
CARLSEN G M and SHEVCHENKO S I 1997 Petroleum exploration in Proterozoic basins
using potential fields data and stratigraphic coring Australian Society of Exploration
Geophysicists 12th Geophysical Conference Handbook Sydney 1997 Preview no 66 p 83
(abstract only)
COWAN D 1995 Savory Basin quantitative magnetic interpretation Western Australia
Geological Survey S-series S10331 (unpublished)
DAISHSAT PTY LTD 1995 Operational and processing report Savory Basin gravity survey
Western Australia Geological Survey S-series S10332 (unpublished)
GARD E and GARD R 1990 Canning Stock Route a travellerrsquos guide for a journey through
history Perth Western Australia Western Desert Guides 448p
GEOLOGICAL SURVEY OF WESTERN AUSTRALIA 1996a Savory Basin first vertical
derivative of Bouguer gravity image 1250 000 Western Australia Geological Survey
GEOLOGICAL SURVEY OF WESTERN AUSTRALIA 1996b Savory Basin Bouguer gravity
image 1250 000 Western Australia Geological Survey
GHORI K A R in prep Petroleum source rock potential and thermal history Officer Basin
Western Australia Western Australia Geological Survey Record
36
GREY K 1995a Savory Basin drillhole BWB 1 (Bullen waterbore) palynology and thermal
maturation GSWA Palaeontology Report no 199512 (unpublished)
GREY K 1995b Savory Basin drillholes TWB 1 2 6 9 (Trainor waterbores) palynology and
thermal maturation GSWA Palaeontology Report no 199520 (unpublished)
GREY K 1995c Palynology of Normandy-Poseidon Lake Disappointment-1 corehole
Tarcunyah Group Paterson Orogen GSWA Palaeontology Report no 199521 (unpublished)
GREY K 1995d Savory Basin drillhole Trainor 1 (Trainor diamond drilling) palynology and
thermal maturity GSWA Palaeontology Report no 199524 (unpublished)
GREY K 1995e Savory Basin drillhole Trainor 1 (Trainor diamond drilling) Additional
Preparation of two samples GSWA Palaeontology Report no 199528 (unpublished)
GREY K 1995f Neoproterozoic stromatolites from the Skates Hills Formation Savory Basin
Western Australia and a review of the distribution of Acaciella australica Australian Journal
of Earth Sciences v 42 p 123ndash132
GREY K 1996a Savory Basin drillhole Trainor 1 (Trainor diamond drilling) Additional
samples palynology and thermal maturation GSWA Palaeontology Report no 199615
(unpublished)
GREY K 1996b Preliminary stromatolite correlations for the Neoproterozoic of the Officer
Basin and a review of Australia-wide correlations GSWA Palaeontology Report no 199615
(unpublished)
GREY K and COTTER K L 1996 Palynology in the search for Proterozoic hydrocarbons
Western Australia Geological Survey Annual Review for 1995ndash96 p 70ndash80
GREY K and STEVENS M K 1997 Neoproterozoic palynomorphs of the Savory Sub-basin
Western Australia and their relevance to petroleum exploration Western Australia
Geological Survey Annual Review for 1996ndash97 p 49ndash54
HUBBARD R J PAPE J and ROBERTS D G 1985 Depositional sequence mapping as a
technique to establish tectonic and stratigraphic framework and evaluate hydrocarbon
potential on a passive continental margin in Seismic stratigraphy II an integrated approach
37
edited by O R BERG and D G WOOLVERTON American Association of Petroleum
Geologists Memoir 39 p 79ndash91
LIBBY WG 1995 A petrological report on six samples of bore cuttings from the Savory Basin
Western Australia Western Australia Geological Survey S-series S31307 (unpublished)
MORTON JGG and DREXEL JF 1997 The petroleum geology of South Australia Vol 3
Officer Basin South Australia Department of Mines and Energy Resources Report Book
9719
MUHLING P C and BRAKEL A T 1985 Geology of the Bangemall Group mdash the evolution
of an intracratonic Proterozoic basin Western Australia Geological Survey Bulletin 128
219p
MYERS J S 1990 Precambrian tectonic evolution of part of Gondwana southwestern Australia
Geology v18 p 537ndash540
NELSON D R 1997 Compilation of SHRIMP UndashPb zircon data Western Australia Geological
Survey Record 19972 196p
PAYTON C E 1977 Seismic stratigraphy mdash applications to hydrocarbon exploration
American Association of Petroleum Geologists Memoir 26 516p
PERINCEK D 1996a The age of NeoproterozoicndashPalaeozoic sediments within the Officer Basin
of the Centralian Super-basin can be constrained by major sequence-bounding unconformities
APPEA Journal v 36 pt 1 p 350ndash368
PERINCEK D 1996b The stratigraphic and structural development of the Officer Basin
Western Australia a review Western Australia Geological Survey Annual Review 1995ndash
1996 p 135ndash148
PERINCEK D 1998 A compilation and review of data pertaining to the hydrocarbon
prospectivity of the Officer Basin Western Australia Geological Survey Record 19976
POSAMENTIER H W JERSEY M T and VAIL P R 1988 Eustatic controls on clastic
deposition 1 mdash Conceptual framework in Sea-level changes an integrated approach edited by
C K WILGUS B S HASTINGS C G St C KENDALL H W POSAMENTIER
38
C A ROSS and J C VAN WAGONER Society of Economic Paleontologists and
Mineralogists Special Publication no 42
STEVENS M K and ADAMIDES N G in prep GSWA Trainor 1 well completion report
Savory Sub-basin Officer Basin Western Australia with notes on petroleum and mineral
potential Western Australia Geological Survey Record 199612
STEVENS M K and GREY K 1997 Skates Hills Formation and Tarcunyah Group Officer
Basin mdash carbonate cycles stratigraphic position and hydrocarbon prospectivity Western
Australia Geological Survey Annual Review for 1996ndash97 p 55ndash60
SUMMONS RE and POWELL C McA 1991 Petroleum source rocks of the Amadeus Basin
in Geological and geophysical studies in the Amadeus Basin central Australia edited by R J
KORSCH and JM KENNARD Australia BMR Geology and Geophysics Bulletin 236
TRAVERSE A 1988 Palaeopalynology Boston Unwin Hyman 600p
VAIL P R MITCHUM R M Jr TODD R G WIDMIER J M THOMPSON S III
SANGREE J B BUBB J N and HATLELID W G 1977 Seismic stratigraphy and
global changes of sea level in Seismic stratigraphy mdash applications to hydrocarbon
exploration edited by C E PAYTON American Association of Petroleum Geologists
Memoir 26 516p
WALTER M R and GORTER J 1994 The Neoproterozoic Centralian Superbasin in Western
Australia the Savory and Officer Basins in The sedimentary basins of Western Australia
edited by P G PURCELL and R R PURCELL Petroleum Exploration Society of Australia
Symposium Perth WA 1994 Proceedings p851ndash864
WALTER M R GREY K WILLIAMS I R and CALVER C R 1994 Stratigraphy of the
Neoproterozoic to early Palaeozoic Savory Basin and correlation with the Amadeus and
Officer Basins Australian Journal of Earth Sciences v 41 p 533ndash546
WALTER M R VEEVERS J J CALVER C R and GREY K 1995 Neoproterozoic
stratigraphy of the Centralian Superbasin Australia Precambrian Research v 73 p 173ndash195
WILLIAMS I R 1992 Geology of the Savory Basin Western Australia Western Australia
Geological Survey Bulletin 141 115p
39
WILLIAMS I R 1995a Bullen WA (2nd Edition) Western Australia Geological Survey
1250 000 Geological Series Explanatory Notes 23p
WILLIAMS I R 1995b Trainor WA (2nd Edition) Western Australia Geological Survey
1250 000 Geological Series Explanatory Notes 31p
WILLIAMS I R and TYLER I M 1991 Robertson WA (2nd edition) Western Australia
Geological Survey 1250 000 Geological Series Explanatory Notes 36p
40
41
Appendix 1
Bibliography
Reports which are relevant to this investigation but which are not specifically cited are listed
below
BAILLIE P W POWELL C McA LI Z X and RYALL A M 1994 The tectonic
framework of Western Australiarsquos Neoproterozoic to recent sedimentary basins in The
sedimentary basins of Western Australia edited by P G PURCELL and R R PURCELL
Petroleum Exploration Society of Australia Symposium Perth WA 1994 Proceedings p
45ndash62
BRADSHAW M T BRADSHAW J MURRAY A P NEEDHAM D J SPENCER L
SUMMONS R E WILMOT J and WINN S 1994 Petroleum systems in West Australian
basins in The sedimentary basins of Western Australia edited by P G PURCELL and R R
PURCELL Petroleum Exploration Society of Australia Symposium Perth WA 1994
Proceedings p 93ndash118
CLARKE G L 1991 Proterozoic tectonic reworking in the Rudall Complex Western Australia
Australian Journal of Earth Science v38 p 31ndash44
COCKBAIN A E and HOCKING R M 1990 Phanerozoic in Geology and mineral resources
of Western Australia Western Australia Geological Survey Memoir 3 p 750ndash755
ETHERIDGE M and WALL V 1994 Tectonic and structural evolution of the Australian
Proterozoic 12th Australian Geological Convention Geological Society of Australia
Abstracts no 37 p 102ndash103
GOODE A D T 1981 Proterozoic geology of Western Australia in Precambrian of the
Southern Hemisphere Developments in Precambrian geology 2 edited by I R HUNTER
Amsterdam Elsevier p 105ndash203
GREY K and JACKSON M J 1983 A re-assessment of stromatolite evidence for the
correlation of the Late Proterozoic Neale and Ilma Beds Officer Basin Western Australia
Australia BMR Journal of Australian Geology and Geophysics v 8 p 359
42
HICKMAN A H WILLIAMS I R and BAGAS L 1994 Proterozoic geology and
mineralization of the TelferndashRudall region Paterson Orogen Geological Society of Australia
(WA Division) Excursion Guidebook no 5 56p
HOCKING R M MORY A J and WILLIAMS I R 1994 An atlas of Neoproterozoic and
Phanerozoic basins of Western Australia in The sedimentary basins of Western Australia
edited by P G PURCELL and R R PURCELL Petroleum Exploration Society of Australia
Symposium Perth WA 1994 Proceedings p 21ndash 44
JACKSON P R 1966 Geology and review of exploration Officer Basin Western Australia
Hunt Oil Company Western Australia Geological Survey S-series S26 (unpublished)
JACKSON M J 1971 Notes on a geological reconnaissance of the Officer Basin Western
Australia Australia BMR Geology and Geophysics Record 19715 30p
JACKSON M J and van de GRAAFF W J E 1981 Geology of the Officer Basin Western
Australia Australia BMR Geology and Geophysics Bulletin 206 102 p
LOWRY D C JACKSON M J van de GRAAFF W J E and KENNEWELL P J 1971
Preliminary result of geological mapping in the Officer Basin Western Australia Western
Australia Geological Survey Annual Report for 1971 p 50ndash56
MYERS J S 1990 Precambrian in Geology and mineral resources of Western Australia
Western Australia Geological Survey Memoir 3 p 737ndash750
MYERS J S SHAW R D and TYLER I M 1994 Proterozoic tectonic evolution of
Australia 12th Australian Geological Convention Geological Society of Australia Abstracts
no 37 p 312
NEDIN C and JENKINS R J F 1991 Re-evaluation of unconformities separating the
lsquoEdiacaranrsquo and Cambrian systems South Australia Palaios v 6 p 102ndash108
PHILLIPS B J JAMES A W and PHILIP G M 1985 The geology and hydrocarbon
potential of the north-western Officer Basin APEA Journal 25 (1) p 52ndash61
POWELL C McA LI Z X McELHINNY M W MEERT J G and PARK J K 1993
Paleomagnetic constraints on timing of the Neoproterozoic breakup of Rodinia and Cambrian
formation of Gondwana Geology v 21 p 889ndash892
43
POWELL C McA PREISS W V GATEHOUSE C G KRAPEZ B and LI Z X 1994
South Australian record of a Rodinian epicontinental basin and its mid-Neoproterozoic
breakup to form the Palaeo-Pacific Ocean Tectonophysics v 237 no 3ndash4 p 113ndash140
PREISS W V 1976 Proterozoic stromatolites from the Nabberu and Officer Basins Western
Australia and their biostratigraphic significance South Australia Geological Survey Report
of Investigations no 47 p 1ndash51
TOWNSON W G 1985 The subsurface geology of the western Officer Basin mdash results of
Shellrsquos 1980ndash1984 petroleum exploration campaign APEA Journal v 25 (1) p 34ndash51
WATTS K J 1982 The geology of the Townsend Quartzite Upper Proterozoic shallow water
deposit of the Northern Officer Basin Western Australia Perth University of Western
Australia BSc honours thesis (unpublished)
WELLS A T and KENNEWELL P J 1974 Evaporite exploration in the Officer Basin
Western Australia at the Madley Diapirs Australia BMR Record 1974194 (unpublished)
WILLIAMS I R and MYERS J S 1990 Paterson Orogen in Geology and mineral resources
of Western Australia Western Australia Geological Survey Memoir 3 p 274ndash286
WILLIAMS I R 1990 Savory Basin in Geology and mineral resources of Western Australia
Western Australia Geological Survey Memoir 3 p 329ndash334
WILLIAMS I R 1994 The Neoproterozoic Savory Basin Western Australia in The
sedimentary basins of Western Australia edited by P G PURCELL and R R PURCELL
Petroleum Exploration Society of Australia Symposium Perth WA 1994 Proceedings p
841ndash850
WILSON R B 1967 Woolnough Hills and Madley diapiric structures Gibson Desert WA
APEA Journal v 7 p 94ndash102
44
Appendix 2
Meteorological data (from Bureau of Meteorology Perth 1994)
Table 21 Wiluna rainfall (mm)
Year Jan Feb Mar Apr May Jun Jul Aug Sept Oct Nov Dec
1975 0 45 446 309 306 59 276 4 34 886 638 164 1976 16 154 12 138 53 16 34 62 12 238 0 2 1977 44 0 66 74 68 95 24 363 1 58 12 727 1978 234 522 94 16 0 96 367 24 16 353 185 45 1979 19 173 122 88 91 4 0 246 58 0 169 114 1980 148 764 68 1081 259 626 629 06 56 02 174 0 1981 123 476 192 32 196 118 44 74 14 0 28 312 1982 374 705 206 244 1079 92 02 143 368 526 368 118 1983 1 112 928 248 0 212 56 32 5 1 42 496 1984 149 7 342 84 836 0 348 132 224 04 16 172 1985 596 483 0 166 556 0 514 56 0 0 4 0 1986 0 154 35 0 0 1085 23 01 239 137 0 04 1987 1204 119 19 89 17 575 154 126 07 1 0 398 1988 46 202 164 13 388 0 202 104 0 0 224 1309 1989 207 234 26 703 278 536 57 0 01 0 144 02 1990 1035 23 281 46 126 53 94 218 44 9 42 0 1991 48 0 41 45 0 472 297 12 0 1 0 7 1992 112 96 1025 1227 323 65 04 174 0 132 48 4 1993 0 697 0 202 445 0 12 306 18 05 14 33 Mean 25 35 22 27 27 25 18 12 6 13 13 21
JAN FEB MAR APR MAY JUN JUL AUG SEP OCT NOV DEC0
10
20
30
40
Mea
n R
ain
fall
(mm
)
Month
Mean monthly rainfall in Wiluna
MKS41 140498
45
Table 22 Wiluna minimum temperature (degC)
Year Jan Feb Mar Apr May Jun Jul Aug Sept Oct Nov Dec
1975 ndash 23 203 15 94 63 71 62 103 124 169 205 1976 242 229 194 15 10 63 59 73 95 143 16 228 1977 243 25 197 148 96 95 56 86 102 ndash 188 23 1978 241 232 203 18 102 64 76 8 9 152 19 205 1979 255 226 216 167 83 6 59 79 97 145 198 223 1980 255 226 231 155 134 83 68 75 121 108 193 223 1981 245 216 19 182 119 6 54 78 138 159 163 218 1982 232 224 177 16 ndash ndash 37 111 112 164 209 225 1983 235 24 197 147 112 88 39 88 121 162 189 219 1984 241 243 191 156 ndash 72 66 7 95 161 182 211 1985 244 231 ndash 159 98 65 71 73 117 147 205 ndash 1986 ndash 229 226 155 93 96 43 49 10 122 ndash 219 1987 ndash 217 183 175 85 77 68 68 112 ndash ndash 221 1988 238 214 209 178 111 ndash ndash 86 104 157 171 195 1989 ndash 237 199 165 107 67 44 61 107 131 187 ndash 1990 232 ndash 211 155 118 62 57 87 102 149 195 22 1991 26 256 217 168 122 101 78 ndash 113 18 168 219 1992 227 227 214 169 102 98 59 69 ndash 125 159 196 1993 241 218 196 171 103 ndash 49 68 88 128 192 211 Mean 24 23 20 16 10 8 6 8 11 14 18 21
NOTE Dashes indicate data unavailable
JAN FEB MAR APR MAY JUN JUL AUG SEP OCT NOV DEC0
10
20
30
40
Month
MKS43 140498
50
Mean monthly minimum temperatures at Wiluna
Mea
n T
emp
erat
ure
(degC
)
46
Table 23 Wiluna maximum temperature (degC)
Year Jan Feb Mar Apr May Jun Jul Aug Sept Oct Nov Dec
1975 ndash 349 326 281 247 201 197 212 256 248 31 344 1976 374 369 346 297 248 206 208 225 265 287 313 388 1977 397 392 352 296 234 212 222 244 ndash 308 337 383 1978 378 345 346 316 242 195 176 205 231 295 334 356 1979 403 36 364 295 ndash ndash ndash 193 242 318 359 373 1980 392 342 377 275 24 176 179 233 292 288 349 391 1981 385 346 337 342 242 178 201 224 30 326 326 369 1982 372 359 315 307 ndash ndash 196 253 252 305 353 379 1983 381 389 327 272 263 222 187 248 287 321 336 366 1984 378 393 322 299 226 215 178 214 234 ndash 336 364 1985 40 366 ndash 294 224 216 205 212 284 307 355 ndash 1986 ndash 383 372 307 ndash 193 166 196 261 277 ndash 382 1987 ndash 339 328 305 21 202 214 218 275 ndash ndash 374 1988 388 365 353 301 23 ndash ndash 228 283 334 31 33 1989 ndash 375 339 285 238 179 181 219 275 298 336 ndash 1990 368 ndash 36 309 268 19 188 205 274 309 373 393 1991 414 416 363 315 268 206 21 ndash 279 338 332 368 1992 363 383 336 263 213 178 213 197 ndash 285 313 359 1993 396 357 344 301 221 ndash 197 215 253 294 347 362 Mean 39 37 34 30 24 20 20 22 27 30 34 37 NOTE Dashes indicate data unavailable
JAN FEB MAR APR MAY JUN JUL AUG SEP OCT NOV DEC0
10
20
30
40
Month
MKS42 140498
50
Mean monthly maximum temperatures at Wiluna
Mea
n T
emp
erat
ure
(degC
)
47
Appendix 3
Table 31 Summary of palynological results
Drillhole Depth (m) F no(a) GSWA no Lithology Formation Assemblage TAI(b)
BWB 1 74ndash75 F49668 135741 dark-grey siltstone basalt Jilyilli gt5 BWB 1 98ndash100 F49669 135742 dark-grey siltstone basalt Jilyilli gt5 BWB 1 121ndash122 F49670 135743 dark-grey siltstone basalt Jilyilli gt5 TWB 1 86ndash87 F49671 135631 dark-grey siltstone McFadden 3+ TWB 1 104ndash105 F49672 135632 dark-grey siltstone Cornelia 3+ TWB 1 121ndash122 F49673 135633 dark-grey siltstone Cornelia 4 TWB 2 14ndash15 F49674 135634 dark-grey siltstone Skates Hills 3+ TWB 6 49ndash50 F49675 135675 dark-grey siltstone Cornelia 1 3+ TWB 9 49ndash51 F49676 135704 dark-grey siltstone Brassey Range 1 3+ Trainor 1 37497- F49733 138939 black mudstone with Cornelia 5 37509 light-grey siltstone Trainor 1 3809 F49734 138940 dark-grey and black Cornelia 4- laminated mudstone Trainor 1 4170 F49735 138941 black unlaminated mudstone Cornelia 4- Trainor 1 4950 F49851 139501 dark-grey indurated siltstone Cornelia 5 Trainor 1 6032 F49852 139502 dark- and light-grey Cornelia 5 indurated siltstone Trainor 1 6434 F49853 139503 greenish indurated finely Cornelia 5 laminated siltstone LDDH 1 270 F49678 138934 dark-grey siltstone interbeds Waters 1 3+ in enterolithic evaporite Tarcunyah Gp LDDH 1 277 F49679 138935 dark-grey siltstone in cavity Waters 1 3+ in enterolithic evaporite Tarcunyah Gp
NOTES (a) GSWA Fossil Catalogue number (b) TAI = Thermal Alteration Index of Traverse (1988 plate 1)
48
Appendix 4
Savory Sub-basin quantitative magnetic and gravity interpretation (extracted from Cowan 1995)
Summary
A program of quantitative aeromagnetic interpretation has been completed on BMRAGSO data from the Savory Sub-
basin Western Australia Quantitative aeromagnetic interpretation utilized the 3D Euler deconvolution method
supported by wavenumber filtering and image processing The results have provided useful information on structural
trends and depth to magnetic sources in a structurally complex area Depth to magnetic source analysis has provided
information on intra-sedimentary magnetic sources as well as basement rocks
The results of the interpretation support previously identified depocentres However the presence of magnetic
sources at several levels makes it very difficult to produce a reliable magnetic basement depth contour map It is
considered more productive to work with the 3D Euler colour circle plots and images rather than trying to contour the
results It would be necessary to carry out a full-scale interpretation of the BMRAGSO profile data to improve on the
3D Euler results The regional gravity was found to be useful in interpreting the regional setting of the area although
the very wide data spacing limits quantitative use of the data The gravity data show quite a complex picture with
limited consistent correlation between gravity features and basin structures This suggests that gravity anomalies
reflect changes in density of the basement rocks rather than basement topography especially in the northern part of the
basin
It is recommended that the GSWA investigate access to company confidential high-resolution aeromagnetic data
prior to planning further aeromagnetic surveys Private companies have flown large parts of the northern half of the
area as part of their diamond exploration program Additional gravity coverage of the area may be more cost effective
than magnetic surveys as the gravity data provides more information on changes within the sedimentary section
Introduction
The main use of aeromagnetic data in petroleum exploration has been the determination of magnetic basement
topography although there has been increasing interest in analysis of intra-sedimentary magnetic anomalies
intrabasement and suprabasement magnetic anomalies These anomalies are used to determine depth to magnetic
basement rocks and hence determine the thickness of the sedimentary sequence Unfortunately interpretation of the
intrabasement and suprabasement magnetic anomalies is non-unique in terms of position and size of causative sources
because of the inherent ambiguity of potential-field methods However this ambiguity can be reduced by placing
49
constraints on source geometry and magnetization and by using geological and other geophysical data to constrain
the solution
Before 1970 most depth-determination techniques involved graphical determination of slopes of selected
magnetic anomalies and application of various empirical factors to convert the slopes into depth estimates Geological
Society of America Memoir 47 Interpretation of Aeromagnetic Maps by Vacquier et al (1951) was a landmark for
this type of interpretation
Automated interpretation procedures have played an increasingly important role in depth interpretation and a
wide range of techniques have been developed Many of these techniques are designed for application to located data
profiles and assume a two-dimensional geometry However there has been renewed interest in techniques applicable
to gridded data
Two distinct types of method can be recognized In the first case often described as discrete methods individual
isolated magnetic anomalies are interpreted and the results used to produce a map of basement relief In the second
case often described as continuous methods areas of data containing a number of anomalies are interpreted
statistically to produce direct output of basement depths
The discrete methods usually involve a semiautomatic initial phase which generates a large number of possible
depth solutions and an interactive second phase to screen and select acceptable solutions The advantage of this
approach is that the interpreter can select features that are relatively free from interference from adjacent anomalies
and consider all aspects of a particular magnetic anomaly The disadvantage is that interpretation can be very time
consuming as a wide range of depths are usually possible depending on the initial model chosen and a significant
amount of effort is needed to select the correct model In the case of the Savory Sub-basin dataset we encountered
problems in separating basement related effects from the effects of shallower intrasedimentary magnetic sources
Because of these problems we have concentrated on displaying the Euler results accompanied by separation filter
images of the data to show the shallower effects and deeper effects rather than trying to refine a 3D Euler
deconvolution depth-to-crystalline-basement contour
The continuous methods are very direct provided that the rather restrictive assumption can be made that all
anomalies are due to lateral magnetization changes due to basement topography This means that shallow effects and
large intrabasement anomalies must be removed from the data This involves judgement and skill as it is necessary to
distinguish between the lower amplitude suprabasement anomalies due to basement topography and the larger
intrabasement anomalies reflecting magnetization changes within the basement These methods were not considered
suitable for the Savory Sub-basin magnetic dataset but were used to invert the gravity data
50
Limitations of magnetic and gravity interpretation
Interpretation of the area is limited by a shortage of information on the nature and physical properties of the deeper
sedimentary sequence and the underlying basement rocks However using techniques such as cross-correlation of
gravity and pseudo-gravity data it is possible to try to differentiate between anomalies relating to basement and those
related to the sedimentary sequence
Gravity anomalies reflect changes within the sedimentary sequence as well as basement condition These
changes in density of sedimentary rocks produce gravity anomalies without a corresponding magnetic anomaly hence
the complementary nature of gravity and magnetic surveys The main use of magnetics is to determine depth to
magnetic basement and any intra-sedimentary volcanic rocks or intrusives whereas gravity provides much more
general information on the sedimentary sequence
Unfortunately interpretation of gravity anomalies is complicated since they can be due to a number of geological
features including
bull major basement faults
bull basement highs
bull igneous intrusions within the basement
bull sedimentary basins which may or may not be isostatically compensated
bull intra-sedimentary volcanics and associated plutonic centres
Two major problems affect the interpretation of both magnetic and gravity data
1 The inherent ambiguity of potential-field data There is no unique solution to any measured gravity or magnetic
anomaly and theoretically there will be an infinite number of source geometry and magnetizationdensity
combinations which will fit the observed data This means that any a priori information which helps to select a
suitable model is very useful
2 Measured anomalies are the summation of effects from different depths For example an observed gravity profile
may contain contributions from shallow sources (density variations within the sedimentary basin) intermediate
depth sources (density variations due to large igneous intrusions within the basement) and deep sources (crustal
thinning producing a mantle anomaly) Separation of these component responses is the regionalresidual problem
which we solve using spectral analysis and differential upward continuation-based separation filtering
Regional setting and interpretation overview
The area studied includes parts of BALFOUR DOWNS (SF51-9) RUDALL (SF51-10) ROBERTSON (SF51-13) GUNANYA
(SF51-14) COLLIER (SG50-4) BULLEN (SG51-1) TRAINOR (SG51-2) MADLEY (SG51-3) NABBERU (SG50-5)
STANLEY (SG51-6) and HERBERT (SG51-7) 1250 000 sheets Broadly the area lies between latitudes 22deg00rsquondash25deg30rsquoS
and longitudes 119deg30rsquondash123deg30rsquoE
51
Regional gravity
The AGSO regional gravity data (at nominal 11 km spacing) was gridded at a 4 km mesh spacing using a minimum-
curvature algorithm Bouguer gravity values in the area are negative reflecting mass deficiency at depth and range
from -84 mgals to -25 mgals
A Bouguer gravity colour image is shown as Figure 41 A residual grid was produced by removing a fifth-order
orthogonal polynomial from the Bouguer data but did not add to the interpretation
120deg 121deg 122deg 123deg
23deg
24deg
25deg
-25
-84
50 km
MKS46 180598
mgal
Figure 41 Regional Bouguer gravity (BMRAGSO data) gridded at 4 km
52
The data show a complex pattern of positive and negative anomalies with no clearly defined trends Correlations
with aeromagnetic data and known basin structures are poor A vague north-northwest linear trend appears to coincide
with the Marloo Fault (Figure 42) A prominent negative anomaly appears to coincide with the Blake Fold and Fault
Belt depocentre and continues as a narrower negative anomaly to the east until it widens out again near the edge of the
basin Elsewhere the gravity data show little correlation with known basin structures and it is likely that especially in
the north of the area gravity anomalies are due to density changes in the basement rather than changes in basement
topography
Production of wavelength-filtered residual gravity plots and vertical gradient plots showed very patchy aliased
data reflecting poor sampling in much of the area
Regional magnetics
The AGSO regional aeromagnetic data were gridded at a 400 m mesh spacing using a minimum-curvature algorithm
(Figure 43) Most of the data has a line spacing of 1600 m with small areas of 1 km spacing The quality of the data is
acceptable for regional interpretation but is not adequate for detailed analysis The accuracy of the flight path is rather
variable reflecting the vintage of the data and the noise envelope of the data is poor by modern standards Problems
were also encountered in joining different map sheets
The magnetic anomaly pattern over the south and west part of the area shows a strong high frequency signature
reflecting the presence of widespread basic sills and dykes Some of the major north-northeasterly trending dykes can
be traced over considerable distances
Discontinuous high-frequency anomalies extend as a northwest-trending zone through the centre of the area and
this zone includes a conspicuous circular magnetic anomaly which is probably a ring complex
The northern and eastern parts of the area are characterized by long-wavelength deep-seated basement magnetic
anomalies with 120deg and 150deg trends dominant The Marloo and Perentie Faults (Figure 42) appear as distinct linear
zones and offsets A prominent easterly trending negative anomaly in the northwest of the area appears to swing round
to the southeast and may separate different basement blocks One possible interpretation is that this very deep seated
anomaly separates areas of Archaean and Proterozoic basement
Regional geology
The regional geology is described in Williams (1992) The GSWA provided a digitized version of Plate 2 from this
Bulletin the structural interpretation map to use as an overlay (Figure 42)
53
Pp
Pp
PSd
PSd
PSd
PSd
PSd
PSo
PSt
PSt
PSf
PSf
PSf
PSb
PSb
PSb
PSsPSs
PSs
PSb
PSm
PSp
PSc
PSc
PSw
PSw
PSw
PSg
PSr
PSj
PSg
PM
Pk
PY
PY
PSd
L
L
L
L
L
L
L
LL
L
L
L
LL
L
LL
L L
LL
L L
L
L
L
L
L
L
L
LL
L
L
BLAKEDEPOCENTRE
MA
RLO
O
FAU
LT
PERENTIEFAULT
50 km
MKS39120598
120deg 121deg 122deg 123deg
25deg
24deg
23deg
Approximate boundaryof aeromagnetic interpretation
PML
PSgL
PSjL
PML
PSpL
PML
PML
PSfL
PSfL
PSpL
LPc
LPcLPcPSrL
LPA
Durba Sandstone
Woora Woora Formation
McFadden Formation
Tchukardine Formation
Boondawari Formation
Skates Hills Formation
Mundadjini Formation
Coondra Formation
Spearhole Formation
Watch Point Formation
Jilyili Formation
Brassey Range Formation
Glass Spring Formation
Paterson Formation
Yeneena Group
Karara Formation
Cornelia Formation
Kahrban Subgroup
Bangemall Group
Fault
Formation boundary
PSdL
PSoL
PSfL
PStL
PSbL
PSsL
PSmL
PScL
PSpL
PSwL
PSjL
PSrL
PSgL
Pp
PYL
PkL
LPc
LPA
PML
Savory Group Other Units
PYL
Figure 42 Regional geology and structure map (after Williams 1992)
54
120deg 121deg 122deg 123deg
23deg
24deg
25deg
5820
3750
MKS47 180598
nT
50 km
Figure 43 Regional aeromagnetic data total magnetic intensity (BMRAGSO data) gridded at 400 m
Analysis
3D analysis
3D Euler deconvolution was used as the primary depth-determination method The advantage of this approach is that
consistent solutions can be obtained over the entire area with minimal assumptions about source geometries Euler
deconvolution of gridded data is used for positional information and estimation of depth to top of source Euler
55
deconvolution yields a large number of depth solutions which have to be screened to reject spurious solutions Results
are plotted as circles in eight depth ranges with radius proportional to depth and colour coded
The 400 m total magnetic intensity grid was used for the analysis Horizontal gradients in x and y and the vertical
gradient were calculated 3D Euler deconvolution was tested on the 400 m gridded data using windows of 9 times 9 and
11 times 11 and 16 times 16 data points and structural indices 05 (fault) and 10 (sill or dyke) It was concluded that the
16 times 16 window produced the best results overall and final plots were produced for the 16 times 16 window and structural
index 05 (Fig 44) Results were very good over the northern and central parts of the area showing magnetic sources
Figure 44 Depth to magnetic source 3D Euler deconvolution 16 times 16 window of 400 m gridded data structural index 05
56
at several different levels Unfortunately in the extreme south of the area shallow intrasedimentary magnetic sources
(sills and dykes) dominated the inversion and the results contained few basement solutions
In order to reduce these problems the 400 m gridded data were filtered using a separation filter based on
interpretation of the log-energy spectrum The 3D Euler method was run on the filtered data in order to generate more
basement-depth solutions Results for the deep-separation filter data were gridded and presented as a colour image in
Cowan (1995) Attempts to grid the Euler output were unsatisfactory and it is considered safer to interpret the 3D
Euler depth plots The 3D Euler depth results from the separation-filter run should be analysed with care as perfect
separation of the basement can never be achieved and there will always be some contamination from sources at
different levels
The results of original total magnetic intensity 3D Euler depth estimation for structural index 05 using a 16 point
window have been plotted at 1500 000 scale (not included in this publication but available in Cowan (1995) from the
GSWA Library as S10331) and as reduced A4 colour circle plots (Figure 44)
The results of deep-basement 3D Euler depth estimation for structural index 05 using a 16 point window have
been plotted as a colour image at 1500 000 scale and as an A4 image (not included in this publication)
2D analysis
Two equispaced profiles were interpolated with a 50 m station interval from the AGSO-located data profiles for the
BULLEN 1250 000 sheet The interpolated profiles were analysed using 2D Euler deconvolution and Werner
deconvolution Results are included in Cowan (1995) and show the use of these methods for more detailed analysis
Filtered data
In order to reconcile 3D Euler results from shallow basement and intrasedimentary magnetic sources we produced
several separation-filtered maps and images We found the shallow-layer double-separation filter (Figure 45) to be
very effective for shallow sources and the deep-layer standard-separation filter (Figure 46) for the basement layer
Gravity and magnetic data correlation
Both lsquoreduced to the polersquo (RTP) magnetics (Figure 47) and pseudo-gravity data (Figure 48) were produced as part of
the reconciliation of gravity and magnetic signatures In both cases the filtering operations assumed magnetization by
induction in the present Earths field The RTP data are fairly similar to the total magnetic intensity The pseudo-
57
gravity data are dominated by a northwest-trending strong positive anomaly and there is little correlation with the
Bouguer gravity data
The poor magneticgravity correlation is confirmed by cross-correlation of the RTP magnetics and the gravity
gradient The correlation plot in Figure 49 shows little coherent response with numerous zones of positive and
negative correlation
Figure 45 Regional aeromagnetic data shallow layer separation filter (BMRAGSO data) gridded at 400 m
Results
In the north and east of the area on the Wells Foreland Sub-basin trend (refer to Figure 1 main text) we see a range
of quite deep 3D Euler depths and several trend directions with north-northwesterly dominant There are relatively few
shallow intrasedimentary solutions in this zone
The second area of deep 3D Euler solutions lies over the Blake depocentre (Figure 43) with several trend
directions
Elsewhere the 3D Euler results are dominated by shallow intrasedimentary depth solutions reflecting mainly the
dolerite sills dykes and the ring complex However where we do see basement-related solutions in the south and
west of the area they appear to be shallower than those noted for the Wells Foreland Sub-basin and the Blake
depocentre
58
Figure 46 Regional aeromagnetic data deep-layer separation filter (BMRAGSO data) gridded at 400 m
Figure 48 Regional aeromagnetic data pseudo-gravity transform (BMRAGSO data) gridded at 400 m
Figure 47 Regional aeromagnetic data reduced-to-pole (BMRAGSO data) gridded at 400 m
Figure 49 Regional aeromagnetic and gravity data gravitymagnetic correlation using RTP magnetics and gravity gradient (BMRAGSO data) gridded at 4 km
59
This subdivision of the area into two zones of deep solutions is consistent with interpreted depocentres
However the interference between sources at different levels and the complexity of the magnetic response of the
basement rocks precludes more refined interpretation at this stage
The area of deep 3D Euler solutions over the Blake depocentre correlates with the pronounced negative gravity
anomaly discussed in the gravity interpretation section Using a density contrast of -015 gcc the negative gravity
anomaly could indicate up to 6ndash8 km of low-density sedimentary rocks depending on assumptions about the regional
field
The area of deep 3D Euler solutions over the Wells Foreland Sub-basin has a complex gravity expression and no
clear basin structure emerges from inversion of these data As noted previously it is likely that observed gravity
anomalies reflect contrasts in basement density rather than basement topography
Separation filtering applied to the magnetic data helps to enhance the intrasedimentary magnetic signature and to
give a better impression of the basement magnetic signature even though separation of the basement response is not
perfect
Conclusions
Quantitative aeromagnetic interpretation using 3D Euler deconvolution supported by wavenumber filtering and image
processing has been successful in providing structural trend and depth information for the Savory Sub-basin
Quantitative magnetic interpretation has revealed two zones of relatively deep magnetic basement beneath the
Wells Foreland Sub-basin and the Blake depocentre
This analysis of the magnetic data supports interpreted depocentres but the complexity of the basement magnetic
signature and interference from sources at different depths precludes further refinement to a map of basement
topography
Regional gravity proved to be very useful in understanding the regional setting of the area and in providing
support for aspects of the interpretation The gravity data support the interpretation of the Blake depocentre
suggesting up to 6ndash8 km of low-density sedimentary rocks
The deep structure of the Savory Sub-basin area is obviously complex with different areas underlain by
Archaean and Proterozoic basement and with the Capricorn suture occurring in the centre of the area
60
Recommendations
The quantitative magnetic interpretation needs to be reconciled with geological models available for the area
In particular the zones tentatively identified as areas with thick sedimentary rocks the Wells Foreland Sub-
basin and the Blake depocentre need to be investigated
Cross sections should be prepared across the basin for joint magneticgravity modelling especially for the Blake
depocentre It is important to be able to explain the strong negative gravity anomaly in this area
In view of the effects of basement density contrasts on the gravity field for the northern part of the area we think
that additional gravity interpretation and acquisition of new gravity data may not be justified as they will not
contribute significantly to understanding basin evolution and structure
It is recommended that GSWA try to get access to company confidential high-resolution aeromagnetic data
rather than flying new surveys The GSWA might offer to fund flying of new infill areas as a bargaining point
References
The original text of this report by Cowan (1995) and 1500 000 scale maps are filed in the GSWA Library under
S10331
COWAN D 1995 Savory Basin quantitative magnetic interpretation Western Australia Geological Survey S-series
S10331 (unpublished)
VACQUIER V STEENLAND N C HENDERSON R G and ZIETZ I 1951 Interpretation of aeromagnetic
maps The Geological Society of America Memoir 47 151p
WILLIAMS I R 1992 Geology of the Savory Basin Western Australia Western Australia Geological Survey
Bulletin 141 115p
61
Appendix 5
Geochemistry
MKS38 250398
Saturate FractionC12+ GLC
1217
Pr18
Ph
22
31CSR WELL-13 315m Cuttings
Figure 51 Canning Stock Route Well 13 gas chromatograph of extract of auger drill sample
12
17
18
22
31
Pr Ph
LDDH 1 6623m CoreSaturate FractionC12+ GLC
MKS35 240398
Figure 52 Gas chromatograph of extract from core sample at 6623 m LDDH1
62
Table 51 Canning Stock Route Well 13 auger drill samples
GSWA sample Drill depth (m)(a) Comments
135601 150 At watertable 135602 203 (all samples consist 135603 310 of sand mud and water) 135604 315 At total depth
NOTE (a) Datum for drill depth is the top of sediment fill in the well which is 155 m below ground level (ie the total depth of 315 m is 47 m below ground level)
Table 52 Canning Stock Route Well 13 gas chromatography data for 315 m depth sediment sample
Parameter Value
Weight of rock extracted (grams) 945 Total extract (ppm) 519 n-Alkane distribution n-C12 07 n-C13 23 n-C14 26 n-C15 22 n-C16 19 n-C17 14 i-C19 23 n-C18 14 i-C20 08 n-C19 11 n-C20 16 n-C21 25 n-C22 29 n-C23 70 n-C24 42 n-C25 95 n-C26 43 n-C27 83 n-C28 38 n-C29 87 n-C30 31 n-C31 273 Alkane compositional data Pristane phytane ratio 279 Pristane n-C17 ratio 161 Phytane n-C18 ratio 059 CPI (1)(a) 284 CPI (2) 209 (C21 + C22) (C28 + C29) 043
NOTE (a) CPI= Carbon preference index
63
Table 53 LDDH1 extract liquid chromatography data for 6623 m concentration
Rock extracted Total extract (grams) (ppm)
702 313
NOTE ppm= parts per million
Table 54 LDDH1 saturate gas chromatography data of core for 6623 m alkane composition
Pristane Pristane Phytane (a) CPI (1) CPI (2) (C21+C22) Phytane n-C17 n-C18 (C28+C29)
103 026 024 103 102 325
NOTE (a)CPI = carbon preference index
Table 55 LDDH1 saturate gas chromatography data of core for 6623 m n-alkane distributions
Parameter Value
n-C12 17 n-C13 38 n-C14 55 n-C15 60 n-C16 65 n-C17 74 i-C19 19 n-C18 78 i-C20 19 n-C19 80 n-C20 79 n-C21 71 n-C22 64 n-C23 57 n-C25 43 n-C24 38 n-C27 31 n-C28 23 n-C29 19 n-C30 12 n-C31 10
64
Appendix 6
Table 61 Summary of data from Trainor waterbores (TWB) and Bullen waterbores (BWB)
Well AMG Elevation TD Status(b) Completion details Water Salinity Water level Flow rate Depth to consolidated AGD84 GL (m) (m) struck mgl(c) (m) (LHr) lithology aquifer(e) Z51(a) Interval (m) (100 mm PVC) (m) (mgl)(d)
TWB 1 473660E 453 122 comp 0ndash75 plain 63 7 300 24 2 880 12 m 7287404N 75ndash93 slotted (9 260) McFadden Fm 93ndash99 plain TWB 2 472 977E 475 23 abd nil 15 m 7285877N Skates Hills Fm dry TWB 3 473259E 475 50 abd nil 7 m 7285849N Skates Hills Fm dry TWB 4 463225 E 445 50 comp 0ndash22 plain 35 7 200 55 3 600 0 m 7286143N 22ndash34 slotted (8 140) Tertiary sand and gravel 23ndash60 plain TWB 5 463095E 445 31 comp 0ndash19 plain 13 26 000 655 3 600 Tertiary sand and gravel 7277721N 19ndash25 slotted (36 700) 25ndash31 plain TWB 6 457013E 455 50 comp 0ndash42 plain 38 920 119 600 0 m 7274352N 42ndash48 slotted (1 030) Cornelia Fm ss TWB 7 453739E 475 26 susp 0ndash2 plain 11 9 300 48 4 500 0 m 7263891N (10 500) Tertiary sand TWB 8 433893E 535 60 susp 0ndash2 plain 47 8 500 gt46 1 200 0 m 7245991N (10 900) Tertiary sand and Brassey Range Fm ss TWB 9 437219E 505 51 comp 0ndash47 plain 45 1 000 58 600 1 m 7235905N 47ndash51 slotted (990) Brassey Range Fm ss TWB 10 434927E 495 32 susp 0ndash2 plain 235 450 120 0 m 7225875N (500) Dolerite
65
BWB 1 287337E 580 122 abd Nil 1 m 7245861N Jilyili Fm dry BWB 2 288346E 545 50 comp 0ndash26 plain 15 630 3 29 000 0 m 7240423N 26ndash38 slotted (730) Tertiary sand and gravel 38ndash50 plain BWB 3 305637E 545 50 abd 19 8 800 43 7 200 0 m 7240423N (10 550) Tertiary ss BWB 4 320167E 515 445 comp 0ndash20 plain 9 980 445 24 000 0 m 7248097N 20ndash32 slotted (1 190) Tertiary ss 32ndash44 plain BWB 5 353393E 545 20 susp 0ndash2 plain 45 (970) 1 m 7238934N Basalt
NOTES (a) GPS accuracy ~ 150 m (b) Comp = completed abd = abandoned susp = suspended (c) Salinity from conductivity (d) Analysis total dissolved solids (e) Fm = Formation ss = sandstone
11
The depositional sequences recognized in the sub-basin are an order of magnitude thicker than
those described from Phanerozoic passive-margin settings (Payton 1977 Posamentier et al 1988)
and are broadly comparable in scale to the second-order cycles of Vail et al (1977) and to the
megasequences of Hubbard et al (1985) The main subsurface data available to reveal the
unweathered nature of these rocks are Trainor-1 and the three-well diamond coring program in
Petroleum Permit EP 380 (Akubra 1 Boondawari 1 Mundadjini 1) completed in late 1997 in the
central west of the sub-basin (Figs 5 and 6)
The ages of all formations in the Savory Sub-basin are poorly constrained The only fossils
known are stromatolites and palynomorphs (acid-insoluble microfossils) Palynology from
available wells is summarized in Appendix 3 from Grey and Stevens (1997) and Grey and Cotter
(1996) and correlations using stromatolite biostratigraphy (Stevens and Grey 1997 Grey 1995f
Walter et al 1994 1995) are consistent with a Neoproterozoic age for the formations for which
data are available
A dolerite within the Boondawari Formation gave a poorly constrained RbndashSr age of about
640 Ma (Williams 1992) SHRIMP UndashPb dating of sedimentary zircons from the McFadden and
Cornelia Formations in stratigraphic drillhole Trainor 1 are discussed in Stevens and Adamides (in
prep) and Nelson (1997) The youngest ages from these analyses indicate that the maximum age
of the Cornelia Formation is Early Cambrian or Sturtian but these ages are inconsistent with
previous tectonic interpretations (Williams 1992) and current stratigraphic correlations which
suggest the Cornelia Formation is of Supersequence 1 age or older (Fig 4)
Depositional Sequence A Supersequence 1
Depositional Sequence A includes the Glass Spring Jilyili and Brassey Range Formations (Fig
3) All of these units are predominantly quartzose sandstones some of which are friable and have
significant visible porosity in outcrop Conglomerates are present in the Glass Spring and Jilyili
Formations
Depositional Sequence B Supersequence 1
Depositional Sequence B consists of the Watch Point Coondra Mundadjini Spearhole and
Skates Hills Formations (Fig 3) All of these formations contain beds of quartzose sandstone and
some also contain conglomerates The porosity of dolomites in the Skates Hills Formation appears
poor in surface exposures but its subsurface characteristics are unknown
12
50 km
120deg 121deg30 123deg
25deg
24deg
23deg
22deg
Greater Officer Basin
PNCEXP CA11PNCEXP CA12
PNCEXP CA13PNCEXP CA19
PNCEXP CA05
PNCEXP CA09
BD134589
GSWA Trainor 1 and TWB123
Fortescue River 1A
Mundadjini 1
Akubra 1Boondawari 1
TWB4TWB5
TWB6
TWB7
TWB8
TWB9
TWB10
BWB1
BWB2 BWB3
BWB4
BWB5
OD23
Mineral exploration drillhole
Stratigraphic drillhole
Waterbores and wells(TWB and BWB serieswaterbores identified)
MKS33270398
LDDH 1
Savory Sub-basin
Canning SR Well 13
EP380
Petroleum Exploration permit
Petroleum exploration well
Figure 5 Locations of petroleum exploration wells mineral exploration and stratigraphic drillholes water bores and wells and petroleum exploration permit EP380 in the Savory Sub-basin
13
TD=600m
TD=1367m
TD=701m
TD=709m
TD=50m
SS
1S
S1
SS1
SS
1S
S1
SS
1
SS
1
SS1
SS4 SS1
Pha
nero
zoic
or
SS
2
Cz
CzCz
Karst Bitumen
SS1
TD=181m
Mundadjini 1 Akubra 1 Boondawari 1 LDDH 1 Trainor 1 TWB 6
Munda-djini Fm
Spear-hole Fm
Munda-djini Fm
Munda-djini Fm
Spear-hole Fm
Spear-hole Fm
Waters Fm
McFadden Fm
Cornelia Fm
Cornelia Fm
Cornelia Fm
511 plusmn 13Maor 696 plusmn 20Ma(maximum)
779 plusmn 10Ma(maximum)
Mundadjini 1
Akubra 1 Boondawari 1
LDDH 1
Trainor 1TWB 6100 km
N
LOCATION
NW SE
Sea level
0m AHD
Dolerite basalt
Conglomerate
Sandstone
Mudstone
Dolomite
Limestone
Evaporite
TOC gt08
Permeability gt100md
Oil fluorescence
Sedimentary zircon U-Pb age
Identifiable polymorphs
Cainozoic
Supersequence 1 age
Unconformity
Formation contact
Cz
SS1
r
r
0
100
200
metres
VerticalScale
MKS36 120598
LEGEND
Figure 6 Geological cross section through significant drillholes in the Savory Sub-basin
14
Depositional Sequence C Supersequence 3
Depositional Sequence C consists of the Boondawari Formation (Fig 3) and although it contains
sandstone conglomerate and dolomite the sandstones contain significant amounts of feldspar and
clay and hence are likely to be poorer reservoirs than older sandstones
Depositional Sequence D Supersequence 4
Depositional Sequence D includes the McFadden Tchukardine and Woora Woora Formations
(Fig 3) The McFadden Formation is poorly sorted and sandstones contain significant amounts of
feldspathic clasts in the north of the basin but are significantly coarser and cleaner in the northeast
of the sub-basin (Williams 1992)
Sandstones of the Tchukardine and Woora Woora Formations are generally cleaner than those
of the McFadden Formation and are expected to have fair to good porosity although the
Tchukardine Formation has a higher clay content in parts
Depositional Sequence E Supersequence 4
Depositional Sequence E consists of the Durba Sandstone (Fig 3) a coarse sandstone with minor
conglomerate which has good to excellent visible porosity in surface exposures
Other depositional sequences and regional correlations
Sedimentary rocks which were not included in the Savory Group by Williams (1992) but which
are likely to be of Neoproterozoic age and hence part of the greater Officer Basin include the
Tarcunyah Group the Cornelia Formation and the Kahrban Subgroup
As discussed in the Introduction all of the strata in the Karara Basin and the younger strata
of the Yeneena Basin were redefined to form the Tarcunyah Group of the greater Officer Basin
(Bagas et al 1995) (Fig 7) In outcrop the Tarcunyah Group consists predominantly of quartzose
feldspathic and arkosic sandstone shale which is carbonaceous in parts and carbonate which
includes stromatolitic dolomite Mineral hole LDDH1 drilled on GUNANYA intersected the
15
120598
122deg
123deg
21deg
22deg
23deg
24deg
23deg
22deg
21deg
122deg
123deg
Fault
Thrust
Reverse thrust
CANNINGBASIN
OFFICERBASIN
GROUP
PILBARACRATON
TARCUNYAH
SAVORY GROUP
BANGEMALL
GROUP
THROSSELL
GROUP
LAMIL
GROUP
ConnaughtonTerrane
TerraneTalbot
complexTabletop granitic
Tabletop Terrane
Permian
Neoproterozoicgranitoid
50 km
FormationWaltha Woora
McKay Fault
South west Thrust
Vines
Fault
24deg
120deg
YENEENA CANNINGBASIN
ARUNTAINLIERRUDALL
COMPLEX
AMADEUSBASIN
MUSGRAVEBLOCK
OFFICERBASINYILGARN
CRATON
GROUP
GROUP
GROUP
PILBARACRATON
GROUP
EARAHEEDY
GLENGARRY
BANGEMALL
WYLOO GROUP
SAVORY
WA
CARNARVONBASIN
GASCOYNECOMPLEX
GROUPTARCUNYAH
400 kmGROUP
SA
N
T
CamelndashTabletopfault zone
KAHRBANSUBGROUP
CORNELIAFORMATION
MKS37
Figure 7 Regional geological setting of the Savory Group and western Officer Basin The dashed line on the inset map marks the interpreted margin of the greater Officer Basin
16
Tarcunyah Group and consists predominantly of mudstone with minor sandstone limestone
dolomite and anhydrite (Fig 6)
The age of the Tarcunyah Group is uncertain although limited palynological and stromatolite
evidence suggests that it is probably coeval with Supersequence 1 of the Centralian Superbasin
Drillhole LDDH1 contains palynomorphs equivalent to assemblages in the Browne and Bitter
Springs Formations of the Officer and Amadeus Basins respectively and from the Cornelia
Formation in TWB 6 (Grey and Stevens 1997) (Figs 4 and 6) Stromatolite specimens tentatively
assigned to Acaciella australica (Howchin 1914) Walter 1972 occur in the lower Tarcunyah
Group (Bagas et al 1995) The stromatolite Baicalia burra Preiss 1972 and a conical
stromatolite were reported from the upper part of the Tarcunyah Group (Stevens and Grey 1997)
The recognition of two stromatolite assemblages interpreted to have age significance in
Supersequence 1 sedimentary rocks of the Centralian Superbasin has permitted biostratigraphic
correlations between outcrop and well data The Acaciella australica assemblage appears to be
slightly older than 800 Ma and is restricted to the middle part of Supersequence 1 The Baicalia
burra assemblage is considered to be slightly younger than 800 Ma and occurs in the upper part
of Supersequence 1 (Grey 1996b Stevens and Grey 1997) The older A australica assemblage
is recognized in the Skates Hills Formation in the Savory Sub-basin and the stromatolite A
australica itself has been tentatively identified in the lower Tarcunyah Group The occurrence of
the A australica assemblage in the Woolnough Madley and Browne Formations of the Officer
Basin and in the Loves Creek Member of the Bitter Springs Formation of the Amadeus Basin
allows correlations throughout the Centralian Superbasin (Fig 4)
The younger B burra assemblage has not been recognized in sedimentary rocks of the
Savory Group as defined by Williams (1992) but it occurs in the upper parts of the Tarcunyah
Group and allows correlation of this group with outcrops of the Neale Formation and with the
Kanpa Formation in petroleum exploration well Hussar 1 both located in the central Officer Basin
of Western Australia (Fig 4) (Grey 1996b Stevens and Grey 1997) The occurrence of the B
burra assemblage in these units permits their correlation with the Burra Group in the Adelaide
Geosyncline of South Australia (K Grey unpublished data)
The Cornelia Formation and Kahrban Subgroup outcrop in the southeast of the sub-basin and
were considered by Williams (1992) to be part of the Mesoproterozoic Bangemall Basin Limited
evidence suggests that all or parts of these two units are of Neoproterozoic age The Ward and
Oldham Inliers consist of outcrops of the Cornelia Formation Waterbore TWB 6 which was
drilled on TRAINOR in the Cornelia Formation contains palynomorphs consistent with a
Supersequence 1 age (Grey and Stevens 1997) (Figs 5 and 6) In outcrop the Cornelia Formation
17
consists predominantly of sandstone and quartzite with lesser siltstone shale mudstone and chert
In Trainor 1 this formation consists predominantly of indurated mudstone with minor sandstone
chert and dolomite A major erosional unconformity separates the Cornelia Formation from
overlying formations and parts of the Cornelia Formation have been folded with dips exceeding
70deg In contrast the majority of the Savory Sub-basin sedimentary rocks have dips of less than 30deg
except where they are adjacent to faults The Cornelia Formation apparently consists of an older
unit of steeply dipping quartzites cherts and well-indurated mudstones and a younger unit of
shallower dipping sandstones which are sub-friable in parts However caution should be used in
interpreting the age of units based on their structural deformation and additional mapping and age
dating of this formation is required
It is proposed here that the Kahrban Subgroup is likely to be of early Neoproterozoic age and
hence should be considered as part of the greater Officer Basin This proposal is based largely on
the relatively low dip of the strata (generally less than 20deg) and their west-northwest strike which
is parallel with strikes in the overlying Brassey Range Formation of the Savory Group The lower
contact of the Kahrban Subgroup is obscured but is thought to be an unconfirmity on the
Earaheedy Basin on the southeast of STANLEY (Muhling and Brakel 1985)
Structural setting
The Savory Sub-basin forms the most northwesterly sub-basin of the Neoproterozoic to
Phanerozoic Officer Basin The western boundary of the sub-basin with the Mesoproterozoic
Bangemall Basin consists of steep-reverse and strike-slip faults The northeastern boundary of the
Savory Sub-basin was mapped where Supersequence 4 formations of the Savory Group
unconformably overlie sedimentary rocks of the Karara and Yeneena Basins with the two older
units considered to be part of the Paterson Orogen (Williams 1992) This contact was defined as a
series of steeply dipping reverse faults in the northernmost parts of the sub-basin on BALFOUR
DOWNS and RUDALL and was extrapolated as an inferred reverse fault farther along strike to the
southeast on GUNANYA and MADLEY where the contact is obscured by Cainozoic sediments It is
now recognized that all the sedimentary rocks in the Karara Basin and younger sedimentary rocks
of the Yeneena Basin are from the Supersequence 1 Tarcunyah Group and part of the greater
Officer Basin (Bagas et al 1995) The northern boundary of the Tarcunyah Group and the greater
Officer Basin is in thrust-and reverse-faulted contact with the Rudall Complex and other parts of
the Paterson Orogen (Fig 7)
To the south the sub-basin unconformably overlies the Bangemall Basin The eastern
boundary of the sub-basin used in this study is where Permian and younger strata of the Officer
Basin unconformably overlie Neoproterozoic strata although there are no significant structural or
stratigraphic differences between the Neoproterozoic units
18
The sub-basin is subdivided into three principal structural areas (Fig 1) Trainor Platform
Blake Fault and Fold Belt and Wells Foreland Sub-basin (Williams 1992) A major review of
these boundaries is beyond the scope of this report but the processing of regional aeromagnetic
data (Appendix 4) and acquisition of a semi-detailed gravity survey by the GSWA in the east of
the sub-basin has enabled these tectonic units to be reassessed and some modifications are
proposed
The Wells Foreland Sub-basin (originally termed the Wells Foreland Basin in Williams 1992)
and sedimentary rocks of the Tarcunyah Group are both considered to be the northwest
continuation of the Gibson Sub-basin of the Officer Basin Aeromagnetic gravity and outcrop
data suggest that the Blake Fault and Fold Belt is significantly faulted and folded in the west but
is less deformed in the east where the thickest sedimentary section in is located on BULLEN
(Appendix 4) The Trainor Platform is reinterpreted to represent an area of the sub-basin that has
undergone major compression during the Petermann Ranges Orogeny resulting in folding and
faulting with a northwest strike This interpretation contrasts with that proposed by Williams
(1992) who envisaged that only a thin section of the Savory Group was present on the platform
Perincek (1998) has recognized nine periods of tectonic activity in the Officer Basin from the
beginning of the Neoproterozoic to the end of the Cretaceous Three major tectonic episodes are
recognized in the Centralian Superbasin The oldest event is the Areyonga Movement which is
pre-Sturtian and forms the boundary between Supersequences 1 and 2 (Fig 4) The Souths Range
Movement occurred at the end of the Sturtian at the boundary between Supersequences 2 and 3
The youngest major event is the Petermann Ranges Orogeny which occured at the end of the
Marinoan and forms the boundary between Supersequences 3 and 4
One minor and two major tectonic episodes are recognized in the Savory Sub-basin the
LP1ALP1B structural event and the Areyonga Movement and the Petermann Ranges Orogeny
respectively The LP1ALP1B structural event is revealed where the Spearhole Formations rests
disconformably and locally unconformably on the Brassey Range Jilyili and Glass Spring
Formations The Neoproterozoic Areyonga Movement (equivalent to the Blake Movement of
Williams 1992) produced folds and faults with a general northeast strike in the western and
southern parts of the region The Souths Range Movement has not been recognized in the sub-
basin This may be due to the fact that no Sturtian glacial rocks have been identified and hence it
is possible that structures attributed to the Areyonga Movement could be the result of the Souths
Range Movement or a combination of the two movements
The major tectonic event recorded in the sub-basin is the latest Neoproterozoic to Cambrian
Petermann Ranges Orogeny (equivalent to the Paterson Orogeny) which produced large reverse
19
faults thrusts strike-slip faults and folds with a general northwest strike The McFadden
Formation and other Supersequence 4 strata are considered to be at least partially coeval with this
orogeny (Williams 1992) We also interpret the Durba Sandstone as having been deposited during
the later stages of the Petermann Ranges Orogeny as this unit mildly deformed with fold axes
parallel to the strike of other structures attributed to the Petermann Ranges Orogeny
Quantitative aeromagnetic interpretation of the Savory Sub-basin utilizing the 3D Euler
deconvolution method supported by wave-number filtering and image processing has provided
structural trends and depth to magnetic source within the sub-basin (Cowan 1995) Gravity data
are interpreted by Cowan (1995) as changes in both the density of the basement rocks andor
basement topography depending on local conditions Part of Cowanrsquos report is reproduced in
Appendix 4
Exploration history
The only petroleum exploration conducted in the sub-basin has been the recent drilling in the
western part of three diamond drillholes of which two have minor oil shows (Table 2) There has
been some mineral exploration the results of which are stored in the GSWA Western Australian
Mineral Exploration (WAMEX) database system Much of the mineral exploration was in the
southwest and west where the sub-basin is in contact with the Bangemall Basin and along the
northern margin of the sub-basin Many of these mineral exploration programs included
aeromagnetic surveys and surface geochemical sampling (Fig 8)
Hydrocarbon potential
The sub-basin contains a sedimentary succession up to 8 km thick which is generally gently
folded and faulted and apparently unmetamorphosed Limited drilling has shown that thick
mudstones are present in the sub-basin with some mudstones in Trainor 1 having high Total
Organic Carbon (TOC) values Outcrops of sub-friable sandstones in many of the formations
within the sub-basin suggests widespread reservoir potential Mudstone and inferred thick
evaporite sequences are likely to form seals Maturity data suggest that near-surface samples are
approximately at the base of the oil window and top of the gas window in parts of the north and
southeast of the sub-basin However parts of the southwest of the sub-basin and the mudstones in
Trainor 1 have very high levels of maturity Numerous faults and folds have been identified from
surface mapping suggesting good potential for large structural traps Minor oil shows in
20
Table 2 Neoproterozoic formations and hydrocarbon shows in diamond drillholes in the Savory Sub-basin
Drillhole AMG Core TD (m) Approx Formation Depth Formation Depth Formation Depth Shows (AGD84) start (m) GL (m) (m) (m) (m)
LDDH 1 431148E 112 701 350 Tarcunyah 68ndash701 ndash ndash bitumen at 6623 m 7443826N Group Trainor 1 473640E 6 709 455 McFadden 9ndash83 Cornelia Fm 83ndash709 possible bitumen at 4537 m 7287400N Fm Mundadjini 1 319056E 170 600 500 Mundadjini 16ndash361 Spearhole Fm 361ndash600 10 fluorescence at 36102 m 7404844N Fm Boondawari 1 348959E 299 1 367 490 Mundadjini Fm 15ndash312 Spearhole Fm 312ndash1 283 Intrusive 1 283ndash1 367 40 fluorescence at 35364 m 5 7398174N fluorescence at 4963 m Akubra 1 334249E 15 181 530 Mundadjini 15ndash42 Intrusive 42ndash181 None 7401252N Fm
21
50 km
120deg 121deg30 123deg
25deg
24deg
23deg
22deg
Greater Officer Basin
Savory Sub-basin
1
2
3
4
6
8
3 Seismic line (prefixed N83-00)
Aeromagnetic survey
GS
WA
Sav
ory
1995
gra
vity
sur
vey
Gravity survey
MKS34270398
Figure 8 Locations of aeromagnetic and gravity surveys (other than regional BMRAGSO data)
22
sandstones in two petroleum wells in the northwest of the sub-basin and bitumen and oil shows
elsewhere in the region indicate that oil has been generated and migrated through the sub-basin
Source rocks
Source potential is considered to be the major exploration risk in the Savory Sub-basin although
minor oil shows in Mundadjini 1 and Boondawari 1 indicate that at least some oil has been
generated and migrated into potential reservoirs within the sub-basin Sandstone is the
predominant lithology observed in outcrop Outcrops of fine-grained lithologies in the basin are
rare because of intense surface weathering and erosion Only about 8 of the surface area of the
sub-basin is exposed bedrock and recessive lithologies (such as shale evaporite and friable
sandstone) may be present although they rarely outcrop
Outcrops of stromatolitic dolomite with associated cauliflower chert and cubic pseudomorphs
interpreted as being after halite indicate that evaporitic environments are present within the
Mundadjini Skates Hills and Boondawari Formations Evaporitic minerals are also present in
drillhole LDDH1 in the Tarcunyah Group
In 1995 GSWA drilled a continuous-core diamond drillhole (Trainor 1) in the sub-basin on
TRAINOR to a depth of 709 m to test for source rocks thus providing the first such data for the sub-
basin The drillhole intersected flat-lying clastics and carbonates of the McFadden Formation (9ndash
83 m) overlying indurated mudstones of the Cornelia Formation (83ndash709 m total depth) dipping at
about 40deg Of the six samples analysed from the Cornelia Formation in this drillhole the five
located between 375 and 6032 m depth have TOC values exceeding 05 (range 066ndash365)
Rock-Eval pyrolysis of these five samples indicates that they are at best in the dry-gas thermal
stage and as a result of their high level of maturation (Stevens and Adamides in prep) have poor
remaining hydrocarbon-generating potential Although the Cornelia Formation is overmature at
Trainor 1 the high TOC values are encouraging as it is likely that this sequence is less mature
elsewhere in the sub-basin
The Mundadjini Formation contains potential source rocks that comprise marine mudstones
with evaporitic minerals present in parts Thin dark mudstones were intersected in the Mundadjini
Formation in Akubra 1 In Mundadjini 1 and Boondawari 1 however the mudstones appear to be
too oxidized to have source potential
The Boondawari Formation also may be a source rock as it contains black mudstones The
unit is laterally equivalent to the Pertatataka Formation of the Amadeus Basin and the Ungoolya
23
Group of the Officer Basin in South Australia both of which have some source potential
(Summons and Powell 1991 Morton and Drexel 1997) Samples from the Dey Dey Mudstone of
the Ungoolya Group generally have poor TOC values (average 011 range 003ndash081)
moderate hydrogen index (HI) values (100ndash382) and poor to fair genetic potential with a
maximum of 292 kg hydrocarbon per tonne of source rock (Morton and Drexel 1997)
Stromatolitic dolomites and mudstones at the top of the Boondawari Formation and within the
Skates Hills Formation are potential source rocks Stromatolitic dolomite and evaporitic rocks
deposited in a marginal marine to sabkha environment are considered to have good potential to
generate and preserve organic carbon without requiring a deep-water setting (Stevens and Grey
1997) Such conditions are recognized in the Skates Hills Formation and in the upper parts of the
Tarcunyah Group
Maturity
Knowledge of the maturity of sedimentary rocks within the Savory Sub-basin is still limited From
a review of palynological studies Grey and Stevens (1997) report that the thermal maturity
inferred from the Thermal Alteration Index (TAI) of 3+ from Supersequence 1 age palynomorphs
in TWB 6 TWB 9 and LDDH1 is within the hydrocarbon window (Appendix 3) In Phanerozoic
spores and pollen a TAI of 3+ approximately equates to the end of liquid petroleum generation
and the start of dry gas generation and to a vitrinite reflectance of about 13 (Traverse 1988)
However the use of TAI for estimating thermal maturity from Neoproterozoic palynomorphs
requires calibration
In Trainor 1 the Cornelia Formation contains organically rich claystones between 375 and
6032 m depth Based on Rock-Eval maturity data (Stevens and Adamides in prep) and the dark
colour of poorly preserved organic material (Grey 1995de 1996) with TAI 4- to 5 all samples
had a high level of maturation with at best dry-gas generating potential remaining In contrast
drillhole LDDH1 on GUNANYA recorded lower levels of maturity (TAI values of 3+) with two of
sixteen samples from the Tarcunyah Group having greater than 1 TOC (Grey 1995abc Grey
and Cotter 1996) Organic petrology and Rock-Eval maturity data for samples from LDDH1
indicate that the section above 500 m is within the oil-generative window whereas below 500 m
the rocks are within the gas window (Ghori in prep Fig 9 Appendix 5)
Waterbores TWB 1 2 6 and 9 which are located on TRAINOR in the southeast of the sub-
basin all had organic matter with TAI values of 3+ from the McFadden Skates Hills Cornelia
and Brassey Range Formations respectively
24
100
200
300
400
500
600
700
Oil
gene
ratin
g
Gas
gene
ratin
g
Fai
r
Fai
r
Poo
r
Poo
r
Goo
d
Imm
atur
e
Oil
win
dow
Oil
win
dow
Imm
atur
e
01 0110 10 0 150 300 440 480 1
Neo
prot
eroz
oic
TOC S1+S2 mgg Hydrogen Index Tmax degC
Depth(m)
Organicrichness
Generatingpotential
Kerogentype Maturity Maturity
TD=701m
Sandstone
Mudstone
Dolomite
Limestone
Evaporite
Source rock
MKS40 070498
Ro equivalent
Figure 9 Petroleum source potential of rocks in Normandy LDDH1
Small amounts of organic matter associated with basalt and dolerite in cuttings from
waterbore BWB 1 on BULLEN showed high levels of thermal maturity (Grey 1995a Libby 1995)
It is unclear whether all sedimentary rocks on BULLEN are overmature for hydrocarbon generation
or the results from BWB 1 are related to local heating events associated with the volcanic bodies
that are common in the Jilyili Formation
25
Reservoirs
Each of the five depositional sequences of the Savory Group (Table 1) are inferred to contain
significant sandstone reservoirs with the possible exception of depositional sequence C as
discussed above in Stratigraphy The Spearhole Formation was cored in Mundadjini 1 and
Boondawari 1 and visual estimates of porosity vary from generally poor (less than 5) to fair
(approximately 5ndash15) The McFadden Formation in Trainor 1 has porosity values of up to 232
and a maximum permeability of 195 md (Stevens and Adamides in prep) Sandstones from
Neoproterozoic formations form the acquifers in the following waterbores the McFadden
Formation in TWB 1 the Cornelia Formation in TWB 6 and the Brassey Range Formation in
TWB 8 and TWB 9 (Appendix 6 Table 61)
Based on outcrop observations the Durba Sandstone is considered to be the best reservoir of
the Savory Group Similarly some sandstones from the Tarcunyah Group also have good visible
porosity in outcrop
Dolomites occur in several formations in the sub-basin Reservoir potential may exist
particularly where the dolomites are stromatolitic and oolitic However dolomites have not been
drilled in the sub-basin and porosity can only be inferred from the preferential silicification of
some stromatolite bioherms observed in outcrop (Stevens and Grey 1997) Elsewhere in the
Officer Basin porosities of up to10 have been measured in dolomites A limestone breccia
(karst) is described from 663 to 677 m in drillhole LDDH1 (Fig 6 Busbridge 1994)
Seals
Indications of evaporitic environments in the Mundadjini Skates Hills and Boondawari
Formations are described by Williams (1992) In Mundadjini 1 from 287 to 337 m anhydrite and
chert occurs as nodules beds and veins in mudstone of the Mundadjini Formation Evaporitic
minerals (predominantly gypsum) are described in the Tarcunyah Group in LDDH1 The presence
of the Woolnough and Madley salt diapirs in the Officer Basin (approximately 110 km east of the
sub-basin) and halite beds over 25 m thick in the well Hussar 1 (130 km east of the sub-basin)
provide further evidence that evaporite seals may be present in the Savory Sub-basin
Mudstones and shales form only a small proportion of the limited Neoproterozoic outcrop in
the sub-basin but significant thicknesses of mudstone were encountered in the Mundadjini
Formation in Mundadjini 1 and Boondawari 1 the Tarcunyah Group in LDDH1 and in the
26
Cornelia Formation in Trainor 1 These data suggest that mudstones form a significant proportion
of strata in the sub-basin despite their limited outcrop
Traps
Potential structural closures including folds and faults occur at various scales throughout the
Savory Sub-basin However the region has only been mapped at 1250 000 scale and
independently closed structures such as domes have yet to be confirmed The western margin of
the basin contains abundant faults (with a northeast strike) but elsewhere faults are less common
Some anticlines are recognized in outcrop including one with a strike length of up to 45 km
inferred from surface bedding dips in the Mundadjini and Spearhole Formations at approximately
24deg15rsquoS 121deg10rsquoE on BULLEN (Fig 1)
Salt diapirs and other halokinetic structures are recognized in outcrop well and seismic data
in the Officer Basin to the west of the Savory Sub-basin and it is probable that there are
significant thicknesses of evaporitic sedimentary rocks in the sub-basin The gravity field data
suggest there is good potential for salt diapirs and traps related to halokinesis
Although there is potential for stratigraphic traps to be present in the sub-basin insufficient
data are available to assess them
Preservation of hydrocarbons
The range of thermal maturities measured to date and the large periods of time envisaged for
deposition of sediments implies hydrocarbon generation may have occurred a number of times
during the evolution of the Savory Sub-basin Any hydrocarbons that were generated early may
have been trapped in palaeostructures and remigration to younger traps could have taken place
later The Petermann Ranges Orogeny which has been equated with the Paterson Orogeny (Myers
1990) is believed to have occurred in the latest Neoproterozoic to early Cambrian This is the last
major tectonic event recognized in the sub-basin suggesting that it is reasonable to expect that trap
integrity will have been preserved
If the inference of the presence of thick halite beds in the sub-basin is correct the preservation
potential of sub-salt traps should be excellent
27
Reported hydrocarbon shows and oil seep
Amadeus Petroleum recorded minor oil shows in cores from Mundadjini 1 and Boondawari 1 In
Mundadjini 1 at 36102 m (top of the Spearhole Formation) a 3 mm thick zone had 10 moderate
white fluorescence with slow solvent cut This show was in a granular sandstone with visually
estimated porosity of about 10 In Boondawari 1 at 35364 m (within the Spearhole Formation) a
broken surface of sandstone had 40 moderate yellow-white fluorescence with slow solvent cut
Visually estimated porosity is about 5 Because the fluorescing surface was broken during the
drilling process this show could have resulted from contamination A second show occurs in
Boondawari 1 at 4963 m (within the Spearhole Formation) where a 1 cm-thick zone had 5 dull
yellow fluorescence with slow solvent cut in a conglomerate with visually estimated porosity of
about 10 The company intends to further investigate the nature of these occurrences
Minor bitumen is present at 6623 m in drillhole LDDH1 on GUNANYA (Figs 5 and 6) as a
vein in mudstones of the Tarcunyah Group A sample was analysed by gas chromatography
(Ghori in prep) and confirmed that it is natural bitumen (Appendix 5)
Mineral hole OD 23 drilled by Jubilee Gold Mines NL on NABBERU in the Bangemall Basin
immediately to the south of the Savory Sub-basin (Fig 5) encountered bitumen and trace oil in
vugs in dolomite (M Stevens unpublished data) but no further data are available at present
In their popular guide to the Canning Stock Route Gard and Gard (1990 p 218) refer to an
oil seep at Well 13 on TRAINOR (Fig 5) They reported that between 1977 and 1984 lsquonatural oilrsquo
was seen in the well Although the well is now largely filled with sediment four auger drill
samples were collected by the GSWA in 1995 and all four were analysed for oil shows One
sample from 315 m total depth (GSWA sample 135604) yielded just enough extract (519 ppm)
for saturate gas chromatography analysis The gas chromatograph (Appendix 5) shows that the
extract does contain some hydrocarbons probably from recent plant material Because the depth to
the oil was not quoted in Gard and Gard (1990) the hand-augered well may not have been deep
enough to properly test this reported seep
Geological and geophysical databases
Geological and geophysical data available for the Savory Sub-basin are limited The most recently
completed geological maps for the sub-basin were published by the GSWA between 1991 and
1995 (Williams and Tyler 1991 Williams 1992 1995ab)
28
The cores from the five drillholes listed in Table 2 believed to be all of the core available
from the sub-basin are available for inspection at GSWA Mineral exploration reports submitted
to GSWA may be searched using the WAMEX database and open-file reports are available on
microfiche Geophysical data acquired by the mining industry is not required to be filed with
GSWA if acquired over Vacant Crown Land which is the case for much of the sub-basin
Geophysical survey data submitted in mining tenement reports and which extend into Vacant
Crown Land remain confidential to the companies Original regional aeromagnetic and gravity
datasets are available from the Australian Geological Survey Organisation (AGSO)
Data pertinent to oil exploration in the sub-basin such as structural style and salt diapirism
are presented in a review of the hydrocarbon prospectivity of the Officer Basin (Perincek 1998)
Drilling
Significant drillholes in the sub-basin are summarized in Table 2
Petroleum industry data
Amadeus Petroleum drilled three petroleum exploration wells in the central west of the Savory
Sub-basin in late 1997 These wells Mundadjini 1 Boondawari 1 and Akubra 1 were drilled by
continuous diamond coring (Figs 5 and 6) All targeted potential reservoirs within the Spearhole
Formation with the Mundadjini Formation as the proposed seal The wells were located on
structures interpreted from Landsat images and limited geological investigations Both Mundadjini
1 and Boondawari 1 had minor oil shows as discussed above (Reported hydrocarbon shows)
Government data
Stratigraphic drillhole Trainor 1 was drilled by GSWA in 1995 (Stevens and Adamides in prep)
and the main results are discussed above (Source rocks and Maturity)
Mineral industry data
Normandy Exploration drillhole LDDH1 was cored in the Tarcunyah Group to a total depth of
701 m and provided source-rock and maturity data as discussed above
29
Oilmin NL drilled six percussion drillholes (BD 1 3 4 5 8 and 9) through sandstones and
shales in the northern part of the Savory Sub-basin to a maximum depth of 198 m (Fig 5
WAMEX Microfiche File M 26811 I 2610) but only brief geological descriptions are available
Hydrogeological data
Hydrogeological data within the Savory Sub-basin are limited although a long history of water
exploration extends back to the construction of the Canning Stock Route early this century No
detailed geological or wireline logs are available for the older wells along this route A few station
wells have been drilled by various methods on the south and west margins of the basin but data
are unavailable as reports are not required to be filed with the government Depth to watertable
throughout the basin is largely controlled by porosity of the bedrock
The GSWA drilled fifteen waterbores in the winter of 1995 in the southern part of the sub-
basin in preparation for the drilling of Trainor 1 and the proposed Bullen 1 Twelve bores found
water and six of these bores have salinities of less than 1000 mgL (Fig 5 Appendix 6 Table 61)
One waterbore TWB 6 has gamma ray and neutron logs run through PVC casing and these are
available from the GSWA with the digital log data included herein
Seismic data
No geophysical data have been acquired by the petroleum industry in the Savory Sub-basin
Seismic data acquired in the Officer Basin to the east particularly in the Gibson and Yowalga
Sub-basins is pertinent to structural interpretation in the Savory Sub-basin (Perincek 1996a
1998)
Aeromagnetic surveys
Government data
There are over 95 277 line kilometres of aeromagnetic data included in the AGSO dataset There
are three regional aeromagnetic surveys covering the Savory Sub-basin These were flown by the
Bureau of Mineral Resources (BMR now AGSO) in 1984 at a line spacing of 1500 m with 36 740
and 52 587 line kilometres flown and by Aerodata in 1984 at a line spacing of 1000m with 5950
line kilometres flown These data were reprocessed and interpreted for GSWA by Cowan (1995)
An edited copy of this report is included as Appendix 4 and the original report is filed in the
GSWA Library under S-series reports item 10331
30
Mineral industry data
The approximate locations of non-AGSO aeromagnetic surveys are shown in Figure 8 More
detailed information regarding the location of these surveys may be obtained using the GSWA
MAGCAT II database Additional information such as contours of aeromagnetic values may be
obtained by inspecting items on file with the GSWA
Gravity surveys
Government data
The average spacing for gravity data in the Savory Sub-basin is one station per 121 km2 (11 times 11
km grid) These data were principally collected by BMR in the early 1960s There are a few
additional regional gravity traverses across the sub-basin which are also included in the
BMRAGSO dataset These data were reprocessed and interpreted for GSWA (Fig 10) and a
report on this work is also included in Appendix 4
The GSWA completed a large semi-detailed gravity survey in the eastern Savory Sub-basin
utilizing helicopter support and Differential Global Positioning Survey (DGPS) techniques (Fig
8) This gravity survey completed in August 1995 consists of 2300 gravity stations on a 2 times 3 km
grid All stations were acquired by helicopter using Scintrex gravimeters and Ashtek dual
frequency DGPS equipment for determining location This highly efficient system allowed the
acquisition of more than 100 gravity stations per day in remote areas The resolution of this survey
is +30 cm and +05 microms-2 (Daishsat 1995) These data (Fig 11) represent a significant
improvement on the previous regional survey data and are available from GSWA (GSWA
1996ab) The results of the interpretation of these data were presented at the 1997 ASEG
Convention (Carlsen and Shevchenko 1997)
Mineral industry data
Three small gravity surveys were conducted by Oilmin NL (Fig 8) and the relevant WAMEX
reports are M 2681I 2610 I 2435 I 2567 These three surveys are of limited value because height
control was provided by barometers only and the surveys were not tied to the national gravity grid
31
23deg
25deg
120deg 122deg
Trainor 1
SAVORY
SUB-BASIN
MKS54 160498
100 km
1995 SavoryGravity Survey
254
-1056
micromsec2
Figure 10 Regional Bouguer gravity map of the Savory Sub-basin
23deg
24deg
25deg
122deg30 123deg
TRAINOR 1
123deg30
50 km
MKS53 160498
-116
-626
micro msec2
Figure11 Detailed Bouguer gravity map of the
Savory 1995 Gravity Survey from the eastern Savory Sub-basin
32
Government and academic reports
Chronostratigraphy and geochemistry
The understanding of Neoproterozoic organic chemistry palynology and structural evolution is
essential to the interpretation of hydrocarbon prospectivity Pertinent reports are included in the
bibliography (Appendix 1) Unpublished palaeontology reports describe the palynology of wells in
the Savory Sub-basin (Grey 1995andashe 1996a) Grey and Cotter (1996) discussed the potential for
Neoproterozoic palynomorphs to provide a biostratigraphic framework and palaeoenvironmental
interpretation Grey and Stevens (1997) reviewed the results of palynological studies of wells
drilled in the sub-basin and reported that Supersequence 1 palynomorphs are present in TWB 6
TWB 9 and LDDH1 (Appendix 3) Grey (1996b) reported on the use of stromatolites for
correlation in the Neoproterozoic and Stevens and Grey (1997) discussed the application of
stromatolite biostratigraphy in correlating isolated dolomite outcrops in the sub-basin with well
and seismic data in the Officer Basin and Centralian Superbasin
Although geochemical data from the Savory Sub-basin are very limited results mostly
confirm thermal maturities inferred from TAI for LDDH1 and Trainor 1 (Ghori in prep Stevens
and Adamides in prep) Those parts of the Officer Basin in Western Australia which lie to the
east of the Savory Sub-basin are sparsely drilled but Ghori (in prep) reports that most of the
Neoproterozoic succession presently lies within the oil-generative window However his study
has been unable to identify effective source-rock units and the source for oil shows Thin source
rocks are present in the Neoproterozoic in LDDH1 (Fig 9) and in three wells which lie to the east
and southeast of the Savory Sub-basin namely NJD 1 Kanpa 1A and Yowalga 3
Proposed work program
From the above limited information it is concluded that additional research on the hydrocarbon
potential of the sub-basin is justified and proposals are outlined below
bull Additional modelling of gravity and aeromagnetic data from the Savory Sub-basin is required
in light of the results from Trainor 1 and Boondawari 1 Trainor 1 showed that what appeared
to be a structurally simple area based on outcrop aeromagnetic and gravity data was in fact an
area of major structuring Boondawari 1 intersected a dolerite which is in good depth
agreement with aeromagnetic depth to source results showing this technique is useful in
detecting the depth to intrusive bodies
33
bull Additional data from mineral and petroleum exploration bores may become available and
analysis of samples from these wells should be undertaken and interpreted in the context of
their relevance to the Officer Basin
bull Stratigraphic coring in the Blake Fault and Fold Belt and in the Wells Foreland Sub-basin (Fig
1) targeting source rocks is considered essential to the continuing evaluation of the
hydrocarbon prospectivity of the Savory Sub-basin
bull Correlations using at least outcrop well and potential-field data should be prepared to link the
sub-basin with the better known parts of the Officer Basin to the east
bull Remapping is required to clarify boundary positions within the Cornelia Formation this may
resolve some of the current problems of the relationship between this unit and the rest of the
Savory Sub-basin
bull Further work is required to explain the Early Cambrian or Sturtian ages interpreted for the
Cornelia Formation from sedimentary zircon UndashPb dating in drillhole Trainor 1 The
determination of the age of the organically rich but overmature claystones in this well is
critical to assessing the hydrocarbon potential of the region
bull The thin dark mudstones intersected by Akubra 1 in the Mundadjini Formation warrant
geochemical analysis Analyses of the oil shows in Mundadjini 1 and Boondawari 1 are
currently being undertaken by Amadeus Petroleum
bull Geochemical analysis of hydrocarbons in the Bangemall Basin drillhole OD23 has been
performed by Jubilee Gold and the results will be reviewed when they are submitted to
GSWA The possibility of source rocks within the Bangemall Basin charging traps within the
Bangemall Basin and the overlying Savory Sub-basin requires further investigation
Conclusions
The Savory Sub-basin is a frontier region with only three recently drilled petroleum exploration
wells and no seismic data Based on existing geological and geophysical data it is considered too
early to draw conclusions about the hydrocarbon prospectivity of the sub-basin at this stage and
there are several reasons why the area warrants further investigation
34
1 Thick accumulations of sedimentary rocks are present (up to 8 km thickness inferred) which
may contain source reservoir and sealing strata
2 Minor oil shows occur in Mundadjini 1 and Boondawari 1 and bitumen is present in mineral
exploration drillhole LDDH1 suggesting that hydrocarbons have migrated within the
Neoproterozoic sequence of the Savory Sub-basin Oil and bitumen are present in mineral
exploration drillhole OD23 in the Bangemall Basin immediately to the south of the Savory
Sub-basin and it is possible that source rocks from the Bangemall Basin could charge traps in
the overlying Savory Sub-basin
3 The age of sedimentary rocks in the sub-basin is still poorly constrained but some of the
Neoproterozoic sedimentary rocks located on GUNANYA and TRAINOR are within the
hydrocarbon-generation window It is possible that a significant thickness of Phanerozoic
sedimentary rocks may also be present
4 Friable sandstones with visible porosity outcrop extensively suggesting numerous potential
reservoirs
5 Significant but not intense faulting and folding has been mapped implying large structural
traps may be present
6 Evaporitic sedimentary rocks occur in several formations and may provide good source rocks
and excellent seals
35
References
APAK S N and CARLSEN G M 1997 A compilation and review of data pertaining to the
hydrocarbon prospectivity of the Canning Basin Western Australia Geological Survey
Record 199610 103p
BAGAS L GREY K and WILLIAMS I R 1995 Reappraisal of the Paterson Orogen and
Savory Basin Western Australia Geological Survey Annual Review 1994ndash95 p 55ndash63
BUSBRIDGE M 1994 Lake Disappointment Exploration Licence 451064 Third Annual
Report Lake Disappointment Diamond Drill Hole LDDH1 Normandy Exploration Limited
Western Australia Geological Survey M-series Item 7567 A41358 (unpublished)
CARLSEN G M and SHEVCHENKO S I 1997 Petroleum exploration in Proterozoic basins
using potential fields data and stratigraphic coring Australian Society of Exploration
Geophysicists 12th Geophysical Conference Handbook Sydney 1997 Preview no 66 p 83
(abstract only)
COWAN D 1995 Savory Basin quantitative magnetic interpretation Western Australia
Geological Survey S-series S10331 (unpublished)
DAISHSAT PTY LTD 1995 Operational and processing report Savory Basin gravity survey
Western Australia Geological Survey S-series S10332 (unpublished)
GARD E and GARD R 1990 Canning Stock Route a travellerrsquos guide for a journey through
history Perth Western Australia Western Desert Guides 448p
GEOLOGICAL SURVEY OF WESTERN AUSTRALIA 1996a Savory Basin first vertical
derivative of Bouguer gravity image 1250 000 Western Australia Geological Survey
GEOLOGICAL SURVEY OF WESTERN AUSTRALIA 1996b Savory Basin Bouguer gravity
image 1250 000 Western Australia Geological Survey
GHORI K A R in prep Petroleum source rock potential and thermal history Officer Basin
Western Australia Western Australia Geological Survey Record
36
GREY K 1995a Savory Basin drillhole BWB 1 (Bullen waterbore) palynology and thermal
maturation GSWA Palaeontology Report no 199512 (unpublished)
GREY K 1995b Savory Basin drillholes TWB 1 2 6 9 (Trainor waterbores) palynology and
thermal maturation GSWA Palaeontology Report no 199520 (unpublished)
GREY K 1995c Palynology of Normandy-Poseidon Lake Disappointment-1 corehole
Tarcunyah Group Paterson Orogen GSWA Palaeontology Report no 199521 (unpublished)
GREY K 1995d Savory Basin drillhole Trainor 1 (Trainor diamond drilling) palynology and
thermal maturity GSWA Palaeontology Report no 199524 (unpublished)
GREY K 1995e Savory Basin drillhole Trainor 1 (Trainor diamond drilling) Additional
Preparation of two samples GSWA Palaeontology Report no 199528 (unpublished)
GREY K 1995f Neoproterozoic stromatolites from the Skates Hills Formation Savory Basin
Western Australia and a review of the distribution of Acaciella australica Australian Journal
of Earth Sciences v 42 p 123ndash132
GREY K 1996a Savory Basin drillhole Trainor 1 (Trainor diamond drilling) Additional
samples palynology and thermal maturation GSWA Palaeontology Report no 199615
(unpublished)
GREY K 1996b Preliminary stromatolite correlations for the Neoproterozoic of the Officer
Basin and a review of Australia-wide correlations GSWA Palaeontology Report no 199615
(unpublished)
GREY K and COTTER K L 1996 Palynology in the search for Proterozoic hydrocarbons
Western Australia Geological Survey Annual Review for 1995ndash96 p 70ndash80
GREY K and STEVENS M K 1997 Neoproterozoic palynomorphs of the Savory Sub-basin
Western Australia and their relevance to petroleum exploration Western Australia
Geological Survey Annual Review for 1996ndash97 p 49ndash54
HUBBARD R J PAPE J and ROBERTS D G 1985 Depositional sequence mapping as a
technique to establish tectonic and stratigraphic framework and evaluate hydrocarbon
potential on a passive continental margin in Seismic stratigraphy II an integrated approach
37
edited by O R BERG and D G WOOLVERTON American Association of Petroleum
Geologists Memoir 39 p 79ndash91
LIBBY WG 1995 A petrological report on six samples of bore cuttings from the Savory Basin
Western Australia Western Australia Geological Survey S-series S31307 (unpublished)
MORTON JGG and DREXEL JF 1997 The petroleum geology of South Australia Vol 3
Officer Basin South Australia Department of Mines and Energy Resources Report Book
9719
MUHLING P C and BRAKEL A T 1985 Geology of the Bangemall Group mdash the evolution
of an intracratonic Proterozoic basin Western Australia Geological Survey Bulletin 128
219p
MYERS J S 1990 Precambrian tectonic evolution of part of Gondwana southwestern Australia
Geology v18 p 537ndash540
NELSON D R 1997 Compilation of SHRIMP UndashPb zircon data Western Australia Geological
Survey Record 19972 196p
PAYTON C E 1977 Seismic stratigraphy mdash applications to hydrocarbon exploration
American Association of Petroleum Geologists Memoir 26 516p
PERINCEK D 1996a The age of NeoproterozoicndashPalaeozoic sediments within the Officer Basin
of the Centralian Super-basin can be constrained by major sequence-bounding unconformities
APPEA Journal v 36 pt 1 p 350ndash368
PERINCEK D 1996b The stratigraphic and structural development of the Officer Basin
Western Australia a review Western Australia Geological Survey Annual Review 1995ndash
1996 p 135ndash148
PERINCEK D 1998 A compilation and review of data pertaining to the hydrocarbon
prospectivity of the Officer Basin Western Australia Geological Survey Record 19976
POSAMENTIER H W JERSEY M T and VAIL P R 1988 Eustatic controls on clastic
deposition 1 mdash Conceptual framework in Sea-level changes an integrated approach edited by
C K WILGUS B S HASTINGS C G St C KENDALL H W POSAMENTIER
38
C A ROSS and J C VAN WAGONER Society of Economic Paleontologists and
Mineralogists Special Publication no 42
STEVENS M K and ADAMIDES N G in prep GSWA Trainor 1 well completion report
Savory Sub-basin Officer Basin Western Australia with notes on petroleum and mineral
potential Western Australia Geological Survey Record 199612
STEVENS M K and GREY K 1997 Skates Hills Formation and Tarcunyah Group Officer
Basin mdash carbonate cycles stratigraphic position and hydrocarbon prospectivity Western
Australia Geological Survey Annual Review for 1996ndash97 p 55ndash60
SUMMONS RE and POWELL C McA 1991 Petroleum source rocks of the Amadeus Basin
in Geological and geophysical studies in the Amadeus Basin central Australia edited by R J
KORSCH and JM KENNARD Australia BMR Geology and Geophysics Bulletin 236
TRAVERSE A 1988 Palaeopalynology Boston Unwin Hyman 600p
VAIL P R MITCHUM R M Jr TODD R G WIDMIER J M THOMPSON S III
SANGREE J B BUBB J N and HATLELID W G 1977 Seismic stratigraphy and
global changes of sea level in Seismic stratigraphy mdash applications to hydrocarbon
exploration edited by C E PAYTON American Association of Petroleum Geologists
Memoir 26 516p
WALTER M R and GORTER J 1994 The Neoproterozoic Centralian Superbasin in Western
Australia the Savory and Officer Basins in The sedimentary basins of Western Australia
edited by P G PURCELL and R R PURCELL Petroleum Exploration Society of Australia
Symposium Perth WA 1994 Proceedings p851ndash864
WALTER M R GREY K WILLIAMS I R and CALVER C R 1994 Stratigraphy of the
Neoproterozoic to early Palaeozoic Savory Basin and correlation with the Amadeus and
Officer Basins Australian Journal of Earth Sciences v 41 p 533ndash546
WALTER M R VEEVERS J J CALVER C R and GREY K 1995 Neoproterozoic
stratigraphy of the Centralian Superbasin Australia Precambrian Research v 73 p 173ndash195
WILLIAMS I R 1992 Geology of the Savory Basin Western Australia Western Australia
Geological Survey Bulletin 141 115p
39
WILLIAMS I R 1995a Bullen WA (2nd Edition) Western Australia Geological Survey
1250 000 Geological Series Explanatory Notes 23p
WILLIAMS I R 1995b Trainor WA (2nd Edition) Western Australia Geological Survey
1250 000 Geological Series Explanatory Notes 31p
WILLIAMS I R and TYLER I M 1991 Robertson WA (2nd edition) Western Australia
Geological Survey 1250 000 Geological Series Explanatory Notes 36p
40
41
Appendix 1
Bibliography
Reports which are relevant to this investigation but which are not specifically cited are listed
below
BAILLIE P W POWELL C McA LI Z X and RYALL A M 1994 The tectonic
framework of Western Australiarsquos Neoproterozoic to recent sedimentary basins in The
sedimentary basins of Western Australia edited by P G PURCELL and R R PURCELL
Petroleum Exploration Society of Australia Symposium Perth WA 1994 Proceedings p
45ndash62
BRADSHAW M T BRADSHAW J MURRAY A P NEEDHAM D J SPENCER L
SUMMONS R E WILMOT J and WINN S 1994 Petroleum systems in West Australian
basins in The sedimentary basins of Western Australia edited by P G PURCELL and R R
PURCELL Petroleum Exploration Society of Australia Symposium Perth WA 1994
Proceedings p 93ndash118
CLARKE G L 1991 Proterozoic tectonic reworking in the Rudall Complex Western Australia
Australian Journal of Earth Science v38 p 31ndash44
COCKBAIN A E and HOCKING R M 1990 Phanerozoic in Geology and mineral resources
of Western Australia Western Australia Geological Survey Memoir 3 p 750ndash755
ETHERIDGE M and WALL V 1994 Tectonic and structural evolution of the Australian
Proterozoic 12th Australian Geological Convention Geological Society of Australia
Abstracts no 37 p 102ndash103
GOODE A D T 1981 Proterozoic geology of Western Australia in Precambrian of the
Southern Hemisphere Developments in Precambrian geology 2 edited by I R HUNTER
Amsterdam Elsevier p 105ndash203
GREY K and JACKSON M J 1983 A re-assessment of stromatolite evidence for the
correlation of the Late Proterozoic Neale and Ilma Beds Officer Basin Western Australia
Australia BMR Journal of Australian Geology and Geophysics v 8 p 359
42
HICKMAN A H WILLIAMS I R and BAGAS L 1994 Proterozoic geology and
mineralization of the TelferndashRudall region Paterson Orogen Geological Society of Australia
(WA Division) Excursion Guidebook no 5 56p
HOCKING R M MORY A J and WILLIAMS I R 1994 An atlas of Neoproterozoic and
Phanerozoic basins of Western Australia in The sedimentary basins of Western Australia
edited by P G PURCELL and R R PURCELL Petroleum Exploration Society of Australia
Symposium Perth WA 1994 Proceedings p 21ndash 44
JACKSON P R 1966 Geology and review of exploration Officer Basin Western Australia
Hunt Oil Company Western Australia Geological Survey S-series S26 (unpublished)
JACKSON M J 1971 Notes on a geological reconnaissance of the Officer Basin Western
Australia Australia BMR Geology and Geophysics Record 19715 30p
JACKSON M J and van de GRAAFF W J E 1981 Geology of the Officer Basin Western
Australia Australia BMR Geology and Geophysics Bulletin 206 102 p
LOWRY D C JACKSON M J van de GRAAFF W J E and KENNEWELL P J 1971
Preliminary result of geological mapping in the Officer Basin Western Australia Western
Australia Geological Survey Annual Report for 1971 p 50ndash56
MYERS J S 1990 Precambrian in Geology and mineral resources of Western Australia
Western Australia Geological Survey Memoir 3 p 737ndash750
MYERS J S SHAW R D and TYLER I M 1994 Proterozoic tectonic evolution of
Australia 12th Australian Geological Convention Geological Society of Australia Abstracts
no 37 p 312
NEDIN C and JENKINS R J F 1991 Re-evaluation of unconformities separating the
lsquoEdiacaranrsquo and Cambrian systems South Australia Palaios v 6 p 102ndash108
PHILLIPS B J JAMES A W and PHILIP G M 1985 The geology and hydrocarbon
potential of the north-western Officer Basin APEA Journal 25 (1) p 52ndash61
POWELL C McA LI Z X McELHINNY M W MEERT J G and PARK J K 1993
Paleomagnetic constraints on timing of the Neoproterozoic breakup of Rodinia and Cambrian
formation of Gondwana Geology v 21 p 889ndash892
43
POWELL C McA PREISS W V GATEHOUSE C G KRAPEZ B and LI Z X 1994
South Australian record of a Rodinian epicontinental basin and its mid-Neoproterozoic
breakup to form the Palaeo-Pacific Ocean Tectonophysics v 237 no 3ndash4 p 113ndash140
PREISS W V 1976 Proterozoic stromatolites from the Nabberu and Officer Basins Western
Australia and their biostratigraphic significance South Australia Geological Survey Report
of Investigations no 47 p 1ndash51
TOWNSON W G 1985 The subsurface geology of the western Officer Basin mdash results of
Shellrsquos 1980ndash1984 petroleum exploration campaign APEA Journal v 25 (1) p 34ndash51
WATTS K J 1982 The geology of the Townsend Quartzite Upper Proterozoic shallow water
deposit of the Northern Officer Basin Western Australia Perth University of Western
Australia BSc honours thesis (unpublished)
WELLS A T and KENNEWELL P J 1974 Evaporite exploration in the Officer Basin
Western Australia at the Madley Diapirs Australia BMR Record 1974194 (unpublished)
WILLIAMS I R and MYERS J S 1990 Paterson Orogen in Geology and mineral resources
of Western Australia Western Australia Geological Survey Memoir 3 p 274ndash286
WILLIAMS I R 1990 Savory Basin in Geology and mineral resources of Western Australia
Western Australia Geological Survey Memoir 3 p 329ndash334
WILLIAMS I R 1994 The Neoproterozoic Savory Basin Western Australia in The
sedimentary basins of Western Australia edited by P G PURCELL and R R PURCELL
Petroleum Exploration Society of Australia Symposium Perth WA 1994 Proceedings p
841ndash850
WILSON R B 1967 Woolnough Hills and Madley diapiric structures Gibson Desert WA
APEA Journal v 7 p 94ndash102
44
Appendix 2
Meteorological data (from Bureau of Meteorology Perth 1994)
Table 21 Wiluna rainfall (mm)
Year Jan Feb Mar Apr May Jun Jul Aug Sept Oct Nov Dec
1975 0 45 446 309 306 59 276 4 34 886 638 164 1976 16 154 12 138 53 16 34 62 12 238 0 2 1977 44 0 66 74 68 95 24 363 1 58 12 727 1978 234 522 94 16 0 96 367 24 16 353 185 45 1979 19 173 122 88 91 4 0 246 58 0 169 114 1980 148 764 68 1081 259 626 629 06 56 02 174 0 1981 123 476 192 32 196 118 44 74 14 0 28 312 1982 374 705 206 244 1079 92 02 143 368 526 368 118 1983 1 112 928 248 0 212 56 32 5 1 42 496 1984 149 7 342 84 836 0 348 132 224 04 16 172 1985 596 483 0 166 556 0 514 56 0 0 4 0 1986 0 154 35 0 0 1085 23 01 239 137 0 04 1987 1204 119 19 89 17 575 154 126 07 1 0 398 1988 46 202 164 13 388 0 202 104 0 0 224 1309 1989 207 234 26 703 278 536 57 0 01 0 144 02 1990 1035 23 281 46 126 53 94 218 44 9 42 0 1991 48 0 41 45 0 472 297 12 0 1 0 7 1992 112 96 1025 1227 323 65 04 174 0 132 48 4 1993 0 697 0 202 445 0 12 306 18 05 14 33 Mean 25 35 22 27 27 25 18 12 6 13 13 21
JAN FEB MAR APR MAY JUN JUL AUG SEP OCT NOV DEC0
10
20
30
40
Mea
n R
ain
fall
(mm
)
Month
Mean monthly rainfall in Wiluna
MKS41 140498
45
Table 22 Wiluna minimum temperature (degC)
Year Jan Feb Mar Apr May Jun Jul Aug Sept Oct Nov Dec
1975 ndash 23 203 15 94 63 71 62 103 124 169 205 1976 242 229 194 15 10 63 59 73 95 143 16 228 1977 243 25 197 148 96 95 56 86 102 ndash 188 23 1978 241 232 203 18 102 64 76 8 9 152 19 205 1979 255 226 216 167 83 6 59 79 97 145 198 223 1980 255 226 231 155 134 83 68 75 121 108 193 223 1981 245 216 19 182 119 6 54 78 138 159 163 218 1982 232 224 177 16 ndash ndash 37 111 112 164 209 225 1983 235 24 197 147 112 88 39 88 121 162 189 219 1984 241 243 191 156 ndash 72 66 7 95 161 182 211 1985 244 231 ndash 159 98 65 71 73 117 147 205 ndash 1986 ndash 229 226 155 93 96 43 49 10 122 ndash 219 1987 ndash 217 183 175 85 77 68 68 112 ndash ndash 221 1988 238 214 209 178 111 ndash ndash 86 104 157 171 195 1989 ndash 237 199 165 107 67 44 61 107 131 187 ndash 1990 232 ndash 211 155 118 62 57 87 102 149 195 22 1991 26 256 217 168 122 101 78 ndash 113 18 168 219 1992 227 227 214 169 102 98 59 69 ndash 125 159 196 1993 241 218 196 171 103 ndash 49 68 88 128 192 211 Mean 24 23 20 16 10 8 6 8 11 14 18 21
NOTE Dashes indicate data unavailable
JAN FEB MAR APR MAY JUN JUL AUG SEP OCT NOV DEC0
10
20
30
40
Month
MKS43 140498
50
Mean monthly minimum temperatures at Wiluna
Mea
n T
emp
erat
ure
(degC
)
46
Table 23 Wiluna maximum temperature (degC)
Year Jan Feb Mar Apr May Jun Jul Aug Sept Oct Nov Dec
1975 ndash 349 326 281 247 201 197 212 256 248 31 344 1976 374 369 346 297 248 206 208 225 265 287 313 388 1977 397 392 352 296 234 212 222 244 ndash 308 337 383 1978 378 345 346 316 242 195 176 205 231 295 334 356 1979 403 36 364 295 ndash ndash ndash 193 242 318 359 373 1980 392 342 377 275 24 176 179 233 292 288 349 391 1981 385 346 337 342 242 178 201 224 30 326 326 369 1982 372 359 315 307 ndash ndash 196 253 252 305 353 379 1983 381 389 327 272 263 222 187 248 287 321 336 366 1984 378 393 322 299 226 215 178 214 234 ndash 336 364 1985 40 366 ndash 294 224 216 205 212 284 307 355 ndash 1986 ndash 383 372 307 ndash 193 166 196 261 277 ndash 382 1987 ndash 339 328 305 21 202 214 218 275 ndash ndash 374 1988 388 365 353 301 23 ndash ndash 228 283 334 31 33 1989 ndash 375 339 285 238 179 181 219 275 298 336 ndash 1990 368 ndash 36 309 268 19 188 205 274 309 373 393 1991 414 416 363 315 268 206 21 ndash 279 338 332 368 1992 363 383 336 263 213 178 213 197 ndash 285 313 359 1993 396 357 344 301 221 ndash 197 215 253 294 347 362 Mean 39 37 34 30 24 20 20 22 27 30 34 37 NOTE Dashes indicate data unavailable
JAN FEB MAR APR MAY JUN JUL AUG SEP OCT NOV DEC0
10
20
30
40
Month
MKS42 140498
50
Mean monthly maximum temperatures at Wiluna
Mea
n T
emp
erat
ure
(degC
)
47
Appendix 3
Table 31 Summary of palynological results
Drillhole Depth (m) F no(a) GSWA no Lithology Formation Assemblage TAI(b)
BWB 1 74ndash75 F49668 135741 dark-grey siltstone basalt Jilyilli gt5 BWB 1 98ndash100 F49669 135742 dark-grey siltstone basalt Jilyilli gt5 BWB 1 121ndash122 F49670 135743 dark-grey siltstone basalt Jilyilli gt5 TWB 1 86ndash87 F49671 135631 dark-grey siltstone McFadden 3+ TWB 1 104ndash105 F49672 135632 dark-grey siltstone Cornelia 3+ TWB 1 121ndash122 F49673 135633 dark-grey siltstone Cornelia 4 TWB 2 14ndash15 F49674 135634 dark-grey siltstone Skates Hills 3+ TWB 6 49ndash50 F49675 135675 dark-grey siltstone Cornelia 1 3+ TWB 9 49ndash51 F49676 135704 dark-grey siltstone Brassey Range 1 3+ Trainor 1 37497- F49733 138939 black mudstone with Cornelia 5 37509 light-grey siltstone Trainor 1 3809 F49734 138940 dark-grey and black Cornelia 4- laminated mudstone Trainor 1 4170 F49735 138941 black unlaminated mudstone Cornelia 4- Trainor 1 4950 F49851 139501 dark-grey indurated siltstone Cornelia 5 Trainor 1 6032 F49852 139502 dark- and light-grey Cornelia 5 indurated siltstone Trainor 1 6434 F49853 139503 greenish indurated finely Cornelia 5 laminated siltstone LDDH 1 270 F49678 138934 dark-grey siltstone interbeds Waters 1 3+ in enterolithic evaporite Tarcunyah Gp LDDH 1 277 F49679 138935 dark-grey siltstone in cavity Waters 1 3+ in enterolithic evaporite Tarcunyah Gp
NOTES (a) GSWA Fossil Catalogue number (b) TAI = Thermal Alteration Index of Traverse (1988 plate 1)
48
Appendix 4
Savory Sub-basin quantitative magnetic and gravity interpretation (extracted from Cowan 1995)
Summary
A program of quantitative aeromagnetic interpretation has been completed on BMRAGSO data from the Savory Sub-
basin Western Australia Quantitative aeromagnetic interpretation utilized the 3D Euler deconvolution method
supported by wavenumber filtering and image processing The results have provided useful information on structural
trends and depth to magnetic sources in a structurally complex area Depth to magnetic source analysis has provided
information on intra-sedimentary magnetic sources as well as basement rocks
The results of the interpretation support previously identified depocentres However the presence of magnetic
sources at several levels makes it very difficult to produce a reliable magnetic basement depth contour map It is
considered more productive to work with the 3D Euler colour circle plots and images rather than trying to contour the
results It would be necessary to carry out a full-scale interpretation of the BMRAGSO profile data to improve on the
3D Euler results The regional gravity was found to be useful in interpreting the regional setting of the area although
the very wide data spacing limits quantitative use of the data The gravity data show quite a complex picture with
limited consistent correlation between gravity features and basin structures This suggests that gravity anomalies
reflect changes in density of the basement rocks rather than basement topography especially in the northern part of the
basin
It is recommended that the GSWA investigate access to company confidential high-resolution aeromagnetic data
prior to planning further aeromagnetic surveys Private companies have flown large parts of the northern half of the
area as part of their diamond exploration program Additional gravity coverage of the area may be more cost effective
than magnetic surveys as the gravity data provides more information on changes within the sedimentary section
Introduction
The main use of aeromagnetic data in petroleum exploration has been the determination of magnetic basement
topography although there has been increasing interest in analysis of intra-sedimentary magnetic anomalies
intrabasement and suprabasement magnetic anomalies These anomalies are used to determine depth to magnetic
basement rocks and hence determine the thickness of the sedimentary sequence Unfortunately interpretation of the
intrabasement and suprabasement magnetic anomalies is non-unique in terms of position and size of causative sources
because of the inherent ambiguity of potential-field methods However this ambiguity can be reduced by placing
49
constraints on source geometry and magnetization and by using geological and other geophysical data to constrain
the solution
Before 1970 most depth-determination techniques involved graphical determination of slopes of selected
magnetic anomalies and application of various empirical factors to convert the slopes into depth estimates Geological
Society of America Memoir 47 Interpretation of Aeromagnetic Maps by Vacquier et al (1951) was a landmark for
this type of interpretation
Automated interpretation procedures have played an increasingly important role in depth interpretation and a
wide range of techniques have been developed Many of these techniques are designed for application to located data
profiles and assume a two-dimensional geometry However there has been renewed interest in techniques applicable
to gridded data
Two distinct types of method can be recognized In the first case often described as discrete methods individual
isolated magnetic anomalies are interpreted and the results used to produce a map of basement relief In the second
case often described as continuous methods areas of data containing a number of anomalies are interpreted
statistically to produce direct output of basement depths
The discrete methods usually involve a semiautomatic initial phase which generates a large number of possible
depth solutions and an interactive second phase to screen and select acceptable solutions The advantage of this
approach is that the interpreter can select features that are relatively free from interference from adjacent anomalies
and consider all aspects of a particular magnetic anomaly The disadvantage is that interpretation can be very time
consuming as a wide range of depths are usually possible depending on the initial model chosen and a significant
amount of effort is needed to select the correct model In the case of the Savory Sub-basin dataset we encountered
problems in separating basement related effects from the effects of shallower intrasedimentary magnetic sources
Because of these problems we have concentrated on displaying the Euler results accompanied by separation filter
images of the data to show the shallower effects and deeper effects rather than trying to refine a 3D Euler
deconvolution depth-to-crystalline-basement contour
The continuous methods are very direct provided that the rather restrictive assumption can be made that all
anomalies are due to lateral magnetization changes due to basement topography This means that shallow effects and
large intrabasement anomalies must be removed from the data This involves judgement and skill as it is necessary to
distinguish between the lower amplitude suprabasement anomalies due to basement topography and the larger
intrabasement anomalies reflecting magnetization changes within the basement These methods were not considered
suitable for the Savory Sub-basin magnetic dataset but were used to invert the gravity data
50
Limitations of magnetic and gravity interpretation
Interpretation of the area is limited by a shortage of information on the nature and physical properties of the deeper
sedimentary sequence and the underlying basement rocks However using techniques such as cross-correlation of
gravity and pseudo-gravity data it is possible to try to differentiate between anomalies relating to basement and those
related to the sedimentary sequence
Gravity anomalies reflect changes within the sedimentary sequence as well as basement condition These
changes in density of sedimentary rocks produce gravity anomalies without a corresponding magnetic anomaly hence
the complementary nature of gravity and magnetic surveys The main use of magnetics is to determine depth to
magnetic basement and any intra-sedimentary volcanic rocks or intrusives whereas gravity provides much more
general information on the sedimentary sequence
Unfortunately interpretation of gravity anomalies is complicated since they can be due to a number of geological
features including
bull major basement faults
bull basement highs
bull igneous intrusions within the basement
bull sedimentary basins which may or may not be isostatically compensated
bull intra-sedimentary volcanics and associated plutonic centres
Two major problems affect the interpretation of both magnetic and gravity data
1 The inherent ambiguity of potential-field data There is no unique solution to any measured gravity or magnetic
anomaly and theoretically there will be an infinite number of source geometry and magnetizationdensity
combinations which will fit the observed data This means that any a priori information which helps to select a
suitable model is very useful
2 Measured anomalies are the summation of effects from different depths For example an observed gravity profile
may contain contributions from shallow sources (density variations within the sedimentary basin) intermediate
depth sources (density variations due to large igneous intrusions within the basement) and deep sources (crustal
thinning producing a mantle anomaly) Separation of these component responses is the regionalresidual problem
which we solve using spectral analysis and differential upward continuation-based separation filtering
Regional setting and interpretation overview
The area studied includes parts of BALFOUR DOWNS (SF51-9) RUDALL (SF51-10) ROBERTSON (SF51-13) GUNANYA
(SF51-14) COLLIER (SG50-4) BULLEN (SG51-1) TRAINOR (SG51-2) MADLEY (SG51-3) NABBERU (SG50-5)
STANLEY (SG51-6) and HERBERT (SG51-7) 1250 000 sheets Broadly the area lies between latitudes 22deg00rsquondash25deg30rsquoS
and longitudes 119deg30rsquondash123deg30rsquoE
51
Regional gravity
The AGSO regional gravity data (at nominal 11 km spacing) was gridded at a 4 km mesh spacing using a minimum-
curvature algorithm Bouguer gravity values in the area are negative reflecting mass deficiency at depth and range
from -84 mgals to -25 mgals
A Bouguer gravity colour image is shown as Figure 41 A residual grid was produced by removing a fifth-order
orthogonal polynomial from the Bouguer data but did not add to the interpretation
120deg 121deg 122deg 123deg
23deg
24deg
25deg
-25
-84
50 km
MKS46 180598
mgal
Figure 41 Regional Bouguer gravity (BMRAGSO data) gridded at 4 km
52
The data show a complex pattern of positive and negative anomalies with no clearly defined trends Correlations
with aeromagnetic data and known basin structures are poor A vague north-northwest linear trend appears to coincide
with the Marloo Fault (Figure 42) A prominent negative anomaly appears to coincide with the Blake Fold and Fault
Belt depocentre and continues as a narrower negative anomaly to the east until it widens out again near the edge of the
basin Elsewhere the gravity data show little correlation with known basin structures and it is likely that especially in
the north of the area gravity anomalies are due to density changes in the basement rather than changes in basement
topography
Production of wavelength-filtered residual gravity plots and vertical gradient plots showed very patchy aliased
data reflecting poor sampling in much of the area
Regional magnetics
The AGSO regional aeromagnetic data were gridded at a 400 m mesh spacing using a minimum-curvature algorithm
(Figure 43) Most of the data has a line spacing of 1600 m with small areas of 1 km spacing The quality of the data is
acceptable for regional interpretation but is not adequate for detailed analysis The accuracy of the flight path is rather
variable reflecting the vintage of the data and the noise envelope of the data is poor by modern standards Problems
were also encountered in joining different map sheets
The magnetic anomaly pattern over the south and west part of the area shows a strong high frequency signature
reflecting the presence of widespread basic sills and dykes Some of the major north-northeasterly trending dykes can
be traced over considerable distances
Discontinuous high-frequency anomalies extend as a northwest-trending zone through the centre of the area and
this zone includes a conspicuous circular magnetic anomaly which is probably a ring complex
The northern and eastern parts of the area are characterized by long-wavelength deep-seated basement magnetic
anomalies with 120deg and 150deg trends dominant The Marloo and Perentie Faults (Figure 42) appear as distinct linear
zones and offsets A prominent easterly trending negative anomaly in the northwest of the area appears to swing round
to the southeast and may separate different basement blocks One possible interpretation is that this very deep seated
anomaly separates areas of Archaean and Proterozoic basement
Regional geology
The regional geology is described in Williams (1992) The GSWA provided a digitized version of Plate 2 from this
Bulletin the structural interpretation map to use as an overlay (Figure 42)
53
Pp
Pp
PSd
PSd
PSd
PSd
PSd
PSo
PSt
PSt
PSf
PSf
PSf
PSb
PSb
PSb
PSsPSs
PSs
PSb
PSm
PSp
PSc
PSc
PSw
PSw
PSw
PSg
PSr
PSj
PSg
PM
Pk
PY
PY
PSd
L
L
L
L
L
L
L
LL
L
L
L
LL
L
LL
L L
LL
L L
L
L
L
L
L
L
L
LL
L
L
BLAKEDEPOCENTRE
MA
RLO
O
FAU
LT
PERENTIEFAULT
50 km
MKS39120598
120deg 121deg 122deg 123deg
25deg
24deg
23deg
Approximate boundaryof aeromagnetic interpretation
PML
PSgL
PSjL
PML
PSpL
PML
PML
PSfL
PSfL
PSpL
LPc
LPcLPcPSrL
LPA
Durba Sandstone
Woora Woora Formation
McFadden Formation
Tchukardine Formation
Boondawari Formation
Skates Hills Formation
Mundadjini Formation
Coondra Formation
Spearhole Formation
Watch Point Formation
Jilyili Formation
Brassey Range Formation
Glass Spring Formation
Paterson Formation
Yeneena Group
Karara Formation
Cornelia Formation
Kahrban Subgroup
Bangemall Group
Fault
Formation boundary
PSdL
PSoL
PSfL
PStL
PSbL
PSsL
PSmL
PScL
PSpL
PSwL
PSjL
PSrL
PSgL
Pp
PYL
PkL
LPc
LPA
PML
Savory Group Other Units
PYL
Figure 42 Regional geology and structure map (after Williams 1992)
54
120deg 121deg 122deg 123deg
23deg
24deg
25deg
5820
3750
MKS47 180598
nT
50 km
Figure 43 Regional aeromagnetic data total magnetic intensity (BMRAGSO data) gridded at 400 m
Analysis
3D analysis
3D Euler deconvolution was used as the primary depth-determination method The advantage of this approach is that
consistent solutions can be obtained over the entire area with minimal assumptions about source geometries Euler
deconvolution of gridded data is used for positional information and estimation of depth to top of source Euler
55
deconvolution yields a large number of depth solutions which have to be screened to reject spurious solutions Results
are plotted as circles in eight depth ranges with radius proportional to depth and colour coded
The 400 m total magnetic intensity grid was used for the analysis Horizontal gradients in x and y and the vertical
gradient were calculated 3D Euler deconvolution was tested on the 400 m gridded data using windows of 9 times 9 and
11 times 11 and 16 times 16 data points and structural indices 05 (fault) and 10 (sill or dyke) It was concluded that the
16 times 16 window produced the best results overall and final plots were produced for the 16 times 16 window and structural
index 05 (Fig 44) Results were very good over the northern and central parts of the area showing magnetic sources
Figure 44 Depth to magnetic source 3D Euler deconvolution 16 times 16 window of 400 m gridded data structural index 05
56
at several different levels Unfortunately in the extreme south of the area shallow intrasedimentary magnetic sources
(sills and dykes) dominated the inversion and the results contained few basement solutions
In order to reduce these problems the 400 m gridded data were filtered using a separation filter based on
interpretation of the log-energy spectrum The 3D Euler method was run on the filtered data in order to generate more
basement-depth solutions Results for the deep-separation filter data were gridded and presented as a colour image in
Cowan (1995) Attempts to grid the Euler output were unsatisfactory and it is considered safer to interpret the 3D
Euler depth plots The 3D Euler depth results from the separation-filter run should be analysed with care as perfect
separation of the basement can never be achieved and there will always be some contamination from sources at
different levels
The results of original total magnetic intensity 3D Euler depth estimation for structural index 05 using a 16 point
window have been plotted at 1500 000 scale (not included in this publication but available in Cowan (1995) from the
GSWA Library as S10331) and as reduced A4 colour circle plots (Figure 44)
The results of deep-basement 3D Euler depth estimation for structural index 05 using a 16 point window have
been plotted as a colour image at 1500 000 scale and as an A4 image (not included in this publication)
2D analysis
Two equispaced profiles were interpolated with a 50 m station interval from the AGSO-located data profiles for the
BULLEN 1250 000 sheet The interpolated profiles were analysed using 2D Euler deconvolution and Werner
deconvolution Results are included in Cowan (1995) and show the use of these methods for more detailed analysis
Filtered data
In order to reconcile 3D Euler results from shallow basement and intrasedimentary magnetic sources we produced
several separation-filtered maps and images We found the shallow-layer double-separation filter (Figure 45) to be
very effective for shallow sources and the deep-layer standard-separation filter (Figure 46) for the basement layer
Gravity and magnetic data correlation
Both lsquoreduced to the polersquo (RTP) magnetics (Figure 47) and pseudo-gravity data (Figure 48) were produced as part of
the reconciliation of gravity and magnetic signatures In both cases the filtering operations assumed magnetization by
induction in the present Earths field The RTP data are fairly similar to the total magnetic intensity The pseudo-
57
gravity data are dominated by a northwest-trending strong positive anomaly and there is little correlation with the
Bouguer gravity data
The poor magneticgravity correlation is confirmed by cross-correlation of the RTP magnetics and the gravity
gradient The correlation plot in Figure 49 shows little coherent response with numerous zones of positive and
negative correlation
Figure 45 Regional aeromagnetic data shallow layer separation filter (BMRAGSO data) gridded at 400 m
Results
In the north and east of the area on the Wells Foreland Sub-basin trend (refer to Figure 1 main text) we see a range
of quite deep 3D Euler depths and several trend directions with north-northwesterly dominant There are relatively few
shallow intrasedimentary solutions in this zone
The second area of deep 3D Euler solutions lies over the Blake depocentre (Figure 43) with several trend
directions
Elsewhere the 3D Euler results are dominated by shallow intrasedimentary depth solutions reflecting mainly the
dolerite sills dykes and the ring complex However where we do see basement-related solutions in the south and
west of the area they appear to be shallower than those noted for the Wells Foreland Sub-basin and the Blake
depocentre
58
Figure 46 Regional aeromagnetic data deep-layer separation filter (BMRAGSO data) gridded at 400 m
Figure 48 Regional aeromagnetic data pseudo-gravity transform (BMRAGSO data) gridded at 400 m
Figure 47 Regional aeromagnetic data reduced-to-pole (BMRAGSO data) gridded at 400 m
Figure 49 Regional aeromagnetic and gravity data gravitymagnetic correlation using RTP magnetics and gravity gradient (BMRAGSO data) gridded at 4 km
59
This subdivision of the area into two zones of deep solutions is consistent with interpreted depocentres
However the interference between sources at different levels and the complexity of the magnetic response of the
basement rocks precludes more refined interpretation at this stage
The area of deep 3D Euler solutions over the Blake depocentre correlates with the pronounced negative gravity
anomaly discussed in the gravity interpretation section Using a density contrast of -015 gcc the negative gravity
anomaly could indicate up to 6ndash8 km of low-density sedimentary rocks depending on assumptions about the regional
field
The area of deep 3D Euler solutions over the Wells Foreland Sub-basin has a complex gravity expression and no
clear basin structure emerges from inversion of these data As noted previously it is likely that observed gravity
anomalies reflect contrasts in basement density rather than basement topography
Separation filtering applied to the magnetic data helps to enhance the intrasedimentary magnetic signature and to
give a better impression of the basement magnetic signature even though separation of the basement response is not
perfect
Conclusions
Quantitative aeromagnetic interpretation using 3D Euler deconvolution supported by wavenumber filtering and image
processing has been successful in providing structural trend and depth information for the Savory Sub-basin
Quantitative magnetic interpretation has revealed two zones of relatively deep magnetic basement beneath the
Wells Foreland Sub-basin and the Blake depocentre
This analysis of the magnetic data supports interpreted depocentres but the complexity of the basement magnetic
signature and interference from sources at different depths precludes further refinement to a map of basement
topography
Regional gravity proved to be very useful in understanding the regional setting of the area and in providing
support for aspects of the interpretation The gravity data support the interpretation of the Blake depocentre
suggesting up to 6ndash8 km of low-density sedimentary rocks
The deep structure of the Savory Sub-basin area is obviously complex with different areas underlain by
Archaean and Proterozoic basement and with the Capricorn suture occurring in the centre of the area
60
Recommendations
The quantitative magnetic interpretation needs to be reconciled with geological models available for the area
In particular the zones tentatively identified as areas with thick sedimentary rocks the Wells Foreland Sub-
basin and the Blake depocentre need to be investigated
Cross sections should be prepared across the basin for joint magneticgravity modelling especially for the Blake
depocentre It is important to be able to explain the strong negative gravity anomaly in this area
In view of the effects of basement density contrasts on the gravity field for the northern part of the area we think
that additional gravity interpretation and acquisition of new gravity data may not be justified as they will not
contribute significantly to understanding basin evolution and structure
It is recommended that GSWA try to get access to company confidential high-resolution aeromagnetic data
rather than flying new surveys The GSWA might offer to fund flying of new infill areas as a bargaining point
References
The original text of this report by Cowan (1995) and 1500 000 scale maps are filed in the GSWA Library under
S10331
COWAN D 1995 Savory Basin quantitative magnetic interpretation Western Australia Geological Survey S-series
S10331 (unpublished)
VACQUIER V STEENLAND N C HENDERSON R G and ZIETZ I 1951 Interpretation of aeromagnetic
maps The Geological Society of America Memoir 47 151p
WILLIAMS I R 1992 Geology of the Savory Basin Western Australia Western Australia Geological Survey
Bulletin 141 115p
61
Appendix 5
Geochemistry
MKS38 250398
Saturate FractionC12+ GLC
1217
Pr18
Ph
22
31CSR WELL-13 315m Cuttings
Figure 51 Canning Stock Route Well 13 gas chromatograph of extract of auger drill sample
12
17
18
22
31
Pr Ph
LDDH 1 6623m CoreSaturate FractionC12+ GLC
MKS35 240398
Figure 52 Gas chromatograph of extract from core sample at 6623 m LDDH1
62
Table 51 Canning Stock Route Well 13 auger drill samples
GSWA sample Drill depth (m)(a) Comments
135601 150 At watertable 135602 203 (all samples consist 135603 310 of sand mud and water) 135604 315 At total depth
NOTE (a) Datum for drill depth is the top of sediment fill in the well which is 155 m below ground level (ie the total depth of 315 m is 47 m below ground level)
Table 52 Canning Stock Route Well 13 gas chromatography data for 315 m depth sediment sample
Parameter Value
Weight of rock extracted (grams) 945 Total extract (ppm) 519 n-Alkane distribution n-C12 07 n-C13 23 n-C14 26 n-C15 22 n-C16 19 n-C17 14 i-C19 23 n-C18 14 i-C20 08 n-C19 11 n-C20 16 n-C21 25 n-C22 29 n-C23 70 n-C24 42 n-C25 95 n-C26 43 n-C27 83 n-C28 38 n-C29 87 n-C30 31 n-C31 273 Alkane compositional data Pristane phytane ratio 279 Pristane n-C17 ratio 161 Phytane n-C18 ratio 059 CPI (1)(a) 284 CPI (2) 209 (C21 + C22) (C28 + C29) 043
NOTE (a) CPI= Carbon preference index
63
Table 53 LDDH1 extract liquid chromatography data for 6623 m concentration
Rock extracted Total extract (grams) (ppm)
702 313
NOTE ppm= parts per million
Table 54 LDDH1 saturate gas chromatography data of core for 6623 m alkane composition
Pristane Pristane Phytane (a) CPI (1) CPI (2) (C21+C22) Phytane n-C17 n-C18 (C28+C29)
103 026 024 103 102 325
NOTE (a)CPI = carbon preference index
Table 55 LDDH1 saturate gas chromatography data of core for 6623 m n-alkane distributions
Parameter Value
n-C12 17 n-C13 38 n-C14 55 n-C15 60 n-C16 65 n-C17 74 i-C19 19 n-C18 78 i-C20 19 n-C19 80 n-C20 79 n-C21 71 n-C22 64 n-C23 57 n-C25 43 n-C24 38 n-C27 31 n-C28 23 n-C29 19 n-C30 12 n-C31 10
64
Appendix 6
Table 61 Summary of data from Trainor waterbores (TWB) and Bullen waterbores (BWB)
Well AMG Elevation TD Status(b) Completion details Water Salinity Water level Flow rate Depth to consolidated AGD84 GL (m) (m) struck mgl(c) (m) (LHr) lithology aquifer(e) Z51(a) Interval (m) (100 mm PVC) (m) (mgl)(d)
TWB 1 473660E 453 122 comp 0ndash75 plain 63 7 300 24 2 880 12 m 7287404N 75ndash93 slotted (9 260) McFadden Fm 93ndash99 plain TWB 2 472 977E 475 23 abd nil 15 m 7285877N Skates Hills Fm dry TWB 3 473259E 475 50 abd nil 7 m 7285849N Skates Hills Fm dry TWB 4 463225 E 445 50 comp 0ndash22 plain 35 7 200 55 3 600 0 m 7286143N 22ndash34 slotted (8 140) Tertiary sand and gravel 23ndash60 plain TWB 5 463095E 445 31 comp 0ndash19 plain 13 26 000 655 3 600 Tertiary sand and gravel 7277721N 19ndash25 slotted (36 700) 25ndash31 plain TWB 6 457013E 455 50 comp 0ndash42 plain 38 920 119 600 0 m 7274352N 42ndash48 slotted (1 030) Cornelia Fm ss TWB 7 453739E 475 26 susp 0ndash2 plain 11 9 300 48 4 500 0 m 7263891N (10 500) Tertiary sand TWB 8 433893E 535 60 susp 0ndash2 plain 47 8 500 gt46 1 200 0 m 7245991N (10 900) Tertiary sand and Brassey Range Fm ss TWB 9 437219E 505 51 comp 0ndash47 plain 45 1 000 58 600 1 m 7235905N 47ndash51 slotted (990) Brassey Range Fm ss TWB 10 434927E 495 32 susp 0ndash2 plain 235 450 120 0 m 7225875N (500) Dolerite
65
BWB 1 287337E 580 122 abd Nil 1 m 7245861N Jilyili Fm dry BWB 2 288346E 545 50 comp 0ndash26 plain 15 630 3 29 000 0 m 7240423N 26ndash38 slotted (730) Tertiary sand and gravel 38ndash50 plain BWB 3 305637E 545 50 abd 19 8 800 43 7 200 0 m 7240423N (10 550) Tertiary ss BWB 4 320167E 515 445 comp 0ndash20 plain 9 980 445 24 000 0 m 7248097N 20ndash32 slotted (1 190) Tertiary ss 32ndash44 plain BWB 5 353393E 545 20 susp 0ndash2 plain 45 (970) 1 m 7238934N Basalt
NOTES (a) GPS accuracy ~ 150 m (b) Comp = completed abd = abandoned susp = suspended (c) Salinity from conductivity (d) Analysis total dissolved solids (e) Fm = Formation ss = sandstone
12
50 km
120deg 121deg30 123deg
25deg
24deg
23deg
22deg
Greater Officer Basin
PNCEXP CA11PNCEXP CA12
PNCEXP CA13PNCEXP CA19
PNCEXP CA05
PNCEXP CA09
BD134589
GSWA Trainor 1 and TWB123
Fortescue River 1A
Mundadjini 1
Akubra 1Boondawari 1
TWB4TWB5
TWB6
TWB7
TWB8
TWB9
TWB10
BWB1
BWB2 BWB3
BWB4
BWB5
OD23
Mineral exploration drillhole
Stratigraphic drillhole
Waterbores and wells(TWB and BWB serieswaterbores identified)
MKS33270398
LDDH 1
Savory Sub-basin
Canning SR Well 13
EP380
Petroleum Exploration permit
Petroleum exploration well
Figure 5 Locations of petroleum exploration wells mineral exploration and stratigraphic drillholes water bores and wells and petroleum exploration permit EP380 in the Savory Sub-basin
13
TD=600m
TD=1367m
TD=701m
TD=709m
TD=50m
SS
1S
S1
SS1
SS
1S
S1
SS
1
SS
1
SS1
SS4 SS1
Pha
nero
zoic
or
SS
2
Cz
CzCz
Karst Bitumen
SS1
TD=181m
Mundadjini 1 Akubra 1 Boondawari 1 LDDH 1 Trainor 1 TWB 6
Munda-djini Fm
Spear-hole Fm
Munda-djini Fm
Munda-djini Fm
Spear-hole Fm
Spear-hole Fm
Waters Fm
McFadden Fm
Cornelia Fm
Cornelia Fm
Cornelia Fm
511 plusmn 13Maor 696 plusmn 20Ma(maximum)
779 plusmn 10Ma(maximum)
Mundadjini 1
Akubra 1 Boondawari 1
LDDH 1
Trainor 1TWB 6100 km
N
LOCATION
NW SE
Sea level
0m AHD
Dolerite basalt
Conglomerate
Sandstone
Mudstone
Dolomite
Limestone
Evaporite
TOC gt08
Permeability gt100md
Oil fluorescence
Sedimentary zircon U-Pb age
Identifiable polymorphs
Cainozoic
Supersequence 1 age
Unconformity
Formation contact
Cz
SS1
r
r
0
100
200
metres
VerticalScale
MKS36 120598
LEGEND
Figure 6 Geological cross section through significant drillholes in the Savory Sub-basin
14
Depositional Sequence C Supersequence 3
Depositional Sequence C consists of the Boondawari Formation (Fig 3) and although it contains
sandstone conglomerate and dolomite the sandstones contain significant amounts of feldspar and
clay and hence are likely to be poorer reservoirs than older sandstones
Depositional Sequence D Supersequence 4
Depositional Sequence D includes the McFadden Tchukardine and Woora Woora Formations
(Fig 3) The McFadden Formation is poorly sorted and sandstones contain significant amounts of
feldspathic clasts in the north of the basin but are significantly coarser and cleaner in the northeast
of the sub-basin (Williams 1992)
Sandstones of the Tchukardine and Woora Woora Formations are generally cleaner than those
of the McFadden Formation and are expected to have fair to good porosity although the
Tchukardine Formation has a higher clay content in parts
Depositional Sequence E Supersequence 4
Depositional Sequence E consists of the Durba Sandstone (Fig 3) a coarse sandstone with minor
conglomerate which has good to excellent visible porosity in surface exposures
Other depositional sequences and regional correlations
Sedimentary rocks which were not included in the Savory Group by Williams (1992) but which
are likely to be of Neoproterozoic age and hence part of the greater Officer Basin include the
Tarcunyah Group the Cornelia Formation and the Kahrban Subgroup
As discussed in the Introduction all of the strata in the Karara Basin and the younger strata
of the Yeneena Basin were redefined to form the Tarcunyah Group of the greater Officer Basin
(Bagas et al 1995) (Fig 7) In outcrop the Tarcunyah Group consists predominantly of quartzose
feldspathic and arkosic sandstone shale which is carbonaceous in parts and carbonate which
includes stromatolitic dolomite Mineral hole LDDH1 drilled on GUNANYA intersected the
15
120598
122deg
123deg
21deg
22deg
23deg
24deg
23deg
22deg
21deg
122deg
123deg
Fault
Thrust
Reverse thrust
CANNINGBASIN
OFFICERBASIN
GROUP
PILBARACRATON
TARCUNYAH
SAVORY GROUP
BANGEMALL
GROUP
THROSSELL
GROUP
LAMIL
GROUP
ConnaughtonTerrane
TerraneTalbot
complexTabletop granitic
Tabletop Terrane
Permian
Neoproterozoicgranitoid
50 km
FormationWaltha Woora
McKay Fault
South west Thrust
Vines
Fault
24deg
120deg
YENEENA CANNINGBASIN
ARUNTAINLIERRUDALL
COMPLEX
AMADEUSBASIN
MUSGRAVEBLOCK
OFFICERBASINYILGARN
CRATON
GROUP
GROUP
GROUP
PILBARACRATON
GROUP
EARAHEEDY
GLENGARRY
BANGEMALL
WYLOO GROUP
SAVORY
WA
CARNARVONBASIN
GASCOYNECOMPLEX
GROUPTARCUNYAH
400 kmGROUP
SA
N
T
CamelndashTabletopfault zone
KAHRBANSUBGROUP
CORNELIAFORMATION
MKS37
Figure 7 Regional geological setting of the Savory Group and western Officer Basin The dashed line on the inset map marks the interpreted margin of the greater Officer Basin
16
Tarcunyah Group and consists predominantly of mudstone with minor sandstone limestone
dolomite and anhydrite (Fig 6)
The age of the Tarcunyah Group is uncertain although limited palynological and stromatolite
evidence suggests that it is probably coeval with Supersequence 1 of the Centralian Superbasin
Drillhole LDDH1 contains palynomorphs equivalent to assemblages in the Browne and Bitter
Springs Formations of the Officer and Amadeus Basins respectively and from the Cornelia
Formation in TWB 6 (Grey and Stevens 1997) (Figs 4 and 6) Stromatolite specimens tentatively
assigned to Acaciella australica (Howchin 1914) Walter 1972 occur in the lower Tarcunyah
Group (Bagas et al 1995) The stromatolite Baicalia burra Preiss 1972 and a conical
stromatolite were reported from the upper part of the Tarcunyah Group (Stevens and Grey 1997)
The recognition of two stromatolite assemblages interpreted to have age significance in
Supersequence 1 sedimentary rocks of the Centralian Superbasin has permitted biostratigraphic
correlations between outcrop and well data The Acaciella australica assemblage appears to be
slightly older than 800 Ma and is restricted to the middle part of Supersequence 1 The Baicalia
burra assemblage is considered to be slightly younger than 800 Ma and occurs in the upper part
of Supersequence 1 (Grey 1996b Stevens and Grey 1997) The older A australica assemblage
is recognized in the Skates Hills Formation in the Savory Sub-basin and the stromatolite A
australica itself has been tentatively identified in the lower Tarcunyah Group The occurrence of
the A australica assemblage in the Woolnough Madley and Browne Formations of the Officer
Basin and in the Loves Creek Member of the Bitter Springs Formation of the Amadeus Basin
allows correlations throughout the Centralian Superbasin (Fig 4)
The younger B burra assemblage has not been recognized in sedimentary rocks of the
Savory Group as defined by Williams (1992) but it occurs in the upper parts of the Tarcunyah
Group and allows correlation of this group with outcrops of the Neale Formation and with the
Kanpa Formation in petroleum exploration well Hussar 1 both located in the central Officer Basin
of Western Australia (Fig 4) (Grey 1996b Stevens and Grey 1997) The occurrence of the B
burra assemblage in these units permits their correlation with the Burra Group in the Adelaide
Geosyncline of South Australia (K Grey unpublished data)
The Cornelia Formation and Kahrban Subgroup outcrop in the southeast of the sub-basin and
were considered by Williams (1992) to be part of the Mesoproterozoic Bangemall Basin Limited
evidence suggests that all or parts of these two units are of Neoproterozoic age The Ward and
Oldham Inliers consist of outcrops of the Cornelia Formation Waterbore TWB 6 which was
drilled on TRAINOR in the Cornelia Formation contains palynomorphs consistent with a
Supersequence 1 age (Grey and Stevens 1997) (Figs 5 and 6) In outcrop the Cornelia Formation
17
consists predominantly of sandstone and quartzite with lesser siltstone shale mudstone and chert
In Trainor 1 this formation consists predominantly of indurated mudstone with minor sandstone
chert and dolomite A major erosional unconformity separates the Cornelia Formation from
overlying formations and parts of the Cornelia Formation have been folded with dips exceeding
70deg In contrast the majority of the Savory Sub-basin sedimentary rocks have dips of less than 30deg
except where they are adjacent to faults The Cornelia Formation apparently consists of an older
unit of steeply dipping quartzites cherts and well-indurated mudstones and a younger unit of
shallower dipping sandstones which are sub-friable in parts However caution should be used in
interpreting the age of units based on their structural deformation and additional mapping and age
dating of this formation is required
It is proposed here that the Kahrban Subgroup is likely to be of early Neoproterozoic age and
hence should be considered as part of the greater Officer Basin This proposal is based largely on
the relatively low dip of the strata (generally less than 20deg) and their west-northwest strike which
is parallel with strikes in the overlying Brassey Range Formation of the Savory Group The lower
contact of the Kahrban Subgroup is obscured but is thought to be an unconfirmity on the
Earaheedy Basin on the southeast of STANLEY (Muhling and Brakel 1985)
Structural setting
The Savory Sub-basin forms the most northwesterly sub-basin of the Neoproterozoic to
Phanerozoic Officer Basin The western boundary of the sub-basin with the Mesoproterozoic
Bangemall Basin consists of steep-reverse and strike-slip faults The northeastern boundary of the
Savory Sub-basin was mapped where Supersequence 4 formations of the Savory Group
unconformably overlie sedimentary rocks of the Karara and Yeneena Basins with the two older
units considered to be part of the Paterson Orogen (Williams 1992) This contact was defined as a
series of steeply dipping reverse faults in the northernmost parts of the sub-basin on BALFOUR
DOWNS and RUDALL and was extrapolated as an inferred reverse fault farther along strike to the
southeast on GUNANYA and MADLEY where the contact is obscured by Cainozoic sediments It is
now recognized that all the sedimentary rocks in the Karara Basin and younger sedimentary rocks
of the Yeneena Basin are from the Supersequence 1 Tarcunyah Group and part of the greater
Officer Basin (Bagas et al 1995) The northern boundary of the Tarcunyah Group and the greater
Officer Basin is in thrust-and reverse-faulted contact with the Rudall Complex and other parts of
the Paterson Orogen (Fig 7)
To the south the sub-basin unconformably overlies the Bangemall Basin The eastern
boundary of the sub-basin used in this study is where Permian and younger strata of the Officer
Basin unconformably overlie Neoproterozoic strata although there are no significant structural or
stratigraphic differences between the Neoproterozoic units
18
The sub-basin is subdivided into three principal structural areas (Fig 1) Trainor Platform
Blake Fault and Fold Belt and Wells Foreland Sub-basin (Williams 1992) A major review of
these boundaries is beyond the scope of this report but the processing of regional aeromagnetic
data (Appendix 4) and acquisition of a semi-detailed gravity survey by the GSWA in the east of
the sub-basin has enabled these tectonic units to be reassessed and some modifications are
proposed
The Wells Foreland Sub-basin (originally termed the Wells Foreland Basin in Williams 1992)
and sedimentary rocks of the Tarcunyah Group are both considered to be the northwest
continuation of the Gibson Sub-basin of the Officer Basin Aeromagnetic gravity and outcrop
data suggest that the Blake Fault and Fold Belt is significantly faulted and folded in the west but
is less deformed in the east where the thickest sedimentary section in is located on BULLEN
(Appendix 4) The Trainor Platform is reinterpreted to represent an area of the sub-basin that has
undergone major compression during the Petermann Ranges Orogeny resulting in folding and
faulting with a northwest strike This interpretation contrasts with that proposed by Williams
(1992) who envisaged that only a thin section of the Savory Group was present on the platform
Perincek (1998) has recognized nine periods of tectonic activity in the Officer Basin from the
beginning of the Neoproterozoic to the end of the Cretaceous Three major tectonic episodes are
recognized in the Centralian Superbasin The oldest event is the Areyonga Movement which is
pre-Sturtian and forms the boundary between Supersequences 1 and 2 (Fig 4) The Souths Range
Movement occurred at the end of the Sturtian at the boundary between Supersequences 2 and 3
The youngest major event is the Petermann Ranges Orogeny which occured at the end of the
Marinoan and forms the boundary between Supersequences 3 and 4
One minor and two major tectonic episodes are recognized in the Savory Sub-basin the
LP1ALP1B structural event and the Areyonga Movement and the Petermann Ranges Orogeny
respectively The LP1ALP1B structural event is revealed where the Spearhole Formations rests
disconformably and locally unconformably on the Brassey Range Jilyili and Glass Spring
Formations The Neoproterozoic Areyonga Movement (equivalent to the Blake Movement of
Williams 1992) produced folds and faults with a general northeast strike in the western and
southern parts of the region The Souths Range Movement has not been recognized in the sub-
basin This may be due to the fact that no Sturtian glacial rocks have been identified and hence it
is possible that structures attributed to the Areyonga Movement could be the result of the Souths
Range Movement or a combination of the two movements
The major tectonic event recorded in the sub-basin is the latest Neoproterozoic to Cambrian
Petermann Ranges Orogeny (equivalent to the Paterson Orogeny) which produced large reverse
19
faults thrusts strike-slip faults and folds with a general northwest strike The McFadden
Formation and other Supersequence 4 strata are considered to be at least partially coeval with this
orogeny (Williams 1992) We also interpret the Durba Sandstone as having been deposited during
the later stages of the Petermann Ranges Orogeny as this unit mildly deformed with fold axes
parallel to the strike of other structures attributed to the Petermann Ranges Orogeny
Quantitative aeromagnetic interpretation of the Savory Sub-basin utilizing the 3D Euler
deconvolution method supported by wave-number filtering and image processing has provided
structural trends and depth to magnetic source within the sub-basin (Cowan 1995) Gravity data
are interpreted by Cowan (1995) as changes in both the density of the basement rocks andor
basement topography depending on local conditions Part of Cowanrsquos report is reproduced in
Appendix 4
Exploration history
The only petroleum exploration conducted in the sub-basin has been the recent drilling in the
western part of three diamond drillholes of which two have minor oil shows (Table 2) There has
been some mineral exploration the results of which are stored in the GSWA Western Australian
Mineral Exploration (WAMEX) database system Much of the mineral exploration was in the
southwest and west where the sub-basin is in contact with the Bangemall Basin and along the
northern margin of the sub-basin Many of these mineral exploration programs included
aeromagnetic surveys and surface geochemical sampling (Fig 8)
Hydrocarbon potential
The sub-basin contains a sedimentary succession up to 8 km thick which is generally gently
folded and faulted and apparently unmetamorphosed Limited drilling has shown that thick
mudstones are present in the sub-basin with some mudstones in Trainor 1 having high Total
Organic Carbon (TOC) values Outcrops of sub-friable sandstones in many of the formations
within the sub-basin suggests widespread reservoir potential Mudstone and inferred thick
evaporite sequences are likely to form seals Maturity data suggest that near-surface samples are
approximately at the base of the oil window and top of the gas window in parts of the north and
southeast of the sub-basin However parts of the southwest of the sub-basin and the mudstones in
Trainor 1 have very high levels of maturity Numerous faults and folds have been identified from
surface mapping suggesting good potential for large structural traps Minor oil shows in
20
Table 2 Neoproterozoic formations and hydrocarbon shows in diamond drillholes in the Savory Sub-basin
Drillhole AMG Core TD (m) Approx Formation Depth Formation Depth Formation Depth Shows (AGD84) start (m) GL (m) (m) (m) (m)
LDDH 1 431148E 112 701 350 Tarcunyah 68ndash701 ndash ndash bitumen at 6623 m 7443826N Group Trainor 1 473640E 6 709 455 McFadden 9ndash83 Cornelia Fm 83ndash709 possible bitumen at 4537 m 7287400N Fm Mundadjini 1 319056E 170 600 500 Mundadjini 16ndash361 Spearhole Fm 361ndash600 10 fluorescence at 36102 m 7404844N Fm Boondawari 1 348959E 299 1 367 490 Mundadjini Fm 15ndash312 Spearhole Fm 312ndash1 283 Intrusive 1 283ndash1 367 40 fluorescence at 35364 m 5 7398174N fluorescence at 4963 m Akubra 1 334249E 15 181 530 Mundadjini 15ndash42 Intrusive 42ndash181 None 7401252N Fm
21
50 km
120deg 121deg30 123deg
25deg
24deg
23deg
22deg
Greater Officer Basin
Savory Sub-basin
1
2
3
4
6
8
3 Seismic line (prefixed N83-00)
Aeromagnetic survey
GS
WA
Sav
ory
1995
gra
vity
sur
vey
Gravity survey
MKS34270398
Figure 8 Locations of aeromagnetic and gravity surveys (other than regional BMRAGSO data)
22
sandstones in two petroleum wells in the northwest of the sub-basin and bitumen and oil shows
elsewhere in the region indicate that oil has been generated and migrated through the sub-basin
Source rocks
Source potential is considered to be the major exploration risk in the Savory Sub-basin although
minor oil shows in Mundadjini 1 and Boondawari 1 indicate that at least some oil has been
generated and migrated into potential reservoirs within the sub-basin Sandstone is the
predominant lithology observed in outcrop Outcrops of fine-grained lithologies in the basin are
rare because of intense surface weathering and erosion Only about 8 of the surface area of the
sub-basin is exposed bedrock and recessive lithologies (such as shale evaporite and friable
sandstone) may be present although they rarely outcrop
Outcrops of stromatolitic dolomite with associated cauliflower chert and cubic pseudomorphs
interpreted as being after halite indicate that evaporitic environments are present within the
Mundadjini Skates Hills and Boondawari Formations Evaporitic minerals are also present in
drillhole LDDH1 in the Tarcunyah Group
In 1995 GSWA drilled a continuous-core diamond drillhole (Trainor 1) in the sub-basin on
TRAINOR to a depth of 709 m to test for source rocks thus providing the first such data for the sub-
basin The drillhole intersected flat-lying clastics and carbonates of the McFadden Formation (9ndash
83 m) overlying indurated mudstones of the Cornelia Formation (83ndash709 m total depth) dipping at
about 40deg Of the six samples analysed from the Cornelia Formation in this drillhole the five
located between 375 and 6032 m depth have TOC values exceeding 05 (range 066ndash365)
Rock-Eval pyrolysis of these five samples indicates that they are at best in the dry-gas thermal
stage and as a result of their high level of maturation (Stevens and Adamides in prep) have poor
remaining hydrocarbon-generating potential Although the Cornelia Formation is overmature at
Trainor 1 the high TOC values are encouraging as it is likely that this sequence is less mature
elsewhere in the sub-basin
The Mundadjini Formation contains potential source rocks that comprise marine mudstones
with evaporitic minerals present in parts Thin dark mudstones were intersected in the Mundadjini
Formation in Akubra 1 In Mundadjini 1 and Boondawari 1 however the mudstones appear to be
too oxidized to have source potential
The Boondawari Formation also may be a source rock as it contains black mudstones The
unit is laterally equivalent to the Pertatataka Formation of the Amadeus Basin and the Ungoolya
23
Group of the Officer Basin in South Australia both of which have some source potential
(Summons and Powell 1991 Morton and Drexel 1997) Samples from the Dey Dey Mudstone of
the Ungoolya Group generally have poor TOC values (average 011 range 003ndash081)
moderate hydrogen index (HI) values (100ndash382) and poor to fair genetic potential with a
maximum of 292 kg hydrocarbon per tonne of source rock (Morton and Drexel 1997)
Stromatolitic dolomites and mudstones at the top of the Boondawari Formation and within the
Skates Hills Formation are potential source rocks Stromatolitic dolomite and evaporitic rocks
deposited in a marginal marine to sabkha environment are considered to have good potential to
generate and preserve organic carbon without requiring a deep-water setting (Stevens and Grey
1997) Such conditions are recognized in the Skates Hills Formation and in the upper parts of the
Tarcunyah Group
Maturity
Knowledge of the maturity of sedimentary rocks within the Savory Sub-basin is still limited From
a review of palynological studies Grey and Stevens (1997) report that the thermal maturity
inferred from the Thermal Alteration Index (TAI) of 3+ from Supersequence 1 age palynomorphs
in TWB 6 TWB 9 and LDDH1 is within the hydrocarbon window (Appendix 3) In Phanerozoic
spores and pollen a TAI of 3+ approximately equates to the end of liquid petroleum generation
and the start of dry gas generation and to a vitrinite reflectance of about 13 (Traverse 1988)
However the use of TAI for estimating thermal maturity from Neoproterozoic palynomorphs
requires calibration
In Trainor 1 the Cornelia Formation contains organically rich claystones between 375 and
6032 m depth Based on Rock-Eval maturity data (Stevens and Adamides in prep) and the dark
colour of poorly preserved organic material (Grey 1995de 1996) with TAI 4- to 5 all samples
had a high level of maturation with at best dry-gas generating potential remaining In contrast
drillhole LDDH1 on GUNANYA recorded lower levels of maturity (TAI values of 3+) with two of
sixteen samples from the Tarcunyah Group having greater than 1 TOC (Grey 1995abc Grey
and Cotter 1996) Organic petrology and Rock-Eval maturity data for samples from LDDH1
indicate that the section above 500 m is within the oil-generative window whereas below 500 m
the rocks are within the gas window (Ghori in prep Fig 9 Appendix 5)
Waterbores TWB 1 2 6 and 9 which are located on TRAINOR in the southeast of the sub-
basin all had organic matter with TAI values of 3+ from the McFadden Skates Hills Cornelia
and Brassey Range Formations respectively
24
100
200
300
400
500
600
700
Oil
gene
ratin
g
Gas
gene
ratin
g
Fai
r
Fai
r
Poo
r
Poo
r
Goo
d
Imm
atur
e
Oil
win
dow
Oil
win
dow
Imm
atur
e
01 0110 10 0 150 300 440 480 1
Neo
prot
eroz
oic
TOC S1+S2 mgg Hydrogen Index Tmax degC
Depth(m)
Organicrichness
Generatingpotential
Kerogentype Maturity Maturity
TD=701m
Sandstone
Mudstone
Dolomite
Limestone
Evaporite
Source rock
MKS40 070498
Ro equivalent
Figure 9 Petroleum source potential of rocks in Normandy LDDH1
Small amounts of organic matter associated with basalt and dolerite in cuttings from
waterbore BWB 1 on BULLEN showed high levels of thermal maturity (Grey 1995a Libby 1995)
It is unclear whether all sedimentary rocks on BULLEN are overmature for hydrocarbon generation
or the results from BWB 1 are related to local heating events associated with the volcanic bodies
that are common in the Jilyili Formation
25
Reservoirs
Each of the five depositional sequences of the Savory Group (Table 1) are inferred to contain
significant sandstone reservoirs with the possible exception of depositional sequence C as
discussed above in Stratigraphy The Spearhole Formation was cored in Mundadjini 1 and
Boondawari 1 and visual estimates of porosity vary from generally poor (less than 5) to fair
(approximately 5ndash15) The McFadden Formation in Trainor 1 has porosity values of up to 232
and a maximum permeability of 195 md (Stevens and Adamides in prep) Sandstones from
Neoproterozoic formations form the acquifers in the following waterbores the McFadden
Formation in TWB 1 the Cornelia Formation in TWB 6 and the Brassey Range Formation in
TWB 8 and TWB 9 (Appendix 6 Table 61)
Based on outcrop observations the Durba Sandstone is considered to be the best reservoir of
the Savory Group Similarly some sandstones from the Tarcunyah Group also have good visible
porosity in outcrop
Dolomites occur in several formations in the sub-basin Reservoir potential may exist
particularly where the dolomites are stromatolitic and oolitic However dolomites have not been
drilled in the sub-basin and porosity can only be inferred from the preferential silicification of
some stromatolite bioherms observed in outcrop (Stevens and Grey 1997) Elsewhere in the
Officer Basin porosities of up to10 have been measured in dolomites A limestone breccia
(karst) is described from 663 to 677 m in drillhole LDDH1 (Fig 6 Busbridge 1994)
Seals
Indications of evaporitic environments in the Mundadjini Skates Hills and Boondawari
Formations are described by Williams (1992) In Mundadjini 1 from 287 to 337 m anhydrite and
chert occurs as nodules beds and veins in mudstone of the Mundadjini Formation Evaporitic
minerals (predominantly gypsum) are described in the Tarcunyah Group in LDDH1 The presence
of the Woolnough and Madley salt diapirs in the Officer Basin (approximately 110 km east of the
sub-basin) and halite beds over 25 m thick in the well Hussar 1 (130 km east of the sub-basin)
provide further evidence that evaporite seals may be present in the Savory Sub-basin
Mudstones and shales form only a small proportion of the limited Neoproterozoic outcrop in
the sub-basin but significant thicknesses of mudstone were encountered in the Mundadjini
Formation in Mundadjini 1 and Boondawari 1 the Tarcunyah Group in LDDH1 and in the
26
Cornelia Formation in Trainor 1 These data suggest that mudstones form a significant proportion
of strata in the sub-basin despite their limited outcrop
Traps
Potential structural closures including folds and faults occur at various scales throughout the
Savory Sub-basin However the region has only been mapped at 1250 000 scale and
independently closed structures such as domes have yet to be confirmed The western margin of
the basin contains abundant faults (with a northeast strike) but elsewhere faults are less common
Some anticlines are recognized in outcrop including one with a strike length of up to 45 km
inferred from surface bedding dips in the Mundadjini and Spearhole Formations at approximately
24deg15rsquoS 121deg10rsquoE on BULLEN (Fig 1)
Salt diapirs and other halokinetic structures are recognized in outcrop well and seismic data
in the Officer Basin to the west of the Savory Sub-basin and it is probable that there are
significant thicknesses of evaporitic sedimentary rocks in the sub-basin The gravity field data
suggest there is good potential for salt diapirs and traps related to halokinesis
Although there is potential for stratigraphic traps to be present in the sub-basin insufficient
data are available to assess them
Preservation of hydrocarbons
The range of thermal maturities measured to date and the large periods of time envisaged for
deposition of sediments implies hydrocarbon generation may have occurred a number of times
during the evolution of the Savory Sub-basin Any hydrocarbons that were generated early may
have been trapped in palaeostructures and remigration to younger traps could have taken place
later The Petermann Ranges Orogeny which has been equated with the Paterson Orogeny (Myers
1990) is believed to have occurred in the latest Neoproterozoic to early Cambrian This is the last
major tectonic event recognized in the sub-basin suggesting that it is reasonable to expect that trap
integrity will have been preserved
If the inference of the presence of thick halite beds in the sub-basin is correct the preservation
potential of sub-salt traps should be excellent
27
Reported hydrocarbon shows and oil seep
Amadeus Petroleum recorded minor oil shows in cores from Mundadjini 1 and Boondawari 1 In
Mundadjini 1 at 36102 m (top of the Spearhole Formation) a 3 mm thick zone had 10 moderate
white fluorescence with slow solvent cut This show was in a granular sandstone with visually
estimated porosity of about 10 In Boondawari 1 at 35364 m (within the Spearhole Formation) a
broken surface of sandstone had 40 moderate yellow-white fluorescence with slow solvent cut
Visually estimated porosity is about 5 Because the fluorescing surface was broken during the
drilling process this show could have resulted from contamination A second show occurs in
Boondawari 1 at 4963 m (within the Spearhole Formation) where a 1 cm-thick zone had 5 dull
yellow fluorescence with slow solvent cut in a conglomerate with visually estimated porosity of
about 10 The company intends to further investigate the nature of these occurrences
Minor bitumen is present at 6623 m in drillhole LDDH1 on GUNANYA (Figs 5 and 6) as a
vein in mudstones of the Tarcunyah Group A sample was analysed by gas chromatography
(Ghori in prep) and confirmed that it is natural bitumen (Appendix 5)
Mineral hole OD 23 drilled by Jubilee Gold Mines NL on NABBERU in the Bangemall Basin
immediately to the south of the Savory Sub-basin (Fig 5) encountered bitumen and trace oil in
vugs in dolomite (M Stevens unpublished data) but no further data are available at present
In their popular guide to the Canning Stock Route Gard and Gard (1990 p 218) refer to an
oil seep at Well 13 on TRAINOR (Fig 5) They reported that between 1977 and 1984 lsquonatural oilrsquo
was seen in the well Although the well is now largely filled with sediment four auger drill
samples were collected by the GSWA in 1995 and all four were analysed for oil shows One
sample from 315 m total depth (GSWA sample 135604) yielded just enough extract (519 ppm)
for saturate gas chromatography analysis The gas chromatograph (Appendix 5) shows that the
extract does contain some hydrocarbons probably from recent plant material Because the depth to
the oil was not quoted in Gard and Gard (1990) the hand-augered well may not have been deep
enough to properly test this reported seep
Geological and geophysical databases
Geological and geophysical data available for the Savory Sub-basin are limited The most recently
completed geological maps for the sub-basin were published by the GSWA between 1991 and
1995 (Williams and Tyler 1991 Williams 1992 1995ab)
28
The cores from the five drillholes listed in Table 2 believed to be all of the core available
from the sub-basin are available for inspection at GSWA Mineral exploration reports submitted
to GSWA may be searched using the WAMEX database and open-file reports are available on
microfiche Geophysical data acquired by the mining industry is not required to be filed with
GSWA if acquired over Vacant Crown Land which is the case for much of the sub-basin
Geophysical survey data submitted in mining tenement reports and which extend into Vacant
Crown Land remain confidential to the companies Original regional aeromagnetic and gravity
datasets are available from the Australian Geological Survey Organisation (AGSO)
Data pertinent to oil exploration in the sub-basin such as structural style and salt diapirism
are presented in a review of the hydrocarbon prospectivity of the Officer Basin (Perincek 1998)
Drilling
Significant drillholes in the sub-basin are summarized in Table 2
Petroleum industry data
Amadeus Petroleum drilled three petroleum exploration wells in the central west of the Savory
Sub-basin in late 1997 These wells Mundadjini 1 Boondawari 1 and Akubra 1 were drilled by
continuous diamond coring (Figs 5 and 6) All targeted potential reservoirs within the Spearhole
Formation with the Mundadjini Formation as the proposed seal The wells were located on
structures interpreted from Landsat images and limited geological investigations Both Mundadjini
1 and Boondawari 1 had minor oil shows as discussed above (Reported hydrocarbon shows)
Government data
Stratigraphic drillhole Trainor 1 was drilled by GSWA in 1995 (Stevens and Adamides in prep)
and the main results are discussed above (Source rocks and Maturity)
Mineral industry data
Normandy Exploration drillhole LDDH1 was cored in the Tarcunyah Group to a total depth of
701 m and provided source-rock and maturity data as discussed above
29
Oilmin NL drilled six percussion drillholes (BD 1 3 4 5 8 and 9) through sandstones and
shales in the northern part of the Savory Sub-basin to a maximum depth of 198 m (Fig 5
WAMEX Microfiche File M 26811 I 2610) but only brief geological descriptions are available
Hydrogeological data
Hydrogeological data within the Savory Sub-basin are limited although a long history of water
exploration extends back to the construction of the Canning Stock Route early this century No
detailed geological or wireline logs are available for the older wells along this route A few station
wells have been drilled by various methods on the south and west margins of the basin but data
are unavailable as reports are not required to be filed with the government Depth to watertable
throughout the basin is largely controlled by porosity of the bedrock
The GSWA drilled fifteen waterbores in the winter of 1995 in the southern part of the sub-
basin in preparation for the drilling of Trainor 1 and the proposed Bullen 1 Twelve bores found
water and six of these bores have salinities of less than 1000 mgL (Fig 5 Appendix 6 Table 61)
One waterbore TWB 6 has gamma ray and neutron logs run through PVC casing and these are
available from the GSWA with the digital log data included herein
Seismic data
No geophysical data have been acquired by the petroleum industry in the Savory Sub-basin
Seismic data acquired in the Officer Basin to the east particularly in the Gibson and Yowalga
Sub-basins is pertinent to structural interpretation in the Savory Sub-basin (Perincek 1996a
1998)
Aeromagnetic surveys
Government data
There are over 95 277 line kilometres of aeromagnetic data included in the AGSO dataset There
are three regional aeromagnetic surveys covering the Savory Sub-basin These were flown by the
Bureau of Mineral Resources (BMR now AGSO) in 1984 at a line spacing of 1500 m with 36 740
and 52 587 line kilometres flown and by Aerodata in 1984 at a line spacing of 1000m with 5950
line kilometres flown These data were reprocessed and interpreted for GSWA by Cowan (1995)
An edited copy of this report is included as Appendix 4 and the original report is filed in the
GSWA Library under S-series reports item 10331
30
Mineral industry data
The approximate locations of non-AGSO aeromagnetic surveys are shown in Figure 8 More
detailed information regarding the location of these surveys may be obtained using the GSWA
MAGCAT II database Additional information such as contours of aeromagnetic values may be
obtained by inspecting items on file with the GSWA
Gravity surveys
Government data
The average spacing for gravity data in the Savory Sub-basin is one station per 121 km2 (11 times 11
km grid) These data were principally collected by BMR in the early 1960s There are a few
additional regional gravity traverses across the sub-basin which are also included in the
BMRAGSO dataset These data were reprocessed and interpreted for GSWA (Fig 10) and a
report on this work is also included in Appendix 4
The GSWA completed a large semi-detailed gravity survey in the eastern Savory Sub-basin
utilizing helicopter support and Differential Global Positioning Survey (DGPS) techniques (Fig
8) This gravity survey completed in August 1995 consists of 2300 gravity stations on a 2 times 3 km
grid All stations were acquired by helicopter using Scintrex gravimeters and Ashtek dual
frequency DGPS equipment for determining location This highly efficient system allowed the
acquisition of more than 100 gravity stations per day in remote areas The resolution of this survey
is +30 cm and +05 microms-2 (Daishsat 1995) These data (Fig 11) represent a significant
improvement on the previous regional survey data and are available from GSWA (GSWA
1996ab) The results of the interpretation of these data were presented at the 1997 ASEG
Convention (Carlsen and Shevchenko 1997)
Mineral industry data
Three small gravity surveys were conducted by Oilmin NL (Fig 8) and the relevant WAMEX
reports are M 2681I 2610 I 2435 I 2567 These three surveys are of limited value because height
control was provided by barometers only and the surveys were not tied to the national gravity grid
31
23deg
25deg
120deg 122deg
Trainor 1
SAVORY
SUB-BASIN
MKS54 160498
100 km
1995 SavoryGravity Survey
254
-1056
micromsec2
Figure 10 Regional Bouguer gravity map of the Savory Sub-basin
23deg
24deg
25deg
122deg30 123deg
TRAINOR 1
123deg30
50 km
MKS53 160498
-116
-626
micro msec2
Figure11 Detailed Bouguer gravity map of the
Savory 1995 Gravity Survey from the eastern Savory Sub-basin
32
Government and academic reports
Chronostratigraphy and geochemistry
The understanding of Neoproterozoic organic chemistry palynology and structural evolution is
essential to the interpretation of hydrocarbon prospectivity Pertinent reports are included in the
bibliography (Appendix 1) Unpublished palaeontology reports describe the palynology of wells in
the Savory Sub-basin (Grey 1995andashe 1996a) Grey and Cotter (1996) discussed the potential for
Neoproterozoic palynomorphs to provide a biostratigraphic framework and palaeoenvironmental
interpretation Grey and Stevens (1997) reviewed the results of palynological studies of wells
drilled in the sub-basin and reported that Supersequence 1 palynomorphs are present in TWB 6
TWB 9 and LDDH1 (Appendix 3) Grey (1996b) reported on the use of stromatolites for
correlation in the Neoproterozoic and Stevens and Grey (1997) discussed the application of
stromatolite biostratigraphy in correlating isolated dolomite outcrops in the sub-basin with well
and seismic data in the Officer Basin and Centralian Superbasin
Although geochemical data from the Savory Sub-basin are very limited results mostly
confirm thermal maturities inferred from TAI for LDDH1 and Trainor 1 (Ghori in prep Stevens
and Adamides in prep) Those parts of the Officer Basin in Western Australia which lie to the
east of the Savory Sub-basin are sparsely drilled but Ghori (in prep) reports that most of the
Neoproterozoic succession presently lies within the oil-generative window However his study
has been unable to identify effective source-rock units and the source for oil shows Thin source
rocks are present in the Neoproterozoic in LDDH1 (Fig 9) and in three wells which lie to the east
and southeast of the Savory Sub-basin namely NJD 1 Kanpa 1A and Yowalga 3
Proposed work program
From the above limited information it is concluded that additional research on the hydrocarbon
potential of the sub-basin is justified and proposals are outlined below
bull Additional modelling of gravity and aeromagnetic data from the Savory Sub-basin is required
in light of the results from Trainor 1 and Boondawari 1 Trainor 1 showed that what appeared
to be a structurally simple area based on outcrop aeromagnetic and gravity data was in fact an
area of major structuring Boondawari 1 intersected a dolerite which is in good depth
agreement with aeromagnetic depth to source results showing this technique is useful in
detecting the depth to intrusive bodies
33
bull Additional data from mineral and petroleum exploration bores may become available and
analysis of samples from these wells should be undertaken and interpreted in the context of
their relevance to the Officer Basin
bull Stratigraphic coring in the Blake Fault and Fold Belt and in the Wells Foreland Sub-basin (Fig
1) targeting source rocks is considered essential to the continuing evaluation of the
hydrocarbon prospectivity of the Savory Sub-basin
bull Correlations using at least outcrop well and potential-field data should be prepared to link the
sub-basin with the better known parts of the Officer Basin to the east
bull Remapping is required to clarify boundary positions within the Cornelia Formation this may
resolve some of the current problems of the relationship between this unit and the rest of the
Savory Sub-basin
bull Further work is required to explain the Early Cambrian or Sturtian ages interpreted for the
Cornelia Formation from sedimentary zircon UndashPb dating in drillhole Trainor 1 The
determination of the age of the organically rich but overmature claystones in this well is
critical to assessing the hydrocarbon potential of the region
bull The thin dark mudstones intersected by Akubra 1 in the Mundadjini Formation warrant
geochemical analysis Analyses of the oil shows in Mundadjini 1 and Boondawari 1 are
currently being undertaken by Amadeus Petroleum
bull Geochemical analysis of hydrocarbons in the Bangemall Basin drillhole OD23 has been
performed by Jubilee Gold and the results will be reviewed when they are submitted to
GSWA The possibility of source rocks within the Bangemall Basin charging traps within the
Bangemall Basin and the overlying Savory Sub-basin requires further investigation
Conclusions
The Savory Sub-basin is a frontier region with only three recently drilled petroleum exploration
wells and no seismic data Based on existing geological and geophysical data it is considered too
early to draw conclusions about the hydrocarbon prospectivity of the sub-basin at this stage and
there are several reasons why the area warrants further investigation
34
1 Thick accumulations of sedimentary rocks are present (up to 8 km thickness inferred) which
may contain source reservoir and sealing strata
2 Minor oil shows occur in Mundadjini 1 and Boondawari 1 and bitumen is present in mineral
exploration drillhole LDDH1 suggesting that hydrocarbons have migrated within the
Neoproterozoic sequence of the Savory Sub-basin Oil and bitumen are present in mineral
exploration drillhole OD23 in the Bangemall Basin immediately to the south of the Savory
Sub-basin and it is possible that source rocks from the Bangemall Basin could charge traps in
the overlying Savory Sub-basin
3 The age of sedimentary rocks in the sub-basin is still poorly constrained but some of the
Neoproterozoic sedimentary rocks located on GUNANYA and TRAINOR are within the
hydrocarbon-generation window It is possible that a significant thickness of Phanerozoic
sedimentary rocks may also be present
4 Friable sandstones with visible porosity outcrop extensively suggesting numerous potential
reservoirs
5 Significant but not intense faulting and folding has been mapped implying large structural
traps may be present
6 Evaporitic sedimentary rocks occur in several formations and may provide good source rocks
and excellent seals
35
References
APAK S N and CARLSEN G M 1997 A compilation and review of data pertaining to the
hydrocarbon prospectivity of the Canning Basin Western Australia Geological Survey
Record 199610 103p
BAGAS L GREY K and WILLIAMS I R 1995 Reappraisal of the Paterson Orogen and
Savory Basin Western Australia Geological Survey Annual Review 1994ndash95 p 55ndash63
BUSBRIDGE M 1994 Lake Disappointment Exploration Licence 451064 Third Annual
Report Lake Disappointment Diamond Drill Hole LDDH1 Normandy Exploration Limited
Western Australia Geological Survey M-series Item 7567 A41358 (unpublished)
CARLSEN G M and SHEVCHENKO S I 1997 Petroleum exploration in Proterozoic basins
using potential fields data and stratigraphic coring Australian Society of Exploration
Geophysicists 12th Geophysical Conference Handbook Sydney 1997 Preview no 66 p 83
(abstract only)
COWAN D 1995 Savory Basin quantitative magnetic interpretation Western Australia
Geological Survey S-series S10331 (unpublished)
DAISHSAT PTY LTD 1995 Operational and processing report Savory Basin gravity survey
Western Australia Geological Survey S-series S10332 (unpublished)
GARD E and GARD R 1990 Canning Stock Route a travellerrsquos guide for a journey through
history Perth Western Australia Western Desert Guides 448p
GEOLOGICAL SURVEY OF WESTERN AUSTRALIA 1996a Savory Basin first vertical
derivative of Bouguer gravity image 1250 000 Western Australia Geological Survey
GEOLOGICAL SURVEY OF WESTERN AUSTRALIA 1996b Savory Basin Bouguer gravity
image 1250 000 Western Australia Geological Survey
GHORI K A R in prep Petroleum source rock potential and thermal history Officer Basin
Western Australia Western Australia Geological Survey Record
36
GREY K 1995a Savory Basin drillhole BWB 1 (Bullen waterbore) palynology and thermal
maturation GSWA Palaeontology Report no 199512 (unpublished)
GREY K 1995b Savory Basin drillholes TWB 1 2 6 9 (Trainor waterbores) palynology and
thermal maturation GSWA Palaeontology Report no 199520 (unpublished)
GREY K 1995c Palynology of Normandy-Poseidon Lake Disappointment-1 corehole
Tarcunyah Group Paterson Orogen GSWA Palaeontology Report no 199521 (unpublished)
GREY K 1995d Savory Basin drillhole Trainor 1 (Trainor diamond drilling) palynology and
thermal maturity GSWA Palaeontology Report no 199524 (unpublished)
GREY K 1995e Savory Basin drillhole Trainor 1 (Trainor diamond drilling) Additional
Preparation of two samples GSWA Palaeontology Report no 199528 (unpublished)
GREY K 1995f Neoproterozoic stromatolites from the Skates Hills Formation Savory Basin
Western Australia and a review of the distribution of Acaciella australica Australian Journal
of Earth Sciences v 42 p 123ndash132
GREY K 1996a Savory Basin drillhole Trainor 1 (Trainor diamond drilling) Additional
samples palynology and thermal maturation GSWA Palaeontology Report no 199615
(unpublished)
GREY K 1996b Preliminary stromatolite correlations for the Neoproterozoic of the Officer
Basin and a review of Australia-wide correlations GSWA Palaeontology Report no 199615
(unpublished)
GREY K and COTTER K L 1996 Palynology in the search for Proterozoic hydrocarbons
Western Australia Geological Survey Annual Review for 1995ndash96 p 70ndash80
GREY K and STEVENS M K 1997 Neoproterozoic palynomorphs of the Savory Sub-basin
Western Australia and their relevance to petroleum exploration Western Australia
Geological Survey Annual Review for 1996ndash97 p 49ndash54
HUBBARD R J PAPE J and ROBERTS D G 1985 Depositional sequence mapping as a
technique to establish tectonic and stratigraphic framework and evaluate hydrocarbon
potential on a passive continental margin in Seismic stratigraphy II an integrated approach
37
edited by O R BERG and D G WOOLVERTON American Association of Petroleum
Geologists Memoir 39 p 79ndash91
LIBBY WG 1995 A petrological report on six samples of bore cuttings from the Savory Basin
Western Australia Western Australia Geological Survey S-series S31307 (unpublished)
MORTON JGG and DREXEL JF 1997 The petroleum geology of South Australia Vol 3
Officer Basin South Australia Department of Mines and Energy Resources Report Book
9719
MUHLING P C and BRAKEL A T 1985 Geology of the Bangemall Group mdash the evolution
of an intracratonic Proterozoic basin Western Australia Geological Survey Bulletin 128
219p
MYERS J S 1990 Precambrian tectonic evolution of part of Gondwana southwestern Australia
Geology v18 p 537ndash540
NELSON D R 1997 Compilation of SHRIMP UndashPb zircon data Western Australia Geological
Survey Record 19972 196p
PAYTON C E 1977 Seismic stratigraphy mdash applications to hydrocarbon exploration
American Association of Petroleum Geologists Memoir 26 516p
PERINCEK D 1996a The age of NeoproterozoicndashPalaeozoic sediments within the Officer Basin
of the Centralian Super-basin can be constrained by major sequence-bounding unconformities
APPEA Journal v 36 pt 1 p 350ndash368
PERINCEK D 1996b The stratigraphic and structural development of the Officer Basin
Western Australia a review Western Australia Geological Survey Annual Review 1995ndash
1996 p 135ndash148
PERINCEK D 1998 A compilation and review of data pertaining to the hydrocarbon
prospectivity of the Officer Basin Western Australia Geological Survey Record 19976
POSAMENTIER H W JERSEY M T and VAIL P R 1988 Eustatic controls on clastic
deposition 1 mdash Conceptual framework in Sea-level changes an integrated approach edited by
C K WILGUS B S HASTINGS C G St C KENDALL H W POSAMENTIER
38
C A ROSS and J C VAN WAGONER Society of Economic Paleontologists and
Mineralogists Special Publication no 42
STEVENS M K and ADAMIDES N G in prep GSWA Trainor 1 well completion report
Savory Sub-basin Officer Basin Western Australia with notes on petroleum and mineral
potential Western Australia Geological Survey Record 199612
STEVENS M K and GREY K 1997 Skates Hills Formation and Tarcunyah Group Officer
Basin mdash carbonate cycles stratigraphic position and hydrocarbon prospectivity Western
Australia Geological Survey Annual Review for 1996ndash97 p 55ndash60
SUMMONS RE and POWELL C McA 1991 Petroleum source rocks of the Amadeus Basin
in Geological and geophysical studies in the Amadeus Basin central Australia edited by R J
KORSCH and JM KENNARD Australia BMR Geology and Geophysics Bulletin 236
TRAVERSE A 1988 Palaeopalynology Boston Unwin Hyman 600p
VAIL P R MITCHUM R M Jr TODD R G WIDMIER J M THOMPSON S III
SANGREE J B BUBB J N and HATLELID W G 1977 Seismic stratigraphy and
global changes of sea level in Seismic stratigraphy mdash applications to hydrocarbon
exploration edited by C E PAYTON American Association of Petroleum Geologists
Memoir 26 516p
WALTER M R and GORTER J 1994 The Neoproterozoic Centralian Superbasin in Western
Australia the Savory and Officer Basins in The sedimentary basins of Western Australia
edited by P G PURCELL and R R PURCELL Petroleum Exploration Society of Australia
Symposium Perth WA 1994 Proceedings p851ndash864
WALTER M R GREY K WILLIAMS I R and CALVER C R 1994 Stratigraphy of the
Neoproterozoic to early Palaeozoic Savory Basin and correlation with the Amadeus and
Officer Basins Australian Journal of Earth Sciences v 41 p 533ndash546
WALTER M R VEEVERS J J CALVER C R and GREY K 1995 Neoproterozoic
stratigraphy of the Centralian Superbasin Australia Precambrian Research v 73 p 173ndash195
WILLIAMS I R 1992 Geology of the Savory Basin Western Australia Western Australia
Geological Survey Bulletin 141 115p
39
WILLIAMS I R 1995a Bullen WA (2nd Edition) Western Australia Geological Survey
1250 000 Geological Series Explanatory Notes 23p
WILLIAMS I R 1995b Trainor WA (2nd Edition) Western Australia Geological Survey
1250 000 Geological Series Explanatory Notes 31p
WILLIAMS I R and TYLER I M 1991 Robertson WA (2nd edition) Western Australia
Geological Survey 1250 000 Geological Series Explanatory Notes 36p
40
41
Appendix 1
Bibliography
Reports which are relevant to this investigation but which are not specifically cited are listed
below
BAILLIE P W POWELL C McA LI Z X and RYALL A M 1994 The tectonic
framework of Western Australiarsquos Neoproterozoic to recent sedimentary basins in The
sedimentary basins of Western Australia edited by P G PURCELL and R R PURCELL
Petroleum Exploration Society of Australia Symposium Perth WA 1994 Proceedings p
45ndash62
BRADSHAW M T BRADSHAW J MURRAY A P NEEDHAM D J SPENCER L
SUMMONS R E WILMOT J and WINN S 1994 Petroleum systems in West Australian
basins in The sedimentary basins of Western Australia edited by P G PURCELL and R R
PURCELL Petroleum Exploration Society of Australia Symposium Perth WA 1994
Proceedings p 93ndash118
CLARKE G L 1991 Proterozoic tectonic reworking in the Rudall Complex Western Australia
Australian Journal of Earth Science v38 p 31ndash44
COCKBAIN A E and HOCKING R M 1990 Phanerozoic in Geology and mineral resources
of Western Australia Western Australia Geological Survey Memoir 3 p 750ndash755
ETHERIDGE M and WALL V 1994 Tectonic and structural evolution of the Australian
Proterozoic 12th Australian Geological Convention Geological Society of Australia
Abstracts no 37 p 102ndash103
GOODE A D T 1981 Proterozoic geology of Western Australia in Precambrian of the
Southern Hemisphere Developments in Precambrian geology 2 edited by I R HUNTER
Amsterdam Elsevier p 105ndash203
GREY K and JACKSON M J 1983 A re-assessment of stromatolite evidence for the
correlation of the Late Proterozoic Neale and Ilma Beds Officer Basin Western Australia
Australia BMR Journal of Australian Geology and Geophysics v 8 p 359
42
HICKMAN A H WILLIAMS I R and BAGAS L 1994 Proterozoic geology and
mineralization of the TelferndashRudall region Paterson Orogen Geological Society of Australia
(WA Division) Excursion Guidebook no 5 56p
HOCKING R M MORY A J and WILLIAMS I R 1994 An atlas of Neoproterozoic and
Phanerozoic basins of Western Australia in The sedimentary basins of Western Australia
edited by P G PURCELL and R R PURCELL Petroleum Exploration Society of Australia
Symposium Perth WA 1994 Proceedings p 21ndash 44
JACKSON P R 1966 Geology and review of exploration Officer Basin Western Australia
Hunt Oil Company Western Australia Geological Survey S-series S26 (unpublished)
JACKSON M J 1971 Notes on a geological reconnaissance of the Officer Basin Western
Australia Australia BMR Geology and Geophysics Record 19715 30p
JACKSON M J and van de GRAAFF W J E 1981 Geology of the Officer Basin Western
Australia Australia BMR Geology and Geophysics Bulletin 206 102 p
LOWRY D C JACKSON M J van de GRAAFF W J E and KENNEWELL P J 1971
Preliminary result of geological mapping in the Officer Basin Western Australia Western
Australia Geological Survey Annual Report for 1971 p 50ndash56
MYERS J S 1990 Precambrian in Geology and mineral resources of Western Australia
Western Australia Geological Survey Memoir 3 p 737ndash750
MYERS J S SHAW R D and TYLER I M 1994 Proterozoic tectonic evolution of
Australia 12th Australian Geological Convention Geological Society of Australia Abstracts
no 37 p 312
NEDIN C and JENKINS R J F 1991 Re-evaluation of unconformities separating the
lsquoEdiacaranrsquo and Cambrian systems South Australia Palaios v 6 p 102ndash108
PHILLIPS B J JAMES A W and PHILIP G M 1985 The geology and hydrocarbon
potential of the north-western Officer Basin APEA Journal 25 (1) p 52ndash61
POWELL C McA LI Z X McELHINNY M W MEERT J G and PARK J K 1993
Paleomagnetic constraints on timing of the Neoproterozoic breakup of Rodinia and Cambrian
formation of Gondwana Geology v 21 p 889ndash892
43
POWELL C McA PREISS W V GATEHOUSE C G KRAPEZ B and LI Z X 1994
South Australian record of a Rodinian epicontinental basin and its mid-Neoproterozoic
breakup to form the Palaeo-Pacific Ocean Tectonophysics v 237 no 3ndash4 p 113ndash140
PREISS W V 1976 Proterozoic stromatolites from the Nabberu and Officer Basins Western
Australia and their biostratigraphic significance South Australia Geological Survey Report
of Investigations no 47 p 1ndash51
TOWNSON W G 1985 The subsurface geology of the western Officer Basin mdash results of
Shellrsquos 1980ndash1984 petroleum exploration campaign APEA Journal v 25 (1) p 34ndash51
WATTS K J 1982 The geology of the Townsend Quartzite Upper Proterozoic shallow water
deposit of the Northern Officer Basin Western Australia Perth University of Western
Australia BSc honours thesis (unpublished)
WELLS A T and KENNEWELL P J 1974 Evaporite exploration in the Officer Basin
Western Australia at the Madley Diapirs Australia BMR Record 1974194 (unpublished)
WILLIAMS I R and MYERS J S 1990 Paterson Orogen in Geology and mineral resources
of Western Australia Western Australia Geological Survey Memoir 3 p 274ndash286
WILLIAMS I R 1990 Savory Basin in Geology and mineral resources of Western Australia
Western Australia Geological Survey Memoir 3 p 329ndash334
WILLIAMS I R 1994 The Neoproterozoic Savory Basin Western Australia in The
sedimentary basins of Western Australia edited by P G PURCELL and R R PURCELL
Petroleum Exploration Society of Australia Symposium Perth WA 1994 Proceedings p
841ndash850
WILSON R B 1967 Woolnough Hills and Madley diapiric structures Gibson Desert WA
APEA Journal v 7 p 94ndash102
44
Appendix 2
Meteorological data (from Bureau of Meteorology Perth 1994)
Table 21 Wiluna rainfall (mm)
Year Jan Feb Mar Apr May Jun Jul Aug Sept Oct Nov Dec
1975 0 45 446 309 306 59 276 4 34 886 638 164 1976 16 154 12 138 53 16 34 62 12 238 0 2 1977 44 0 66 74 68 95 24 363 1 58 12 727 1978 234 522 94 16 0 96 367 24 16 353 185 45 1979 19 173 122 88 91 4 0 246 58 0 169 114 1980 148 764 68 1081 259 626 629 06 56 02 174 0 1981 123 476 192 32 196 118 44 74 14 0 28 312 1982 374 705 206 244 1079 92 02 143 368 526 368 118 1983 1 112 928 248 0 212 56 32 5 1 42 496 1984 149 7 342 84 836 0 348 132 224 04 16 172 1985 596 483 0 166 556 0 514 56 0 0 4 0 1986 0 154 35 0 0 1085 23 01 239 137 0 04 1987 1204 119 19 89 17 575 154 126 07 1 0 398 1988 46 202 164 13 388 0 202 104 0 0 224 1309 1989 207 234 26 703 278 536 57 0 01 0 144 02 1990 1035 23 281 46 126 53 94 218 44 9 42 0 1991 48 0 41 45 0 472 297 12 0 1 0 7 1992 112 96 1025 1227 323 65 04 174 0 132 48 4 1993 0 697 0 202 445 0 12 306 18 05 14 33 Mean 25 35 22 27 27 25 18 12 6 13 13 21
JAN FEB MAR APR MAY JUN JUL AUG SEP OCT NOV DEC0
10
20
30
40
Mea
n R
ain
fall
(mm
)
Month
Mean monthly rainfall in Wiluna
MKS41 140498
45
Table 22 Wiluna minimum temperature (degC)
Year Jan Feb Mar Apr May Jun Jul Aug Sept Oct Nov Dec
1975 ndash 23 203 15 94 63 71 62 103 124 169 205 1976 242 229 194 15 10 63 59 73 95 143 16 228 1977 243 25 197 148 96 95 56 86 102 ndash 188 23 1978 241 232 203 18 102 64 76 8 9 152 19 205 1979 255 226 216 167 83 6 59 79 97 145 198 223 1980 255 226 231 155 134 83 68 75 121 108 193 223 1981 245 216 19 182 119 6 54 78 138 159 163 218 1982 232 224 177 16 ndash ndash 37 111 112 164 209 225 1983 235 24 197 147 112 88 39 88 121 162 189 219 1984 241 243 191 156 ndash 72 66 7 95 161 182 211 1985 244 231 ndash 159 98 65 71 73 117 147 205 ndash 1986 ndash 229 226 155 93 96 43 49 10 122 ndash 219 1987 ndash 217 183 175 85 77 68 68 112 ndash ndash 221 1988 238 214 209 178 111 ndash ndash 86 104 157 171 195 1989 ndash 237 199 165 107 67 44 61 107 131 187 ndash 1990 232 ndash 211 155 118 62 57 87 102 149 195 22 1991 26 256 217 168 122 101 78 ndash 113 18 168 219 1992 227 227 214 169 102 98 59 69 ndash 125 159 196 1993 241 218 196 171 103 ndash 49 68 88 128 192 211 Mean 24 23 20 16 10 8 6 8 11 14 18 21
NOTE Dashes indicate data unavailable
JAN FEB MAR APR MAY JUN JUL AUG SEP OCT NOV DEC0
10
20
30
40
Month
MKS43 140498
50
Mean monthly minimum temperatures at Wiluna
Mea
n T
emp
erat
ure
(degC
)
46
Table 23 Wiluna maximum temperature (degC)
Year Jan Feb Mar Apr May Jun Jul Aug Sept Oct Nov Dec
1975 ndash 349 326 281 247 201 197 212 256 248 31 344 1976 374 369 346 297 248 206 208 225 265 287 313 388 1977 397 392 352 296 234 212 222 244 ndash 308 337 383 1978 378 345 346 316 242 195 176 205 231 295 334 356 1979 403 36 364 295 ndash ndash ndash 193 242 318 359 373 1980 392 342 377 275 24 176 179 233 292 288 349 391 1981 385 346 337 342 242 178 201 224 30 326 326 369 1982 372 359 315 307 ndash ndash 196 253 252 305 353 379 1983 381 389 327 272 263 222 187 248 287 321 336 366 1984 378 393 322 299 226 215 178 214 234 ndash 336 364 1985 40 366 ndash 294 224 216 205 212 284 307 355 ndash 1986 ndash 383 372 307 ndash 193 166 196 261 277 ndash 382 1987 ndash 339 328 305 21 202 214 218 275 ndash ndash 374 1988 388 365 353 301 23 ndash ndash 228 283 334 31 33 1989 ndash 375 339 285 238 179 181 219 275 298 336 ndash 1990 368 ndash 36 309 268 19 188 205 274 309 373 393 1991 414 416 363 315 268 206 21 ndash 279 338 332 368 1992 363 383 336 263 213 178 213 197 ndash 285 313 359 1993 396 357 344 301 221 ndash 197 215 253 294 347 362 Mean 39 37 34 30 24 20 20 22 27 30 34 37 NOTE Dashes indicate data unavailable
JAN FEB MAR APR MAY JUN JUL AUG SEP OCT NOV DEC0
10
20
30
40
Month
MKS42 140498
50
Mean monthly maximum temperatures at Wiluna
Mea
n T
emp
erat
ure
(degC
)
47
Appendix 3
Table 31 Summary of palynological results
Drillhole Depth (m) F no(a) GSWA no Lithology Formation Assemblage TAI(b)
BWB 1 74ndash75 F49668 135741 dark-grey siltstone basalt Jilyilli gt5 BWB 1 98ndash100 F49669 135742 dark-grey siltstone basalt Jilyilli gt5 BWB 1 121ndash122 F49670 135743 dark-grey siltstone basalt Jilyilli gt5 TWB 1 86ndash87 F49671 135631 dark-grey siltstone McFadden 3+ TWB 1 104ndash105 F49672 135632 dark-grey siltstone Cornelia 3+ TWB 1 121ndash122 F49673 135633 dark-grey siltstone Cornelia 4 TWB 2 14ndash15 F49674 135634 dark-grey siltstone Skates Hills 3+ TWB 6 49ndash50 F49675 135675 dark-grey siltstone Cornelia 1 3+ TWB 9 49ndash51 F49676 135704 dark-grey siltstone Brassey Range 1 3+ Trainor 1 37497- F49733 138939 black mudstone with Cornelia 5 37509 light-grey siltstone Trainor 1 3809 F49734 138940 dark-grey and black Cornelia 4- laminated mudstone Trainor 1 4170 F49735 138941 black unlaminated mudstone Cornelia 4- Trainor 1 4950 F49851 139501 dark-grey indurated siltstone Cornelia 5 Trainor 1 6032 F49852 139502 dark- and light-grey Cornelia 5 indurated siltstone Trainor 1 6434 F49853 139503 greenish indurated finely Cornelia 5 laminated siltstone LDDH 1 270 F49678 138934 dark-grey siltstone interbeds Waters 1 3+ in enterolithic evaporite Tarcunyah Gp LDDH 1 277 F49679 138935 dark-grey siltstone in cavity Waters 1 3+ in enterolithic evaporite Tarcunyah Gp
NOTES (a) GSWA Fossil Catalogue number (b) TAI = Thermal Alteration Index of Traverse (1988 plate 1)
48
Appendix 4
Savory Sub-basin quantitative magnetic and gravity interpretation (extracted from Cowan 1995)
Summary
A program of quantitative aeromagnetic interpretation has been completed on BMRAGSO data from the Savory Sub-
basin Western Australia Quantitative aeromagnetic interpretation utilized the 3D Euler deconvolution method
supported by wavenumber filtering and image processing The results have provided useful information on structural
trends and depth to magnetic sources in a structurally complex area Depth to magnetic source analysis has provided
information on intra-sedimentary magnetic sources as well as basement rocks
The results of the interpretation support previously identified depocentres However the presence of magnetic
sources at several levels makes it very difficult to produce a reliable magnetic basement depth contour map It is
considered more productive to work with the 3D Euler colour circle plots and images rather than trying to contour the
results It would be necessary to carry out a full-scale interpretation of the BMRAGSO profile data to improve on the
3D Euler results The regional gravity was found to be useful in interpreting the regional setting of the area although
the very wide data spacing limits quantitative use of the data The gravity data show quite a complex picture with
limited consistent correlation between gravity features and basin structures This suggests that gravity anomalies
reflect changes in density of the basement rocks rather than basement topography especially in the northern part of the
basin
It is recommended that the GSWA investigate access to company confidential high-resolution aeromagnetic data
prior to planning further aeromagnetic surveys Private companies have flown large parts of the northern half of the
area as part of their diamond exploration program Additional gravity coverage of the area may be more cost effective
than magnetic surveys as the gravity data provides more information on changes within the sedimentary section
Introduction
The main use of aeromagnetic data in petroleum exploration has been the determination of magnetic basement
topography although there has been increasing interest in analysis of intra-sedimentary magnetic anomalies
intrabasement and suprabasement magnetic anomalies These anomalies are used to determine depth to magnetic
basement rocks and hence determine the thickness of the sedimentary sequence Unfortunately interpretation of the
intrabasement and suprabasement magnetic anomalies is non-unique in terms of position and size of causative sources
because of the inherent ambiguity of potential-field methods However this ambiguity can be reduced by placing
49
constraints on source geometry and magnetization and by using geological and other geophysical data to constrain
the solution
Before 1970 most depth-determination techniques involved graphical determination of slopes of selected
magnetic anomalies and application of various empirical factors to convert the slopes into depth estimates Geological
Society of America Memoir 47 Interpretation of Aeromagnetic Maps by Vacquier et al (1951) was a landmark for
this type of interpretation
Automated interpretation procedures have played an increasingly important role in depth interpretation and a
wide range of techniques have been developed Many of these techniques are designed for application to located data
profiles and assume a two-dimensional geometry However there has been renewed interest in techniques applicable
to gridded data
Two distinct types of method can be recognized In the first case often described as discrete methods individual
isolated magnetic anomalies are interpreted and the results used to produce a map of basement relief In the second
case often described as continuous methods areas of data containing a number of anomalies are interpreted
statistically to produce direct output of basement depths
The discrete methods usually involve a semiautomatic initial phase which generates a large number of possible
depth solutions and an interactive second phase to screen and select acceptable solutions The advantage of this
approach is that the interpreter can select features that are relatively free from interference from adjacent anomalies
and consider all aspects of a particular magnetic anomaly The disadvantage is that interpretation can be very time
consuming as a wide range of depths are usually possible depending on the initial model chosen and a significant
amount of effort is needed to select the correct model In the case of the Savory Sub-basin dataset we encountered
problems in separating basement related effects from the effects of shallower intrasedimentary magnetic sources
Because of these problems we have concentrated on displaying the Euler results accompanied by separation filter
images of the data to show the shallower effects and deeper effects rather than trying to refine a 3D Euler
deconvolution depth-to-crystalline-basement contour
The continuous methods are very direct provided that the rather restrictive assumption can be made that all
anomalies are due to lateral magnetization changes due to basement topography This means that shallow effects and
large intrabasement anomalies must be removed from the data This involves judgement and skill as it is necessary to
distinguish between the lower amplitude suprabasement anomalies due to basement topography and the larger
intrabasement anomalies reflecting magnetization changes within the basement These methods were not considered
suitable for the Savory Sub-basin magnetic dataset but were used to invert the gravity data
50
Limitations of magnetic and gravity interpretation
Interpretation of the area is limited by a shortage of information on the nature and physical properties of the deeper
sedimentary sequence and the underlying basement rocks However using techniques such as cross-correlation of
gravity and pseudo-gravity data it is possible to try to differentiate between anomalies relating to basement and those
related to the sedimentary sequence
Gravity anomalies reflect changes within the sedimentary sequence as well as basement condition These
changes in density of sedimentary rocks produce gravity anomalies without a corresponding magnetic anomaly hence
the complementary nature of gravity and magnetic surveys The main use of magnetics is to determine depth to
magnetic basement and any intra-sedimentary volcanic rocks or intrusives whereas gravity provides much more
general information on the sedimentary sequence
Unfortunately interpretation of gravity anomalies is complicated since they can be due to a number of geological
features including
bull major basement faults
bull basement highs
bull igneous intrusions within the basement
bull sedimentary basins which may or may not be isostatically compensated
bull intra-sedimentary volcanics and associated plutonic centres
Two major problems affect the interpretation of both magnetic and gravity data
1 The inherent ambiguity of potential-field data There is no unique solution to any measured gravity or magnetic
anomaly and theoretically there will be an infinite number of source geometry and magnetizationdensity
combinations which will fit the observed data This means that any a priori information which helps to select a
suitable model is very useful
2 Measured anomalies are the summation of effects from different depths For example an observed gravity profile
may contain contributions from shallow sources (density variations within the sedimentary basin) intermediate
depth sources (density variations due to large igneous intrusions within the basement) and deep sources (crustal
thinning producing a mantle anomaly) Separation of these component responses is the regionalresidual problem
which we solve using spectral analysis and differential upward continuation-based separation filtering
Regional setting and interpretation overview
The area studied includes parts of BALFOUR DOWNS (SF51-9) RUDALL (SF51-10) ROBERTSON (SF51-13) GUNANYA
(SF51-14) COLLIER (SG50-4) BULLEN (SG51-1) TRAINOR (SG51-2) MADLEY (SG51-3) NABBERU (SG50-5)
STANLEY (SG51-6) and HERBERT (SG51-7) 1250 000 sheets Broadly the area lies between latitudes 22deg00rsquondash25deg30rsquoS
and longitudes 119deg30rsquondash123deg30rsquoE
51
Regional gravity
The AGSO regional gravity data (at nominal 11 km spacing) was gridded at a 4 km mesh spacing using a minimum-
curvature algorithm Bouguer gravity values in the area are negative reflecting mass deficiency at depth and range
from -84 mgals to -25 mgals
A Bouguer gravity colour image is shown as Figure 41 A residual grid was produced by removing a fifth-order
orthogonal polynomial from the Bouguer data but did not add to the interpretation
120deg 121deg 122deg 123deg
23deg
24deg
25deg
-25
-84
50 km
MKS46 180598
mgal
Figure 41 Regional Bouguer gravity (BMRAGSO data) gridded at 4 km
52
The data show a complex pattern of positive and negative anomalies with no clearly defined trends Correlations
with aeromagnetic data and known basin structures are poor A vague north-northwest linear trend appears to coincide
with the Marloo Fault (Figure 42) A prominent negative anomaly appears to coincide with the Blake Fold and Fault
Belt depocentre and continues as a narrower negative anomaly to the east until it widens out again near the edge of the
basin Elsewhere the gravity data show little correlation with known basin structures and it is likely that especially in
the north of the area gravity anomalies are due to density changes in the basement rather than changes in basement
topography
Production of wavelength-filtered residual gravity plots and vertical gradient plots showed very patchy aliased
data reflecting poor sampling in much of the area
Regional magnetics
The AGSO regional aeromagnetic data were gridded at a 400 m mesh spacing using a minimum-curvature algorithm
(Figure 43) Most of the data has a line spacing of 1600 m with small areas of 1 km spacing The quality of the data is
acceptable for regional interpretation but is not adequate for detailed analysis The accuracy of the flight path is rather
variable reflecting the vintage of the data and the noise envelope of the data is poor by modern standards Problems
were also encountered in joining different map sheets
The magnetic anomaly pattern over the south and west part of the area shows a strong high frequency signature
reflecting the presence of widespread basic sills and dykes Some of the major north-northeasterly trending dykes can
be traced over considerable distances
Discontinuous high-frequency anomalies extend as a northwest-trending zone through the centre of the area and
this zone includes a conspicuous circular magnetic anomaly which is probably a ring complex
The northern and eastern parts of the area are characterized by long-wavelength deep-seated basement magnetic
anomalies with 120deg and 150deg trends dominant The Marloo and Perentie Faults (Figure 42) appear as distinct linear
zones and offsets A prominent easterly trending negative anomaly in the northwest of the area appears to swing round
to the southeast and may separate different basement blocks One possible interpretation is that this very deep seated
anomaly separates areas of Archaean and Proterozoic basement
Regional geology
The regional geology is described in Williams (1992) The GSWA provided a digitized version of Plate 2 from this
Bulletin the structural interpretation map to use as an overlay (Figure 42)
53
Pp
Pp
PSd
PSd
PSd
PSd
PSd
PSo
PSt
PSt
PSf
PSf
PSf
PSb
PSb
PSb
PSsPSs
PSs
PSb
PSm
PSp
PSc
PSc
PSw
PSw
PSw
PSg
PSr
PSj
PSg
PM
Pk
PY
PY
PSd
L
L
L
L
L
L
L
LL
L
L
L
LL
L
LL
L L
LL
L L
L
L
L
L
L
L
L
LL
L
L
BLAKEDEPOCENTRE
MA
RLO
O
FAU
LT
PERENTIEFAULT
50 km
MKS39120598
120deg 121deg 122deg 123deg
25deg
24deg
23deg
Approximate boundaryof aeromagnetic interpretation
PML
PSgL
PSjL
PML
PSpL
PML
PML
PSfL
PSfL
PSpL
LPc
LPcLPcPSrL
LPA
Durba Sandstone
Woora Woora Formation
McFadden Formation
Tchukardine Formation
Boondawari Formation
Skates Hills Formation
Mundadjini Formation
Coondra Formation
Spearhole Formation
Watch Point Formation
Jilyili Formation
Brassey Range Formation
Glass Spring Formation
Paterson Formation
Yeneena Group
Karara Formation
Cornelia Formation
Kahrban Subgroup
Bangemall Group
Fault
Formation boundary
PSdL
PSoL
PSfL
PStL
PSbL
PSsL
PSmL
PScL
PSpL
PSwL
PSjL
PSrL
PSgL
Pp
PYL
PkL
LPc
LPA
PML
Savory Group Other Units
PYL
Figure 42 Regional geology and structure map (after Williams 1992)
54
120deg 121deg 122deg 123deg
23deg
24deg
25deg
5820
3750
MKS47 180598
nT
50 km
Figure 43 Regional aeromagnetic data total magnetic intensity (BMRAGSO data) gridded at 400 m
Analysis
3D analysis
3D Euler deconvolution was used as the primary depth-determination method The advantage of this approach is that
consistent solutions can be obtained over the entire area with minimal assumptions about source geometries Euler
deconvolution of gridded data is used for positional information and estimation of depth to top of source Euler
55
deconvolution yields a large number of depth solutions which have to be screened to reject spurious solutions Results
are plotted as circles in eight depth ranges with radius proportional to depth and colour coded
The 400 m total magnetic intensity grid was used for the analysis Horizontal gradients in x and y and the vertical
gradient were calculated 3D Euler deconvolution was tested on the 400 m gridded data using windows of 9 times 9 and
11 times 11 and 16 times 16 data points and structural indices 05 (fault) and 10 (sill or dyke) It was concluded that the
16 times 16 window produced the best results overall and final plots were produced for the 16 times 16 window and structural
index 05 (Fig 44) Results were very good over the northern and central parts of the area showing magnetic sources
Figure 44 Depth to magnetic source 3D Euler deconvolution 16 times 16 window of 400 m gridded data structural index 05
56
at several different levels Unfortunately in the extreme south of the area shallow intrasedimentary magnetic sources
(sills and dykes) dominated the inversion and the results contained few basement solutions
In order to reduce these problems the 400 m gridded data were filtered using a separation filter based on
interpretation of the log-energy spectrum The 3D Euler method was run on the filtered data in order to generate more
basement-depth solutions Results for the deep-separation filter data were gridded and presented as a colour image in
Cowan (1995) Attempts to grid the Euler output were unsatisfactory and it is considered safer to interpret the 3D
Euler depth plots The 3D Euler depth results from the separation-filter run should be analysed with care as perfect
separation of the basement can never be achieved and there will always be some contamination from sources at
different levels
The results of original total magnetic intensity 3D Euler depth estimation for structural index 05 using a 16 point
window have been plotted at 1500 000 scale (not included in this publication but available in Cowan (1995) from the
GSWA Library as S10331) and as reduced A4 colour circle plots (Figure 44)
The results of deep-basement 3D Euler depth estimation for structural index 05 using a 16 point window have
been plotted as a colour image at 1500 000 scale and as an A4 image (not included in this publication)
2D analysis
Two equispaced profiles were interpolated with a 50 m station interval from the AGSO-located data profiles for the
BULLEN 1250 000 sheet The interpolated profiles were analysed using 2D Euler deconvolution and Werner
deconvolution Results are included in Cowan (1995) and show the use of these methods for more detailed analysis
Filtered data
In order to reconcile 3D Euler results from shallow basement and intrasedimentary magnetic sources we produced
several separation-filtered maps and images We found the shallow-layer double-separation filter (Figure 45) to be
very effective for shallow sources and the deep-layer standard-separation filter (Figure 46) for the basement layer
Gravity and magnetic data correlation
Both lsquoreduced to the polersquo (RTP) magnetics (Figure 47) and pseudo-gravity data (Figure 48) were produced as part of
the reconciliation of gravity and magnetic signatures In both cases the filtering operations assumed magnetization by
induction in the present Earths field The RTP data are fairly similar to the total magnetic intensity The pseudo-
57
gravity data are dominated by a northwest-trending strong positive anomaly and there is little correlation with the
Bouguer gravity data
The poor magneticgravity correlation is confirmed by cross-correlation of the RTP magnetics and the gravity
gradient The correlation plot in Figure 49 shows little coherent response with numerous zones of positive and
negative correlation
Figure 45 Regional aeromagnetic data shallow layer separation filter (BMRAGSO data) gridded at 400 m
Results
In the north and east of the area on the Wells Foreland Sub-basin trend (refer to Figure 1 main text) we see a range
of quite deep 3D Euler depths and several trend directions with north-northwesterly dominant There are relatively few
shallow intrasedimentary solutions in this zone
The second area of deep 3D Euler solutions lies over the Blake depocentre (Figure 43) with several trend
directions
Elsewhere the 3D Euler results are dominated by shallow intrasedimentary depth solutions reflecting mainly the
dolerite sills dykes and the ring complex However where we do see basement-related solutions in the south and
west of the area they appear to be shallower than those noted for the Wells Foreland Sub-basin and the Blake
depocentre
58
Figure 46 Regional aeromagnetic data deep-layer separation filter (BMRAGSO data) gridded at 400 m
Figure 48 Regional aeromagnetic data pseudo-gravity transform (BMRAGSO data) gridded at 400 m
Figure 47 Regional aeromagnetic data reduced-to-pole (BMRAGSO data) gridded at 400 m
Figure 49 Regional aeromagnetic and gravity data gravitymagnetic correlation using RTP magnetics and gravity gradient (BMRAGSO data) gridded at 4 km
59
This subdivision of the area into two zones of deep solutions is consistent with interpreted depocentres
However the interference between sources at different levels and the complexity of the magnetic response of the
basement rocks precludes more refined interpretation at this stage
The area of deep 3D Euler solutions over the Blake depocentre correlates with the pronounced negative gravity
anomaly discussed in the gravity interpretation section Using a density contrast of -015 gcc the negative gravity
anomaly could indicate up to 6ndash8 km of low-density sedimentary rocks depending on assumptions about the regional
field
The area of deep 3D Euler solutions over the Wells Foreland Sub-basin has a complex gravity expression and no
clear basin structure emerges from inversion of these data As noted previously it is likely that observed gravity
anomalies reflect contrasts in basement density rather than basement topography
Separation filtering applied to the magnetic data helps to enhance the intrasedimentary magnetic signature and to
give a better impression of the basement magnetic signature even though separation of the basement response is not
perfect
Conclusions
Quantitative aeromagnetic interpretation using 3D Euler deconvolution supported by wavenumber filtering and image
processing has been successful in providing structural trend and depth information for the Savory Sub-basin
Quantitative magnetic interpretation has revealed two zones of relatively deep magnetic basement beneath the
Wells Foreland Sub-basin and the Blake depocentre
This analysis of the magnetic data supports interpreted depocentres but the complexity of the basement magnetic
signature and interference from sources at different depths precludes further refinement to a map of basement
topography
Regional gravity proved to be very useful in understanding the regional setting of the area and in providing
support for aspects of the interpretation The gravity data support the interpretation of the Blake depocentre
suggesting up to 6ndash8 km of low-density sedimentary rocks
The deep structure of the Savory Sub-basin area is obviously complex with different areas underlain by
Archaean and Proterozoic basement and with the Capricorn suture occurring in the centre of the area
60
Recommendations
The quantitative magnetic interpretation needs to be reconciled with geological models available for the area
In particular the zones tentatively identified as areas with thick sedimentary rocks the Wells Foreland Sub-
basin and the Blake depocentre need to be investigated
Cross sections should be prepared across the basin for joint magneticgravity modelling especially for the Blake
depocentre It is important to be able to explain the strong negative gravity anomaly in this area
In view of the effects of basement density contrasts on the gravity field for the northern part of the area we think
that additional gravity interpretation and acquisition of new gravity data may not be justified as they will not
contribute significantly to understanding basin evolution and structure
It is recommended that GSWA try to get access to company confidential high-resolution aeromagnetic data
rather than flying new surveys The GSWA might offer to fund flying of new infill areas as a bargaining point
References
The original text of this report by Cowan (1995) and 1500 000 scale maps are filed in the GSWA Library under
S10331
COWAN D 1995 Savory Basin quantitative magnetic interpretation Western Australia Geological Survey S-series
S10331 (unpublished)
VACQUIER V STEENLAND N C HENDERSON R G and ZIETZ I 1951 Interpretation of aeromagnetic
maps The Geological Society of America Memoir 47 151p
WILLIAMS I R 1992 Geology of the Savory Basin Western Australia Western Australia Geological Survey
Bulletin 141 115p
61
Appendix 5
Geochemistry
MKS38 250398
Saturate FractionC12+ GLC
1217
Pr18
Ph
22
31CSR WELL-13 315m Cuttings
Figure 51 Canning Stock Route Well 13 gas chromatograph of extract of auger drill sample
12
17
18
22
31
Pr Ph
LDDH 1 6623m CoreSaturate FractionC12+ GLC
MKS35 240398
Figure 52 Gas chromatograph of extract from core sample at 6623 m LDDH1
62
Table 51 Canning Stock Route Well 13 auger drill samples
GSWA sample Drill depth (m)(a) Comments
135601 150 At watertable 135602 203 (all samples consist 135603 310 of sand mud and water) 135604 315 At total depth
NOTE (a) Datum for drill depth is the top of sediment fill in the well which is 155 m below ground level (ie the total depth of 315 m is 47 m below ground level)
Table 52 Canning Stock Route Well 13 gas chromatography data for 315 m depth sediment sample
Parameter Value
Weight of rock extracted (grams) 945 Total extract (ppm) 519 n-Alkane distribution n-C12 07 n-C13 23 n-C14 26 n-C15 22 n-C16 19 n-C17 14 i-C19 23 n-C18 14 i-C20 08 n-C19 11 n-C20 16 n-C21 25 n-C22 29 n-C23 70 n-C24 42 n-C25 95 n-C26 43 n-C27 83 n-C28 38 n-C29 87 n-C30 31 n-C31 273 Alkane compositional data Pristane phytane ratio 279 Pristane n-C17 ratio 161 Phytane n-C18 ratio 059 CPI (1)(a) 284 CPI (2) 209 (C21 + C22) (C28 + C29) 043
NOTE (a) CPI= Carbon preference index
63
Table 53 LDDH1 extract liquid chromatography data for 6623 m concentration
Rock extracted Total extract (grams) (ppm)
702 313
NOTE ppm= parts per million
Table 54 LDDH1 saturate gas chromatography data of core for 6623 m alkane composition
Pristane Pristane Phytane (a) CPI (1) CPI (2) (C21+C22) Phytane n-C17 n-C18 (C28+C29)
103 026 024 103 102 325
NOTE (a)CPI = carbon preference index
Table 55 LDDH1 saturate gas chromatography data of core for 6623 m n-alkane distributions
Parameter Value
n-C12 17 n-C13 38 n-C14 55 n-C15 60 n-C16 65 n-C17 74 i-C19 19 n-C18 78 i-C20 19 n-C19 80 n-C20 79 n-C21 71 n-C22 64 n-C23 57 n-C25 43 n-C24 38 n-C27 31 n-C28 23 n-C29 19 n-C30 12 n-C31 10
64
Appendix 6
Table 61 Summary of data from Trainor waterbores (TWB) and Bullen waterbores (BWB)
Well AMG Elevation TD Status(b) Completion details Water Salinity Water level Flow rate Depth to consolidated AGD84 GL (m) (m) struck mgl(c) (m) (LHr) lithology aquifer(e) Z51(a) Interval (m) (100 mm PVC) (m) (mgl)(d)
TWB 1 473660E 453 122 comp 0ndash75 plain 63 7 300 24 2 880 12 m 7287404N 75ndash93 slotted (9 260) McFadden Fm 93ndash99 plain TWB 2 472 977E 475 23 abd nil 15 m 7285877N Skates Hills Fm dry TWB 3 473259E 475 50 abd nil 7 m 7285849N Skates Hills Fm dry TWB 4 463225 E 445 50 comp 0ndash22 plain 35 7 200 55 3 600 0 m 7286143N 22ndash34 slotted (8 140) Tertiary sand and gravel 23ndash60 plain TWB 5 463095E 445 31 comp 0ndash19 plain 13 26 000 655 3 600 Tertiary sand and gravel 7277721N 19ndash25 slotted (36 700) 25ndash31 plain TWB 6 457013E 455 50 comp 0ndash42 plain 38 920 119 600 0 m 7274352N 42ndash48 slotted (1 030) Cornelia Fm ss TWB 7 453739E 475 26 susp 0ndash2 plain 11 9 300 48 4 500 0 m 7263891N (10 500) Tertiary sand TWB 8 433893E 535 60 susp 0ndash2 plain 47 8 500 gt46 1 200 0 m 7245991N (10 900) Tertiary sand and Brassey Range Fm ss TWB 9 437219E 505 51 comp 0ndash47 plain 45 1 000 58 600 1 m 7235905N 47ndash51 slotted (990) Brassey Range Fm ss TWB 10 434927E 495 32 susp 0ndash2 plain 235 450 120 0 m 7225875N (500) Dolerite
65
BWB 1 287337E 580 122 abd Nil 1 m 7245861N Jilyili Fm dry BWB 2 288346E 545 50 comp 0ndash26 plain 15 630 3 29 000 0 m 7240423N 26ndash38 slotted (730) Tertiary sand and gravel 38ndash50 plain BWB 3 305637E 545 50 abd 19 8 800 43 7 200 0 m 7240423N (10 550) Tertiary ss BWB 4 320167E 515 445 comp 0ndash20 plain 9 980 445 24 000 0 m 7248097N 20ndash32 slotted (1 190) Tertiary ss 32ndash44 plain BWB 5 353393E 545 20 susp 0ndash2 plain 45 (970) 1 m 7238934N Basalt
NOTES (a) GPS accuracy ~ 150 m (b) Comp = completed abd = abandoned susp = suspended (c) Salinity from conductivity (d) Analysis total dissolved solids (e) Fm = Formation ss = sandstone
13
TD=600m
TD=1367m
TD=701m
TD=709m
TD=50m
SS
1S
S1
SS1
SS
1S
S1
SS
1
SS
1
SS1
SS4 SS1
Pha
nero
zoic
or
SS
2
Cz
CzCz
Karst Bitumen
SS1
TD=181m
Mundadjini 1 Akubra 1 Boondawari 1 LDDH 1 Trainor 1 TWB 6
Munda-djini Fm
Spear-hole Fm
Munda-djini Fm
Munda-djini Fm
Spear-hole Fm
Spear-hole Fm
Waters Fm
McFadden Fm
Cornelia Fm
Cornelia Fm
Cornelia Fm
511 plusmn 13Maor 696 plusmn 20Ma(maximum)
779 plusmn 10Ma(maximum)
Mundadjini 1
Akubra 1 Boondawari 1
LDDH 1
Trainor 1TWB 6100 km
N
LOCATION
NW SE
Sea level
0m AHD
Dolerite basalt
Conglomerate
Sandstone
Mudstone
Dolomite
Limestone
Evaporite
TOC gt08
Permeability gt100md
Oil fluorescence
Sedimentary zircon U-Pb age
Identifiable polymorphs
Cainozoic
Supersequence 1 age
Unconformity
Formation contact
Cz
SS1
r
r
0
100
200
metres
VerticalScale
MKS36 120598
LEGEND
Figure 6 Geological cross section through significant drillholes in the Savory Sub-basin
14
Depositional Sequence C Supersequence 3
Depositional Sequence C consists of the Boondawari Formation (Fig 3) and although it contains
sandstone conglomerate and dolomite the sandstones contain significant amounts of feldspar and
clay and hence are likely to be poorer reservoirs than older sandstones
Depositional Sequence D Supersequence 4
Depositional Sequence D includes the McFadden Tchukardine and Woora Woora Formations
(Fig 3) The McFadden Formation is poorly sorted and sandstones contain significant amounts of
feldspathic clasts in the north of the basin but are significantly coarser and cleaner in the northeast
of the sub-basin (Williams 1992)
Sandstones of the Tchukardine and Woora Woora Formations are generally cleaner than those
of the McFadden Formation and are expected to have fair to good porosity although the
Tchukardine Formation has a higher clay content in parts
Depositional Sequence E Supersequence 4
Depositional Sequence E consists of the Durba Sandstone (Fig 3) a coarse sandstone with minor
conglomerate which has good to excellent visible porosity in surface exposures
Other depositional sequences and regional correlations
Sedimentary rocks which were not included in the Savory Group by Williams (1992) but which
are likely to be of Neoproterozoic age and hence part of the greater Officer Basin include the
Tarcunyah Group the Cornelia Formation and the Kahrban Subgroup
As discussed in the Introduction all of the strata in the Karara Basin and the younger strata
of the Yeneena Basin were redefined to form the Tarcunyah Group of the greater Officer Basin
(Bagas et al 1995) (Fig 7) In outcrop the Tarcunyah Group consists predominantly of quartzose
feldspathic and arkosic sandstone shale which is carbonaceous in parts and carbonate which
includes stromatolitic dolomite Mineral hole LDDH1 drilled on GUNANYA intersected the
15
120598
122deg
123deg
21deg
22deg
23deg
24deg
23deg
22deg
21deg
122deg
123deg
Fault
Thrust
Reverse thrust
CANNINGBASIN
OFFICERBASIN
GROUP
PILBARACRATON
TARCUNYAH
SAVORY GROUP
BANGEMALL
GROUP
THROSSELL
GROUP
LAMIL
GROUP
ConnaughtonTerrane
TerraneTalbot
complexTabletop granitic
Tabletop Terrane
Permian
Neoproterozoicgranitoid
50 km
FormationWaltha Woora
McKay Fault
South west Thrust
Vines
Fault
24deg
120deg
YENEENA CANNINGBASIN
ARUNTAINLIERRUDALL
COMPLEX
AMADEUSBASIN
MUSGRAVEBLOCK
OFFICERBASINYILGARN
CRATON
GROUP
GROUP
GROUP
PILBARACRATON
GROUP
EARAHEEDY
GLENGARRY
BANGEMALL
WYLOO GROUP
SAVORY
WA
CARNARVONBASIN
GASCOYNECOMPLEX
GROUPTARCUNYAH
400 kmGROUP
SA
N
T
CamelndashTabletopfault zone
KAHRBANSUBGROUP
CORNELIAFORMATION
MKS37
Figure 7 Regional geological setting of the Savory Group and western Officer Basin The dashed line on the inset map marks the interpreted margin of the greater Officer Basin
16
Tarcunyah Group and consists predominantly of mudstone with minor sandstone limestone
dolomite and anhydrite (Fig 6)
The age of the Tarcunyah Group is uncertain although limited palynological and stromatolite
evidence suggests that it is probably coeval with Supersequence 1 of the Centralian Superbasin
Drillhole LDDH1 contains palynomorphs equivalent to assemblages in the Browne and Bitter
Springs Formations of the Officer and Amadeus Basins respectively and from the Cornelia
Formation in TWB 6 (Grey and Stevens 1997) (Figs 4 and 6) Stromatolite specimens tentatively
assigned to Acaciella australica (Howchin 1914) Walter 1972 occur in the lower Tarcunyah
Group (Bagas et al 1995) The stromatolite Baicalia burra Preiss 1972 and a conical
stromatolite were reported from the upper part of the Tarcunyah Group (Stevens and Grey 1997)
The recognition of two stromatolite assemblages interpreted to have age significance in
Supersequence 1 sedimentary rocks of the Centralian Superbasin has permitted biostratigraphic
correlations between outcrop and well data The Acaciella australica assemblage appears to be
slightly older than 800 Ma and is restricted to the middle part of Supersequence 1 The Baicalia
burra assemblage is considered to be slightly younger than 800 Ma and occurs in the upper part
of Supersequence 1 (Grey 1996b Stevens and Grey 1997) The older A australica assemblage
is recognized in the Skates Hills Formation in the Savory Sub-basin and the stromatolite A
australica itself has been tentatively identified in the lower Tarcunyah Group The occurrence of
the A australica assemblage in the Woolnough Madley and Browne Formations of the Officer
Basin and in the Loves Creek Member of the Bitter Springs Formation of the Amadeus Basin
allows correlations throughout the Centralian Superbasin (Fig 4)
The younger B burra assemblage has not been recognized in sedimentary rocks of the
Savory Group as defined by Williams (1992) but it occurs in the upper parts of the Tarcunyah
Group and allows correlation of this group with outcrops of the Neale Formation and with the
Kanpa Formation in petroleum exploration well Hussar 1 both located in the central Officer Basin
of Western Australia (Fig 4) (Grey 1996b Stevens and Grey 1997) The occurrence of the B
burra assemblage in these units permits their correlation with the Burra Group in the Adelaide
Geosyncline of South Australia (K Grey unpublished data)
The Cornelia Formation and Kahrban Subgroup outcrop in the southeast of the sub-basin and
were considered by Williams (1992) to be part of the Mesoproterozoic Bangemall Basin Limited
evidence suggests that all or parts of these two units are of Neoproterozoic age The Ward and
Oldham Inliers consist of outcrops of the Cornelia Formation Waterbore TWB 6 which was
drilled on TRAINOR in the Cornelia Formation contains palynomorphs consistent with a
Supersequence 1 age (Grey and Stevens 1997) (Figs 5 and 6) In outcrop the Cornelia Formation
17
consists predominantly of sandstone and quartzite with lesser siltstone shale mudstone and chert
In Trainor 1 this formation consists predominantly of indurated mudstone with minor sandstone
chert and dolomite A major erosional unconformity separates the Cornelia Formation from
overlying formations and parts of the Cornelia Formation have been folded with dips exceeding
70deg In contrast the majority of the Savory Sub-basin sedimentary rocks have dips of less than 30deg
except where they are adjacent to faults The Cornelia Formation apparently consists of an older
unit of steeply dipping quartzites cherts and well-indurated mudstones and a younger unit of
shallower dipping sandstones which are sub-friable in parts However caution should be used in
interpreting the age of units based on their structural deformation and additional mapping and age
dating of this formation is required
It is proposed here that the Kahrban Subgroup is likely to be of early Neoproterozoic age and
hence should be considered as part of the greater Officer Basin This proposal is based largely on
the relatively low dip of the strata (generally less than 20deg) and their west-northwest strike which
is parallel with strikes in the overlying Brassey Range Formation of the Savory Group The lower
contact of the Kahrban Subgroup is obscured but is thought to be an unconfirmity on the
Earaheedy Basin on the southeast of STANLEY (Muhling and Brakel 1985)
Structural setting
The Savory Sub-basin forms the most northwesterly sub-basin of the Neoproterozoic to
Phanerozoic Officer Basin The western boundary of the sub-basin with the Mesoproterozoic
Bangemall Basin consists of steep-reverse and strike-slip faults The northeastern boundary of the
Savory Sub-basin was mapped where Supersequence 4 formations of the Savory Group
unconformably overlie sedimentary rocks of the Karara and Yeneena Basins with the two older
units considered to be part of the Paterson Orogen (Williams 1992) This contact was defined as a
series of steeply dipping reverse faults in the northernmost parts of the sub-basin on BALFOUR
DOWNS and RUDALL and was extrapolated as an inferred reverse fault farther along strike to the
southeast on GUNANYA and MADLEY where the contact is obscured by Cainozoic sediments It is
now recognized that all the sedimentary rocks in the Karara Basin and younger sedimentary rocks
of the Yeneena Basin are from the Supersequence 1 Tarcunyah Group and part of the greater
Officer Basin (Bagas et al 1995) The northern boundary of the Tarcunyah Group and the greater
Officer Basin is in thrust-and reverse-faulted contact with the Rudall Complex and other parts of
the Paterson Orogen (Fig 7)
To the south the sub-basin unconformably overlies the Bangemall Basin The eastern
boundary of the sub-basin used in this study is where Permian and younger strata of the Officer
Basin unconformably overlie Neoproterozoic strata although there are no significant structural or
stratigraphic differences between the Neoproterozoic units
18
The sub-basin is subdivided into three principal structural areas (Fig 1) Trainor Platform
Blake Fault and Fold Belt and Wells Foreland Sub-basin (Williams 1992) A major review of
these boundaries is beyond the scope of this report but the processing of regional aeromagnetic
data (Appendix 4) and acquisition of a semi-detailed gravity survey by the GSWA in the east of
the sub-basin has enabled these tectonic units to be reassessed and some modifications are
proposed
The Wells Foreland Sub-basin (originally termed the Wells Foreland Basin in Williams 1992)
and sedimentary rocks of the Tarcunyah Group are both considered to be the northwest
continuation of the Gibson Sub-basin of the Officer Basin Aeromagnetic gravity and outcrop
data suggest that the Blake Fault and Fold Belt is significantly faulted and folded in the west but
is less deformed in the east where the thickest sedimentary section in is located on BULLEN
(Appendix 4) The Trainor Platform is reinterpreted to represent an area of the sub-basin that has
undergone major compression during the Petermann Ranges Orogeny resulting in folding and
faulting with a northwest strike This interpretation contrasts with that proposed by Williams
(1992) who envisaged that only a thin section of the Savory Group was present on the platform
Perincek (1998) has recognized nine periods of tectonic activity in the Officer Basin from the
beginning of the Neoproterozoic to the end of the Cretaceous Three major tectonic episodes are
recognized in the Centralian Superbasin The oldest event is the Areyonga Movement which is
pre-Sturtian and forms the boundary between Supersequences 1 and 2 (Fig 4) The Souths Range
Movement occurred at the end of the Sturtian at the boundary between Supersequences 2 and 3
The youngest major event is the Petermann Ranges Orogeny which occured at the end of the
Marinoan and forms the boundary between Supersequences 3 and 4
One minor and two major tectonic episodes are recognized in the Savory Sub-basin the
LP1ALP1B structural event and the Areyonga Movement and the Petermann Ranges Orogeny
respectively The LP1ALP1B structural event is revealed where the Spearhole Formations rests
disconformably and locally unconformably on the Brassey Range Jilyili and Glass Spring
Formations The Neoproterozoic Areyonga Movement (equivalent to the Blake Movement of
Williams 1992) produced folds and faults with a general northeast strike in the western and
southern parts of the region The Souths Range Movement has not been recognized in the sub-
basin This may be due to the fact that no Sturtian glacial rocks have been identified and hence it
is possible that structures attributed to the Areyonga Movement could be the result of the Souths
Range Movement or a combination of the two movements
The major tectonic event recorded in the sub-basin is the latest Neoproterozoic to Cambrian
Petermann Ranges Orogeny (equivalent to the Paterson Orogeny) which produced large reverse
19
faults thrusts strike-slip faults and folds with a general northwest strike The McFadden
Formation and other Supersequence 4 strata are considered to be at least partially coeval with this
orogeny (Williams 1992) We also interpret the Durba Sandstone as having been deposited during
the later stages of the Petermann Ranges Orogeny as this unit mildly deformed with fold axes
parallel to the strike of other structures attributed to the Petermann Ranges Orogeny
Quantitative aeromagnetic interpretation of the Savory Sub-basin utilizing the 3D Euler
deconvolution method supported by wave-number filtering and image processing has provided
structural trends and depth to magnetic source within the sub-basin (Cowan 1995) Gravity data
are interpreted by Cowan (1995) as changes in both the density of the basement rocks andor
basement topography depending on local conditions Part of Cowanrsquos report is reproduced in
Appendix 4
Exploration history
The only petroleum exploration conducted in the sub-basin has been the recent drilling in the
western part of three diamond drillholes of which two have minor oil shows (Table 2) There has
been some mineral exploration the results of which are stored in the GSWA Western Australian
Mineral Exploration (WAMEX) database system Much of the mineral exploration was in the
southwest and west where the sub-basin is in contact with the Bangemall Basin and along the
northern margin of the sub-basin Many of these mineral exploration programs included
aeromagnetic surveys and surface geochemical sampling (Fig 8)
Hydrocarbon potential
The sub-basin contains a sedimentary succession up to 8 km thick which is generally gently
folded and faulted and apparently unmetamorphosed Limited drilling has shown that thick
mudstones are present in the sub-basin with some mudstones in Trainor 1 having high Total
Organic Carbon (TOC) values Outcrops of sub-friable sandstones in many of the formations
within the sub-basin suggests widespread reservoir potential Mudstone and inferred thick
evaporite sequences are likely to form seals Maturity data suggest that near-surface samples are
approximately at the base of the oil window and top of the gas window in parts of the north and
southeast of the sub-basin However parts of the southwest of the sub-basin and the mudstones in
Trainor 1 have very high levels of maturity Numerous faults and folds have been identified from
surface mapping suggesting good potential for large structural traps Minor oil shows in
20
Table 2 Neoproterozoic formations and hydrocarbon shows in diamond drillholes in the Savory Sub-basin
Drillhole AMG Core TD (m) Approx Formation Depth Formation Depth Formation Depth Shows (AGD84) start (m) GL (m) (m) (m) (m)
LDDH 1 431148E 112 701 350 Tarcunyah 68ndash701 ndash ndash bitumen at 6623 m 7443826N Group Trainor 1 473640E 6 709 455 McFadden 9ndash83 Cornelia Fm 83ndash709 possible bitumen at 4537 m 7287400N Fm Mundadjini 1 319056E 170 600 500 Mundadjini 16ndash361 Spearhole Fm 361ndash600 10 fluorescence at 36102 m 7404844N Fm Boondawari 1 348959E 299 1 367 490 Mundadjini Fm 15ndash312 Spearhole Fm 312ndash1 283 Intrusive 1 283ndash1 367 40 fluorescence at 35364 m 5 7398174N fluorescence at 4963 m Akubra 1 334249E 15 181 530 Mundadjini 15ndash42 Intrusive 42ndash181 None 7401252N Fm
21
50 km
120deg 121deg30 123deg
25deg
24deg
23deg
22deg
Greater Officer Basin
Savory Sub-basin
1
2
3
4
6
8
3 Seismic line (prefixed N83-00)
Aeromagnetic survey
GS
WA
Sav
ory
1995
gra
vity
sur
vey
Gravity survey
MKS34270398
Figure 8 Locations of aeromagnetic and gravity surveys (other than regional BMRAGSO data)
22
sandstones in two petroleum wells in the northwest of the sub-basin and bitumen and oil shows
elsewhere in the region indicate that oil has been generated and migrated through the sub-basin
Source rocks
Source potential is considered to be the major exploration risk in the Savory Sub-basin although
minor oil shows in Mundadjini 1 and Boondawari 1 indicate that at least some oil has been
generated and migrated into potential reservoirs within the sub-basin Sandstone is the
predominant lithology observed in outcrop Outcrops of fine-grained lithologies in the basin are
rare because of intense surface weathering and erosion Only about 8 of the surface area of the
sub-basin is exposed bedrock and recessive lithologies (such as shale evaporite and friable
sandstone) may be present although they rarely outcrop
Outcrops of stromatolitic dolomite with associated cauliflower chert and cubic pseudomorphs
interpreted as being after halite indicate that evaporitic environments are present within the
Mundadjini Skates Hills and Boondawari Formations Evaporitic minerals are also present in
drillhole LDDH1 in the Tarcunyah Group
In 1995 GSWA drilled a continuous-core diamond drillhole (Trainor 1) in the sub-basin on
TRAINOR to a depth of 709 m to test for source rocks thus providing the first such data for the sub-
basin The drillhole intersected flat-lying clastics and carbonates of the McFadden Formation (9ndash
83 m) overlying indurated mudstones of the Cornelia Formation (83ndash709 m total depth) dipping at
about 40deg Of the six samples analysed from the Cornelia Formation in this drillhole the five
located between 375 and 6032 m depth have TOC values exceeding 05 (range 066ndash365)
Rock-Eval pyrolysis of these five samples indicates that they are at best in the dry-gas thermal
stage and as a result of their high level of maturation (Stevens and Adamides in prep) have poor
remaining hydrocarbon-generating potential Although the Cornelia Formation is overmature at
Trainor 1 the high TOC values are encouraging as it is likely that this sequence is less mature
elsewhere in the sub-basin
The Mundadjini Formation contains potential source rocks that comprise marine mudstones
with evaporitic minerals present in parts Thin dark mudstones were intersected in the Mundadjini
Formation in Akubra 1 In Mundadjini 1 and Boondawari 1 however the mudstones appear to be
too oxidized to have source potential
The Boondawari Formation also may be a source rock as it contains black mudstones The
unit is laterally equivalent to the Pertatataka Formation of the Amadeus Basin and the Ungoolya
23
Group of the Officer Basin in South Australia both of which have some source potential
(Summons and Powell 1991 Morton and Drexel 1997) Samples from the Dey Dey Mudstone of
the Ungoolya Group generally have poor TOC values (average 011 range 003ndash081)
moderate hydrogen index (HI) values (100ndash382) and poor to fair genetic potential with a
maximum of 292 kg hydrocarbon per tonne of source rock (Morton and Drexel 1997)
Stromatolitic dolomites and mudstones at the top of the Boondawari Formation and within the
Skates Hills Formation are potential source rocks Stromatolitic dolomite and evaporitic rocks
deposited in a marginal marine to sabkha environment are considered to have good potential to
generate and preserve organic carbon without requiring a deep-water setting (Stevens and Grey
1997) Such conditions are recognized in the Skates Hills Formation and in the upper parts of the
Tarcunyah Group
Maturity
Knowledge of the maturity of sedimentary rocks within the Savory Sub-basin is still limited From
a review of palynological studies Grey and Stevens (1997) report that the thermal maturity
inferred from the Thermal Alteration Index (TAI) of 3+ from Supersequence 1 age palynomorphs
in TWB 6 TWB 9 and LDDH1 is within the hydrocarbon window (Appendix 3) In Phanerozoic
spores and pollen a TAI of 3+ approximately equates to the end of liquid petroleum generation
and the start of dry gas generation and to a vitrinite reflectance of about 13 (Traverse 1988)
However the use of TAI for estimating thermal maturity from Neoproterozoic palynomorphs
requires calibration
In Trainor 1 the Cornelia Formation contains organically rich claystones between 375 and
6032 m depth Based on Rock-Eval maturity data (Stevens and Adamides in prep) and the dark
colour of poorly preserved organic material (Grey 1995de 1996) with TAI 4- to 5 all samples
had a high level of maturation with at best dry-gas generating potential remaining In contrast
drillhole LDDH1 on GUNANYA recorded lower levels of maturity (TAI values of 3+) with two of
sixteen samples from the Tarcunyah Group having greater than 1 TOC (Grey 1995abc Grey
and Cotter 1996) Organic petrology and Rock-Eval maturity data for samples from LDDH1
indicate that the section above 500 m is within the oil-generative window whereas below 500 m
the rocks are within the gas window (Ghori in prep Fig 9 Appendix 5)
Waterbores TWB 1 2 6 and 9 which are located on TRAINOR in the southeast of the sub-
basin all had organic matter with TAI values of 3+ from the McFadden Skates Hills Cornelia
and Brassey Range Formations respectively
24
100
200
300
400
500
600
700
Oil
gene
ratin
g
Gas
gene
ratin
g
Fai
r
Fai
r
Poo
r
Poo
r
Goo
d
Imm
atur
e
Oil
win
dow
Oil
win
dow
Imm
atur
e
01 0110 10 0 150 300 440 480 1
Neo
prot
eroz
oic
TOC S1+S2 mgg Hydrogen Index Tmax degC
Depth(m)
Organicrichness
Generatingpotential
Kerogentype Maturity Maturity
TD=701m
Sandstone
Mudstone
Dolomite
Limestone
Evaporite
Source rock
MKS40 070498
Ro equivalent
Figure 9 Petroleum source potential of rocks in Normandy LDDH1
Small amounts of organic matter associated with basalt and dolerite in cuttings from
waterbore BWB 1 on BULLEN showed high levels of thermal maturity (Grey 1995a Libby 1995)
It is unclear whether all sedimentary rocks on BULLEN are overmature for hydrocarbon generation
or the results from BWB 1 are related to local heating events associated with the volcanic bodies
that are common in the Jilyili Formation
25
Reservoirs
Each of the five depositional sequences of the Savory Group (Table 1) are inferred to contain
significant sandstone reservoirs with the possible exception of depositional sequence C as
discussed above in Stratigraphy The Spearhole Formation was cored in Mundadjini 1 and
Boondawari 1 and visual estimates of porosity vary from generally poor (less than 5) to fair
(approximately 5ndash15) The McFadden Formation in Trainor 1 has porosity values of up to 232
and a maximum permeability of 195 md (Stevens and Adamides in prep) Sandstones from
Neoproterozoic formations form the acquifers in the following waterbores the McFadden
Formation in TWB 1 the Cornelia Formation in TWB 6 and the Brassey Range Formation in
TWB 8 and TWB 9 (Appendix 6 Table 61)
Based on outcrop observations the Durba Sandstone is considered to be the best reservoir of
the Savory Group Similarly some sandstones from the Tarcunyah Group also have good visible
porosity in outcrop
Dolomites occur in several formations in the sub-basin Reservoir potential may exist
particularly where the dolomites are stromatolitic and oolitic However dolomites have not been
drilled in the sub-basin and porosity can only be inferred from the preferential silicification of
some stromatolite bioherms observed in outcrop (Stevens and Grey 1997) Elsewhere in the
Officer Basin porosities of up to10 have been measured in dolomites A limestone breccia
(karst) is described from 663 to 677 m in drillhole LDDH1 (Fig 6 Busbridge 1994)
Seals
Indications of evaporitic environments in the Mundadjini Skates Hills and Boondawari
Formations are described by Williams (1992) In Mundadjini 1 from 287 to 337 m anhydrite and
chert occurs as nodules beds and veins in mudstone of the Mundadjini Formation Evaporitic
minerals (predominantly gypsum) are described in the Tarcunyah Group in LDDH1 The presence
of the Woolnough and Madley salt diapirs in the Officer Basin (approximately 110 km east of the
sub-basin) and halite beds over 25 m thick in the well Hussar 1 (130 km east of the sub-basin)
provide further evidence that evaporite seals may be present in the Savory Sub-basin
Mudstones and shales form only a small proportion of the limited Neoproterozoic outcrop in
the sub-basin but significant thicknesses of mudstone were encountered in the Mundadjini
Formation in Mundadjini 1 and Boondawari 1 the Tarcunyah Group in LDDH1 and in the
26
Cornelia Formation in Trainor 1 These data suggest that mudstones form a significant proportion
of strata in the sub-basin despite their limited outcrop
Traps
Potential structural closures including folds and faults occur at various scales throughout the
Savory Sub-basin However the region has only been mapped at 1250 000 scale and
independently closed structures such as domes have yet to be confirmed The western margin of
the basin contains abundant faults (with a northeast strike) but elsewhere faults are less common
Some anticlines are recognized in outcrop including one with a strike length of up to 45 km
inferred from surface bedding dips in the Mundadjini and Spearhole Formations at approximately
24deg15rsquoS 121deg10rsquoE on BULLEN (Fig 1)
Salt diapirs and other halokinetic structures are recognized in outcrop well and seismic data
in the Officer Basin to the west of the Savory Sub-basin and it is probable that there are
significant thicknesses of evaporitic sedimentary rocks in the sub-basin The gravity field data
suggest there is good potential for salt diapirs and traps related to halokinesis
Although there is potential for stratigraphic traps to be present in the sub-basin insufficient
data are available to assess them
Preservation of hydrocarbons
The range of thermal maturities measured to date and the large periods of time envisaged for
deposition of sediments implies hydrocarbon generation may have occurred a number of times
during the evolution of the Savory Sub-basin Any hydrocarbons that were generated early may
have been trapped in palaeostructures and remigration to younger traps could have taken place
later The Petermann Ranges Orogeny which has been equated with the Paterson Orogeny (Myers
1990) is believed to have occurred in the latest Neoproterozoic to early Cambrian This is the last
major tectonic event recognized in the sub-basin suggesting that it is reasonable to expect that trap
integrity will have been preserved
If the inference of the presence of thick halite beds in the sub-basin is correct the preservation
potential of sub-salt traps should be excellent
27
Reported hydrocarbon shows and oil seep
Amadeus Petroleum recorded minor oil shows in cores from Mundadjini 1 and Boondawari 1 In
Mundadjini 1 at 36102 m (top of the Spearhole Formation) a 3 mm thick zone had 10 moderate
white fluorescence with slow solvent cut This show was in a granular sandstone with visually
estimated porosity of about 10 In Boondawari 1 at 35364 m (within the Spearhole Formation) a
broken surface of sandstone had 40 moderate yellow-white fluorescence with slow solvent cut
Visually estimated porosity is about 5 Because the fluorescing surface was broken during the
drilling process this show could have resulted from contamination A second show occurs in
Boondawari 1 at 4963 m (within the Spearhole Formation) where a 1 cm-thick zone had 5 dull
yellow fluorescence with slow solvent cut in a conglomerate with visually estimated porosity of
about 10 The company intends to further investigate the nature of these occurrences
Minor bitumen is present at 6623 m in drillhole LDDH1 on GUNANYA (Figs 5 and 6) as a
vein in mudstones of the Tarcunyah Group A sample was analysed by gas chromatography
(Ghori in prep) and confirmed that it is natural bitumen (Appendix 5)
Mineral hole OD 23 drilled by Jubilee Gold Mines NL on NABBERU in the Bangemall Basin
immediately to the south of the Savory Sub-basin (Fig 5) encountered bitumen and trace oil in
vugs in dolomite (M Stevens unpublished data) but no further data are available at present
In their popular guide to the Canning Stock Route Gard and Gard (1990 p 218) refer to an
oil seep at Well 13 on TRAINOR (Fig 5) They reported that between 1977 and 1984 lsquonatural oilrsquo
was seen in the well Although the well is now largely filled with sediment four auger drill
samples were collected by the GSWA in 1995 and all four were analysed for oil shows One
sample from 315 m total depth (GSWA sample 135604) yielded just enough extract (519 ppm)
for saturate gas chromatography analysis The gas chromatograph (Appendix 5) shows that the
extract does contain some hydrocarbons probably from recent plant material Because the depth to
the oil was not quoted in Gard and Gard (1990) the hand-augered well may not have been deep
enough to properly test this reported seep
Geological and geophysical databases
Geological and geophysical data available for the Savory Sub-basin are limited The most recently
completed geological maps for the sub-basin were published by the GSWA between 1991 and
1995 (Williams and Tyler 1991 Williams 1992 1995ab)
28
The cores from the five drillholes listed in Table 2 believed to be all of the core available
from the sub-basin are available for inspection at GSWA Mineral exploration reports submitted
to GSWA may be searched using the WAMEX database and open-file reports are available on
microfiche Geophysical data acquired by the mining industry is not required to be filed with
GSWA if acquired over Vacant Crown Land which is the case for much of the sub-basin
Geophysical survey data submitted in mining tenement reports and which extend into Vacant
Crown Land remain confidential to the companies Original regional aeromagnetic and gravity
datasets are available from the Australian Geological Survey Organisation (AGSO)
Data pertinent to oil exploration in the sub-basin such as structural style and salt diapirism
are presented in a review of the hydrocarbon prospectivity of the Officer Basin (Perincek 1998)
Drilling
Significant drillholes in the sub-basin are summarized in Table 2
Petroleum industry data
Amadeus Petroleum drilled three petroleum exploration wells in the central west of the Savory
Sub-basin in late 1997 These wells Mundadjini 1 Boondawari 1 and Akubra 1 were drilled by
continuous diamond coring (Figs 5 and 6) All targeted potential reservoirs within the Spearhole
Formation with the Mundadjini Formation as the proposed seal The wells were located on
structures interpreted from Landsat images and limited geological investigations Both Mundadjini
1 and Boondawari 1 had minor oil shows as discussed above (Reported hydrocarbon shows)
Government data
Stratigraphic drillhole Trainor 1 was drilled by GSWA in 1995 (Stevens and Adamides in prep)
and the main results are discussed above (Source rocks and Maturity)
Mineral industry data
Normandy Exploration drillhole LDDH1 was cored in the Tarcunyah Group to a total depth of
701 m and provided source-rock and maturity data as discussed above
29
Oilmin NL drilled six percussion drillholes (BD 1 3 4 5 8 and 9) through sandstones and
shales in the northern part of the Savory Sub-basin to a maximum depth of 198 m (Fig 5
WAMEX Microfiche File M 26811 I 2610) but only brief geological descriptions are available
Hydrogeological data
Hydrogeological data within the Savory Sub-basin are limited although a long history of water
exploration extends back to the construction of the Canning Stock Route early this century No
detailed geological or wireline logs are available for the older wells along this route A few station
wells have been drilled by various methods on the south and west margins of the basin but data
are unavailable as reports are not required to be filed with the government Depth to watertable
throughout the basin is largely controlled by porosity of the bedrock
The GSWA drilled fifteen waterbores in the winter of 1995 in the southern part of the sub-
basin in preparation for the drilling of Trainor 1 and the proposed Bullen 1 Twelve bores found
water and six of these bores have salinities of less than 1000 mgL (Fig 5 Appendix 6 Table 61)
One waterbore TWB 6 has gamma ray and neutron logs run through PVC casing and these are
available from the GSWA with the digital log data included herein
Seismic data
No geophysical data have been acquired by the petroleum industry in the Savory Sub-basin
Seismic data acquired in the Officer Basin to the east particularly in the Gibson and Yowalga
Sub-basins is pertinent to structural interpretation in the Savory Sub-basin (Perincek 1996a
1998)
Aeromagnetic surveys
Government data
There are over 95 277 line kilometres of aeromagnetic data included in the AGSO dataset There
are three regional aeromagnetic surveys covering the Savory Sub-basin These were flown by the
Bureau of Mineral Resources (BMR now AGSO) in 1984 at a line spacing of 1500 m with 36 740
and 52 587 line kilometres flown and by Aerodata in 1984 at a line spacing of 1000m with 5950
line kilometres flown These data were reprocessed and interpreted for GSWA by Cowan (1995)
An edited copy of this report is included as Appendix 4 and the original report is filed in the
GSWA Library under S-series reports item 10331
30
Mineral industry data
The approximate locations of non-AGSO aeromagnetic surveys are shown in Figure 8 More
detailed information regarding the location of these surveys may be obtained using the GSWA
MAGCAT II database Additional information such as contours of aeromagnetic values may be
obtained by inspecting items on file with the GSWA
Gravity surveys
Government data
The average spacing for gravity data in the Savory Sub-basin is one station per 121 km2 (11 times 11
km grid) These data were principally collected by BMR in the early 1960s There are a few
additional regional gravity traverses across the sub-basin which are also included in the
BMRAGSO dataset These data were reprocessed and interpreted for GSWA (Fig 10) and a
report on this work is also included in Appendix 4
The GSWA completed a large semi-detailed gravity survey in the eastern Savory Sub-basin
utilizing helicopter support and Differential Global Positioning Survey (DGPS) techniques (Fig
8) This gravity survey completed in August 1995 consists of 2300 gravity stations on a 2 times 3 km
grid All stations were acquired by helicopter using Scintrex gravimeters and Ashtek dual
frequency DGPS equipment for determining location This highly efficient system allowed the
acquisition of more than 100 gravity stations per day in remote areas The resolution of this survey
is +30 cm and +05 microms-2 (Daishsat 1995) These data (Fig 11) represent a significant
improvement on the previous regional survey data and are available from GSWA (GSWA
1996ab) The results of the interpretation of these data were presented at the 1997 ASEG
Convention (Carlsen and Shevchenko 1997)
Mineral industry data
Three small gravity surveys were conducted by Oilmin NL (Fig 8) and the relevant WAMEX
reports are M 2681I 2610 I 2435 I 2567 These three surveys are of limited value because height
control was provided by barometers only and the surveys were not tied to the national gravity grid
31
23deg
25deg
120deg 122deg
Trainor 1
SAVORY
SUB-BASIN
MKS54 160498
100 km
1995 SavoryGravity Survey
254
-1056
micromsec2
Figure 10 Regional Bouguer gravity map of the Savory Sub-basin
23deg
24deg
25deg
122deg30 123deg
TRAINOR 1
123deg30
50 km
MKS53 160498
-116
-626
micro msec2
Figure11 Detailed Bouguer gravity map of the
Savory 1995 Gravity Survey from the eastern Savory Sub-basin
32
Government and academic reports
Chronostratigraphy and geochemistry
The understanding of Neoproterozoic organic chemistry palynology and structural evolution is
essential to the interpretation of hydrocarbon prospectivity Pertinent reports are included in the
bibliography (Appendix 1) Unpublished palaeontology reports describe the palynology of wells in
the Savory Sub-basin (Grey 1995andashe 1996a) Grey and Cotter (1996) discussed the potential for
Neoproterozoic palynomorphs to provide a biostratigraphic framework and palaeoenvironmental
interpretation Grey and Stevens (1997) reviewed the results of palynological studies of wells
drilled in the sub-basin and reported that Supersequence 1 palynomorphs are present in TWB 6
TWB 9 and LDDH1 (Appendix 3) Grey (1996b) reported on the use of stromatolites for
correlation in the Neoproterozoic and Stevens and Grey (1997) discussed the application of
stromatolite biostratigraphy in correlating isolated dolomite outcrops in the sub-basin with well
and seismic data in the Officer Basin and Centralian Superbasin
Although geochemical data from the Savory Sub-basin are very limited results mostly
confirm thermal maturities inferred from TAI for LDDH1 and Trainor 1 (Ghori in prep Stevens
and Adamides in prep) Those parts of the Officer Basin in Western Australia which lie to the
east of the Savory Sub-basin are sparsely drilled but Ghori (in prep) reports that most of the
Neoproterozoic succession presently lies within the oil-generative window However his study
has been unable to identify effective source-rock units and the source for oil shows Thin source
rocks are present in the Neoproterozoic in LDDH1 (Fig 9) and in three wells which lie to the east
and southeast of the Savory Sub-basin namely NJD 1 Kanpa 1A and Yowalga 3
Proposed work program
From the above limited information it is concluded that additional research on the hydrocarbon
potential of the sub-basin is justified and proposals are outlined below
bull Additional modelling of gravity and aeromagnetic data from the Savory Sub-basin is required
in light of the results from Trainor 1 and Boondawari 1 Trainor 1 showed that what appeared
to be a structurally simple area based on outcrop aeromagnetic and gravity data was in fact an
area of major structuring Boondawari 1 intersected a dolerite which is in good depth
agreement with aeromagnetic depth to source results showing this technique is useful in
detecting the depth to intrusive bodies
33
bull Additional data from mineral and petroleum exploration bores may become available and
analysis of samples from these wells should be undertaken and interpreted in the context of
their relevance to the Officer Basin
bull Stratigraphic coring in the Blake Fault and Fold Belt and in the Wells Foreland Sub-basin (Fig
1) targeting source rocks is considered essential to the continuing evaluation of the
hydrocarbon prospectivity of the Savory Sub-basin
bull Correlations using at least outcrop well and potential-field data should be prepared to link the
sub-basin with the better known parts of the Officer Basin to the east
bull Remapping is required to clarify boundary positions within the Cornelia Formation this may
resolve some of the current problems of the relationship between this unit and the rest of the
Savory Sub-basin
bull Further work is required to explain the Early Cambrian or Sturtian ages interpreted for the
Cornelia Formation from sedimentary zircon UndashPb dating in drillhole Trainor 1 The
determination of the age of the organically rich but overmature claystones in this well is
critical to assessing the hydrocarbon potential of the region
bull The thin dark mudstones intersected by Akubra 1 in the Mundadjini Formation warrant
geochemical analysis Analyses of the oil shows in Mundadjini 1 and Boondawari 1 are
currently being undertaken by Amadeus Petroleum
bull Geochemical analysis of hydrocarbons in the Bangemall Basin drillhole OD23 has been
performed by Jubilee Gold and the results will be reviewed when they are submitted to
GSWA The possibility of source rocks within the Bangemall Basin charging traps within the
Bangemall Basin and the overlying Savory Sub-basin requires further investigation
Conclusions
The Savory Sub-basin is a frontier region with only three recently drilled petroleum exploration
wells and no seismic data Based on existing geological and geophysical data it is considered too
early to draw conclusions about the hydrocarbon prospectivity of the sub-basin at this stage and
there are several reasons why the area warrants further investigation
34
1 Thick accumulations of sedimentary rocks are present (up to 8 km thickness inferred) which
may contain source reservoir and sealing strata
2 Minor oil shows occur in Mundadjini 1 and Boondawari 1 and bitumen is present in mineral
exploration drillhole LDDH1 suggesting that hydrocarbons have migrated within the
Neoproterozoic sequence of the Savory Sub-basin Oil and bitumen are present in mineral
exploration drillhole OD23 in the Bangemall Basin immediately to the south of the Savory
Sub-basin and it is possible that source rocks from the Bangemall Basin could charge traps in
the overlying Savory Sub-basin
3 The age of sedimentary rocks in the sub-basin is still poorly constrained but some of the
Neoproterozoic sedimentary rocks located on GUNANYA and TRAINOR are within the
hydrocarbon-generation window It is possible that a significant thickness of Phanerozoic
sedimentary rocks may also be present
4 Friable sandstones with visible porosity outcrop extensively suggesting numerous potential
reservoirs
5 Significant but not intense faulting and folding has been mapped implying large structural
traps may be present
6 Evaporitic sedimentary rocks occur in several formations and may provide good source rocks
and excellent seals
35
References
APAK S N and CARLSEN G M 1997 A compilation and review of data pertaining to the
hydrocarbon prospectivity of the Canning Basin Western Australia Geological Survey
Record 199610 103p
BAGAS L GREY K and WILLIAMS I R 1995 Reappraisal of the Paterson Orogen and
Savory Basin Western Australia Geological Survey Annual Review 1994ndash95 p 55ndash63
BUSBRIDGE M 1994 Lake Disappointment Exploration Licence 451064 Third Annual
Report Lake Disappointment Diamond Drill Hole LDDH1 Normandy Exploration Limited
Western Australia Geological Survey M-series Item 7567 A41358 (unpublished)
CARLSEN G M and SHEVCHENKO S I 1997 Petroleum exploration in Proterozoic basins
using potential fields data and stratigraphic coring Australian Society of Exploration
Geophysicists 12th Geophysical Conference Handbook Sydney 1997 Preview no 66 p 83
(abstract only)
COWAN D 1995 Savory Basin quantitative magnetic interpretation Western Australia
Geological Survey S-series S10331 (unpublished)
DAISHSAT PTY LTD 1995 Operational and processing report Savory Basin gravity survey
Western Australia Geological Survey S-series S10332 (unpublished)
GARD E and GARD R 1990 Canning Stock Route a travellerrsquos guide for a journey through
history Perth Western Australia Western Desert Guides 448p
GEOLOGICAL SURVEY OF WESTERN AUSTRALIA 1996a Savory Basin first vertical
derivative of Bouguer gravity image 1250 000 Western Australia Geological Survey
GEOLOGICAL SURVEY OF WESTERN AUSTRALIA 1996b Savory Basin Bouguer gravity
image 1250 000 Western Australia Geological Survey
GHORI K A R in prep Petroleum source rock potential and thermal history Officer Basin
Western Australia Western Australia Geological Survey Record
36
GREY K 1995a Savory Basin drillhole BWB 1 (Bullen waterbore) palynology and thermal
maturation GSWA Palaeontology Report no 199512 (unpublished)
GREY K 1995b Savory Basin drillholes TWB 1 2 6 9 (Trainor waterbores) palynology and
thermal maturation GSWA Palaeontology Report no 199520 (unpublished)
GREY K 1995c Palynology of Normandy-Poseidon Lake Disappointment-1 corehole
Tarcunyah Group Paterson Orogen GSWA Palaeontology Report no 199521 (unpublished)
GREY K 1995d Savory Basin drillhole Trainor 1 (Trainor diamond drilling) palynology and
thermal maturity GSWA Palaeontology Report no 199524 (unpublished)
GREY K 1995e Savory Basin drillhole Trainor 1 (Trainor diamond drilling) Additional
Preparation of two samples GSWA Palaeontology Report no 199528 (unpublished)
GREY K 1995f Neoproterozoic stromatolites from the Skates Hills Formation Savory Basin
Western Australia and a review of the distribution of Acaciella australica Australian Journal
of Earth Sciences v 42 p 123ndash132
GREY K 1996a Savory Basin drillhole Trainor 1 (Trainor diamond drilling) Additional
samples palynology and thermal maturation GSWA Palaeontology Report no 199615
(unpublished)
GREY K 1996b Preliminary stromatolite correlations for the Neoproterozoic of the Officer
Basin and a review of Australia-wide correlations GSWA Palaeontology Report no 199615
(unpublished)
GREY K and COTTER K L 1996 Palynology in the search for Proterozoic hydrocarbons
Western Australia Geological Survey Annual Review for 1995ndash96 p 70ndash80
GREY K and STEVENS M K 1997 Neoproterozoic palynomorphs of the Savory Sub-basin
Western Australia and their relevance to petroleum exploration Western Australia
Geological Survey Annual Review for 1996ndash97 p 49ndash54
HUBBARD R J PAPE J and ROBERTS D G 1985 Depositional sequence mapping as a
technique to establish tectonic and stratigraphic framework and evaluate hydrocarbon
potential on a passive continental margin in Seismic stratigraphy II an integrated approach
37
edited by O R BERG and D G WOOLVERTON American Association of Petroleum
Geologists Memoir 39 p 79ndash91
LIBBY WG 1995 A petrological report on six samples of bore cuttings from the Savory Basin
Western Australia Western Australia Geological Survey S-series S31307 (unpublished)
MORTON JGG and DREXEL JF 1997 The petroleum geology of South Australia Vol 3
Officer Basin South Australia Department of Mines and Energy Resources Report Book
9719
MUHLING P C and BRAKEL A T 1985 Geology of the Bangemall Group mdash the evolution
of an intracratonic Proterozoic basin Western Australia Geological Survey Bulletin 128
219p
MYERS J S 1990 Precambrian tectonic evolution of part of Gondwana southwestern Australia
Geology v18 p 537ndash540
NELSON D R 1997 Compilation of SHRIMP UndashPb zircon data Western Australia Geological
Survey Record 19972 196p
PAYTON C E 1977 Seismic stratigraphy mdash applications to hydrocarbon exploration
American Association of Petroleum Geologists Memoir 26 516p
PERINCEK D 1996a The age of NeoproterozoicndashPalaeozoic sediments within the Officer Basin
of the Centralian Super-basin can be constrained by major sequence-bounding unconformities
APPEA Journal v 36 pt 1 p 350ndash368
PERINCEK D 1996b The stratigraphic and structural development of the Officer Basin
Western Australia a review Western Australia Geological Survey Annual Review 1995ndash
1996 p 135ndash148
PERINCEK D 1998 A compilation and review of data pertaining to the hydrocarbon
prospectivity of the Officer Basin Western Australia Geological Survey Record 19976
POSAMENTIER H W JERSEY M T and VAIL P R 1988 Eustatic controls on clastic
deposition 1 mdash Conceptual framework in Sea-level changes an integrated approach edited by
C K WILGUS B S HASTINGS C G St C KENDALL H W POSAMENTIER
38
C A ROSS and J C VAN WAGONER Society of Economic Paleontologists and
Mineralogists Special Publication no 42
STEVENS M K and ADAMIDES N G in prep GSWA Trainor 1 well completion report
Savory Sub-basin Officer Basin Western Australia with notes on petroleum and mineral
potential Western Australia Geological Survey Record 199612
STEVENS M K and GREY K 1997 Skates Hills Formation and Tarcunyah Group Officer
Basin mdash carbonate cycles stratigraphic position and hydrocarbon prospectivity Western
Australia Geological Survey Annual Review for 1996ndash97 p 55ndash60
SUMMONS RE and POWELL C McA 1991 Petroleum source rocks of the Amadeus Basin
in Geological and geophysical studies in the Amadeus Basin central Australia edited by R J
KORSCH and JM KENNARD Australia BMR Geology and Geophysics Bulletin 236
TRAVERSE A 1988 Palaeopalynology Boston Unwin Hyman 600p
VAIL P R MITCHUM R M Jr TODD R G WIDMIER J M THOMPSON S III
SANGREE J B BUBB J N and HATLELID W G 1977 Seismic stratigraphy and
global changes of sea level in Seismic stratigraphy mdash applications to hydrocarbon
exploration edited by C E PAYTON American Association of Petroleum Geologists
Memoir 26 516p
WALTER M R and GORTER J 1994 The Neoproterozoic Centralian Superbasin in Western
Australia the Savory and Officer Basins in The sedimentary basins of Western Australia
edited by P G PURCELL and R R PURCELL Petroleum Exploration Society of Australia
Symposium Perth WA 1994 Proceedings p851ndash864
WALTER M R GREY K WILLIAMS I R and CALVER C R 1994 Stratigraphy of the
Neoproterozoic to early Palaeozoic Savory Basin and correlation with the Amadeus and
Officer Basins Australian Journal of Earth Sciences v 41 p 533ndash546
WALTER M R VEEVERS J J CALVER C R and GREY K 1995 Neoproterozoic
stratigraphy of the Centralian Superbasin Australia Precambrian Research v 73 p 173ndash195
WILLIAMS I R 1992 Geology of the Savory Basin Western Australia Western Australia
Geological Survey Bulletin 141 115p
39
WILLIAMS I R 1995a Bullen WA (2nd Edition) Western Australia Geological Survey
1250 000 Geological Series Explanatory Notes 23p
WILLIAMS I R 1995b Trainor WA (2nd Edition) Western Australia Geological Survey
1250 000 Geological Series Explanatory Notes 31p
WILLIAMS I R and TYLER I M 1991 Robertson WA (2nd edition) Western Australia
Geological Survey 1250 000 Geological Series Explanatory Notes 36p
40
41
Appendix 1
Bibliography
Reports which are relevant to this investigation but which are not specifically cited are listed
below
BAILLIE P W POWELL C McA LI Z X and RYALL A M 1994 The tectonic
framework of Western Australiarsquos Neoproterozoic to recent sedimentary basins in The
sedimentary basins of Western Australia edited by P G PURCELL and R R PURCELL
Petroleum Exploration Society of Australia Symposium Perth WA 1994 Proceedings p
45ndash62
BRADSHAW M T BRADSHAW J MURRAY A P NEEDHAM D J SPENCER L
SUMMONS R E WILMOT J and WINN S 1994 Petroleum systems in West Australian
basins in The sedimentary basins of Western Australia edited by P G PURCELL and R R
PURCELL Petroleum Exploration Society of Australia Symposium Perth WA 1994
Proceedings p 93ndash118
CLARKE G L 1991 Proterozoic tectonic reworking in the Rudall Complex Western Australia
Australian Journal of Earth Science v38 p 31ndash44
COCKBAIN A E and HOCKING R M 1990 Phanerozoic in Geology and mineral resources
of Western Australia Western Australia Geological Survey Memoir 3 p 750ndash755
ETHERIDGE M and WALL V 1994 Tectonic and structural evolution of the Australian
Proterozoic 12th Australian Geological Convention Geological Society of Australia
Abstracts no 37 p 102ndash103
GOODE A D T 1981 Proterozoic geology of Western Australia in Precambrian of the
Southern Hemisphere Developments in Precambrian geology 2 edited by I R HUNTER
Amsterdam Elsevier p 105ndash203
GREY K and JACKSON M J 1983 A re-assessment of stromatolite evidence for the
correlation of the Late Proterozoic Neale and Ilma Beds Officer Basin Western Australia
Australia BMR Journal of Australian Geology and Geophysics v 8 p 359
42
HICKMAN A H WILLIAMS I R and BAGAS L 1994 Proterozoic geology and
mineralization of the TelferndashRudall region Paterson Orogen Geological Society of Australia
(WA Division) Excursion Guidebook no 5 56p
HOCKING R M MORY A J and WILLIAMS I R 1994 An atlas of Neoproterozoic and
Phanerozoic basins of Western Australia in The sedimentary basins of Western Australia
edited by P G PURCELL and R R PURCELL Petroleum Exploration Society of Australia
Symposium Perth WA 1994 Proceedings p 21ndash 44
JACKSON P R 1966 Geology and review of exploration Officer Basin Western Australia
Hunt Oil Company Western Australia Geological Survey S-series S26 (unpublished)
JACKSON M J 1971 Notes on a geological reconnaissance of the Officer Basin Western
Australia Australia BMR Geology and Geophysics Record 19715 30p
JACKSON M J and van de GRAAFF W J E 1981 Geology of the Officer Basin Western
Australia Australia BMR Geology and Geophysics Bulletin 206 102 p
LOWRY D C JACKSON M J van de GRAAFF W J E and KENNEWELL P J 1971
Preliminary result of geological mapping in the Officer Basin Western Australia Western
Australia Geological Survey Annual Report for 1971 p 50ndash56
MYERS J S 1990 Precambrian in Geology and mineral resources of Western Australia
Western Australia Geological Survey Memoir 3 p 737ndash750
MYERS J S SHAW R D and TYLER I M 1994 Proterozoic tectonic evolution of
Australia 12th Australian Geological Convention Geological Society of Australia Abstracts
no 37 p 312
NEDIN C and JENKINS R J F 1991 Re-evaluation of unconformities separating the
lsquoEdiacaranrsquo and Cambrian systems South Australia Palaios v 6 p 102ndash108
PHILLIPS B J JAMES A W and PHILIP G M 1985 The geology and hydrocarbon
potential of the north-western Officer Basin APEA Journal 25 (1) p 52ndash61
POWELL C McA LI Z X McELHINNY M W MEERT J G and PARK J K 1993
Paleomagnetic constraints on timing of the Neoproterozoic breakup of Rodinia and Cambrian
formation of Gondwana Geology v 21 p 889ndash892
43
POWELL C McA PREISS W V GATEHOUSE C G KRAPEZ B and LI Z X 1994
South Australian record of a Rodinian epicontinental basin and its mid-Neoproterozoic
breakup to form the Palaeo-Pacific Ocean Tectonophysics v 237 no 3ndash4 p 113ndash140
PREISS W V 1976 Proterozoic stromatolites from the Nabberu and Officer Basins Western
Australia and their biostratigraphic significance South Australia Geological Survey Report
of Investigations no 47 p 1ndash51
TOWNSON W G 1985 The subsurface geology of the western Officer Basin mdash results of
Shellrsquos 1980ndash1984 petroleum exploration campaign APEA Journal v 25 (1) p 34ndash51
WATTS K J 1982 The geology of the Townsend Quartzite Upper Proterozoic shallow water
deposit of the Northern Officer Basin Western Australia Perth University of Western
Australia BSc honours thesis (unpublished)
WELLS A T and KENNEWELL P J 1974 Evaporite exploration in the Officer Basin
Western Australia at the Madley Diapirs Australia BMR Record 1974194 (unpublished)
WILLIAMS I R and MYERS J S 1990 Paterson Orogen in Geology and mineral resources
of Western Australia Western Australia Geological Survey Memoir 3 p 274ndash286
WILLIAMS I R 1990 Savory Basin in Geology and mineral resources of Western Australia
Western Australia Geological Survey Memoir 3 p 329ndash334
WILLIAMS I R 1994 The Neoproterozoic Savory Basin Western Australia in The
sedimentary basins of Western Australia edited by P G PURCELL and R R PURCELL
Petroleum Exploration Society of Australia Symposium Perth WA 1994 Proceedings p
841ndash850
WILSON R B 1967 Woolnough Hills and Madley diapiric structures Gibson Desert WA
APEA Journal v 7 p 94ndash102
44
Appendix 2
Meteorological data (from Bureau of Meteorology Perth 1994)
Table 21 Wiluna rainfall (mm)
Year Jan Feb Mar Apr May Jun Jul Aug Sept Oct Nov Dec
1975 0 45 446 309 306 59 276 4 34 886 638 164 1976 16 154 12 138 53 16 34 62 12 238 0 2 1977 44 0 66 74 68 95 24 363 1 58 12 727 1978 234 522 94 16 0 96 367 24 16 353 185 45 1979 19 173 122 88 91 4 0 246 58 0 169 114 1980 148 764 68 1081 259 626 629 06 56 02 174 0 1981 123 476 192 32 196 118 44 74 14 0 28 312 1982 374 705 206 244 1079 92 02 143 368 526 368 118 1983 1 112 928 248 0 212 56 32 5 1 42 496 1984 149 7 342 84 836 0 348 132 224 04 16 172 1985 596 483 0 166 556 0 514 56 0 0 4 0 1986 0 154 35 0 0 1085 23 01 239 137 0 04 1987 1204 119 19 89 17 575 154 126 07 1 0 398 1988 46 202 164 13 388 0 202 104 0 0 224 1309 1989 207 234 26 703 278 536 57 0 01 0 144 02 1990 1035 23 281 46 126 53 94 218 44 9 42 0 1991 48 0 41 45 0 472 297 12 0 1 0 7 1992 112 96 1025 1227 323 65 04 174 0 132 48 4 1993 0 697 0 202 445 0 12 306 18 05 14 33 Mean 25 35 22 27 27 25 18 12 6 13 13 21
JAN FEB MAR APR MAY JUN JUL AUG SEP OCT NOV DEC0
10
20
30
40
Mea
n R
ain
fall
(mm
)
Month
Mean monthly rainfall in Wiluna
MKS41 140498
45
Table 22 Wiluna minimum temperature (degC)
Year Jan Feb Mar Apr May Jun Jul Aug Sept Oct Nov Dec
1975 ndash 23 203 15 94 63 71 62 103 124 169 205 1976 242 229 194 15 10 63 59 73 95 143 16 228 1977 243 25 197 148 96 95 56 86 102 ndash 188 23 1978 241 232 203 18 102 64 76 8 9 152 19 205 1979 255 226 216 167 83 6 59 79 97 145 198 223 1980 255 226 231 155 134 83 68 75 121 108 193 223 1981 245 216 19 182 119 6 54 78 138 159 163 218 1982 232 224 177 16 ndash ndash 37 111 112 164 209 225 1983 235 24 197 147 112 88 39 88 121 162 189 219 1984 241 243 191 156 ndash 72 66 7 95 161 182 211 1985 244 231 ndash 159 98 65 71 73 117 147 205 ndash 1986 ndash 229 226 155 93 96 43 49 10 122 ndash 219 1987 ndash 217 183 175 85 77 68 68 112 ndash ndash 221 1988 238 214 209 178 111 ndash ndash 86 104 157 171 195 1989 ndash 237 199 165 107 67 44 61 107 131 187 ndash 1990 232 ndash 211 155 118 62 57 87 102 149 195 22 1991 26 256 217 168 122 101 78 ndash 113 18 168 219 1992 227 227 214 169 102 98 59 69 ndash 125 159 196 1993 241 218 196 171 103 ndash 49 68 88 128 192 211 Mean 24 23 20 16 10 8 6 8 11 14 18 21
NOTE Dashes indicate data unavailable
JAN FEB MAR APR MAY JUN JUL AUG SEP OCT NOV DEC0
10
20
30
40
Month
MKS43 140498
50
Mean monthly minimum temperatures at Wiluna
Mea
n T
emp
erat
ure
(degC
)
46
Table 23 Wiluna maximum temperature (degC)
Year Jan Feb Mar Apr May Jun Jul Aug Sept Oct Nov Dec
1975 ndash 349 326 281 247 201 197 212 256 248 31 344 1976 374 369 346 297 248 206 208 225 265 287 313 388 1977 397 392 352 296 234 212 222 244 ndash 308 337 383 1978 378 345 346 316 242 195 176 205 231 295 334 356 1979 403 36 364 295 ndash ndash ndash 193 242 318 359 373 1980 392 342 377 275 24 176 179 233 292 288 349 391 1981 385 346 337 342 242 178 201 224 30 326 326 369 1982 372 359 315 307 ndash ndash 196 253 252 305 353 379 1983 381 389 327 272 263 222 187 248 287 321 336 366 1984 378 393 322 299 226 215 178 214 234 ndash 336 364 1985 40 366 ndash 294 224 216 205 212 284 307 355 ndash 1986 ndash 383 372 307 ndash 193 166 196 261 277 ndash 382 1987 ndash 339 328 305 21 202 214 218 275 ndash ndash 374 1988 388 365 353 301 23 ndash ndash 228 283 334 31 33 1989 ndash 375 339 285 238 179 181 219 275 298 336 ndash 1990 368 ndash 36 309 268 19 188 205 274 309 373 393 1991 414 416 363 315 268 206 21 ndash 279 338 332 368 1992 363 383 336 263 213 178 213 197 ndash 285 313 359 1993 396 357 344 301 221 ndash 197 215 253 294 347 362 Mean 39 37 34 30 24 20 20 22 27 30 34 37 NOTE Dashes indicate data unavailable
JAN FEB MAR APR MAY JUN JUL AUG SEP OCT NOV DEC0
10
20
30
40
Month
MKS42 140498
50
Mean monthly maximum temperatures at Wiluna
Mea
n T
emp
erat
ure
(degC
)
47
Appendix 3
Table 31 Summary of palynological results
Drillhole Depth (m) F no(a) GSWA no Lithology Formation Assemblage TAI(b)
BWB 1 74ndash75 F49668 135741 dark-grey siltstone basalt Jilyilli gt5 BWB 1 98ndash100 F49669 135742 dark-grey siltstone basalt Jilyilli gt5 BWB 1 121ndash122 F49670 135743 dark-grey siltstone basalt Jilyilli gt5 TWB 1 86ndash87 F49671 135631 dark-grey siltstone McFadden 3+ TWB 1 104ndash105 F49672 135632 dark-grey siltstone Cornelia 3+ TWB 1 121ndash122 F49673 135633 dark-grey siltstone Cornelia 4 TWB 2 14ndash15 F49674 135634 dark-grey siltstone Skates Hills 3+ TWB 6 49ndash50 F49675 135675 dark-grey siltstone Cornelia 1 3+ TWB 9 49ndash51 F49676 135704 dark-grey siltstone Brassey Range 1 3+ Trainor 1 37497- F49733 138939 black mudstone with Cornelia 5 37509 light-grey siltstone Trainor 1 3809 F49734 138940 dark-grey and black Cornelia 4- laminated mudstone Trainor 1 4170 F49735 138941 black unlaminated mudstone Cornelia 4- Trainor 1 4950 F49851 139501 dark-grey indurated siltstone Cornelia 5 Trainor 1 6032 F49852 139502 dark- and light-grey Cornelia 5 indurated siltstone Trainor 1 6434 F49853 139503 greenish indurated finely Cornelia 5 laminated siltstone LDDH 1 270 F49678 138934 dark-grey siltstone interbeds Waters 1 3+ in enterolithic evaporite Tarcunyah Gp LDDH 1 277 F49679 138935 dark-grey siltstone in cavity Waters 1 3+ in enterolithic evaporite Tarcunyah Gp
NOTES (a) GSWA Fossil Catalogue number (b) TAI = Thermal Alteration Index of Traverse (1988 plate 1)
48
Appendix 4
Savory Sub-basin quantitative magnetic and gravity interpretation (extracted from Cowan 1995)
Summary
A program of quantitative aeromagnetic interpretation has been completed on BMRAGSO data from the Savory Sub-
basin Western Australia Quantitative aeromagnetic interpretation utilized the 3D Euler deconvolution method
supported by wavenumber filtering and image processing The results have provided useful information on structural
trends and depth to magnetic sources in a structurally complex area Depth to magnetic source analysis has provided
information on intra-sedimentary magnetic sources as well as basement rocks
The results of the interpretation support previously identified depocentres However the presence of magnetic
sources at several levels makes it very difficult to produce a reliable magnetic basement depth contour map It is
considered more productive to work with the 3D Euler colour circle plots and images rather than trying to contour the
results It would be necessary to carry out a full-scale interpretation of the BMRAGSO profile data to improve on the
3D Euler results The regional gravity was found to be useful in interpreting the regional setting of the area although
the very wide data spacing limits quantitative use of the data The gravity data show quite a complex picture with
limited consistent correlation between gravity features and basin structures This suggests that gravity anomalies
reflect changes in density of the basement rocks rather than basement topography especially in the northern part of the
basin
It is recommended that the GSWA investigate access to company confidential high-resolution aeromagnetic data
prior to planning further aeromagnetic surveys Private companies have flown large parts of the northern half of the
area as part of their diamond exploration program Additional gravity coverage of the area may be more cost effective
than magnetic surveys as the gravity data provides more information on changes within the sedimentary section
Introduction
The main use of aeromagnetic data in petroleum exploration has been the determination of magnetic basement
topography although there has been increasing interest in analysis of intra-sedimentary magnetic anomalies
intrabasement and suprabasement magnetic anomalies These anomalies are used to determine depth to magnetic
basement rocks and hence determine the thickness of the sedimentary sequence Unfortunately interpretation of the
intrabasement and suprabasement magnetic anomalies is non-unique in terms of position and size of causative sources
because of the inherent ambiguity of potential-field methods However this ambiguity can be reduced by placing
49
constraints on source geometry and magnetization and by using geological and other geophysical data to constrain
the solution
Before 1970 most depth-determination techniques involved graphical determination of slopes of selected
magnetic anomalies and application of various empirical factors to convert the slopes into depth estimates Geological
Society of America Memoir 47 Interpretation of Aeromagnetic Maps by Vacquier et al (1951) was a landmark for
this type of interpretation
Automated interpretation procedures have played an increasingly important role in depth interpretation and a
wide range of techniques have been developed Many of these techniques are designed for application to located data
profiles and assume a two-dimensional geometry However there has been renewed interest in techniques applicable
to gridded data
Two distinct types of method can be recognized In the first case often described as discrete methods individual
isolated magnetic anomalies are interpreted and the results used to produce a map of basement relief In the second
case often described as continuous methods areas of data containing a number of anomalies are interpreted
statistically to produce direct output of basement depths
The discrete methods usually involve a semiautomatic initial phase which generates a large number of possible
depth solutions and an interactive second phase to screen and select acceptable solutions The advantage of this
approach is that the interpreter can select features that are relatively free from interference from adjacent anomalies
and consider all aspects of a particular magnetic anomaly The disadvantage is that interpretation can be very time
consuming as a wide range of depths are usually possible depending on the initial model chosen and a significant
amount of effort is needed to select the correct model In the case of the Savory Sub-basin dataset we encountered
problems in separating basement related effects from the effects of shallower intrasedimentary magnetic sources
Because of these problems we have concentrated on displaying the Euler results accompanied by separation filter
images of the data to show the shallower effects and deeper effects rather than trying to refine a 3D Euler
deconvolution depth-to-crystalline-basement contour
The continuous methods are very direct provided that the rather restrictive assumption can be made that all
anomalies are due to lateral magnetization changes due to basement topography This means that shallow effects and
large intrabasement anomalies must be removed from the data This involves judgement and skill as it is necessary to
distinguish between the lower amplitude suprabasement anomalies due to basement topography and the larger
intrabasement anomalies reflecting magnetization changes within the basement These methods were not considered
suitable for the Savory Sub-basin magnetic dataset but were used to invert the gravity data
50
Limitations of magnetic and gravity interpretation
Interpretation of the area is limited by a shortage of information on the nature and physical properties of the deeper
sedimentary sequence and the underlying basement rocks However using techniques such as cross-correlation of
gravity and pseudo-gravity data it is possible to try to differentiate between anomalies relating to basement and those
related to the sedimentary sequence
Gravity anomalies reflect changes within the sedimentary sequence as well as basement condition These
changes in density of sedimentary rocks produce gravity anomalies without a corresponding magnetic anomaly hence
the complementary nature of gravity and magnetic surveys The main use of magnetics is to determine depth to
magnetic basement and any intra-sedimentary volcanic rocks or intrusives whereas gravity provides much more
general information on the sedimentary sequence
Unfortunately interpretation of gravity anomalies is complicated since they can be due to a number of geological
features including
bull major basement faults
bull basement highs
bull igneous intrusions within the basement
bull sedimentary basins which may or may not be isostatically compensated
bull intra-sedimentary volcanics and associated plutonic centres
Two major problems affect the interpretation of both magnetic and gravity data
1 The inherent ambiguity of potential-field data There is no unique solution to any measured gravity or magnetic
anomaly and theoretically there will be an infinite number of source geometry and magnetizationdensity
combinations which will fit the observed data This means that any a priori information which helps to select a
suitable model is very useful
2 Measured anomalies are the summation of effects from different depths For example an observed gravity profile
may contain contributions from shallow sources (density variations within the sedimentary basin) intermediate
depth sources (density variations due to large igneous intrusions within the basement) and deep sources (crustal
thinning producing a mantle anomaly) Separation of these component responses is the regionalresidual problem
which we solve using spectral analysis and differential upward continuation-based separation filtering
Regional setting and interpretation overview
The area studied includes parts of BALFOUR DOWNS (SF51-9) RUDALL (SF51-10) ROBERTSON (SF51-13) GUNANYA
(SF51-14) COLLIER (SG50-4) BULLEN (SG51-1) TRAINOR (SG51-2) MADLEY (SG51-3) NABBERU (SG50-5)
STANLEY (SG51-6) and HERBERT (SG51-7) 1250 000 sheets Broadly the area lies between latitudes 22deg00rsquondash25deg30rsquoS
and longitudes 119deg30rsquondash123deg30rsquoE
51
Regional gravity
The AGSO regional gravity data (at nominal 11 km spacing) was gridded at a 4 km mesh spacing using a minimum-
curvature algorithm Bouguer gravity values in the area are negative reflecting mass deficiency at depth and range
from -84 mgals to -25 mgals
A Bouguer gravity colour image is shown as Figure 41 A residual grid was produced by removing a fifth-order
orthogonal polynomial from the Bouguer data but did not add to the interpretation
120deg 121deg 122deg 123deg
23deg
24deg
25deg
-25
-84
50 km
MKS46 180598
mgal
Figure 41 Regional Bouguer gravity (BMRAGSO data) gridded at 4 km
52
The data show a complex pattern of positive and negative anomalies with no clearly defined trends Correlations
with aeromagnetic data and known basin structures are poor A vague north-northwest linear trend appears to coincide
with the Marloo Fault (Figure 42) A prominent negative anomaly appears to coincide with the Blake Fold and Fault
Belt depocentre and continues as a narrower negative anomaly to the east until it widens out again near the edge of the
basin Elsewhere the gravity data show little correlation with known basin structures and it is likely that especially in
the north of the area gravity anomalies are due to density changes in the basement rather than changes in basement
topography
Production of wavelength-filtered residual gravity plots and vertical gradient plots showed very patchy aliased
data reflecting poor sampling in much of the area
Regional magnetics
The AGSO regional aeromagnetic data were gridded at a 400 m mesh spacing using a minimum-curvature algorithm
(Figure 43) Most of the data has a line spacing of 1600 m with small areas of 1 km spacing The quality of the data is
acceptable for regional interpretation but is not adequate for detailed analysis The accuracy of the flight path is rather
variable reflecting the vintage of the data and the noise envelope of the data is poor by modern standards Problems
were also encountered in joining different map sheets
The magnetic anomaly pattern over the south and west part of the area shows a strong high frequency signature
reflecting the presence of widespread basic sills and dykes Some of the major north-northeasterly trending dykes can
be traced over considerable distances
Discontinuous high-frequency anomalies extend as a northwest-trending zone through the centre of the area and
this zone includes a conspicuous circular magnetic anomaly which is probably a ring complex
The northern and eastern parts of the area are characterized by long-wavelength deep-seated basement magnetic
anomalies with 120deg and 150deg trends dominant The Marloo and Perentie Faults (Figure 42) appear as distinct linear
zones and offsets A prominent easterly trending negative anomaly in the northwest of the area appears to swing round
to the southeast and may separate different basement blocks One possible interpretation is that this very deep seated
anomaly separates areas of Archaean and Proterozoic basement
Regional geology
The regional geology is described in Williams (1992) The GSWA provided a digitized version of Plate 2 from this
Bulletin the structural interpretation map to use as an overlay (Figure 42)
53
Pp
Pp
PSd
PSd
PSd
PSd
PSd
PSo
PSt
PSt
PSf
PSf
PSf
PSb
PSb
PSb
PSsPSs
PSs
PSb
PSm
PSp
PSc
PSc
PSw
PSw
PSw
PSg
PSr
PSj
PSg
PM
Pk
PY
PY
PSd
L
L
L
L
L
L
L
LL
L
L
L
LL
L
LL
L L
LL
L L
L
L
L
L
L
L
L
LL
L
L
BLAKEDEPOCENTRE
MA
RLO
O
FAU
LT
PERENTIEFAULT
50 km
MKS39120598
120deg 121deg 122deg 123deg
25deg
24deg
23deg
Approximate boundaryof aeromagnetic interpretation
PML
PSgL
PSjL
PML
PSpL
PML
PML
PSfL
PSfL
PSpL
LPc
LPcLPcPSrL
LPA
Durba Sandstone
Woora Woora Formation
McFadden Formation
Tchukardine Formation
Boondawari Formation
Skates Hills Formation
Mundadjini Formation
Coondra Formation
Spearhole Formation
Watch Point Formation
Jilyili Formation
Brassey Range Formation
Glass Spring Formation
Paterson Formation
Yeneena Group
Karara Formation
Cornelia Formation
Kahrban Subgroup
Bangemall Group
Fault
Formation boundary
PSdL
PSoL
PSfL
PStL
PSbL
PSsL
PSmL
PScL
PSpL
PSwL
PSjL
PSrL
PSgL
Pp
PYL
PkL
LPc
LPA
PML
Savory Group Other Units
PYL
Figure 42 Regional geology and structure map (after Williams 1992)
54
120deg 121deg 122deg 123deg
23deg
24deg
25deg
5820
3750
MKS47 180598
nT
50 km
Figure 43 Regional aeromagnetic data total magnetic intensity (BMRAGSO data) gridded at 400 m
Analysis
3D analysis
3D Euler deconvolution was used as the primary depth-determination method The advantage of this approach is that
consistent solutions can be obtained over the entire area with minimal assumptions about source geometries Euler
deconvolution of gridded data is used for positional information and estimation of depth to top of source Euler
55
deconvolution yields a large number of depth solutions which have to be screened to reject spurious solutions Results
are plotted as circles in eight depth ranges with radius proportional to depth and colour coded
The 400 m total magnetic intensity grid was used for the analysis Horizontal gradients in x and y and the vertical
gradient were calculated 3D Euler deconvolution was tested on the 400 m gridded data using windows of 9 times 9 and
11 times 11 and 16 times 16 data points and structural indices 05 (fault) and 10 (sill or dyke) It was concluded that the
16 times 16 window produced the best results overall and final plots were produced for the 16 times 16 window and structural
index 05 (Fig 44) Results were very good over the northern and central parts of the area showing magnetic sources
Figure 44 Depth to magnetic source 3D Euler deconvolution 16 times 16 window of 400 m gridded data structural index 05
56
at several different levels Unfortunately in the extreme south of the area shallow intrasedimentary magnetic sources
(sills and dykes) dominated the inversion and the results contained few basement solutions
In order to reduce these problems the 400 m gridded data were filtered using a separation filter based on
interpretation of the log-energy spectrum The 3D Euler method was run on the filtered data in order to generate more
basement-depth solutions Results for the deep-separation filter data were gridded and presented as a colour image in
Cowan (1995) Attempts to grid the Euler output were unsatisfactory and it is considered safer to interpret the 3D
Euler depth plots The 3D Euler depth results from the separation-filter run should be analysed with care as perfect
separation of the basement can never be achieved and there will always be some contamination from sources at
different levels
The results of original total magnetic intensity 3D Euler depth estimation for structural index 05 using a 16 point
window have been plotted at 1500 000 scale (not included in this publication but available in Cowan (1995) from the
GSWA Library as S10331) and as reduced A4 colour circle plots (Figure 44)
The results of deep-basement 3D Euler depth estimation for structural index 05 using a 16 point window have
been plotted as a colour image at 1500 000 scale and as an A4 image (not included in this publication)
2D analysis
Two equispaced profiles were interpolated with a 50 m station interval from the AGSO-located data profiles for the
BULLEN 1250 000 sheet The interpolated profiles were analysed using 2D Euler deconvolution and Werner
deconvolution Results are included in Cowan (1995) and show the use of these methods for more detailed analysis
Filtered data
In order to reconcile 3D Euler results from shallow basement and intrasedimentary magnetic sources we produced
several separation-filtered maps and images We found the shallow-layer double-separation filter (Figure 45) to be
very effective for shallow sources and the deep-layer standard-separation filter (Figure 46) for the basement layer
Gravity and magnetic data correlation
Both lsquoreduced to the polersquo (RTP) magnetics (Figure 47) and pseudo-gravity data (Figure 48) were produced as part of
the reconciliation of gravity and magnetic signatures In both cases the filtering operations assumed magnetization by
induction in the present Earths field The RTP data are fairly similar to the total magnetic intensity The pseudo-
57
gravity data are dominated by a northwest-trending strong positive anomaly and there is little correlation with the
Bouguer gravity data
The poor magneticgravity correlation is confirmed by cross-correlation of the RTP magnetics and the gravity
gradient The correlation plot in Figure 49 shows little coherent response with numerous zones of positive and
negative correlation
Figure 45 Regional aeromagnetic data shallow layer separation filter (BMRAGSO data) gridded at 400 m
Results
In the north and east of the area on the Wells Foreland Sub-basin trend (refer to Figure 1 main text) we see a range
of quite deep 3D Euler depths and several trend directions with north-northwesterly dominant There are relatively few
shallow intrasedimentary solutions in this zone
The second area of deep 3D Euler solutions lies over the Blake depocentre (Figure 43) with several trend
directions
Elsewhere the 3D Euler results are dominated by shallow intrasedimentary depth solutions reflecting mainly the
dolerite sills dykes and the ring complex However where we do see basement-related solutions in the south and
west of the area they appear to be shallower than those noted for the Wells Foreland Sub-basin and the Blake
depocentre
58
Figure 46 Regional aeromagnetic data deep-layer separation filter (BMRAGSO data) gridded at 400 m
Figure 48 Regional aeromagnetic data pseudo-gravity transform (BMRAGSO data) gridded at 400 m
Figure 47 Regional aeromagnetic data reduced-to-pole (BMRAGSO data) gridded at 400 m
Figure 49 Regional aeromagnetic and gravity data gravitymagnetic correlation using RTP magnetics and gravity gradient (BMRAGSO data) gridded at 4 km
59
This subdivision of the area into two zones of deep solutions is consistent with interpreted depocentres
However the interference between sources at different levels and the complexity of the magnetic response of the
basement rocks precludes more refined interpretation at this stage
The area of deep 3D Euler solutions over the Blake depocentre correlates with the pronounced negative gravity
anomaly discussed in the gravity interpretation section Using a density contrast of -015 gcc the negative gravity
anomaly could indicate up to 6ndash8 km of low-density sedimentary rocks depending on assumptions about the regional
field
The area of deep 3D Euler solutions over the Wells Foreland Sub-basin has a complex gravity expression and no
clear basin structure emerges from inversion of these data As noted previously it is likely that observed gravity
anomalies reflect contrasts in basement density rather than basement topography
Separation filtering applied to the magnetic data helps to enhance the intrasedimentary magnetic signature and to
give a better impression of the basement magnetic signature even though separation of the basement response is not
perfect
Conclusions
Quantitative aeromagnetic interpretation using 3D Euler deconvolution supported by wavenumber filtering and image
processing has been successful in providing structural trend and depth information for the Savory Sub-basin
Quantitative magnetic interpretation has revealed two zones of relatively deep magnetic basement beneath the
Wells Foreland Sub-basin and the Blake depocentre
This analysis of the magnetic data supports interpreted depocentres but the complexity of the basement magnetic
signature and interference from sources at different depths precludes further refinement to a map of basement
topography
Regional gravity proved to be very useful in understanding the regional setting of the area and in providing
support for aspects of the interpretation The gravity data support the interpretation of the Blake depocentre
suggesting up to 6ndash8 km of low-density sedimentary rocks
The deep structure of the Savory Sub-basin area is obviously complex with different areas underlain by
Archaean and Proterozoic basement and with the Capricorn suture occurring in the centre of the area
60
Recommendations
The quantitative magnetic interpretation needs to be reconciled with geological models available for the area
In particular the zones tentatively identified as areas with thick sedimentary rocks the Wells Foreland Sub-
basin and the Blake depocentre need to be investigated
Cross sections should be prepared across the basin for joint magneticgravity modelling especially for the Blake
depocentre It is important to be able to explain the strong negative gravity anomaly in this area
In view of the effects of basement density contrasts on the gravity field for the northern part of the area we think
that additional gravity interpretation and acquisition of new gravity data may not be justified as they will not
contribute significantly to understanding basin evolution and structure
It is recommended that GSWA try to get access to company confidential high-resolution aeromagnetic data
rather than flying new surveys The GSWA might offer to fund flying of new infill areas as a bargaining point
References
The original text of this report by Cowan (1995) and 1500 000 scale maps are filed in the GSWA Library under
S10331
COWAN D 1995 Savory Basin quantitative magnetic interpretation Western Australia Geological Survey S-series
S10331 (unpublished)
VACQUIER V STEENLAND N C HENDERSON R G and ZIETZ I 1951 Interpretation of aeromagnetic
maps The Geological Society of America Memoir 47 151p
WILLIAMS I R 1992 Geology of the Savory Basin Western Australia Western Australia Geological Survey
Bulletin 141 115p
61
Appendix 5
Geochemistry
MKS38 250398
Saturate FractionC12+ GLC
1217
Pr18
Ph
22
31CSR WELL-13 315m Cuttings
Figure 51 Canning Stock Route Well 13 gas chromatograph of extract of auger drill sample
12
17
18
22
31
Pr Ph
LDDH 1 6623m CoreSaturate FractionC12+ GLC
MKS35 240398
Figure 52 Gas chromatograph of extract from core sample at 6623 m LDDH1
62
Table 51 Canning Stock Route Well 13 auger drill samples
GSWA sample Drill depth (m)(a) Comments
135601 150 At watertable 135602 203 (all samples consist 135603 310 of sand mud and water) 135604 315 At total depth
NOTE (a) Datum for drill depth is the top of sediment fill in the well which is 155 m below ground level (ie the total depth of 315 m is 47 m below ground level)
Table 52 Canning Stock Route Well 13 gas chromatography data for 315 m depth sediment sample
Parameter Value
Weight of rock extracted (grams) 945 Total extract (ppm) 519 n-Alkane distribution n-C12 07 n-C13 23 n-C14 26 n-C15 22 n-C16 19 n-C17 14 i-C19 23 n-C18 14 i-C20 08 n-C19 11 n-C20 16 n-C21 25 n-C22 29 n-C23 70 n-C24 42 n-C25 95 n-C26 43 n-C27 83 n-C28 38 n-C29 87 n-C30 31 n-C31 273 Alkane compositional data Pristane phytane ratio 279 Pristane n-C17 ratio 161 Phytane n-C18 ratio 059 CPI (1)(a) 284 CPI (2) 209 (C21 + C22) (C28 + C29) 043
NOTE (a) CPI= Carbon preference index
63
Table 53 LDDH1 extract liquid chromatography data for 6623 m concentration
Rock extracted Total extract (grams) (ppm)
702 313
NOTE ppm= parts per million
Table 54 LDDH1 saturate gas chromatography data of core for 6623 m alkane composition
Pristane Pristane Phytane (a) CPI (1) CPI (2) (C21+C22) Phytane n-C17 n-C18 (C28+C29)
103 026 024 103 102 325
NOTE (a)CPI = carbon preference index
Table 55 LDDH1 saturate gas chromatography data of core for 6623 m n-alkane distributions
Parameter Value
n-C12 17 n-C13 38 n-C14 55 n-C15 60 n-C16 65 n-C17 74 i-C19 19 n-C18 78 i-C20 19 n-C19 80 n-C20 79 n-C21 71 n-C22 64 n-C23 57 n-C25 43 n-C24 38 n-C27 31 n-C28 23 n-C29 19 n-C30 12 n-C31 10
64
Appendix 6
Table 61 Summary of data from Trainor waterbores (TWB) and Bullen waterbores (BWB)
Well AMG Elevation TD Status(b) Completion details Water Salinity Water level Flow rate Depth to consolidated AGD84 GL (m) (m) struck mgl(c) (m) (LHr) lithology aquifer(e) Z51(a) Interval (m) (100 mm PVC) (m) (mgl)(d)
TWB 1 473660E 453 122 comp 0ndash75 plain 63 7 300 24 2 880 12 m 7287404N 75ndash93 slotted (9 260) McFadden Fm 93ndash99 plain TWB 2 472 977E 475 23 abd nil 15 m 7285877N Skates Hills Fm dry TWB 3 473259E 475 50 abd nil 7 m 7285849N Skates Hills Fm dry TWB 4 463225 E 445 50 comp 0ndash22 plain 35 7 200 55 3 600 0 m 7286143N 22ndash34 slotted (8 140) Tertiary sand and gravel 23ndash60 plain TWB 5 463095E 445 31 comp 0ndash19 plain 13 26 000 655 3 600 Tertiary sand and gravel 7277721N 19ndash25 slotted (36 700) 25ndash31 plain TWB 6 457013E 455 50 comp 0ndash42 plain 38 920 119 600 0 m 7274352N 42ndash48 slotted (1 030) Cornelia Fm ss TWB 7 453739E 475 26 susp 0ndash2 plain 11 9 300 48 4 500 0 m 7263891N (10 500) Tertiary sand TWB 8 433893E 535 60 susp 0ndash2 plain 47 8 500 gt46 1 200 0 m 7245991N (10 900) Tertiary sand and Brassey Range Fm ss TWB 9 437219E 505 51 comp 0ndash47 plain 45 1 000 58 600 1 m 7235905N 47ndash51 slotted (990) Brassey Range Fm ss TWB 10 434927E 495 32 susp 0ndash2 plain 235 450 120 0 m 7225875N (500) Dolerite
65
BWB 1 287337E 580 122 abd Nil 1 m 7245861N Jilyili Fm dry BWB 2 288346E 545 50 comp 0ndash26 plain 15 630 3 29 000 0 m 7240423N 26ndash38 slotted (730) Tertiary sand and gravel 38ndash50 plain BWB 3 305637E 545 50 abd 19 8 800 43 7 200 0 m 7240423N (10 550) Tertiary ss BWB 4 320167E 515 445 comp 0ndash20 plain 9 980 445 24 000 0 m 7248097N 20ndash32 slotted (1 190) Tertiary ss 32ndash44 plain BWB 5 353393E 545 20 susp 0ndash2 plain 45 (970) 1 m 7238934N Basalt
NOTES (a) GPS accuracy ~ 150 m (b) Comp = completed abd = abandoned susp = suspended (c) Salinity from conductivity (d) Analysis total dissolved solids (e) Fm = Formation ss = sandstone
14
Depositional Sequence C Supersequence 3
Depositional Sequence C consists of the Boondawari Formation (Fig 3) and although it contains
sandstone conglomerate and dolomite the sandstones contain significant amounts of feldspar and
clay and hence are likely to be poorer reservoirs than older sandstones
Depositional Sequence D Supersequence 4
Depositional Sequence D includes the McFadden Tchukardine and Woora Woora Formations
(Fig 3) The McFadden Formation is poorly sorted and sandstones contain significant amounts of
feldspathic clasts in the north of the basin but are significantly coarser and cleaner in the northeast
of the sub-basin (Williams 1992)
Sandstones of the Tchukardine and Woora Woora Formations are generally cleaner than those
of the McFadden Formation and are expected to have fair to good porosity although the
Tchukardine Formation has a higher clay content in parts
Depositional Sequence E Supersequence 4
Depositional Sequence E consists of the Durba Sandstone (Fig 3) a coarse sandstone with minor
conglomerate which has good to excellent visible porosity in surface exposures
Other depositional sequences and regional correlations
Sedimentary rocks which were not included in the Savory Group by Williams (1992) but which
are likely to be of Neoproterozoic age and hence part of the greater Officer Basin include the
Tarcunyah Group the Cornelia Formation and the Kahrban Subgroup
As discussed in the Introduction all of the strata in the Karara Basin and the younger strata
of the Yeneena Basin were redefined to form the Tarcunyah Group of the greater Officer Basin
(Bagas et al 1995) (Fig 7) In outcrop the Tarcunyah Group consists predominantly of quartzose
feldspathic and arkosic sandstone shale which is carbonaceous in parts and carbonate which
includes stromatolitic dolomite Mineral hole LDDH1 drilled on GUNANYA intersected the
15
120598
122deg
123deg
21deg
22deg
23deg
24deg
23deg
22deg
21deg
122deg
123deg
Fault
Thrust
Reverse thrust
CANNINGBASIN
OFFICERBASIN
GROUP
PILBARACRATON
TARCUNYAH
SAVORY GROUP
BANGEMALL
GROUP
THROSSELL
GROUP
LAMIL
GROUP
ConnaughtonTerrane
TerraneTalbot
complexTabletop granitic
Tabletop Terrane
Permian
Neoproterozoicgranitoid
50 km
FormationWaltha Woora
McKay Fault
South west Thrust
Vines
Fault
24deg
120deg
YENEENA CANNINGBASIN
ARUNTAINLIERRUDALL
COMPLEX
AMADEUSBASIN
MUSGRAVEBLOCK
OFFICERBASINYILGARN
CRATON
GROUP
GROUP
GROUP
PILBARACRATON
GROUP
EARAHEEDY
GLENGARRY
BANGEMALL
WYLOO GROUP
SAVORY
WA
CARNARVONBASIN
GASCOYNECOMPLEX
GROUPTARCUNYAH
400 kmGROUP
SA
N
T
CamelndashTabletopfault zone
KAHRBANSUBGROUP
CORNELIAFORMATION
MKS37
Figure 7 Regional geological setting of the Savory Group and western Officer Basin The dashed line on the inset map marks the interpreted margin of the greater Officer Basin
16
Tarcunyah Group and consists predominantly of mudstone with minor sandstone limestone
dolomite and anhydrite (Fig 6)
The age of the Tarcunyah Group is uncertain although limited palynological and stromatolite
evidence suggests that it is probably coeval with Supersequence 1 of the Centralian Superbasin
Drillhole LDDH1 contains palynomorphs equivalent to assemblages in the Browne and Bitter
Springs Formations of the Officer and Amadeus Basins respectively and from the Cornelia
Formation in TWB 6 (Grey and Stevens 1997) (Figs 4 and 6) Stromatolite specimens tentatively
assigned to Acaciella australica (Howchin 1914) Walter 1972 occur in the lower Tarcunyah
Group (Bagas et al 1995) The stromatolite Baicalia burra Preiss 1972 and a conical
stromatolite were reported from the upper part of the Tarcunyah Group (Stevens and Grey 1997)
The recognition of two stromatolite assemblages interpreted to have age significance in
Supersequence 1 sedimentary rocks of the Centralian Superbasin has permitted biostratigraphic
correlations between outcrop and well data The Acaciella australica assemblage appears to be
slightly older than 800 Ma and is restricted to the middle part of Supersequence 1 The Baicalia
burra assemblage is considered to be slightly younger than 800 Ma and occurs in the upper part
of Supersequence 1 (Grey 1996b Stevens and Grey 1997) The older A australica assemblage
is recognized in the Skates Hills Formation in the Savory Sub-basin and the stromatolite A
australica itself has been tentatively identified in the lower Tarcunyah Group The occurrence of
the A australica assemblage in the Woolnough Madley and Browne Formations of the Officer
Basin and in the Loves Creek Member of the Bitter Springs Formation of the Amadeus Basin
allows correlations throughout the Centralian Superbasin (Fig 4)
The younger B burra assemblage has not been recognized in sedimentary rocks of the
Savory Group as defined by Williams (1992) but it occurs in the upper parts of the Tarcunyah
Group and allows correlation of this group with outcrops of the Neale Formation and with the
Kanpa Formation in petroleum exploration well Hussar 1 both located in the central Officer Basin
of Western Australia (Fig 4) (Grey 1996b Stevens and Grey 1997) The occurrence of the B
burra assemblage in these units permits their correlation with the Burra Group in the Adelaide
Geosyncline of South Australia (K Grey unpublished data)
The Cornelia Formation and Kahrban Subgroup outcrop in the southeast of the sub-basin and
were considered by Williams (1992) to be part of the Mesoproterozoic Bangemall Basin Limited
evidence suggests that all or parts of these two units are of Neoproterozoic age The Ward and
Oldham Inliers consist of outcrops of the Cornelia Formation Waterbore TWB 6 which was
drilled on TRAINOR in the Cornelia Formation contains palynomorphs consistent with a
Supersequence 1 age (Grey and Stevens 1997) (Figs 5 and 6) In outcrop the Cornelia Formation
17
consists predominantly of sandstone and quartzite with lesser siltstone shale mudstone and chert
In Trainor 1 this formation consists predominantly of indurated mudstone with minor sandstone
chert and dolomite A major erosional unconformity separates the Cornelia Formation from
overlying formations and parts of the Cornelia Formation have been folded with dips exceeding
70deg In contrast the majority of the Savory Sub-basin sedimentary rocks have dips of less than 30deg
except where they are adjacent to faults The Cornelia Formation apparently consists of an older
unit of steeply dipping quartzites cherts and well-indurated mudstones and a younger unit of
shallower dipping sandstones which are sub-friable in parts However caution should be used in
interpreting the age of units based on their structural deformation and additional mapping and age
dating of this formation is required
It is proposed here that the Kahrban Subgroup is likely to be of early Neoproterozoic age and
hence should be considered as part of the greater Officer Basin This proposal is based largely on
the relatively low dip of the strata (generally less than 20deg) and their west-northwest strike which
is parallel with strikes in the overlying Brassey Range Formation of the Savory Group The lower
contact of the Kahrban Subgroup is obscured but is thought to be an unconfirmity on the
Earaheedy Basin on the southeast of STANLEY (Muhling and Brakel 1985)
Structural setting
The Savory Sub-basin forms the most northwesterly sub-basin of the Neoproterozoic to
Phanerozoic Officer Basin The western boundary of the sub-basin with the Mesoproterozoic
Bangemall Basin consists of steep-reverse and strike-slip faults The northeastern boundary of the
Savory Sub-basin was mapped where Supersequence 4 formations of the Savory Group
unconformably overlie sedimentary rocks of the Karara and Yeneena Basins with the two older
units considered to be part of the Paterson Orogen (Williams 1992) This contact was defined as a
series of steeply dipping reverse faults in the northernmost parts of the sub-basin on BALFOUR
DOWNS and RUDALL and was extrapolated as an inferred reverse fault farther along strike to the
southeast on GUNANYA and MADLEY where the contact is obscured by Cainozoic sediments It is
now recognized that all the sedimentary rocks in the Karara Basin and younger sedimentary rocks
of the Yeneena Basin are from the Supersequence 1 Tarcunyah Group and part of the greater
Officer Basin (Bagas et al 1995) The northern boundary of the Tarcunyah Group and the greater
Officer Basin is in thrust-and reverse-faulted contact with the Rudall Complex and other parts of
the Paterson Orogen (Fig 7)
To the south the sub-basin unconformably overlies the Bangemall Basin The eastern
boundary of the sub-basin used in this study is where Permian and younger strata of the Officer
Basin unconformably overlie Neoproterozoic strata although there are no significant structural or
stratigraphic differences between the Neoproterozoic units
18
The sub-basin is subdivided into three principal structural areas (Fig 1) Trainor Platform
Blake Fault and Fold Belt and Wells Foreland Sub-basin (Williams 1992) A major review of
these boundaries is beyond the scope of this report but the processing of regional aeromagnetic
data (Appendix 4) and acquisition of a semi-detailed gravity survey by the GSWA in the east of
the sub-basin has enabled these tectonic units to be reassessed and some modifications are
proposed
The Wells Foreland Sub-basin (originally termed the Wells Foreland Basin in Williams 1992)
and sedimentary rocks of the Tarcunyah Group are both considered to be the northwest
continuation of the Gibson Sub-basin of the Officer Basin Aeromagnetic gravity and outcrop
data suggest that the Blake Fault and Fold Belt is significantly faulted and folded in the west but
is less deformed in the east where the thickest sedimentary section in is located on BULLEN
(Appendix 4) The Trainor Platform is reinterpreted to represent an area of the sub-basin that has
undergone major compression during the Petermann Ranges Orogeny resulting in folding and
faulting with a northwest strike This interpretation contrasts with that proposed by Williams
(1992) who envisaged that only a thin section of the Savory Group was present on the platform
Perincek (1998) has recognized nine periods of tectonic activity in the Officer Basin from the
beginning of the Neoproterozoic to the end of the Cretaceous Three major tectonic episodes are
recognized in the Centralian Superbasin The oldest event is the Areyonga Movement which is
pre-Sturtian and forms the boundary between Supersequences 1 and 2 (Fig 4) The Souths Range
Movement occurred at the end of the Sturtian at the boundary between Supersequences 2 and 3
The youngest major event is the Petermann Ranges Orogeny which occured at the end of the
Marinoan and forms the boundary between Supersequences 3 and 4
One minor and two major tectonic episodes are recognized in the Savory Sub-basin the
LP1ALP1B structural event and the Areyonga Movement and the Petermann Ranges Orogeny
respectively The LP1ALP1B structural event is revealed where the Spearhole Formations rests
disconformably and locally unconformably on the Brassey Range Jilyili and Glass Spring
Formations The Neoproterozoic Areyonga Movement (equivalent to the Blake Movement of
Williams 1992) produced folds and faults with a general northeast strike in the western and
southern parts of the region The Souths Range Movement has not been recognized in the sub-
basin This may be due to the fact that no Sturtian glacial rocks have been identified and hence it
is possible that structures attributed to the Areyonga Movement could be the result of the Souths
Range Movement or a combination of the two movements
The major tectonic event recorded in the sub-basin is the latest Neoproterozoic to Cambrian
Petermann Ranges Orogeny (equivalent to the Paterson Orogeny) which produced large reverse
19
faults thrusts strike-slip faults and folds with a general northwest strike The McFadden
Formation and other Supersequence 4 strata are considered to be at least partially coeval with this
orogeny (Williams 1992) We also interpret the Durba Sandstone as having been deposited during
the later stages of the Petermann Ranges Orogeny as this unit mildly deformed with fold axes
parallel to the strike of other structures attributed to the Petermann Ranges Orogeny
Quantitative aeromagnetic interpretation of the Savory Sub-basin utilizing the 3D Euler
deconvolution method supported by wave-number filtering and image processing has provided
structural trends and depth to magnetic source within the sub-basin (Cowan 1995) Gravity data
are interpreted by Cowan (1995) as changes in both the density of the basement rocks andor
basement topography depending on local conditions Part of Cowanrsquos report is reproduced in
Appendix 4
Exploration history
The only petroleum exploration conducted in the sub-basin has been the recent drilling in the
western part of three diamond drillholes of which two have minor oil shows (Table 2) There has
been some mineral exploration the results of which are stored in the GSWA Western Australian
Mineral Exploration (WAMEX) database system Much of the mineral exploration was in the
southwest and west where the sub-basin is in contact with the Bangemall Basin and along the
northern margin of the sub-basin Many of these mineral exploration programs included
aeromagnetic surveys and surface geochemical sampling (Fig 8)
Hydrocarbon potential
The sub-basin contains a sedimentary succession up to 8 km thick which is generally gently
folded and faulted and apparently unmetamorphosed Limited drilling has shown that thick
mudstones are present in the sub-basin with some mudstones in Trainor 1 having high Total
Organic Carbon (TOC) values Outcrops of sub-friable sandstones in many of the formations
within the sub-basin suggests widespread reservoir potential Mudstone and inferred thick
evaporite sequences are likely to form seals Maturity data suggest that near-surface samples are
approximately at the base of the oil window and top of the gas window in parts of the north and
southeast of the sub-basin However parts of the southwest of the sub-basin and the mudstones in
Trainor 1 have very high levels of maturity Numerous faults and folds have been identified from
surface mapping suggesting good potential for large structural traps Minor oil shows in
20
Table 2 Neoproterozoic formations and hydrocarbon shows in diamond drillholes in the Savory Sub-basin
Drillhole AMG Core TD (m) Approx Formation Depth Formation Depth Formation Depth Shows (AGD84) start (m) GL (m) (m) (m) (m)
LDDH 1 431148E 112 701 350 Tarcunyah 68ndash701 ndash ndash bitumen at 6623 m 7443826N Group Trainor 1 473640E 6 709 455 McFadden 9ndash83 Cornelia Fm 83ndash709 possible bitumen at 4537 m 7287400N Fm Mundadjini 1 319056E 170 600 500 Mundadjini 16ndash361 Spearhole Fm 361ndash600 10 fluorescence at 36102 m 7404844N Fm Boondawari 1 348959E 299 1 367 490 Mundadjini Fm 15ndash312 Spearhole Fm 312ndash1 283 Intrusive 1 283ndash1 367 40 fluorescence at 35364 m 5 7398174N fluorescence at 4963 m Akubra 1 334249E 15 181 530 Mundadjini 15ndash42 Intrusive 42ndash181 None 7401252N Fm
21
50 km
120deg 121deg30 123deg
25deg
24deg
23deg
22deg
Greater Officer Basin
Savory Sub-basin
1
2
3
4
6
8
3 Seismic line (prefixed N83-00)
Aeromagnetic survey
GS
WA
Sav
ory
1995
gra
vity
sur
vey
Gravity survey
MKS34270398
Figure 8 Locations of aeromagnetic and gravity surveys (other than regional BMRAGSO data)
22
sandstones in two petroleum wells in the northwest of the sub-basin and bitumen and oil shows
elsewhere in the region indicate that oil has been generated and migrated through the sub-basin
Source rocks
Source potential is considered to be the major exploration risk in the Savory Sub-basin although
minor oil shows in Mundadjini 1 and Boondawari 1 indicate that at least some oil has been
generated and migrated into potential reservoirs within the sub-basin Sandstone is the
predominant lithology observed in outcrop Outcrops of fine-grained lithologies in the basin are
rare because of intense surface weathering and erosion Only about 8 of the surface area of the
sub-basin is exposed bedrock and recessive lithologies (such as shale evaporite and friable
sandstone) may be present although they rarely outcrop
Outcrops of stromatolitic dolomite with associated cauliflower chert and cubic pseudomorphs
interpreted as being after halite indicate that evaporitic environments are present within the
Mundadjini Skates Hills and Boondawari Formations Evaporitic minerals are also present in
drillhole LDDH1 in the Tarcunyah Group
In 1995 GSWA drilled a continuous-core diamond drillhole (Trainor 1) in the sub-basin on
TRAINOR to a depth of 709 m to test for source rocks thus providing the first such data for the sub-
basin The drillhole intersected flat-lying clastics and carbonates of the McFadden Formation (9ndash
83 m) overlying indurated mudstones of the Cornelia Formation (83ndash709 m total depth) dipping at
about 40deg Of the six samples analysed from the Cornelia Formation in this drillhole the five
located between 375 and 6032 m depth have TOC values exceeding 05 (range 066ndash365)
Rock-Eval pyrolysis of these five samples indicates that they are at best in the dry-gas thermal
stage and as a result of their high level of maturation (Stevens and Adamides in prep) have poor
remaining hydrocarbon-generating potential Although the Cornelia Formation is overmature at
Trainor 1 the high TOC values are encouraging as it is likely that this sequence is less mature
elsewhere in the sub-basin
The Mundadjini Formation contains potential source rocks that comprise marine mudstones
with evaporitic minerals present in parts Thin dark mudstones were intersected in the Mundadjini
Formation in Akubra 1 In Mundadjini 1 and Boondawari 1 however the mudstones appear to be
too oxidized to have source potential
The Boondawari Formation also may be a source rock as it contains black mudstones The
unit is laterally equivalent to the Pertatataka Formation of the Amadeus Basin and the Ungoolya
23
Group of the Officer Basin in South Australia both of which have some source potential
(Summons and Powell 1991 Morton and Drexel 1997) Samples from the Dey Dey Mudstone of
the Ungoolya Group generally have poor TOC values (average 011 range 003ndash081)
moderate hydrogen index (HI) values (100ndash382) and poor to fair genetic potential with a
maximum of 292 kg hydrocarbon per tonne of source rock (Morton and Drexel 1997)
Stromatolitic dolomites and mudstones at the top of the Boondawari Formation and within the
Skates Hills Formation are potential source rocks Stromatolitic dolomite and evaporitic rocks
deposited in a marginal marine to sabkha environment are considered to have good potential to
generate and preserve organic carbon without requiring a deep-water setting (Stevens and Grey
1997) Such conditions are recognized in the Skates Hills Formation and in the upper parts of the
Tarcunyah Group
Maturity
Knowledge of the maturity of sedimentary rocks within the Savory Sub-basin is still limited From
a review of palynological studies Grey and Stevens (1997) report that the thermal maturity
inferred from the Thermal Alteration Index (TAI) of 3+ from Supersequence 1 age palynomorphs
in TWB 6 TWB 9 and LDDH1 is within the hydrocarbon window (Appendix 3) In Phanerozoic
spores and pollen a TAI of 3+ approximately equates to the end of liquid petroleum generation
and the start of dry gas generation and to a vitrinite reflectance of about 13 (Traverse 1988)
However the use of TAI for estimating thermal maturity from Neoproterozoic palynomorphs
requires calibration
In Trainor 1 the Cornelia Formation contains organically rich claystones between 375 and
6032 m depth Based on Rock-Eval maturity data (Stevens and Adamides in prep) and the dark
colour of poorly preserved organic material (Grey 1995de 1996) with TAI 4- to 5 all samples
had a high level of maturation with at best dry-gas generating potential remaining In contrast
drillhole LDDH1 on GUNANYA recorded lower levels of maturity (TAI values of 3+) with two of
sixteen samples from the Tarcunyah Group having greater than 1 TOC (Grey 1995abc Grey
and Cotter 1996) Organic petrology and Rock-Eval maturity data for samples from LDDH1
indicate that the section above 500 m is within the oil-generative window whereas below 500 m
the rocks are within the gas window (Ghori in prep Fig 9 Appendix 5)
Waterbores TWB 1 2 6 and 9 which are located on TRAINOR in the southeast of the sub-
basin all had organic matter with TAI values of 3+ from the McFadden Skates Hills Cornelia
and Brassey Range Formations respectively
24
100
200
300
400
500
600
700
Oil
gene
ratin
g
Gas
gene
ratin
g
Fai
r
Fai
r
Poo
r
Poo
r
Goo
d
Imm
atur
e
Oil
win
dow
Oil
win
dow
Imm
atur
e
01 0110 10 0 150 300 440 480 1
Neo
prot
eroz
oic
TOC S1+S2 mgg Hydrogen Index Tmax degC
Depth(m)
Organicrichness
Generatingpotential
Kerogentype Maturity Maturity
TD=701m
Sandstone
Mudstone
Dolomite
Limestone
Evaporite
Source rock
MKS40 070498
Ro equivalent
Figure 9 Petroleum source potential of rocks in Normandy LDDH1
Small amounts of organic matter associated with basalt and dolerite in cuttings from
waterbore BWB 1 on BULLEN showed high levels of thermal maturity (Grey 1995a Libby 1995)
It is unclear whether all sedimentary rocks on BULLEN are overmature for hydrocarbon generation
or the results from BWB 1 are related to local heating events associated with the volcanic bodies
that are common in the Jilyili Formation
25
Reservoirs
Each of the five depositional sequences of the Savory Group (Table 1) are inferred to contain
significant sandstone reservoirs with the possible exception of depositional sequence C as
discussed above in Stratigraphy The Spearhole Formation was cored in Mundadjini 1 and
Boondawari 1 and visual estimates of porosity vary from generally poor (less than 5) to fair
(approximately 5ndash15) The McFadden Formation in Trainor 1 has porosity values of up to 232
and a maximum permeability of 195 md (Stevens and Adamides in prep) Sandstones from
Neoproterozoic formations form the acquifers in the following waterbores the McFadden
Formation in TWB 1 the Cornelia Formation in TWB 6 and the Brassey Range Formation in
TWB 8 and TWB 9 (Appendix 6 Table 61)
Based on outcrop observations the Durba Sandstone is considered to be the best reservoir of
the Savory Group Similarly some sandstones from the Tarcunyah Group also have good visible
porosity in outcrop
Dolomites occur in several formations in the sub-basin Reservoir potential may exist
particularly where the dolomites are stromatolitic and oolitic However dolomites have not been
drilled in the sub-basin and porosity can only be inferred from the preferential silicification of
some stromatolite bioherms observed in outcrop (Stevens and Grey 1997) Elsewhere in the
Officer Basin porosities of up to10 have been measured in dolomites A limestone breccia
(karst) is described from 663 to 677 m in drillhole LDDH1 (Fig 6 Busbridge 1994)
Seals
Indications of evaporitic environments in the Mundadjini Skates Hills and Boondawari
Formations are described by Williams (1992) In Mundadjini 1 from 287 to 337 m anhydrite and
chert occurs as nodules beds and veins in mudstone of the Mundadjini Formation Evaporitic
minerals (predominantly gypsum) are described in the Tarcunyah Group in LDDH1 The presence
of the Woolnough and Madley salt diapirs in the Officer Basin (approximately 110 km east of the
sub-basin) and halite beds over 25 m thick in the well Hussar 1 (130 km east of the sub-basin)
provide further evidence that evaporite seals may be present in the Savory Sub-basin
Mudstones and shales form only a small proportion of the limited Neoproterozoic outcrop in
the sub-basin but significant thicknesses of mudstone were encountered in the Mundadjini
Formation in Mundadjini 1 and Boondawari 1 the Tarcunyah Group in LDDH1 and in the
26
Cornelia Formation in Trainor 1 These data suggest that mudstones form a significant proportion
of strata in the sub-basin despite their limited outcrop
Traps
Potential structural closures including folds and faults occur at various scales throughout the
Savory Sub-basin However the region has only been mapped at 1250 000 scale and
independently closed structures such as domes have yet to be confirmed The western margin of
the basin contains abundant faults (with a northeast strike) but elsewhere faults are less common
Some anticlines are recognized in outcrop including one with a strike length of up to 45 km
inferred from surface bedding dips in the Mundadjini and Spearhole Formations at approximately
24deg15rsquoS 121deg10rsquoE on BULLEN (Fig 1)
Salt diapirs and other halokinetic structures are recognized in outcrop well and seismic data
in the Officer Basin to the west of the Savory Sub-basin and it is probable that there are
significant thicknesses of evaporitic sedimentary rocks in the sub-basin The gravity field data
suggest there is good potential for salt diapirs and traps related to halokinesis
Although there is potential for stratigraphic traps to be present in the sub-basin insufficient
data are available to assess them
Preservation of hydrocarbons
The range of thermal maturities measured to date and the large periods of time envisaged for
deposition of sediments implies hydrocarbon generation may have occurred a number of times
during the evolution of the Savory Sub-basin Any hydrocarbons that were generated early may
have been trapped in palaeostructures and remigration to younger traps could have taken place
later The Petermann Ranges Orogeny which has been equated with the Paterson Orogeny (Myers
1990) is believed to have occurred in the latest Neoproterozoic to early Cambrian This is the last
major tectonic event recognized in the sub-basin suggesting that it is reasonable to expect that trap
integrity will have been preserved
If the inference of the presence of thick halite beds in the sub-basin is correct the preservation
potential of sub-salt traps should be excellent
27
Reported hydrocarbon shows and oil seep
Amadeus Petroleum recorded minor oil shows in cores from Mundadjini 1 and Boondawari 1 In
Mundadjini 1 at 36102 m (top of the Spearhole Formation) a 3 mm thick zone had 10 moderate
white fluorescence with slow solvent cut This show was in a granular sandstone with visually
estimated porosity of about 10 In Boondawari 1 at 35364 m (within the Spearhole Formation) a
broken surface of sandstone had 40 moderate yellow-white fluorescence with slow solvent cut
Visually estimated porosity is about 5 Because the fluorescing surface was broken during the
drilling process this show could have resulted from contamination A second show occurs in
Boondawari 1 at 4963 m (within the Spearhole Formation) where a 1 cm-thick zone had 5 dull
yellow fluorescence with slow solvent cut in a conglomerate with visually estimated porosity of
about 10 The company intends to further investigate the nature of these occurrences
Minor bitumen is present at 6623 m in drillhole LDDH1 on GUNANYA (Figs 5 and 6) as a
vein in mudstones of the Tarcunyah Group A sample was analysed by gas chromatography
(Ghori in prep) and confirmed that it is natural bitumen (Appendix 5)
Mineral hole OD 23 drilled by Jubilee Gold Mines NL on NABBERU in the Bangemall Basin
immediately to the south of the Savory Sub-basin (Fig 5) encountered bitumen and trace oil in
vugs in dolomite (M Stevens unpublished data) but no further data are available at present
In their popular guide to the Canning Stock Route Gard and Gard (1990 p 218) refer to an
oil seep at Well 13 on TRAINOR (Fig 5) They reported that between 1977 and 1984 lsquonatural oilrsquo
was seen in the well Although the well is now largely filled with sediment four auger drill
samples were collected by the GSWA in 1995 and all four were analysed for oil shows One
sample from 315 m total depth (GSWA sample 135604) yielded just enough extract (519 ppm)
for saturate gas chromatography analysis The gas chromatograph (Appendix 5) shows that the
extract does contain some hydrocarbons probably from recent plant material Because the depth to
the oil was not quoted in Gard and Gard (1990) the hand-augered well may not have been deep
enough to properly test this reported seep
Geological and geophysical databases
Geological and geophysical data available for the Savory Sub-basin are limited The most recently
completed geological maps for the sub-basin were published by the GSWA between 1991 and
1995 (Williams and Tyler 1991 Williams 1992 1995ab)
28
The cores from the five drillholes listed in Table 2 believed to be all of the core available
from the sub-basin are available for inspection at GSWA Mineral exploration reports submitted
to GSWA may be searched using the WAMEX database and open-file reports are available on
microfiche Geophysical data acquired by the mining industry is not required to be filed with
GSWA if acquired over Vacant Crown Land which is the case for much of the sub-basin
Geophysical survey data submitted in mining tenement reports and which extend into Vacant
Crown Land remain confidential to the companies Original regional aeromagnetic and gravity
datasets are available from the Australian Geological Survey Organisation (AGSO)
Data pertinent to oil exploration in the sub-basin such as structural style and salt diapirism
are presented in a review of the hydrocarbon prospectivity of the Officer Basin (Perincek 1998)
Drilling
Significant drillholes in the sub-basin are summarized in Table 2
Petroleum industry data
Amadeus Petroleum drilled three petroleum exploration wells in the central west of the Savory
Sub-basin in late 1997 These wells Mundadjini 1 Boondawari 1 and Akubra 1 were drilled by
continuous diamond coring (Figs 5 and 6) All targeted potential reservoirs within the Spearhole
Formation with the Mundadjini Formation as the proposed seal The wells were located on
structures interpreted from Landsat images and limited geological investigations Both Mundadjini
1 and Boondawari 1 had minor oil shows as discussed above (Reported hydrocarbon shows)
Government data
Stratigraphic drillhole Trainor 1 was drilled by GSWA in 1995 (Stevens and Adamides in prep)
and the main results are discussed above (Source rocks and Maturity)
Mineral industry data
Normandy Exploration drillhole LDDH1 was cored in the Tarcunyah Group to a total depth of
701 m and provided source-rock and maturity data as discussed above
29
Oilmin NL drilled six percussion drillholes (BD 1 3 4 5 8 and 9) through sandstones and
shales in the northern part of the Savory Sub-basin to a maximum depth of 198 m (Fig 5
WAMEX Microfiche File M 26811 I 2610) but only brief geological descriptions are available
Hydrogeological data
Hydrogeological data within the Savory Sub-basin are limited although a long history of water
exploration extends back to the construction of the Canning Stock Route early this century No
detailed geological or wireline logs are available for the older wells along this route A few station
wells have been drilled by various methods on the south and west margins of the basin but data
are unavailable as reports are not required to be filed with the government Depth to watertable
throughout the basin is largely controlled by porosity of the bedrock
The GSWA drilled fifteen waterbores in the winter of 1995 in the southern part of the sub-
basin in preparation for the drilling of Trainor 1 and the proposed Bullen 1 Twelve bores found
water and six of these bores have salinities of less than 1000 mgL (Fig 5 Appendix 6 Table 61)
One waterbore TWB 6 has gamma ray and neutron logs run through PVC casing and these are
available from the GSWA with the digital log data included herein
Seismic data
No geophysical data have been acquired by the petroleum industry in the Savory Sub-basin
Seismic data acquired in the Officer Basin to the east particularly in the Gibson and Yowalga
Sub-basins is pertinent to structural interpretation in the Savory Sub-basin (Perincek 1996a
1998)
Aeromagnetic surveys
Government data
There are over 95 277 line kilometres of aeromagnetic data included in the AGSO dataset There
are three regional aeromagnetic surveys covering the Savory Sub-basin These were flown by the
Bureau of Mineral Resources (BMR now AGSO) in 1984 at a line spacing of 1500 m with 36 740
and 52 587 line kilometres flown and by Aerodata in 1984 at a line spacing of 1000m with 5950
line kilometres flown These data were reprocessed and interpreted for GSWA by Cowan (1995)
An edited copy of this report is included as Appendix 4 and the original report is filed in the
GSWA Library under S-series reports item 10331
30
Mineral industry data
The approximate locations of non-AGSO aeromagnetic surveys are shown in Figure 8 More
detailed information regarding the location of these surveys may be obtained using the GSWA
MAGCAT II database Additional information such as contours of aeromagnetic values may be
obtained by inspecting items on file with the GSWA
Gravity surveys
Government data
The average spacing for gravity data in the Savory Sub-basin is one station per 121 km2 (11 times 11
km grid) These data were principally collected by BMR in the early 1960s There are a few
additional regional gravity traverses across the sub-basin which are also included in the
BMRAGSO dataset These data were reprocessed and interpreted for GSWA (Fig 10) and a
report on this work is also included in Appendix 4
The GSWA completed a large semi-detailed gravity survey in the eastern Savory Sub-basin
utilizing helicopter support and Differential Global Positioning Survey (DGPS) techniques (Fig
8) This gravity survey completed in August 1995 consists of 2300 gravity stations on a 2 times 3 km
grid All stations were acquired by helicopter using Scintrex gravimeters and Ashtek dual
frequency DGPS equipment for determining location This highly efficient system allowed the
acquisition of more than 100 gravity stations per day in remote areas The resolution of this survey
is +30 cm and +05 microms-2 (Daishsat 1995) These data (Fig 11) represent a significant
improvement on the previous regional survey data and are available from GSWA (GSWA
1996ab) The results of the interpretation of these data were presented at the 1997 ASEG
Convention (Carlsen and Shevchenko 1997)
Mineral industry data
Three small gravity surveys were conducted by Oilmin NL (Fig 8) and the relevant WAMEX
reports are M 2681I 2610 I 2435 I 2567 These three surveys are of limited value because height
control was provided by barometers only and the surveys were not tied to the national gravity grid
31
23deg
25deg
120deg 122deg
Trainor 1
SAVORY
SUB-BASIN
MKS54 160498
100 km
1995 SavoryGravity Survey
254
-1056
micromsec2
Figure 10 Regional Bouguer gravity map of the Savory Sub-basin
23deg
24deg
25deg
122deg30 123deg
TRAINOR 1
123deg30
50 km
MKS53 160498
-116
-626
micro msec2
Figure11 Detailed Bouguer gravity map of the
Savory 1995 Gravity Survey from the eastern Savory Sub-basin
32
Government and academic reports
Chronostratigraphy and geochemistry
The understanding of Neoproterozoic organic chemistry palynology and structural evolution is
essential to the interpretation of hydrocarbon prospectivity Pertinent reports are included in the
bibliography (Appendix 1) Unpublished palaeontology reports describe the palynology of wells in
the Savory Sub-basin (Grey 1995andashe 1996a) Grey and Cotter (1996) discussed the potential for
Neoproterozoic palynomorphs to provide a biostratigraphic framework and palaeoenvironmental
interpretation Grey and Stevens (1997) reviewed the results of palynological studies of wells
drilled in the sub-basin and reported that Supersequence 1 palynomorphs are present in TWB 6
TWB 9 and LDDH1 (Appendix 3) Grey (1996b) reported on the use of stromatolites for
correlation in the Neoproterozoic and Stevens and Grey (1997) discussed the application of
stromatolite biostratigraphy in correlating isolated dolomite outcrops in the sub-basin with well
and seismic data in the Officer Basin and Centralian Superbasin
Although geochemical data from the Savory Sub-basin are very limited results mostly
confirm thermal maturities inferred from TAI for LDDH1 and Trainor 1 (Ghori in prep Stevens
and Adamides in prep) Those parts of the Officer Basin in Western Australia which lie to the
east of the Savory Sub-basin are sparsely drilled but Ghori (in prep) reports that most of the
Neoproterozoic succession presently lies within the oil-generative window However his study
has been unable to identify effective source-rock units and the source for oil shows Thin source
rocks are present in the Neoproterozoic in LDDH1 (Fig 9) and in three wells which lie to the east
and southeast of the Savory Sub-basin namely NJD 1 Kanpa 1A and Yowalga 3
Proposed work program
From the above limited information it is concluded that additional research on the hydrocarbon
potential of the sub-basin is justified and proposals are outlined below
bull Additional modelling of gravity and aeromagnetic data from the Savory Sub-basin is required
in light of the results from Trainor 1 and Boondawari 1 Trainor 1 showed that what appeared
to be a structurally simple area based on outcrop aeromagnetic and gravity data was in fact an
area of major structuring Boondawari 1 intersected a dolerite which is in good depth
agreement with aeromagnetic depth to source results showing this technique is useful in
detecting the depth to intrusive bodies
33
bull Additional data from mineral and petroleum exploration bores may become available and
analysis of samples from these wells should be undertaken and interpreted in the context of
their relevance to the Officer Basin
bull Stratigraphic coring in the Blake Fault and Fold Belt and in the Wells Foreland Sub-basin (Fig
1) targeting source rocks is considered essential to the continuing evaluation of the
hydrocarbon prospectivity of the Savory Sub-basin
bull Correlations using at least outcrop well and potential-field data should be prepared to link the
sub-basin with the better known parts of the Officer Basin to the east
bull Remapping is required to clarify boundary positions within the Cornelia Formation this may
resolve some of the current problems of the relationship between this unit and the rest of the
Savory Sub-basin
bull Further work is required to explain the Early Cambrian or Sturtian ages interpreted for the
Cornelia Formation from sedimentary zircon UndashPb dating in drillhole Trainor 1 The
determination of the age of the organically rich but overmature claystones in this well is
critical to assessing the hydrocarbon potential of the region
bull The thin dark mudstones intersected by Akubra 1 in the Mundadjini Formation warrant
geochemical analysis Analyses of the oil shows in Mundadjini 1 and Boondawari 1 are
currently being undertaken by Amadeus Petroleum
bull Geochemical analysis of hydrocarbons in the Bangemall Basin drillhole OD23 has been
performed by Jubilee Gold and the results will be reviewed when they are submitted to
GSWA The possibility of source rocks within the Bangemall Basin charging traps within the
Bangemall Basin and the overlying Savory Sub-basin requires further investigation
Conclusions
The Savory Sub-basin is a frontier region with only three recently drilled petroleum exploration
wells and no seismic data Based on existing geological and geophysical data it is considered too
early to draw conclusions about the hydrocarbon prospectivity of the sub-basin at this stage and
there are several reasons why the area warrants further investigation
34
1 Thick accumulations of sedimentary rocks are present (up to 8 km thickness inferred) which
may contain source reservoir and sealing strata
2 Minor oil shows occur in Mundadjini 1 and Boondawari 1 and bitumen is present in mineral
exploration drillhole LDDH1 suggesting that hydrocarbons have migrated within the
Neoproterozoic sequence of the Savory Sub-basin Oil and bitumen are present in mineral
exploration drillhole OD23 in the Bangemall Basin immediately to the south of the Savory
Sub-basin and it is possible that source rocks from the Bangemall Basin could charge traps in
the overlying Savory Sub-basin
3 The age of sedimentary rocks in the sub-basin is still poorly constrained but some of the
Neoproterozoic sedimentary rocks located on GUNANYA and TRAINOR are within the
hydrocarbon-generation window It is possible that a significant thickness of Phanerozoic
sedimentary rocks may also be present
4 Friable sandstones with visible porosity outcrop extensively suggesting numerous potential
reservoirs
5 Significant but not intense faulting and folding has been mapped implying large structural
traps may be present
6 Evaporitic sedimentary rocks occur in several formations and may provide good source rocks
and excellent seals
35
References
APAK S N and CARLSEN G M 1997 A compilation and review of data pertaining to the
hydrocarbon prospectivity of the Canning Basin Western Australia Geological Survey
Record 199610 103p
BAGAS L GREY K and WILLIAMS I R 1995 Reappraisal of the Paterson Orogen and
Savory Basin Western Australia Geological Survey Annual Review 1994ndash95 p 55ndash63
BUSBRIDGE M 1994 Lake Disappointment Exploration Licence 451064 Third Annual
Report Lake Disappointment Diamond Drill Hole LDDH1 Normandy Exploration Limited
Western Australia Geological Survey M-series Item 7567 A41358 (unpublished)
CARLSEN G M and SHEVCHENKO S I 1997 Petroleum exploration in Proterozoic basins
using potential fields data and stratigraphic coring Australian Society of Exploration
Geophysicists 12th Geophysical Conference Handbook Sydney 1997 Preview no 66 p 83
(abstract only)
COWAN D 1995 Savory Basin quantitative magnetic interpretation Western Australia
Geological Survey S-series S10331 (unpublished)
DAISHSAT PTY LTD 1995 Operational and processing report Savory Basin gravity survey
Western Australia Geological Survey S-series S10332 (unpublished)
GARD E and GARD R 1990 Canning Stock Route a travellerrsquos guide for a journey through
history Perth Western Australia Western Desert Guides 448p
GEOLOGICAL SURVEY OF WESTERN AUSTRALIA 1996a Savory Basin first vertical
derivative of Bouguer gravity image 1250 000 Western Australia Geological Survey
GEOLOGICAL SURVEY OF WESTERN AUSTRALIA 1996b Savory Basin Bouguer gravity
image 1250 000 Western Australia Geological Survey
GHORI K A R in prep Petroleum source rock potential and thermal history Officer Basin
Western Australia Western Australia Geological Survey Record
36
GREY K 1995a Savory Basin drillhole BWB 1 (Bullen waterbore) palynology and thermal
maturation GSWA Palaeontology Report no 199512 (unpublished)
GREY K 1995b Savory Basin drillholes TWB 1 2 6 9 (Trainor waterbores) palynology and
thermal maturation GSWA Palaeontology Report no 199520 (unpublished)
GREY K 1995c Palynology of Normandy-Poseidon Lake Disappointment-1 corehole
Tarcunyah Group Paterson Orogen GSWA Palaeontology Report no 199521 (unpublished)
GREY K 1995d Savory Basin drillhole Trainor 1 (Trainor diamond drilling) palynology and
thermal maturity GSWA Palaeontology Report no 199524 (unpublished)
GREY K 1995e Savory Basin drillhole Trainor 1 (Trainor diamond drilling) Additional
Preparation of two samples GSWA Palaeontology Report no 199528 (unpublished)
GREY K 1995f Neoproterozoic stromatolites from the Skates Hills Formation Savory Basin
Western Australia and a review of the distribution of Acaciella australica Australian Journal
of Earth Sciences v 42 p 123ndash132
GREY K 1996a Savory Basin drillhole Trainor 1 (Trainor diamond drilling) Additional
samples palynology and thermal maturation GSWA Palaeontology Report no 199615
(unpublished)
GREY K 1996b Preliminary stromatolite correlations for the Neoproterozoic of the Officer
Basin and a review of Australia-wide correlations GSWA Palaeontology Report no 199615
(unpublished)
GREY K and COTTER K L 1996 Palynology in the search for Proterozoic hydrocarbons
Western Australia Geological Survey Annual Review for 1995ndash96 p 70ndash80
GREY K and STEVENS M K 1997 Neoproterozoic palynomorphs of the Savory Sub-basin
Western Australia and their relevance to petroleum exploration Western Australia
Geological Survey Annual Review for 1996ndash97 p 49ndash54
HUBBARD R J PAPE J and ROBERTS D G 1985 Depositional sequence mapping as a
technique to establish tectonic and stratigraphic framework and evaluate hydrocarbon
potential on a passive continental margin in Seismic stratigraphy II an integrated approach
37
edited by O R BERG and D G WOOLVERTON American Association of Petroleum
Geologists Memoir 39 p 79ndash91
LIBBY WG 1995 A petrological report on six samples of bore cuttings from the Savory Basin
Western Australia Western Australia Geological Survey S-series S31307 (unpublished)
MORTON JGG and DREXEL JF 1997 The petroleum geology of South Australia Vol 3
Officer Basin South Australia Department of Mines and Energy Resources Report Book
9719
MUHLING P C and BRAKEL A T 1985 Geology of the Bangemall Group mdash the evolution
of an intracratonic Proterozoic basin Western Australia Geological Survey Bulletin 128
219p
MYERS J S 1990 Precambrian tectonic evolution of part of Gondwana southwestern Australia
Geology v18 p 537ndash540
NELSON D R 1997 Compilation of SHRIMP UndashPb zircon data Western Australia Geological
Survey Record 19972 196p
PAYTON C E 1977 Seismic stratigraphy mdash applications to hydrocarbon exploration
American Association of Petroleum Geologists Memoir 26 516p
PERINCEK D 1996a The age of NeoproterozoicndashPalaeozoic sediments within the Officer Basin
of the Centralian Super-basin can be constrained by major sequence-bounding unconformities
APPEA Journal v 36 pt 1 p 350ndash368
PERINCEK D 1996b The stratigraphic and structural development of the Officer Basin
Western Australia a review Western Australia Geological Survey Annual Review 1995ndash
1996 p 135ndash148
PERINCEK D 1998 A compilation and review of data pertaining to the hydrocarbon
prospectivity of the Officer Basin Western Australia Geological Survey Record 19976
POSAMENTIER H W JERSEY M T and VAIL P R 1988 Eustatic controls on clastic
deposition 1 mdash Conceptual framework in Sea-level changes an integrated approach edited by
C K WILGUS B S HASTINGS C G St C KENDALL H W POSAMENTIER
38
C A ROSS and J C VAN WAGONER Society of Economic Paleontologists and
Mineralogists Special Publication no 42
STEVENS M K and ADAMIDES N G in prep GSWA Trainor 1 well completion report
Savory Sub-basin Officer Basin Western Australia with notes on petroleum and mineral
potential Western Australia Geological Survey Record 199612
STEVENS M K and GREY K 1997 Skates Hills Formation and Tarcunyah Group Officer
Basin mdash carbonate cycles stratigraphic position and hydrocarbon prospectivity Western
Australia Geological Survey Annual Review for 1996ndash97 p 55ndash60
SUMMONS RE and POWELL C McA 1991 Petroleum source rocks of the Amadeus Basin
in Geological and geophysical studies in the Amadeus Basin central Australia edited by R J
KORSCH and JM KENNARD Australia BMR Geology and Geophysics Bulletin 236
TRAVERSE A 1988 Palaeopalynology Boston Unwin Hyman 600p
VAIL P R MITCHUM R M Jr TODD R G WIDMIER J M THOMPSON S III
SANGREE J B BUBB J N and HATLELID W G 1977 Seismic stratigraphy and
global changes of sea level in Seismic stratigraphy mdash applications to hydrocarbon
exploration edited by C E PAYTON American Association of Petroleum Geologists
Memoir 26 516p
WALTER M R and GORTER J 1994 The Neoproterozoic Centralian Superbasin in Western
Australia the Savory and Officer Basins in The sedimentary basins of Western Australia
edited by P G PURCELL and R R PURCELL Petroleum Exploration Society of Australia
Symposium Perth WA 1994 Proceedings p851ndash864
WALTER M R GREY K WILLIAMS I R and CALVER C R 1994 Stratigraphy of the
Neoproterozoic to early Palaeozoic Savory Basin and correlation with the Amadeus and
Officer Basins Australian Journal of Earth Sciences v 41 p 533ndash546
WALTER M R VEEVERS J J CALVER C R and GREY K 1995 Neoproterozoic
stratigraphy of the Centralian Superbasin Australia Precambrian Research v 73 p 173ndash195
WILLIAMS I R 1992 Geology of the Savory Basin Western Australia Western Australia
Geological Survey Bulletin 141 115p
39
WILLIAMS I R 1995a Bullen WA (2nd Edition) Western Australia Geological Survey
1250 000 Geological Series Explanatory Notes 23p
WILLIAMS I R 1995b Trainor WA (2nd Edition) Western Australia Geological Survey
1250 000 Geological Series Explanatory Notes 31p
WILLIAMS I R and TYLER I M 1991 Robertson WA (2nd edition) Western Australia
Geological Survey 1250 000 Geological Series Explanatory Notes 36p
40
41
Appendix 1
Bibliography
Reports which are relevant to this investigation but which are not specifically cited are listed
below
BAILLIE P W POWELL C McA LI Z X and RYALL A M 1994 The tectonic
framework of Western Australiarsquos Neoproterozoic to recent sedimentary basins in The
sedimentary basins of Western Australia edited by P G PURCELL and R R PURCELL
Petroleum Exploration Society of Australia Symposium Perth WA 1994 Proceedings p
45ndash62
BRADSHAW M T BRADSHAW J MURRAY A P NEEDHAM D J SPENCER L
SUMMONS R E WILMOT J and WINN S 1994 Petroleum systems in West Australian
basins in The sedimentary basins of Western Australia edited by P G PURCELL and R R
PURCELL Petroleum Exploration Society of Australia Symposium Perth WA 1994
Proceedings p 93ndash118
CLARKE G L 1991 Proterozoic tectonic reworking in the Rudall Complex Western Australia
Australian Journal of Earth Science v38 p 31ndash44
COCKBAIN A E and HOCKING R M 1990 Phanerozoic in Geology and mineral resources
of Western Australia Western Australia Geological Survey Memoir 3 p 750ndash755
ETHERIDGE M and WALL V 1994 Tectonic and structural evolution of the Australian
Proterozoic 12th Australian Geological Convention Geological Society of Australia
Abstracts no 37 p 102ndash103
GOODE A D T 1981 Proterozoic geology of Western Australia in Precambrian of the
Southern Hemisphere Developments in Precambrian geology 2 edited by I R HUNTER
Amsterdam Elsevier p 105ndash203
GREY K and JACKSON M J 1983 A re-assessment of stromatolite evidence for the
correlation of the Late Proterozoic Neale and Ilma Beds Officer Basin Western Australia
Australia BMR Journal of Australian Geology and Geophysics v 8 p 359
42
HICKMAN A H WILLIAMS I R and BAGAS L 1994 Proterozoic geology and
mineralization of the TelferndashRudall region Paterson Orogen Geological Society of Australia
(WA Division) Excursion Guidebook no 5 56p
HOCKING R M MORY A J and WILLIAMS I R 1994 An atlas of Neoproterozoic and
Phanerozoic basins of Western Australia in The sedimentary basins of Western Australia
edited by P G PURCELL and R R PURCELL Petroleum Exploration Society of Australia
Symposium Perth WA 1994 Proceedings p 21ndash 44
JACKSON P R 1966 Geology and review of exploration Officer Basin Western Australia
Hunt Oil Company Western Australia Geological Survey S-series S26 (unpublished)
JACKSON M J 1971 Notes on a geological reconnaissance of the Officer Basin Western
Australia Australia BMR Geology and Geophysics Record 19715 30p
JACKSON M J and van de GRAAFF W J E 1981 Geology of the Officer Basin Western
Australia Australia BMR Geology and Geophysics Bulletin 206 102 p
LOWRY D C JACKSON M J van de GRAAFF W J E and KENNEWELL P J 1971
Preliminary result of geological mapping in the Officer Basin Western Australia Western
Australia Geological Survey Annual Report for 1971 p 50ndash56
MYERS J S 1990 Precambrian in Geology and mineral resources of Western Australia
Western Australia Geological Survey Memoir 3 p 737ndash750
MYERS J S SHAW R D and TYLER I M 1994 Proterozoic tectonic evolution of
Australia 12th Australian Geological Convention Geological Society of Australia Abstracts
no 37 p 312
NEDIN C and JENKINS R J F 1991 Re-evaluation of unconformities separating the
lsquoEdiacaranrsquo and Cambrian systems South Australia Palaios v 6 p 102ndash108
PHILLIPS B J JAMES A W and PHILIP G M 1985 The geology and hydrocarbon
potential of the north-western Officer Basin APEA Journal 25 (1) p 52ndash61
POWELL C McA LI Z X McELHINNY M W MEERT J G and PARK J K 1993
Paleomagnetic constraints on timing of the Neoproterozoic breakup of Rodinia and Cambrian
formation of Gondwana Geology v 21 p 889ndash892
43
POWELL C McA PREISS W V GATEHOUSE C G KRAPEZ B and LI Z X 1994
South Australian record of a Rodinian epicontinental basin and its mid-Neoproterozoic
breakup to form the Palaeo-Pacific Ocean Tectonophysics v 237 no 3ndash4 p 113ndash140
PREISS W V 1976 Proterozoic stromatolites from the Nabberu and Officer Basins Western
Australia and their biostratigraphic significance South Australia Geological Survey Report
of Investigations no 47 p 1ndash51
TOWNSON W G 1985 The subsurface geology of the western Officer Basin mdash results of
Shellrsquos 1980ndash1984 petroleum exploration campaign APEA Journal v 25 (1) p 34ndash51
WATTS K J 1982 The geology of the Townsend Quartzite Upper Proterozoic shallow water
deposit of the Northern Officer Basin Western Australia Perth University of Western
Australia BSc honours thesis (unpublished)
WELLS A T and KENNEWELL P J 1974 Evaporite exploration in the Officer Basin
Western Australia at the Madley Diapirs Australia BMR Record 1974194 (unpublished)
WILLIAMS I R and MYERS J S 1990 Paterson Orogen in Geology and mineral resources
of Western Australia Western Australia Geological Survey Memoir 3 p 274ndash286
WILLIAMS I R 1990 Savory Basin in Geology and mineral resources of Western Australia
Western Australia Geological Survey Memoir 3 p 329ndash334
WILLIAMS I R 1994 The Neoproterozoic Savory Basin Western Australia in The
sedimentary basins of Western Australia edited by P G PURCELL and R R PURCELL
Petroleum Exploration Society of Australia Symposium Perth WA 1994 Proceedings p
841ndash850
WILSON R B 1967 Woolnough Hills and Madley diapiric structures Gibson Desert WA
APEA Journal v 7 p 94ndash102
44
Appendix 2
Meteorological data (from Bureau of Meteorology Perth 1994)
Table 21 Wiluna rainfall (mm)
Year Jan Feb Mar Apr May Jun Jul Aug Sept Oct Nov Dec
1975 0 45 446 309 306 59 276 4 34 886 638 164 1976 16 154 12 138 53 16 34 62 12 238 0 2 1977 44 0 66 74 68 95 24 363 1 58 12 727 1978 234 522 94 16 0 96 367 24 16 353 185 45 1979 19 173 122 88 91 4 0 246 58 0 169 114 1980 148 764 68 1081 259 626 629 06 56 02 174 0 1981 123 476 192 32 196 118 44 74 14 0 28 312 1982 374 705 206 244 1079 92 02 143 368 526 368 118 1983 1 112 928 248 0 212 56 32 5 1 42 496 1984 149 7 342 84 836 0 348 132 224 04 16 172 1985 596 483 0 166 556 0 514 56 0 0 4 0 1986 0 154 35 0 0 1085 23 01 239 137 0 04 1987 1204 119 19 89 17 575 154 126 07 1 0 398 1988 46 202 164 13 388 0 202 104 0 0 224 1309 1989 207 234 26 703 278 536 57 0 01 0 144 02 1990 1035 23 281 46 126 53 94 218 44 9 42 0 1991 48 0 41 45 0 472 297 12 0 1 0 7 1992 112 96 1025 1227 323 65 04 174 0 132 48 4 1993 0 697 0 202 445 0 12 306 18 05 14 33 Mean 25 35 22 27 27 25 18 12 6 13 13 21
JAN FEB MAR APR MAY JUN JUL AUG SEP OCT NOV DEC0
10
20
30
40
Mea
n R
ain
fall
(mm
)
Month
Mean monthly rainfall in Wiluna
MKS41 140498
45
Table 22 Wiluna minimum temperature (degC)
Year Jan Feb Mar Apr May Jun Jul Aug Sept Oct Nov Dec
1975 ndash 23 203 15 94 63 71 62 103 124 169 205 1976 242 229 194 15 10 63 59 73 95 143 16 228 1977 243 25 197 148 96 95 56 86 102 ndash 188 23 1978 241 232 203 18 102 64 76 8 9 152 19 205 1979 255 226 216 167 83 6 59 79 97 145 198 223 1980 255 226 231 155 134 83 68 75 121 108 193 223 1981 245 216 19 182 119 6 54 78 138 159 163 218 1982 232 224 177 16 ndash ndash 37 111 112 164 209 225 1983 235 24 197 147 112 88 39 88 121 162 189 219 1984 241 243 191 156 ndash 72 66 7 95 161 182 211 1985 244 231 ndash 159 98 65 71 73 117 147 205 ndash 1986 ndash 229 226 155 93 96 43 49 10 122 ndash 219 1987 ndash 217 183 175 85 77 68 68 112 ndash ndash 221 1988 238 214 209 178 111 ndash ndash 86 104 157 171 195 1989 ndash 237 199 165 107 67 44 61 107 131 187 ndash 1990 232 ndash 211 155 118 62 57 87 102 149 195 22 1991 26 256 217 168 122 101 78 ndash 113 18 168 219 1992 227 227 214 169 102 98 59 69 ndash 125 159 196 1993 241 218 196 171 103 ndash 49 68 88 128 192 211 Mean 24 23 20 16 10 8 6 8 11 14 18 21
NOTE Dashes indicate data unavailable
JAN FEB MAR APR MAY JUN JUL AUG SEP OCT NOV DEC0
10
20
30
40
Month
MKS43 140498
50
Mean monthly minimum temperatures at Wiluna
Mea
n T
emp
erat
ure
(degC
)
46
Table 23 Wiluna maximum temperature (degC)
Year Jan Feb Mar Apr May Jun Jul Aug Sept Oct Nov Dec
1975 ndash 349 326 281 247 201 197 212 256 248 31 344 1976 374 369 346 297 248 206 208 225 265 287 313 388 1977 397 392 352 296 234 212 222 244 ndash 308 337 383 1978 378 345 346 316 242 195 176 205 231 295 334 356 1979 403 36 364 295 ndash ndash ndash 193 242 318 359 373 1980 392 342 377 275 24 176 179 233 292 288 349 391 1981 385 346 337 342 242 178 201 224 30 326 326 369 1982 372 359 315 307 ndash ndash 196 253 252 305 353 379 1983 381 389 327 272 263 222 187 248 287 321 336 366 1984 378 393 322 299 226 215 178 214 234 ndash 336 364 1985 40 366 ndash 294 224 216 205 212 284 307 355 ndash 1986 ndash 383 372 307 ndash 193 166 196 261 277 ndash 382 1987 ndash 339 328 305 21 202 214 218 275 ndash ndash 374 1988 388 365 353 301 23 ndash ndash 228 283 334 31 33 1989 ndash 375 339 285 238 179 181 219 275 298 336 ndash 1990 368 ndash 36 309 268 19 188 205 274 309 373 393 1991 414 416 363 315 268 206 21 ndash 279 338 332 368 1992 363 383 336 263 213 178 213 197 ndash 285 313 359 1993 396 357 344 301 221 ndash 197 215 253 294 347 362 Mean 39 37 34 30 24 20 20 22 27 30 34 37 NOTE Dashes indicate data unavailable
JAN FEB MAR APR MAY JUN JUL AUG SEP OCT NOV DEC0
10
20
30
40
Month
MKS42 140498
50
Mean monthly maximum temperatures at Wiluna
Mea
n T
emp
erat
ure
(degC
)
47
Appendix 3
Table 31 Summary of palynological results
Drillhole Depth (m) F no(a) GSWA no Lithology Formation Assemblage TAI(b)
BWB 1 74ndash75 F49668 135741 dark-grey siltstone basalt Jilyilli gt5 BWB 1 98ndash100 F49669 135742 dark-grey siltstone basalt Jilyilli gt5 BWB 1 121ndash122 F49670 135743 dark-grey siltstone basalt Jilyilli gt5 TWB 1 86ndash87 F49671 135631 dark-grey siltstone McFadden 3+ TWB 1 104ndash105 F49672 135632 dark-grey siltstone Cornelia 3+ TWB 1 121ndash122 F49673 135633 dark-grey siltstone Cornelia 4 TWB 2 14ndash15 F49674 135634 dark-grey siltstone Skates Hills 3+ TWB 6 49ndash50 F49675 135675 dark-grey siltstone Cornelia 1 3+ TWB 9 49ndash51 F49676 135704 dark-grey siltstone Brassey Range 1 3+ Trainor 1 37497- F49733 138939 black mudstone with Cornelia 5 37509 light-grey siltstone Trainor 1 3809 F49734 138940 dark-grey and black Cornelia 4- laminated mudstone Trainor 1 4170 F49735 138941 black unlaminated mudstone Cornelia 4- Trainor 1 4950 F49851 139501 dark-grey indurated siltstone Cornelia 5 Trainor 1 6032 F49852 139502 dark- and light-grey Cornelia 5 indurated siltstone Trainor 1 6434 F49853 139503 greenish indurated finely Cornelia 5 laminated siltstone LDDH 1 270 F49678 138934 dark-grey siltstone interbeds Waters 1 3+ in enterolithic evaporite Tarcunyah Gp LDDH 1 277 F49679 138935 dark-grey siltstone in cavity Waters 1 3+ in enterolithic evaporite Tarcunyah Gp
NOTES (a) GSWA Fossil Catalogue number (b) TAI = Thermal Alteration Index of Traverse (1988 plate 1)
48
Appendix 4
Savory Sub-basin quantitative magnetic and gravity interpretation (extracted from Cowan 1995)
Summary
A program of quantitative aeromagnetic interpretation has been completed on BMRAGSO data from the Savory Sub-
basin Western Australia Quantitative aeromagnetic interpretation utilized the 3D Euler deconvolution method
supported by wavenumber filtering and image processing The results have provided useful information on structural
trends and depth to magnetic sources in a structurally complex area Depth to magnetic source analysis has provided
information on intra-sedimentary magnetic sources as well as basement rocks
The results of the interpretation support previously identified depocentres However the presence of magnetic
sources at several levels makes it very difficult to produce a reliable magnetic basement depth contour map It is
considered more productive to work with the 3D Euler colour circle plots and images rather than trying to contour the
results It would be necessary to carry out a full-scale interpretation of the BMRAGSO profile data to improve on the
3D Euler results The regional gravity was found to be useful in interpreting the regional setting of the area although
the very wide data spacing limits quantitative use of the data The gravity data show quite a complex picture with
limited consistent correlation between gravity features and basin structures This suggests that gravity anomalies
reflect changes in density of the basement rocks rather than basement topography especially in the northern part of the
basin
It is recommended that the GSWA investigate access to company confidential high-resolution aeromagnetic data
prior to planning further aeromagnetic surveys Private companies have flown large parts of the northern half of the
area as part of their diamond exploration program Additional gravity coverage of the area may be more cost effective
than magnetic surveys as the gravity data provides more information on changes within the sedimentary section
Introduction
The main use of aeromagnetic data in petroleum exploration has been the determination of magnetic basement
topography although there has been increasing interest in analysis of intra-sedimentary magnetic anomalies
intrabasement and suprabasement magnetic anomalies These anomalies are used to determine depth to magnetic
basement rocks and hence determine the thickness of the sedimentary sequence Unfortunately interpretation of the
intrabasement and suprabasement magnetic anomalies is non-unique in terms of position and size of causative sources
because of the inherent ambiguity of potential-field methods However this ambiguity can be reduced by placing
49
constraints on source geometry and magnetization and by using geological and other geophysical data to constrain
the solution
Before 1970 most depth-determination techniques involved graphical determination of slopes of selected
magnetic anomalies and application of various empirical factors to convert the slopes into depth estimates Geological
Society of America Memoir 47 Interpretation of Aeromagnetic Maps by Vacquier et al (1951) was a landmark for
this type of interpretation
Automated interpretation procedures have played an increasingly important role in depth interpretation and a
wide range of techniques have been developed Many of these techniques are designed for application to located data
profiles and assume a two-dimensional geometry However there has been renewed interest in techniques applicable
to gridded data
Two distinct types of method can be recognized In the first case often described as discrete methods individual
isolated magnetic anomalies are interpreted and the results used to produce a map of basement relief In the second
case often described as continuous methods areas of data containing a number of anomalies are interpreted
statistically to produce direct output of basement depths
The discrete methods usually involve a semiautomatic initial phase which generates a large number of possible
depth solutions and an interactive second phase to screen and select acceptable solutions The advantage of this
approach is that the interpreter can select features that are relatively free from interference from adjacent anomalies
and consider all aspects of a particular magnetic anomaly The disadvantage is that interpretation can be very time
consuming as a wide range of depths are usually possible depending on the initial model chosen and a significant
amount of effort is needed to select the correct model In the case of the Savory Sub-basin dataset we encountered
problems in separating basement related effects from the effects of shallower intrasedimentary magnetic sources
Because of these problems we have concentrated on displaying the Euler results accompanied by separation filter
images of the data to show the shallower effects and deeper effects rather than trying to refine a 3D Euler
deconvolution depth-to-crystalline-basement contour
The continuous methods are very direct provided that the rather restrictive assumption can be made that all
anomalies are due to lateral magnetization changes due to basement topography This means that shallow effects and
large intrabasement anomalies must be removed from the data This involves judgement and skill as it is necessary to
distinguish between the lower amplitude suprabasement anomalies due to basement topography and the larger
intrabasement anomalies reflecting magnetization changes within the basement These methods were not considered
suitable for the Savory Sub-basin magnetic dataset but were used to invert the gravity data
50
Limitations of magnetic and gravity interpretation
Interpretation of the area is limited by a shortage of information on the nature and physical properties of the deeper
sedimentary sequence and the underlying basement rocks However using techniques such as cross-correlation of
gravity and pseudo-gravity data it is possible to try to differentiate between anomalies relating to basement and those
related to the sedimentary sequence
Gravity anomalies reflect changes within the sedimentary sequence as well as basement condition These
changes in density of sedimentary rocks produce gravity anomalies without a corresponding magnetic anomaly hence
the complementary nature of gravity and magnetic surveys The main use of magnetics is to determine depth to
magnetic basement and any intra-sedimentary volcanic rocks or intrusives whereas gravity provides much more
general information on the sedimentary sequence
Unfortunately interpretation of gravity anomalies is complicated since they can be due to a number of geological
features including
bull major basement faults
bull basement highs
bull igneous intrusions within the basement
bull sedimentary basins which may or may not be isostatically compensated
bull intra-sedimentary volcanics and associated plutonic centres
Two major problems affect the interpretation of both magnetic and gravity data
1 The inherent ambiguity of potential-field data There is no unique solution to any measured gravity or magnetic
anomaly and theoretically there will be an infinite number of source geometry and magnetizationdensity
combinations which will fit the observed data This means that any a priori information which helps to select a
suitable model is very useful
2 Measured anomalies are the summation of effects from different depths For example an observed gravity profile
may contain contributions from shallow sources (density variations within the sedimentary basin) intermediate
depth sources (density variations due to large igneous intrusions within the basement) and deep sources (crustal
thinning producing a mantle anomaly) Separation of these component responses is the regionalresidual problem
which we solve using spectral analysis and differential upward continuation-based separation filtering
Regional setting and interpretation overview
The area studied includes parts of BALFOUR DOWNS (SF51-9) RUDALL (SF51-10) ROBERTSON (SF51-13) GUNANYA
(SF51-14) COLLIER (SG50-4) BULLEN (SG51-1) TRAINOR (SG51-2) MADLEY (SG51-3) NABBERU (SG50-5)
STANLEY (SG51-6) and HERBERT (SG51-7) 1250 000 sheets Broadly the area lies between latitudes 22deg00rsquondash25deg30rsquoS
and longitudes 119deg30rsquondash123deg30rsquoE
51
Regional gravity
The AGSO regional gravity data (at nominal 11 km spacing) was gridded at a 4 km mesh spacing using a minimum-
curvature algorithm Bouguer gravity values in the area are negative reflecting mass deficiency at depth and range
from -84 mgals to -25 mgals
A Bouguer gravity colour image is shown as Figure 41 A residual grid was produced by removing a fifth-order
orthogonal polynomial from the Bouguer data but did not add to the interpretation
120deg 121deg 122deg 123deg
23deg
24deg
25deg
-25
-84
50 km
MKS46 180598
mgal
Figure 41 Regional Bouguer gravity (BMRAGSO data) gridded at 4 km
52
The data show a complex pattern of positive and negative anomalies with no clearly defined trends Correlations
with aeromagnetic data and known basin structures are poor A vague north-northwest linear trend appears to coincide
with the Marloo Fault (Figure 42) A prominent negative anomaly appears to coincide with the Blake Fold and Fault
Belt depocentre and continues as a narrower negative anomaly to the east until it widens out again near the edge of the
basin Elsewhere the gravity data show little correlation with known basin structures and it is likely that especially in
the north of the area gravity anomalies are due to density changes in the basement rather than changes in basement
topography
Production of wavelength-filtered residual gravity plots and vertical gradient plots showed very patchy aliased
data reflecting poor sampling in much of the area
Regional magnetics
The AGSO regional aeromagnetic data were gridded at a 400 m mesh spacing using a minimum-curvature algorithm
(Figure 43) Most of the data has a line spacing of 1600 m with small areas of 1 km spacing The quality of the data is
acceptable for regional interpretation but is not adequate for detailed analysis The accuracy of the flight path is rather
variable reflecting the vintage of the data and the noise envelope of the data is poor by modern standards Problems
were also encountered in joining different map sheets
The magnetic anomaly pattern over the south and west part of the area shows a strong high frequency signature
reflecting the presence of widespread basic sills and dykes Some of the major north-northeasterly trending dykes can
be traced over considerable distances
Discontinuous high-frequency anomalies extend as a northwest-trending zone through the centre of the area and
this zone includes a conspicuous circular magnetic anomaly which is probably a ring complex
The northern and eastern parts of the area are characterized by long-wavelength deep-seated basement magnetic
anomalies with 120deg and 150deg trends dominant The Marloo and Perentie Faults (Figure 42) appear as distinct linear
zones and offsets A prominent easterly trending negative anomaly in the northwest of the area appears to swing round
to the southeast and may separate different basement blocks One possible interpretation is that this very deep seated
anomaly separates areas of Archaean and Proterozoic basement
Regional geology
The regional geology is described in Williams (1992) The GSWA provided a digitized version of Plate 2 from this
Bulletin the structural interpretation map to use as an overlay (Figure 42)
53
Pp
Pp
PSd
PSd
PSd
PSd
PSd
PSo
PSt
PSt
PSf
PSf
PSf
PSb
PSb
PSb
PSsPSs
PSs
PSb
PSm
PSp
PSc
PSc
PSw
PSw
PSw
PSg
PSr
PSj
PSg
PM
Pk
PY
PY
PSd
L
L
L
L
L
L
L
LL
L
L
L
LL
L
LL
L L
LL
L L
L
L
L
L
L
L
L
LL
L
L
BLAKEDEPOCENTRE
MA
RLO
O
FAU
LT
PERENTIEFAULT
50 km
MKS39120598
120deg 121deg 122deg 123deg
25deg
24deg
23deg
Approximate boundaryof aeromagnetic interpretation
PML
PSgL
PSjL
PML
PSpL
PML
PML
PSfL
PSfL
PSpL
LPc
LPcLPcPSrL
LPA
Durba Sandstone
Woora Woora Formation
McFadden Formation
Tchukardine Formation
Boondawari Formation
Skates Hills Formation
Mundadjini Formation
Coondra Formation
Spearhole Formation
Watch Point Formation
Jilyili Formation
Brassey Range Formation
Glass Spring Formation
Paterson Formation
Yeneena Group
Karara Formation
Cornelia Formation
Kahrban Subgroup
Bangemall Group
Fault
Formation boundary
PSdL
PSoL
PSfL
PStL
PSbL
PSsL
PSmL
PScL
PSpL
PSwL
PSjL
PSrL
PSgL
Pp
PYL
PkL
LPc
LPA
PML
Savory Group Other Units
PYL
Figure 42 Regional geology and structure map (after Williams 1992)
54
120deg 121deg 122deg 123deg
23deg
24deg
25deg
5820
3750
MKS47 180598
nT
50 km
Figure 43 Regional aeromagnetic data total magnetic intensity (BMRAGSO data) gridded at 400 m
Analysis
3D analysis
3D Euler deconvolution was used as the primary depth-determination method The advantage of this approach is that
consistent solutions can be obtained over the entire area with minimal assumptions about source geometries Euler
deconvolution of gridded data is used for positional information and estimation of depth to top of source Euler
55
deconvolution yields a large number of depth solutions which have to be screened to reject spurious solutions Results
are plotted as circles in eight depth ranges with radius proportional to depth and colour coded
The 400 m total magnetic intensity grid was used for the analysis Horizontal gradients in x and y and the vertical
gradient were calculated 3D Euler deconvolution was tested on the 400 m gridded data using windows of 9 times 9 and
11 times 11 and 16 times 16 data points and structural indices 05 (fault) and 10 (sill or dyke) It was concluded that the
16 times 16 window produced the best results overall and final plots were produced for the 16 times 16 window and structural
index 05 (Fig 44) Results were very good over the northern and central parts of the area showing magnetic sources
Figure 44 Depth to magnetic source 3D Euler deconvolution 16 times 16 window of 400 m gridded data structural index 05
56
at several different levels Unfortunately in the extreme south of the area shallow intrasedimentary magnetic sources
(sills and dykes) dominated the inversion and the results contained few basement solutions
In order to reduce these problems the 400 m gridded data were filtered using a separation filter based on
interpretation of the log-energy spectrum The 3D Euler method was run on the filtered data in order to generate more
basement-depth solutions Results for the deep-separation filter data were gridded and presented as a colour image in
Cowan (1995) Attempts to grid the Euler output were unsatisfactory and it is considered safer to interpret the 3D
Euler depth plots The 3D Euler depth results from the separation-filter run should be analysed with care as perfect
separation of the basement can never be achieved and there will always be some contamination from sources at
different levels
The results of original total magnetic intensity 3D Euler depth estimation for structural index 05 using a 16 point
window have been plotted at 1500 000 scale (not included in this publication but available in Cowan (1995) from the
GSWA Library as S10331) and as reduced A4 colour circle plots (Figure 44)
The results of deep-basement 3D Euler depth estimation for structural index 05 using a 16 point window have
been plotted as a colour image at 1500 000 scale and as an A4 image (not included in this publication)
2D analysis
Two equispaced profiles were interpolated with a 50 m station interval from the AGSO-located data profiles for the
BULLEN 1250 000 sheet The interpolated profiles were analysed using 2D Euler deconvolution and Werner
deconvolution Results are included in Cowan (1995) and show the use of these methods for more detailed analysis
Filtered data
In order to reconcile 3D Euler results from shallow basement and intrasedimentary magnetic sources we produced
several separation-filtered maps and images We found the shallow-layer double-separation filter (Figure 45) to be
very effective for shallow sources and the deep-layer standard-separation filter (Figure 46) for the basement layer
Gravity and magnetic data correlation
Both lsquoreduced to the polersquo (RTP) magnetics (Figure 47) and pseudo-gravity data (Figure 48) were produced as part of
the reconciliation of gravity and magnetic signatures In both cases the filtering operations assumed magnetization by
induction in the present Earths field The RTP data are fairly similar to the total magnetic intensity The pseudo-
57
gravity data are dominated by a northwest-trending strong positive anomaly and there is little correlation with the
Bouguer gravity data
The poor magneticgravity correlation is confirmed by cross-correlation of the RTP magnetics and the gravity
gradient The correlation plot in Figure 49 shows little coherent response with numerous zones of positive and
negative correlation
Figure 45 Regional aeromagnetic data shallow layer separation filter (BMRAGSO data) gridded at 400 m
Results
In the north and east of the area on the Wells Foreland Sub-basin trend (refer to Figure 1 main text) we see a range
of quite deep 3D Euler depths and several trend directions with north-northwesterly dominant There are relatively few
shallow intrasedimentary solutions in this zone
The second area of deep 3D Euler solutions lies over the Blake depocentre (Figure 43) with several trend
directions
Elsewhere the 3D Euler results are dominated by shallow intrasedimentary depth solutions reflecting mainly the
dolerite sills dykes and the ring complex However where we do see basement-related solutions in the south and
west of the area they appear to be shallower than those noted for the Wells Foreland Sub-basin and the Blake
depocentre
58
Figure 46 Regional aeromagnetic data deep-layer separation filter (BMRAGSO data) gridded at 400 m
Figure 48 Regional aeromagnetic data pseudo-gravity transform (BMRAGSO data) gridded at 400 m
Figure 47 Regional aeromagnetic data reduced-to-pole (BMRAGSO data) gridded at 400 m
Figure 49 Regional aeromagnetic and gravity data gravitymagnetic correlation using RTP magnetics and gravity gradient (BMRAGSO data) gridded at 4 km
59
This subdivision of the area into two zones of deep solutions is consistent with interpreted depocentres
However the interference between sources at different levels and the complexity of the magnetic response of the
basement rocks precludes more refined interpretation at this stage
The area of deep 3D Euler solutions over the Blake depocentre correlates with the pronounced negative gravity
anomaly discussed in the gravity interpretation section Using a density contrast of -015 gcc the negative gravity
anomaly could indicate up to 6ndash8 km of low-density sedimentary rocks depending on assumptions about the regional
field
The area of deep 3D Euler solutions over the Wells Foreland Sub-basin has a complex gravity expression and no
clear basin structure emerges from inversion of these data As noted previously it is likely that observed gravity
anomalies reflect contrasts in basement density rather than basement topography
Separation filtering applied to the magnetic data helps to enhance the intrasedimentary magnetic signature and to
give a better impression of the basement magnetic signature even though separation of the basement response is not
perfect
Conclusions
Quantitative aeromagnetic interpretation using 3D Euler deconvolution supported by wavenumber filtering and image
processing has been successful in providing structural trend and depth information for the Savory Sub-basin
Quantitative magnetic interpretation has revealed two zones of relatively deep magnetic basement beneath the
Wells Foreland Sub-basin and the Blake depocentre
This analysis of the magnetic data supports interpreted depocentres but the complexity of the basement magnetic
signature and interference from sources at different depths precludes further refinement to a map of basement
topography
Regional gravity proved to be very useful in understanding the regional setting of the area and in providing
support for aspects of the interpretation The gravity data support the interpretation of the Blake depocentre
suggesting up to 6ndash8 km of low-density sedimentary rocks
The deep structure of the Savory Sub-basin area is obviously complex with different areas underlain by
Archaean and Proterozoic basement and with the Capricorn suture occurring in the centre of the area
60
Recommendations
The quantitative magnetic interpretation needs to be reconciled with geological models available for the area
In particular the zones tentatively identified as areas with thick sedimentary rocks the Wells Foreland Sub-
basin and the Blake depocentre need to be investigated
Cross sections should be prepared across the basin for joint magneticgravity modelling especially for the Blake
depocentre It is important to be able to explain the strong negative gravity anomaly in this area
In view of the effects of basement density contrasts on the gravity field for the northern part of the area we think
that additional gravity interpretation and acquisition of new gravity data may not be justified as they will not
contribute significantly to understanding basin evolution and structure
It is recommended that GSWA try to get access to company confidential high-resolution aeromagnetic data
rather than flying new surveys The GSWA might offer to fund flying of new infill areas as a bargaining point
References
The original text of this report by Cowan (1995) and 1500 000 scale maps are filed in the GSWA Library under
S10331
COWAN D 1995 Savory Basin quantitative magnetic interpretation Western Australia Geological Survey S-series
S10331 (unpublished)
VACQUIER V STEENLAND N C HENDERSON R G and ZIETZ I 1951 Interpretation of aeromagnetic
maps The Geological Society of America Memoir 47 151p
WILLIAMS I R 1992 Geology of the Savory Basin Western Australia Western Australia Geological Survey
Bulletin 141 115p
61
Appendix 5
Geochemistry
MKS38 250398
Saturate FractionC12+ GLC
1217
Pr18
Ph
22
31CSR WELL-13 315m Cuttings
Figure 51 Canning Stock Route Well 13 gas chromatograph of extract of auger drill sample
12
17
18
22
31
Pr Ph
LDDH 1 6623m CoreSaturate FractionC12+ GLC
MKS35 240398
Figure 52 Gas chromatograph of extract from core sample at 6623 m LDDH1
62
Table 51 Canning Stock Route Well 13 auger drill samples
GSWA sample Drill depth (m)(a) Comments
135601 150 At watertable 135602 203 (all samples consist 135603 310 of sand mud and water) 135604 315 At total depth
NOTE (a) Datum for drill depth is the top of sediment fill in the well which is 155 m below ground level (ie the total depth of 315 m is 47 m below ground level)
Table 52 Canning Stock Route Well 13 gas chromatography data for 315 m depth sediment sample
Parameter Value
Weight of rock extracted (grams) 945 Total extract (ppm) 519 n-Alkane distribution n-C12 07 n-C13 23 n-C14 26 n-C15 22 n-C16 19 n-C17 14 i-C19 23 n-C18 14 i-C20 08 n-C19 11 n-C20 16 n-C21 25 n-C22 29 n-C23 70 n-C24 42 n-C25 95 n-C26 43 n-C27 83 n-C28 38 n-C29 87 n-C30 31 n-C31 273 Alkane compositional data Pristane phytane ratio 279 Pristane n-C17 ratio 161 Phytane n-C18 ratio 059 CPI (1)(a) 284 CPI (2) 209 (C21 + C22) (C28 + C29) 043
NOTE (a) CPI= Carbon preference index
63
Table 53 LDDH1 extract liquid chromatography data for 6623 m concentration
Rock extracted Total extract (grams) (ppm)
702 313
NOTE ppm= parts per million
Table 54 LDDH1 saturate gas chromatography data of core for 6623 m alkane composition
Pristane Pristane Phytane (a) CPI (1) CPI (2) (C21+C22) Phytane n-C17 n-C18 (C28+C29)
103 026 024 103 102 325
NOTE (a)CPI = carbon preference index
Table 55 LDDH1 saturate gas chromatography data of core for 6623 m n-alkane distributions
Parameter Value
n-C12 17 n-C13 38 n-C14 55 n-C15 60 n-C16 65 n-C17 74 i-C19 19 n-C18 78 i-C20 19 n-C19 80 n-C20 79 n-C21 71 n-C22 64 n-C23 57 n-C25 43 n-C24 38 n-C27 31 n-C28 23 n-C29 19 n-C30 12 n-C31 10
64
Appendix 6
Table 61 Summary of data from Trainor waterbores (TWB) and Bullen waterbores (BWB)
Well AMG Elevation TD Status(b) Completion details Water Salinity Water level Flow rate Depth to consolidated AGD84 GL (m) (m) struck mgl(c) (m) (LHr) lithology aquifer(e) Z51(a) Interval (m) (100 mm PVC) (m) (mgl)(d)
TWB 1 473660E 453 122 comp 0ndash75 plain 63 7 300 24 2 880 12 m 7287404N 75ndash93 slotted (9 260) McFadden Fm 93ndash99 plain TWB 2 472 977E 475 23 abd nil 15 m 7285877N Skates Hills Fm dry TWB 3 473259E 475 50 abd nil 7 m 7285849N Skates Hills Fm dry TWB 4 463225 E 445 50 comp 0ndash22 plain 35 7 200 55 3 600 0 m 7286143N 22ndash34 slotted (8 140) Tertiary sand and gravel 23ndash60 plain TWB 5 463095E 445 31 comp 0ndash19 plain 13 26 000 655 3 600 Tertiary sand and gravel 7277721N 19ndash25 slotted (36 700) 25ndash31 plain TWB 6 457013E 455 50 comp 0ndash42 plain 38 920 119 600 0 m 7274352N 42ndash48 slotted (1 030) Cornelia Fm ss TWB 7 453739E 475 26 susp 0ndash2 plain 11 9 300 48 4 500 0 m 7263891N (10 500) Tertiary sand TWB 8 433893E 535 60 susp 0ndash2 plain 47 8 500 gt46 1 200 0 m 7245991N (10 900) Tertiary sand and Brassey Range Fm ss TWB 9 437219E 505 51 comp 0ndash47 plain 45 1 000 58 600 1 m 7235905N 47ndash51 slotted (990) Brassey Range Fm ss TWB 10 434927E 495 32 susp 0ndash2 plain 235 450 120 0 m 7225875N (500) Dolerite
65
BWB 1 287337E 580 122 abd Nil 1 m 7245861N Jilyili Fm dry BWB 2 288346E 545 50 comp 0ndash26 plain 15 630 3 29 000 0 m 7240423N 26ndash38 slotted (730) Tertiary sand and gravel 38ndash50 plain BWB 3 305637E 545 50 abd 19 8 800 43 7 200 0 m 7240423N (10 550) Tertiary ss BWB 4 320167E 515 445 comp 0ndash20 plain 9 980 445 24 000 0 m 7248097N 20ndash32 slotted (1 190) Tertiary ss 32ndash44 plain BWB 5 353393E 545 20 susp 0ndash2 plain 45 (970) 1 m 7238934N Basalt
NOTES (a) GPS accuracy ~ 150 m (b) Comp = completed abd = abandoned susp = suspended (c) Salinity from conductivity (d) Analysis total dissolved solids (e) Fm = Formation ss = sandstone
15
120598
122deg
123deg
21deg
22deg
23deg
24deg
23deg
22deg
21deg
122deg
123deg
Fault
Thrust
Reverse thrust
CANNINGBASIN
OFFICERBASIN
GROUP
PILBARACRATON
TARCUNYAH
SAVORY GROUP
BANGEMALL
GROUP
THROSSELL
GROUP
LAMIL
GROUP
ConnaughtonTerrane
TerraneTalbot
complexTabletop granitic
Tabletop Terrane
Permian
Neoproterozoicgranitoid
50 km
FormationWaltha Woora
McKay Fault
South west Thrust
Vines
Fault
24deg
120deg
YENEENA CANNINGBASIN
ARUNTAINLIERRUDALL
COMPLEX
AMADEUSBASIN
MUSGRAVEBLOCK
OFFICERBASINYILGARN
CRATON
GROUP
GROUP
GROUP
PILBARACRATON
GROUP
EARAHEEDY
GLENGARRY
BANGEMALL
WYLOO GROUP
SAVORY
WA
CARNARVONBASIN
GASCOYNECOMPLEX
GROUPTARCUNYAH
400 kmGROUP
SA
N
T
CamelndashTabletopfault zone
KAHRBANSUBGROUP
CORNELIAFORMATION
MKS37
Figure 7 Regional geological setting of the Savory Group and western Officer Basin The dashed line on the inset map marks the interpreted margin of the greater Officer Basin
16
Tarcunyah Group and consists predominantly of mudstone with minor sandstone limestone
dolomite and anhydrite (Fig 6)
The age of the Tarcunyah Group is uncertain although limited palynological and stromatolite
evidence suggests that it is probably coeval with Supersequence 1 of the Centralian Superbasin
Drillhole LDDH1 contains palynomorphs equivalent to assemblages in the Browne and Bitter
Springs Formations of the Officer and Amadeus Basins respectively and from the Cornelia
Formation in TWB 6 (Grey and Stevens 1997) (Figs 4 and 6) Stromatolite specimens tentatively
assigned to Acaciella australica (Howchin 1914) Walter 1972 occur in the lower Tarcunyah
Group (Bagas et al 1995) The stromatolite Baicalia burra Preiss 1972 and a conical
stromatolite were reported from the upper part of the Tarcunyah Group (Stevens and Grey 1997)
The recognition of two stromatolite assemblages interpreted to have age significance in
Supersequence 1 sedimentary rocks of the Centralian Superbasin has permitted biostratigraphic
correlations between outcrop and well data The Acaciella australica assemblage appears to be
slightly older than 800 Ma and is restricted to the middle part of Supersequence 1 The Baicalia
burra assemblage is considered to be slightly younger than 800 Ma and occurs in the upper part
of Supersequence 1 (Grey 1996b Stevens and Grey 1997) The older A australica assemblage
is recognized in the Skates Hills Formation in the Savory Sub-basin and the stromatolite A
australica itself has been tentatively identified in the lower Tarcunyah Group The occurrence of
the A australica assemblage in the Woolnough Madley and Browne Formations of the Officer
Basin and in the Loves Creek Member of the Bitter Springs Formation of the Amadeus Basin
allows correlations throughout the Centralian Superbasin (Fig 4)
The younger B burra assemblage has not been recognized in sedimentary rocks of the
Savory Group as defined by Williams (1992) but it occurs in the upper parts of the Tarcunyah
Group and allows correlation of this group with outcrops of the Neale Formation and with the
Kanpa Formation in petroleum exploration well Hussar 1 both located in the central Officer Basin
of Western Australia (Fig 4) (Grey 1996b Stevens and Grey 1997) The occurrence of the B
burra assemblage in these units permits their correlation with the Burra Group in the Adelaide
Geosyncline of South Australia (K Grey unpublished data)
The Cornelia Formation and Kahrban Subgroup outcrop in the southeast of the sub-basin and
were considered by Williams (1992) to be part of the Mesoproterozoic Bangemall Basin Limited
evidence suggests that all or parts of these two units are of Neoproterozoic age The Ward and
Oldham Inliers consist of outcrops of the Cornelia Formation Waterbore TWB 6 which was
drilled on TRAINOR in the Cornelia Formation contains palynomorphs consistent with a
Supersequence 1 age (Grey and Stevens 1997) (Figs 5 and 6) In outcrop the Cornelia Formation
17
consists predominantly of sandstone and quartzite with lesser siltstone shale mudstone and chert
In Trainor 1 this formation consists predominantly of indurated mudstone with minor sandstone
chert and dolomite A major erosional unconformity separates the Cornelia Formation from
overlying formations and parts of the Cornelia Formation have been folded with dips exceeding
70deg In contrast the majority of the Savory Sub-basin sedimentary rocks have dips of less than 30deg
except where they are adjacent to faults The Cornelia Formation apparently consists of an older
unit of steeply dipping quartzites cherts and well-indurated mudstones and a younger unit of
shallower dipping sandstones which are sub-friable in parts However caution should be used in
interpreting the age of units based on their structural deformation and additional mapping and age
dating of this formation is required
It is proposed here that the Kahrban Subgroup is likely to be of early Neoproterozoic age and
hence should be considered as part of the greater Officer Basin This proposal is based largely on
the relatively low dip of the strata (generally less than 20deg) and their west-northwest strike which
is parallel with strikes in the overlying Brassey Range Formation of the Savory Group The lower
contact of the Kahrban Subgroup is obscured but is thought to be an unconfirmity on the
Earaheedy Basin on the southeast of STANLEY (Muhling and Brakel 1985)
Structural setting
The Savory Sub-basin forms the most northwesterly sub-basin of the Neoproterozoic to
Phanerozoic Officer Basin The western boundary of the sub-basin with the Mesoproterozoic
Bangemall Basin consists of steep-reverse and strike-slip faults The northeastern boundary of the
Savory Sub-basin was mapped where Supersequence 4 formations of the Savory Group
unconformably overlie sedimentary rocks of the Karara and Yeneena Basins with the two older
units considered to be part of the Paterson Orogen (Williams 1992) This contact was defined as a
series of steeply dipping reverse faults in the northernmost parts of the sub-basin on BALFOUR
DOWNS and RUDALL and was extrapolated as an inferred reverse fault farther along strike to the
southeast on GUNANYA and MADLEY where the contact is obscured by Cainozoic sediments It is
now recognized that all the sedimentary rocks in the Karara Basin and younger sedimentary rocks
of the Yeneena Basin are from the Supersequence 1 Tarcunyah Group and part of the greater
Officer Basin (Bagas et al 1995) The northern boundary of the Tarcunyah Group and the greater
Officer Basin is in thrust-and reverse-faulted contact with the Rudall Complex and other parts of
the Paterson Orogen (Fig 7)
To the south the sub-basin unconformably overlies the Bangemall Basin The eastern
boundary of the sub-basin used in this study is where Permian and younger strata of the Officer
Basin unconformably overlie Neoproterozoic strata although there are no significant structural or
stratigraphic differences between the Neoproterozoic units
18
The sub-basin is subdivided into three principal structural areas (Fig 1) Trainor Platform
Blake Fault and Fold Belt and Wells Foreland Sub-basin (Williams 1992) A major review of
these boundaries is beyond the scope of this report but the processing of regional aeromagnetic
data (Appendix 4) and acquisition of a semi-detailed gravity survey by the GSWA in the east of
the sub-basin has enabled these tectonic units to be reassessed and some modifications are
proposed
The Wells Foreland Sub-basin (originally termed the Wells Foreland Basin in Williams 1992)
and sedimentary rocks of the Tarcunyah Group are both considered to be the northwest
continuation of the Gibson Sub-basin of the Officer Basin Aeromagnetic gravity and outcrop
data suggest that the Blake Fault and Fold Belt is significantly faulted and folded in the west but
is less deformed in the east where the thickest sedimentary section in is located on BULLEN
(Appendix 4) The Trainor Platform is reinterpreted to represent an area of the sub-basin that has
undergone major compression during the Petermann Ranges Orogeny resulting in folding and
faulting with a northwest strike This interpretation contrasts with that proposed by Williams
(1992) who envisaged that only a thin section of the Savory Group was present on the platform
Perincek (1998) has recognized nine periods of tectonic activity in the Officer Basin from the
beginning of the Neoproterozoic to the end of the Cretaceous Three major tectonic episodes are
recognized in the Centralian Superbasin The oldest event is the Areyonga Movement which is
pre-Sturtian and forms the boundary between Supersequences 1 and 2 (Fig 4) The Souths Range
Movement occurred at the end of the Sturtian at the boundary between Supersequences 2 and 3
The youngest major event is the Petermann Ranges Orogeny which occured at the end of the
Marinoan and forms the boundary between Supersequences 3 and 4
One minor and two major tectonic episodes are recognized in the Savory Sub-basin the
LP1ALP1B structural event and the Areyonga Movement and the Petermann Ranges Orogeny
respectively The LP1ALP1B structural event is revealed where the Spearhole Formations rests
disconformably and locally unconformably on the Brassey Range Jilyili and Glass Spring
Formations The Neoproterozoic Areyonga Movement (equivalent to the Blake Movement of
Williams 1992) produced folds and faults with a general northeast strike in the western and
southern parts of the region The Souths Range Movement has not been recognized in the sub-
basin This may be due to the fact that no Sturtian glacial rocks have been identified and hence it
is possible that structures attributed to the Areyonga Movement could be the result of the Souths
Range Movement or a combination of the two movements
The major tectonic event recorded in the sub-basin is the latest Neoproterozoic to Cambrian
Petermann Ranges Orogeny (equivalent to the Paterson Orogeny) which produced large reverse
19
faults thrusts strike-slip faults and folds with a general northwest strike The McFadden
Formation and other Supersequence 4 strata are considered to be at least partially coeval with this
orogeny (Williams 1992) We also interpret the Durba Sandstone as having been deposited during
the later stages of the Petermann Ranges Orogeny as this unit mildly deformed with fold axes
parallel to the strike of other structures attributed to the Petermann Ranges Orogeny
Quantitative aeromagnetic interpretation of the Savory Sub-basin utilizing the 3D Euler
deconvolution method supported by wave-number filtering and image processing has provided
structural trends and depth to magnetic source within the sub-basin (Cowan 1995) Gravity data
are interpreted by Cowan (1995) as changes in both the density of the basement rocks andor
basement topography depending on local conditions Part of Cowanrsquos report is reproduced in
Appendix 4
Exploration history
The only petroleum exploration conducted in the sub-basin has been the recent drilling in the
western part of three diamond drillholes of which two have minor oil shows (Table 2) There has
been some mineral exploration the results of which are stored in the GSWA Western Australian
Mineral Exploration (WAMEX) database system Much of the mineral exploration was in the
southwest and west where the sub-basin is in contact with the Bangemall Basin and along the
northern margin of the sub-basin Many of these mineral exploration programs included
aeromagnetic surveys and surface geochemical sampling (Fig 8)
Hydrocarbon potential
The sub-basin contains a sedimentary succession up to 8 km thick which is generally gently
folded and faulted and apparently unmetamorphosed Limited drilling has shown that thick
mudstones are present in the sub-basin with some mudstones in Trainor 1 having high Total
Organic Carbon (TOC) values Outcrops of sub-friable sandstones in many of the formations
within the sub-basin suggests widespread reservoir potential Mudstone and inferred thick
evaporite sequences are likely to form seals Maturity data suggest that near-surface samples are
approximately at the base of the oil window and top of the gas window in parts of the north and
southeast of the sub-basin However parts of the southwest of the sub-basin and the mudstones in
Trainor 1 have very high levels of maturity Numerous faults and folds have been identified from
surface mapping suggesting good potential for large structural traps Minor oil shows in
20
Table 2 Neoproterozoic formations and hydrocarbon shows in diamond drillholes in the Savory Sub-basin
Drillhole AMG Core TD (m) Approx Formation Depth Formation Depth Formation Depth Shows (AGD84) start (m) GL (m) (m) (m) (m)
LDDH 1 431148E 112 701 350 Tarcunyah 68ndash701 ndash ndash bitumen at 6623 m 7443826N Group Trainor 1 473640E 6 709 455 McFadden 9ndash83 Cornelia Fm 83ndash709 possible bitumen at 4537 m 7287400N Fm Mundadjini 1 319056E 170 600 500 Mundadjini 16ndash361 Spearhole Fm 361ndash600 10 fluorescence at 36102 m 7404844N Fm Boondawari 1 348959E 299 1 367 490 Mundadjini Fm 15ndash312 Spearhole Fm 312ndash1 283 Intrusive 1 283ndash1 367 40 fluorescence at 35364 m 5 7398174N fluorescence at 4963 m Akubra 1 334249E 15 181 530 Mundadjini 15ndash42 Intrusive 42ndash181 None 7401252N Fm
21
50 km
120deg 121deg30 123deg
25deg
24deg
23deg
22deg
Greater Officer Basin
Savory Sub-basin
1
2
3
4
6
8
3 Seismic line (prefixed N83-00)
Aeromagnetic survey
GS
WA
Sav
ory
1995
gra
vity
sur
vey
Gravity survey
MKS34270398
Figure 8 Locations of aeromagnetic and gravity surveys (other than regional BMRAGSO data)
22
sandstones in two petroleum wells in the northwest of the sub-basin and bitumen and oil shows
elsewhere in the region indicate that oil has been generated and migrated through the sub-basin
Source rocks
Source potential is considered to be the major exploration risk in the Savory Sub-basin although
minor oil shows in Mundadjini 1 and Boondawari 1 indicate that at least some oil has been
generated and migrated into potential reservoirs within the sub-basin Sandstone is the
predominant lithology observed in outcrop Outcrops of fine-grained lithologies in the basin are
rare because of intense surface weathering and erosion Only about 8 of the surface area of the
sub-basin is exposed bedrock and recessive lithologies (such as shale evaporite and friable
sandstone) may be present although they rarely outcrop
Outcrops of stromatolitic dolomite with associated cauliflower chert and cubic pseudomorphs
interpreted as being after halite indicate that evaporitic environments are present within the
Mundadjini Skates Hills and Boondawari Formations Evaporitic minerals are also present in
drillhole LDDH1 in the Tarcunyah Group
In 1995 GSWA drilled a continuous-core diamond drillhole (Trainor 1) in the sub-basin on
TRAINOR to a depth of 709 m to test for source rocks thus providing the first such data for the sub-
basin The drillhole intersected flat-lying clastics and carbonates of the McFadden Formation (9ndash
83 m) overlying indurated mudstones of the Cornelia Formation (83ndash709 m total depth) dipping at
about 40deg Of the six samples analysed from the Cornelia Formation in this drillhole the five
located between 375 and 6032 m depth have TOC values exceeding 05 (range 066ndash365)
Rock-Eval pyrolysis of these five samples indicates that they are at best in the dry-gas thermal
stage and as a result of their high level of maturation (Stevens and Adamides in prep) have poor
remaining hydrocarbon-generating potential Although the Cornelia Formation is overmature at
Trainor 1 the high TOC values are encouraging as it is likely that this sequence is less mature
elsewhere in the sub-basin
The Mundadjini Formation contains potential source rocks that comprise marine mudstones
with evaporitic minerals present in parts Thin dark mudstones were intersected in the Mundadjini
Formation in Akubra 1 In Mundadjini 1 and Boondawari 1 however the mudstones appear to be
too oxidized to have source potential
The Boondawari Formation also may be a source rock as it contains black mudstones The
unit is laterally equivalent to the Pertatataka Formation of the Amadeus Basin and the Ungoolya
23
Group of the Officer Basin in South Australia both of which have some source potential
(Summons and Powell 1991 Morton and Drexel 1997) Samples from the Dey Dey Mudstone of
the Ungoolya Group generally have poor TOC values (average 011 range 003ndash081)
moderate hydrogen index (HI) values (100ndash382) and poor to fair genetic potential with a
maximum of 292 kg hydrocarbon per tonne of source rock (Morton and Drexel 1997)
Stromatolitic dolomites and mudstones at the top of the Boondawari Formation and within the
Skates Hills Formation are potential source rocks Stromatolitic dolomite and evaporitic rocks
deposited in a marginal marine to sabkha environment are considered to have good potential to
generate and preserve organic carbon without requiring a deep-water setting (Stevens and Grey
1997) Such conditions are recognized in the Skates Hills Formation and in the upper parts of the
Tarcunyah Group
Maturity
Knowledge of the maturity of sedimentary rocks within the Savory Sub-basin is still limited From
a review of palynological studies Grey and Stevens (1997) report that the thermal maturity
inferred from the Thermal Alteration Index (TAI) of 3+ from Supersequence 1 age palynomorphs
in TWB 6 TWB 9 and LDDH1 is within the hydrocarbon window (Appendix 3) In Phanerozoic
spores and pollen a TAI of 3+ approximately equates to the end of liquid petroleum generation
and the start of dry gas generation and to a vitrinite reflectance of about 13 (Traverse 1988)
However the use of TAI for estimating thermal maturity from Neoproterozoic palynomorphs
requires calibration
In Trainor 1 the Cornelia Formation contains organically rich claystones between 375 and
6032 m depth Based on Rock-Eval maturity data (Stevens and Adamides in prep) and the dark
colour of poorly preserved organic material (Grey 1995de 1996) with TAI 4- to 5 all samples
had a high level of maturation with at best dry-gas generating potential remaining In contrast
drillhole LDDH1 on GUNANYA recorded lower levels of maturity (TAI values of 3+) with two of
sixteen samples from the Tarcunyah Group having greater than 1 TOC (Grey 1995abc Grey
and Cotter 1996) Organic petrology and Rock-Eval maturity data for samples from LDDH1
indicate that the section above 500 m is within the oil-generative window whereas below 500 m
the rocks are within the gas window (Ghori in prep Fig 9 Appendix 5)
Waterbores TWB 1 2 6 and 9 which are located on TRAINOR in the southeast of the sub-
basin all had organic matter with TAI values of 3+ from the McFadden Skates Hills Cornelia
and Brassey Range Formations respectively
24
100
200
300
400
500
600
700
Oil
gene
ratin
g
Gas
gene
ratin
g
Fai
r
Fai
r
Poo
r
Poo
r
Goo
d
Imm
atur
e
Oil
win
dow
Oil
win
dow
Imm
atur
e
01 0110 10 0 150 300 440 480 1
Neo
prot
eroz
oic
TOC S1+S2 mgg Hydrogen Index Tmax degC
Depth(m)
Organicrichness
Generatingpotential
Kerogentype Maturity Maturity
TD=701m
Sandstone
Mudstone
Dolomite
Limestone
Evaporite
Source rock
MKS40 070498
Ro equivalent
Figure 9 Petroleum source potential of rocks in Normandy LDDH1
Small amounts of organic matter associated with basalt and dolerite in cuttings from
waterbore BWB 1 on BULLEN showed high levels of thermal maturity (Grey 1995a Libby 1995)
It is unclear whether all sedimentary rocks on BULLEN are overmature for hydrocarbon generation
or the results from BWB 1 are related to local heating events associated with the volcanic bodies
that are common in the Jilyili Formation
25
Reservoirs
Each of the five depositional sequences of the Savory Group (Table 1) are inferred to contain
significant sandstone reservoirs with the possible exception of depositional sequence C as
discussed above in Stratigraphy The Spearhole Formation was cored in Mundadjini 1 and
Boondawari 1 and visual estimates of porosity vary from generally poor (less than 5) to fair
(approximately 5ndash15) The McFadden Formation in Trainor 1 has porosity values of up to 232
and a maximum permeability of 195 md (Stevens and Adamides in prep) Sandstones from
Neoproterozoic formations form the acquifers in the following waterbores the McFadden
Formation in TWB 1 the Cornelia Formation in TWB 6 and the Brassey Range Formation in
TWB 8 and TWB 9 (Appendix 6 Table 61)
Based on outcrop observations the Durba Sandstone is considered to be the best reservoir of
the Savory Group Similarly some sandstones from the Tarcunyah Group also have good visible
porosity in outcrop
Dolomites occur in several formations in the sub-basin Reservoir potential may exist
particularly where the dolomites are stromatolitic and oolitic However dolomites have not been
drilled in the sub-basin and porosity can only be inferred from the preferential silicification of
some stromatolite bioherms observed in outcrop (Stevens and Grey 1997) Elsewhere in the
Officer Basin porosities of up to10 have been measured in dolomites A limestone breccia
(karst) is described from 663 to 677 m in drillhole LDDH1 (Fig 6 Busbridge 1994)
Seals
Indications of evaporitic environments in the Mundadjini Skates Hills and Boondawari
Formations are described by Williams (1992) In Mundadjini 1 from 287 to 337 m anhydrite and
chert occurs as nodules beds and veins in mudstone of the Mundadjini Formation Evaporitic
minerals (predominantly gypsum) are described in the Tarcunyah Group in LDDH1 The presence
of the Woolnough and Madley salt diapirs in the Officer Basin (approximately 110 km east of the
sub-basin) and halite beds over 25 m thick in the well Hussar 1 (130 km east of the sub-basin)
provide further evidence that evaporite seals may be present in the Savory Sub-basin
Mudstones and shales form only a small proportion of the limited Neoproterozoic outcrop in
the sub-basin but significant thicknesses of mudstone were encountered in the Mundadjini
Formation in Mundadjini 1 and Boondawari 1 the Tarcunyah Group in LDDH1 and in the
26
Cornelia Formation in Trainor 1 These data suggest that mudstones form a significant proportion
of strata in the sub-basin despite their limited outcrop
Traps
Potential structural closures including folds and faults occur at various scales throughout the
Savory Sub-basin However the region has only been mapped at 1250 000 scale and
independently closed structures such as domes have yet to be confirmed The western margin of
the basin contains abundant faults (with a northeast strike) but elsewhere faults are less common
Some anticlines are recognized in outcrop including one with a strike length of up to 45 km
inferred from surface bedding dips in the Mundadjini and Spearhole Formations at approximately
24deg15rsquoS 121deg10rsquoE on BULLEN (Fig 1)
Salt diapirs and other halokinetic structures are recognized in outcrop well and seismic data
in the Officer Basin to the west of the Savory Sub-basin and it is probable that there are
significant thicknesses of evaporitic sedimentary rocks in the sub-basin The gravity field data
suggest there is good potential for salt diapirs and traps related to halokinesis
Although there is potential for stratigraphic traps to be present in the sub-basin insufficient
data are available to assess them
Preservation of hydrocarbons
The range of thermal maturities measured to date and the large periods of time envisaged for
deposition of sediments implies hydrocarbon generation may have occurred a number of times
during the evolution of the Savory Sub-basin Any hydrocarbons that were generated early may
have been trapped in palaeostructures and remigration to younger traps could have taken place
later The Petermann Ranges Orogeny which has been equated with the Paterson Orogeny (Myers
1990) is believed to have occurred in the latest Neoproterozoic to early Cambrian This is the last
major tectonic event recognized in the sub-basin suggesting that it is reasonable to expect that trap
integrity will have been preserved
If the inference of the presence of thick halite beds in the sub-basin is correct the preservation
potential of sub-salt traps should be excellent
27
Reported hydrocarbon shows and oil seep
Amadeus Petroleum recorded minor oil shows in cores from Mundadjini 1 and Boondawari 1 In
Mundadjini 1 at 36102 m (top of the Spearhole Formation) a 3 mm thick zone had 10 moderate
white fluorescence with slow solvent cut This show was in a granular sandstone with visually
estimated porosity of about 10 In Boondawari 1 at 35364 m (within the Spearhole Formation) a
broken surface of sandstone had 40 moderate yellow-white fluorescence with slow solvent cut
Visually estimated porosity is about 5 Because the fluorescing surface was broken during the
drilling process this show could have resulted from contamination A second show occurs in
Boondawari 1 at 4963 m (within the Spearhole Formation) where a 1 cm-thick zone had 5 dull
yellow fluorescence with slow solvent cut in a conglomerate with visually estimated porosity of
about 10 The company intends to further investigate the nature of these occurrences
Minor bitumen is present at 6623 m in drillhole LDDH1 on GUNANYA (Figs 5 and 6) as a
vein in mudstones of the Tarcunyah Group A sample was analysed by gas chromatography
(Ghori in prep) and confirmed that it is natural bitumen (Appendix 5)
Mineral hole OD 23 drilled by Jubilee Gold Mines NL on NABBERU in the Bangemall Basin
immediately to the south of the Savory Sub-basin (Fig 5) encountered bitumen and trace oil in
vugs in dolomite (M Stevens unpublished data) but no further data are available at present
In their popular guide to the Canning Stock Route Gard and Gard (1990 p 218) refer to an
oil seep at Well 13 on TRAINOR (Fig 5) They reported that between 1977 and 1984 lsquonatural oilrsquo
was seen in the well Although the well is now largely filled with sediment four auger drill
samples were collected by the GSWA in 1995 and all four were analysed for oil shows One
sample from 315 m total depth (GSWA sample 135604) yielded just enough extract (519 ppm)
for saturate gas chromatography analysis The gas chromatograph (Appendix 5) shows that the
extract does contain some hydrocarbons probably from recent plant material Because the depth to
the oil was not quoted in Gard and Gard (1990) the hand-augered well may not have been deep
enough to properly test this reported seep
Geological and geophysical databases
Geological and geophysical data available for the Savory Sub-basin are limited The most recently
completed geological maps for the sub-basin were published by the GSWA between 1991 and
1995 (Williams and Tyler 1991 Williams 1992 1995ab)
28
The cores from the five drillholes listed in Table 2 believed to be all of the core available
from the sub-basin are available for inspection at GSWA Mineral exploration reports submitted
to GSWA may be searched using the WAMEX database and open-file reports are available on
microfiche Geophysical data acquired by the mining industry is not required to be filed with
GSWA if acquired over Vacant Crown Land which is the case for much of the sub-basin
Geophysical survey data submitted in mining tenement reports and which extend into Vacant
Crown Land remain confidential to the companies Original regional aeromagnetic and gravity
datasets are available from the Australian Geological Survey Organisation (AGSO)
Data pertinent to oil exploration in the sub-basin such as structural style and salt diapirism
are presented in a review of the hydrocarbon prospectivity of the Officer Basin (Perincek 1998)
Drilling
Significant drillholes in the sub-basin are summarized in Table 2
Petroleum industry data
Amadeus Petroleum drilled three petroleum exploration wells in the central west of the Savory
Sub-basin in late 1997 These wells Mundadjini 1 Boondawari 1 and Akubra 1 were drilled by
continuous diamond coring (Figs 5 and 6) All targeted potential reservoirs within the Spearhole
Formation with the Mundadjini Formation as the proposed seal The wells were located on
structures interpreted from Landsat images and limited geological investigations Both Mundadjini
1 and Boondawari 1 had minor oil shows as discussed above (Reported hydrocarbon shows)
Government data
Stratigraphic drillhole Trainor 1 was drilled by GSWA in 1995 (Stevens and Adamides in prep)
and the main results are discussed above (Source rocks and Maturity)
Mineral industry data
Normandy Exploration drillhole LDDH1 was cored in the Tarcunyah Group to a total depth of
701 m and provided source-rock and maturity data as discussed above
29
Oilmin NL drilled six percussion drillholes (BD 1 3 4 5 8 and 9) through sandstones and
shales in the northern part of the Savory Sub-basin to a maximum depth of 198 m (Fig 5
WAMEX Microfiche File M 26811 I 2610) but only brief geological descriptions are available
Hydrogeological data
Hydrogeological data within the Savory Sub-basin are limited although a long history of water
exploration extends back to the construction of the Canning Stock Route early this century No
detailed geological or wireline logs are available for the older wells along this route A few station
wells have been drilled by various methods on the south and west margins of the basin but data
are unavailable as reports are not required to be filed with the government Depth to watertable
throughout the basin is largely controlled by porosity of the bedrock
The GSWA drilled fifteen waterbores in the winter of 1995 in the southern part of the sub-
basin in preparation for the drilling of Trainor 1 and the proposed Bullen 1 Twelve bores found
water and six of these bores have salinities of less than 1000 mgL (Fig 5 Appendix 6 Table 61)
One waterbore TWB 6 has gamma ray and neutron logs run through PVC casing and these are
available from the GSWA with the digital log data included herein
Seismic data
No geophysical data have been acquired by the petroleum industry in the Savory Sub-basin
Seismic data acquired in the Officer Basin to the east particularly in the Gibson and Yowalga
Sub-basins is pertinent to structural interpretation in the Savory Sub-basin (Perincek 1996a
1998)
Aeromagnetic surveys
Government data
There are over 95 277 line kilometres of aeromagnetic data included in the AGSO dataset There
are three regional aeromagnetic surveys covering the Savory Sub-basin These were flown by the
Bureau of Mineral Resources (BMR now AGSO) in 1984 at a line spacing of 1500 m with 36 740
and 52 587 line kilometres flown and by Aerodata in 1984 at a line spacing of 1000m with 5950
line kilometres flown These data were reprocessed and interpreted for GSWA by Cowan (1995)
An edited copy of this report is included as Appendix 4 and the original report is filed in the
GSWA Library under S-series reports item 10331
30
Mineral industry data
The approximate locations of non-AGSO aeromagnetic surveys are shown in Figure 8 More
detailed information regarding the location of these surveys may be obtained using the GSWA
MAGCAT II database Additional information such as contours of aeromagnetic values may be
obtained by inspecting items on file with the GSWA
Gravity surveys
Government data
The average spacing for gravity data in the Savory Sub-basin is one station per 121 km2 (11 times 11
km grid) These data were principally collected by BMR in the early 1960s There are a few
additional regional gravity traverses across the sub-basin which are also included in the
BMRAGSO dataset These data were reprocessed and interpreted for GSWA (Fig 10) and a
report on this work is also included in Appendix 4
The GSWA completed a large semi-detailed gravity survey in the eastern Savory Sub-basin
utilizing helicopter support and Differential Global Positioning Survey (DGPS) techniques (Fig
8) This gravity survey completed in August 1995 consists of 2300 gravity stations on a 2 times 3 km
grid All stations were acquired by helicopter using Scintrex gravimeters and Ashtek dual
frequency DGPS equipment for determining location This highly efficient system allowed the
acquisition of more than 100 gravity stations per day in remote areas The resolution of this survey
is +30 cm and +05 microms-2 (Daishsat 1995) These data (Fig 11) represent a significant
improvement on the previous regional survey data and are available from GSWA (GSWA
1996ab) The results of the interpretation of these data were presented at the 1997 ASEG
Convention (Carlsen and Shevchenko 1997)
Mineral industry data
Three small gravity surveys were conducted by Oilmin NL (Fig 8) and the relevant WAMEX
reports are M 2681I 2610 I 2435 I 2567 These three surveys are of limited value because height
control was provided by barometers only and the surveys were not tied to the national gravity grid
31
23deg
25deg
120deg 122deg
Trainor 1
SAVORY
SUB-BASIN
MKS54 160498
100 km
1995 SavoryGravity Survey
254
-1056
micromsec2
Figure 10 Regional Bouguer gravity map of the Savory Sub-basin
23deg
24deg
25deg
122deg30 123deg
TRAINOR 1
123deg30
50 km
MKS53 160498
-116
-626
micro msec2
Figure11 Detailed Bouguer gravity map of the
Savory 1995 Gravity Survey from the eastern Savory Sub-basin
32
Government and academic reports
Chronostratigraphy and geochemistry
The understanding of Neoproterozoic organic chemistry palynology and structural evolution is
essential to the interpretation of hydrocarbon prospectivity Pertinent reports are included in the
bibliography (Appendix 1) Unpublished palaeontology reports describe the palynology of wells in
the Savory Sub-basin (Grey 1995andashe 1996a) Grey and Cotter (1996) discussed the potential for
Neoproterozoic palynomorphs to provide a biostratigraphic framework and palaeoenvironmental
interpretation Grey and Stevens (1997) reviewed the results of palynological studies of wells
drilled in the sub-basin and reported that Supersequence 1 palynomorphs are present in TWB 6
TWB 9 and LDDH1 (Appendix 3) Grey (1996b) reported on the use of stromatolites for
correlation in the Neoproterozoic and Stevens and Grey (1997) discussed the application of
stromatolite biostratigraphy in correlating isolated dolomite outcrops in the sub-basin with well
and seismic data in the Officer Basin and Centralian Superbasin
Although geochemical data from the Savory Sub-basin are very limited results mostly
confirm thermal maturities inferred from TAI for LDDH1 and Trainor 1 (Ghori in prep Stevens
and Adamides in prep) Those parts of the Officer Basin in Western Australia which lie to the
east of the Savory Sub-basin are sparsely drilled but Ghori (in prep) reports that most of the
Neoproterozoic succession presently lies within the oil-generative window However his study
has been unable to identify effective source-rock units and the source for oil shows Thin source
rocks are present in the Neoproterozoic in LDDH1 (Fig 9) and in three wells which lie to the east
and southeast of the Savory Sub-basin namely NJD 1 Kanpa 1A and Yowalga 3
Proposed work program
From the above limited information it is concluded that additional research on the hydrocarbon
potential of the sub-basin is justified and proposals are outlined below
bull Additional modelling of gravity and aeromagnetic data from the Savory Sub-basin is required
in light of the results from Trainor 1 and Boondawari 1 Trainor 1 showed that what appeared
to be a structurally simple area based on outcrop aeromagnetic and gravity data was in fact an
area of major structuring Boondawari 1 intersected a dolerite which is in good depth
agreement with aeromagnetic depth to source results showing this technique is useful in
detecting the depth to intrusive bodies
33
bull Additional data from mineral and petroleum exploration bores may become available and
analysis of samples from these wells should be undertaken and interpreted in the context of
their relevance to the Officer Basin
bull Stratigraphic coring in the Blake Fault and Fold Belt and in the Wells Foreland Sub-basin (Fig
1) targeting source rocks is considered essential to the continuing evaluation of the
hydrocarbon prospectivity of the Savory Sub-basin
bull Correlations using at least outcrop well and potential-field data should be prepared to link the
sub-basin with the better known parts of the Officer Basin to the east
bull Remapping is required to clarify boundary positions within the Cornelia Formation this may
resolve some of the current problems of the relationship between this unit and the rest of the
Savory Sub-basin
bull Further work is required to explain the Early Cambrian or Sturtian ages interpreted for the
Cornelia Formation from sedimentary zircon UndashPb dating in drillhole Trainor 1 The
determination of the age of the organically rich but overmature claystones in this well is
critical to assessing the hydrocarbon potential of the region
bull The thin dark mudstones intersected by Akubra 1 in the Mundadjini Formation warrant
geochemical analysis Analyses of the oil shows in Mundadjini 1 and Boondawari 1 are
currently being undertaken by Amadeus Petroleum
bull Geochemical analysis of hydrocarbons in the Bangemall Basin drillhole OD23 has been
performed by Jubilee Gold and the results will be reviewed when they are submitted to
GSWA The possibility of source rocks within the Bangemall Basin charging traps within the
Bangemall Basin and the overlying Savory Sub-basin requires further investigation
Conclusions
The Savory Sub-basin is a frontier region with only three recently drilled petroleum exploration
wells and no seismic data Based on existing geological and geophysical data it is considered too
early to draw conclusions about the hydrocarbon prospectivity of the sub-basin at this stage and
there are several reasons why the area warrants further investigation
34
1 Thick accumulations of sedimentary rocks are present (up to 8 km thickness inferred) which
may contain source reservoir and sealing strata
2 Minor oil shows occur in Mundadjini 1 and Boondawari 1 and bitumen is present in mineral
exploration drillhole LDDH1 suggesting that hydrocarbons have migrated within the
Neoproterozoic sequence of the Savory Sub-basin Oil and bitumen are present in mineral
exploration drillhole OD23 in the Bangemall Basin immediately to the south of the Savory
Sub-basin and it is possible that source rocks from the Bangemall Basin could charge traps in
the overlying Savory Sub-basin
3 The age of sedimentary rocks in the sub-basin is still poorly constrained but some of the
Neoproterozoic sedimentary rocks located on GUNANYA and TRAINOR are within the
hydrocarbon-generation window It is possible that a significant thickness of Phanerozoic
sedimentary rocks may also be present
4 Friable sandstones with visible porosity outcrop extensively suggesting numerous potential
reservoirs
5 Significant but not intense faulting and folding has been mapped implying large structural
traps may be present
6 Evaporitic sedimentary rocks occur in several formations and may provide good source rocks
and excellent seals
35
References
APAK S N and CARLSEN G M 1997 A compilation and review of data pertaining to the
hydrocarbon prospectivity of the Canning Basin Western Australia Geological Survey
Record 199610 103p
BAGAS L GREY K and WILLIAMS I R 1995 Reappraisal of the Paterson Orogen and
Savory Basin Western Australia Geological Survey Annual Review 1994ndash95 p 55ndash63
BUSBRIDGE M 1994 Lake Disappointment Exploration Licence 451064 Third Annual
Report Lake Disappointment Diamond Drill Hole LDDH1 Normandy Exploration Limited
Western Australia Geological Survey M-series Item 7567 A41358 (unpublished)
CARLSEN G M and SHEVCHENKO S I 1997 Petroleum exploration in Proterozoic basins
using potential fields data and stratigraphic coring Australian Society of Exploration
Geophysicists 12th Geophysical Conference Handbook Sydney 1997 Preview no 66 p 83
(abstract only)
COWAN D 1995 Savory Basin quantitative magnetic interpretation Western Australia
Geological Survey S-series S10331 (unpublished)
DAISHSAT PTY LTD 1995 Operational and processing report Savory Basin gravity survey
Western Australia Geological Survey S-series S10332 (unpublished)
GARD E and GARD R 1990 Canning Stock Route a travellerrsquos guide for a journey through
history Perth Western Australia Western Desert Guides 448p
GEOLOGICAL SURVEY OF WESTERN AUSTRALIA 1996a Savory Basin first vertical
derivative of Bouguer gravity image 1250 000 Western Australia Geological Survey
GEOLOGICAL SURVEY OF WESTERN AUSTRALIA 1996b Savory Basin Bouguer gravity
image 1250 000 Western Australia Geological Survey
GHORI K A R in prep Petroleum source rock potential and thermal history Officer Basin
Western Australia Western Australia Geological Survey Record
36
GREY K 1995a Savory Basin drillhole BWB 1 (Bullen waterbore) palynology and thermal
maturation GSWA Palaeontology Report no 199512 (unpublished)
GREY K 1995b Savory Basin drillholes TWB 1 2 6 9 (Trainor waterbores) palynology and
thermal maturation GSWA Palaeontology Report no 199520 (unpublished)
GREY K 1995c Palynology of Normandy-Poseidon Lake Disappointment-1 corehole
Tarcunyah Group Paterson Orogen GSWA Palaeontology Report no 199521 (unpublished)
GREY K 1995d Savory Basin drillhole Trainor 1 (Trainor diamond drilling) palynology and
thermal maturity GSWA Palaeontology Report no 199524 (unpublished)
GREY K 1995e Savory Basin drillhole Trainor 1 (Trainor diamond drilling) Additional
Preparation of two samples GSWA Palaeontology Report no 199528 (unpublished)
GREY K 1995f Neoproterozoic stromatolites from the Skates Hills Formation Savory Basin
Western Australia and a review of the distribution of Acaciella australica Australian Journal
of Earth Sciences v 42 p 123ndash132
GREY K 1996a Savory Basin drillhole Trainor 1 (Trainor diamond drilling) Additional
samples palynology and thermal maturation GSWA Palaeontology Report no 199615
(unpublished)
GREY K 1996b Preliminary stromatolite correlations for the Neoproterozoic of the Officer
Basin and a review of Australia-wide correlations GSWA Palaeontology Report no 199615
(unpublished)
GREY K and COTTER K L 1996 Palynology in the search for Proterozoic hydrocarbons
Western Australia Geological Survey Annual Review for 1995ndash96 p 70ndash80
GREY K and STEVENS M K 1997 Neoproterozoic palynomorphs of the Savory Sub-basin
Western Australia and their relevance to petroleum exploration Western Australia
Geological Survey Annual Review for 1996ndash97 p 49ndash54
HUBBARD R J PAPE J and ROBERTS D G 1985 Depositional sequence mapping as a
technique to establish tectonic and stratigraphic framework and evaluate hydrocarbon
potential on a passive continental margin in Seismic stratigraphy II an integrated approach
37
edited by O R BERG and D G WOOLVERTON American Association of Petroleum
Geologists Memoir 39 p 79ndash91
LIBBY WG 1995 A petrological report on six samples of bore cuttings from the Savory Basin
Western Australia Western Australia Geological Survey S-series S31307 (unpublished)
MORTON JGG and DREXEL JF 1997 The petroleum geology of South Australia Vol 3
Officer Basin South Australia Department of Mines and Energy Resources Report Book
9719
MUHLING P C and BRAKEL A T 1985 Geology of the Bangemall Group mdash the evolution
of an intracratonic Proterozoic basin Western Australia Geological Survey Bulletin 128
219p
MYERS J S 1990 Precambrian tectonic evolution of part of Gondwana southwestern Australia
Geology v18 p 537ndash540
NELSON D R 1997 Compilation of SHRIMP UndashPb zircon data Western Australia Geological
Survey Record 19972 196p
PAYTON C E 1977 Seismic stratigraphy mdash applications to hydrocarbon exploration
American Association of Petroleum Geologists Memoir 26 516p
PERINCEK D 1996a The age of NeoproterozoicndashPalaeozoic sediments within the Officer Basin
of the Centralian Super-basin can be constrained by major sequence-bounding unconformities
APPEA Journal v 36 pt 1 p 350ndash368
PERINCEK D 1996b The stratigraphic and structural development of the Officer Basin
Western Australia a review Western Australia Geological Survey Annual Review 1995ndash
1996 p 135ndash148
PERINCEK D 1998 A compilation and review of data pertaining to the hydrocarbon
prospectivity of the Officer Basin Western Australia Geological Survey Record 19976
POSAMENTIER H W JERSEY M T and VAIL P R 1988 Eustatic controls on clastic
deposition 1 mdash Conceptual framework in Sea-level changes an integrated approach edited by
C K WILGUS B S HASTINGS C G St C KENDALL H W POSAMENTIER
38
C A ROSS and J C VAN WAGONER Society of Economic Paleontologists and
Mineralogists Special Publication no 42
STEVENS M K and ADAMIDES N G in prep GSWA Trainor 1 well completion report
Savory Sub-basin Officer Basin Western Australia with notes on petroleum and mineral
potential Western Australia Geological Survey Record 199612
STEVENS M K and GREY K 1997 Skates Hills Formation and Tarcunyah Group Officer
Basin mdash carbonate cycles stratigraphic position and hydrocarbon prospectivity Western
Australia Geological Survey Annual Review for 1996ndash97 p 55ndash60
SUMMONS RE and POWELL C McA 1991 Petroleum source rocks of the Amadeus Basin
in Geological and geophysical studies in the Amadeus Basin central Australia edited by R J
KORSCH and JM KENNARD Australia BMR Geology and Geophysics Bulletin 236
TRAVERSE A 1988 Palaeopalynology Boston Unwin Hyman 600p
VAIL P R MITCHUM R M Jr TODD R G WIDMIER J M THOMPSON S III
SANGREE J B BUBB J N and HATLELID W G 1977 Seismic stratigraphy and
global changes of sea level in Seismic stratigraphy mdash applications to hydrocarbon
exploration edited by C E PAYTON American Association of Petroleum Geologists
Memoir 26 516p
WALTER M R and GORTER J 1994 The Neoproterozoic Centralian Superbasin in Western
Australia the Savory and Officer Basins in The sedimentary basins of Western Australia
edited by P G PURCELL and R R PURCELL Petroleum Exploration Society of Australia
Symposium Perth WA 1994 Proceedings p851ndash864
WALTER M R GREY K WILLIAMS I R and CALVER C R 1994 Stratigraphy of the
Neoproterozoic to early Palaeozoic Savory Basin and correlation with the Amadeus and
Officer Basins Australian Journal of Earth Sciences v 41 p 533ndash546
WALTER M R VEEVERS J J CALVER C R and GREY K 1995 Neoproterozoic
stratigraphy of the Centralian Superbasin Australia Precambrian Research v 73 p 173ndash195
WILLIAMS I R 1992 Geology of the Savory Basin Western Australia Western Australia
Geological Survey Bulletin 141 115p
39
WILLIAMS I R 1995a Bullen WA (2nd Edition) Western Australia Geological Survey
1250 000 Geological Series Explanatory Notes 23p
WILLIAMS I R 1995b Trainor WA (2nd Edition) Western Australia Geological Survey
1250 000 Geological Series Explanatory Notes 31p
WILLIAMS I R and TYLER I M 1991 Robertson WA (2nd edition) Western Australia
Geological Survey 1250 000 Geological Series Explanatory Notes 36p
40
41
Appendix 1
Bibliography
Reports which are relevant to this investigation but which are not specifically cited are listed
below
BAILLIE P W POWELL C McA LI Z X and RYALL A M 1994 The tectonic
framework of Western Australiarsquos Neoproterozoic to recent sedimentary basins in The
sedimentary basins of Western Australia edited by P G PURCELL and R R PURCELL
Petroleum Exploration Society of Australia Symposium Perth WA 1994 Proceedings p
45ndash62
BRADSHAW M T BRADSHAW J MURRAY A P NEEDHAM D J SPENCER L
SUMMONS R E WILMOT J and WINN S 1994 Petroleum systems in West Australian
basins in The sedimentary basins of Western Australia edited by P G PURCELL and R R
PURCELL Petroleum Exploration Society of Australia Symposium Perth WA 1994
Proceedings p 93ndash118
CLARKE G L 1991 Proterozoic tectonic reworking in the Rudall Complex Western Australia
Australian Journal of Earth Science v38 p 31ndash44
COCKBAIN A E and HOCKING R M 1990 Phanerozoic in Geology and mineral resources
of Western Australia Western Australia Geological Survey Memoir 3 p 750ndash755
ETHERIDGE M and WALL V 1994 Tectonic and structural evolution of the Australian
Proterozoic 12th Australian Geological Convention Geological Society of Australia
Abstracts no 37 p 102ndash103
GOODE A D T 1981 Proterozoic geology of Western Australia in Precambrian of the
Southern Hemisphere Developments in Precambrian geology 2 edited by I R HUNTER
Amsterdam Elsevier p 105ndash203
GREY K and JACKSON M J 1983 A re-assessment of stromatolite evidence for the
correlation of the Late Proterozoic Neale and Ilma Beds Officer Basin Western Australia
Australia BMR Journal of Australian Geology and Geophysics v 8 p 359
42
HICKMAN A H WILLIAMS I R and BAGAS L 1994 Proterozoic geology and
mineralization of the TelferndashRudall region Paterson Orogen Geological Society of Australia
(WA Division) Excursion Guidebook no 5 56p
HOCKING R M MORY A J and WILLIAMS I R 1994 An atlas of Neoproterozoic and
Phanerozoic basins of Western Australia in The sedimentary basins of Western Australia
edited by P G PURCELL and R R PURCELL Petroleum Exploration Society of Australia
Symposium Perth WA 1994 Proceedings p 21ndash 44
JACKSON P R 1966 Geology and review of exploration Officer Basin Western Australia
Hunt Oil Company Western Australia Geological Survey S-series S26 (unpublished)
JACKSON M J 1971 Notes on a geological reconnaissance of the Officer Basin Western
Australia Australia BMR Geology and Geophysics Record 19715 30p
JACKSON M J and van de GRAAFF W J E 1981 Geology of the Officer Basin Western
Australia Australia BMR Geology and Geophysics Bulletin 206 102 p
LOWRY D C JACKSON M J van de GRAAFF W J E and KENNEWELL P J 1971
Preliminary result of geological mapping in the Officer Basin Western Australia Western
Australia Geological Survey Annual Report for 1971 p 50ndash56
MYERS J S 1990 Precambrian in Geology and mineral resources of Western Australia
Western Australia Geological Survey Memoir 3 p 737ndash750
MYERS J S SHAW R D and TYLER I M 1994 Proterozoic tectonic evolution of
Australia 12th Australian Geological Convention Geological Society of Australia Abstracts
no 37 p 312
NEDIN C and JENKINS R J F 1991 Re-evaluation of unconformities separating the
lsquoEdiacaranrsquo and Cambrian systems South Australia Palaios v 6 p 102ndash108
PHILLIPS B J JAMES A W and PHILIP G M 1985 The geology and hydrocarbon
potential of the north-western Officer Basin APEA Journal 25 (1) p 52ndash61
POWELL C McA LI Z X McELHINNY M W MEERT J G and PARK J K 1993
Paleomagnetic constraints on timing of the Neoproterozoic breakup of Rodinia and Cambrian
formation of Gondwana Geology v 21 p 889ndash892
43
POWELL C McA PREISS W V GATEHOUSE C G KRAPEZ B and LI Z X 1994
South Australian record of a Rodinian epicontinental basin and its mid-Neoproterozoic
breakup to form the Palaeo-Pacific Ocean Tectonophysics v 237 no 3ndash4 p 113ndash140
PREISS W V 1976 Proterozoic stromatolites from the Nabberu and Officer Basins Western
Australia and their biostratigraphic significance South Australia Geological Survey Report
of Investigations no 47 p 1ndash51
TOWNSON W G 1985 The subsurface geology of the western Officer Basin mdash results of
Shellrsquos 1980ndash1984 petroleum exploration campaign APEA Journal v 25 (1) p 34ndash51
WATTS K J 1982 The geology of the Townsend Quartzite Upper Proterozoic shallow water
deposit of the Northern Officer Basin Western Australia Perth University of Western
Australia BSc honours thesis (unpublished)
WELLS A T and KENNEWELL P J 1974 Evaporite exploration in the Officer Basin
Western Australia at the Madley Diapirs Australia BMR Record 1974194 (unpublished)
WILLIAMS I R and MYERS J S 1990 Paterson Orogen in Geology and mineral resources
of Western Australia Western Australia Geological Survey Memoir 3 p 274ndash286
WILLIAMS I R 1990 Savory Basin in Geology and mineral resources of Western Australia
Western Australia Geological Survey Memoir 3 p 329ndash334
WILLIAMS I R 1994 The Neoproterozoic Savory Basin Western Australia in The
sedimentary basins of Western Australia edited by P G PURCELL and R R PURCELL
Petroleum Exploration Society of Australia Symposium Perth WA 1994 Proceedings p
841ndash850
WILSON R B 1967 Woolnough Hills and Madley diapiric structures Gibson Desert WA
APEA Journal v 7 p 94ndash102
44
Appendix 2
Meteorological data (from Bureau of Meteorology Perth 1994)
Table 21 Wiluna rainfall (mm)
Year Jan Feb Mar Apr May Jun Jul Aug Sept Oct Nov Dec
1975 0 45 446 309 306 59 276 4 34 886 638 164 1976 16 154 12 138 53 16 34 62 12 238 0 2 1977 44 0 66 74 68 95 24 363 1 58 12 727 1978 234 522 94 16 0 96 367 24 16 353 185 45 1979 19 173 122 88 91 4 0 246 58 0 169 114 1980 148 764 68 1081 259 626 629 06 56 02 174 0 1981 123 476 192 32 196 118 44 74 14 0 28 312 1982 374 705 206 244 1079 92 02 143 368 526 368 118 1983 1 112 928 248 0 212 56 32 5 1 42 496 1984 149 7 342 84 836 0 348 132 224 04 16 172 1985 596 483 0 166 556 0 514 56 0 0 4 0 1986 0 154 35 0 0 1085 23 01 239 137 0 04 1987 1204 119 19 89 17 575 154 126 07 1 0 398 1988 46 202 164 13 388 0 202 104 0 0 224 1309 1989 207 234 26 703 278 536 57 0 01 0 144 02 1990 1035 23 281 46 126 53 94 218 44 9 42 0 1991 48 0 41 45 0 472 297 12 0 1 0 7 1992 112 96 1025 1227 323 65 04 174 0 132 48 4 1993 0 697 0 202 445 0 12 306 18 05 14 33 Mean 25 35 22 27 27 25 18 12 6 13 13 21
JAN FEB MAR APR MAY JUN JUL AUG SEP OCT NOV DEC0
10
20
30
40
Mea
n R
ain
fall
(mm
)
Month
Mean monthly rainfall in Wiluna
MKS41 140498
45
Table 22 Wiluna minimum temperature (degC)
Year Jan Feb Mar Apr May Jun Jul Aug Sept Oct Nov Dec
1975 ndash 23 203 15 94 63 71 62 103 124 169 205 1976 242 229 194 15 10 63 59 73 95 143 16 228 1977 243 25 197 148 96 95 56 86 102 ndash 188 23 1978 241 232 203 18 102 64 76 8 9 152 19 205 1979 255 226 216 167 83 6 59 79 97 145 198 223 1980 255 226 231 155 134 83 68 75 121 108 193 223 1981 245 216 19 182 119 6 54 78 138 159 163 218 1982 232 224 177 16 ndash ndash 37 111 112 164 209 225 1983 235 24 197 147 112 88 39 88 121 162 189 219 1984 241 243 191 156 ndash 72 66 7 95 161 182 211 1985 244 231 ndash 159 98 65 71 73 117 147 205 ndash 1986 ndash 229 226 155 93 96 43 49 10 122 ndash 219 1987 ndash 217 183 175 85 77 68 68 112 ndash ndash 221 1988 238 214 209 178 111 ndash ndash 86 104 157 171 195 1989 ndash 237 199 165 107 67 44 61 107 131 187 ndash 1990 232 ndash 211 155 118 62 57 87 102 149 195 22 1991 26 256 217 168 122 101 78 ndash 113 18 168 219 1992 227 227 214 169 102 98 59 69 ndash 125 159 196 1993 241 218 196 171 103 ndash 49 68 88 128 192 211 Mean 24 23 20 16 10 8 6 8 11 14 18 21
NOTE Dashes indicate data unavailable
JAN FEB MAR APR MAY JUN JUL AUG SEP OCT NOV DEC0
10
20
30
40
Month
MKS43 140498
50
Mean monthly minimum temperatures at Wiluna
Mea
n T
emp
erat
ure
(degC
)
46
Table 23 Wiluna maximum temperature (degC)
Year Jan Feb Mar Apr May Jun Jul Aug Sept Oct Nov Dec
1975 ndash 349 326 281 247 201 197 212 256 248 31 344 1976 374 369 346 297 248 206 208 225 265 287 313 388 1977 397 392 352 296 234 212 222 244 ndash 308 337 383 1978 378 345 346 316 242 195 176 205 231 295 334 356 1979 403 36 364 295 ndash ndash ndash 193 242 318 359 373 1980 392 342 377 275 24 176 179 233 292 288 349 391 1981 385 346 337 342 242 178 201 224 30 326 326 369 1982 372 359 315 307 ndash ndash 196 253 252 305 353 379 1983 381 389 327 272 263 222 187 248 287 321 336 366 1984 378 393 322 299 226 215 178 214 234 ndash 336 364 1985 40 366 ndash 294 224 216 205 212 284 307 355 ndash 1986 ndash 383 372 307 ndash 193 166 196 261 277 ndash 382 1987 ndash 339 328 305 21 202 214 218 275 ndash ndash 374 1988 388 365 353 301 23 ndash ndash 228 283 334 31 33 1989 ndash 375 339 285 238 179 181 219 275 298 336 ndash 1990 368 ndash 36 309 268 19 188 205 274 309 373 393 1991 414 416 363 315 268 206 21 ndash 279 338 332 368 1992 363 383 336 263 213 178 213 197 ndash 285 313 359 1993 396 357 344 301 221 ndash 197 215 253 294 347 362 Mean 39 37 34 30 24 20 20 22 27 30 34 37 NOTE Dashes indicate data unavailable
JAN FEB MAR APR MAY JUN JUL AUG SEP OCT NOV DEC0
10
20
30
40
Month
MKS42 140498
50
Mean monthly maximum temperatures at Wiluna
Mea
n T
emp
erat
ure
(degC
)
47
Appendix 3
Table 31 Summary of palynological results
Drillhole Depth (m) F no(a) GSWA no Lithology Formation Assemblage TAI(b)
BWB 1 74ndash75 F49668 135741 dark-grey siltstone basalt Jilyilli gt5 BWB 1 98ndash100 F49669 135742 dark-grey siltstone basalt Jilyilli gt5 BWB 1 121ndash122 F49670 135743 dark-grey siltstone basalt Jilyilli gt5 TWB 1 86ndash87 F49671 135631 dark-grey siltstone McFadden 3+ TWB 1 104ndash105 F49672 135632 dark-grey siltstone Cornelia 3+ TWB 1 121ndash122 F49673 135633 dark-grey siltstone Cornelia 4 TWB 2 14ndash15 F49674 135634 dark-grey siltstone Skates Hills 3+ TWB 6 49ndash50 F49675 135675 dark-grey siltstone Cornelia 1 3+ TWB 9 49ndash51 F49676 135704 dark-grey siltstone Brassey Range 1 3+ Trainor 1 37497- F49733 138939 black mudstone with Cornelia 5 37509 light-grey siltstone Trainor 1 3809 F49734 138940 dark-grey and black Cornelia 4- laminated mudstone Trainor 1 4170 F49735 138941 black unlaminated mudstone Cornelia 4- Trainor 1 4950 F49851 139501 dark-grey indurated siltstone Cornelia 5 Trainor 1 6032 F49852 139502 dark- and light-grey Cornelia 5 indurated siltstone Trainor 1 6434 F49853 139503 greenish indurated finely Cornelia 5 laminated siltstone LDDH 1 270 F49678 138934 dark-grey siltstone interbeds Waters 1 3+ in enterolithic evaporite Tarcunyah Gp LDDH 1 277 F49679 138935 dark-grey siltstone in cavity Waters 1 3+ in enterolithic evaporite Tarcunyah Gp
NOTES (a) GSWA Fossil Catalogue number (b) TAI = Thermal Alteration Index of Traverse (1988 plate 1)
48
Appendix 4
Savory Sub-basin quantitative magnetic and gravity interpretation (extracted from Cowan 1995)
Summary
A program of quantitative aeromagnetic interpretation has been completed on BMRAGSO data from the Savory Sub-
basin Western Australia Quantitative aeromagnetic interpretation utilized the 3D Euler deconvolution method
supported by wavenumber filtering and image processing The results have provided useful information on structural
trends and depth to magnetic sources in a structurally complex area Depth to magnetic source analysis has provided
information on intra-sedimentary magnetic sources as well as basement rocks
The results of the interpretation support previously identified depocentres However the presence of magnetic
sources at several levels makes it very difficult to produce a reliable magnetic basement depth contour map It is
considered more productive to work with the 3D Euler colour circle plots and images rather than trying to contour the
results It would be necessary to carry out a full-scale interpretation of the BMRAGSO profile data to improve on the
3D Euler results The regional gravity was found to be useful in interpreting the regional setting of the area although
the very wide data spacing limits quantitative use of the data The gravity data show quite a complex picture with
limited consistent correlation between gravity features and basin structures This suggests that gravity anomalies
reflect changes in density of the basement rocks rather than basement topography especially in the northern part of the
basin
It is recommended that the GSWA investigate access to company confidential high-resolution aeromagnetic data
prior to planning further aeromagnetic surveys Private companies have flown large parts of the northern half of the
area as part of their diamond exploration program Additional gravity coverage of the area may be more cost effective
than magnetic surveys as the gravity data provides more information on changes within the sedimentary section
Introduction
The main use of aeromagnetic data in petroleum exploration has been the determination of magnetic basement
topography although there has been increasing interest in analysis of intra-sedimentary magnetic anomalies
intrabasement and suprabasement magnetic anomalies These anomalies are used to determine depth to magnetic
basement rocks and hence determine the thickness of the sedimentary sequence Unfortunately interpretation of the
intrabasement and suprabasement magnetic anomalies is non-unique in terms of position and size of causative sources
because of the inherent ambiguity of potential-field methods However this ambiguity can be reduced by placing
49
constraints on source geometry and magnetization and by using geological and other geophysical data to constrain
the solution
Before 1970 most depth-determination techniques involved graphical determination of slopes of selected
magnetic anomalies and application of various empirical factors to convert the slopes into depth estimates Geological
Society of America Memoir 47 Interpretation of Aeromagnetic Maps by Vacquier et al (1951) was a landmark for
this type of interpretation
Automated interpretation procedures have played an increasingly important role in depth interpretation and a
wide range of techniques have been developed Many of these techniques are designed for application to located data
profiles and assume a two-dimensional geometry However there has been renewed interest in techniques applicable
to gridded data
Two distinct types of method can be recognized In the first case often described as discrete methods individual
isolated magnetic anomalies are interpreted and the results used to produce a map of basement relief In the second
case often described as continuous methods areas of data containing a number of anomalies are interpreted
statistically to produce direct output of basement depths
The discrete methods usually involve a semiautomatic initial phase which generates a large number of possible
depth solutions and an interactive second phase to screen and select acceptable solutions The advantage of this
approach is that the interpreter can select features that are relatively free from interference from adjacent anomalies
and consider all aspects of a particular magnetic anomaly The disadvantage is that interpretation can be very time
consuming as a wide range of depths are usually possible depending on the initial model chosen and a significant
amount of effort is needed to select the correct model In the case of the Savory Sub-basin dataset we encountered
problems in separating basement related effects from the effects of shallower intrasedimentary magnetic sources
Because of these problems we have concentrated on displaying the Euler results accompanied by separation filter
images of the data to show the shallower effects and deeper effects rather than trying to refine a 3D Euler
deconvolution depth-to-crystalline-basement contour
The continuous methods are very direct provided that the rather restrictive assumption can be made that all
anomalies are due to lateral magnetization changes due to basement topography This means that shallow effects and
large intrabasement anomalies must be removed from the data This involves judgement and skill as it is necessary to
distinguish between the lower amplitude suprabasement anomalies due to basement topography and the larger
intrabasement anomalies reflecting magnetization changes within the basement These methods were not considered
suitable for the Savory Sub-basin magnetic dataset but were used to invert the gravity data
50
Limitations of magnetic and gravity interpretation
Interpretation of the area is limited by a shortage of information on the nature and physical properties of the deeper
sedimentary sequence and the underlying basement rocks However using techniques such as cross-correlation of
gravity and pseudo-gravity data it is possible to try to differentiate between anomalies relating to basement and those
related to the sedimentary sequence
Gravity anomalies reflect changes within the sedimentary sequence as well as basement condition These
changes in density of sedimentary rocks produce gravity anomalies without a corresponding magnetic anomaly hence
the complementary nature of gravity and magnetic surveys The main use of magnetics is to determine depth to
magnetic basement and any intra-sedimentary volcanic rocks or intrusives whereas gravity provides much more
general information on the sedimentary sequence
Unfortunately interpretation of gravity anomalies is complicated since they can be due to a number of geological
features including
bull major basement faults
bull basement highs
bull igneous intrusions within the basement
bull sedimentary basins which may or may not be isostatically compensated
bull intra-sedimentary volcanics and associated plutonic centres
Two major problems affect the interpretation of both magnetic and gravity data
1 The inherent ambiguity of potential-field data There is no unique solution to any measured gravity or magnetic
anomaly and theoretically there will be an infinite number of source geometry and magnetizationdensity
combinations which will fit the observed data This means that any a priori information which helps to select a
suitable model is very useful
2 Measured anomalies are the summation of effects from different depths For example an observed gravity profile
may contain contributions from shallow sources (density variations within the sedimentary basin) intermediate
depth sources (density variations due to large igneous intrusions within the basement) and deep sources (crustal
thinning producing a mantle anomaly) Separation of these component responses is the regionalresidual problem
which we solve using spectral analysis and differential upward continuation-based separation filtering
Regional setting and interpretation overview
The area studied includes parts of BALFOUR DOWNS (SF51-9) RUDALL (SF51-10) ROBERTSON (SF51-13) GUNANYA
(SF51-14) COLLIER (SG50-4) BULLEN (SG51-1) TRAINOR (SG51-2) MADLEY (SG51-3) NABBERU (SG50-5)
STANLEY (SG51-6) and HERBERT (SG51-7) 1250 000 sheets Broadly the area lies between latitudes 22deg00rsquondash25deg30rsquoS
and longitudes 119deg30rsquondash123deg30rsquoE
51
Regional gravity
The AGSO regional gravity data (at nominal 11 km spacing) was gridded at a 4 km mesh spacing using a minimum-
curvature algorithm Bouguer gravity values in the area are negative reflecting mass deficiency at depth and range
from -84 mgals to -25 mgals
A Bouguer gravity colour image is shown as Figure 41 A residual grid was produced by removing a fifth-order
orthogonal polynomial from the Bouguer data but did not add to the interpretation
120deg 121deg 122deg 123deg
23deg
24deg
25deg
-25
-84
50 km
MKS46 180598
mgal
Figure 41 Regional Bouguer gravity (BMRAGSO data) gridded at 4 km
52
The data show a complex pattern of positive and negative anomalies with no clearly defined trends Correlations
with aeromagnetic data and known basin structures are poor A vague north-northwest linear trend appears to coincide
with the Marloo Fault (Figure 42) A prominent negative anomaly appears to coincide with the Blake Fold and Fault
Belt depocentre and continues as a narrower negative anomaly to the east until it widens out again near the edge of the
basin Elsewhere the gravity data show little correlation with known basin structures and it is likely that especially in
the north of the area gravity anomalies are due to density changes in the basement rather than changes in basement
topography
Production of wavelength-filtered residual gravity plots and vertical gradient plots showed very patchy aliased
data reflecting poor sampling in much of the area
Regional magnetics
The AGSO regional aeromagnetic data were gridded at a 400 m mesh spacing using a minimum-curvature algorithm
(Figure 43) Most of the data has a line spacing of 1600 m with small areas of 1 km spacing The quality of the data is
acceptable for regional interpretation but is not adequate for detailed analysis The accuracy of the flight path is rather
variable reflecting the vintage of the data and the noise envelope of the data is poor by modern standards Problems
were also encountered in joining different map sheets
The magnetic anomaly pattern over the south and west part of the area shows a strong high frequency signature
reflecting the presence of widespread basic sills and dykes Some of the major north-northeasterly trending dykes can
be traced over considerable distances
Discontinuous high-frequency anomalies extend as a northwest-trending zone through the centre of the area and
this zone includes a conspicuous circular magnetic anomaly which is probably a ring complex
The northern and eastern parts of the area are characterized by long-wavelength deep-seated basement magnetic
anomalies with 120deg and 150deg trends dominant The Marloo and Perentie Faults (Figure 42) appear as distinct linear
zones and offsets A prominent easterly trending negative anomaly in the northwest of the area appears to swing round
to the southeast and may separate different basement blocks One possible interpretation is that this very deep seated
anomaly separates areas of Archaean and Proterozoic basement
Regional geology
The regional geology is described in Williams (1992) The GSWA provided a digitized version of Plate 2 from this
Bulletin the structural interpretation map to use as an overlay (Figure 42)
53
Pp
Pp
PSd
PSd
PSd
PSd
PSd
PSo
PSt
PSt
PSf
PSf
PSf
PSb
PSb
PSb
PSsPSs
PSs
PSb
PSm
PSp
PSc
PSc
PSw
PSw
PSw
PSg
PSr
PSj
PSg
PM
Pk
PY
PY
PSd
L
L
L
L
L
L
L
LL
L
L
L
LL
L
LL
L L
LL
L L
L
L
L
L
L
L
L
LL
L
L
BLAKEDEPOCENTRE
MA
RLO
O
FAU
LT
PERENTIEFAULT
50 km
MKS39120598
120deg 121deg 122deg 123deg
25deg
24deg
23deg
Approximate boundaryof aeromagnetic interpretation
PML
PSgL
PSjL
PML
PSpL
PML
PML
PSfL
PSfL
PSpL
LPc
LPcLPcPSrL
LPA
Durba Sandstone
Woora Woora Formation
McFadden Formation
Tchukardine Formation
Boondawari Formation
Skates Hills Formation
Mundadjini Formation
Coondra Formation
Spearhole Formation
Watch Point Formation
Jilyili Formation
Brassey Range Formation
Glass Spring Formation
Paterson Formation
Yeneena Group
Karara Formation
Cornelia Formation
Kahrban Subgroup
Bangemall Group
Fault
Formation boundary
PSdL
PSoL
PSfL
PStL
PSbL
PSsL
PSmL
PScL
PSpL
PSwL
PSjL
PSrL
PSgL
Pp
PYL
PkL
LPc
LPA
PML
Savory Group Other Units
PYL
Figure 42 Regional geology and structure map (after Williams 1992)
54
120deg 121deg 122deg 123deg
23deg
24deg
25deg
5820
3750
MKS47 180598
nT
50 km
Figure 43 Regional aeromagnetic data total magnetic intensity (BMRAGSO data) gridded at 400 m
Analysis
3D analysis
3D Euler deconvolution was used as the primary depth-determination method The advantage of this approach is that
consistent solutions can be obtained over the entire area with minimal assumptions about source geometries Euler
deconvolution of gridded data is used for positional information and estimation of depth to top of source Euler
55
deconvolution yields a large number of depth solutions which have to be screened to reject spurious solutions Results
are plotted as circles in eight depth ranges with radius proportional to depth and colour coded
The 400 m total magnetic intensity grid was used for the analysis Horizontal gradients in x and y and the vertical
gradient were calculated 3D Euler deconvolution was tested on the 400 m gridded data using windows of 9 times 9 and
11 times 11 and 16 times 16 data points and structural indices 05 (fault) and 10 (sill or dyke) It was concluded that the
16 times 16 window produced the best results overall and final plots were produced for the 16 times 16 window and structural
index 05 (Fig 44) Results were very good over the northern and central parts of the area showing magnetic sources
Figure 44 Depth to magnetic source 3D Euler deconvolution 16 times 16 window of 400 m gridded data structural index 05
56
at several different levels Unfortunately in the extreme south of the area shallow intrasedimentary magnetic sources
(sills and dykes) dominated the inversion and the results contained few basement solutions
In order to reduce these problems the 400 m gridded data were filtered using a separation filter based on
interpretation of the log-energy spectrum The 3D Euler method was run on the filtered data in order to generate more
basement-depth solutions Results for the deep-separation filter data were gridded and presented as a colour image in
Cowan (1995) Attempts to grid the Euler output were unsatisfactory and it is considered safer to interpret the 3D
Euler depth plots The 3D Euler depth results from the separation-filter run should be analysed with care as perfect
separation of the basement can never be achieved and there will always be some contamination from sources at
different levels
The results of original total magnetic intensity 3D Euler depth estimation for structural index 05 using a 16 point
window have been plotted at 1500 000 scale (not included in this publication but available in Cowan (1995) from the
GSWA Library as S10331) and as reduced A4 colour circle plots (Figure 44)
The results of deep-basement 3D Euler depth estimation for structural index 05 using a 16 point window have
been plotted as a colour image at 1500 000 scale and as an A4 image (not included in this publication)
2D analysis
Two equispaced profiles were interpolated with a 50 m station interval from the AGSO-located data profiles for the
BULLEN 1250 000 sheet The interpolated profiles were analysed using 2D Euler deconvolution and Werner
deconvolution Results are included in Cowan (1995) and show the use of these methods for more detailed analysis
Filtered data
In order to reconcile 3D Euler results from shallow basement and intrasedimentary magnetic sources we produced
several separation-filtered maps and images We found the shallow-layer double-separation filter (Figure 45) to be
very effective for shallow sources and the deep-layer standard-separation filter (Figure 46) for the basement layer
Gravity and magnetic data correlation
Both lsquoreduced to the polersquo (RTP) magnetics (Figure 47) and pseudo-gravity data (Figure 48) were produced as part of
the reconciliation of gravity and magnetic signatures In both cases the filtering operations assumed magnetization by
induction in the present Earths field The RTP data are fairly similar to the total magnetic intensity The pseudo-
57
gravity data are dominated by a northwest-trending strong positive anomaly and there is little correlation with the
Bouguer gravity data
The poor magneticgravity correlation is confirmed by cross-correlation of the RTP magnetics and the gravity
gradient The correlation plot in Figure 49 shows little coherent response with numerous zones of positive and
negative correlation
Figure 45 Regional aeromagnetic data shallow layer separation filter (BMRAGSO data) gridded at 400 m
Results
In the north and east of the area on the Wells Foreland Sub-basin trend (refer to Figure 1 main text) we see a range
of quite deep 3D Euler depths and several trend directions with north-northwesterly dominant There are relatively few
shallow intrasedimentary solutions in this zone
The second area of deep 3D Euler solutions lies over the Blake depocentre (Figure 43) with several trend
directions
Elsewhere the 3D Euler results are dominated by shallow intrasedimentary depth solutions reflecting mainly the
dolerite sills dykes and the ring complex However where we do see basement-related solutions in the south and
west of the area they appear to be shallower than those noted for the Wells Foreland Sub-basin and the Blake
depocentre
58
Figure 46 Regional aeromagnetic data deep-layer separation filter (BMRAGSO data) gridded at 400 m
Figure 48 Regional aeromagnetic data pseudo-gravity transform (BMRAGSO data) gridded at 400 m
Figure 47 Regional aeromagnetic data reduced-to-pole (BMRAGSO data) gridded at 400 m
Figure 49 Regional aeromagnetic and gravity data gravitymagnetic correlation using RTP magnetics and gravity gradient (BMRAGSO data) gridded at 4 km
59
This subdivision of the area into two zones of deep solutions is consistent with interpreted depocentres
However the interference between sources at different levels and the complexity of the magnetic response of the
basement rocks precludes more refined interpretation at this stage
The area of deep 3D Euler solutions over the Blake depocentre correlates with the pronounced negative gravity
anomaly discussed in the gravity interpretation section Using a density contrast of -015 gcc the negative gravity
anomaly could indicate up to 6ndash8 km of low-density sedimentary rocks depending on assumptions about the regional
field
The area of deep 3D Euler solutions over the Wells Foreland Sub-basin has a complex gravity expression and no
clear basin structure emerges from inversion of these data As noted previously it is likely that observed gravity
anomalies reflect contrasts in basement density rather than basement topography
Separation filtering applied to the magnetic data helps to enhance the intrasedimentary magnetic signature and to
give a better impression of the basement magnetic signature even though separation of the basement response is not
perfect
Conclusions
Quantitative aeromagnetic interpretation using 3D Euler deconvolution supported by wavenumber filtering and image
processing has been successful in providing structural trend and depth information for the Savory Sub-basin
Quantitative magnetic interpretation has revealed two zones of relatively deep magnetic basement beneath the
Wells Foreland Sub-basin and the Blake depocentre
This analysis of the magnetic data supports interpreted depocentres but the complexity of the basement magnetic
signature and interference from sources at different depths precludes further refinement to a map of basement
topography
Regional gravity proved to be very useful in understanding the regional setting of the area and in providing
support for aspects of the interpretation The gravity data support the interpretation of the Blake depocentre
suggesting up to 6ndash8 km of low-density sedimentary rocks
The deep structure of the Savory Sub-basin area is obviously complex with different areas underlain by
Archaean and Proterozoic basement and with the Capricorn suture occurring in the centre of the area
60
Recommendations
The quantitative magnetic interpretation needs to be reconciled with geological models available for the area
In particular the zones tentatively identified as areas with thick sedimentary rocks the Wells Foreland Sub-
basin and the Blake depocentre need to be investigated
Cross sections should be prepared across the basin for joint magneticgravity modelling especially for the Blake
depocentre It is important to be able to explain the strong negative gravity anomaly in this area
In view of the effects of basement density contrasts on the gravity field for the northern part of the area we think
that additional gravity interpretation and acquisition of new gravity data may not be justified as they will not
contribute significantly to understanding basin evolution and structure
It is recommended that GSWA try to get access to company confidential high-resolution aeromagnetic data
rather than flying new surveys The GSWA might offer to fund flying of new infill areas as a bargaining point
References
The original text of this report by Cowan (1995) and 1500 000 scale maps are filed in the GSWA Library under
S10331
COWAN D 1995 Savory Basin quantitative magnetic interpretation Western Australia Geological Survey S-series
S10331 (unpublished)
VACQUIER V STEENLAND N C HENDERSON R G and ZIETZ I 1951 Interpretation of aeromagnetic
maps The Geological Society of America Memoir 47 151p
WILLIAMS I R 1992 Geology of the Savory Basin Western Australia Western Australia Geological Survey
Bulletin 141 115p
61
Appendix 5
Geochemistry
MKS38 250398
Saturate FractionC12+ GLC
1217
Pr18
Ph
22
31CSR WELL-13 315m Cuttings
Figure 51 Canning Stock Route Well 13 gas chromatograph of extract of auger drill sample
12
17
18
22
31
Pr Ph
LDDH 1 6623m CoreSaturate FractionC12+ GLC
MKS35 240398
Figure 52 Gas chromatograph of extract from core sample at 6623 m LDDH1
62
Table 51 Canning Stock Route Well 13 auger drill samples
GSWA sample Drill depth (m)(a) Comments
135601 150 At watertable 135602 203 (all samples consist 135603 310 of sand mud and water) 135604 315 At total depth
NOTE (a) Datum for drill depth is the top of sediment fill in the well which is 155 m below ground level (ie the total depth of 315 m is 47 m below ground level)
Table 52 Canning Stock Route Well 13 gas chromatography data for 315 m depth sediment sample
Parameter Value
Weight of rock extracted (grams) 945 Total extract (ppm) 519 n-Alkane distribution n-C12 07 n-C13 23 n-C14 26 n-C15 22 n-C16 19 n-C17 14 i-C19 23 n-C18 14 i-C20 08 n-C19 11 n-C20 16 n-C21 25 n-C22 29 n-C23 70 n-C24 42 n-C25 95 n-C26 43 n-C27 83 n-C28 38 n-C29 87 n-C30 31 n-C31 273 Alkane compositional data Pristane phytane ratio 279 Pristane n-C17 ratio 161 Phytane n-C18 ratio 059 CPI (1)(a) 284 CPI (2) 209 (C21 + C22) (C28 + C29) 043
NOTE (a) CPI= Carbon preference index
63
Table 53 LDDH1 extract liquid chromatography data for 6623 m concentration
Rock extracted Total extract (grams) (ppm)
702 313
NOTE ppm= parts per million
Table 54 LDDH1 saturate gas chromatography data of core for 6623 m alkane composition
Pristane Pristane Phytane (a) CPI (1) CPI (2) (C21+C22) Phytane n-C17 n-C18 (C28+C29)
103 026 024 103 102 325
NOTE (a)CPI = carbon preference index
Table 55 LDDH1 saturate gas chromatography data of core for 6623 m n-alkane distributions
Parameter Value
n-C12 17 n-C13 38 n-C14 55 n-C15 60 n-C16 65 n-C17 74 i-C19 19 n-C18 78 i-C20 19 n-C19 80 n-C20 79 n-C21 71 n-C22 64 n-C23 57 n-C25 43 n-C24 38 n-C27 31 n-C28 23 n-C29 19 n-C30 12 n-C31 10
64
Appendix 6
Table 61 Summary of data from Trainor waterbores (TWB) and Bullen waterbores (BWB)
Well AMG Elevation TD Status(b) Completion details Water Salinity Water level Flow rate Depth to consolidated AGD84 GL (m) (m) struck mgl(c) (m) (LHr) lithology aquifer(e) Z51(a) Interval (m) (100 mm PVC) (m) (mgl)(d)
TWB 1 473660E 453 122 comp 0ndash75 plain 63 7 300 24 2 880 12 m 7287404N 75ndash93 slotted (9 260) McFadden Fm 93ndash99 plain TWB 2 472 977E 475 23 abd nil 15 m 7285877N Skates Hills Fm dry TWB 3 473259E 475 50 abd nil 7 m 7285849N Skates Hills Fm dry TWB 4 463225 E 445 50 comp 0ndash22 plain 35 7 200 55 3 600 0 m 7286143N 22ndash34 slotted (8 140) Tertiary sand and gravel 23ndash60 plain TWB 5 463095E 445 31 comp 0ndash19 plain 13 26 000 655 3 600 Tertiary sand and gravel 7277721N 19ndash25 slotted (36 700) 25ndash31 plain TWB 6 457013E 455 50 comp 0ndash42 plain 38 920 119 600 0 m 7274352N 42ndash48 slotted (1 030) Cornelia Fm ss TWB 7 453739E 475 26 susp 0ndash2 plain 11 9 300 48 4 500 0 m 7263891N (10 500) Tertiary sand TWB 8 433893E 535 60 susp 0ndash2 plain 47 8 500 gt46 1 200 0 m 7245991N (10 900) Tertiary sand and Brassey Range Fm ss TWB 9 437219E 505 51 comp 0ndash47 plain 45 1 000 58 600 1 m 7235905N 47ndash51 slotted (990) Brassey Range Fm ss TWB 10 434927E 495 32 susp 0ndash2 plain 235 450 120 0 m 7225875N (500) Dolerite
65
BWB 1 287337E 580 122 abd Nil 1 m 7245861N Jilyili Fm dry BWB 2 288346E 545 50 comp 0ndash26 plain 15 630 3 29 000 0 m 7240423N 26ndash38 slotted (730) Tertiary sand and gravel 38ndash50 plain BWB 3 305637E 545 50 abd 19 8 800 43 7 200 0 m 7240423N (10 550) Tertiary ss BWB 4 320167E 515 445 comp 0ndash20 plain 9 980 445 24 000 0 m 7248097N 20ndash32 slotted (1 190) Tertiary ss 32ndash44 plain BWB 5 353393E 545 20 susp 0ndash2 plain 45 (970) 1 m 7238934N Basalt
NOTES (a) GPS accuracy ~ 150 m (b) Comp = completed abd = abandoned susp = suspended (c) Salinity from conductivity (d) Analysis total dissolved solids (e) Fm = Formation ss = sandstone
16
Tarcunyah Group and consists predominantly of mudstone with minor sandstone limestone
dolomite and anhydrite (Fig 6)
The age of the Tarcunyah Group is uncertain although limited palynological and stromatolite
evidence suggests that it is probably coeval with Supersequence 1 of the Centralian Superbasin
Drillhole LDDH1 contains palynomorphs equivalent to assemblages in the Browne and Bitter
Springs Formations of the Officer and Amadeus Basins respectively and from the Cornelia
Formation in TWB 6 (Grey and Stevens 1997) (Figs 4 and 6) Stromatolite specimens tentatively
assigned to Acaciella australica (Howchin 1914) Walter 1972 occur in the lower Tarcunyah
Group (Bagas et al 1995) The stromatolite Baicalia burra Preiss 1972 and a conical
stromatolite were reported from the upper part of the Tarcunyah Group (Stevens and Grey 1997)
The recognition of two stromatolite assemblages interpreted to have age significance in
Supersequence 1 sedimentary rocks of the Centralian Superbasin has permitted biostratigraphic
correlations between outcrop and well data The Acaciella australica assemblage appears to be
slightly older than 800 Ma and is restricted to the middle part of Supersequence 1 The Baicalia
burra assemblage is considered to be slightly younger than 800 Ma and occurs in the upper part
of Supersequence 1 (Grey 1996b Stevens and Grey 1997) The older A australica assemblage
is recognized in the Skates Hills Formation in the Savory Sub-basin and the stromatolite A
australica itself has been tentatively identified in the lower Tarcunyah Group The occurrence of
the A australica assemblage in the Woolnough Madley and Browne Formations of the Officer
Basin and in the Loves Creek Member of the Bitter Springs Formation of the Amadeus Basin
allows correlations throughout the Centralian Superbasin (Fig 4)
The younger B burra assemblage has not been recognized in sedimentary rocks of the
Savory Group as defined by Williams (1992) but it occurs in the upper parts of the Tarcunyah
Group and allows correlation of this group with outcrops of the Neale Formation and with the
Kanpa Formation in petroleum exploration well Hussar 1 both located in the central Officer Basin
of Western Australia (Fig 4) (Grey 1996b Stevens and Grey 1997) The occurrence of the B
burra assemblage in these units permits their correlation with the Burra Group in the Adelaide
Geosyncline of South Australia (K Grey unpublished data)
The Cornelia Formation and Kahrban Subgroup outcrop in the southeast of the sub-basin and
were considered by Williams (1992) to be part of the Mesoproterozoic Bangemall Basin Limited
evidence suggests that all or parts of these two units are of Neoproterozoic age The Ward and
Oldham Inliers consist of outcrops of the Cornelia Formation Waterbore TWB 6 which was
drilled on TRAINOR in the Cornelia Formation contains palynomorphs consistent with a
Supersequence 1 age (Grey and Stevens 1997) (Figs 5 and 6) In outcrop the Cornelia Formation
17
consists predominantly of sandstone and quartzite with lesser siltstone shale mudstone and chert
In Trainor 1 this formation consists predominantly of indurated mudstone with minor sandstone
chert and dolomite A major erosional unconformity separates the Cornelia Formation from
overlying formations and parts of the Cornelia Formation have been folded with dips exceeding
70deg In contrast the majority of the Savory Sub-basin sedimentary rocks have dips of less than 30deg
except where they are adjacent to faults The Cornelia Formation apparently consists of an older
unit of steeply dipping quartzites cherts and well-indurated mudstones and a younger unit of
shallower dipping sandstones which are sub-friable in parts However caution should be used in
interpreting the age of units based on their structural deformation and additional mapping and age
dating of this formation is required
It is proposed here that the Kahrban Subgroup is likely to be of early Neoproterozoic age and
hence should be considered as part of the greater Officer Basin This proposal is based largely on
the relatively low dip of the strata (generally less than 20deg) and their west-northwest strike which
is parallel with strikes in the overlying Brassey Range Formation of the Savory Group The lower
contact of the Kahrban Subgroup is obscured but is thought to be an unconfirmity on the
Earaheedy Basin on the southeast of STANLEY (Muhling and Brakel 1985)
Structural setting
The Savory Sub-basin forms the most northwesterly sub-basin of the Neoproterozoic to
Phanerozoic Officer Basin The western boundary of the sub-basin with the Mesoproterozoic
Bangemall Basin consists of steep-reverse and strike-slip faults The northeastern boundary of the
Savory Sub-basin was mapped where Supersequence 4 formations of the Savory Group
unconformably overlie sedimentary rocks of the Karara and Yeneena Basins with the two older
units considered to be part of the Paterson Orogen (Williams 1992) This contact was defined as a
series of steeply dipping reverse faults in the northernmost parts of the sub-basin on BALFOUR
DOWNS and RUDALL and was extrapolated as an inferred reverse fault farther along strike to the
southeast on GUNANYA and MADLEY where the contact is obscured by Cainozoic sediments It is
now recognized that all the sedimentary rocks in the Karara Basin and younger sedimentary rocks
of the Yeneena Basin are from the Supersequence 1 Tarcunyah Group and part of the greater
Officer Basin (Bagas et al 1995) The northern boundary of the Tarcunyah Group and the greater
Officer Basin is in thrust-and reverse-faulted contact with the Rudall Complex and other parts of
the Paterson Orogen (Fig 7)
To the south the sub-basin unconformably overlies the Bangemall Basin The eastern
boundary of the sub-basin used in this study is where Permian and younger strata of the Officer
Basin unconformably overlie Neoproterozoic strata although there are no significant structural or
stratigraphic differences between the Neoproterozoic units
18
The sub-basin is subdivided into three principal structural areas (Fig 1) Trainor Platform
Blake Fault and Fold Belt and Wells Foreland Sub-basin (Williams 1992) A major review of
these boundaries is beyond the scope of this report but the processing of regional aeromagnetic
data (Appendix 4) and acquisition of a semi-detailed gravity survey by the GSWA in the east of
the sub-basin has enabled these tectonic units to be reassessed and some modifications are
proposed
The Wells Foreland Sub-basin (originally termed the Wells Foreland Basin in Williams 1992)
and sedimentary rocks of the Tarcunyah Group are both considered to be the northwest
continuation of the Gibson Sub-basin of the Officer Basin Aeromagnetic gravity and outcrop
data suggest that the Blake Fault and Fold Belt is significantly faulted and folded in the west but
is less deformed in the east where the thickest sedimentary section in is located on BULLEN
(Appendix 4) The Trainor Platform is reinterpreted to represent an area of the sub-basin that has
undergone major compression during the Petermann Ranges Orogeny resulting in folding and
faulting with a northwest strike This interpretation contrasts with that proposed by Williams
(1992) who envisaged that only a thin section of the Savory Group was present on the platform
Perincek (1998) has recognized nine periods of tectonic activity in the Officer Basin from the
beginning of the Neoproterozoic to the end of the Cretaceous Three major tectonic episodes are
recognized in the Centralian Superbasin The oldest event is the Areyonga Movement which is
pre-Sturtian and forms the boundary between Supersequences 1 and 2 (Fig 4) The Souths Range
Movement occurred at the end of the Sturtian at the boundary between Supersequences 2 and 3
The youngest major event is the Petermann Ranges Orogeny which occured at the end of the
Marinoan and forms the boundary between Supersequences 3 and 4
One minor and two major tectonic episodes are recognized in the Savory Sub-basin the
LP1ALP1B structural event and the Areyonga Movement and the Petermann Ranges Orogeny
respectively The LP1ALP1B structural event is revealed where the Spearhole Formations rests
disconformably and locally unconformably on the Brassey Range Jilyili and Glass Spring
Formations The Neoproterozoic Areyonga Movement (equivalent to the Blake Movement of
Williams 1992) produced folds and faults with a general northeast strike in the western and
southern parts of the region The Souths Range Movement has not been recognized in the sub-
basin This may be due to the fact that no Sturtian glacial rocks have been identified and hence it
is possible that structures attributed to the Areyonga Movement could be the result of the Souths
Range Movement or a combination of the two movements
The major tectonic event recorded in the sub-basin is the latest Neoproterozoic to Cambrian
Petermann Ranges Orogeny (equivalent to the Paterson Orogeny) which produced large reverse
19
faults thrusts strike-slip faults and folds with a general northwest strike The McFadden
Formation and other Supersequence 4 strata are considered to be at least partially coeval with this
orogeny (Williams 1992) We also interpret the Durba Sandstone as having been deposited during
the later stages of the Petermann Ranges Orogeny as this unit mildly deformed with fold axes
parallel to the strike of other structures attributed to the Petermann Ranges Orogeny
Quantitative aeromagnetic interpretation of the Savory Sub-basin utilizing the 3D Euler
deconvolution method supported by wave-number filtering and image processing has provided
structural trends and depth to magnetic source within the sub-basin (Cowan 1995) Gravity data
are interpreted by Cowan (1995) as changes in both the density of the basement rocks andor
basement topography depending on local conditions Part of Cowanrsquos report is reproduced in
Appendix 4
Exploration history
The only petroleum exploration conducted in the sub-basin has been the recent drilling in the
western part of three diamond drillholes of which two have minor oil shows (Table 2) There has
been some mineral exploration the results of which are stored in the GSWA Western Australian
Mineral Exploration (WAMEX) database system Much of the mineral exploration was in the
southwest and west where the sub-basin is in contact with the Bangemall Basin and along the
northern margin of the sub-basin Many of these mineral exploration programs included
aeromagnetic surveys and surface geochemical sampling (Fig 8)
Hydrocarbon potential
The sub-basin contains a sedimentary succession up to 8 km thick which is generally gently
folded and faulted and apparently unmetamorphosed Limited drilling has shown that thick
mudstones are present in the sub-basin with some mudstones in Trainor 1 having high Total
Organic Carbon (TOC) values Outcrops of sub-friable sandstones in many of the formations
within the sub-basin suggests widespread reservoir potential Mudstone and inferred thick
evaporite sequences are likely to form seals Maturity data suggest that near-surface samples are
approximately at the base of the oil window and top of the gas window in parts of the north and
southeast of the sub-basin However parts of the southwest of the sub-basin and the mudstones in
Trainor 1 have very high levels of maturity Numerous faults and folds have been identified from
surface mapping suggesting good potential for large structural traps Minor oil shows in
20
Table 2 Neoproterozoic formations and hydrocarbon shows in diamond drillholes in the Savory Sub-basin
Drillhole AMG Core TD (m) Approx Formation Depth Formation Depth Formation Depth Shows (AGD84) start (m) GL (m) (m) (m) (m)
LDDH 1 431148E 112 701 350 Tarcunyah 68ndash701 ndash ndash bitumen at 6623 m 7443826N Group Trainor 1 473640E 6 709 455 McFadden 9ndash83 Cornelia Fm 83ndash709 possible bitumen at 4537 m 7287400N Fm Mundadjini 1 319056E 170 600 500 Mundadjini 16ndash361 Spearhole Fm 361ndash600 10 fluorescence at 36102 m 7404844N Fm Boondawari 1 348959E 299 1 367 490 Mundadjini Fm 15ndash312 Spearhole Fm 312ndash1 283 Intrusive 1 283ndash1 367 40 fluorescence at 35364 m 5 7398174N fluorescence at 4963 m Akubra 1 334249E 15 181 530 Mundadjini 15ndash42 Intrusive 42ndash181 None 7401252N Fm
21
50 km
120deg 121deg30 123deg
25deg
24deg
23deg
22deg
Greater Officer Basin
Savory Sub-basin
1
2
3
4
6
8
3 Seismic line (prefixed N83-00)
Aeromagnetic survey
GS
WA
Sav
ory
1995
gra
vity
sur
vey
Gravity survey
MKS34270398
Figure 8 Locations of aeromagnetic and gravity surveys (other than regional BMRAGSO data)
22
sandstones in two petroleum wells in the northwest of the sub-basin and bitumen and oil shows
elsewhere in the region indicate that oil has been generated and migrated through the sub-basin
Source rocks
Source potential is considered to be the major exploration risk in the Savory Sub-basin although
minor oil shows in Mundadjini 1 and Boondawari 1 indicate that at least some oil has been
generated and migrated into potential reservoirs within the sub-basin Sandstone is the
predominant lithology observed in outcrop Outcrops of fine-grained lithologies in the basin are
rare because of intense surface weathering and erosion Only about 8 of the surface area of the
sub-basin is exposed bedrock and recessive lithologies (such as shale evaporite and friable
sandstone) may be present although they rarely outcrop
Outcrops of stromatolitic dolomite with associated cauliflower chert and cubic pseudomorphs
interpreted as being after halite indicate that evaporitic environments are present within the
Mundadjini Skates Hills and Boondawari Formations Evaporitic minerals are also present in
drillhole LDDH1 in the Tarcunyah Group
In 1995 GSWA drilled a continuous-core diamond drillhole (Trainor 1) in the sub-basin on
TRAINOR to a depth of 709 m to test for source rocks thus providing the first such data for the sub-
basin The drillhole intersected flat-lying clastics and carbonates of the McFadden Formation (9ndash
83 m) overlying indurated mudstones of the Cornelia Formation (83ndash709 m total depth) dipping at
about 40deg Of the six samples analysed from the Cornelia Formation in this drillhole the five
located between 375 and 6032 m depth have TOC values exceeding 05 (range 066ndash365)
Rock-Eval pyrolysis of these five samples indicates that they are at best in the dry-gas thermal
stage and as a result of their high level of maturation (Stevens and Adamides in prep) have poor
remaining hydrocarbon-generating potential Although the Cornelia Formation is overmature at
Trainor 1 the high TOC values are encouraging as it is likely that this sequence is less mature
elsewhere in the sub-basin
The Mundadjini Formation contains potential source rocks that comprise marine mudstones
with evaporitic minerals present in parts Thin dark mudstones were intersected in the Mundadjini
Formation in Akubra 1 In Mundadjini 1 and Boondawari 1 however the mudstones appear to be
too oxidized to have source potential
The Boondawari Formation also may be a source rock as it contains black mudstones The
unit is laterally equivalent to the Pertatataka Formation of the Amadeus Basin and the Ungoolya
23
Group of the Officer Basin in South Australia both of which have some source potential
(Summons and Powell 1991 Morton and Drexel 1997) Samples from the Dey Dey Mudstone of
the Ungoolya Group generally have poor TOC values (average 011 range 003ndash081)
moderate hydrogen index (HI) values (100ndash382) and poor to fair genetic potential with a
maximum of 292 kg hydrocarbon per tonne of source rock (Morton and Drexel 1997)
Stromatolitic dolomites and mudstones at the top of the Boondawari Formation and within the
Skates Hills Formation are potential source rocks Stromatolitic dolomite and evaporitic rocks
deposited in a marginal marine to sabkha environment are considered to have good potential to
generate and preserve organic carbon without requiring a deep-water setting (Stevens and Grey
1997) Such conditions are recognized in the Skates Hills Formation and in the upper parts of the
Tarcunyah Group
Maturity
Knowledge of the maturity of sedimentary rocks within the Savory Sub-basin is still limited From
a review of palynological studies Grey and Stevens (1997) report that the thermal maturity
inferred from the Thermal Alteration Index (TAI) of 3+ from Supersequence 1 age palynomorphs
in TWB 6 TWB 9 and LDDH1 is within the hydrocarbon window (Appendix 3) In Phanerozoic
spores and pollen a TAI of 3+ approximately equates to the end of liquid petroleum generation
and the start of dry gas generation and to a vitrinite reflectance of about 13 (Traverse 1988)
However the use of TAI for estimating thermal maturity from Neoproterozoic palynomorphs
requires calibration
In Trainor 1 the Cornelia Formation contains organically rich claystones between 375 and
6032 m depth Based on Rock-Eval maturity data (Stevens and Adamides in prep) and the dark
colour of poorly preserved organic material (Grey 1995de 1996) with TAI 4- to 5 all samples
had a high level of maturation with at best dry-gas generating potential remaining In contrast
drillhole LDDH1 on GUNANYA recorded lower levels of maturity (TAI values of 3+) with two of
sixteen samples from the Tarcunyah Group having greater than 1 TOC (Grey 1995abc Grey
and Cotter 1996) Organic petrology and Rock-Eval maturity data for samples from LDDH1
indicate that the section above 500 m is within the oil-generative window whereas below 500 m
the rocks are within the gas window (Ghori in prep Fig 9 Appendix 5)
Waterbores TWB 1 2 6 and 9 which are located on TRAINOR in the southeast of the sub-
basin all had organic matter with TAI values of 3+ from the McFadden Skates Hills Cornelia
and Brassey Range Formations respectively
24
100
200
300
400
500
600
700
Oil
gene
ratin
g
Gas
gene
ratin
g
Fai
r
Fai
r
Poo
r
Poo
r
Goo
d
Imm
atur
e
Oil
win
dow
Oil
win
dow
Imm
atur
e
01 0110 10 0 150 300 440 480 1
Neo
prot
eroz
oic
TOC S1+S2 mgg Hydrogen Index Tmax degC
Depth(m)
Organicrichness
Generatingpotential
Kerogentype Maturity Maturity
TD=701m
Sandstone
Mudstone
Dolomite
Limestone
Evaporite
Source rock
MKS40 070498
Ro equivalent
Figure 9 Petroleum source potential of rocks in Normandy LDDH1
Small amounts of organic matter associated with basalt and dolerite in cuttings from
waterbore BWB 1 on BULLEN showed high levels of thermal maturity (Grey 1995a Libby 1995)
It is unclear whether all sedimentary rocks on BULLEN are overmature for hydrocarbon generation
or the results from BWB 1 are related to local heating events associated with the volcanic bodies
that are common in the Jilyili Formation
25
Reservoirs
Each of the five depositional sequences of the Savory Group (Table 1) are inferred to contain
significant sandstone reservoirs with the possible exception of depositional sequence C as
discussed above in Stratigraphy The Spearhole Formation was cored in Mundadjini 1 and
Boondawari 1 and visual estimates of porosity vary from generally poor (less than 5) to fair
(approximately 5ndash15) The McFadden Formation in Trainor 1 has porosity values of up to 232
and a maximum permeability of 195 md (Stevens and Adamides in prep) Sandstones from
Neoproterozoic formations form the acquifers in the following waterbores the McFadden
Formation in TWB 1 the Cornelia Formation in TWB 6 and the Brassey Range Formation in
TWB 8 and TWB 9 (Appendix 6 Table 61)
Based on outcrop observations the Durba Sandstone is considered to be the best reservoir of
the Savory Group Similarly some sandstones from the Tarcunyah Group also have good visible
porosity in outcrop
Dolomites occur in several formations in the sub-basin Reservoir potential may exist
particularly where the dolomites are stromatolitic and oolitic However dolomites have not been
drilled in the sub-basin and porosity can only be inferred from the preferential silicification of
some stromatolite bioherms observed in outcrop (Stevens and Grey 1997) Elsewhere in the
Officer Basin porosities of up to10 have been measured in dolomites A limestone breccia
(karst) is described from 663 to 677 m in drillhole LDDH1 (Fig 6 Busbridge 1994)
Seals
Indications of evaporitic environments in the Mundadjini Skates Hills and Boondawari
Formations are described by Williams (1992) In Mundadjini 1 from 287 to 337 m anhydrite and
chert occurs as nodules beds and veins in mudstone of the Mundadjini Formation Evaporitic
minerals (predominantly gypsum) are described in the Tarcunyah Group in LDDH1 The presence
of the Woolnough and Madley salt diapirs in the Officer Basin (approximately 110 km east of the
sub-basin) and halite beds over 25 m thick in the well Hussar 1 (130 km east of the sub-basin)
provide further evidence that evaporite seals may be present in the Savory Sub-basin
Mudstones and shales form only a small proportion of the limited Neoproterozoic outcrop in
the sub-basin but significant thicknesses of mudstone were encountered in the Mundadjini
Formation in Mundadjini 1 and Boondawari 1 the Tarcunyah Group in LDDH1 and in the
26
Cornelia Formation in Trainor 1 These data suggest that mudstones form a significant proportion
of strata in the sub-basin despite their limited outcrop
Traps
Potential structural closures including folds and faults occur at various scales throughout the
Savory Sub-basin However the region has only been mapped at 1250 000 scale and
independently closed structures such as domes have yet to be confirmed The western margin of
the basin contains abundant faults (with a northeast strike) but elsewhere faults are less common
Some anticlines are recognized in outcrop including one with a strike length of up to 45 km
inferred from surface bedding dips in the Mundadjini and Spearhole Formations at approximately
24deg15rsquoS 121deg10rsquoE on BULLEN (Fig 1)
Salt diapirs and other halokinetic structures are recognized in outcrop well and seismic data
in the Officer Basin to the west of the Savory Sub-basin and it is probable that there are
significant thicknesses of evaporitic sedimentary rocks in the sub-basin The gravity field data
suggest there is good potential for salt diapirs and traps related to halokinesis
Although there is potential for stratigraphic traps to be present in the sub-basin insufficient
data are available to assess them
Preservation of hydrocarbons
The range of thermal maturities measured to date and the large periods of time envisaged for
deposition of sediments implies hydrocarbon generation may have occurred a number of times
during the evolution of the Savory Sub-basin Any hydrocarbons that were generated early may
have been trapped in palaeostructures and remigration to younger traps could have taken place
later The Petermann Ranges Orogeny which has been equated with the Paterson Orogeny (Myers
1990) is believed to have occurred in the latest Neoproterozoic to early Cambrian This is the last
major tectonic event recognized in the sub-basin suggesting that it is reasonable to expect that trap
integrity will have been preserved
If the inference of the presence of thick halite beds in the sub-basin is correct the preservation
potential of sub-salt traps should be excellent
27
Reported hydrocarbon shows and oil seep
Amadeus Petroleum recorded minor oil shows in cores from Mundadjini 1 and Boondawari 1 In
Mundadjini 1 at 36102 m (top of the Spearhole Formation) a 3 mm thick zone had 10 moderate
white fluorescence with slow solvent cut This show was in a granular sandstone with visually
estimated porosity of about 10 In Boondawari 1 at 35364 m (within the Spearhole Formation) a
broken surface of sandstone had 40 moderate yellow-white fluorescence with slow solvent cut
Visually estimated porosity is about 5 Because the fluorescing surface was broken during the
drilling process this show could have resulted from contamination A second show occurs in
Boondawari 1 at 4963 m (within the Spearhole Formation) where a 1 cm-thick zone had 5 dull
yellow fluorescence with slow solvent cut in a conglomerate with visually estimated porosity of
about 10 The company intends to further investigate the nature of these occurrences
Minor bitumen is present at 6623 m in drillhole LDDH1 on GUNANYA (Figs 5 and 6) as a
vein in mudstones of the Tarcunyah Group A sample was analysed by gas chromatography
(Ghori in prep) and confirmed that it is natural bitumen (Appendix 5)
Mineral hole OD 23 drilled by Jubilee Gold Mines NL on NABBERU in the Bangemall Basin
immediately to the south of the Savory Sub-basin (Fig 5) encountered bitumen and trace oil in
vugs in dolomite (M Stevens unpublished data) but no further data are available at present
In their popular guide to the Canning Stock Route Gard and Gard (1990 p 218) refer to an
oil seep at Well 13 on TRAINOR (Fig 5) They reported that between 1977 and 1984 lsquonatural oilrsquo
was seen in the well Although the well is now largely filled with sediment four auger drill
samples were collected by the GSWA in 1995 and all four were analysed for oil shows One
sample from 315 m total depth (GSWA sample 135604) yielded just enough extract (519 ppm)
for saturate gas chromatography analysis The gas chromatograph (Appendix 5) shows that the
extract does contain some hydrocarbons probably from recent plant material Because the depth to
the oil was not quoted in Gard and Gard (1990) the hand-augered well may not have been deep
enough to properly test this reported seep
Geological and geophysical databases
Geological and geophysical data available for the Savory Sub-basin are limited The most recently
completed geological maps for the sub-basin were published by the GSWA between 1991 and
1995 (Williams and Tyler 1991 Williams 1992 1995ab)
28
The cores from the five drillholes listed in Table 2 believed to be all of the core available
from the sub-basin are available for inspection at GSWA Mineral exploration reports submitted
to GSWA may be searched using the WAMEX database and open-file reports are available on
microfiche Geophysical data acquired by the mining industry is not required to be filed with
GSWA if acquired over Vacant Crown Land which is the case for much of the sub-basin
Geophysical survey data submitted in mining tenement reports and which extend into Vacant
Crown Land remain confidential to the companies Original regional aeromagnetic and gravity
datasets are available from the Australian Geological Survey Organisation (AGSO)
Data pertinent to oil exploration in the sub-basin such as structural style and salt diapirism
are presented in a review of the hydrocarbon prospectivity of the Officer Basin (Perincek 1998)
Drilling
Significant drillholes in the sub-basin are summarized in Table 2
Petroleum industry data
Amadeus Petroleum drilled three petroleum exploration wells in the central west of the Savory
Sub-basin in late 1997 These wells Mundadjini 1 Boondawari 1 and Akubra 1 were drilled by
continuous diamond coring (Figs 5 and 6) All targeted potential reservoirs within the Spearhole
Formation with the Mundadjini Formation as the proposed seal The wells were located on
structures interpreted from Landsat images and limited geological investigations Both Mundadjini
1 and Boondawari 1 had minor oil shows as discussed above (Reported hydrocarbon shows)
Government data
Stratigraphic drillhole Trainor 1 was drilled by GSWA in 1995 (Stevens and Adamides in prep)
and the main results are discussed above (Source rocks and Maturity)
Mineral industry data
Normandy Exploration drillhole LDDH1 was cored in the Tarcunyah Group to a total depth of
701 m and provided source-rock and maturity data as discussed above
29
Oilmin NL drilled six percussion drillholes (BD 1 3 4 5 8 and 9) through sandstones and
shales in the northern part of the Savory Sub-basin to a maximum depth of 198 m (Fig 5
WAMEX Microfiche File M 26811 I 2610) but only brief geological descriptions are available
Hydrogeological data
Hydrogeological data within the Savory Sub-basin are limited although a long history of water
exploration extends back to the construction of the Canning Stock Route early this century No
detailed geological or wireline logs are available for the older wells along this route A few station
wells have been drilled by various methods on the south and west margins of the basin but data
are unavailable as reports are not required to be filed with the government Depth to watertable
throughout the basin is largely controlled by porosity of the bedrock
The GSWA drilled fifteen waterbores in the winter of 1995 in the southern part of the sub-
basin in preparation for the drilling of Trainor 1 and the proposed Bullen 1 Twelve bores found
water and six of these bores have salinities of less than 1000 mgL (Fig 5 Appendix 6 Table 61)
One waterbore TWB 6 has gamma ray and neutron logs run through PVC casing and these are
available from the GSWA with the digital log data included herein
Seismic data
No geophysical data have been acquired by the petroleum industry in the Savory Sub-basin
Seismic data acquired in the Officer Basin to the east particularly in the Gibson and Yowalga
Sub-basins is pertinent to structural interpretation in the Savory Sub-basin (Perincek 1996a
1998)
Aeromagnetic surveys
Government data
There are over 95 277 line kilometres of aeromagnetic data included in the AGSO dataset There
are three regional aeromagnetic surveys covering the Savory Sub-basin These were flown by the
Bureau of Mineral Resources (BMR now AGSO) in 1984 at a line spacing of 1500 m with 36 740
and 52 587 line kilometres flown and by Aerodata in 1984 at a line spacing of 1000m with 5950
line kilometres flown These data were reprocessed and interpreted for GSWA by Cowan (1995)
An edited copy of this report is included as Appendix 4 and the original report is filed in the
GSWA Library under S-series reports item 10331
30
Mineral industry data
The approximate locations of non-AGSO aeromagnetic surveys are shown in Figure 8 More
detailed information regarding the location of these surveys may be obtained using the GSWA
MAGCAT II database Additional information such as contours of aeromagnetic values may be
obtained by inspecting items on file with the GSWA
Gravity surveys
Government data
The average spacing for gravity data in the Savory Sub-basin is one station per 121 km2 (11 times 11
km grid) These data were principally collected by BMR in the early 1960s There are a few
additional regional gravity traverses across the sub-basin which are also included in the
BMRAGSO dataset These data were reprocessed and interpreted for GSWA (Fig 10) and a
report on this work is also included in Appendix 4
The GSWA completed a large semi-detailed gravity survey in the eastern Savory Sub-basin
utilizing helicopter support and Differential Global Positioning Survey (DGPS) techniques (Fig
8) This gravity survey completed in August 1995 consists of 2300 gravity stations on a 2 times 3 km
grid All stations were acquired by helicopter using Scintrex gravimeters and Ashtek dual
frequency DGPS equipment for determining location This highly efficient system allowed the
acquisition of more than 100 gravity stations per day in remote areas The resolution of this survey
is +30 cm and +05 microms-2 (Daishsat 1995) These data (Fig 11) represent a significant
improvement on the previous regional survey data and are available from GSWA (GSWA
1996ab) The results of the interpretation of these data were presented at the 1997 ASEG
Convention (Carlsen and Shevchenko 1997)
Mineral industry data
Three small gravity surveys were conducted by Oilmin NL (Fig 8) and the relevant WAMEX
reports are M 2681I 2610 I 2435 I 2567 These three surveys are of limited value because height
control was provided by barometers only and the surveys were not tied to the national gravity grid
31
23deg
25deg
120deg 122deg
Trainor 1
SAVORY
SUB-BASIN
MKS54 160498
100 km
1995 SavoryGravity Survey
254
-1056
micromsec2
Figure 10 Regional Bouguer gravity map of the Savory Sub-basin
23deg
24deg
25deg
122deg30 123deg
TRAINOR 1
123deg30
50 km
MKS53 160498
-116
-626
micro msec2
Figure11 Detailed Bouguer gravity map of the
Savory 1995 Gravity Survey from the eastern Savory Sub-basin
32
Government and academic reports
Chronostratigraphy and geochemistry
The understanding of Neoproterozoic organic chemistry palynology and structural evolution is
essential to the interpretation of hydrocarbon prospectivity Pertinent reports are included in the
bibliography (Appendix 1) Unpublished palaeontology reports describe the palynology of wells in
the Savory Sub-basin (Grey 1995andashe 1996a) Grey and Cotter (1996) discussed the potential for
Neoproterozoic palynomorphs to provide a biostratigraphic framework and palaeoenvironmental
interpretation Grey and Stevens (1997) reviewed the results of palynological studies of wells
drilled in the sub-basin and reported that Supersequence 1 palynomorphs are present in TWB 6
TWB 9 and LDDH1 (Appendix 3) Grey (1996b) reported on the use of stromatolites for
correlation in the Neoproterozoic and Stevens and Grey (1997) discussed the application of
stromatolite biostratigraphy in correlating isolated dolomite outcrops in the sub-basin with well
and seismic data in the Officer Basin and Centralian Superbasin
Although geochemical data from the Savory Sub-basin are very limited results mostly
confirm thermal maturities inferred from TAI for LDDH1 and Trainor 1 (Ghori in prep Stevens
and Adamides in prep) Those parts of the Officer Basin in Western Australia which lie to the
east of the Savory Sub-basin are sparsely drilled but Ghori (in prep) reports that most of the
Neoproterozoic succession presently lies within the oil-generative window However his study
has been unable to identify effective source-rock units and the source for oil shows Thin source
rocks are present in the Neoproterozoic in LDDH1 (Fig 9) and in three wells which lie to the east
and southeast of the Savory Sub-basin namely NJD 1 Kanpa 1A and Yowalga 3
Proposed work program
From the above limited information it is concluded that additional research on the hydrocarbon
potential of the sub-basin is justified and proposals are outlined below
bull Additional modelling of gravity and aeromagnetic data from the Savory Sub-basin is required
in light of the results from Trainor 1 and Boondawari 1 Trainor 1 showed that what appeared
to be a structurally simple area based on outcrop aeromagnetic and gravity data was in fact an
area of major structuring Boondawari 1 intersected a dolerite which is in good depth
agreement with aeromagnetic depth to source results showing this technique is useful in
detecting the depth to intrusive bodies
33
bull Additional data from mineral and petroleum exploration bores may become available and
analysis of samples from these wells should be undertaken and interpreted in the context of
their relevance to the Officer Basin
bull Stratigraphic coring in the Blake Fault and Fold Belt and in the Wells Foreland Sub-basin (Fig
1) targeting source rocks is considered essential to the continuing evaluation of the
hydrocarbon prospectivity of the Savory Sub-basin
bull Correlations using at least outcrop well and potential-field data should be prepared to link the
sub-basin with the better known parts of the Officer Basin to the east
bull Remapping is required to clarify boundary positions within the Cornelia Formation this may
resolve some of the current problems of the relationship between this unit and the rest of the
Savory Sub-basin
bull Further work is required to explain the Early Cambrian or Sturtian ages interpreted for the
Cornelia Formation from sedimentary zircon UndashPb dating in drillhole Trainor 1 The
determination of the age of the organically rich but overmature claystones in this well is
critical to assessing the hydrocarbon potential of the region
bull The thin dark mudstones intersected by Akubra 1 in the Mundadjini Formation warrant
geochemical analysis Analyses of the oil shows in Mundadjini 1 and Boondawari 1 are
currently being undertaken by Amadeus Petroleum
bull Geochemical analysis of hydrocarbons in the Bangemall Basin drillhole OD23 has been
performed by Jubilee Gold and the results will be reviewed when they are submitted to
GSWA The possibility of source rocks within the Bangemall Basin charging traps within the
Bangemall Basin and the overlying Savory Sub-basin requires further investigation
Conclusions
The Savory Sub-basin is a frontier region with only three recently drilled petroleum exploration
wells and no seismic data Based on existing geological and geophysical data it is considered too
early to draw conclusions about the hydrocarbon prospectivity of the sub-basin at this stage and
there are several reasons why the area warrants further investigation
34
1 Thick accumulations of sedimentary rocks are present (up to 8 km thickness inferred) which
may contain source reservoir and sealing strata
2 Minor oil shows occur in Mundadjini 1 and Boondawari 1 and bitumen is present in mineral
exploration drillhole LDDH1 suggesting that hydrocarbons have migrated within the
Neoproterozoic sequence of the Savory Sub-basin Oil and bitumen are present in mineral
exploration drillhole OD23 in the Bangemall Basin immediately to the south of the Savory
Sub-basin and it is possible that source rocks from the Bangemall Basin could charge traps in
the overlying Savory Sub-basin
3 The age of sedimentary rocks in the sub-basin is still poorly constrained but some of the
Neoproterozoic sedimentary rocks located on GUNANYA and TRAINOR are within the
hydrocarbon-generation window It is possible that a significant thickness of Phanerozoic
sedimentary rocks may also be present
4 Friable sandstones with visible porosity outcrop extensively suggesting numerous potential
reservoirs
5 Significant but not intense faulting and folding has been mapped implying large structural
traps may be present
6 Evaporitic sedimentary rocks occur in several formations and may provide good source rocks
and excellent seals
35
References
APAK S N and CARLSEN G M 1997 A compilation and review of data pertaining to the
hydrocarbon prospectivity of the Canning Basin Western Australia Geological Survey
Record 199610 103p
BAGAS L GREY K and WILLIAMS I R 1995 Reappraisal of the Paterson Orogen and
Savory Basin Western Australia Geological Survey Annual Review 1994ndash95 p 55ndash63
BUSBRIDGE M 1994 Lake Disappointment Exploration Licence 451064 Third Annual
Report Lake Disappointment Diamond Drill Hole LDDH1 Normandy Exploration Limited
Western Australia Geological Survey M-series Item 7567 A41358 (unpublished)
CARLSEN G M and SHEVCHENKO S I 1997 Petroleum exploration in Proterozoic basins
using potential fields data and stratigraphic coring Australian Society of Exploration
Geophysicists 12th Geophysical Conference Handbook Sydney 1997 Preview no 66 p 83
(abstract only)
COWAN D 1995 Savory Basin quantitative magnetic interpretation Western Australia
Geological Survey S-series S10331 (unpublished)
DAISHSAT PTY LTD 1995 Operational and processing report Savory Basin gravity survey
Western Australia Geological Survey S-series S10332 (unpublished)
GARD E and GARD R 1990 Canning Stock Route a travellerrsquos guide for a journey through
history Perth Western Australia Western Desert Guides 448p
GEOLOGICAL SURVEY OF WESTERN AUSTRALIA 1996a Savory Basin first vertical
derivative of Bouguer gravity image 1250 000 Western Australia Geological Survey
GEOLOGICAL SURVEY OF WESTERN AUSTRALIA 1996b Savory Basin Bouguer gravity
image 1250 000 Western Australia Geological Survey
GHORI K A R in prep Petroleum source rock potential and thermal history Officer Basin
Western Australia Western Australia Geological Survey Record
36
GREY K 1995a Savory Basin drillhole BWB 1 (Bullen waterbore) palynology and thermal
maturation GSWA Palaeontology Report no 199512 (unpublished)
GREY K 1995b Savory Basin drillholes TWB 1 2 6 9 (Trainor waterbores) palynology and
thermal maturation GSWA Palaeontology Report no 199520 (unpublished)
GREY K 1995c Palynology of Normandy-Poseidon Lake Disappointment-1 corehole
Tarcunyah Group Paterson Orogen GSWA Palaeontology Report no 199521 (unpublished)
GREY K 1995d Savory Basin drillhole Trainor 1 (Trainor diamond drilling) palynology and
thermal maturity GSWA Palaeontology Report no 199524 (unpublished)
GREY K 1995e Savory Basin drillhole Trainor 1 (Trainor diamond drilling) Additional
Preparation of two samples GSWA Palaeontology Report no 199528 (unpublished)
GREY K 1995f Neoproterozoic stromatolites from the Skates Hills Formation Savory Basin
Western Australia and a review of the distribution of Acaciella australica Australian Journal
of Earth Sciences v 42 p 123ndash132
GREY K 1996a Savory Basin drillhole Trainor 1 (Trainor diamond drilling) Additional
samples palynology and thermal maturation GSWA Palaeontology Report no 199615
(unpublished)
GREY K 1996b Preliminary stromatolite correlations for the Neoproterozoic of the Officer
Basin and a review of Australia-wide correlations GSWA Palaeontology Report no 199615
(unpublished)
GREY K and COTTER K L 1996 Palynology in the search for Proterozoic hydrocarbons
Western Australia Geological Survey Annual Review for 1995ndash96 p 70ndash80
GREY K and STEVENS M K 1997 Neoproterozoic palynomorphs of the Savory Sub-basin
Western Australia and their relevance to petroleum exploration Western Australia
Geological Survey Annual Review for 1996ndash97 p 49ndash54
HUBBARD R J PAPE J and ROBERTS D G 1985 Depositional sequence mapping as a
technique to establish tectonic and stratigraphic framework and evaluate hydrocarbon
potential on a passive continental margin in Seismic stratigraphy II an integrated approach
37
edited by O R BERG and D G WOOLVERTON American Association of Petroleum
Geologists Memoir 39 p 79ndash91
LIBBY WG 1995 A petrological report on six samples of bore cuttings from the Savory Basin
Western Australia Western Australia Geological Survey S-series S31307 (unpublished)
MORTON JGG and DREXEL JF 1997 The petroleum geology of South Australia Vol 3
Officer Basin South Australia Department of Mines and Energy Resources Report Book
9719
MUHLING P C and BRAKEL A T 1985 Geology of the Bangemall Group mdash the evolution
of an intracratonic Proterozoic basin Western Australia Geological Survey Bulletin 128
219p
MYERS J S 1990 Precambrian tectonic evolution of part of Gondwana southwestern Australia
Geology v18 p 537ndash540
NELSON D R 1997 Compilation of SHRIMP UndashPb zircon data Western Australia Geological
Survey Record 19972 196p
PAYTON C E 1977 Seismic stratigraphy mdash applications to hydrocarbon exploration
American Association of Petroleum Geologists Memoir 26 516p
PERINCEK D 1996a The age of NeoproterozoicndashPalaeozoic sediments within the Officer Basin
of the Centralian Super-basin can be constrained by major sequence-bounding unconformities
APPEA Journal v 36 pt 1 p 350ndash368
PERINCEK D 1996b The stratigraphic and structural development of the Officer Basin
Western Australia a review Western Australia Geological Survey Annual Review 1995ndash
1996 p 135ndash148
PERINCEK D 1998 A compilation and review of data pertaining to the hydrocarbon
prospectivity of the Officer Basin Western Australia Geological Survey Record 19976
POSAMENTIER H W JERSEY M T and VAIL P R 1988 Eustatic controls on clastic
deposition 1 mdash Conceptual framework in Sea-level changes an integrated approach edited by
C K WILGUS B S HASTINGS C G St C KENDALL H W POSAMENTIER
38
C A ROSS and J C VAN WAGONER Society of Economic Paleontologists and
Mineralogists Special Publication no 42
STEVENS M K and ADAMIDES N G in prep GSWA Trainor 1 well completion report
Savory Sub-basin Officer Basin Western Australia with notes on petroleum and mineral
potential Western Australia Geological Survey Record 199612
STEVENS M K and GREY K 1997 Skates Hills Formation and Tarcunyah Group Officer
Basin mdash carbonate cycles stratigraphic position and hydrocarbon prospectivity Western
Australia Geological Survey Annual Review for 1996ndash97 p 55ndash60
SUMMONS RE and POWELL C McA 1991 Petroleum source rocks of the Amadeus Basin
in Geological and geophysical studies in the Amadeus Basin central Australia edited by R J
KORSCH and JM KENNARD Australia BMR Geology and Geophysics Bulletin 236
TRAVERSE A 1988 Palaeopalynology Boston Unwin Hyman 600p
VAIL P R MITCHUM R M Jr TODD R G WIDMIER J M THOMPSON S III
SANGREE J B BUBB J N and HATLELID W G 1977 Seismic stratigraphy and
global changes of sea level in Seismic stratigraphy mdash applications to hydrocarbon
exploration edited by C E PAYTON American Association of Petroleum Geologists
Memoir 26 516p
WALTER M R and GORTER J 1994 The Neoproterozoic Centralian Superbasin in Western
Australia the Savory and Officer Basins in The sedimentary basins of Western Australia
edited by P G PURCELL and R R PURCELL Petroleum Exploration Society of Australia
Symposium Perth WA 1994 Proceedings p851ndash864
WALTER M R GREY K WILLIAMS I R and CALVER C R 1994 Stratigraphy of the
Neoproterozoic to early Palaeozoic Savory Basin and correlation with the Amadeus and
Officer Basins Australian Journal of Earth Sciences v 41 p 533ndash546
WALTER M R VEEVERS J J CALVER C R and GREY K 1995 Neoproterozoic
stratigraphy of the Centralian Superbasin Australia Precambrian Research v 73 p 173ndash195
WILLIAMS I R 1992 Geology of the Savory Basin Western Australia Western Australia
Geological Survey Bulletin 141 115p
39
WILLIAMS I R 1995a Bullen WA (2nd Edition) Western Australia Geological Survey
1250 000 Geological Series Explanatory Notes 23p
WILLIAMS I R 1995b Trainor WA (2nd Edition) Western Australia Geological Survey
1250 000 Geological Series Explanatory Notes 31p
WILLIAMS I R and TYLER I M 1991 Robertson WA (2nd edition) Western Australia
Geological Survey 1250 000 Geological Series Explanatory Notes 36p
40
41
Appendix 1
Bibliography
Reports which are relevant to this investigation but which are not specifically cited are listed
below
BAILLIE P W POWELL C McA LI Z X and RYALL A M 1994 The tectonic
framework of Western Australiarsquos Neoproterozoic to recent sedimentary basins in The
sedimentary basins of Western Australia edited by P G PURCELL and R R PURCELL
Petroleum Exploration Society of Australia Symposium Perth WA 1994 Proceedings p
45ndash62
BRADSHAW M T BRADSHAW J MURRAY A P NEEDHAM D J SPENCER L
SUMMONS R E WILMOT J and WINN S 1994 Petroleum systems in West Australian
basins in The sedimentary basins of Western Australia edited by P G PURCELL and R R
PURCELL Petroleum Exploration Society of Australia Symposium Perth WA 1994
Proceedings p 93ndash118
CLARKE G L 1991 Proterozoic tectonic reworking in the Rudall Complex Western Australia
Australian Journal of Earth Science v38 p 31ndash44
COCKBAIN A E and HOCKING R M 1990 Phanerozoic in Geology and mineral resources
of Western Australia Western Australia Geological Survey Memoir 3 p 750ndash755
ETHERIDGE M and WALL V 1994 Tectonic and structural evolution of the Australian
Proterozoic 12th Australian Geological Convention Geological Society of Australia
Abstracts no 37 p 102ndash103
GOODE A D T 1981 Proterozoic geology of Western Australia in Precambrian of the
Southern Hemisphere Developments in Precambrian geology 2 edited by I R HUNTER
Amsterdam Elsevier p 105ndash203
GREY K and JACKSON M J 1983 A re-assessment of stromatolite evidence for the
correlation of the Late Proterozoic Neale and Ilma Beds Officer Basin Western Australia
Australia BMR Journal of Australian Geology and Geophysics v 8 p 359
42
HICKMAN A H WILLIAMS I R and BAGAS L 1994 Proterozoic geology and
mineralization of the TelferndashRudall region Paterson Orogen Geological Society of Australia
(WA Division) Excursion Guidebook no 5 56p
HOCKING R M MORY A J and WILLIAMS I R 1994 An atlas of Neoproterozoic and
Phanerozoic basins of Western Australia in The sedimentary basins of Western Australia
edited by P G PURCELL and R R PURCELL Petroleum Exploration Society of Australia
Symposium Perth WA 1994 Proceedings p 21ndash 44
JACKSON P R 1966 Geology and review of exploration Officer Basin Western Australia
Hunt Oil Company Western Australia Geological Survey S-series S26 (unpublished)
JACKSON M J 1971 Notes on a geological reconnaissance of the Officer Basin Western
Australia Australia BMR Geology and Geophysics Record 19715 30p
JACKSON M J and van de GRAAFF W J E 1981 Geology of the Officer Basin Western
Australia Australia BMR Geology and Geophysics Bulletin 206 102 p
LOWRY D C JACKSON M J van de GRAAFF W J E and KENNEWELL P J 1971
Preliminary result of geological mapping in the Officer Basin Western Australia Western
Australia Geological Survey Annual Report for 1971 p 50ndash56
MYERS J S 1990 Precambrian in Geology and mineral resources of Western Australia
Western Australia Geological Survey Memoir 3 p 737ndash750
MYERS J S SHAW R D and TYLER I M 1994 Proterozoic tectonic evolution of
Australia 12th Australian Geological Convention Geological Society of Australia Abstracts
no 37 p 312
NEDIN C and JENKINS R J F 1991 Re-evaluation of unconformities separating the
lsquoEdiacaranrsquo and Cambrian systems South Australia Palaios v 6 p 102ndash108
PHILLIPS B J JAMES A W and PHILIP G M 1985 The geology and hydrocarbon
potential of the north-western Officer Basin APEA Journal 25 (1) p 52ndash61
POWELL C McA LI Z X McELHINNY M W MEERT J G and PARK J K 1993
Paleomagnetic constraints on timing of the Neoproterozoic breakup of Rodinia and Cambrian
formation of Gondwana Geology v 21 p 889ndash892
43
POWELL C McA PREISS W V GATEHOUSE C G KRAPEZ B and LI Z X 1994
South Australian record of a Rodinian epicontinental basin and its mid-Neoproterozoic
breakup to form the Palaeo-Pacific Ocean Tectonophysics v 237 no 3ndash4 p 113ndash140
PREISS W V 1976 Proterozoic stromatolites from the Nabberu and Officer Basins Western
Australia and their biostratigraphic significance South Australia Geological Survey Report
of Investigations no 47 p 1ndash51
TOWNSON W G 1985 The subsurface geology of the western Officer Basin mdash results of
Shellrsquos 1980ndash1984 petroleum exploration campaign APEA Journal v 25 (1) p 34ndash51
WATTS K J 1982 The geology of the Townsend Quartzite Upper Proterozoic shallow water
deposit of the Northern Officer Basin Western Australia Perth University of Western
Australia BSc honours thesis (unpublished)
WELLS A T and KENNEWELL P J 1974 Evaporite exploration in the Officer Basin
Western Australia at the Madley Diapirs Australia BMR Record 1974194 (unpublished)
WILLIAMS I R and MYERS J S 1990 Paterson Orogen in Geology and mineral resources
of Western Australia Western Australia Geological Survey Memoir 3 p 274ndash286
WILLIAMS I R 1990 Savory Basin in Geology and mineral resources of Western Australia
Western Australia Geological Survey Memoir 3 p 329ndash334
WILLIAMS I R 1994 The Neoproterozoic Savory Basin Western Australia in The
sedimentary basins of Western Australia edited by P G PURCELL and R R PURCELL
Petroleum Exploration Society of Australia Symposium Perth WA 1994 Proceedings p
841ndash850
WILSON R B 1967 Woolnough Hills and Madley diapiric structures Gibson Desert WA
APEA Journal v 7 p 94ndash102
44
Appendix 2
Meteorological data (from Bureau of Meteorology Perth 1994)
Table 21 Wiluna rainfall (mm)
Year Jan Feb Mar Apr May Jun Jul Aug Sept Oct Nov Dec
1975 0 45 446 309 306 59 276 4 34 886 638 164 1976 16 154 12 138 53 16 34 62 12 238 0 2 1977 44 0 66 74 68 95 24 363 1 58 12 727 1978 234 522 94 16 0 96 367 24 16 353 185 45 1979 19 173 122 88 91 4 0 246 58 0 169 114 1980 148 764 68 1081 259 626 629 06 56 02 174 0 1981 123 476 192 32 196 118 44 74 14 0 28 312 1982 374 705 206 244 1079 92 02 143 368 526 368 118 1983 1 112 928 248 0 212 56 32 5 1 42 496 1984 149 7 342 84 836 0 348 132 224 04 16 172 1985 596 483 0 166 556 0 514 56 0 0 4 0 1986 0 154 35 0 0 1085 23 01 239 137 0 04 1987 1204 119 19 89 17 575 154 126 07 1 0 398 1988 46 202 164 13 388 0 202 104 0 0 224 1309 1989 207 234 26 703 278 536 57 0 01 0 144 02 1990 1035 23 281 46 126 53 94 218 44 9 42 0 1991 48 0 41 45 0 472 297 12 0 1 0 7 1992 112 96 1025 1227 323 65 04 174 0 132 48 4 1993 0 697 0 202 445 0 12 306 18 05 14 33 Mean 25 35 22 27 27 25 18 12 6 13 13 21
JAN FEB MAR APR MAY JUN JUL AUG SEP OCT NOV DEC0
10
20
30
40
Mea
n R
ain
fall
(mm
)
Month
Mean monthly rainfall in Wiluna
MKS41 140498
45
Table 22 Wiluna minimum temperature (degC)
Year Jan Feb Mar Apr May Jun Jul Aug Sept Oct Nov Dec
1975 ndash 23 203 15 94 63 71 62 103 124 169 205 1976 242 229 194 15 10 63 59 73 95 143 16 228 1977 243 25 197 148 96 95 56 86 102 ndash 188 23 1978 241 232 203 18 102 64 76 8 9 152 19 205 1979 255 226 216 167 83 6 59 79 97 145 198 223 1980 255 226 231 155 134 83 68 75 121 108 193 223 1981 245 216 19 182 119 6 54 78 138 159 163 218 1982 232 224 177 16 ndash ndash 37 111 112 164 209 225 1983 235 24 197 147 112 88 39 88 121 162 189 219 1984 241 243 191 156 ndash 72 66 7 95 161 182 211 1985 244 231 ndash 159 98 65 71 73 117 147 205 ndash 1986 ndash 229 226 155 93 96 43 49 10 122 ndash 219 1987 ndash 217 183 175 85 77 68 68 112 ndash ndash 221 1988 238 214 209 178 111 ndash ndash 86 104 157 171 195 1989 ndash 237 199 165 107 67 44 61 107 131 187 ndash 1990 232 ndash 211 155 118 62 57 87 102 149 195 22 1991 26 256 217 168 122 101 78 ndash 113 18 168 219 1992 227 227 214 169 102 98 59 69 ndash 125 159 196 1993 241 218 196 171 103 ndash 49 68 88 128 192 211 Mean 24 23 20 16 10 8 6 8 11 14 18 21
NOTE Dashes indicate data unavailable
JAN FEB MAR APR MAY JUN JUL AUG SEP OCT NOV DEC0
10
20
30
40
Month
MKS43 140498
50
Mean monthly minimum temperatures at Wiluna
Mea
n T
emp
erat
ure
(degC
)
46
Table 23 Wiluna maximum temperature (degC)
Year Jan Feb Mar Apr May Jun Jul Aug Sept Oct Nov Dec
1975 ndash 349 326 281 247 201 197 212 256 248 31 344 1976 374 369 346 297 248 206 208 225 265 287 313 388 1977 397 392 352 296 234 212 222 244 ndash 308 337 383 1978 378 345 346 316 242 195 176 205 231 295 334 356 1979 403 36 364 295 ndash ndash ndash 193 242 318 359 373 1980 392 342 377 275 24 176 179 233 292 288 349 391 1981 385 346 337 342 242 178 201 224 30 326 326 369 1982 372 359 315 307 ndash ndash 196 253 252 305 353 379 1983 381 389 327 272 263 222 187 248 287 321 336 366 1984 378 393 322 299 226 215 178 214 234 ndash 336 364 1985 40 366 ndash 294 224 216 205 212 284 307 355 ndash 1986 ndash 383 372 307 ndash 193 166 196 261 277 ndash 382 1987 ndash 339 328 305 21 202 214 218 275 ndash ndash 374 1988 388 365 353 301 23 ndash ndash 228 283 334 31 33 1989 ndash 375 339 285 238 179 181 219 275 298 336 ndash 1990 368 ndash 36 309 268 19 188 205 274 309 373 393 1991 414 416 363 315 268 206 21 ndash 279 338 332 368 1992 363 383 336 263 213 178 213 197 ndash 285 313 359 1993 396 357 344 301 221 ndash 197 215 253 294 347 362 Mean 39 37 34 30 24 20 20 22 27 30 34 37 NOTE Dashes indicate data unavailable
JAN FEB MAR APR MAY JUN JUL AUG SEP OCT NOV DEC0
10
20
30
40
Month
MKS42 140498
50
Mean monthly maximum temperatures at Wiluna
Mea
n T
emp
erat
ure
(degC
)
47
Appendix 3
Table 31 Summary of palynological results
Drillhole Depth (m) F no(a) GSWA no Lithology Formation Assemblage TAI(b)
BWB 1 74ndash75 F49668 135741 dark-grey siltstone basalt Jilyilli gt5 BWB 1 98ndash100 F49669 135742 dark-grey siltstone basalt Jilyilli gt5 BWB 1 121ndash122 F49670 135743 dark-grey siltstone basalt Jilyilli gt5 TWB 1 86ndash87 F49671 135631 dark-grey siltstone McFadden 3+ TWB 1 104ndash105 F49672 135632 dark-grey siltstone Cornelia 3+ TWB 1 121ndash122 F49673 135633 dark-grey siltstone Cornelia 4 TWB 2 14ndash15 F49674 135634 dark-grey siltstone Skates Hills 3+ TWB 6 49ndash50 F49675 135675 dark-grey siltstone Cornelia 1 3+ TWB 9 49ndash51 F49676 135704 dark-grey siltstone Brassey Range 1 3+ Trainor 1 37497- F49733 138939 black mudstone with Cornelia 5 37509 light-grey siltstone Trainor 1 3809 F49734 138940 dark-grey and black Cornelia 4- laminated mudstone Trainor 1 4170 F49735 138941 black unlaminated mudstone Cornelia 4- Trainor 1 4950 F49851 139501 dark-grey indurated siltstone Cornelia 5 Trainor 1 6032 F49852 139502 dark- and light-grey Cornelia 5 indurated siltstone Trainor 1 6434 F49853 139503 greenish indurated finely Cornelia 5 laminated siltstone LDDH 1 270 F49678 138934 dark-grey siltstone interbeds Waters 1 3+ in enterolithic evaporite Tarcunyah Gp LDDH 1 277 F49679 138935 dark-grey siltstone in cavity Waters 1 3+ in enterolithic evaporite Tarcunyah Gp
NOTES (a) GSWA Fossil Catalogue number (b) TAI = Thermal Alteration Index of Traverse (1988 plate 1)
48
Appendix 4
Savory Sub-basin quantitative magnetic and gravity interpretation (extracted from Cowan 1995)
Summary
A program of quantitative aeromagnetic interpretation has been completed on BMRAGSO data from the Savory Sub-
basin Western Australia Quantitative aeromagnetic interpretation utilized the 3D Euler deconvolution method
supported by wavenumber filtering and image processing The results have provided useful information on structural
trends and depth to magnetic sources in a structurally complex area Depth to magnetic source analysis has provided
information on intra-sedimentary magnetic sources as well as basement rocks
The results of the interpretation support previously identified depocentres However the presence of magnetic
sources at several levels makes it very difficult to produce a reliable magnetic basement depth contour map It is
considered more productive to work with the 3D Euler colour circle plots and images rather than trying to contour the
results It would be necessary to carry out a full-scale interpretation of the BMRAGSO profile data to improve on the
3D Euler results The regional gravity was found to be useful in interpreting the regional setting of the area although
the very wide data spacing limits quantitative use of the data The gravity data show quite a complex picture with
limited consistent correlation between gravity features and basin structures This suggests that gravity anomalies
reflect changes in density of the basement rocks rather than basement topography especially in the northern part of the
basin
It is recommended that the GSWA investigate access to company confidential high-resolution aeromagnetic data
prior to planning further aeromagnetic surveys Private companies have flown large parts of the northern half of the
area as part of their diamond exploration program Additional gravity coverage of the area may be more cost effective
than magnetic surveys as the gravity data provides more information on changes within the sedimentary section
Introduction
The main use of aeromagnetic data in petroleum exploration has been the determination of magnetic basement
topography although there has been increasing interest in analysis of intra-sedimentary magnetic anomalies
intrabasement and suprabasement magnetic anomalies These anomalies are used to determine depth to magnetic
basement rocks and hence determine the thickness of the sedimentary sequence Unfortunately interpretation of the
intrabasement and suprabasement magnetic anomalies is non-unique in terms of position and size of causative sources
because of the inherent ambiguity of potential-field methods However this ambiguity can be reduced by placing
49
constraints on source geometry and magnetization and by using geological and other geophysical data to constrain
the solution
Before 1970 most depth-determination techniques involved graphical determination of slopes of selected
magnetic anomalies and application of various empirical factors to convert the slopes into depth estimates Geological
Society of America Memoir 47 Interpretation of Aeromagnetic Maps by Vacquier et al (1951) was a landmark for
this type of interpretation
Automated interpretation procedures have played an increasingly important role in depth interpretation and a
wide range of techniques have been developed Many of these techniques are designed for application to located data
profiles and assume a two-dimensional geometry However there has been renewed interest in techniques applicable
to gridded data
Two distinct types of method can be recognized In the first case often described as discrete methods individual
isolated magnetic anomalies are interpreted and the results used to produce a map of basement relief In the second
case often described as continuous methods areas of data containing a number of anomalies are interpreted
statistically to produce direct output of basement depths
The discrete methods usually involve a semiautomatic initial phase which generates a large number of possible
depth solutions and an interactive second phase to screen and select acceptable solutions The advantage of this
approach is that the interpreter can select features that are relatively free from interference from adjacent anomalies
and consider all aspects of a particular magnetic anomaly The disadvantage is that interpretation can be very time
consuming as a wide range of depths are usually possible depending on the initial model chosen and a significant
amount of effort is needed to select the correct model In the case of the Savory Sub-basin dataset we encountered
problems in separating basement related effects from the effects of shallower intrasedimentary magnetic sources
Because of these problems we have concentrated on displaying the Euler results accompanied by separation filter
images of the data to show the shallower effects and deeper effects rather than trying to refine a 3D Euler
deconvolution depth-to-crystalline-basement contour
The continuous methods are very direct provided that the rather restrictive assumption can be made that all
anomalies are due to lateral magnetization changes due to basement topography This means that shallow effects and
large intrabasement anomalies must be removed from the data This involves judgement and skill as it is necessary to
distinguish between the lower amplitude suprabasement anomalies due to basement topography and the larger
intrabasement anomalies reflecting magnetization changes within the basement These methods were not considered
suitable for the Savory Sub-basin magnetic dataset but were used to invert the gravity data
50
Limitations of magnetic and gravity interpretation
Interpretation of the area is limited by a shortage of information on the nature and physical properties of the deeper
sedimentary sequence and the underlying basement rocks However using techniques such as cross-correlation of
gravity and pseudo-gravity data it is possible to try to differentiate between anomalies relating to basement and those
related to the sedimentary sequence
Gravity anomalies reflect changes within the sedimentary sequence as well as basement condition These
changes in density of sedimentary rocks produce gravity anomalies without a corresponding magnetic anomaly hence
the complementary nature of gravity and magnetic surveys The main use of magnetics is to determine depth to
magnetic basement and any intra-sedimentary volcanic rocks or intrusives whereas gravity provides much more
general information on the sedimentary sequence
Unfortunately interpretation of gravity anomalies is complicated since they can be due to a number of geological
features including
bull major basement faults
bull basement highs
bull igneous intrusions within the basement
bull sedimentary basins which may or may not be isostatically compensated
bull intra-sedimentary volcanics and associated plutonic centres
Two major problems affect the interpretation of both magnetic and gravity data
1 The inherent ambiguity of potential-field data There is no unique solution to any measured gravity or magnetic
anomaly and theoretically there will be an infinite number of source geometry and magnetizationdensity
combinations which will fit the observed data This means that any a priori information which helps to select a
suitable model is very useful
2 Measured anomalies are the summation of effects from different depths For example an observed gravity profile
may contain contributions from shallow sources (density variations within the sedimentary basin) intermediate
depth sources (density variations due to large igneous intrusions within the basement) and deep sources (crustal
thinning producing a mantle anomaly) Separation of these component responses is the regionalresidual problem
which we solve using spectral analysis and differential upward continuation-based separation filtering
Regional setting and interpretation overview
The area studied includes parts of BALFOUR DOWNS (SF51-9) RUDALL (SF51-10) ROBERTSON (SF51-13) GUNANYA
(SF51-14) COLLIER (SG50-4) BULLEN (SG51-1) TRAINOR (SG51-2) MADLEY (SG51-3) NABBERU (SG50-5)
STANLEY (SG51-6) and HERBERT (SG51-7) 1250 000 sheets Broadly the area lies between latitudes 22deg00rsquondash25deg30rsquoS
and longitudes 119deg30rsquondash123deg30rsquoE
51
Regional gravity
The AGSO regional gravity data (at nominal 11 km spacing) was gridded at a 4 km mesh spacing using a minimum-
curvature algorithm Bouguer gravity values in the area are negative reflecting mass deficiency at depth and range
from -84 mgals to -25 mgals
A Bouguer gravity colour image is shown as Figure 41 A residual grid was produced by removing a fifth-order
orthogonal polynomial from the Bouguer data but did not add to the interpretation
120deg 121deg 122deg 123deg
23deg
24deg
25deg
-25
-84
50 km
MKS46 180598
mgal
Figure 41 Regional Bouguer gravity (BMRAGSO data) gridded at 4 km
52
The data show a complex pattern of positive and negative anomalies with no clearly defined trends Correlations
with aeromagnetic data and known basin structures are poor A vague north-northwest linear trend appears to coincide
with the Marloo Fault (Figure 42) A prominent negative anomaly appears to coincide with the Blake Fold and Fault
Belt depocentre and continues as a narrower negative anomaly to the east until it widens out again near the edge of the
basin Elsewhere the gravity data show little correlation with known basin structures and it is likely that especially in
the north of the area gravity anomalies are due to density changes in the basement rather than changes in basement
topography
Production of wavelength-filtered residual gravity plots and vertical gradient plots showed very patchy aliased
data reflecting poor sampling in much of the area
Regional magnetics
The AGSO regional aeromagnetic data were gridded at a 400 m mesh spacing using a minimum-curvature algorithm
(Figure 43) Most of the data has a line spacing of 1600 m with small areas of 1 km spacing The quality of the data is
acceptable for regional interpretation but is not adequate for detailed analysis The accuracy of the flight path is rather
variable reflecting the vintage of the data and the noise envelope of the data is poor by modern standards Problems
were also encountered in joining different map sheets
The magnetic anomaly pattern over the south and west part of the area shows a strong high frequency signature
reflecting the presence of widespread basic sills and dykes Some of the major north-northeasterly trending dykes can
be traced over considerable distances
Discontinuous high-frequency anomalies extend as a northwest-trending zone through the centre of the area and
this zone includes a conspicuous circular magnetic anomaly which is probably a ring complex
The northern and eastern parts of the area are characterized by long-wavelength deep-seated basement magnetic
anomalies with 120deg and 150deg trends dominant The Marloo and Perentie Faults (Figure 42) appear as distinct linear
zones and offsets A prominent easterly trending negative anomaly in the northwest of the area appears to swing round
to the southeast and may separate different basement blocks One possible interpretation is that this very deep seated
anomaly separates areas of Archaean and Proterozoic basement
Regional geology
The regional geology is described in Williams (1992) The GSWA provided a digitized version of Plate 2 from this
Bulletin the structural interpretation map to use as an overlay (Figure 42)
53
Pp
Pp
PSd
PSd
PSd
PSd
PSd
PSo
PSt
PSt
PSf
PSf
PSf
PSb
PSb
PSb
PSsPSs
PSs
PSb
PSm
PSp
PSc
PSc
PSw
PSw
PSw
PSg
PSr
PSj
PSg
PM
Pk
PY
PY
PSd
L
L
L
L
L
L
L
LL
L
L
L
LL
L
LL
L L
LL
L L
L
L
L
L
L
L
L
LL
L
L
BLAKEDEPOCENTRE
MA
RLO
O
FAU
LT
PERENTIEFAULT
50 km
MKS39120598
120deg 121deg 122deg 123deg
25deg
24deg
23deg
Approximate boundaryof aeromagnetic interpretation
PML
PSgL
PSjL
PML
PSpL
PML
PML
PSfL
PSfL
PSpL
LPc
LPcLPcPSrL
LPA
Durba Sandstone
Woora Woora Formation
McFadden Formation
Tchukardine Formation
Boondawari Formation
Skates Hills Formation
Mundadjini Formation
Coondra Formation
Spearhole Formation
Watch Point Formation
Jilyili Formation
Brassey Range Formation
Glass Spring Formation
Paterson Formation
Yeneena Group
Karara Formation
Cornelia Formation
Kahrban Subgroup
Bangemall Group
Fault
Formation boundary
PSdL
PSoL
PSfL
PStL
PSbL
PSsL
PSmL
PScL
PSpL
PSwL
PSjL
PSrL
PSgL
Pp
PYL
PkL
LPc
LPA
PML
Savory Group Other Units
PYL
Figure 42 Regional geology and structure map (after Williams 1992)
54
120deg 121deg 122deg 123deg
23deg
24deg
25deg
5820
3750
MKS47 180598
nT
50 km
Figure 43 Regional aeromagnetic data total magnetic intensity (BMRAGSO data) gridded at 400 m
Analysis
3D analysis
3D Euler deconvolution was used as the primary depth-determination method The advantage of this approach is that
consistent solutions can be obtained over the entire area with minimal assumptions about source geometries Euler
deconvolution of gridded data is used for positional information and estimation of depth to top of source Euler
55
deconvolution yields a large number of depth solutions which have to be screened to reject spurious solutions Results
are plotted as circles in eight depth ranges with radius proportional to depth and colour coded
The 400 m total magnetic intensity grid was used for the analysis Horizontal gradients in x and y and the vertical
gradient were calculated 3D Euler deconvolution was tested on the 400 m gridded data using windows of 9 times 9 and
11 times 11 and 16 times 16 data points and structural indices 05 (fault) and 10 (sill or dyke) It was concluded that the
16 times 16 window produced the best results overall and final plots were produced for the 16 times 16 window and structural
index 05 (Fig 44) Results were very good over the northern and central parts of the area showing magnetic sources
Figure 44 Depth to magnetic source 3D Euler deconvolution 16 times 16 window of 400 m gridded data structural index 05
56
at several different levels Unfortunately in the extreme south of the area shallow intrasedimentary magnetic sources
(sills and dykes) dominated the inversion and the results contained few basement solutions
In order to reduce these problems the 400 m gridded data were filtered using a separation filter based on
interpretation of the log-energy spectrum The 3D Euler method was run on the filtered data in order to generate more
basement-depth solutions Results for the deep-separation filter data were gridded and presented as a colour image in
Cowan (1995) Attempts to grid the Euler output were unsatisfactory and it is considered safer to interpret the 3D
Euler depth plots The 3D Euler depth results from the separation-filter run should be analysed with care as perfect
separation of the basement can never be achieved and there will always be some contamination from sources at
different levels
The results of original total magnetic intensity 3D Euler depth estimation for structural index 05 using a 16 point
window have been plotted at 1500 000 scale (not included in this publication but available in Cowan (1995) from the
GSWA Library as S10331) and as reduced A4 colour circle plots (Figure 44)
The results of deep-basement 3D Euler depth estimation for structural index 05 using a 16 point window have
been plotted as a colour image at 1500 000 scale and as an A4 image (not included in this publication)
2D analysis
Two equispaced profiles were interpolated with a 50 m station interval from the AGSO-located data profiles for the
BULLEN 1250 000 sheet The interpolated profiles were analysed using 2D Euler deconvolution and Werner
deconvolution Results are included in Cowan (1995) and show the use of these methods for more detailed analysis
Filtered data
In order to reconcile 3D Euler results from shallow basement and intrasedimentary magnetic sources we produced
several separation-filtered maps and images We found the shallow-layer double-separation filter (Figure 45) to be
very effective for shallow sources and the deep-layer standard-separation filter (Figure 46) for the basement layer
Gravity and magnetic data correlation
Both lsquoreduced to the polersquo (RTP) magnetics (Figure 47) and pseudo-gravity data (Figure 48) were produced as part of
the reconciliation of gravity and magnetic signatures In both cases the filtering operations assumed magnetization by
induction in the present Earths field The RTP data are fairly similar to the total magnetic intensity The pseudo-
57
gravity data are dominated by a northwest-trending strong positive anomaly and there is little correlation with the
Bouguer gravity data
The poor magneticgravity correlation is confirmed by cross-correlation of the RTP magnetics and the gravity
gradient The correlation plot in Figure 49 shows little coherent response with numerous zones of positive and
negative correlation
Figure 45 Regional aeromagnetic data shallow layer separation filter (BMRAGSO data) gridded at 400 m
Results
In the north and east of the area on the Wells Foreland Sub-basin trend (refer to Figure 1 main text) we see a range
of quite deep 3D Euler depths and several trend directions with north-northwesterly dominant There are relatively few
shallow intrasedimentary solutions in this zone
The second area of deep 3D Euler solutions lies over the Blake depocentre (Figure 43) with several trend
directions
Elsewhere the 3D Euler results are dominated by shallow intrasedimentary depth solutions reflecting mainly the
dolerite sills dykes and the ring complex However where we do see basement-related solutions in the south and
west of the area they appear to be shallower than those noted for the Wells Foreland Sub-basin and the Blake
depocentre
58
Figure 46 Regional aeromagnetic data deep-layer separation filter (BMRAGSO data) gridded at 400 m
Figure 48 Regional aeromagnetic data pseudo-gravity transform (BMRAGSO data) gridded at 400 m
Figure 47 Regional aeromagnetic data reduced-to-pole (BMRAGSO data) gridded at 400 m
Figure 49 Regional aeromagnetic and gravity data gravitymagnetic correlation using RTP magnetics and gravity gradient (BMRAGSO data) gridded at 4 km
59
This subdivision of the area into two zones of deep solutions is consistent with interpreted depocentres
However the interference between sources at different levels and the complexity of the magnetic response of the
basement rocks precludes more refined interpretation at this stage
The area of deep 3D Euler solutions over the Blake depocentre correlates with the pronounced negative gravity
anomaly discussed in the gravity interpretation section Using a density contrast of -015 gcc the negative gravity
anomaly could indicate up to 6ndash8 km of low-density sedimentary rocks depending on assumptions about the regional
field
The area of deep 3D Euler solutions over the Wells Foreland Sub-basin has a complex gravity expression and no
clear basin structure emerges from inversion of these data As noted previously it is likely that observed gravity
anomalies reflect contrasts in basement density rather than basement topography
Separation filtering applied to the magnetic data helps to enhance the intrasedimentary magnetic signature and to
give a better impression of the basement magnetic signature even though separation of the basement response is not
perfect
Conclusions
Quantitative aeromagnetic interpretation using 3D Euler deconvolution supported by wavenumber filtering and image
processing has been successful in providing structural trend and depth information for the Savory Sub-basin
Quantitative magnetic interpretation has revealed two zones of relatively deep magnetic basement beneath the
Wells Foreland Sub-basin and the Blake depocentre
This analysis of the magnetic data supports interpreted depocentres but the complexity of the basement magnetic
signature and interference from sources at different depths precludes further refinement to a map of basement
topography
Regional gravity proved to be very useful in understanding the regional setting of the area and in providing
support for aspects of the interpretation The gravity data support the interpretation of the Blake depocentre
suggesting up to 6ndash8 km of low-density sedimentary rocks
The deep structure of the Savory Sub-basin area is obviously complex with different areas underlain by
Archaean and Proterozoic basement and with the Capricorn suture occurring in the centre of the area
60
Recommendations
The quantitative magnetic interpretation needs to be reconciled with geological models available for the area
In particular the zones tentatively identified as areas with thick sedimentary rocks the Wells Foreland Sub-
basin and the Blake depocentre need to be investigated
Cross sections should be prepared across the basin for joint magneticgravity modelling especially for the Blake
depocentre It is important to be able to explain the strong negative gravity anomaly in this area
In view of the effects of basement density contrasts on the gravity field for the northern part of the area we think
that additional gravity interpretation and acquisition of new gravity data may not be justified as they will not
contribute significantly to understanding basin evolution and structure
It is recommended that GSWA try to get access to company confidential high-resolution aeromagnetic data
rather than flying new surveys The GSWA might offer to fund flying of new infill areas as a bargaining point
References
The original text of this report by Cowan (1995) and 1500 000 scale maps are filed in the GSWA Library under
S10331
COWAN D 1995 Savory Basin quantitative magnetic interpretation Western Australia Geological Survey S-series
S10331 (unpublished)
VACQUIER V STEENLAND N C HENDERSON R G and ZIETZ I 1951 Interpretation of aeromagnetic
maps The Geological Society of America Memoir 47 151p
WILLIAMS I R 1992 Geology of the Savory Basin Western Australia Western Australia Geological Survey
Bulletin 141 115p
61
Appendix 5
Geochemistry
MKS38 250398
Saturate FractionC12+ GLC
1217
Pr18
Ph
22
31CSR WELL-13 315m Cuttings
Figure 51 Canning Stock Route Well 13 gas chromatograph of extract of auger drill sample
12
17
18
22
31
Pr Ph
LDDH 1 6623m CoreSaturate FractionC12+ GLC
MKS35 240398
Figure 52 Gas chromatograph of extract from core sample at 6623 m LDDH1
62
Table 51 Canning Stock Route Well 13 auger drill samples
GSWA sample Drill depth (m)(a) Comments
135601 150 At watertable 135602 203 (all samples consist 135603 310 of sand mud and water) 135604 315 At total depth
NOTE (a) Datum for drill depth is the top of sediment fill in the well which is 155 m below ground level (ie the total depth of 315 m is 47 m below ground level)
Table 52 Canning Stock Route Well 13 gas chromatography data for 315 m depth sediment sample
Parameter Value
Weight of rock extracted (grams) 945 Total extract (ppm) 519 n-Alkane distribution n-C12 07 n-C13 23 n-C14 26 n-C15 22 n-C16 19 n-C17 14 i-C19 23 n-C18 14 i-C20 08 n-C19 11 n-C20 16 n-C21 25 n-C22 29 n-C23 70 n-C24 42 n-C25 95 n-C26 43 n-C27 83 n-C28 38 n-C29 87 n-C30 31 n-C31 273 Alkane compositional data Pristane phytane ratio 279 Pristane n-C17 ratio 161 Phytane n-C18 ratio 059 CPI (1)(a) 284 CPI (2) 209 (C21 + C22) (C28 + C29) 043
NOTE (a) CPI= Carbon preference index
63
Table 53 LDDH1 extract liquid chromatography data for 6623 m concentration
Rock extracted Total extract (grams) (ppm)
702 313
NOTE ppm= parts per million
Table 54 LDDH1 saturate gas chromatography data of core for 6623 m alkane composition
Pristane Pristane Phytane (a) CPI (1) CPI (2) (C21+C22) Phytane n-C17 n-C18 (C28+C29)
103 026 024 103 102 325
NOTE (a)CPI = carbon preference index
Table 55 LDDH1 saturate gas chromatography data of core for 6623 m n-alkane distributions
Parameter Value
n-C12 17 n-C13 38 n-C14 55 n-C15 60 n-C16 65 n-C17 74 i-C19 19 n-C18 78 i-C20 19 n-C19 80 n-C20 79 n-C21 71 n-C22 64 n-C23 57 n-C25 43 n-C24 38 n-C27 31 n-C28 23 n-C29 19 n-C30 12 n-C31 10
64
Appendix 6
Table 61 Summary of data from Trainor waterbores (TWB) and Bullen waterbores (BWB)
Well AMG Elevation TD Status(b) Completion details Water Salinity Water level Flow rate Depth to consolidated AGD84 GL (m) (m) struck mgl(c) (m) (LHr) lithology aquifer(e) Z51(a) Interval (m) (100 mm PVC) (m) (mgl)(d)
TWB 1 473660E 453 122 comp 0ndash75 plain 63 7 300 24 2 880 12 m 7287404N 75ndash93 slotted (9 260) McFadden Fm 93ndash99 plain TWB 2 472 977E 475 23 abd nil 15 m 7285877N Skates Hills Fm dry TWB 3 473259E 475 50 abd nil 7 m 7285849N Skates Hills Fm dry TWB 4 463225 E 445 50 comp 0ndash22 plain 35 7 200 55 3 600 0 m 7286143N 22ndash34 slotted (8 140) Tertiary sand and gravel 23ndash60 plain TWB 5 463095E 445 31 comp 0ndash19 plain 13 26 000 655 3 600 Tertiary sand and gravel 7277721N 19ndash25 slotted (36 700) 25ndash31 plain TWB 6 457013E 455 50 comp 0ndash42 plain 38 920 119 600 0 m 7274352N 42ndash48 slotted (1 030) Cornelia Fm ss TWB 7 453739E 475 26 susp 0ndash2 plain 11 9 300 48 4 500 0 m 7263891N (10 500) Tertiary sand TWB 8 433893E 535 60 susp 0ndash2 plain 47 8 500 gt46 1 200 0 m 7245991N (10 900) Tertiary sand and Brassey Range Fm ss TWB 9 437219E 505 51 comp 0ndash47 plain 45 1 000 58 600 1 m 7235905N 47ndash51 slotted (990) Brassey Range Fm ss TWB 10 434927E 495 32 susp 0ndash2 plain 235 450 120 0 m 7225875N (500) Dolerite
65
BWB 1 287337E 580 122 abd Nil 1 m 7245861N Jilyili Fm dry BWB 2 288346E 545 50 comp 0ndash26 plain 15 630 3 29 000 0 m 7240423N 26ndash38 slotted (730) Tertiary sand and gravel 38ndash50 plain BWB 3 305637E 545 50 abd 19 8 800 43 7 200 0 m 7240423N (10 550) Tertiary ss BWB 4 320167E 515 445 comp 0ndash20 plain 9 980 445 24 000 0 m 7248097N 20ndash32 slotted (1 190) Tertiary ss 32ndash44 plain BWB 5 353393E 545 20 susp 0ndash2 plain 45 (970) 1 m 7238934N Basalt
NOTES (a) GPS accuracy ~ 150 m (b) Comp = completed abd = abandoned susp = suspended (c) Salinity from conductivity (d) Analysis total dissolved solids (e) Fm = Formation ss = sandstone
17
consists predominantly of sandstone and quartzite with lesser siltstone shale mudstone and chert
In Trainor 1 this formation consists predominantly of indurated mudstone with minor sandstone
chert and dolomite A major erosional unconformity separates the Cornelia Formation from
overlying formations and parts of the Cornelia Formation have been folded with dips exceeding
70deg In contrast the majority of the Savory Sub-basin sedimentary rocks have dips of less than 30deg
except where they are adjacent to faults The Cornelia Formation apparently consists of an older
unit of steeply dipping quartzites cherts and well-indurated mudstones and a younger unit of
shallower dipping sandstones which are sub-friable in parts However caution should be used in
interpreting the age of units based on their structural deformation and additional mapping and age
dating of this formation is required
It is proposed here that the Kahrban Subgroup is likely to be of early Neoproterozoic age and
hence should be considered as part of the greater Officer Basin This proposal is based largely on
the relatively low dip of the strata (generally less than 20deg) and their west-northwest strike which
is parallel with strikes in the overlying Brassey Range Formation of the Savory Group The lower
contact of the Kahrban Subgroup is obscured but is thought to be an unconfirmity on the
Earaheedy Basin on the southeast of STANLEY (Muhling and Brakel 1985)
Structural setting
The Savory Sub-basin forms the most northwesterly sub-basin of the Neoproterozoic to
Phanerozoic Officer Basin The western boundary of the sub-basin with the Mesoproterozoic
Bangemall Basin consists of steep-reverse and strike-slip faults The northeastern boundary of the
Savory Sub-basin was mapped where Supersequence 4 formations of the Savory Group
unconformably overlie sedimentary rocks of the Karara and Yeneena Basins with the two older
units considered to be part of the Paterson Orogen (Williams 1992) This contact was defined as a
series of steeply dipping reverse faults in the northernmost parts of the sub-basin on BALFOUR
DOWNS and RUDALL and was extrapolated as an inferred reverse fault farther along strike to the
southeast on GUNANYA and MADLEY where the contact is obscured by Cainozoic sediments It is
now recognized that all the sedimentary rocks in the Karara Basin and younger sedimentary rocks
of the Yeneena Basin are from the Supersequence 1 Tarcunyah Group and part of the greater
Officer Basin (Bagas et al 1995) The northern boundary of the Tarcunyah Group and the greater
Officer Basin is in thrust-and reverse-faulted contact with the Rudall Complex and other parts of
the Paterson Orogen (Fig 7)
To the south the sub-basin unconformably overlies the Bangemall Basin The eastern
boundary of the sub-basin used in this study is where Permian and younger strata of the Officer
Basin unconformably overlie Neoproterozoic strata although there are no significant structural or
stratigraphic differences between the Neoproterozoic units
18
The sub-basin is subdivided into three principal structural areas (Fig 1) Trainor Platform
Blake Fault and Fold Belt and Wells Foreland Sub-basin (Williams 1992) A major review of
these boundaries is beyond the scope of this report but the processing of regional aeromagnetic
data (Appendix 4) and acquisition of a semi-detailed gravity survey by the GSWA in the east of
the sub-basin has enabled these tectonic units to be reassessed and some modifications are
proposed
The Wells Foreland Sub-basin (originally termed the Wells Foreland Basin in Williams 1992)
and sedimentary rocks of the Tarcunyah Group are both considered to be the northwest
continuation of the Gibson Sub-basin of the Officer Basin Aeromagnetic gravity and outcrop
data suggest that the Blake Fault and Fold Belt is significantly faulted and folded in the west but
is less deformed in the east where the thickest sedimentary section in is located on BULLEN
(Appendix 4) The Trainor Platform is reinterpreted to represent an area of the sub-basin that has
undergone major compression during the Petermann Ranges Orogeny resulting in folding and
faulting with a northwest strike This interpretation contrasts with that proposed by Williams
(1992) who envisaged that only a thin section of the Savory Group was present on the platform
Perincek (1998) has recognized nine periods of tectonic activity in the Officer Basin from the
beginning of the Neoproterozoic to the end of the Cretaceous Three major tectonic episodes are
recognized in the Centralian Superbasin The oldest event is the Areyonga Movement which is
pre-Sturtian and forms the boundary between Supersequences 1 and 2 (Fig 4) The Souths Range
Movement occurred at the end of the Sturtian at the boundary between Supersequences 2 and 3
The youngest major event is the Petermann Ranges Orogeny which occured at the end of the
Marinoan and forms the boundary between Supersequences 3 and 4
One minor and two major tectonic episodes are recognized in the Savory Sub-basin the
LP1ALP1B structural event and the Areyonga Movement and the Petermann Ranges Orogeny
respectively The LP1ALP1B structural event is revealed where the Spearhole Formations rests
disconformably and locally unconformably on the Brassey Range Jilyili and Glass Spring
Formations The Neoproterozoic Areyonga Movement (equivalent to the Blake Movement of
Williams 1992) produced folds and faults with a general northeast strike in the western and
southern parts of the region The Souths Range Movement has not been recognized in the sub-
basin This may be due to the fact that no Sturtian glacial rocks have been identified and hence it
is possible that structures attributed to the Areyonga Movement could be the result of the Souths
Range Movement or a combination of the two movements
The major tectonic event recorded in the sub-basin is the latest Neoproterozoic to Cambrian
Petermann Ranges Orogeny (equivalent to the Paterson Orogeny) which produced large reverse
19
faults thrusts strike-slip faults and folds with a general northwest strike The McFadden
Formation and other Supersequence 4 strata are considered to be at least partially coeval with this
orogeny (Williams 1992) We also interpret the Durba Sandstone as having been deposited during
the later stages of the Petermann Ranges Orogeny as this unit mildly deformed with fold axes
parallel to the strike of other structures attributed to the Petermann Ranges Orogeny
Quantitative aeromagnetic interpretation of the Savory Sub-basin utilizing the 3D Euler
deconvolution method supported by wave-number filtering and image processing has provided
structural trends and depth to magnetic source within the sub-basin (Cowan 1995) Gravity data
are interpreted by Cowan (1995) as changes in both the density of the basement rocks andor
basement topography depending on local conditions Part of Cowanrsquos report is reproduced in
Appendix 4
Exploration history
The only petroleum exploration conducted in the sub-basin has been the recent drilling in the
western part of three diamond drillholes of which two have minor oil shows (Table 2) There has
been some mineral exploration the results of which are stored in the GSWA Western Australian
Mineral Exploration (WAMEX) database system Much of the mineral exploration was in the
southwest and west where the sub-basin is in contact with the Bangemall Basin and along the
northern margin of the sub-basin Many of these mineral exploration programs included
aeromagnetic surveys and surface geochemical sampling (Fig 8)
Hydrocarbon potential
The sub-basin contains a sedimentary succession up to 8 km thick which is generally gently
folded and faulted and apparently unmetamorphosed Limited drilling has shown that thick
mudstones are present in the sub-basin with some mudstones in Trainor 1 having high Total
Organic Carbon (TOC) values Outcrops of sub-friable sandstones in many of the formations
within the sub-basin suggests widespread reservoir potential Mudstone and inferred thick
evaporite sequences are likely to form seals Maturity data suggest that near-surface samples are
approximately at the base of the oil window and top of the gas window in parts of the north and
southeast of the sub-basin However parts of the southwest of the sub-basin and the mudstones in
Trainor 1 have very high levels of maturity Numerous faults and folds have been identified from
surface mapping suggesting good potential for large structural traps Minor oil shows in
20
Table 2 Neoproterozoic formations and hydrocarbon shows in diamond drillholes in the Savory Sub-basin
Drillhole AMG Core TD (m) Approx Formation Depth Formation Depth Formation Depth Shows (AGD84) start (m) GL (m) (m) (m) (m)
LDDH 1 431148E 112 701 350 Tarcunyah 68ndash701 ndash ndash bitumen at 6623 m 7443826N Group Trainor 1 473640E 6 709 455 McFadden 9ndash83 Cornelia Fm 83ndash709 possible bitumen at 4537 m 7287400N Fm Mundadjini 1 319056E 170 600 500 Mundadjini 16ndash361 Spearhole Fm 361ndash600 10 fluorescence at 36102 m 7404844N Fm Boondawari 1 348959E 299 1 367 490 Mundadjini Fm 15ndash312 Spearhole Fm 312ndash1 283 Intrusive 1 283ndash1 367 40 fluorescence at 35364 m 5 7398174N fluorescence at 4963 m Akubra 1 334249E 15 181 530 Mundadjini 15ndash42 Intrusive 42ndash181 None 7401252N Fm
21
50 km
120deg 121deg30 123deg
25deg
24deg
23deg
22deg
Greater Officer Basin
Savory Sub-basin
1
2
3
4
6
8
3 Seismic line (prefixed N83-00)
Aeromagnetic survey
GS
WA
Sav
ory
1995
gra
vity
sur
vey
Gravity survey
MKS34270398
Figure 8 Locations of aeromagnetic and gravity surveys (other than regional BMRAGSO data)
22
sandstones in two petroleum wells in the northwest of the sub-basin and bitumen and oil shows
elsewhere in the region indicate that oil has been generated and migrated through the sub-basin
Source rocks
Source potential is considered to be the major exploration risk in the Savory Sub-basin although
minor oil shows in Mundadjini 1 and Boondawari 1 indicate that at least some oil has been
generated and migrated into potential reservoirs within the sub-basin Sandstone is the
predominant lithology observed in outcrop Outcrops of fine-grained lithologies in the basin are
rare because of intense surface weathering and erosion Only about 8 of the surface area of the
sub-basin is exposed bedrock and recessive lithologies (such as shale evaporite and friable
sandstone) may be present although they rarely outcrop
Outcrops of stromatolitic dolomite with associated cauliflower chert and cubic pseudomorphs
interpreted as being after halite indicate that evaporitic environments are present within the
Mundadjini Skates Hills and Boondawari Formations Evaporitic minerals are also present in
drillhole LDDH1 in the Tarcunyah Group
In 1995 GSWA drilled a continuous-core diamond drillhole (Trainor 1) in the sub-basin on
TRAINOR to a depth of 709 m to test for source rocks thus providing the first such data for the sub-
basin The drillhole intersected flat-lying clastics and carbonates of the McFadden Formation (9ndash
83 m) overlying indurated mudstones of the Cornelia Formation (83ndash709 m total depth) dipping at
about 40deg Of the six samples analysed from the Cornelia Formation in this drillhole the five
located between 375 and 6032 m depth have TOC values exceeding 05 (range 066ndash365)
Rock-Eval pyrolysis of these five samples indicates that they are at best in the dry-gas thermal
stage and as a result of their high level of maturation (Stevens and Adamides in prep) have poor
remaining hydrocarbon-generating potential Although the Cornelia Formation is overmature at
Trainor 1 the high TOC values are encouraging as it is likely that this sequence is less mature
elsewhere in the sub-basin
The Mundadjini Formation contains potential source rocks that comprise marine mudstones
with evaporitic minerals present in parts Thin dark mudstones were intersected in the Mundadjini
Formation in Akubra 1 In Mundadjini 1 and Boondawari 1 however the mudstones appear to be
too oxidized to have source potential
The Boondawari Formation also may be a source rock as it contains black mudstones The
unit is laterally equivalent to the Pertatataka Formation of the Amadeus Basin and the Ungoolya
23
Group of the Officer Basin in South Australia both of which have some source potential
(Summons and Powell 1991 Morton and Drexel 1997) Samples from the Dey Dey Mudstone of
the Ungoolya Group generally have poor TOC values (average 011 range 003ndash081)
moderate hydrogen index (HI) values (100ndash382) and poor to fair genetic potential with a
maximum of 292 kg hydrocarbon per tonne of source rock (Morton and Drexel 1997)
Stromatolitic dolomites and mudstones at the top of the Boondawari Formation and within the
Skates Hills Formation are potential source rocks Stromatolitic dolomite and evaporitic rocks
deposited in a marginal marine to sabkha environment are considered to have good potential to
generate and preserve organic carbon without requiring a deep-water setting (Stevens and Grey
1997) Such conditions are recognized in the Skates Hills Formation and in the upper parts of the
Tarcunyah Group
Maturity
Knowledge of the maturity of sedimentary rocks within the Savory Sub-basin is still limited From
a review of palynological studies Grey and Stevens (1997) report that the thermal maturity
inferred from the Thermal Alteration Index (TAI) of 3+ from Supersequence 1 age palynomorphs
in TWB 6 TWB 9 and LDDH1 is within the hydrocarbon window (Appendix 3) In Phanerozoic
spores and pollen a TAI of 3+ approximately equates to the end of liquid petroleum generation
and the start of dry gas generation and to a vitrinite reflectance of about 13 (Traverse 1988)
However the use of TAI for estimating thermal maturity from Neoproterozoic palynomorphs
requires calibration
In Trainor 1 the Cornelia Formation contains organically rich claystones between 375 and
6032 m depth Based on Rock-Eval maturity data (Stevens and Adamides in prep) and the dark
colour of poorly preserved organic material (Grey 1995de 1996) with TAI 4- to 5 all samples
had a high level of maturation with at best dry-gas generating potential remaining In contrast
drillhole LDDH1 on GUNANYA recorded lower levels of maturity (TAI values of 3+) with two of
sixteen samples from the Tarcunyah Group having greater than 1 TOC (Grey 1995abc Grey
and Cotter 1996) Organic petrology and Rock-Eval maturity data for samples from LDDH1
indicate that the section above 500 m is within the oil-generative window whereas below 500 m
the rocks are within the gas window (Ghori in prep Fig 9 Appendix 5)
Waterbores TWB 1 2 6 and 9 which are located on TRAINOR in the southeast of the sub-
basin all had organic matter with TAI values of 3+ from the McFadden Skates Hills Cornelia
and Brassey Range Formations respectively
24
100
200
300
400
500
600
700
Oil
gene
ratin
g
Gas
gene
ratin
g
Fai
r
Fai
r
Poo
r
Poo
r
Goo
d
Imm
atur
e
Oil
win
dow
Oil
win
dow
Imm
atur
e
01 0110 10 0 150 300 440 480 1
Neo
prot
eroz
oic
TOC S1+S2 mgg Hydrogen Index Tmax degC
Depth(m)
Organicrichness
Generatingpotential
Kerogentype Maturity Maturity
TD=701m
Sandstone
Mudstone
Dolomite
Limestone
Evaporite
Source rock
MKS40 070498
Ro equivalent
Figure 9 Petroleum source potential of rocks in Normandy LDDH1
Small amounts of organic matter associated with basalt and dolerite in cuttings from
waterbore BWB 1 on BULLEN showed high levels of thermal maturity (Grey 1995a Libby 1995)
It is unclear whether all sedimentary rocks on BULLEN are overmature for hydrocarbon generation
or the results from BWB 1 are related to local heating events associated with the volcanic bodies
that are common in the Jilyili Formation
25
Reservoirs
Each of the five depositional sequences of the Savory Group (Table 1) are inferred to contain
significant sandstone reservoirs with the possible exception of depositional sequence C as
discussed above in Stratigraphy The Spearhole Formation was cored in Mundadjini 1 and
Boondawari 1 and visual estimates of porosity vary from generally poor (less than 5) to fair
(approximately 5ndash15) The McFadden Formation in Trainor 1 has porosity values of up to 232
and a maximum permeability of 195 md (Stevens and Adamides in prep) Sandstones from
Neoproterozoic formations form the acquifers in the following waterbores the McFadden
Formation in TWB 1 the Cornelia Formation in TWB 6 and the Brassey Range Formation in
TWB 8 and TWB 9 (Appendix 6 Table 61)
Based on outcrop observations the Durba Sandstone is considered to be the best reservoir of
the Savory Group Similarly some sandstones from the Tarcunyah Group also have good visible
porosity in outcrop
Dolomites occur in several formations in the sub-basin Reservoir potential may exist
particularly where the dolomites are stromatolitic and oolitic However dolomites have not been
drilled in the sub-basin and porosity can only be inferred from the preferential silicification of
some stromatolite bioherms observed in outcrop (Stevens and Grey 1997) Elsewhere in the
Officer Basin porosities of up to10 have been measured in dolomites A limestone breccia
(karst) is described from 663 to 677 m in drillhole LDDH1 (Fig 6 Busbridge 1994)
Seals
Indications of evaporitic environments in the Mundadjini Skates Hills and Boondawari
Formations are described by Williams (1992) In Mundadjini 1 from 287 to 337 m anhydrite and
chert occurs as nodules beds and veins in mudstone of the Mundadjini Formation Evaporitic
minerals (predominantly gypsum) are described in the Tarcunyah Group in LDDH1 The presence
of the Woolnough and Madley salt diapirs in the Officer Basin (approximately 110 km east of the
sub-basin) and halite beds over 25 m thick in the well Hussar 1 (130 km east of the sub-basin)
provide further evidence that evaporite seals may be present in the Savory Sub-basin
Mudstones and shales form only a small proportion of the limited Neoproterozoic outcrop in
the sub-basin but significant thicknesses of mudstone were encountered in the Mundadjini
Formation in Mundadjini 1 and Boondawari 1 the Tarcunyah Group in LDDH1 and in the
26
Cornelia Formation in Trainor 1 These data suggest that mudstones form a significant proportion
of strata in the sub-basin despite their limited outcrop
Traps
Potential structural closures including folds and faults occur at various scales throughout the
Savory Sub-basin However the region has only been mapped at 1250 000 scale and
independently closed structures such as domes have yet to be confirmed The western margin of
the basin contains abundant faults (with a northeast strike) but elsewhere faults are less common
Some anticlines are recognized in outcrop including one with a strike length of up to 45 km
inferred from surface bedding dips in the Mundadjini and Spearhole Formations at approximately
24deg15rsquoS 121deg10rsquoE on BULLEN (Fig 1)
Salt diapirs and other halokinetic structures are recognized in outcrop well and seismic data
in the Officer Basin to the west of the Savory Sub-basin and it is probable that there are
significant thicknesses of evaporitic sedimentary rocks in the sub-basin The gravity field data
suggest there is good potential for salt diapirs and traps related to halokinesis
Although there is potential for stratigraphic traps to be present in the sub-basin insufficient
data are available to assess them
Preservation of hydrocarbons
The range of thermal maturities measured to date and the large periods of time envisaged for
deposition of sediments implies hydrocarbon generation may have occurred a number of times
during the evolution of the Savory Sub-basin Any hydrocarbons that were generated early may
have been trapped in palaeostructures and remigration to younger traps could have taken place
later The Petermann Ranges Orogeny which has been equated with the Paterson Orogeny (Myers
1990) is believed to have occurred in the latest Neoproterozoic to early Cambrian This is the last
major tectonic event recognized in the sub-basin suggesting that it is reasonable to expect that trap
integrity will have been preserved
If the inference of the presence of thick halite beds in the sub-basin is correct the preservation
potential of sub-salt traps should be excellent
27
Reported hydrocarbon shows and oil seep
Amadeus Petroleum recorded minor oil shows in cores from Mundadjini 1 and Boondawari 1 In
Mundadjini 1 at 36102 m (top of the Spearhole Formation) a 3 mm thick zone had 10 moderate
white fluorescence with slow solvent cut This show was in a granular sandstone with visually
estimated porosity of about 10 In Boondawari 1 at 35364 m (within the Spearhole Formation) a
broken surface of sandstone had 40 moderate yellow-white fluorescence with slow solvent cut
Visually estimated porosity is about 5 Because the fluorescing surface was broken during the
drilling process this show could have resulted from contamination A second show occurs in
Boondawari 1 at 4963 m (within the Spearhole Formation) where a 1 cm-thick zone had 5 dull
yellow fluorescence with slow solvent cut in a conglomerate with visually estimated porosity of
about 10 The company intends to further investigate the nature of these occurrences
Minor bitumen is present at 6623 m in drillhole LDDH1 on GUNANYA (Figs 5 and 6) as a
vein in mudstones of the Tarcunyah Group A sample was analysed by gas chromatography
(Ghori in prep) and confirmed that it is natural bitumen (Appendix 5)
Mineral hole OD 23 drilled by Jubilee Gold Mines NL on NABBERU in the Bangemall Basin
immediately to the south of the Savory Sub-basin (Fig 5) encountered bitumen and trace oil in
vugs in dolomite (M Stevens unpublished data) but no further data are available at present
In their popular guide to the Canning Stock Route Gard and Gard (1990 p 218) refer to an
oil seep at Well 13 on TRAINOR (Fig 5) They reported that between 1977 and 1984 lsquonatural oilrsquo
was seen in the well Although the well is now largely filled with sediment four auger drill
samples were collected by the GSWA in 1995 and all four were analysed for oil shows One
sample from 315 m total depth (GSWA sample 135604) yielded just enough extract (519 ppm)
for saturate gas chromatography analysis The gas chromatograph (Appendix 5) shows that the
extract does contain some hydrocarbons probably from recent plant material Because the depth to
the oil was not quoted in Gard and Gard (1990) the hand-augered well may not have been deep
enough to properly test this reported seep
Geological and geophysical databases
Geological and geophysical data available for the Savory Sub-basin are limited The most recently
completed geological maps for the sub-basin were published by the GSWA between 1991 and
1995 (Williams and Tyler 1991 Williams 1992 1995ab)
28
The cores from the five drillholes listed in Table 2 believed to be all of the core available
from the sub-basin are available for inspection at GSWA Mineral exploration reports submitted
to GSWA may be searched using the WAMEX database and open-file reports are available on
microfiche Geophysical data acquired by the mining industry is not required to be filed with
GSWA if acquired over Vacant Crown Land which is the case for much of the sub-basin
Geophysical survey data submitted in mining tenement reports and which extend into Vacant
Crown Land remain confidential to the companies Original regional aeromagnetic and gravity
datasets are available from the Australian Geological Survey Organisation (AGSO)
Data pertinent to oil exploration in the sub-basin such as structural style and salt diapirism
are presented in a review of the hydrocarbon prospectivity of the Officer Basin (Perincek 1998)
Drilling
Significant drillholes in the sub-basin are summarized in Table 2
Petroleum industry data
Amadeus Petroleum drilled three petroleum exploration wells in the central west of the Savory
Sub-basin in late 1997 These wells Mundadjini 1 Boondawari 1 and Akubra 1 were drilled by
continuous diamond coring (Figs 5 and 6) All targeted potential reservoirs within the Spearhole
Formation with the Mundadjini Formation as the proposed seal The wells were located on
structures interpreted from Landsat images and limited geological investigations Both Mundadjini
1 and Boondawari 1 had minor oil shows as discussed above (Reported hydrocarbon shows)
Government data
Stratigraphic drillhole Trainor 1 was drilled by GSWA in 1995 (Stevens and Adamides in prep)
and the main results are discussed above (Source rocks and Maturity)
Mineral industry data
Normandy Exploration drillhole LDDH1 was cored in the Tarcunyah Group to a total depth of
701 m and provided source-rock and maturity data as discussed above
29
Oilmin NL drilled six percussion drillholes (BD 1 3 4 5 8 and 9) through sandstones and
shales in the northern part of the Savory Sub-basin to a maximum depth of 198 m (Fig 5
WAMEX Microfiche File M 26811 I 2610) but only brief geological descriptions are available
Hydrogeological data
Hydrogeological data within the Savory Sub-basin are limited although a long history of water
exploration extends back to the construction of the Canning Stock Route early this century No
detailed geological or wireline logs are available for the older wells along this route A few station
wells have been drilled by various methods on the south and west margins of the basin but data
are unavailable as reports are not required to be filed with the government Depth to watertable
throughout the basin is largely controlled by porosity of the bedrock
The GSWA drilled fifteen waterbores in the winter of 1995 in the southern part of the sub-
basin in preparation for the drilling of Trainor 1 and the proposed Bullen 1 Twelve bores found
water and six of these bores have salinities of less than 1000 mgL (Fig 5 Appendix 6 Table 61)
One waterbore TWB 6 has gamma ray and neutron logs run through PVC casing and these are
available from the GSWA with the digital log data included herein
Seismic data
No geophysical data have been acquired by the petroleum industry in the Savory Sub-basin
Seismic data acquired in the Officer Basin to the east particularly in the Gibson and Yowalga
Sub-basins is pertinent to structural interpretation in the Savory Sub-basin (Perincek 1996a
1998)
Aeromagnetic surveys
Government data
There are over 95 277 line kilometres of aeromagnetic data included in the AGSO dataset There
are three regional aeromagnetic surveys covering the Savory Sub-basin These were flown by the
Bureau of Mineral Resources (BMR now AGSO) in 1984 at a line spacing of 1500 m with 36 740
and 52 587 line kilometres flown and by Aerodata in 1984 at a line spacing of 1000m with 5950
line kilometres flown These data were reprocessed and interpreted for GSWA by Cowan (1995)
An edited copy of this report is included as Appendix 4 and the original report is filed in the
GSWA Library under S-series reports item 10331
30
Mineral industry data
The approximate locations of non-AGSO aeromagnetic surveys are shown in Figure 8 More
detailed information regarding the location of these surveys may be obtained using the GSWA
MAGCAT II database Additional information such as contours of aeromagnetic values may be
obtained by inspecting items on file with the GSWA
Gravity surveys
Government data
The average spacing for gravity data in the Savory Sub-basin is one station per 121 km2 (11 times 11
km grid) These data were principally collected by BMR in the early 1960s There are a few
additional regional gravity traverses across the sub-basin which are also included in the
BMRAGSO dataset These data were reprocessed and interpreted for GSWA (Fig 10) and a
report on this work is also included in Appendix 4
The GSWA completed a large semi-detailed gravity survey in the eastern Savory Sub-basin
utilizing helicopter support and Differential Global Positioning Survey (DGPS) techniques (Fig
8) This gravity survey completed in August 1995 consists of 2300 gravity stations on a 2 times 3 km
grid All stations were acquired by helicopter using Scintrex gravimeters and Ashtek dual
frequency DGPS equipment for determining location This highly efficient system allowed the
acquisition of more than 100 gravity stations per day in remote areas The resolution of this survey
is +30 cm and +05 microms-2 (Daishsat 1995) These data (Fig 11) represent a significant
improvement on the previous regional survey data and are available from GSWA (GSWA
1996ab) The results of the interpretation of these data were presented at the 1997 ASEG
Convention (Carlsen and Shevchenko 1997)
Mineral industry data
Three small gravity surveys were conducted by Oilmin NL (Fig 8) and the relevant WAMEX
reports are M 2681I 2610 I 2435 I 2567 These three surveys are of limited value because height
control was provided by barometers only and the surveys were not tied to the national gravity grid
31
23deg
25deg
120deg 122deg
Trainor 1
SAVORY
SUB-BASIN
MKS54 160498
100 km
1995 SavoryGravity Survey
254
-1056
micromsec2
Figure 10 Regional Bouguer gravity map of the Savory Sub-basin
23deg
24deg
25deg
122deg30 123deg
TRAINOR 1
123deg30
50 km
MKS53 160498
-116
-626
micro msec2
Figure11 Detailed Bouguer gravity map of the
Savory 1995 Gravity Survey from the eastern Savory Sub-basin
32
Government and academic reports
Chronostratigraphy and geochemistry
The understanding of Neoproterozoic organic chemistry palynology and structural evolution is
essential to the interpretation of hydrocarbon prospectivity Pertinent reports are included in the
bibliography (Appendix 1) Unpublished palaeontology reports describe the palynology of wells in
the Savory Sub-basin (Grey 1995andashe 1996a) Grey and Cotter (1996) discussed the potential for
Neoproterozoic palynomorphs to provide a biostratigraphic framework and palaeoenvironmental
interpretation Grey and Stevens (1997) reviewed the results of palynological studies of wells
drilled in the sub-basin and reported that Supersequence 1 palynomorphs are present in TWB 6
TWB 9 and LDDH1 (Appendix 3) Grey (1996b) reported on the use of stromatolites for
correlation in the Neoproterozoic and Stevens and Grey (1997) discussed the application of
stromatolite biostratigraphy in correlating isolated dolomite outcrops in the sub-basin with well
and seismic data in the Officer Basin and Centralian Superbasin
Although geochemical data from the Savory Sub-basin are very limited results mostly
confirm thermal maturities inferred from TAI for LDDH1 and Trainor 1 (Ghori in prep Stevens
and Adamides in prep) Those parts of the Officer Basin in Western Australia which lie to the
east of the Savory Sub-basin are sparsely drilled but Ghori (in prep) reports that most of the
Neoproterozoic succession presently lies within the oil-generative window However his study
has been unable to identify effective source-rock units and the source for oil shows Thin source
rocks are present in the Neoproterozoic in LDDH1 (Fig 9) and in three wells which lie to the east
and southeast of the Savory Sub-basin namely NJD 1 Kanpa 1A and Yowalga 3
Proposed work program
From the above limited information it is concluded that additional research on the hydrocarbon
potential of the sub-basin is justified and proposals are outlined below
bull Additional modelling of gravity and aeromagnetic data from the Savory Sub-basin is required
in light of the results from Trainor 1 and Boondawari 1 Trainor 1 showed that what appeared
to be a structurally simple area based on outcrop aeromagnetic and gravity data was in fact an
area of major structuring Boondawari 1 intersected a dolerite which is in good depth
agreement with aeromagnetic depth to source results showing this technique is useful in
detecting the depth to intrusive bodies
33
bull Additional data from mineral and petroleum exploration bores may become available and
analysis of samples from these wells should be undertaken and interpreted in the context of
their relevance to the Officer Basin
bull Stratigraphic coring in the Blake Fault and Fold Belt and in the Wells Foreland Sub-basin (Fig
1) targeting source rocks is considered essential to the continuing evaluation of the
hydrocarbon prospectivity of the Savory Sub-basin
bull Correlations using at least outcrop well and potential-field data should be prepared to link the
sub-basin with the better known parts of the Officer Basin to the east
bull Remapping is required to clarify boundary positions within the Cornelia Formation this may
resolve some of the current problems of the relationship between this unit and the rest of the
Savory Sub-basin
bull Further work is required to explain the Early Cambrian or Sturtian ages interpreted for the
Cornelia Formation from sedimentary zircon UndashPb dating in drillhole Trainor 1 The
determination of the age of the organically rich but overmature claystones in this well is
critical to assessing the hydrocarbon potential of the region
bull The thin dark mudstones intersected by Akubra 1 in the Mundadjini Formation warrant
geochemical analysis Analyses of the oil shows in Mundadjini 1 and Boondawari 1 are
currently being undertaken by Amadeus Petroleum
bull Geochemical analysis of hydrocarbons in the Bangemall Basin drillhole OD23 has been
performed by Jubilee Gold and the results will be reviewed when they are submitted to
GSWA The possibility of source rocks within the Bangemall Basin charging traps within the
Bangemall Basin and the overlying Savory Sub-basin requires further investigation
Conclusions
The Savory Sub-basin is a frontier region with only three recently drilled petroleum exploration
wells and no seismic data Based on existing geological and geophysical data it is considered too
early to draw conclusions about the hydrocarbon prospectivity of the sub-basin at this stage and
there are several reasons why the area warrants further investigation
34
1 Thick accumulations of sedimentary rocks are present (up to 8 km thickness inferred) which
may contain source reservoir and sealing strata
2 Minor oil shows occur in Mundadjini 1 and Boondawari 1 and bitumen is present in mineral
exploration drillhole LDDH1 suggesting that hydrocarbons have migrated within the
Neoproterozoic sequence of the Savory Sub-basin Oil and bitumen are present in mineral
exploration drillhole OD23 in the Bangemall Basin immediately to the south of the Savory
Sub-basin and it is possible that source rocks from the Bangemall Basin could charge traps in
the overlying Savory Sub-basin
3 The age of sedimentary rocks in the sub-basin is still poorly constrained but some of the
Neoproterozoic sedimentary rocks located on GUNANYA and TRAINOR are within the
hydrocarbon-generation window It is possible that a significant thickness of Phanerozoic
sedimentary rocks may also be present
4 Friable sandstones with visible porosity outcrop extensively suggesting numerous potential
reservoirs
5 Significant but not intense faulting and folding has been mapped implying large structural
traps may be present
6 Evaporitic sedimentary rocks occur in several formations and may provide good source rocks
and excellent seals
35
References
APAK S N and CARLSEN G M 1997 A compilation and review of data pertaining to the
hydrocarbon prospectivity of the Canning Basin Western Australia Geological Survey
Record 199610 103p
BAGAS L GREY K and WILLIAMS I R 1995 Reappraisal of the Paterson Orogen and
Savory Basin Western Australia Geological Survey Annual Review 1994ndash95 p 55ndash63
BUSBRIDGE M 1994 Lake Disappointment Exploration Licence 451064 Third Annual
Report Lake Disappointment Diamond Drill Hole LDDH1 Normandy Exploration Limited
Western Australia Geological Survey M-series Item 7567 A41358 (unpublished)
CARLSEN G M and SHEVCHENKO S I 1997 Petroleum exploration in Proterozoic basins
using potential fields data and stratigraphic coring Australian Society of Exploration
Geophysicists 12th Geophysical Conference Handbook Sydney 1997 Preview no 66 p 83
(abstract only)
COWAN D 1995 Savory Basin quantitative magnetic interpretation Western Australia
Geological Survey S-series S10331 (unpublished)
DAISHSAT PTY LTD 1995 Operational and processing report Savory Basin gravity survey
Western Australia Geological Survey S-series S10332 (unpublished)
GARD E and GARD R 1990 Canning Stock Route a travellerrsquos guide for a journey through
history Perth Western Australia Western Desert Guides 448p
GEOLOGICAL SURVEY OF WESTERN AUSTRALIA 1996a Savory Basin first vertical
derivative of Bouguer gravity image 1250 000 Western Australia Geological Survey
GEOLOGICAL SURVEY OF WESTERN AUSTRALIA 1996b Savory Basin Bouguer gravity
image 1250 000 Western Australia Geological Survey
GHORI K A R in prep Petroleum source rock potential and thermal history Officer Basin
Western Australia Western Australia Geological Survey Record
36
GREY K 1995a Savory Basin drillhole BWB 1 (Bullen waterbore) palynology and thermal
maturation GSWA Palaeontology Report no 199512 (unpublished)
GREY K 1995b Savory Basin drillholes TWB 1 2 6 9 (Trainor waterbores) palynology and
thermal maturation GSWA Palaeontology Report no 199520 (unpublished)
GREY K 1995c Palynology of Normandy-Poseidon Lake Disappointment-1 corehole
Tarcunyah Group Paterson Orogen GSWA Palaeontology Report no 199521 (unpublished)
GREY K 1995d Savory Basin drillhole Trainor 1 (Trainor diamond drilling) palynology and
thermal maturity GSWA Palaeontology Report no 199524 (unpublished)
GREY K 1995e Savory Basin drillhole Trainor 1 (Trainor diamond drilling) Additional
Preparation of two samples GSWA Palaeontology Report no 199528 (unpublished)
GREY K 1995f Neoproterozoic stromatolites from the Skates Hills Formation Savory Basin
Western Australia and a review of the distribution of Acaciella australica Australian Journal
of Earth Sciences v 42 p 123ndash132
GREY K 1996a Savory Basin drillhole Trainor 1 (Trainor diamond drilling) Additional
samples palynology and thermal maturation GSWA Palaeontology Report no 199615
(unpublished)
GREY K 1996b Preliminary stromatolite correlations for the Neoproterozoic of the Officer
Basin and a review of Australia-wide correlations GSWA Palaeontology Report no 199615
(unpublished)
GREY K and COTTER K L 1996 Palynology in the search for Proterozoic hydrocarbons
Western Australia Geological Survey Annual Review for 1995ndash96 p 70ndash80
GREY K and STEVENS M K 1997 Neoproterozoic palynomorphs of the Savory Sub-basin
Western Australia and their relevance to petroleum exploration Western Australia
Geological Survey Annual Review for 1996ndash97 p 49ndash54
HUBBARD R J PAPE J and ROBERTS D G 1985 Depositional sequence mapping as a
technique to establish tectonic and stratigraphic framework and evaluate hydrocarbon
potential on a passive continental margin in Seismic stratigraphy II an integrated approach
37
edited by O R BERG and D G WOOLVERTON American Association of Petroleum
Geologists Memoir 39 p 79ndash91
LIBBY WG 1995 A petrological report on six samples of bore cuttings from the Savory Basin
Western Australia Western Australia Geological Survey S-series S31307 (unpublished)
MORTON JGG and DREXEL JF 1997 The petroleum geology of South Australia Vol 3
Officer Basin South Australia Department of Mines and Energy Resources Report Book
9719
MUHLING P C and BRAKEL A T 1985 Geology of the Bangemall Group mdash the evolution
of an intracratonic Proterozoic basin Western Australia Geological Survey Bulletin 128
219p
MYERS J S 1990 Precambrian tectonic evolution of part of Gondwana southwestern Australia
Geology v18 p 537ndash540
NELSON D R 1997 Compilation of SHRIMP UndashPb zircon data Western Australia Geological
Survey Record 19972 196p
PAYTON C E 1977 Seismic stratigraphy mdash applications to hydrocarbon exploration
American Association of Petroleum Geologists Memoir 26 516p
PERINCEK D 1996a The age of NeoproterozoicndashPalaeozoic sediments within the Officer Basin
of the Centralian Super-basin can be constrained by major sequence-bounding unconformities
APPEA Journal v 36 pt 1 p 350ndash368
PERINCEK D 1996b The stratigraphic and structural development of the Officer Basin
Western Australia a review Western Australia Geological Survey Annual Review 1995ndash
1996 p 135ndash148
PERINCEK D 1998 A compilation and review of data pertaining to the hydrocarbon
prospectivity of the Officer Basin Western Australia Geological Survey Record 19976
POSAMENTIER H W JERSEY M T and VAIL P R 1988 Eustatic controls on clastic
deposition 1 mdash Conceptual framework in Sea-level changes an integrated approach edited by
C K WILGUS B S HASTINGS C G St C KENDALL H W POSAMENTIER
38
C A ROSS and J C VAN WAGONER Society of Economic Paleontologists and
Mineralogists Special Publication no 42
STEVENS M K and ADAMIDES N G in prep GSWA Trainor 1 well completion report
Savory Sub-basin Officer Basin Western Australia with notes on petroleum and mineral
potential Western Australia Geological Survey Record 199612
STEVENS M K and GREY K 1997 Skates Hills Formation and Tarcunyah Group Officer
Basin mdash carbonate cycles stratigraphic position and hydrocarbon prospectivity Western
Australia Geological Survey Annual Review for 1996ndash97 p 55ndash60
SUMMONS RE and POWELL C McA 1991 Petroleum source rocks of the Amadeus Basin
in Geological and geophysical studies in the Amadeus Basin central Australia edited by R J
KORSCH and JM KENNARD Australia BMR Geology and Geophysics Bulletin 236
TRAVERSE A 1988 Palaeopalynology Boston Unwin Hyman 600p
VAIL P R MITCHUM R M Jr TODD R G WIDMIER J M THOMPSON S III
SANGREE J B BUBB J N and HATLELID W G 1977 Seismic stratigraphy and
global changes of sea level in Seismic stratigraphy mdash applications to hydrocarbon
exploration edited by C E PAYTON American Association of Petroleum Geologists
Memoir 26 516p
WALTER M R and GORTER J 1994 The Neoproterozoic Centralian Superbasin in Western
Australia the Savory and Officer Basins in The sedimentary basins of Western Australia
edited by P G PURCELL and R R PURCELL Petroleum Exploration Society of Australia
Symposium Perth WA 1994 Proceedings p851ndash864
WALTER M R GREY K WILLIAMS I R and CALVER C R 1994 Stratigraphy of the
Neoproterozoic to early Palaeozoic Savory Basin and correlation with the Amadeus and
Officer Basins Australian Journal of Earth Sciences v 41 p 533ndash546
WALTER M R VEEVERS J J CALVER C R and GREY K 1995 Neoproterozoic
stratigraphy of the Centralian Superbasin Australia Precambrian Research v 73 p 173ndash195
WILLIAMS I R 1992 Geology of the Savory Basin Western Australia Western Australia
Geological Survey Bulletin 141 115p
39
WILLIAMS I R 1995a Bullen WA (2nd Edition) Western Australia Geological Survey
1250 000 Geological Series Explanatory Notes 23p
WILLIAMS I R 1995b Trainor WA (2nd Edition) Western Australia Geological Survey
1250 000 Geological Series Explanatory Notes 31p
WILLIAMS I R and TYLER I M 1991 Robertson WA (2nd edition) Western Australia
Geological Survey 1250 000 Geological Series Explanatory Notes 36p
40
41
Appendix 1
Bibliography
Reports which are relevant to this investigation but which are not specifically cited are listed
below
BAILLIE P W POWELL C McA LI Z X and RYALL A M 1994 The tectonic
framework of Western Australiarsquos Neoproterozoic to recent sedimentary basins in The
sedimentary basins of Western Australia edited by P G PURCELL and R R PURCELL
Petroleum Exploration Society of Australia Symposium Perth WA 1994 Proceedings p
45ndash62
BRADSHAW M T BRADSHAW J MURRAY A P NEEDHAM D J SPENCER L
SUMMONS R E WILMOT J and WINN S 1994 Petroleum systems in West Australian
basins in The sedimentary basins of Western Australia edited by P G PURCELL and R R
PURCELL Petroleum Exploration Society of Australia Symposium Perth WA 1994
Proceedings p 93ndash118
CLARKE G L 1991 Proterozoic tectonic reworking in the Rudall Complex Western Australia
Australian Journal of Earth Science v38 p 31ndash44
COCKBAIN A E and HOCKING R M 1990 Phanerozoic in Geology and mineral resources
of Western Australia Western Australia Geological Survey Memoir 3 p 750ndash755
ETHERIDGE M and WALL V 1994 Tectonic and structural evolution of the Australian
Proterozoic 12th Australian Geological Convention Geological Society of Australia
Abstracts no 37 p 102ndash103
GOODE A D T 1981 Proterozoic geology of Western Australia in Precambrian of the
Southern Hemisphere Developments in Precambrian geology 2 edited by I R HUNTER
Amsterdam Elsevier p 105ndash203
GREY K and JACKSON M J 1983 A re-assessment of stromatolite evidence for the
correlation of the Late Proterozoic Neale and Ilma Beds Officer Basin Western Australia
Australia BMR Journal of Australian Geology and Geophysics v 8 p 359
42
HICKMAN A H WILLIAMS I R and BAGAS L 1994 Proterozoic geology and
mineralization of the TelferndashRudall region Paterson Orogen Geological Society of Australia
(WA Division) Excursion Guidebook no 5 56p
HOCKING R M MORY A J and WILLIAMS I R 1994 An atlas of Neoproterozoic and
Phanerozoic basins of Western Australia in The sedimentary basins of Western Australia
edited by P G PURCELL and R R PURCELL Petroleum Exploration Society of Australia
Symposium Perth WA 1994 Proceedings p 21ndash 44
JACKSON P R 1966 Geology and review of exploration Officer Basin Western Australia
Hunt Oil Company Western Australia Geological Survey S-series S26 (unpublished)
JACKSON M J 1971 Notes on a geological reconnaissance of the Officer Basin Western
Australia Australia BMR Geology and Geophysics Record 19715 30p
JACKSON M J and van de GRAAFF W J E 1981 Geology of the Officer Basin Western
Australia Australia BMR Geology and Geophysics Bulletin 206 102 p
LOWRY D C JACKSON M J van de GRAAFF W J E and KENNEWELL P J 1971
Preliminary result of geological mapping in the Officer Basin Western Australia Western
Australia Geological Survey Annual Report for 1971 p 50ndash56
MYERS J S 1990 Precambrian in Geology and mineral resources of Western Australia
Western Australia Geological Survey Memoir 3 p 737ndash750
MYERS J S SHAW R D and TYLER I M 1994 Proterozoic tectonic evolution of
Australia 12th Australian Geological Convention Geological Society of Australia Abstracts
no 37 p 312
NEDIN C and JENKINS R J F 1991 Re-evaluation of unconformities separating the
lsquoEdiacaranrsquo and Cambrian systems South Australia Palaios v 6 p 102ndash108
PHILLIPS B J JAMES A W and PHILIP G M 1985 The geology and hydrocarbon
potential of the north-western Officer Basin APEA Journal 25 (1) p 52ndash61
POWELL C McA LI Z X McELHINNY M W MEERT J G and PARK J K 1993
Paleomagnetic constraints on timing of the Neoproterozoic breakup of Rodinia and Cambrian
formation of Gondwana Geology v 21 p 889ndash892
43
POWELL C McA PREISS W V GATEHOUSE C G KRAPEZ B and LI Z X 1994
South Australian record of a Rodinian epicontinental basin and its mid-Neoproterozoic
breakup to form the Palaeo-Pacific Ocean Tectonophysics v 237 no 3ndash4 p 113ndash140
PREISS W V 1976 Proterozoic stromatolites from the Nabberu and Officer Basins Western
Australia and their biostratigraphic significance South Australia Geological Survey Report
of Investigations no 47 p 1ndash51
TOWNSON W G 1985 The subsurface geology of the western Officer Basin mdash results of
Shellrsquos 1980ndash1984 petroleum exploration campaign APEA Journal v 25 (1) p 34ndash51
WATTS K J 1982 The geology of the Townsend Quartzite Upper Proterozoic shallow water
deposit of the Northern Officer Basin Western Australia Perth University of Western
Australia BSc honours thesis (unpublished)
WELLS A T and KENNEWELL P J 1974 Evaporite exploration in the Officer Basin
Western Australia at the Madley Diapirs Australia BMR Record 1974194 (unpublished)
WILLIAMS I R and MYERS J S 1990 Paterson Orogen in Geology and mineral resources
of Western Australia Western Australia Geological Survey Memoir 3 p 274ndash286
WILLIAMS I R 1990 Savory Basin in Geology and mineral resources of Western Australia
Western Australia Geological Survey Memoir 3 p 329ndash334
WILLIAMS I R 1994 The Neoproterozoic Savory Basin Western Australia in The
sedimentary basins of Western Australia edited by P G PURCELL and R R PURCELL
Petroleum Exploration Society of Australia Symposium Perth WA 1994 Proceedings p
841ndash850
WILSON R B 1967 Woolnough Hills and Madley diapiric structures Gibson Desert WA
APEA Journal v 7 p 94ndash102
44
Appendix 2
Meteorological data (from Bureau of Meteorology Perth 1994)
Table 21 Wiluna rainfall (mm)
Year Jan Feb Mar Apr May Jun Jul Aug Sept Oct Nov Dec
1975 0 45 446 309 306 59 276 4 34 886 638 164 1976 16 154 12 138 53 16 34 62 12 238 0 2 1977 44 0 66 74 68 95 24 363 1 58 12 727 1978 234 522 94 16 0 96 367 24 16 353 185 45 1979 19 173 122 88 91 4 0 246 58 0 169 114 1980 148 764 68 1081 259 626 629 06 56 02 174 0 1981 123 476 192 32 196 118 44 74 14 0 28 312 1982 374 705 206 244 1079 92 02 143 368 526 368 118 1983 1 112 928 248 0 212 56 32 5 1 42 496 1984 149 7 342 84 836 0 348 132 224 04 16 172 1985 596 483 0 166 556 0 514 56 0 0 4 0 1986 0 154 35 0 0 1085 23 01 239 137 0 04 1987 1204 119 19 89 17 575 154 126 07 1 0 398 1988 46 202 164 13 388 0 202 104 0 0 224 1309 1989 207 234 26 703 278 536 57 0 01 0 144 02 1990 1035 23 281 46 126 53 94 218 44 9 42 0 1991 48 0 41 45 0 472 297 12 0 1 0 7 1992 112 96 1025 1227 323 65 04 174 0 132 48 4 1993 0 697 0 202 445 0 12 306 18 05 14 33 Mean 25 35 22 27 27 25 18 12 6 13 13 21
JAN FEB MAR APR MAY JUN JUL AUG SEP OCT NOV DEC0
10
20
30
40
Mea
n R
ain
fall
(mm
)
Month
Mean monthly rainfall in Wiluna
MKS41 140498
45
Table 22 Wiluna minimum temperature (degC)
Year Jan Feb Mar Apr May Jun Jul Aug Sept Oct Nov Dec
1975 ndash 23 203 15 94 63 71 62 103 124 169 205 1976 242 229 194 15 10 63 59 73 95 143 16 228 1977 243 25 197 148 96 95 56 86 102 ndash 188 23 1978 241 232 203 18 102 64 76 8 9 152 19 205 1979 255 226 216 167 83 6 59 79 97 145 198 223 1980 255 226 231 155 134 83 68 75 121 108 193 223 1981 245 216 19 182 119 6 54 78 138 159 163 218 1982 232 224 177 16 ndash ndash 37 111 112 164 209 225 1983 235 24 197 147 112 88 39 88 121 162 189 219 1984 241 243 191 156 ndash 72 66 7 95 161 182 211 1985 244 231 ndash 159 98 65 71 73 117 147 205 ndash 1986 ndash 229 226 155 93 96 43 49 10 122 ndash 219 1987 ndash 217 183 175 85 77 68 68 112 ndash ndash 221 1988 238 214 209 178 111 ndash ndash 86 104 157 171 195 1989 ndash 237 199 165 107 67 44 61 107 131 187 ndash 1990 232 ndash 211 155 118 62 57 87 102 149 195 22 1991 26 256 217 168 122 101 78 ndash 113 18 168 219 1992 227 227 214 169 102 98 59 69 ndash 125 159 196 1993 241 218 196 171 103 ndash 49 68 88 128 192 211 Mean 24 23 20 16 10 8 6 8 11 14 18 21
NOTE Dashes indicate data unavailable
JAN FEB MAR APR MAY JUN JUL AUG SEP OCT NOV DEC0
10
20
30
40
Month
MKS43 140498
50
Mean monthly minimum temperatures at Wiluna
Mea
n T
emp
erat
ure
(degC
)
46
Table 23 Wiluna maximum temperature (degC)
Year Jan Feb Mar Apr May Jun Jul Aug Sept Oct Nov Dec
1975 ndash 349 326 281 247 201 197 212 256 248 31 344 1976 374 369 346 297 248 206 208 225 265 287 313 388 1977 397 392 352 296 234 212 222 244 ndash 308 337 383 1978 378 345 346 316 242 195 176 205 231 295 334 356 1979 403 36 364 295 ndash ndash ndash 193 242 318 359 373 1980 392 342 377 275 24 176 179 233 292 288 349 391 1981 385 346 337 342 242 178 201 224 30 326 326 369 1982 372 359 315 307 ndash ndash 196 253 252 305 353 379 1983 381 389 327 272 263 222 187 248 287 321 336 366 1984 378 393 322 299 226 215 178 214 234 ndash 336 364 1985 40 366 ndash 294 224 216 205 212 284 307 355 ndash 1986 ndash 383 372 307 ndash 193 166 196 261 277 ndash 382 1987 ndash 339 328 305 21 202 214 218 275 ndash ndash 374 1988 388 365 353 301 23 ndash ndash 228 283 334 31 33 1989 ndash 375 339 285 238 179 181 219 275 298 336 ndash 1990 368 ndash 36 309 268 19 188 205 274 309 373 393 1991 414 416 363 315 268 206 21 ndash 279 338 332 368 1992 363 383 336 263 213 178 213 197 ndash 285 313 359 1993 396 357 344 301 221 ndash 197 215 253 294 347 362 Mean 39 37 34 30 24 20 20 22 27 30 34 37 NOTE Dashes indicate data unavailable
JAN FEB MAR APR MAY JUN JUL AUG SEP OCT NOV DEC0
10
20
30
40
Month
MKS42 140498
50
Mean monthly maximum temperatures at Wiluna
Mea
n T
emp
erat
ure
(degC
)
47
Appendix 3
Table 31 Summary of palynological results
Drillhole Depth (m) F no(a) GSWA no Lithology Formation Assemblage TAI(b)
BWB 1 74ndash75 F49668 135741 dark-grey siltstone basalt Jilyilli gt5 BWB 1 98ndash100 F49669 135742 dark-grey siltstone basalt Jilyilli gt5 BWB 1 121ndash122 F49670 135743 dark-grey siltstone basalt Jilyilli gt5 TWB 1 86ndash87 F49671 135631 dark-grey siltstone McFadden 3+ TWB 1 104ndash105 F49672 135632 dark-grey siltstone Cornelia 3+ TWB 1 121ndash122 F49673 135633 dark-grey siltstone Cornelia 4 TWB 2 14ndash15 F49674 135634 dark-grey siltstone Skates Hills 3+ TWB 6 49ndash50 F49675 135675 dark-grey siltstone Cornelia 1 3+ TWB 9 49ndash51 F49676 135704 dark-grey siltstone Brassey Range 1 3+ Trainor 1 37497- F49733 138939 black mudstone with Cornelia 5 37509 light-grey siltstone Trainor 1 3809 F49734 138940 dark-grey and black Cornelia 4- laminated mudstone Trainor 1 4170 F49735 138941 black unlaminated mudstone Cornelia 4- Trainor 1 4950 F49851 139501 dark-grey indurated siltstone Cornelia 5 Trainor 1 6032 F49852 139502 dark- and light-grey Cornelia 5 indurated siltstone Trainor 1 6434 F49853 139503 greenish indurated finely Cornelia 5 laminated siltstone LDDH 1 270 F49678 138934 dark-grey siltstone interbeds Waters 1 3+ in enterolithic evaporite Tarcunyah Gp LDDH 1 277 F49679 138935 dark-grey siltstone in cavity Waters 1 3+ in enterolithic evaporite Tarcunyah Gp
NOTES (a) GSWA Fossil Catalogue number (b) TAI = Thermal Alteration Index of Traverse (1988 plate 1)
48
Appendix 4
Savory Sub-basin quantitative magnetic and gravity interpretation (extracted from Cowan 1995)
Summary
A program of quantitative aeromagnetic interpretation has been completed on BMRAGSO data from the Savory Sub-
basin Western Australia Quantitative aeromagnetic interpretation utilized the 3D Euler deconvolution method
supported by wavenumber filtering and image processing The results have provided useful information on structural
trends and depth to magnetic sources in a structurally complex area Depth to magnetic source analysis has provided
information on intra-sedimentary magnetic sources as well as basement rocks
The results of the interpretation support previously identified depocentres However the presence of magnetic
sources at several levels makes it very difficult to produce a reliable magnetic basement depth contour map It is
considered more productive to work with the 3D Euler colour circle plots and images rather than trying to contour the
results It would be necessary to carry out a full-scale interpretation of the BMRAGSO profile data to improve on the
3D Euler results The regional gravity was found to be useful in interpreting the regional setting of the area although
the very wide data spacing limits quantitative use of the data The gravity data show quite a complex picture with
limited consistent correlation between gravity features and basin structures This suggests that gravity anomalies
reflect changes in density of the basement rocks rather than basement topography especially in the northern part of the
basin
It is recommended that the GSWA investigate access to company confidential high-resolution aeromagnetic data
prior to planning further aeromagnetic surveys Private companies have flown large parts of the northern half of the
area as part of their diamond exploration program Additional gravity coverage of the area may be more cost effective
than magnetic surveys as the gravity data provides more information on changes within the sedimentary section
Introduction
The main use of aeromagnetic data in petroleum exploration has been the determination of magnetic basement
topography although there has been increasing interest in analysis of intra-sedimentary magnetic anomalies
intrabasement and suprabasement magnetic anomalies These anomalies are used to determine depth to magnetic
basement rocks and hence determine the thickness of the sedimentary sequence Unfortunately interpretation of the
intrabasement and suprabasement magnetic anomalies is non-unique in terms of position and size of causative sources
because of the inherent ambiguity of potential-field methods However this ambiguity can be reduced by placing
49
constraints on source geometry and magnetization and by using geological and other geophysical data to constrain
the solution
Before 1970 most depth-determination techniques involved graphical determination of slopes of selected
magnetic anomalies and application of various empirical factors to convert the slopes into depth estimates Geological
Society of America Memoir 47 Interpretation of Aeromagnetic Maps by Vacquier et al (1951) was a landmark for
this type of interpretation
Automated interpretation procedures have played an increasingly important role in depth interpretation and a
wide range of techniques have been developed Many of these techniques are designed for application to located data
profiles and assume a two-dimensional geometry However there has been renewed interest in techniques applicable
to gridded data
Two distinct types of method can be recognized In the first case often described as discrete methods individual
isolated magnetic anomalies are interpreted and the results used to produce a map of basement relief In the second
case often described as continuous methods areas of data containing a number of anomalies are interpreted
statistically to produce direct output of basement depths
The discrete methods usually involve a semiautomatic initial phase which generates a large number of possible
depth solutions and an interactive second phase to screen and select acceptable solutions The advantage of this
approach is that the interpreter can select features that are relatively free from interference from adjacent anomalies
and consider all aspects of a particular magnetic anomaly The disadvantage is that interpretation can be very time
consuming as a wide range of depths are usually possible depending on the initial model chosen and a significant
amount of effort is needed to select the correct model In the case of the Savory Sub-basin dataset we encountered
problems in separating basement related effects from the effects of shallower intrasedimentary magnetic sources
Because of these problems we have concentrated on displaying the Euler results accompanied by separation filter
images of the data to show the shallower effects and deeper effects rather than trying to refine a 3D Euler
deconvolution depth-to-crystalline-basement contour
The continuous methods are very direct provided that the rather restrictive assumption can be made that all
anomalies are due to lateral magnetization changes due to basement topography This means that shallow effects and
large intrabasement anomalies must be removed from the data This involves judgement and skill as it is necessary to
distinguish between the lower amplitude suprabasement anomalies due to basement topography and the larger
intrabasement anomalies reflecting magnetization changes within the basement These methods were not considered
suitable for the Savory Sub-basin magnetic dataset but were used to invert the gravity data
50
Limitations of magnetic and gravity interpretation
Interpretation of the area is limited by a shortage of information on the nature and physical properties of the deeper
sedimentary sequence and the underlying basement rocks However using techniques such as cross-correlation of
gravity and pseudo-gravity data it is possible to try to differentiate between anomalies relating to basement and those
related to the sedimentary sequence
Gravity anomalies reflect changes within the sedimentary sequence as well as basement condition These
changes in density of sedimentary rocks produce gravity anomalies without a corresponding magnetic anomaly hence
the complementary nature of gravity and magnetic surveys The main use of magnetics is to determine depth to
magnetic basement and any intra-sedimentary volcanic rocks or intrusives whereas gravity provides much more
general information on the sedimentary sequence
Unfortunately interpretation of gravity anomalies is complicated since they can be due to a number of geological
features including
bull major basement faults
bull basement highs
bull igneous intrusions within the basement
bull sedimentary basins which may or may not be isostatically compensated
bull intra-sedimentary volcanics and associated plutonic centres
Two major problems affect the interpretation of both magnetic and gravity data
1 The inherent ambiguity of potential-field data There is no unique solution to any measured gravity or magnetic
anomaly and theoretically there will be an infinite number of source geometry and magnetizationdensity
combinations which will fit the observed data This means that any a priori information which helps to select a
suitable model is very useful
2 Measured anomalies are the summation of effects from different depths For example an observed gravity profile
may contain contributions from shallow sources (density variations within the sedimentary basin) intermediate
depth sources (density variations due to large igneous intrusions within the basement) and deep sources (crustal
thinning producing a mantle anomaly) Separation of these component responses is the regionalresidual problem
which we solve using spectral analysis and differential upward continuation-based separation filtering
Regional setting and interpretation overview
The area studied includes parts of BALFOUR DOWNS (SF51-9) RUDALL (SF51-10) ROBERTSON (SF51-13) GUNANYA
(SF51-14) COLLIER (SG50-4) BULLEN (SG51-1) TRAINOR (SG51-2) MADLEY (SG51-3) NABBERU (SG50-5)
STANLEY (SG51-6) and HERBERT (SG51-7) 1250 000 sheets Broadly the area lies between latitudes 22deg00rsquondash25deg30rsquoS
and longitudes 119deg30rsquondash123deg30rsquoE
51
Regional gravity
The AGSO regional gravity data (at nominal 11 km spacing) was gridded at a 4 km mesh spacing using a minimum-
curvature algorithm Bouguer gravity values in the area are negative reflecting mass deficiency at depth and range
from -84 mgals to -25 mgals
A Bouguer gravity colour image is shown as Figure 41 A residual grid was produced by removing a fifth-order
orthogonal polynomial from the Bouguer data but did not add to the interpretation
120deg 121deg 122deg 123deg
23deg
24deg
25deg
-25
-84
50 km
MKS46 180598
mgal
Figure 41 Regional Bouguer gravity (BMRAGSO data) gridded at 4 km
52
The data show a complex pattern of positive and negative anomalies with no clearly defined trends Correlations
with aeromagnetic data and known basin structures are poor A vague north-northwest linear trend appears to coincide
with the Marloo Fault (Figure 42) A prominent negative anomaly appears to coincide with the Blake Fold and Fault
Belt depocentre and continues as a narrower negative anomaly to the east until it widens out again near the edge of the
basin Elsewhere the gravity data show little correlation with known basin structures and it is likely that especially in
the north of the area gravity anomalies are due to density changes in the basement rather than changes in basement
topography
Production of wavelength-filtered residual gravity plots and vertical gradient plots showed very patchy aliased
data reflecting poor sampling in much of the area
Regional magnetics
The AGSO regional aeromagnetic data were gridded at a 400 m mesh spacing using a minimum-curvature algorithm
(Figure 43) Most of the data has a line spacing of 1600 m with small areas of 1 km spacing The quality of the data is
acceptable for regional interpretation but is not adequate for detailed analysis The accuracy of the flight path is rather
variable reflecting the vintage of the data and the noise envelope of the data is poor by modern standards Problems
were also encountered in joining different map sheets
The magnetic anomaly pattern over the south and west part of the area shows a strong high frequency signature
reflecting the presence of widespread basic sills and dykes Some of the major north-northeasterly trending dykes can
be traced over considerable distances
Discontinuous high-frequency anomalies extend as a northwest-trending zone through the centre of the area and
this zone includes a conspicuous circular magnetic anomaly which is probably a ring complex
The northern and eastern parts of the area are characterized by long-wavelength deep-seated basement magnetic
anomalies with 120deg and 150deg trends dominant The Marloo and Perentie Faults (Figure 42) appear as distinct linear
zones and offsets A prominent easterly trending negative anomaly in the northwest of the area appears to swing round
to the southeast and may separate different basement blocks One possible interpretation is that this very deep seated
anomaly separates areas of Archaean and Proterozoic basement
Regional geology
The regional geology is described in Williams (1992) The GSWA provided a digitized version of Plate 2 from this
Bulletin the structural interpretation map to use as an overlay (Figure 42)
53
Pp
Pp
PSd
PSd
PSd
PSd
PSd
PSo
PSt
PSt
PSf
PSf
PSf
PSb
PSb
PSb
PSsPSs
PSs
PSb
PSm
PSp
PSc
PSc
PSw
PSw
PSw
PSg
PSr
PSj
PSg
PM
Pk
PY
PY
PSd
L
L
L
L
L
L
L
LL
L
L
L
LL
L
LL
L L
LL
L L
L
L
L
L
L
L
L
LL
L
L
BLAKEDEPOCENTRE
MA
RLO
O
FAU
LT
PERENTIEFAULT
50 km
MKS39120598
120deg 121deg 122deg 123deg
25deg
24deg
23deg
Approximate boundaryof aeromagnetic interpretation
PML
PSgL
PSjL
PML
PSpL
PML
PML
PSfL
PSfL
PSpL
LPc
LPcLPcPSrL
LPA
Durba Sandstone
Woora Woora Formation
McFadden Formation
Tchukardine Formation
Boondawari Formation
Skates Hills Formation
Mundadjini Formation
Coondra Formation
Spearhole Formation
Watch Point Formation
Jilyili Formation
Brassey Range Formation
Glass Spring Formation
Paterson Formation
Yeneena Group
Karara Formation
Cornelia Formation
Kahrban Subgroup
Bangemall Group
Fault
Formation boundary
PSdL
PSoL
PSfL
PStL
PSbL
PSsL
PSmL
PScL
PSpL
PSwL
PSjL
PSrL
PSgL
Pp
PYL
PkL
LPc
LPA
PML
Savory Group Other Units
PYL
Figure 42 Regional geology and structure map (after Williams 1992)
54
120deg 121deg 122deg 123deg
23deg
24deg
25deg
5820
3750
MKS47 180598
nT
50 km
Figure 43 Regional aeromagnetic data total magnetic intensity (BMRAGSO data) gridded at 400 m
Analysis
3D analysis
3D Euler deconvolution was used as the primary depth-determination method The advantage of this approach is that
consistent solutions can be obtained over the entire area with minimal assumptions about source geometries Euler
deconvolution of gridded data is used for positional information and estimation of depth to top of source Euler
55
deconvolution yields a large number of depth solutions which have to be screened to reject spurious solutions Results
are plotted as circles in eight depth ranges with radius proportional to depth and colour coded
The 400 m total magnetic intensity grid was used for the analysis Horizontal gradients in x and y and the vertical
gradient were calculated 3D Euler deconvolution was tested on the 400 m gridded data using windows of 9 times 9 and
11 times 11 and 16 times 16 data points and structural indices 05 (fault) and 10 (sill or dyke) It was concluded that the
16 times 16 window produced the best results overall and final plots were produced for the 16 times 16 window and structural
index 05 (Fig 44) Results were very good over the northern and central parts of the area showing magnetic sources
Figure 44 Depth to magnetic source 3D Euler deconvolution 16 times 16 window of 400 m gridded data structural index 05
56
at several different levels Unfortunately in the extreme south of the area shallow intrasedimentary magnetic sources
(sills and dykes) dominated the inversion and the results contained few basement solutions
In order to reduce these problems the 400 m gridded data were filtered using a separation filter based on
interpretation of the log-energy spectrum The 3D Euler method was run on the filtered data in order to generate more
basement-depth solutions Results for the deep-separation filter data were gridded and presented as a colour image in
Cowan (1995) Attempts to grid the Euler output were unsatisfactory and it is considered safer to interpret the 3D
Euler depth plots The 3D Euler depth results from the separation-filter run should be analysed with care as perfect
separation of the basement can never be achieved and there will always be some contamination from sources at
different levels
The results of original total magnetic intensity 3D Euler depth estimation for structural index 05 using a 16 point
window have been plotted at 1500 000 scale (not included in this publication but available in Cowan (1995) from the
GSWA Library as S10331) and as reduced A4 colour circle plots (Figure 44)
The results of deep-basement 3D Euler depth estimation for structural index 05 using a 16 point window have
been plotted as a colour image at 1500 000 scale and as an A4 image (not included in this publication)
2D analysis
Two equispaced profiles were interpolated with a 50 m station interval from the AGSO-located data profiles for the
BULLEN 1250 000 sheet The interpolated profiles were analysed using 2D Euler deconvolution and Werner
deconvolution Results are included in Cowan (1995) and show the use of these methods for more detailed analysis
Filtered data
In order to reconcile 3D Euler results from shallow basement and intrasedimentary magnetic sources we produced
several separation-filtered maps and images We found the shallow-layer double-separation filter (Figure 45) to be
very effective for shallow sources and the deep-layer standard-separation filter (Figure 46) for the basement layer
Gravity and magnetic data correlation
Both lsquoreduced to the polersquo (RTP) magnetics (Figure 47) and pseudo-gravity data (Figure 48) were produced as part of
the reconciliation of gravity and magnetic signatures In both cases the filtering operations assumed magnetization by
induction in the present Earths field The RTP data are fairly similar to the total magnetic intensity The pseudo-
57
gravity data are dominated by a northwest-trending strong positive anomaly and there is little correlation with the
Bouguer gravity data
The poor magneticgravity correlation is confirmed by cross-correlation of the RTP magnetics and the gravity
gradient The correlation plot in Figure 49 shows little coherent response with numerous zones of positive and
negative correlation
Figure 45 Regional aeromagnetic data shallow layer separation filter (BMRAGSO data) gridded at 400 m
Results
In the north and east of the area on the Wells Foreland Sub-basin trend (refer to Figure 1 main text) we see a range
of quite deep 3D Euler depths and several trend directions with north-northwesterly dominant There are relatively few
shallow intrasedimentary solutions in this zone
The second area of deep 3D Euler solutions lies over the Blake depocentre (Figure 43) with several trend
directions
Elsewhere the 3D Euler results are dominated by shallow intrasedimentary depth solutions reflecting mainly the
dolerite sills dykes and the ring complex However where we do see basement-related solutions in the south and
west of the area they appear to be shallower than those noted for the Wells Foreland Sub-basin and the Blake
depocentre
58
Figure 46 Regional aeromagnetic data deep-layer separation filter (BMRAGSO data) gridded at 400 m
Figure 48 Regional aeromagnetic data pseudo-gravity transform (BMRAGSO data) gridded at 400 m
Figure 47 Regional aeromagnetic data reduced-to-pole (BMRAGSO data) gridded at 400 m
Figure 49 Regional aeromagnetic and gravity data gravitymagnetic correlation using RTP magnetics and gravity gradient (BMRAGSO data) gridded at 4 km
59
This subdivision of the area into two zones of deep solutions is consistent with interpreted depocentres
However the interference between sources at different levels and the complexity of the magnetic response of the
basement rocks precludes more refined interpretation at this stage
The area of deep 3D Euler solutions over the Blake depocentre correlates with the pronounced negative gravity
anomaly discussed in the gravity interpretation section Using a density contrast of -015 gcc the negative gravity
anomaly could indicate up to 6ndash8 km of low-density sedimentary rocks depending on assumptions about the regional
field
The area of deep 3D Euler solutions over the Wells Foreland Sub-basin has a complex gravity expression and no
clear basin structure emerges from inversion of these data As noted previously it is likely that observed gravity
anomalies reflect contrasts in basement density rather than basement topography
Separation filtering applied to the magnetic data helps to enhance the intrasedimentary magnetic signature and to
give a better impression of the basement magnetic signature even though separation of the basement response is not
perfect
Conclusions
Quantitative aeromagnetic interpretation using 3D Euler deconvolution supported by wavenumber filtering and image
processing has been successful in providing structural trend and depth information for the Savory Sub-basin
Quantitative magnetic interpretation has revealed two zones of relatively deep magnetic basement beneath the
Wells Foreland Sub-basin and the Blake depocentre
This analysis of the magnetic data supports interpreted depocentres but the complexity of the basement magnetic
signature and interference from sources at different depths precludes further refinement to a map of basement
topography
Regional gravity proved to be very useful in understanding the regional setting of the area and in providing
support for aspects of the interpretation The gravity data support the interpretation of the Blake depocentre
suggesting up to 6ndash8 km of low-density sedimentary rocks
The deep structure of the Savory Sub-basin area is obviously complex with different areas underlain by
Archaean and Proterozoic basement and with the Capricorn suture occurring in the centre of the area
60
Recommendations
The quantitative magnetic interpretation needs to be reconciled with geological models available for the area
In particular the zones tentatively identified as areas with thick sedimentary rocks the Wells Foreland Sub-
basin and the Blake depocentre need to be investigated
Cross sections should be prepared across the basin for joint magneticgravity modelling especially for the Blake
depocentre It is important to be able to explain the strong negative gravity anomaly in this area
In view of the effects of basement density contrasts on the gravity field for the northern part of the area we think
that additional gravity interpretation and acquisition of new gravity data may not be justified as they will not
contribute significantly to understanding basin evolution and structure
It is recommended that GSWA try to get access to company confidential high-resolution aeromagnetic data
rather than flying new surveys The GSWA might offer to fund flying of new infill areas as a bargaining point
References
The original text of this report by Cowan (1995) and 1500 000 scale maps are filed in the GSWA Library under
S10331
COWAN D 1995 Savory Basin quantitative magnetic interpretation Western Australia Geological Survey S-series
S10331 (unpublished)
VACQUIER V STEENLAND N C HENDERSON R G and ZIETZ I 1951 Interpretation of aeromagnetic
maps The Geological Society of America Memoir 47 151p
WILLIAMS I R 1992 Geology of the Savory Basin Western Australia Western Australia Geological Survey
Bulletin 141 115p
61
Appendix 5
Geochemistry
MKS38 250398
Saturate FractionC12+ GLC
1217
Pr18
Ph
22
31CSR WELL-13 315m Cuttings
Figure 51 Canning Stock Route Well 13 gas chromatograph of extract of auger drill sample
12
17
18
22
31
Pr Ph
LDDH 1 6623m CoreSaturate FractionC12+ GLC
MKS35 240398
Figure 52 Gas chromatograph of extract from core sample at 6623 m LDDH1
62
Table 51 Canning Stock Route Well 13 auger drill samples
GSWA sample Drill depth (m)(a) Comments
135601 150 At watertable 135602 203 (all samples consist 135603 310 of sand mud and water) 135604 315 At total depth
NOTE (a) Datum for drill depth is the top of sediment fill in the well which is 155 m below ground level (ie the total depth of 315 m is 47 m below ground level)
Table 52 Canning Stock Route Well 13 gas chromatography data for 315 m depth sediment sample
Parameter Value
Weight of rock extracted (grams) 945 Total extract (ppm) 519 n-Alkane distribution n-C12 07 n-C13 23 n-C14 26 n-C15 22 n-C16 19 n-C17 14 i-C19 23 n-C18 14 i-C20 08 n-C19 11 n-C20 16 n-C21 25 n-C22 29 n-C23 70 n-C24 42 n-C25 95 n-C26 43 n-C27 83 n-C28 38 n-C29 87 n-C30 31 n-C31 273 Alkane compositional data Pristane phytane ratio 279 Pristane n-C17 ratio 161 Phytane n-C18 ratio 059 CPI (1)(a) 284 CPI (2) 209 (C21 + C22) (C28 + C29) 043
NOTE (a) CPI= Carbon preference index
63
Table 53 LDDH1 extract liquid chromatography data for 6623 m concentration
Rock extracted Total extract (grams) (ppm)
702 313
NOTE ppm= parts per million
Table 54 LDDH1 saturate gas chromatography data of core for 6623 m alkane composition
Pristane Pristane Phytane (a) CPI (1) CPI (2) (C21+C22) Phytane n-C17 n-C18 (C28+C29)
103 026 024 103 102 325
NOTE (a)CPI = carbon preference index
Table 55 LDDH1 saturate gas chromatography data of core for 6623 m n-alkane distributions
Parameter Value
n-C12 17 n-C13 38 n-C14 55 n-C15 60 n-C16 65 n-C17 74 i-C19 19 n-C18 78 i-C20 19 n-C19 80 n-C20 79 n-C21 71 n-C22 64 n-C23 57 n-C25 43 n-C24 38 n-C27 31 n-C28 23 n-C29 19 n-C30 12 n-C31 10
64
Appendix 6
Table 61 Summary of data from Trainor waterbores (TWB) and Bullen waterbores (BWB)
Well AMG Elevation TD Status(b) Completion details Water Salinity Water level Flow rate Depth to consolidated AGD84 GL (m) (m) struck mgl(c) (m) (LHr) lithology aquifer(e) Z51(a) Interval (m) (100 mm PVC) (m) (mgl)(d)
TWB 1 473660E 453 122 comp 0ndash75 plain 63 7 300 24 2 880 12 m 7287404N 75ndash93 slotted (9 260) McFadden Fm 93ndash99 plain TWB 2 472 977E 475 23 abd nil 15 m 7285877N Skates Hills Fm dry TWB 3 473259E 475 50 abd nil 7 m 7285849N Skates Hills Fm dry TWB 4 463225 E 445 50 comp 0ndash22 plain 35 7 200 55 3 600 0 m 7286143N 22ndash34 slotted (8 140) Tertiary sand and gravel 23ndash60 plain TWB 5 463095E 445 31 comp 0ndash19 plain 13 26 000 655 3 600 Tertiary sand and gravel 7277721N 19ndash25 slotted (36 700) 25ndash31 plain TWB 6 457013E 455 50 comp 0ndash42 plain 38 920 119 600 0 m 7274352N 42ndash48 slotted (1 030) Cornelia Fm ss TWB 7 453739E 475 26 susp 0ndash2 plain 11 9 300 48 4 500 0 m 7263891N (10 500) Tertiary sand TWB 8 433893E 535 60 susp 0ndash2 plain 47 8 500 gt46 1 200 0 m 7245991N (10 900) Tertiary sand and Brassey Range Fm ss TWB 9 437219E 505 51 comp 0ndash47 plain 45 1 000 58 600 1 m 7235905N 47ndash51 slotted (990) Brassey Range Fm ss TWB 10 434927E 495 32 susp 0ndash2 plain 235 450 120 0 m 7225875N (500) Dolerite
65
BWB 1 287337E 580 122 abd Nil 1 m 7245861N Jilyili Fm dry BWB 2 288346E 545 50 comp 0ndash26 plain 15 630 3 29 000 0 m 7240423N 26ndash38 slotted (730) Tertiary sand and gravel 38ndash50 plain BWB 3 305637E 545 50 abd 19 8 800 43 7 200 0 m 7240423N (10 550) Tertiary ss BWB 4 320167E 515 445 comp 0ndash20 plain 9 980 445 24 000 0 m 7248097N 20ndash32 slotted (1 190) Tertiary ss 32ndash44 plain BWB 5 353393E 545 20 susp 0ndash2 plain 45 (970) 1 m 7238934N Basalt
NOTES (a) GPS accuracy ~ 150 m (b) Comp = completed abd = abandoned susp = suspended (c) Salinity from conductivity (d) Analysis total dissolved solids (e) Fm = Formation ss = sandstone
18
The sub-basin is subdivided into three principal structural areas (Fig 1) Trainor Platform
Blake Fault and Fold Belt and Wells Foreland Sub-basin (Williams 1992) A major review of
these boundaries is beyond the scope of this report but the processing of regional aeromagnetic
data (Appendix 4) and acquisition of a semi-detailed gravity survey by the GSWA in the east of
the sub-basin has enabled these tectonic units to be reassessed and some modifications are
proposed
The Wells Foreland Sub-basin (originally termed the Wells Foreland Basin in Williams 1992)
and sedimentary rocks of the Tarcunyah Group are both considered to be the northwest
continuation of the Gibson Sub-basin of the Officer Basin Aeromagnetic gravity and outcrop
data suggest that the Blake Fault and Fold Belt is significantly faulted and folded in the west but
is less deformed in the east where the thickest sedimentary section in is located on BULLEN
(Appendix 4) The Trainor Platform is reinterpreted to represent an area of the sub-basin that has
undergone major compression during the Petermann Ranges Orogeny resulting in folding and
faulting with a northwest strike This interpretation contrasts with that proposed by Williams
(1992) who envisaged that only a thin section of the Savory Group was present on the platform
Perincek (1998) has recognized nine periods of tectonic activity in the Officer Basin from the
beginning of the Neoproterozoic to the end of the Cretaceous Three major tectonic episodes are
recognized in the Centralian Superbasin The oldest event is the Areyonga Movement which is
pre-Sturtian and forms the boundary between Supersequences 1 and 2 (Fig 4) The Souths Range
Movement occurred at the end of the Sturtian at the boundary between Supersequences 2 and 3
The youngest major event is the Petermann Ranges Orogeny which occured at the end of the
Marinoan and forms the boundary between Supersequences 3 and 4
One minor and two major tectonic episodes are recognized in the Savory Sub-basin the
LP1ALP1B structural event and the Areyonga Movement and the Petermann Ranges Orogeny
respectively The LP1ALP1B structural event is revealed where the Spearhole Formations rests
disconformably and locally unconformably on the Brassey Range Jilyili and Glass Spring
Formations The Neoproterozoic Areyonga Movement (equivalent to the Blake Movement of
Williams 1992) produced folds and faults with a general northeast strike in the western and
southern parts of the region The Souths Range Movement has not been recognized in the sub-
basin This may be due to the fact that no Sturtian glacial rocks have been identified and hence it
is possible that structures attributed to the Areyonga Movement could be the result of the Souths
Range Movement or a combination of the two movements
The major tectonic event recorded in the sub-basin is the latest Neoproterozoic to Cambrian
Petermann Ranges Orogeny (equivalent to the Paterson Orogeny) which produced large reverse
19
faults thrusts strike-slip faults and folds with a general northwest strike The McFadden
Formation and other Supersequence 4 strata are considered to be at least partially coeval with this
orogeny (Williams 1992) We also interpret the Durba Sandstone as having been deposited during
the later stages of the Petermann Ranges Orogeny as this unit mildly deformed with fold axes
parallel to the strike of other structures attributed to the Petermann Ranges Orogeny
Quantitative aeromagnetic interpretation of the Savory Sub-basin utilizing the 3D Euler
deconvolution method supported by wave-number filtering and image processing has provided
structural trends and depth to magnetic source within the sub-basin (Cowan 1995) Gravity data
are interpreted by Cowan (1995) as changes in both the density of the basement rocks andor
basement topography depending on local conditions Part of Cowanrsquos report is reproduced in
Appendix 4
Exploration history
The only petroleum exploration conducted in the sub-basin has been the recent drilling in the
western part of three diamond drillholes of which two have minor oil shows (Table 2) There has
been some mineral exploration the results of which are stored in the GSWA Western Australian
Mineral Exploration (WAMEX) database system Much of the mineral exploration was in the
southwest and west where the sub-basin is in contact with the Bangemall Basin and along the
northern margin of the sub-basin Many of these mineral exploration programs included
aeromagnetic surveys and surface geochemical sampling (Fig 8)
Hydrocarbon potential
The sub-basin contains a sedimentary succession up to 8 km thick which is generally gently
folded and faulted and apparently unmetamorphosed Limited drilling has shown that thick
mudstones are present in the sub-basin with some mudstones in Trainor 1 having high Total
Organic Carbon (TOC) values Outcrops of sub-friable sandstones in many of the formations
within the sub-basin suggests widespread reservoir potential Mudstone and inferred thick
evaporite sequences are likely to form seals Maturity data suggest that near-surface samples are
approximately at the base of the oil window and top of the gas window in parts of the north and
southeast of the sub-basin However parts of the southwest of the sub-basin and the mudstones in
Trainor 1 have very high levels of maturity Numerous faults and folds have been identified from
surface mapping suggesting good potential for large structural traps Minor oil shows in
20
Table 2 Neoproterozoic formations and hydrocarbon shows in diamond drillholes in the Savory Sub-basin
Drillhole AMG Core TD (m) Approx Formation Depth Formation Depth Formation Depth Shows (AGD84) start (m) GL (m) (m) (m) (m)
LDDH 1 431148E 112 701 350 Tarcunyah 68ndash701 ndash ndash bitumen at 6623 m 7443826N Group Trainor 1 473640E 6 709 455 McFadden 9ndash83 Cornelia Fm 83ndash709 possible bitumen at 4537 m 7287400N Fm Mundadjini 1 319056E 170 600 500 Mundadjini 16ndash361 Spearhole Fm 361ndash600 10 fluorescence at 36102 m 7404844N Fm Boondawari 1 348959E 299 1 367 490 Mundadjini Fm 15ndash312 Spearhole Fm 312ndash1 283 Intrusive 1 283ndash1 367 40 fluorescence at 35364 m 5 7398174N fluorescence at 4963 m Akubra 1 334249E 15 181 530 Mundadjini 15ndash42 Intrusive 42ndash181 None 7401252N Fm
21
50 km
120deg 121deg30 123deg
25deg
24deg
23deg
22deg
Greater Officer Basin
Savory Sub-basin
1
2
3
4
6
8
3 Seismic line (prefixed N83-00)
Aeromagnetic survey
GS
WA
Sav
ory
1995
gra
vity
sur
vey
Gravity survey
MKS34270398
Figure 8 Locations of aeromagnetic and gravity surveys (other than regional BMRAGSO data)
22
sandstones in two petroleum wells in the northwest of the sub-basin and bitumen and oil shows
elsewhere in the region indicate that oil has been generated and migrated through the sub-basin
Source rocks
Source potential is considered to be the major exploration risk in the Savory Sub-basin although
minor oil shows in Mundadjini 1 and Boondawari 1 indicate that at least some oil has been
generated and migrated into potential reservoirs within the sub-basin Sandstone is the
predominant lithology observed in outcrop Outcrops of fine-grained lithologies in the basin are
rare because of intense surface weathering and erosion Only about 8 of the surface area of the
sub-basin is exposed bedrock and recessive lithologies (such as shale evaporite and friable
sandstone) may be present although they rarely outcrop
Outcrops of stromatolitic dolomite with associated cauliflower chert and cubic pseudomorphs
interpreted as being after halite indicate that evaporitic environments are present within the
Mundadjini Skates Hills and Boondawari Formations Evaporitic minerals are also present in
drillhole LDDH1 in the Tarcunyah Group
In 1995 GSWA drilled a continuous-core diamond drillhole (Trainor 1) in the sub-basin on
TRAINOR to a depth of 709 m to test for source rocks thus providing the first such data for the sub-
basin The drillhole intersected flat-lying clastics and carbonates of the McFadden Formation (9ndash
83 m) overlying indurated mudstones of the Cornelia Formation (83ndash709 m total depth) dipping at
about 40deg Of the six samples analysed from the Cornelia Formation in this drillhole the five
located between 375 and 6032 m depth have TOC values exceeding 05 (range 066ndash365)
Rock-Eval pyrolysis of these five samples indicates that they are at best in the dry-gas thermal
stage and as a result of their high level of maturation (Stevens and Adamides in prep) have poor
remaining hydrocarbon-generating potential Although the Cornelia Formation is overmature at
Trainor 1 the high TOC values are encouraging as it is likely that this sequence is less mature
elsewhere in the sub-basin
The Mundadjini Formation contains potential source rocks that comprise marine mudstones
with evaporitic minerals present in parts Thin dark mudstones were intersected in the Mundadjini
Formation in Akubra 1 In Mundadjini 1 and Boondawari 1 however the mudstones appear to be
too oxidized to have source potential
The Boondawari Formation also may be a source rock as it contains black mudstones The
unit is laterally equivalent to the Pertatataka Formation of the Amadeus Basin and the Ungoolya
23
Group of the Officer Basin in South Australia both of which have some source potential
(Summons and Powell 1991 Morton and Drexel 1997) Samples from the Dey Dey Mudstone of
the Ungoolya Group generally have poor TOC values (average 011 range 003ndash081)
moderate hydrogen index (HI) values (100ndash382) and poor to fair genetic potential with a
maximum of 292 kg hydrocarbon per tonne of source rock (Morton and Drexel 1997)
Stromatolitic dolomites and mudstones at the top of the Boondawari Formation and within the
Skates Hills Formation are potential source rocks Stromatolitic dolomite and evaporitic rocks
deposited in a marginal marine to sabkha environment are considered to have good potential to
generate and preserve organic carbon without requiring a deep-water setting (Stevens and Grey
1997) Such conditions are recognized in the Skates Hills Formation and in the upper parts of the
Tarcunyah Group
Maturity
Knowledge of the maturity of sedimentary rocks within the Savory Sub-basin is still limited From
a review of palynological studies Grey and Stevens (1997) report that the thermal maturity
inferred from the Thermal Alteration Index (TAI) of 3+ from Supersequence 1 age palynomorphs
in TWB 6 TWB 9 and LDDH1 is within the hydrocarbon window (Appendix 3) In Phanerozoic
spores and pollen a TAI of 3+ approximately equates to the end of liquid petroleum generation
and the start of dry gas generation and to a vitrinite reflectance of about 13 (Traverse 1988)
However the use of TAI for estimating thermal maturity from Neoproterozoic palynomorphs
requires calibration
In Trainor 1 the Cornelia Formation contains organically rich claystones between 375 and
6032 m depth Based on Rock-Eval maturity data (Stevens and Adamides in prep) and the dark
colour of poorly preserved organic material (Grey 1995de 1996) with TAI 4- to 5 all samples
had a high level of maturation with at best dry-gas generating potential remaining In contrast
drillhole LDDH1 on GUNANYA recorded lower levels of maturity (TAI values of 3+) with two of
sixteen samples from the Tarcunyah Group having greater than 1 TOC (Grey 1995abc Grey
and Cotter 1996) Organic petrology and Rock-Eval maturity data for samples from LDDH1
indicate that the section above 500 m is within the oil-generative window whereas below 500 m
the rocks are within the gas window (Ghori in prep Fig 9 Appendix 5)
Waterbores TWB 1 2 6 and 9 which are located on TRAINOR in the southeast of the sub-
basin all had organic matter with TAI values of 3+ from the McFadden Skates Hills Cornelia
and Brassey Range Formations respectively
24
100
200
300
400
500
600
700
Oil
gene
ratin
g
Gas
gene
ratin
g
Fai
r
Fai
r
Poo
r
Poo
r
Goo
d
Imm
atur
e
Oil
win
dow
Oil
win
dow
Imm
atur
e
01 0110 10 0 150 300 440 480 1
Neo
prot
eroz
oic
TOC S1+S2 mgg Hydrogen Index Tmax degC
Depth(m)
Organicrichness
Generatingpotential
Kerogentype Maturity Maturity
TD=701m
Sandstone
Mudstone
Dolomite
Limestone
Evaporite
Source rock
MKS40 070498
Ro equivalent
Figure 9 Petroleum source potential of rocks in Normandy LDDH1
Small amounts of organic matter associated with basalt and dolerite in cuttings from
waterbore BWB 1 on BULLEN showed high levels of thermal maturity (Grey 1995a Libby 1995)
It is unclear whether all sedimentary rocks on BULLEN are overmature for hydrocarbon generation
or the results from BWB 1 are related to local heating events associated with the volcanic bodies
that are common in the Jilyili Formation
25
Reservoirs
Each of the five depositional sequences of the Savory Group (Table 1) are inferred to contain
significant sandstone reservoirs with the possible exception of depositional sequence C as
discussed above in Stratigraphy The Spearhole Formation was cored in Mundadjini 1 and
Boondawari 1 and visual estimates of porosity vary from generally poor (less than 5) to fair
(approximately 5ndash15) The McFadden Formation in Trainor 1 has porosity values of up to 232
and a maximum permeability of 195 md (Stevens and Adamides in prep) Sandstones from
Neoproterozoic formations form the acquifers in the following waterbores the McFadden
Formation in TWB 1 the Cornelia Formation in TWB 6 and the Brassey Range Formation in
TWB 8 and TWB 9 (Appendix 6 Table 61)
Based on outcrop observations the Durba Sandstone is considered to be the best reservoir of
the Savory Group Similarly some sandstones from the Tarcunyah Group also have good visible
porosity in outcrop
Dolomites occur in several formations in the sub-basin Reservoir potential may exist
particularly where the dolomites are stromatolitic and oolitic However dolomites have not been
drilled in the sub-basin and porosity can only be inferred from the preferential silicification of
some stromatolite bioherms observed in outcrop (Stevens and Grey 1997) Elsewhere in the
Officer Basin porosities of up to10 have been measured in dolomites A limestone breccia
(karst) is described from 663 to 677 m in drillhole LDDH1 (Fig 6 Busbridge 1994)
Seals
Indications of evaporitic environments in the Mundadjini Skates Hills and Boondawari
Formations are described by Williams (1992) In Mundadjini 1 from 287 to 337 m anhydrite and
chert occurs as nodules beds and veins in mudstone of the Mundadjini Formation Evaporitic
minerals (predominantly gypsum) are described in the Tarcunyah Group in LDDH1 The presence
of the Woolnough and Madley salt diapirs in the Officer Basin (approximately 110 km east of the
sub-basin) and halite beds over 25 m thick in the well Hussar 1 (130 km east of the sub-basin)
provide further evidence that evaporite seals may be present in the Savory Sub-basin
Mudstones and shales form only a small proportion of the limited Neoproterozoic outcrop in
the sub-basin but significant thicknesses of mudstone were encountered in the Mundadjini
Formation in Mundadjini 1 and Boondawari 1 the Tarcunyah Group in LDDH1 and in the
26
Cornelia Formation in Trainor 1 These data suggest that mudstones form a significant proportion
of strata in the sub-basin despite their limited outcrop
Traps
Potential structural closures including folds and faults occur at various scales throughout the
Savory Sub-basin However the region has only been mapped at 1250 000 scale and
independently closed structures such as domes have yet to be confirmed The western margin of
the basin contains abundant faults (with a northeast strike) but elsewhere faults are less common
Some anticlines are recognized in outcrop including one with a strike length of up to 45 km
inferred from surface bedding dips in the Mundadjini and Spearhole Formations at approximately
24deg15rsquoS 121deg10rsquoE on BULLEN (Fig 1)
Salt diapirs and other halokinetic structures are recognized in outcrop well and seismic data
in the Officer Basin to the west of the Savory Sub-basin and it is probable that there are
significant thicknesses of evaporitic sedimentary rocks in the sub-basin The gravity field data
suggest there is good potential for salt diapirs and traps related to halokinesis
Although there is potential for stratigraphic traps to be present in the sub-basin insufficient
data are available to assess them
Preservation of hydrocarbons
The range of thermal maturities measured to date and the large periods of time envisaged for
deposition of sediments implies hydrocarbon generation may have occurred a number of times
during the evolution of the Savory Sub-basin Any hydrocarbons that were generated early may
have been trapped in palaeostructures and remigration to younger traps could have taken place
later The Petermann Ranges Orogeny which has been equated with the Paterson Orogeny (Myers
1990) is believed to have occurred in the latest Neoproterozoic to early Cambrian This is the last
major tectonic event recognized in the sub-basin suggesting that it is reasonable to expect that trap
integrity will have been preserved
If the inference of the presence of thick halite beds in the sub-basin is correct the preservation
potential of sub-salt traps should be excellent
27
Reported hydrocarbon shows and oil seep
Amadeus Petroleum recorded minor oil shows in cores from Mundadjini 1 and Boondawari 1 In
Mundadjini 1 at 36102 m (top of the Spearhole Formation) a 3 mm thick zone had 10 moderate
white fluorescence with slow solvent cut This show was in a granular sandstone with visually
estimated porosity of about 10 In Boondawari 1 at 35364 m (within the Spearhole Formation) a
broken surface of sandstone had 40 moderate yellow-white fluorescence with slow solvent cut
Visually estimated porosity is about 5 Because the fluorescing surface was broken during the
drilling process this show could have resulted from contamination A second show occurs in
Boondawari 1 at 4963 m (within the Spearhole Formation) where a 1 cm-thick zone had 5 dull
yellow fluorescence with slow solvent cut in a conglomerate with visually estimated porosity of
about 10 The company intends to further investigate the nature of these occurrences
Minor bitumen is present at 6623 m in drillhole LDDH1 on GUNANYA (Figs 5 and 6) as a
vein in mudstones of the Tarcunyah Group A sample was analysed by gas chromatography
(Ghori in prep) and confirmed that it is natural bitumen (Appendix 5)
Mineral hole OD 23 drilled by Jubilee Gold Mines NL on NABBERU in the Bangemall Basin
immediately to the south of the Savory Sub-basin (Fig 5) encountered bitumen and trace oil in
vugs in dolomite (M Stevens unpublished data) but no further data are available at present
In their popular guide to the Canning Stock Route Gard and Gard (1990 p 218) refer to an
oil seep at Well 13 on TRAINOR (Fig 5) They reported that between 1977 and 1984 lsquonatural oilrsquo
was seen in the well Although the well is now largely filled with sediment four auger drill
samples were collected by the GSWA in 1995 and all four were analysed for oil shows One
sample from 315 m total depth (GSWA sample 135604) yielded just enough extract (519 ppm)
for saturate gas chromatography analysis The gas chromatograph (Appendix 5) shows that the
extract does contain some hydrocarbons probably from recent plant material Because the depth to
the oil was not quoted in Gard and Gard (1990) the hand-augered well may not have been deep
enough to properly test this reported seep
Geological and geophysical databases
Geological and geophysical data available for the Savory Sub-basin are limited The most recently
completed geological maps for the sub-basin were published by the GSWA between 1991 and
1995 (Williams and Tyler 1991 Williams 1992 1995ab)
28
The cores from the five drillholes listed in Table 2 believed to be all of the core available
from the sub-basin are available for inspection at GSWA Mineral exploration reports submitted
to GSWA may be searched using the WAMEX database and open-file reports are available on
microfiche Geophysical data acquired by the mining industry is not required to be filed with
GSWA if acquired over Vacant Crown Land which is the case for much of the sub-basin
Geophysical survey data submitted in mining tenement reports and which extend into Vacant
Crown Land remain confidential to the companies Original regional aeromagnetic and gravity
datasets are available from the Australian Geological Survey Organisation (AGSO)
Data pertinent to oil exploration in the sub-basin such as structural style and salt diapirism
are presented in a review of the hydrocarbon prospectivity of the Officer Basin (Perincek 1998)
Drilling
Significant drillholes in the sub-basin are summarized in Table 2
Petroleum industry data
Amadeus Petroleum drilled three petroleum exploration wells in the central west of the Savory
Sub-basin in late 1997 These wells Mundadjini 1 Boondawari 1 and Akubra 1 were drilled by
continuous diamond coring (Figs 5 and 6) All targeted potential reservoirs within the Spearhole
Formation with the Mundadjini Formation as the proposed seal The wells were located on
structures interpreted from Landsat images and limited geological investigations Both Mundadjini
1 and Boondawari 1 had minor oil shows as discussed above (Reported hydrocarbon shows)
Government data
Stratigraphic drillhole Trainor 1 was drilled by GSWA in 1995 (Stevens and Adamides in prep)
and the main results are discussed above (Source rocks and Maturity)
Mineral industry data
Normandy Exploration drillhole LDDH1 was cored in the Tarcunyah Group to a total depth of
701 m and provided source-rock and maturity data as discussed above
29
Oilmin NL drilled six percussion drillholes (BD 1 3 4 5 8 and 9) through sandstones and
shales in the northern part of the Savory Sub-basin to a maximum depth of 198 m (Fig 5
WAMEX Microfiche File M 26811 I 2610) but only brief geological descriptions are available
Hydrogeological data
Hydrogeological data within the Savory Sub-basin are limited although a long history of water
exploration extends back to the construction of the Canning Stock Route early this century No
detailed geological or wireline logs are available for the older wells along this route A few station
wells have been drilled by various methods on the south and west margins of the basin but data
are unavailable as reports are not required to be filed with the government Depth to watertable
throughout the basin is largely controlled by porosity of the bedrock
The GSWA drilled fifteen waterbores in the winter of 1995 in the southern part of the sub-
basin in preparation for the drilling of Trainor 1 and the proposed Bullen 1 Twelve bores found
water and six of these bores have salinities of less than 1000 mgL (Fig 5 Appendix 6 Table 61)
One waterbore TWB 6 has gamma ray and neutron logs run through PVC casing and these are
available from the GSWA with the digital log data included herein
Seismic data
No geophysical data have been acquired by the petroleum industry in the Savory Sub-basin
Seismic data acquired in the Officer Basin to the east particularly in the Gibson and Yowalga
Sub-basins is pertinent to structural interpretation in the Savory Sub-basin (Perincek 1996a
1998)
Aeromagnetic surveys
Government data
There are over 95 277 line kilometres of aeromagnetic data included in the AGSO dataset There
are three regional aeromagnetic surveys covering the Savory Sub-basin These were flown by the
Bureau of Mineral Resources (BMR now AGSO) in 1984 at a line spacing of 1500 m with 36 740
and 52 587 line kilometres flown and by Aerodata in 1984 at a line spacing of 1000m with 5950
line kilometres flown These data were reprocessed and interpreted for GSWA by Cowan (1995)
An edited copy of this report is included as Appendix 4 and the original report is filed in the
GSWA Library under S-series reports item 10331
30
Mineral industry data
The approximate locations of non-AGSO aeromagnetic surveys are shown in Figure 8 More
detailed information regarding the location of these surveys may be obtained using the GSWA
MAGCAT II database Additional information such as contours of aeromagnetic values may be
obtained by inspecting items on file with the GSWA
Gravity surveys
Government data
The average spacing for gravity data in the Savory Sub-basin is one station per 121 km2 (11 times 11
km grid) These data were principally collected by BMR in the early 1960s There are a few
additional regional gravity traverses across the sub-basin which are also included in the
BMRAGSO dataset These data were reprocessed and interpreted for GSWA (Fig 10) and a
report on this work is also included in Appendix 4
The GSWA completed a large semi-detailed gravity survey in the eastern Savory Sub-basin
utilizing helicopter support and Differential Global Positioning Survey (DGPS) techniques (Fig
8) This gravity survey completed in August 1995 consists of 2300 gravity stations on a 2 times 3 km
grid All stations were acquired by helicopter using Scintrex gravimeters and Ashtek dual
frequency DGPS equipment for determining location This highly efficient system allowed the
acquisition of more than 100 gravity stations per day in remote areas The resolution of this survey
is +30 cm and +05 microms-2 (Daishsat 1995) These data (Fig 11) represent a significant
improvement on the previous regional survey data and are available from GSWA (GSWA
1996ab) The results of the interpretation of these data were presented at the 1997 ASEG
Convention (Carlsen and Shevchenko 1997)
Mineral industry data
Three small gravity surveys were conducted by Oilmin NL (Fig 8) and the relevant WAMEX
reports are M 2681I 2610 I 2435 I 2567 These three surveys are of limited value because height
control was provided by barometers only and the surveys were not tied to the national gravity grid
31
23deg
25deg
120deg 122deg
Trainor 1
SAVORY
SUB-BASIN
MKS54 160498
100 km
1995 SavoryGravity Survey
254
-1056
micromsec2
Figure 10 Regional Bouguer gravity map of the Savory Sub-basin
23deg
24deg
25deg
122deg30 123deg
TRAINOR 1
123deg30
50 km
MKS53 160498
-116
-626
micro msec2
Figure11 Detailed Bouguer gravity map of the
Savory 1995 Gravity Survey from the eastern Savory Sub-basin
32
Government and academic reports
Chronostratigraphy and geochemistry
The understanding of Neoproterozoic organic chemistry palynology and structural evolution is
essential to the interpretation of hydrocarbon prospectivity Pertinent reports are included in the
bibliography (Appendix 1) Unpublished palaeontology reports describe the palynology of wells in
the Savory Sub-basin (Grey 1995andashe 1996a) Grey and Cotter (1996) discussed the potential for
Neoproterozoic palynomorphs to provide a biostratigraphic framework and palaeoenvironmental
interpretation Grey and Stevens (1997) reviewed the results of palynological studies of wells
drilled in the sub-basin and reported that Supersequence 1 palynomorphs are present in TWB 6
TWB 9 and LDDH1 (Appendix 3) Grey (1996b) reported on the use of stromatolites for
correlation in the Neoproterozoic and Stevens and Grey (1997) discussed the application of
stromatolite biostratigraphy in correlating isolated dolomite outcrops in the sub-basin with well
and seismic data in the Officer Basin and Centralian Superbasin
Although geochemical data from the Savory Sub-basin are very limited results mostly
confirm thermal maturities inferred from TAI for LDDH1 and Trainor 1 (Ghori in prep Stevens
and Adamides in prep) Those parts of the Officer Basin in Western Australia which lie to the
east of the Savory Sub-basin are sparsely drilled but Ghori (in prep) reports that most of the
Neoproterozoic succession presently lies within the oil-generative window However his study
has been unable to identify effective source-rock units and the source for oil shows Thin source
rocks are present in the Neoproterozoic in LDDH1 (Fig 9) and in three wells which lie to the east
and southeast of the Savory Sub-basin namely NJD 1 Kanpa 1A and Yowalga 3
Proposed work program
From the above limited information it is concluded that additional research on the hydrocarbon
potential of the sub-basin is justified and proposals are outlined below
bull Additional modelling of gravity and aeromagnetic data from the Savory Sub-basin is required
in light of the results from Trainor 1 and Boondawari 1 Trainor 1 showed that what appeared
to be a structurally simple area based on outcrop aeromagnetic and gravity data was in fact an
area of major structuring Boondawari 1 intersected a dolerite which is in good depth
agreement with aeromagnetic depth to source results showing this technique is useful in
detecting the depth to intrusive bodies
33
bull Additional data from mineral and petroleum exploration bores may become available and
analysis of samples from these wells should be undertaken and interpreted in the context of
their relevance to the Officer Basin
bull Stratigraphic coring in the Blake Fault and Fold Belt and in the Wells Foreland Sub-basin (Fig
1) targeting source rocks is considered essential to the continuing evaluation of the
hydrocarbon prospectivity of the Savory Sub-basin
bull Correlations using at least outcrop well and potential-field data should be prepared to link the
sub-basin with the better known parts of the Officer Basin to the east
bull Remapping is required to clarify boundary positions within the Cornelia Formation this may
resolve some of the current problems of the relationship between this unit and the rest of the
Savory Sub-basin
bull Further work is required to explain the Early Cambrian or Sturtian ages interpreted for the
Cornelia Formation from sedimentary zircon UndashPb dating in drillhole Trainor 1 The
determination of the age of the organically rich but overmature claystones in this well is
critical to assessing the hydrocarbon potential of the region
bull The thin dark mudstones intersected by Akubra 1 in the Mundadjini Formation warrant
geochemical analysis Analyses of the oil shows in Mundadjini 1 and Boondawari 1 are
currently being undertaken by Amadeus Petroleum
bull Geochemical analysis of hydrocarbons in the Bangemall Basin drillhole OD23 has been
performed by Jubilee Gold and the results will be reviewed when they are submitted to
GSWA The possibility of source rocks within the Bangemall Basin charging traps within the
Bangemall Basin and the overlying Savory Sub-basin requires further investigation
Conclusions
The Savory Sub-basin is a frontier region with only three recently drilled petroleum exploration
wells and no seismic data Based on existing geological and geophysical data it is considered too
early to draw conclusions about the hydrocarbon prospectivity of the sub-basin at this stage and
there are several reasons why the area warrants further investigation
34
1 Thick accumulations of sedimentary rocks are present (up to 8 km thickness inferred) which
may contain source reservoir and sealing strata
2 Minor oil shows occur in Mundadjini 1 and Boondawari 1 and bitumen is present in mineral
exploration drillhole LDDH1 suggesting that hydrocarbons have migrated within the
Neoproterozoic sequence of the Savory Sub-basin Oil and bitumen are present in mineral
exploration drillhole OD23 in the Bangemall Basin immediately to the south of the Savory
Sub-basin and it is possible that source rocks from the Bangemall Basin could charge traps in
the overlying Savory Sub-basin
3 The age of sedimentary rocks in the sub-basin is still poorly constrained but some of the
Neoproterozoic sedimentary rocks located on GUNANYA and TRAINOR are within the
hydrocarbon-generation window It is possible that a significant thickness of Phanerozoic
sedimentary rocks may also be present
4 Friable sandstones with visible porosity outcrop extensively suggesting numerous potential
reservoirs
5 Significant but not intense faulting and folding has been mapped implying large structural
traps may be present
6 Evaporitic sedimentary rocks occur in several formations and may provide good source rocks
and excellent seals
35
References
APAK S N and CARLSEN G M 1997 A compilation and review of data pertaining to the
hydrocarbon prospectivity of the Canning Basin Western Australia Geological Survey
Record 199610 103p
BAGAS L GREY K and WILLIAMS I R 1995 Reappraisal of the Paterson Orogen and
Savory Basin Western Australia Geological Survey Annual Review 1994ndash95 p 55ndash63
BUSBRIDGE M 1994 Lake Disappointment Exploration Licence 451064 Third Annual
Report Lake Disappointment Diamond Drill Hole LDDH1 Normandy Exploration Limited
Western Australia Geological Survey M-series Item 7567 A41358 (unpublished)
CARLSEN G M and SHEVCHENKO S I 1997 Petroleum exploration in Proterozoic basins
using potential fields data and stratigraphic coring Australian Society of Exploration
Geophysicists 12th Geophysical Conference Handbook Sydney 1997 Preview no 66 p 83
(abstract only)
COWAN D 1995 Savory Basin quantitative magnetic interpretation Western Australia
Geological Survey S-series S10331 (unpublished)
DAISHSAT PTY LTD 1995 Operational and processing report Savory Basin gravity survey
Western Australia Geological Survey S-series S10332 (unpublished)
GARD E and GARD R 1990 Canning Stock Route a travellerrsquos guide for a journey through
history Perth Western Australia Western Desert Guides 448p
GEOLOGICAL SURVEY OF WESTERN AUSTRALIA 1996a Savory Basin first vertical
derivative of Bouguer gravity image 1250 000 Western Australia Geological Survey
GEOLOGICAL SURVEY OF WESTERN AUSTRALIA 1996b Savory Basin Bouguer gravity
image 1250 000 Western Australia Geological Survey
GHORI K A R in prep Petroleum source rock potential and thermal history Officer Basin
Western Australia Western Australia Geological Survey Record
36
GREY K 1995a Savory Basin drillhole BWB 1 (Bullen waterbore) palynology and thermal
maturation GSWA Palaeontology Report no 199512 (unpublished)
GREY K 1995b Savory Basin drillholes TWB 1 2 6 9 (Trainor waterbores) palynology and
thermal maturation GSWA Palaeontology Report no 199520 (unpublished)
GREY K 1995c Palynology of Normandy-Poseidon Lake Disappointment-1 corehole
Tarcunyah Group Paterson Orogen GSWA Palaeontology Report no 199521 (unpublished)
GREY K 1995d Savory Basin drillhole Trainor 1 (Trainor diamond drilling) palynology and
thermal maturity GSWA Palaeontology Report no 199524 (unpublished)
GREY K 1995e Savory Basin drillhole Trainor 1 (Trainor diamond drilling) Additional
Preparation of two samples GSWA Palaeontology Report no 199528 (unpublished)
GREY K 1995f Neoproterozoic stromatolites from the Skates Hills Formation Savory Basin
Western Australia and a review of the distribution of Acaciella australica Australian Journal
of Earth Sciences v 42 p 123ndash132
GREY K 1996a Savory Basin drillhole Trainor 1 (Trainor diamond drilling) Additional
samples palynology and thermal maturation GSWA Palaeontology Report no 199615
(unpublished)
GREY K 1996b Preliminary stromatolite correlations for the Neoproterozoic of the Officer
Basin and a review of Australia-wide correlations GSWA Palaeontology Report no 199615
(unpublished)
GREY K and COTTER K L 1996 Palynology in the search for Proterozoic hydrocarbons
Western Australia Geological Survey Annual Review for 1995ndash96 p 70ndash80
GREY K and STEVENS M K 1997 Neoproterozoic palynomorphs of the Savory Sub-basin
Western Australia and their relevance to petroleum exploration Western Australia
Geological Survey Annual Review for 1996ndash97 p 49ndash54
HUBBARD R J PAPE J and ROBERTS D G 1985 Depositional sequence mapping as a
technique to establish tectonic and stratigraphic framework and evaluate hydrocarbon
potential on a passive continental margin in Seismic stratigraphy II an integrated approach
37
edited by O R BERG and D G WOOLVERTON American Association of Petroleum
Geologists Memoir 39 p 79ndash91
LIBBY WG 1995 A petrological report on six samples of bore cuttings from the Savory Basin
Western Australia Western Australia Geological Survey S-series S31307 (unpublished)
MORTON JGG and DREXEL JF 1997 The petroleum geology of South Australia Vol 3
Officer Basin South Australia Department of Mines and Energy Resources Report Book
9719
MUHLING P C and BRAKEL A T 1985 Geology of the Bangemall Group mdash the evolution
of an intracratonic Proterozoic basin Western Australia Geological Survey Bulletin 128
219p
MYERS J S 1990 Precambrian tectonic evolution of part of Gondwana southwestern Australia
Geology v18 p 537ndash540
NELSON D R 1997 Compilation of SHRIMP UndashPb zircon data Western Australia Geological
Survey Record 19972 196p
PAYTON C E 1977 Seismic stratigraphy mdash applications to hydrocarbon exploration
American Association of Petroleum Geologists Memoir 26 516p
PERINCEK D 1996a The age of NeoproterozoicndashPalaeozoic sediments within the Officer Basin
of the Centralian Super-basin can be constrained by major sequence-bounding unconformities
APPEA Journal v 36 pt 1 p 350ndash368
PERINCEK D 1996b The stratigraphic and structural development of the Officer Basin
Western Australia a review Western Australia Geological Survey Annual Review 1995ndash
1996 p 135ndash148
PERINCEK D 1998 A compilation and review of data pertaining to the hydrocarbon
prospectivity of the Officer Basin Western Australia Geological Survey Record 19976
POSAMENTIER H W JERSEY M T and VAIL P R 1988 Eustatic controls on clastic
deposition 1 mdash Conceptual framework in Sea-level changes an integrated approach edited by
C K WILGUS B S HASTINGS C G St C KENDALL H W POSAMENTIER
38
C A ROSS and J C VAN WAGONER Society of Economic Paleontologists and
Mineralogists Special Publication no 42
STEVENS M K and ADAMIDES N G in prep GSWA Trainor 1 well completion report
Savory Sub-basin Officer Basin Western Australia with notes on petroleum and mineral
potential Western Australia Geological Survey Record 199612
STEVENS M K and GREY K 1997 Skates Hills Formation and Tarcunyah Group Officer
Basin mdash carbonate cycles stratigraphic position and hydrocarbon prospectivity Western
Australia Geological Survey Annual Review for 1996ndash97 p 55ndash60
SUMMONS RE and POWELL C McA 1991 Petroleum source rocks of the Amadeus Basin
in Geological and geophysical studies in the Amadeus Basin central Australia edited by R J
KORSCH and JM KENNARD Australia BMR Geology and Geophysics Bulletin 236
TRAVERSE A 1988 Palaeopalynology Boston Unwin Hyman 600p
VAIL P R MITCHUM R M Jr TODD R G WIDMIER J M THOMPSON S III
SANGREE J B BUBB J N and HATLELID W G 1977 Seismic stratigraphy and
global changes of sea level in Seismic stratigraphy mdash applications to hydrocarbon
exploration edited by C E PAYTON American Association of Petroleum Geologists
Memoir 26 516p
WALTER M R and GORTER J 1994 The Neoproterozoic Centralian Superbasin in Western
Australia the Savory and Officer Basins in The sedimentary basins of Western Australia
edited by P G PURCELL and R R PURCELL Petroleum Exploration Society of Australia
Symposium Perth WA 1994 Proceedings p851ndash864
WALTER M R GREY K WILLIAMS I R and CALVER C R 1994 Stratigraphy of the
Neoproterozoic to early Palaeozoic Savory Basin and correlation with the Amadeus and
Officer Basins Australian Journal of Earth Sciences v 41 p 533ndash546
WALTER M R VEEVERS J J CALVER C R and GREY K 1995 Neoproterozoic
stratigraphy of the Centralian Superbasin Australia Precambrian Research v 73 p 173ndash195
WILLIAMS I R 1992 Geology of the Savory Basin Western Australia Western Australia
Geological Survey Bulletin 141 115p
39
WILLIAMS I R 1995a Bullen WA (2nd Edition) Western Australia Geological Survey
1250 000 Geological Series Explanatory Notes 23p
WILLIAMS I R 1995b Trainor WA (2nd Edition) Western Australia Geological Survey
1250 000 Geological Series Explanatory Notes 31p
WILLIAMS I R and TYLER I M 1991 Robertson WA (2nd edition) Western Australia
Geological Survey 1250 000 Geological Series Explanatory Notes 36p
40
41
Appendix 1
Bibliography
Reports which are relevant to this investigation but which are not specifically cited are listed
below
BAILLIE P W POWELL C McA LI Z X and RYALL A M 1994 The tectonic
framework of Western Australiarsquos Neoproterozoic to recent sedimentary basins in The
sedimentary basins of Western Australia edited by P G PURCELL and R R PURCELL
Petroleum Exploration Society of Australia Symposium Perth WA 1994 Proceedings p
45ndash62
BRADSHAW M T BRADSHAW J MURRAY A P NEEDHAM D J SPENCER L
SUMMONS R E WILMOT J and WINN S 1994 Petroleum systems in West Australian
basins in The sedimentary basins of Western Australia edited by P G PURCELL and R R
PURCELL Petroleum Exploration Society of Australia Symposium Perth WA 1994
Proceedings p 93ndash118
CLARKE G L 1991 Proterozoic tectonic reworking in the Rudall Complex Western Australia
Australian Journal of Earth Science v38 p 31ndash44
COCKBAIN A E and HOCKING R M 1990 Phanerozoic in Geology and mineral resources
of Western Australia Western Australia Geological Survey Memoir 3 p 750ndash755
ETHERIDGE M and WALL V 1994 Tectonic and structural evolution of the Australian
Proterozoic 12th Australian Geological Convention Geological Society of Australia
Abstracts no 37 p 102ndash103
GOODE A D T 1981 Proterozoic geology of Western Australia in Precambrian of the
Southern Hemisphere Developments in Precambrian geology 2 edited by I R HUNTER
Amsterdam Elsevier p 105ndash203
GREY K and JACKSON M J 1983 A re-assessment of stromatolite evidence for the
correlation of the Late Proterozoic Neale and Ilma Beds Officer Basin Western Australia
Australia BMR Journal of Australian Geology and Geophysics v 8 p 359
42
HICKMAN A H WILLIAMS I R and BAGAS L 1994 Proterozoic geology and
mineralization of the TelferndashRudall region Paterson Orogen Geological Society of Australia
(WA Division) Excursion Guidebook no 5 56p
HOCKING R M MORY A J and WILLIAMS I R 1994 An atlas of Neoproterozoic and
Phanerozoic basins of Western Australia in The sedimentary basins of Western Australia
edited by P G PURCELL and R R PURCELL Petroleum Exploration Society of Australia
Symposium Perth WA 1994 Proceedings p 21ndash 44
JACKSON P R 1966 Geology and review of exploration Officer Basin Western Australia
Hunt Oil Company Western Australia Geological Survey S-series S26 (unpublished)
JACKSON M J 1971 Notes on a geological reconnaissance of the Officer Basin Western
Australia Australia BMR Geology and Geophysics Record 19715 30p
JACKSON M J and van de GRAAFF W J E 1981 Geology of the Officer Basin Western
Australia Australia BMR Geology and Geophysics Bulletin 206 102 p
LOWRY D C JACKSON M J van de GRAAFF W J E and KENNEWELL P J 1971
Preliminary result of geological mapping in the Officer Basin Western Australia Western
Australia Geological Survey Annual Report for 1971 p 50ndash56
MYERS J S 1990 Precambrian in Geology and mineral resources of Western Australia
Western Australia Geological Survey Memoir 3 p 737ndash750
MYERS J S SHAW R D and TYLER I M 1994 Proterozoic tectonic evolution of
Australia 12th Australian Geological Convention Geological Society of Australia Abstracts
no 37 p 312
NEDIN C and JENKINS R J F 1991 Re-evaluation of unconformities separating the
lsquoEdiacaranrsquo and Cambrian systems South Australia Palaios v 6 p 102ndash108
PHILLIPS B J JAMES A W and PHILIP G M 1985 The geology and hydrocarbon
potential of the north-western Officer Basin APEA Journal 25 (1) p 52ndash61
POWELL C McA LI Z X McELHINNY M W MEERT J G and PARK J K 1993
Paleomagnetic constraints on timing of the Neoproterozoic breakup of Rodinia and Cambrian
formation of Gondwana Geology v 21 p 889ndash892
43
POWELL C McA PREISS W V GATEHOUSE C G KRAPEZ B and LI Z X 1994
South Australian record of a Rodinian epicontinental basin and its mid-Neoproterozoic
breakup to form the Palaeo-Pacific Ocean Tectonophysics v 237 no 3ndash4 p 113ndash140
PREISS W V 1976 Proterozoic stromatolites from the Nabberu and Officer Basins Western
Australia and their biostratigraphic significance South Australia Geological Survey Report
of Investigations no 47 p 1ndash51
TOWNSON W G 1985 The subsurface geology of the western Officer Basin mdash results of
Shellrsquos 1980ndash1984 petroleum exploration campaign APEA Journal v 25 (1) p 34ndash51
WATTS K J 1982 The geology of the Townsend Quartzite Upper Proterozoic shallow water
deposit of the Northern Officer Basin Western Australia Perth University of Western
Australia BSc honours thesis (unpublished)
WELLS A T and KENNEWELL P J 1974 Evaporite exploration in the Officer Basin
Western Australia at the Madley Diapirs Australia BMR Record 1974194 (unpublished)
WILLIAMS I R and MYERS J S 1990 Paterson Orogen in Geology and mineral resources
of Western Australia Western Australia Geological Survey Memoir 3 p 274ndash286
WILLIAMS I R 1990 Savory Basin in Geology and mineral resources of Western Australia
Western Australia Geological Survey Memoir 3 p 329ndash334
WILLIAMS I R 1994 The Neoproterozoic Savory Basin Western Australia in The
sedimentary basins of Western Australia edited by P G PURCELL and R R PURCELL
Petroleum Exploration Society of Australia Symposium Perth WA 1994 Proceedings p
841ndash850
WILSON R B 1967 Woolnough Hills and Madley diapiric structures Gibson Desert WA
APEA Journal v 7 p 94ndash102
44
Appendix 2
Meteorological data (from Bureau of Meteorology Perth 1994)
Table 21 Wiluna rainfall (mm)
Year Jan Feb Mar Apr May Jun Jul Aug Sept Oct Nov Dec
1975 0 45 446 309 306 59 276 4 34 886 638 164 1976 16 154 12 138 53 16 34 62 12 238 0 2 1977 44 0 66 74 68 95 24 363 1 58 12 727 1978 234 522 94 16 0 96 367 24 16 353 185 45 1979 19 173 122 88 91 4 0 246 58 0 169 114 1980 148 764 68 1081 259 626 629 06 56 02 174 0 1981 123 476 192 32 196 118 44 74 14 0 28 312 1982 374 705 206 244 1079 92 02 143 368 526 368 118 1983 1 112 928 248 0 212 56 32 5 1 42 496 1984 149 7 342 84 836 0 348 132 224 04 16 172 1985 596 483 0 166 556 0 514 56 0 0 4 0 1986 0 154 35 0 0 1085 23 01 239 137 0 04 1987 1204 119 19 89 17 575 154 126 07 1 0 398 1988 46 202 164 13 388 0 202 104 0 0 224 1309 1989 207 234 26 703 278 536 57 0 01 0 144 02 1990 1035 23 281 46 126 53 94 218 44 9 42 0 1991 48 0 41 45 0 472 297 12 0 1 0 7 1992 112 96 1025 1227 323 65 04 174 0 132 48 4 1993 0 697 0 202 445 0 12 306 18 05 14 33 Mean 25 35 22 27 27 25 18 12 6 13 13 21
JAN FEB MAR APR MAY JUN JUL AUG SEP OCT NOV DEC0
10
20
30
40
Mea
n R
ain
fall
(mm
)
Month
Mean monthly rainfall in Wiluna
MKS41 140498
45
Table 22 Wiluna minimum temperature (degC)
Year Jan Feb Mar Apr May Jun Jul Aug Sept Oct Nov Dec
1975 ndash 23 203 15 94 63 71 62 103 124 169 205 1976 242 229 194 15 10 63 59 73 95 143 16 228 1977 243 25 197 148 96 95 56 86 102 ndash 188 23 1978 241 232 203 18 102 64 76 8 9 152 19 205 1979 255 226 216 167 83 6 59 79 97 145 198 223 1980 255 226 231 155 134 83 68 75 121 108 193 223 1981 245 216 19 182 119 6 54 78 138 159 163 218 1982 232 224 177 16 ndash ndash 37 111 112 164 209 225 1983 235 24 197 147 112 88 39 88 121 162 189 219 1984 241 243 191 156 ndash 72 66 7 95 161 182 211 1985 244 231 ndash 159 98 65 71 73 117 147 205 ndash 1986 ndash 229 226 155 93 96 43 49 10 122 ndash 219 1987 ndash 217 183 175 85 77 68 68 112 ndash ndash 221 1988 238 214 209 178 111 ndash ndash 86 104 157 171 195 1989 ndash 237 199 165 107 67 44 61 107 131 187 ndash 1990 232 ndash 211 155 118 62 57 87 102 149 195 22 1991 26 256 217 168 122 101 78 ndash 113 18 168 219 1992 227 227 214 169 102 98 59 69 ndash 125 159 196 1993 241 218 196 171 103 ndash 49 68 88 128 192 211 Mean 24 23 20 16 10 8 6 8 11 14 18 21
NOTE Dashes indicate data unavailable
JAN FEB MAR APR MAY JUN JUL AUG SEP OCT NOV DEC0
10
20
30
40
Month
MKS43 140498
50
Mean monthly minimum temperatures at Wiluna
Mea
n T
emp
erat
ure
(degC
)
46
Table 23 Wiluna maximum temperature (degC)
Year Jan Feb Mar Apr May Jun Jul Aug Sept Oct Nov Dec
1975 ndash 349 326 281 247 201 197 212 256 248 31 344 1976 374 369 346 297 248 206 208 225 265 287 313 388 1977 397 392 352 296 234 212 222 244 ndash 308 337 383 1978 378 345 346 316 242 195 176 205 231 295 334 356 1979 403 36 364 295 ndash ndash ndash 193 242 318 359 373 1980 392 342 377 275 24 176 179 233 292 288 349 391 1981 385 346 337 342 242 178 201 224 30 326 326 369 1982 372 359 315 307 ndash ndash 196 253 252 305 353 379 1983 381 389 327 272 263 222 187 248 287 321 336 366 1984 378 393 322 299 226 215 178 214 234 ndash 336 364 1985 40 366 ndash 294 224 216 205 212 284 307 355 ndash 1986 ndash 383 372 307 ndash 193 166 196 261 277 ndash 382 1987 ndash 339 328 305 21 202 214 218 275 ndash ndash 374 1988 388 365 353 301 23 ndash ndash 228 283 334 31 33 1989 ndash 375 339 285 238 179 181 219 275 298 336 ndash 1990 368 ndash 36 309 268 19 188 205 274 309 373 393 1991 414 416 363 315 268 206 21 ndash 279 338 332 368 1992 363 383 336 263 213 178 213 197 ndash 285 313 359 1993 396 357 344 301 221 ndash 197 215 253 294 347 362 Mean 39 37 34 30 24 20 20 22 27 30 34 37 NOTE Dashes indicate data unavailable
JAN FEB MAR APR MAY JUN JUL AUG SEP OCT NOV DEC0
10
20
30
40
Month
MKS42 140498
50
Mean monthly maximum temperatures at Wiluna
Mea
n T
emp
erat
ure
(degC
)
47
Appendix 3
Table 31 Summary of palynological results
Drillhole Depth (m) F no(a) GSWA no Lithology Formation Assemblage TAI(b)
BWB 1 74ndash75 F49668 135741 dark-grey siltstone basalt Jilyilli gt5 BWB 1 98ndash100 F49669 135742 dark-grey siltstone basalt Jilyilli gt5 BWB 1 121ndash122 F49670 135743 dark-grey siltstone basalt Jilyilli gt5 TWB 1 86ndash87 F49671 135631 dark-grey siltstone McFadden 3+ TWB 1 104ndash105 F49672 135632 dark-grey siltstone Cornelia 3+ TWB 1 121ndash122 F49673 135633 dark-grey siltstone Cornelia 4 TWB 2 14ndash15 F49674 135634 dark-grey siltstone Skates Hills 3+ TWB 6 49ndash50 F49675 135675 dark-grey siltstone Cornelia 1 3+ TWB 9 49ndash51 F49676 135704 dark-grey siltstone Brassey Range 1 3+ Trainor 1 37497- F49733 138939 black mudstone with Cornelia 5 37509 light-grey siltstone Trainor 1 3809 F49734 138940 dark-grey and black Cornelia 4- laminated mudstone Trainor 1 4170 F49735 138941 black unlaminated mudstone Cornelia 4- Trainor 1 4950 F49851 139501 dark-grey indurated siltstone Cornelia 5 Trainor 1 6032 F49852 139502 dark- and light-grey Cornelia 5 indurated siltstone Trainor 1 6434 F49853 139503 greenish indurated finely Cornelia 5 laminated siltstone LDDH 1 270 F49678 138934 dark-grey siltstone interbeds Waters 1 3+ in enterolithic evaporite Tarcunyah Gp LDDH 1 277 F49679 138935 dark-grey siltstone in cavity Waters 1 3+ in enterolithic evaporite Tarcunyah Gp
NOTES (a) GSWA Fossil Catalogue number (b) TAI = Thermal Alteration Index of Traverse (1988 plate 1)
48
Appendix 4
Savory Sub-basin quantitative magnetic and gravity interpretation (extracted from Cowan 1995)
Summary
A program of quantitative aeromagnetic interpretation has been completed on BMRAGSO data from the Savory Sub-
basin Western Australia Quantitative aeromagnetic interpretation utilized the 3D Euler deconvolution method
supported by wavenumber filtering and image processing The results have provided useful information on structural
trends and depth to magnetic sources in a structurally complex area Depth to magnetic source analysis has provided
information on intra-sedimentary magnetic sources as well as basement rocks
The results of the interpretation support previously identified depocentres However the presence of magnetic
sources at several levels makes it very difficult to produce a reliable magnetic basement depth contour map It is
considered more productive to work with the 3D Euler colour circle plots and images rather than trying to contour the
results It would be necessary to carry out a full-scale interpretation of the BMRAGSO profile data to improve on the
3D Euler results The regional gravity was found to be useful in interpreting the regional setting of the area although
the very wide data spacing limits quantitative use of the data The gravity data show quite a complex picture with
limited consistent correlation between gravity features and basin structures This suggests that gravity anomalies
reflect changes in density of the basement rocks rather than basement topography especially in the northern part of the
basin
It is recommended that the GSWA investigate access to company confidential high-resolution aeromagnetic data
prior to planning further aeromagnetic surveys Private companies have flown large parts of the northern half of the
area as part of their diamond exploration program Additional gravity coverage of the area may be more cost effective
than magnetic surveys as the gravity data provides more information on changes within the sedimentary section
Introduction
The main use of aeromagnetic data in petroleum exploration has been the determination of magnetic basement
topography although there has been increasing interest in analysis of intra-sedimentary magnetic anomalies
intrabasement and suprabasement magnetic anomalies These anomalies are used to determine depth to magnetic
basement rocks and hence determine the thickness of the sedimentary sequence Unfortunately interpretation of the
intrabasement and suprabasement magnetic anomalies is non-unique in terms of position and size of causative sources
because of the inherent ambiguity of potential-field methods However this ambiguity can be reduced by placing
49
constraints on source geometry and magnetization and by using geological and other geophysical data to constrain
the solution
Before 1970 most depth-determination techniques involved graphical determination of slopes of selected
magnetic anomalies and application of various empirical factors to convert the slopes into depth estimates Geological
Society of America Memoir 47 Interpretation of Aeromagnetic Maps by Vacquier et al (1951) was a landmark for
this type of interpretation
Automated interpretation procedures have played an increasingly important role in depth interpretation and a
wide range of techniques have been developed Many of these techniques are designed for application to located data
profiles and assume a two-dimensional geometry However there has been renewed interest in techniques applicable
to gridded data
Two distinct types of method can be recognized In the first case often described as discrete methods individual
isolated magnetic anomalies are interpreted and the results used to produce a map of basement relief In the second
case often described as continuous methods areas of data containing a number of anomalies are interpreted
statistically to produce direct output of basement depths
The discrete methods usually involve a semiautomatic initial phase which generates a large number of possible
depth solutions and an interactive second phase to screen and select acceptable solutions The advantage of this
approach is that the interpreter can select features that are relatively free from interference from adjacent anomalies
and consider all aspects of a particular magnetic anomaly The disadvantage is that interpretation can be very time
consuming as a wide range of depths are usually possible depending on the initial model chosen and a significant
amount of effort is needed to select the correct model In the case of the Savory Sub-basin dataset we encountered
problems in separating basement related effects from the effects of shallower intrasedimentary magnetic sources
Because of these problems we have concentrated on displaying the Euler results accompanied by separation filter
images of the data to show the shallower effects and deeper effects rather than trying to refine a 3D Euler
deconvolution depth-to-crystalline-basement contour
The continuous methods are very direct provided that the rather restrictive assumption can be made that all
anomalies are due to lateral magnetization changes due to basement topography This means that shallow effects and
large intrabasement anomalies must be removed from the data This involves judgement and skill as it is necessary to
distinguish between the lower amplitude suprabasement anomalies due to basement topography and the larger
intrabasement anomalies reflecting magnetization changes within the basement These methods were not considered
suitable for the Savory Sub-basin magnetic dataset but were used to invert the gravity data
50
Limitations of magnetic and gravity interpretation
Interpretation of the area is limited by a shortage of information on the nature and physical properties of the deeper
sedimentary sequence and the underlying basement rocks However using techniques such as cross-correlation of
gravity and pseudo-gravity data it is possible to try to differentiate between anomalies relating to basement and those
related to the sedimentary sequence
Gravity anomalies reflect changes within the sedimentary sequence as well as basement condition These
changes in density of sedimentary rocks produce gravity anomalies without a corresponding magnetic anomaly hence
the complementary nature of gravity and magnetic surveys The main use of magnetics is to determine depth to
magnetic basement and any intra-sedimentary volcanic rocks or intrusives whereas gravity provides much more
general information on the sedimentary sequence
Unfortunately interpretation of gravity anomalies is complicated since they can be due to a number of geological
features including
bull major basement faults
bull basement highs
bull igneous intrusions within the basement
bull sedimentary basins which may or may not be isostatically compensated
bull intra-sedimentary volcanics and associated plutonic centres
Two major problems affect the interpretation of both magnetic and gravity data
1 The inherent ambiguity of potential-field data There is no unique solution to any measured gravity or magnetic
anomaly and theoretically there will be an infinite number of source geometry and magnetizationdensity
combinations which will fit the observed data This means that any a priori information which helps to select a
suitable model is very useful
2 Measured anomalies are the summation of effects from different depths For example an observed gravity profile
may contain contributions from shallow sources (density variations within the sedimentary basin) intermediate
depth sources (density variations due to large igneous intrusions within the basement) and deep sources (crustal
thinning producing a mantle anomaly) Separation of these component responses is the regionalresidual problem
which we solve using spectral analysis and differential upward continuation-based separation filtering
Regional setting and interpretation overview
The area studied includes parts of BALFOUR DOWNS (SF51-9) RUDALL (SF51-10) ROBERTSON (SF51-13) GUNANYA
(SF51-14) COLLIER (SG50-4) BULLEN (SG51-1) TRAINOR (SG51-2) MADLEY (SG51-3) NABBERU (SG50-5)
STANLEY (SG51-6) and HERBERT (SG51-7) 1250 000 sheets Broadly the area lies between latitudes 22deg00rsquondash25deg30rsquoS
and longitudes 119deg30rsquondash123deg30rsquoE
51
Regional gravity
The AGSO regional gravity data (at nominal 11 km spacing) was gridded at a 4 km mesh spacing using a minimum-
curvature algorithm Bouguer gravity values in the area are negative reflecting mass deficiency at depth and range
from -84 mgals to -25 mgals
A Bouguer gravity colour image is shown as Figure 41 A residual grid was produced by removing a fifth-order
orthogonal polynomial from the Bouguer data but did not add to the interpretation
120deg 121deg 122deg 123deg
23deg
24deg
25deg
-25
-84
50 km
MKS46 180598
mgal
Figure 41 Regional Bouguer gravity (BMRAGSO data) gridded at 4 km
52
The data show a complex pattern of positive and negative anomalies with no clearly defined trends Correlations
with aeromagnetic data and known basin structures are poor A vague north-northwest linear trend appears to coincide
with the Marloo Fault (Figure 42) A prominent negative anomaly appears to coincide with the Blake Fold and Fault
Belt depocentre and continues as a narrower negative anomaly to the east until it widens out again near the edge of the
basin Elsewhere the gravity data show little correlation with known basin structures and it is likely that especially in
the north of the area gravity anomalies are due to density changes in the basement rather than changes in basement
topography
Production of wavelength-filtered residual gravity plots and vertical gradient plots showed very patchy aliased
data reflecting poor sampling in much of the area
Regional magnetics
The AGSO regional aeromagnetic data were gridded at a 400 m mesh spacing using a minimum-curvature algorithm
(Figure 43) Most of the data has a line spacing of 1600 m with small areas of 1 km spacing The quality of the data is
acceptable for regional interpretation but is not adequate for detailed analysis The accuracy of the flight path is rather
variable reflecting the vintage of the data and the noise envelope of the data is poor by modern standards Problems
were also encountered in joining different map sheets
The magnetic anomaly pattern over the south and west part of the area shows a strong high frequency signature
reflecting the presence of widespread basic sills and dykes Some of the major north-northeasterly trending dykes can
be traced over considerable distances
Discontinuous high-frequency anomalies extend as a northwest-trending zone through the centre of the area and
this zone includes a conspicuous circular magnetic anomaly which is probably a ring complex
The northern and eastern parts of the area are characterized by long-wavelength deep-seated basement magnetic
anomalies with 120deg and 150deg trends dominant The Marloo and Perentie Faults (Figure 42) appear as distinct linear
zones and offsets A prominent easterly trending negative anomaly in the northwest of the area appears to swing round
to the southeast and may separate different basement blocks One possible interpretation is that this very deep seated
anomaly separates areas of Archaean and Proterozoic basement
Regional geology
The regional geology is described in Williams (1992) The GSWA provided a digitized version of Plate 2 from this
Bulletin the structural interpretation map to use as an overlay (Figure 42)
53
Pp
Pp
PSd
PSd
PSd
PSd
PSd
PSo
PSt
PSt
PSf
PSf
PSf
PSb
PSb
PSb
PSsPSs
PSs
PSb
PSm
PSp
PSc
PSc
PSw
PSw
PSw
PSg
PSr
PSj
PSg
PM
Pk
PY
PY
PSd
L
L
L
L
L
L
L
LL
L
L
L
LL
L
LL
L L
LL
L L
L
L
L
L
L
L
L
LL
L
L
BLAKEDEPOCENTRE
MA
RLO
O
FAU
LT
PERENTIEFAULT
50 km
MKS39120598
120deg 121deg 122deg 123deg
25deg
24deg
23deg
Approximate boundaryof aeromagnetic interpretation
PML
PSgL
PSjL
PML
PSpL
PML
PML
PSfL
PSfL
PSpL
LPc
LPcLPcPSrL
LPA
Durba Sandstone
Woora Woora Formation
McFadden Formation
Tchukardine Formation
Boondawari Formation
Skates Hills Formation
Mundadjini Formation
Coondra Formation
Spearhole Formation
Watch Point Formation
Jilyili Formation
Brassey Range Formation
Glass Spring Formation
Paterson Formation
Yeneena Group
Karara Formation
Cornelia Formation
Kahrban Subgroup
Bangemall Group
Fault
Formation boundary
PSdL
PSoL
PSfL
PStL
PSbL
PSsL
PSmL
PScL
PSpL
PSwL
PSjL
PSrL
PSgL
Pp
PYL
PkL
LPc
LPA
PML
Savory Group Other Units
PYL
Figure 42 Regional geology and structure map (after Williams 1992)
54
120deg 121deg 122deg 123deg
23deg
24deg
25deg
5820
3750
MKS47 180598
nT
50 km
Figure 43 Regional aeromagnetic data total magnetic intensity (BMRAGSO data) gridded at 400 m
Analysis
3D analysis
3D Euler deconvolution was used as the primary depth-determination method The advantage of this approach is that
consistent solutions can be obtained over the entire area with minimal assumptions about source geometries Euler
deconvolution of gridded data is used for positional information and estimation of depth to top of source Euler
55
deconvolution yields a large number of depth solutions which have to be screened to reject spurious solutions Results
are plotted as circles in eight depth ranges with radius proportional to depth and colour coded
The 400 m total magnetic intensity grid was used for the analysis Horizontal gradients in x and y and the vertical
gradient were calculated 3D Euler deconvolution was tested on the 400 m gridded data using windows of 9 times 9 and
11 times 11 and 16 times 16 data points and structural indices 05 (fault) and 10 (sill or dyke) It was concluded that the
16 times 16 window produced the best results overall and final plots were produced for the 16 times 16 window and structural
index 05 (Fig 44) Results were very good over the northern and central parts of the area showing magnetic sources
Figure 44 Depth to magnetic source 3D Euler deconvolution 16 times 16 window of 400 m gridded data structural index 05
56
at several different levels Unfortunately in the extreme south of the area shallow intrasedimentary magnetic sources
(sills and dykes) dominated the inversion and the results contained few basement solutions
In order to reduce these problems the 400 m gridded data were filtered using a separation filter based on
interpretation of the log-energy spectrum The 3D Euler method was run on the filtered data in order to generate more
basement-depth solutions Results for the deep-separation filter data were gridded and presented as a colour image in
Cowan (1995) Attempts to grid the Euler output were unsatisfactory and it is considered safer to interpret the 3D
Euler depth plots The 3D Euler depth results from the separation-filter run should be analysed with care as perfect
separation of the basement can never be achieved and there will always be some contamination from sources at
different levels
The results of original total magnetic intensity 3D Euler depth estimation for structural index 05 using a 16 point
window have been plotted at 1500 000 scale (not included in this publication but available in Cowan (1995) from the
GSWA Library as S10331) and as reduced A4 colour circle plots (Figure 44)
The results of deep-basement 3D Euler depth estimation for structural index 05 using a 16 point window have
been plotted as a colour image at 1500 000 scale and as an A4 image (not included in this publication)
2D analysis
Two equispaced profiles were interpolated with a 50 m station interval from the AGSO-located data profiles for the
BULLEN 1250 000 sheet The interpolated profiles were analysed using 2D Euler deconvolution and Werner
deconvolution Results are included in Cowan (1995) and show the use of these methods for more detailed analysis
Filtered data
In order to reconcile 3D Euler results from shallow basement and intrasedimentary magnetic sources we produced
several separation-filtered maps and images We found the shallow-layer double-separation filter (Figure 45) to be
very effective for shallow sources and the deep-layer standard-separation filter (Figure 46) for the basement layer
Gravity and magnetic data correlation
Both lsquoreduced to the polersquo (RTP) magnetics (Figure 47) and pseudo-gravity data (Figure 48) were produced as part of
the reconciliation of gravity and magnetic signatures In both cases the filtering operations assumed magnetization by
induction in the present Earths field The RTP data are fairly similar to the total magnetic intensity The pseudo-
57
gravity data are dominated by a northwest-trending strong positive anomaly and there is little correlation with the
Bouguer gravity data
The poor magneticgravity correlation is confirmed by cross-correlation of the RTP magnetics and the gravity
gradient The correlation plot in Figure 49 shows little coherent response with numerous zones of positive and
negative correlation
Figure 45 Regional aeromagnetic data shallow layer separation filter (BMRAGSO data) gridded at 400 m
Results
In the north and east of the area on the Wells Foreland Sub-basin trend (refer to Figure 1 main text) we see a range
of quite deep 3D Euler depths and several trend directions with north-northwesterly dominant There are relatively few
shallow intrasedimentary solutions in this zone
The second area of deep 3D Euler solutions lies over the Blake depocentre (Figure 43) with several trend
directions
Elsewhere the 3D Euler results are dominated by shallow intrasedimentary depth solutions reflecting mainly the
dolerite sills dykes and the ring complex However where we do see basement-related solutions in the south and
west of the area they appear to be shallower than those noted for the Wells Foreland Sub-basin and the Blake
depocentre
58
Figure 46 Regional aeromagnetic data deep-layer separation filter (BMRAGSO data) gridded at 400 m
Figure 48 Regional aeromagnetic data pseudo-gravity transform (BMRAGSO data) gridded at 400 m
Figure 47 Regional aeromagnetic data reduced-to-pole (BMRAGSO data) gridded at 400 m
Figure 49 Regional aeromagnetic and gravity data gravitymagnetic correlation using RTP magnetics and gravity gradient (BMRAGSO data) gridded at 4 km
59
This subdivision of the area into two zones of deep solutions is consistent with interpreted depocentres
However the interference between sources at different levels and the complexity of the magnetic response of the
basement rocks precludes more refined interpretation at this stage
The area of deep 3D Euler solutions over the Blake depocentre correlates with the pronounced negative gravity
anomaly discussed in the gravity interpretation section Using a density contrast of -015 gcc the negative gravity
anomaly could indicate up to 6ndash8 km of low-density sedimentary rocks depending on assumptions about the regional
field
The area of deep 3D Euler solutions over the Wells Foreland Sub-basin has a complex gravity expression and no
clear basin structure emerges from inversion of these data As noted previously it is likely that observed gravity
anomalies reflect contrasts in basement density rather than basement topography
Separation filtering applied to the magnetic data helps to enhance the intrasedimentary magnetic signature and to
give a better impression of the basement magnetic signature even though separation of the basement response is not
perfect
Conclusions
Quantitative aeromagnetic interpretation using 3D Euler deconvolution supported by wavenumber filtering and image
processing has been successful in providing structural trend and depth information for the Savory Sub-basin
Quantitative magnetic interpretation has revealed two zones of relatively deep magnetic basement beneath the
Wells Foreland Sub-basin and the Blake depocentre
This analysis of the magnetic data supports interpreted depocentres but the complexity of the basement magnetic
signature and interference from sources at different depths precludes further refinement to a map of basement
topography
Regional gravity proved to be very useful in understanding the regional setting of the area and in providing
support for aspects of the interpretation The gravity data support the interpretation of the Blake depocentre
suggesting up to 6ndash8 km of low-density sedimentary rocks
The deep structure of the Savory Sub-basin area is obviously complex with different areas underlain by
Archaean and Proterozoic basement and with the Capricorn suture occurring in the centre of the area
60
Recommendations
The quantitative magnetic interpretation needs to be reconciled with geological models available for the area
In particular the zones tentatively identified as areas with thick sedimentary rocks the Wells Foreland Sub-
basin and the Blake depocentre need to be investigated
Cross sections should be prepared across the basin for joint magneticgravity modelling especially for the Blake
depocentre It is important to be able to explain the strong negative gravity anomaly in this area
In view of the effects of basement density contrasts on the gravity field for the northern part of the area we think
that additional gravity interpretation and acquisition of new gravity data may not be justified as they will not
contribute significantly to understanding basin evolution and structure
It is recommended that GSWA try to get access to company confidential high-resolution aeromagnetic data
rather than flying new surveys The GSWA might offer to fund flying of new infill areas as a bargaining point
References
The original text of this report by Cowan (1995) and 1500 000 scale maps are filed in the GSWA Library under
S10331
COWAN D 1995 Savory Basin quantitative magnetic interpretation Western Australia Geological Survey S-series
S10331 (unpublished)
VACQUIER V STEENLAND N C HENDERSON R G and ZIETZ I 1951 Interpretation of aeromagnetic
maps The Geological Society of America Memoir 47 151p
WILLIAMS I R 1992 Geology of the Savory Basin Western Australia Western Australia Geological Survey
Bulletin 141 115p
61
Appendix 5
Geochemistry
MKS38 250398
Saturate FractionC12+ GLC
1217
Pr18
Ph
22
31CSR WELL-13 315m Cuttings
Figure 51 Canning Stock Route Well 13 gas chromatograph of extract of auger drill sample
12
17
18
22
31
Pr Ph
LDDH 1 6623m CoreSaturate FractionC12+ GLC
MKS35 240398
Figure 52 Gas chromatograph of extract from core sample at 6623 m LDDH1
62
Table 51 Canning Stock Route Well 13 auger drill samples
GSWA sample Drill depth (m)(a) Comments
135601 150 At watertable 135602 203 (all samples consist 135603 310 of sand mud and water) 135604 315 At total depth
NOTE (a) Datum for drill depth is the top of sediment fill in the well which is 155 m below ground level (ie the total depth of 315 m is 47 m below ground level)
Table 52 Canning Stock Route Well 13 gas chromatography data for 315 m depth sediment sample
Parameter Value
Weight of rock extracted (grams) 945 Total extract (ppm) 519 n-Alkane distribution n-C12 07 n-C13 23 n-C14 26 n-C15 22 n-C16 19 n-C17 14 i-C19 23 n-C18 14 i-C20 08 n-C19 11 n-C20 16 n-C21 25 n-C22 29 n-C23 70 n-C24 42 n-C25 95 n-C26 43 n-C27 83 n-C28 38 n-C29 87 n-C30 31 n-C31 273 Alkane compositional data Pristane phytane ratio 279 Pristane n-C17 ratio 161 Phytane n-C18 ratio 059 CPI (1)(a) 284 CPI (2) 209 (C21 + C22) (C28 + C29) 043
NOTE (a) CPI= Carbon preference index
63
Table 53 LDDH1 extract liquid chromatography data for 6623 m concentration
Rock extracted Total extract (grams) (ppm)
702 313
NOTE ppm= parts per million
Table 54 LDDH1 saturate gas chromatography data of core for 6623 m alkane composition
Pristane Pristane Phytane (a) CPI (1) CPI (2) (C21+C22) Phytane n-C17 n-C18 (C28+C29)
103 026 024 103 102 325
NOTE (a)CPI = carbon preference index
Table 55 LDDH1 saturate gas chromatography data of core for 6623 m n-alkane distributions
Parameter Value
n-C12 17 n-C13 38 n-C14 55 n-C15 60 n-C16 65 n-C17 74 i-C19 19 n-C18 78 i-C20 19 n-C19 80 n-C20 79 n-C21 71 n-C22 64 n-C23 57 n-C25 43 n-C24 38 n-C27 31 n-C28 23 n-C29 19 n-C30 12 n-C31 10
64
Appendix 6
Table 61 Summary of data from Trainor waterbores (TWB) and Bullen waterbores (BWB)
Well AMG Elevation TD Status(b) Completion details Water Salinity Water level Flow rate Depth to consolidated AGD84 GL (m) (m) struck mgl(c) (m) (LHr) lithology aquifer(e) Z51(a) Interval (m) (100 mm PVC) (m) (mgl)(d)
TWB 1 473660E 453 122 comp 0ndash75 plain 63 7 300 24 2 880 12 m 7287404N 75ndash93 slotted (9 260) McFadden Fm 93ndash99 plain TWB 2 472 977E 475 23 abd nil 15 m 7285877N Skates Hills Fm dry TWB 3 473259E 475 50 abd nil 7 m 7285849N Skates Hills Fm dry TWB 4 463225 E 445 50 comp 0ndash22 plain 35 7 200 55 3 600 0 m 7286143N 22ndash34 slotted (8 140) Tertiary sand and gravel 23ndash60 plain TWB 5 463095E 445 31 comp 0ndash19 plain 13 26 000 655 3 600 Tertiary sand and gravel 7277721N 19ndash25 slotted (36 700) 25ndash31 plain TWB 6 457013E 455 50 comp 0ndash42 plain 38 920 119 600 0 m 7274352N 42ndash48 slotted (1 030) Cornelia Fm ss TWB 7 453739E 475 26 susp 0ndash2 plain 11 9 300 48 4 500 0 m 7263891N (10 500) Tertiary sand TWB 8 433893E 535 60 susp 0ndash2 plain 47 8 500 gt46 1 200 0 m 7245991N (10 900) Tertiary sand and Brassey Range Fm ss TWB 9 437219E 505 51 comp 0ndash47 plain 45 1 000 58 600 1 m 7235905N 47ndash51 slotted (990) Brassey Range Fm ss TWB 10 434927E 495 32 susp 0ndash2 plain 235 450 120 0 m 7225875N (500) Dolerite
65
BWB 1 287337E 580 122 abd Nil 1 m 7245861N Jilyili Fm dry BWB 2 288346E 545 50 comp 0ndash26 plain 15 630 3 29 000 0 m 7240423N 26ndash38 slotted (730) Tertiary sand and gravel 38ndash50 plain BWB 3 305637E 545 50 abd 19 8 800 43 7 200 0 m 7240423N (10 550) Tertiary ss BWB 4 320167E 515 445 comp 0ndash20 plain 9 980 445 24 000 0 m 7248097N 20ndash32 slotted (1 190) Tertiary ss 32ndash44 plain BWB 5 353393E 545 20 susp 0ndash2 plain 45 (970) 1 m 7238934N Basalt
NOTES (a) GPS accuracy ~ 150 m (b) Comp = completed abd = abandoned susp = suspended (c) Salinity from conductivity (d) Analysis total dissolved solids (e) Fm = Formation ss = sandstone
19
faults thrusts strike-slip faults and folds with a general northwest strike The McFadden
Formation and other Supersequence 4 strata are considered to be at least partially coeval with this
orogeny (Williams 1992) We also interpret the Durba Sandstone as having been deposited during
the later stages of the Petermann Ranges Orogeny as this unit mildly deformed with fold axes
parallel to the strike of other structures attributed to the Petermann Ranges Orogeny
Quantitative aeromagnetic interpretation of the Savory Sub-basin utilizing the 3D Euler
deconvolution method supported by wave-number filtering and image processing has provided
structural trends and depth to magnetic source within the sub-basin (Cowan 1995) Gravity data
are interpreted by Cowan (1995) as changes in both the density of the basement rocks andor
basement topography depending on local conditions Part of Cowanrsquos report is reproduced in
Appendix 4
Exploration history
The only petroleum exploration conducted in the sub-basin has been the recent drilling in the
western part of three diamond drillholes of which two have minor oil shows (Table 2) There has
been some mineral exploration the results of which are stored in the GSWA Western Australian
Mineral Exploration (WAMEX) database system Much of the mineral exploration was in the
southwest and west where the sub-basin is in contact with the Bangemall Basin and along the
northern margin of the sub-basin Many of these mineral exploration programs included
aeromagnetic surveys and surface geochemical sampling (Fig 8)
Hydrocarbon potential
The sub-basin contains a sedimentary succession up to 8 km thick which is generally gently
folded and faulted and apparently unmetamorphosed Limited drilling has shown that thick
mudstones are present in the sub-basin with some mudstones in Trainor 1 having high Total
Organic Carbon (TOC) values Outcrops of sub-friable sandstones in many of the formations
within the sub-basin suggests widespread reservoir potential Mudstone and inferred thick
evaporite sequences are likely to form seals Maturity data suggest that near-surface samples are
approximately at the base of the oil window and top of the gas window in parts of the north and
southeast of the sub-basin However parts of the southwest of the sub-basin and the mudstones in
Trainor 1 have very high levels of maturity Numerous faults and folds have been identified from
surface mapping suggesting good potential for large structural traps Minor oil shows in
20
Table 2 Neoproterozoic formations and hydrocarbon shows in diamond drillholes in the Savory Sub-basin
Drillhole AMG Core TD (m) Approx Formation Depth Formation Depth Formation Depth Shows (AGD84) start (m) GL (m) (m) (m) (m)
LDDH 1 431148E 112 701 350 Tarcunyah 68ndash701 ndash ndash bitumen at 6623 m 7443826N Group Trainor 1 473640E 6 709 455 McFadden 9ndash83 Cornelia Fm 83ndash709 possible bitumen at 4537 m 7287400N Fm Mundadjini 1 319056E 170 600 500 Mundadjini 16ndash361 Spearhole Fm 361ndash600 10 fluorescence at 36102 m 7404844N Fm Boondawari 1 348959E 299 1 367 490 Mundadjini Fm 15ndash312 Spearhole Fm 312ndash1 283 Intrusive 1 283ndash1 367 40 fluorescence at 35364 m 5 7398174N fluorescence at 4963 m Akubra 1 334249E 15 181 530 Mundadjini 15ndash42 Intrusive 42ndash181 None 7401252N Fm
21
50 km
120deg 121deg30 123deg
25deg
24deg
23deg
22deg
Greater Officer Basin
Savory Sub-basin
1
2
3
4
6
8
3 Seismic line (prefixed N83-00)
Aeromagnetic survey
GS
WA
Sav
ory
1995
gra
vity
sur
vey
Gravity survey
MKS34270398
Figure 8 Locations of aeromagnetic and gravity surveys (other than regional BMRAGSO data)
22
sandstones in two petroleum wells in the northwest of the sub-basin and bitumen and oil shows
elsewhere in the region indicate that oil has been generated and migrated through the sub-basin
Source rocks
Source potential is considered to be the major exploration risk in the Savory Sub-basin although
minor oil shows in Mundadjini 1 and Boondawari 1 indicate that at least some oil has been
generated and migrated into potential reservoirs within the sub-basin Sandstone is the
predominant lithology observed in outcrop Outcrops of fine-grained lithologies in the basin are
rare because of intense surface weathering and erosion Only about 8 of the surface area of the
sub-basin is exposed bedrock and recessive lithologies (such as shale evaporite and friable
sandstone) may be present although they rarely outcrop
Outcrops of stromatolitic dolomite with associated cauliflower chert and cubic pseudomorphs
interpreted as being after halite indicate that evaporitic environments are present within the
Mundadjini Skates Hills and Boondawari Formations Evaporitic minerals are also present in
drillhole LDDH1 in the Tarcunyah Group
In 1995 GSWA drilled a continuous-core diamond drillhole (Trainor 1) in the sub-basin on
TRAINOR to a depth of 709 m to test for source rocks thus providing the first such data for the sub-
basin The drillhole intersected flat-lying clastics and carbonates of the McFadden Formation (9ndash
83 m) overlying indurated mudstones of the Cornelia Formation (83ndash709 m total depth) dipping at
about 40deg Of the six samples analysed from the Cornelia Formation in this drillhole the five
located between 375 and 6032 m depth have TOC values exceeding 05 (range 066ndash365)
Rock-Eval pyrolysis of these five samples indicates that they are at best in the dry-gas thermal
stage and as a result of their high level of maturation (Stevens and Adamides in prep) have poor
remaining hydrocarbon-generating potential Although the Cornelia Formation is overmature at
Trainor 1 the high TOC values are encouraging as it is likely that this sequence is less mature
elsewhere in the sub-basin
The Mundadjini Formation contains potential source rocks that comprise marine mudstones
with evaporitic minerals present in parts Thin dark mudstones were intersected in the Mundadjini
Formation in Akubra 1 In Mundadjini 1 and Boondawari 1 however the mudstones appear to be
too oxidized to have source potential
The Boondawari Formation also may be a source rock as it contains black mudstones The
unit is laterally equivalent to the Pertatataka Formation of the Amadeus Basin and the Ungoolya
23
Group of the Officer Basin in South Australia both of which have some source potential
(Summons and Powell 1991 Morton and Drexel 1997) Samples from the Dey Dey Mudstone of
the Ungoolya Group generally have poor TOC values (average 011 range 003ndash081)
moderate hydrogen index (HI) values (100ndash382) and poor to fair genetic potential with a
maximum of 292 kg hydrocarbon per tonne of source rock (Morton and Drexel 1997)
Stromatolitic dolomites and mudstones at the top of the Boondawari Formation and within the
Skates Hills Formation are potential source rocks Stromatolitic dolomite and evaporitic rocks
deposited in a marginal marine to sabkha environment are considered to have good potential to
generate and preserve organic carbon without requiring a deep-water setting (Stevens and Grey
1997) Such conditions are recognized in the Skates Hills Formation and in the upper parts of the
Tarcunyah Group
Maturity
Knowledge of the maturity of sedimentary rocks within the Savory Sub-basin is still limited From
a review of palynological studies Grey and Stevens (1997) report that the thermal maturity
inferred from the Thermal Alteration Index (TAI) of 3+ from Supersequence 1 age palynomorphs
in TWB 6 TWB 9 and LDDH1 is within the hydrocarbon window (Appendix 3) In Phanerozoic
spores and pollen a TAI of 3+ approximately equates to the end of liquid petroleum generation
and the start of dry gas generation and to a vitrinite reflectance of about 13 (Traverse 1988)
However the use of TAI for estimating thermal maturity from Neoproterozoic palynomorphs
requires calibration
In Trainor 1 the Cornelia Formation contains organically rich claystones between 375 and
6032 m depth Based on Rock-Eval maturity data (Stevens and Adamides in prep) and the dark
colour of poorly preserved organic material (Grey 1995de 1996) with TAI 4- to 5 all samples
had a high level of maturation with at best dry-gas generating potential remaining In contrast
drillhole LDDH1 on GUNANYA recorded lower levels of maturity (TAI values of 3+) with two of
sixteen samples from the Tarcunyah Group having greater than 1 TOC (Grey 1995abc Grey
and Cotter 1996) Organic petrology and Rock-Eval maturity data for samples from LDDH1
indicate that the section above 500 m is within the oil-generative window whereas below 500 m
the rocks are within the gas window (Ghori in prep Fig 9 Appendix 5)
Waterbores TWB 1 2 6 and 9 which are located on TRAINOR in the southeast of the sub-
basin all had organic matter with TAI values of 3+ from the McFadden Skates Hills Cornelia
and Brassey Range Formations respectively
24
100
200
300
400
500
600
700
Oil
gene
ratin
g
Gas
gene
ratin
g
Fai
r
Fai
r
Poo
r
Poo
r
Goo
d
Imm
atur
e
Oil
win
dow
Oil
win
dow
Imm
atur
e
01 0110 10 0 150 300 440 480 1
Neo
prot
eroz
oic
TOC S1+S2 mgg Hydrogen Index Tmax degC
Depth(m)
Organicrichness
Generatingpotential
Kerogentype Maturity Maturity
TD=701m
Sandstone
Mudstone
Dolomite
Limestone
Evaporite
Source rock
MKS40 070498
Ro equivalent
Figure 9 Petroleum source potential of rocks in Normandy LDDH1
Small amounts of organic matter associated with basalt and dolerite in cuttings from
waterbore BWB 1 on BULLEN showed high levels of thermal maturity (Grey 1995a Libby 1995)
It is unclear whether all sedimentary rocks on BULLEN are overmature for hydrocarbon generation
or the results from BWB 1 are related to local heating events associated with the volcanic bodies
that are common in the Jilyili Formation
25
Reservoirs
Each of the five depositional sequences of the Savory Group (Table 1) are inferred to contain
significant sandstone reservoirs with the possible exception of depositional sequence C as
discussed above in Stratigraphy The Spearhole Formation was cored in Mundadjini 1 and
Boondawari 1 and visual estimates of porosity vary from generally poor (less than 5) to fair
(approximately 5ndash15) The McFadden Formation in Trainor 1 has porosity values of up to 232
and a maximum permeability of 195 md (Stevens and Adamides in prep) Sandstones from
Neoproterozoic formations form the acquifers in the following waterbores the McFadden
Formation in TWB 1 the Cornelia Formation in TWB 6 and the Brassey Range Formation in
TWB 8 and TWB 9 (Appendix 6 Table 61)
Based on outcrop observations the Durba Sandstone is considered to be the best reservoir of
the Savory Group Similarly some sandstones from the Tarcunyah Group also have good visible
porosity in outcrop
Dolomites occur in several formations in the sub-basin Reservoir potential may exist
particularly where the dolomites are stromatolitic and oolitic However dolomites have not been
drilled in the sub-basin and porosity can only be inferred from the preferential silicification of
some stromatolite bioherms observed in outcrop (Stevens and Grey 1997) Elsewhere in the
Officer Basin porosities of up to10 have been measured in dolomites A limestone breccia
(karst) is described from 663 to 677 m in drillhole LDDH1 (Fig 6 Busbridge 1994)
Seals
Indications of evaporitic environments in the Mundadjini Skates Hills and Boondawari
Formations are described by Williams (1992) In Mundadjini 1 from 287 to 337 m anhydrite and
chert occurs as nodules beds and veins in mudstone of the Mundadjini Formation Evaporitic
minerals (predominantly gypsum) are described in the Tarcunyah Group in LDDH1 The presence
of the Woolnough and Madley salt diapirs in the Officer Basin (approximately 110 km east of the
sub-basin) and halite beds over 25 m thick in the well Hussar 1 (130 km east of the sub-basin)
provide further evidence that evaporite seals may be present in the Savory Sub-basin
Mudstones and shales form only a small proportion of the limited Neoproterozoic outcrop in
the sub-basin but significant thicknesses of mudstone were encountered in the Mundadjini
Formation in Mundadjini 1 and Boondawari 1 the Tarcunyah Group in LDDH1 and in the
26
Cornelia Formation in Trainor 1 These data suggest that mudstones form a significant proportion
of strata in the sub-basin despite their limited outcrop
Traps
Potential structural closures including folds and faults occur at various scales throughout the
Savory Sub-basin However the region has only been mapped at 1250 000 scale and
independently closed structures such as domes have yet to be confirmed The western margin of
the basin contains abundant faults (with a northeast strike) but elsewhere faults are less common
Some anticlines are recognized in outcrop including one with a strike length of up to 45 km
inferred from surface bedding dips in the Mundadjini and Spearhole Formations at approximately
24deg15rsquoS 121deg10rsquoE on BULLEN (Fig 1)
Salt diapirs and other halokinetic structures are recognized in outcrop well and seismic data
in the Officer Basin to the west of the Savory Sub-basin and it is probable that there are
significant thicknesses of evaporitic sedimentary rocks in the sub-basin The gravity field data
suggest there is good potential for salt diapirs and traps related to halokinesis
Although there is potential for stratigraphic traps to be present in the sub-basin insufficient
data are available to assess them
Preservation of hydrocarbons
The range of thermal maturities measured to date and the large periods of time envisaged for
deposition of sediments implies hydrocarbon generation may have occurred a number of times
during the evolution of the Savory Sub-basin Any hydrocarbons that were generated early may
have been trapped in palaeostructures and remigration to younger traps could have taken place
later The Petermann Ranges Orogeny which has been equated with the Paterson Orogeny (Myers
1990) is believed to have occurred in the latest Neoproterozoic to early Cambrian This is the last
major tectonic event recognized in the sub-basin suggesting that it is reasonable to expect that trap
integrity will have been preserved
If the inference of the presence of thick halite beds in the sub-basin is correct the preservation
potential of sub-salt traps should be excellent
27
Reported hydrocarbon shows and oil seep
Amadeus Petroleum recorded minor oil shows in cores from Mundadjini 1 and Boondawari 1 In
Mundadjini 1 at 36102 m (top of the Spearhole Formation) a 3 mm thick zone had 10 moderate
white fluorescence with slow solvent cut This show was in a granular sandstone with visually
estimated porosity of about 10 In Boondawari 1 at 35364 m (within the Spearhole Formation) a
broken surface of sandstone had 40 moderate yellow-white fluorescence with slow solvent cut
Visually estimated porosity is about 5 Because the fluorescing surface was broken during the
drilling process this show could have resulted from contamination A second show occurs in
Boondawari 1 at 4963 m (within the Spearhole Formation) where a 1 cm-thick zone had 5 dull
yellow fluorescence with slow solvent cut in a conglomerate with visually estimated porosity of
about 10 The company intends to further investigate the nature of these occurrences
Minor bitumen is present at 6623 m in drillhole LDDH1 on GUNANYA (Figs 5 and 6) as a
vein in mudstones of the Tarcunyah Group A sample was analysed by gas chromatography
(Ghori in prep) and confirmed that it is natural bitumen (Appendix 5)
Mineral hole OD 23 drilled by Jubilee Gold Mines NL on NABBERU in the Bangemall Basin
immediately to the south of the Savory Sub-basin (Fig 5) encountered bitumen and trace oil in
vugs in dolomite (M Stevens unpublished data) but no further data are available at present
In their popular guide to the Canning Stock Route Gard and Gard (1990 p 218) refer to an
oil seep at Well 13 on TRAINOR (Fig 5) They reported that between 1977 and 1984 lsquonatural oilrsquo
was seen in the well Although the well is now largely filled with sediment four auger drill
samples were collected by the GSWA in 1995 and all four were analysed for oil shows One
sample from 315 m total depth (GSWA sample 135604) yielded just enough extract (519 ppm)
for saturate gas chromatography analysis The gas chromatograph (Appendix 5) shows that the
extract does contain some hydrocarbons probably from recent plant material Because the depth to
the oil was not quoted in Gard and Gard (1990) the hand-augered well may not have been deep
enough to properly test this reported seep
Geological and geophysical databases
Geological and geophysical data available for the Savory Sub-basin are limited The most recently
completed geological maps for the sub-basin were published by the GSWA between 1991 and
1995 (Williams and Tyler 1991 Williams 1992 1995ab)
28
The cores from the five drillholes listed in Table 2 believed to be all of the core available
from the sub-basin are available for inspection at GSWA Mineral exploration reports submitted
to GSWA may be searched using the WAMEX database and open-file reports are available on
microfiche Geophysical data acquired by the mining industry is not required to be filed with
GSWA if acquired over Vacant Crown Land which is the case for much of the sub-basin
Geophysical survey data submitted in mining tenement reports and which extend into Vacant
Crown Land remain confidential to the companies Original regional aeromagnetic and gravity
datasets are available from the Australian Geological Survey Organisation (AGSO)
Data pertinent to oil exploration in the sub-basin such as structural style and salt diapirism
are presented in a review of the hydrocarbon prospectivity of the Officer Basin (Perincek 1998)
Drilling
Significant drillholes in the sub-basin are summarized in Table 2
Petroleum industry data
Amadeus Petroleum drilled three petroleum exploration wells in the central west of the Savory
Sub-basin in late 1997 These wells Mundadjini 1 Boondawari 1 and Akubra 1 were drilled by
continuous diamond coring (Figs 5 and 6) All targeted potential reservoirs within the Spearhole
Formation with the Mundadjini Formation as the proposed seal The wells were located on
structures interpreted from Landsat images and limited geological investigations Both Mundadjini
1 and Boondawari 1 had minor oil shows as discussed above (Reported hydrocarbon shows)
Government data
Stratigraphic drillhole Trainor 1 was drilled by GSWA in 1995 (Stevens and Adamides in prep)
and the main results are discussed above (Source rocks and Maturity)
Mineral industry data
Normandy Exploration drillhole LDDH1 was cored in the Tarcunyah Group to a total depth of
701 m and provided source-rock and maturity data as discussed above
29
Oilmin NL drilled six percussion drillholes (BD 1 3 4 5 8 and 9) through sandstones and
shales in the northern part of the Savory Sub-basin to a maximum depth of 198 m (Fig 5
WAMEX Microfiche File M 26811 I 2610) but only brief geological descriptions are available
Hydrogeological data
Hydrogeological data within the Savory Sub-basin are limited although a long history of water
exploration extends back to the construction of the Canning Stock Route early this century No
detailed geological or wireline logs are available for the older wells along this route A few station
wells have been drilled by various methods on the south and west margins of the basin but data
are unavailable as reports are not required to be filed with the government Depth to watertable
throughout the basin is largely controlled by porosity of the bedrock
The GSWA drilled fifteen waterbores in the winter of 1995 in the southern part of the sub-
basin in preparation for the drilling of Trainor 1 and the proposed Bullen 1 Twelve bores found
water and six of these bores have salinities of less than 1000 mgL (Fig 5 Appendix 6 Table 61)
One waterbore TWB 6 has gamma ray and neutron logs run through PVC casing and these are
available from the GSWA with the digital log data included herein
Seismic data
No geophysical data have been acquired by the petroleum industry in the Savory Sub-basin
Seismic data acquired in the Officer Basin to the east particularly in the Gibson and Yowalga
Sub-basins is pertinent to structural interpretation in the Savory Sub-basin (Perincek 1996a
1998)
Aeromagnetic surveys
Government data
There are over 95 277 line kilometres of aeromagnetic data included in the AGSO dataset There
are three regional aeromagnetic surveys covering the Savory Sub-basin These were flown by the
Bureau of Mineral Resources (BMR now AGSO) in 1984 at a line spacing of 1500 m with 36 740
and 52 587 line kilometres flown and by Aerodata in 1984 at a line spacing of 1000m with 5950
line kilometres flown These data were reprocessed and interpreted for GSWA by Cowan (1995)
An edited copy of this report is included as Appendix 4 and the original report is filed in the
GSWA Library under S-series reports item 10331
30
Mineral industry data
The approximate locations of non-AGSO aeromagnetic surveys are shown in Figure 8 More
detailed information regarding the location of these surveys may be obtained using the GSWA
MAGCAT II database Additional information such as contours of aeromagnetic values may be
obtained by inspecting items on file with the GSWA
Gravity surveys
Government data
The average spacing for gravity data in the Savory Sub-basin is one station per 121 km2 (11 times 11
km grid) These data were principally collected by BMR in the early 1960s There are a few
additional regional gravity traverses across the sub-basin which are also included in the
BMRAGSO dataset These data were reprocessed and interpreted for GSWA (Fig 10) and a
report on this work is also included in Appendix 4
The GSWA completed a large semi-detailed gravity survey in the eastern Savory Sub-basin
utilizing helicopter support and Differential Global Positioning Survey (DGPS) techniques (Fig
8) This gravity survey completed in August 1995 consists of 2300 gravity stations on a 2 times 3 km
grid All stations were acquired by helicopter using Scintrex gravimeters and Ashtek dual
frequency DGPS equipment for determining location This highly efficient system allowed the
acquisition of more than 100 gravity stations per day in remote areas The resolution of this survey
is +30 cm and +05 microms-2 (Daishsat 1995) These data (Fig 11) represent a significant
improvement on the previous regional survey data and are available from GSWA (GSWA
1996ab) The results of the interpretation of these data were presented at the 1997 ASEG
Convention (Carlsen and Shevchenko 1997)
Mineral industry data
Three small gravity surveys were conducted by Oilmin NL (Fig 8) and the relevant WAMEX
reports are M 2681I 2610 I 2435 I 2567 These three surveys are of limited value because height
control was provided by barometers only and the surveys were not tied to the national gravity grid
31
23deg
25deg
120deg 122deg
Trainor 1
SAVORY
SUB-BASIN
MKS54 160498
100 km
1995 SavoryGravity Survey
254
-1056
micromsec2
Figure 10 Regional Bouguer gravity map of the Savory Sub-basin
23deg
24deg
25deg
122deg30 123deg
TRAINOR 1
123deg30
50 km
MKS53 160498
-116
-626
micro msec2
Figure11 Detailed Bouguer gravity map of the
Savory 1995 Gravity Survey from the eastern Savory Sub-basin
32
Government and academic reports
Chronostratigraphy and geochemistry
The understanding of Neoproterozoic organic chemistry palynology and structural evolution is
essential to the interpretation of hydrocarbon prospectivity Pertinent reports are included in the
bibliography (Appendix 1) Unpublished palaeontology reports describe the palynology of wells in
the Savory Sub-basin (Grey 1995andashe 1996a) Grey and Cotter (1996) discussed the potential for
Neoproterozoic palynomorphs to provide a biostratigraphic framework and palaeoenvironmental
interpretation Grey and Stevens (1997) reviewed the results of palynological studies of wells
drilled in the sub-basin and reported that Supersequence 1 palynomorphs are present in TWB 6
TWB 9 and LDDH1 (Appendix 3) Grey (1996b) reported on the use of stromatolites for
correlation in the Neoproterozoic and Stevens and Grey (1997) discussed the application of
stromatolite biostratigraphy in correlating isolated dolomite outcrops in the sub-basin with well
and seismic data in the Officer Basin and Centralian Superbasin
Although geochemical data from the Savory Sub-basin are very limited results mostly
confirm thermal maturities inferred from TAI for LDDH1 and Trainor 1 (Ghori in prep Stevens
and Adamides in prep) Those parts of the Officer Basin in Western Australia which lie to the
east of the Savory Sub-basin are sparsely drilled but Ghori (in prep) reports that most of the
Neoproterozoic succession presently lies within the oil-generative window However his study
has been unable to identify effective source-rock units and the source for oil shows Thin source
rocks are present in the Neoproterozoic in LDDH1 (Fig 9) and in three wells which lie to the east
and southeast of the Savory Sub-basin namely NJD 1 Kanpa 1A and Yowalga 3
Proposed work program
From the above limited information it is concluded that additional research on the hydrocarbon
potential of the sub-basin is justified and proposals are outlined below
bull Additional modelling of gravity and aeromagnetic data from the Savory Sub-basin is required
in light of the results from Trainor 1 and Boondawari 1 Trainor 1 showed that what appeared
to be a structurally simple area based on outcrop aeromagnetic and gravity data was in fact an
area of major structuring Boondawari 1 intersected a dolerite which is in good depth
agreement with aeromagnetic depth to source results showing this technique is useful in
detecting the depth to intrusive bodies
33
bull Additional data from mineral and petroleum exploration bores may become available and
analysis of samples from these wells should be undertaken and interpreted in the context of
their relevance to the Officer Basin
bull Stratigraphic coring in the Blake Fault and Fold Belt and in the Wells Foreland Sub-basin (Fig
1) targeting source rocks is considered essential to the continuing evaluation of the
hydrocarbon prospectivity of the Savory Sub-basin
bull Correlations using at least outcrop well and potential-field data should be prepared to link the
sub-basin with the better known parts of the Officer Basin to the east
bull Remapping is required to clarify boundary positions within the Cornelia Formation this may
resolve some of the current problems of the relationship between this unit and the rest of the
Savory Sub-basin
bull Further work is required to explain the Early Cambrian or Sturtian ages interpreted for the
Cornelia Formation from sedimentary zircon UndashPb dating in drillhole Trainor 1 The
determination of the age of the organically rich but overmature claystones in this well is
critical to assessing the hydrocarbon potential of the region
bull The thin dark mudstones intersected by Akubra 1 in the Mundadjini Formation warrant
geochemical analysis Analyses of the oil shows in Mundadjini 1 and Boondawari 1 are
currently being undertaken by Amadeus Petroleum
bull Geochemical analysis of hydrocarbons in the Bangemall Basin drillhole OD23 has been
performed by Jubilee Gold and the results will be reviewed when they are submitted to
GSWA The possibility of source rocks within the Bangemall Basin charging traps within the
Bangemall Basin and the overlying Savory Sub-basin requires further investigation
Conclusions
The Savory Sub-basin is a frontier region with only three recently drilled petroleum exploration
wells and no seismic data Based on existing geological and geophysical data it is considered too
early to draw conclusions about the hydrocarbon prospectivity of the sub-basin at this stage and
there are several reasons why the area warrants further investigation
34
1 Thick accumulations of sedimentary rocks are present (up to 8 km thickness inferred) which
may contain source reservoir and sealing strata
2 Minor oil shows occur in Mundadjini 1 and Boondawari 1 and bitumen is present in mineral
exploration drillhole LDDH1 suggesting that hydrocarbons have migrated within the
Neoproterozoic sequence of the Savory Sub-basin Oil and bitumen are present in mineral
exploration drillhole OD23 in the Bangemall Basin immediately to the south of the Savory
Sub-basin and it is possible that source rocks from the Bangemall Basin could charge traps in
the overlying Savory Sub-basin
3 The age of sedimentary rocks in the sub-basin is still poorly constrained but some of the
Neoproterozoic sedimentary rocks located on GUNANYA and TRAINOR are within the
hydrocarbon-generation window It is possible that a significant thickness of Phanerozoic
sedimentary rocks may also be present
4 Friable sandstones with visible porosity outcrop extensively suggesting numerous potential
reservoirs
5 Significant but not intense faulting and folding has been mapped implying large structural
traps may be present
6 Evaporitic sedimentary rocks occur in several formations and may provide good source rocks
and excellent seals
35
References
APAK S N and CARLSEN G M 1997 A compilation and review of data pertaining to the
hydrocarbon prospectivity of the Canning Basin Western Australia Geological Survey
Record 199610 103p
BAGAS L GREY K and WILLIAMS I R 1995 Reappraisal of the Paterson Orogen and
Savory Basin Western Australia Geological Survey Annual Review 1994ndash95 p 55ndash63
BUSBRIDGE M 1994 Lake Disappointment Exploration Licence 451064 Third Annual
Report Lake Disappointment Diamond Drill Hole LDDH1 Normandy Exploration Limited
Western Australia Geological Survey M-series Item 7567 A41358 (unpublished)
CARLSEN G M and SHEVCHENKO S I 1997 Petroleum exploration in Proterozoic basins
using potential fields data and stratigraphic coring Australian Society of Exploration
Geophysicists 12th Geophysical Conference Handbook Sydney 1997 Preview no 66 p 83
(abstract only)
COWAN D 1995 Savory Basin quantitative magnetic interpretation Western Australia
Geological Survey S-series S10331 (unpublished)
DAISHSAT PTY LTD 1995 Operational and processing report Savory Basin gravity survey
Western Australia Geological Survey S-series S10332 (unpublished)
GARD E and GARD R 1990 Canning Stock Route a travellerrsquos guide for a journey through
history Perth Western Australia Western Desert Guides 448p
GEOLOGICAL SURVEY OF WESTERN AUSTRALIA 1996a Savory Basin first vertical
derivative of Bouguer gravity image 1250 000 Western Australia Geological Survey
GEOLOGICAL SURVEY OF WESTERN AUSTRALIA 1996b Savory Basin Bouguer gravity
image 1250 000 Western Australia Geological Survey
GHORI K A R in prep Petroleum source rock potential and thermal history Officer Basin
Western Australia Western Australia Geological Survey Record
36
GREY K 1995a Savory Basin drillhole BWB 1 (Bullen waterbore) palynology and thermal
maturation GSWA Palaeontology Report no 199512 (unpublished)
GREY K 1995b Savory Basin drillholes TWB 1 2 6 9 (Trainor waterbores) palynology and
thermal maturation GSWA Palaeontology Report no 199520 (unpublished)
GREY K 1995c Palynology of Normandy-Poseidon Lake Disappointment-1 corehole
Tarcunyah Group Paterson Orogen GSWA Palaeontology Report no 199521 (unpublished)
GREY K 1995d Savory Basin drillhole Trainor 1 (Trainor diamond drilling) palynology and
thermal maturity GSWA Palaeontology Report no 199524 (unpublished)
GREY K 1995e Savory Basin drillhole Trainor 1 (Trainor diamond drilling) Additional
Preparation of two samples GSWA Palaeontology Report no 199528 (unpublished)
GREY K 1995f Neoproterozoic stromatolites from the Skates Hills Formation Savory Basin
Western Australia and a review of the distribution of Acaciella australica Australian Journal
of Earth Sciences v 42 p 123ndash132
GREY K 1996a Savory Basin drillhole Trainor 1 (Trainor diamond drilling) Additional
samples palynology and thermal maturation GSWA Palaeontology Report no 199615
(unpublished)
GREY K 1996b Preliminary stromatolite correlations for the Neoproterozoic of the Officer
Basin and a review of Australia-wide correlations GSWA Palaeontology Report no 199615
(unpublished)
GREY K and COTTER K L 1996 Palynology in the search for Proterozoic hydrocarbons
Western Australia Geological Survey Annual Review for 1995ndash96 p 70ndash80
GREY K and STEVENS M K 1997 Neoproterozoic palynomorphs of the Savory Sub-basin
Western Australia and their relevance to petroleum exploration Western Australia
Geological Survey Annual Review for 1996ndash97 p 49ndash54
HUBBARD R J PAPE J and ROBERTS D G 1985 Depositional sequence mapping as a
technique to establish tectonic and stratigraphic framework and evaluate hydrocarbon
potential on a passive continental margin in Seismic stratigraphy II an integrated approach
37
edited by O R BERG and D G WOOLVERTON American Association of Petroleum
Geologists Memoir 39 p 79ndash91
LIBBY WG 1995 A petrological report on six samples of bore cuttings from the Savory Basin
Western Australia Western Australia Geological Survey S-series S31307 (unpublished)
MORTON JGG and DREXEL JF 1997 The petroleum geology of South Australia Vol 3
Officer Basin South Australia Department of Mines and Energy Resources Report Book
9719
MUHLING P C and BRAKEL A T 1985 Geology of the Bangemall Group mdash the evolution
of an intracratonic Proterozoic basin Western Australia Geological Survey Bulletin 128
219p
MYERS J S 1990 Precambrian tectonic evolution of part of Gondwana southwestern Australia
Geology v18 p 537ndash540
NELSON D R 1997 Compilation of SHRIMP UndashPb zircon data Western Australia Geological
Survey Record 19972 196p
PAYTON C E 1977 Seismic stratigraphy mdash applications to hydrocarbon exploration
American Association of Petroleum Geologists Memoir 26 516p
PERINCEK D 1996a The age of NeoproterozoicndashPalaeozoic sediments within the Officer Basin
of the Centralian Super-basin can be constrained by major sequence-bounding unconformities
APPEA Journal v 36 pt 1 p 350ndash368
PERINCEK D 1996b The stratigraphic and structural development of the Officer Basin
Western Australia a review Western Australia Geological Survey Annual Review 1995ndash
1996 p 135ndash148
PERINCEK D 1998 A compilation and review of data pertaining to the hydrocarbon
prospectivity of the Officer Basin Western Australia Geological Survey Record 19976
POSAMENTIER H W JERSEY M T and VAIL P R 1988 Eustatic controls on clastic
deposition 1 mdash Conceptual framework in Sea-level changes an integrated approach edited by
C K WILGUS B S HASTINGS C G St C KENDALL H W POSAMENTIER
38
C A ROSS and J C VAN WAGONER Society of Economic Paleontologists and
Mineralogists Special Publication no 42
STEVENS M K and ADAMIDES N G in prep GSWA Trainor 1 well completion report
Savory Sub-basin Officer Basin Western Australia with notes on petroleum and mineral
potential Western Australia Geological Survey Record 199612
STEVENS M K and GREY K 1997 Skates Hills Formation and Tarcunyah Group Officer
Basin mdash carbonate cycles stratigraphic position and hydrocarbon prospectivity Western
Australia Geological Survey Annual Review for 1996ndash97 p 55ndash60
SUMMONS RE and POWELL C McA 1991 Petroleum source rocks of the Amadeus Basin
in Geological and geophysical studies in the Amadeus Basin central Australia edited by R J
KORSCH and JM KENNARD Australia BMR Geology and Geophysics Bulletin 236
TRAVERSE A 1988 Palaeopalynology Boston Unwin Hyman 600p
VAIL P R MITCHUM R M Jr TODD R G WIDMIER J M THOMPSON S III
SANGREE J B BUBB J N and HATLELID W G 1977 Seismic stratigraphy and
global changes of sea level in Seismic stratigraphy mdash applications to hydrocarbon
exploration edited by C E PAYTON American Association of Petroleum Geologists
Memoir 26 516p
WALTER M R and GORTER J 1994 The Neoproterozoic Centralian Superbasin in Western
Australia the Savory and Officer Basins in The sedimentary basins of Western Australia
edited by P G PURCELL and R R PURCELL Petroleum Exploration Society of Australia
Symposium Perth WA 1994 Proceedings p851ndash864
WALTER M R GREY K WILLIAMS I R and CALVER C R 1994 Stratigraphy of the
Neoproterozoic to early Palaeozoic Savory Basin and correlation with the Amadeus and
Officer Basins Australian Journal of Earth Sciences v 41 p 533ndash546
WALTER M R VEEVERS J J CALVER C R and GREY K 1995 Neoproterozoic
stratigraphy of the Centralian Superbasin Australia Precambrian Research v 73 p 173ndash195
WILLIAMS I R 1992 Geology of the Savory Basin Western Australia Western Australia
Geological Survey Bulletin 141 115p
39
WILLIAMS I R 1995a Bullen WA (2nd Edition) Western Australia Geological Survey
1250 000 Geological Series Explanatory Notes 23p
WILLIAMS I R 1995b Trainor WA (2nd Edition) Western Australia Geological Survey
1250 000 Geological Series Explanatory Notes 31p
WILLIAMS I R and TYLER I M 1991 Robertson WA (2nd edition) Western Australia
Geological Survey 1250 000 Geological Series Explanatory Notes 36p
40
41
Appendix 1
Bibliography
Reports which are relevant to this investigation but which are not specifically cited are listed
below
BAILLIE P W POWELL C McA LI Z X and RYALL A M 1994 The tectonic
framework of Western Australiarsquos Neoproterozoic to recent sedimentary basins in The
sedimentary basins of Western Australia edited by P G PURCELL and R R PURCELL
Petroleum Exploration Society of Australia Symposium Perth WA 1994 Proceedings p
45ndash62
BRADSHAW M T BRADSHAW J MURRAY A P NEEDHAM D J SPENCER L
SUMMONS R E WILMOT J and WINN S 1994 Petroleum systems in West Australian
basins in The sedimentary basins of Western Australia edited by P G PURCELL and R R
PURCELL Petroleum Exploration Society of Australia Symposium Perth WA 1994
Proceedings p 93ndash118
CLARKE G L 1991 Proterozoic tectonic reworking in the Rudall Complex Western Australia
Australian Journal of Earth Science v38 p 31ndash44
COCKBAIN A E and HOCKING R M 1990 Phanerozoic in Geology and mineral resources
of Western Australia Western Australia Geological Survey Memoir 3 p 750ndash755
ETHERIDGE M and WALL V 1994 Tectonic and structural evolution of the Australian
Proterozoic 12th Australian Geological Convention Geological Society of Australia
Abstracts no 37 p 102ndash103
GOODE A D T 1981 Proterozoic geology of Western Australia in Precambrian of the
Southern Hemisphere Developments in Precambrian geology 2 edited by I R HUNTER
Amsterdam Elsevier p 105ndash203
GREY K and JACKSON M J 1983 A re-assessment of stromatolite evidence for the
correlation of the Late Proterozoic Neale and Ilma Beds Officer Basin Western Australia
Australia BMR Journal of Australian Geology and Geophysics v 8 p 359
42
HICKMAN A H WILLIAMS I R and BAGAS L 1994 Proterozoic geology and
mineralization of the TelferndashRudall region Paterson Orogen Geological Society of Australia
(WA Division) Excursion Guidebook no 5 56p
HOCKING R M MORY A J and WILLIAMS I R 1994 An atlas of Neoproterozoic and
Phanerozoic basins of Western Australia in The sedimentary basins of Western Australia
edited by P G PURCELL and R R PURCELL Petroleum Exploration Society of Australia
Symposium Perth WA 1994 Proceedings p 21ndash 44
JACKSON P R 1966 Geology and review of exploration Officer Basin Western Australia
Hunt Oil Company Western Australia Geological Survey S-series S26 (unpublished)
JACKSON M J 1971 Notes on a geological reconnaissance of the Officer Basin Western
Australia Australia BMR Geology and Geophysics Record 19715 30p
JACKSON M J and van de GRAAFF W J E 1981 Geology of the Officer Basin Western
Australia Australia BMR Geology and Geophysics Bulletin 206 102 p
LOWRY D C JACKSON M J van de GRAAFF W J E and KENNEWELL P J 1971
Preliminary result of geological mapping in the Officer Basin Western Australia Western
Australia Geological Survey Annual Report for 1971 p 50ndash56
MYERS J S 1990 Precambrian in Geology and mineral resources of Western Australia
Western Australia Geological Survey Memoir 3 p 737ndash750
MYERS J S SHAW R D and TYLER I M 1994 Proterozoic tectonic evolution of
Australia 12th Australian Geological Convention Geological Society of Australia Abstracts
no 37 p 312
NEDIN C and JENKINS R J F 1991 Re-evaluation of unconformities separating the
lsquoEdiacaranrsquo and Cambrian systems South Australia Palaios v 6 p 102ndash108
PHILLIPS B J JAMES A W and PHILIP G M 1985 The geology and hydrocarbon
potential of the north-western Officer Basin APEA Journal 25 (1) p 52ndash61
POWELL C McA LI Z X McELHINNY M W MEERT J G and PARK J K 1993
Paleomagnetic constraints on timing of the Neoproterozoic breakup of Rodinia and Cambrian
formation of Gondwana Geology v 21 p 889ndash892
43
POWELL C McA PREISS W V GATEHOUSE C G KRAPEZ B and LI Z X 1994
South Australian record of a Rodinian epicontinental basin and its mid-Neoproterozoic
breakup to form the Palaeo-Pacific Ocean Tectonophysics v 237 no 3ndash4 p 113ndash140
PREISS W V 1976 Proterozoic stromatolites from the Nabberu and Officer Basins Western
Australia and their biostratigraphic significance South Australia Geological Survey Report
of Investigations no 47 p 1ndash51
TOWNSON W G 1985 The subsurface geology of the western Officer Basin mdash results of
Shellrsquos 1980ndash1984 petroleum exploration campaign APEA Journal v 25 (1) p 34ndash51
WATTS K J 1982 The geology of the Townsend Quartzite Upper Proterozoic shallow water
deposit of the Northern Officer Basin Western Australia Perth University of Western
Australia BSc honours thesis (unpublished)
WELLS A T and KENNEWELL P J 1974 Evaporite exploration in the Officer Basin
Western Australia at the Madley Diapirs Australia BMR Record 1974194 (unpublished)
WILLIAMS I R and MYERS J S 1990 Paterson Orogen in Geology and mineral resources
of Western Australia Western Australia Geological Survey Memoir 3 p 274ndash286
WILLIAMS I R 1990 Savory Basin in Geology and mineral resources of Western Australia
Western Australia Geological Survey Memoir 3 p 329ndash334
WILLIAMS I R 1994 The Neoproterozoic Savory Basin Western Australia in The
sedimentary basins of Western Australia edited by P G PURCELL and R R PURCELL
Petroleum Exploration Society of Australia Symposium Perth WA 1994 Proceedings p
841ndash850
WILSON R B 1967 Woolnough Hills and Madley diapiric structures Gibson Desert WA
APEA Journal v 7 p 94ndash102
44
Appendix 2
Meteorological data (from Bureau of Meteorology Perth 1994)
Table 21 Wiluna rainfall (mm)
Year Jan Feb Mar Apr May Jun Jul Aug Sept Oct Nov Dec
1975 0 45 446 309 306 59 276 4 34 886 638 164 1976 16 154 12 138 53 16 34 62 12 238 0 2 1977 44 0 66 74 68 95 24 363 1 58 12 727 1978 234 522 94 16 0 96 367 24 16 353 185 45 1979 19 173 122 88 91 4 0 246 58 0 169 114 1980 148 764 68 1081 259 626 629 06 56 02 174 0 1981 123 476 192 32 196 118 44 74 14 0 28 312 1982 374 705 206 244 1079 92 02 143 368 526 368 118 1983 1 112 928 248 0 212 56 32 5 1 42 496 1984 149 7 342 84 836 0 348 132 224 04 16 172 1985 596 483 0 166 556 0 514 56 0 0 4 0 1986 0 154 35 0 0 1085 23 01 239 137 0 04 1987 1204 119 19 89 17 575 154 126 07 1 0 398 1988 46 202 164 13 388 0 202 104 0 0 224 1309 1989 207 234 26 703 278 536 57 0 01 0 144 02 1990 1035 23 281 46 126 53 94 218 44 9 42 0 1991 48 0 41 45 0 472 297 12 0 1 0 7 1992 112 96 1025 1227 323 65 04 174 0 132 48 4 1993 0 697 0 202 445 0 12 306 18 05 14 33 Mean 25 35 22 27 27 25 18 12 6 13 13 21
JAN FEB MAR APR MAY JUN JUL AUG SEP OCT NOV DEC0
10
20
30
40
Mea
n R
ain
fall
(mm
)
Month
Mean monthly rainfall in Wiluna
MKS41 140498
45
Table 22 Wiluna minimum temperature (degC)
Year Jan Feb Mar Apr May Jun Jul Aug Sept Oct Nov Dec
1975 ndash 23 203 15 94 63 71 62 103 124 169 205 1976 242 229 194 15 10 63 59 73 95 143 16 228 1977 243 25 197 148 96 95 56 86 102 ndash 188 23 1978 241 232 203 18 102 64 76 8 9 152 19 205 1979 255 226 216 167 83 6 59 79 97 145 198 223 1980 255 226 231 155 134 83 68 75 121 108 193 223 1981 245 216 19 182 119 6 54 78 138 159 163 218 1982 232 224 177 16 ndash ndash 37 111 112 164 209 225 1983 235 24 197 147 112 88 39 88 121 162 189 219 1984 241 243 191 156 ndash 72 66 7 95 161 182 211 1985 244 231 ndash 159 98 65 71 73 117 147 205 ndash 1986 ndash 229 226 155 93 96 43 49 10 122 ndash 219 1987 ndash 217 183 175 85 77 68 68 112 ndash ndash 221 1988 238 214 209 178 111 ndash ndash 86 104 157 171 195 1989 ndash 237 199 165 107 67 44 61 107 131 187 ndash 1990 232 ndash 211 155 118 62 57 87 102 149 195 22 1991 26 256 217 168 122 101 78 ndash 113 18 168 219 1992 227 227 214 169 102 98 59 69 ndash 125 159 196 1993 241 218 196 171 103 ndash 49 68 88 128 192 211 Mean 24 23 20 16 10 8 6 8 11 14 18 21
NOTE Dashes indicate data unavailable
JAN FEB MAR APR MAY JUN JUL AUG SEP OCT NOV DEC0
10
20
30
40
Month
MKS43 140498
50
Mean monthly minimum temperatures at Wiluna
Mea
n T
emp
erat
ure
(degC
)
46
Table 23 Wiluna maximum temperature (degC)
Year Jan Feb Mar Apr May Jun Jul Aug Sept Oct Nov Dec
1975 ndash 349 326 281 247 201 197 212 256 248 31 344 1976 374 369 346 297 248 206 208 225 265 287 313 388 1977 397 392 352 296 234 212 222 244 ndash 308 337 383 1978 378 345 346 316 242 195 176 205 231 295 334 356 1979 403 36 364 295 ndash ndash ndash 193 242 318 359 373 1980 392 342 377 275 24 176 179 233 292 288 349 391 1981 385 346 337 342 242 178 201 224 30 326 326 369 1982 372 359 315 307 ndash ndash 196 253 252 305 353 379 1983 381 389 327 272 263 222 187 248 287 321 336 366 1984 378 393 322 299 226 215 178 214 234 ndash 336 364 1985 40 366 ndash 294 224 216 205 212 284 307 355 ndash 1986 ndash 383 372 307 ndash 193 166 196 261 277 ndash 382 1987 ndash 339 328 305 21 202 214 218 275 ndash ndash 374 1988 388 365 353 301 23 ndash ndash 228 283 334 31 33 1989 ndash 375 339 285 238 179 181 219 275 298 336 ndash 1990 368 ndash 36 309 268 19 188 205 274 309 373 393 1991 414 416 363 315 268 206 21 ndash 279 338 332 368 1992 363 383 336 263 213 178 213 197 ndash 285 313 359 1993 396 357 344 301 221 ndash 197 215 253 294 347 362 Mean 39 37 34 30 24 20 20 22 27 30 34 37 NOTE Dashes indicate data unavailable
JAN FEB MAR APR MAY JUN JUL AUG SEP OCT NOV DEC0
10
20
30
40
Month
MKS42 140498
50
Mean monthly maximum temperatures at Wiluna
Mea
n T
emp
erat
ure
(degC
)
47
Appendix 3
Table 31 Summary of palynological results
Drillhole Depth (m) F no(a) GSWA no Lithology Formation Assemblage TAI(b)
BWB 1 74ndash75 F49668 135741 dark-grey siltstone basalt Jilyilli gt5 BWB 1 98ndash100 F49669 135742 dark-grey siltstone basalt Jilyilli gt5 BWB 1 121ndash122 F49670 135743 dark-grey siltstone basalt Jilyilli gt5 TWB 1 86ndash87 F49671 135631 dark-grey siltstone McFadden 3+ TWB 1 104ndash105 F49672 135632 dark-grey siltstone Cornelia 3+ TWB 1 121ndash122 F49673 135633 dark-grey siltstone Cornelia 4 TWB 2 14ndash15 F49674 135634 dark-grey siltstone Skates Hills 3+ TWB 6 49ndash50 F49675 135675 dark-grey siltstone Cornelia 1 3+ TWB 9 49ndash51 F49676 135704 dark-grey siltstone Brassey Range 1 3+ Trainor 1 37497- F49733 138939 black mudstone with Cornelia 5 37509 light-grey siltstone Trainor 1 3809 F49734 138940 dark-grey and black Cornelia 4- laminated mudstone Trainor 1 4170 F49735 138941 black unlaminated mudstone Cornelia 4- Trainor 1 4950 F49851 139501 dark-grey indurated siltstone Cornelia 5 Trainor 1 6032 F49852 139502 dark- and light-grey Cornelia 5 indurated siltstone Trainor 1 6434 F49853 139503 greenish indurated finely Cornelia 5 laminated siltstone LDDH 1 270 F49678 138934 dark-grey siltstone interbeds Waters 1 3+ in enterolithic evaporite Tarcunyah Gp LDDH 1 277 F49679 138935 dark-grey siltstone in cavity Waters 1 3+ in enterolithic evaporite Tarcunyah Gp
NOTES (a) GSWA Fossil Catalogue number (b) TAI = Thermal Alteration Index of Traverse (1988 plate 1)
48
Appendix 4
Savory Sub-basin quantitative magnetic and gravity interpretation (extracted from Cowan 1995)
Summary
A program of quantitative aeromagnetic interpretation has been completed on BMRAGSO data from the Savory Sub-
basin Western Australia Quantitative aeromagnetic interpretation utilized the 3D Euler deconvolution method
supported by wavenumber filtering and image processing The results have provided useful information on structural
trends and depth to magnetic sources in a structurally complex area Depth to magnetic source analysis has provided
information on intra-sedimentary magnetic sources as well as basement rocks
The results of the interpretation support previously identified depocentres However the presence of magnetic
sources at several levels makes it very difficult to produce a reliable magnetic basement depth contour map It is
considered more productive to work with the 3D Euler colour circle plots and images rather than trying to contour the
results It would be necessary to carry out a full-scale interpretation of the BMRAGSO profile data to improve on the
3D Euler results The regional gravity was found to be useful in interpreting the regional setting of the area although
the very wide data spacing limits quantitative use of the data The gravity data show quite a complex picture with
limited consistent correlation between gravity features and basin structures This suggests that gravity anomalies
reflect changes in density of the basement rocks rather than basement topography especially in the northern part of the
basin
It is recommended that the GSWA investigate access to company confidential high-resolution aeromagnetic data
prior to planning further aeromagnetic surveys Private companies have flown large parts of the northern half of the
area as part of their diamond exploration program Additional gravity coverage of the area may be more cost effective
than magnetic surveys as the gravity data provides more information on changes within the sedimentary section
Introduction
The main use of aeromagnetic data in petroleum exploration has been the determination of magnetic basement
topography although there has been increasing interest in analysis of intra-sedimentary magnetic anomalies
intrabasement and suprabasement magnetic anomalies These anomalies are used to determine depth to magnetic
basement rocks and hence determine the thickness of the sedimentary sequence Unfortunately interpretation of the
intrabasement and suprabasement magnetic anomalies is non-unique in terms of position and size of causative sources
because of the inherent ambiguity of potential-field methods However this ambiguity can be reduced by placing
49
constraints on source geometry and magnetization and by using geological and other geophysical data to constrain
the solution
Before 1970 most depth-determination techniques involved graphical determination of slopes of selected
magnetic anomalies and application of various empirical factors to convert the slopes into depth estimates Geological
Society of America Memoir 47 Interpretation of Aeromagnetic Maps by Vacquier et al (1951) was a landmark for
this type of interpretation
Automated interpretation procedures have played an increasingly important role in depth interpretation and a
wide range of techniques have been developed Many of these techniques are designed for application to located data
profiles and assume a two-dimensional geometry However there has been renewed interest in techniques applicable
to gridded data
Two distinct types of method can be recognized In the first case often described as discrete methods individual
isolated magnetic anomalies are interpreted and the results used to produce a map of basement relief In the second
case often described as continuous methods areas of data containing a number of anomalies are interpreted
statistically to produce direct output of basement depths
The discrete methods usually involve a semiautomatic initial phase which generates a large number of possible
depth solutions and an interactive second phase to screen and select acceptable solutions The advantage of this
approach is that the interpreter can select features that are relatively free from interference from adjacent anomalies
and consider all aspects of a particular magnetic anomaly The disadvantage is that interpretation can be very time
consuming as a wide range of depths are usually possible depending on the initial model chosen and a significant
amount of effort is needed to select the correct model In the case of the Savory Sub-basin dataset we encountered
problems in separating basement related effects from the effects of shallower intrasedimentary magnetic sources
Because of these problems we have concentrated on displaying the Euler results accompanied by separation filter
images of the data to show the shallower effects and deeper effects rather than trying to refine a 3D Euler
deconvolution depth-to-crystalline-basement contour
The continuous methods are very direct provided that the rather restrictive assumption can be made that all
anomalies are due to lateral magnetization changes due to basement topography This means that shallow effects and
large intrabasement anomalies must be removed from the data This involves judgement and skill as it is necessary to
distinguish between the lower amplitude suprabasement anomalies due to basement topography and the larger
intrabasement anomalies reflecting magnetization changes within the basement These methods were not considered
suitable for the Savory Sub-basin magnetic dataset but were used to invert the gravity data
50
Limitations of magnetic and gravity interpretation
Interpretation of the area is limited by a shortage of information on the nature and physical properties of the deeper
sedimentary sequence and the underlying basement rocks However using techniques such as cross-correlation of
gravity and pseudo-gravity data it is possible to try to differentiate between anomalies relating to basement and those
related to the sedimentary sequence
Gravity anomalies reflect changes within the sedimentary sequence as well as basement condition These
changes in density of sedimentary rocks produce gravity anomalies without a corresponding magnetic anomaly hence
the complementary nature of gravity and magnetic surveys The main use of magnetics is to determine depth to
magnetic basement and any intra-sedimentary volcanic rocks or intrusives whereas gravity provides much more
general information on the sedimentary sequence
Unfortunately interpretation of gravity anomalies is complicated since they can be due to a number of geological
features including
bull major basement faults
bull basement highs
bull igneous intrusions within the basement
bull sedimentary basins which may or may not be isostatically compensated
bull intra-sedimentary volcanics and associated plutonic centres
Two major problems affect the interpretation of both magnetic and gravity data
1 The inherent ambiguity of potential-field data There is no unique solution to any measured gravity or magnetic
anomaly and theoretically there will be an infinite number of source geometry and magnetizationdensity
combinations which will fit the observed data This means that any a priori information which helps to select a
suitable model is very useful
2 Measured anomalies are the summation of effects from different depths For example an observed gravity profile
may contain contributions from shallow sources (density variations within the sedimentary basin) intermediate
depth sources (density variations due to large igneous intrusions within the basement) and deep sources (crustal
thinning producing a mantle anomaly) Separation of these component responses is the regionalresidual problem
which we solve using spectral analysis and differential upward continuation-based separation filtering
Regional setting and interpretation overview
The area studied includes parts of BALFOUR DOWNS (SF51-9) RUDALL (SF51-10) ROBERTSON (SF51-13) GUNANYA
(SF51-14) COLLIER (SG50-4) BULLEN (SG51-1) TRAINOR (SG51-2) MADLEY (SG51-3) NABBERU (SG50-5)
STANLEY (SG51-6) and HERBERT (SG51-7) 1250 000 sheets Broadly the area lies between latitudes 22deg00rsquondash25deg30rsquoS
and longitudes 119deg30rsquondash123deg30rsquoE
51
Regional gravity
The AGSO regional gravity data (at nominal 11 km spacing) was gridded at a 4 km mesh spacing using a minimum-
curvature algorithm Bouguer gravity values in the area are negative reflecting mass deficiency at depth and range
from -84 mgals to -25 mgals
A Bouguer gravity colour image is shown as Figure 41 A residual grid was produced by removing a fifth-order
orthogonal polynomial from the Bouguer data but did not add to the interpretation
120deg 121deg 122deg 123deg
23deg
24deg
25deg
-25
-84
50 km
MKS46 180598
mgal
Figure 41 Regional Bouguer gravity (BMRAGSO data) gridded at 4 km
52
The data show a complex pattern of positive and negative anomalies with no clearly defined trends Correlations
with aeromagnetic data and known basin structures are poor A vague north-northwest linear trend appears to coincide
with the Marloo Fault (Figure 42) A prominent negative anomaly appears to coincide with the Blake Fold and Fault
Belt depocentre and continues as a narrower negative anomaly to the east until it widens out again near the edge of the
basin Elsewhere the gravity data show little correlation with known basin structures and it is likely that especially in
the north of the area gravity anomalies are due to density changes in the basement rather than changes in basement
topography
Production of wavelength-filtered residual gravity plots and vertical gradient plots showed very patchy aliased
data reflecting poor sampling in much of the area
Regional magnetics
The AGSO regional aeromagnetic data were gridded at a 400 m mesh spacing using a minimum-curvature algorithm
(Figure 43) Most of the data has a line spacing of 1600 m with small areas of 1 km spacing The quality of the data is
acceptable for regional interpretation but is not adequate for detailed analysis The accuracy of the flight path is rather
variable reflecting the vintage of the data and the noise envelope of the data is poor by modern standards Problems
were also encountered in joining different map sheets
The magnetic anomaly pattern over the south and west part of the area shows a strong high frequency signature
reflecting the presence of widespread basic sills and dykes Some of the major north-northeasterly trending dykes can
be traced over considerable distances
Discontinuous high-frequency anomalies extend as a northwest-trending zone through the centre of the area and
this zone includes a conspicuous circular magnetic anomaly which is probably a ring complex
The northern and eastern parts of the area are characterized by long-wavelength deep-seated basement magnetic
anomalies with 120deg and 150deg trends dominant The Marloo and Perentie Faults (Figure 42) appear as distinct linear
zones and offsets A prominent easterly trending negative anomaly in the northwest of the area appears to swing round
to the southeast and may separate different basement blocks One possible interpretation is that this very deep seated
anomaly separates areas of Archaean and Proterozoic basement
Regional geology
The regional geology is described in Williams (1992) The GSWA provided a digitized version of Plate 2 from this
Bulletin the structural interpretation map to use as an overlay (Figure 42)
53
Pp
Pp
PSd
PSd
PSd
PSd
PSd
PSo
PSt
PSt
PSf
PSf
PSf
PSb
PSb
PSb
PSsPSs
PSs
PSb
PSm
PSp
PSc
PSc
PSw
PSw
PSw
PSg
PSr
PSj
PSg
PM
Pk
PY
PY
PSd
L
L
L
L
L
L
L
LL
L
L
L
LL
L
LL
L L
LL
L L
L
L
L
L
L
L
L
LL
L
L
BLAKEDEPOCENTRE
MA
RLO
O
FAU
LT
PERENTIEFAULT
50 km
MKS39120598
120deg 121deg 122deg 123deg
25deg
24deg
23deg
Approximate boundaryof aeromagnetic interpretation
PML
PSgL
PSjL
PML
PSpL
PML
PML
PSfL
PSfL
PSpL
LPc
LPcLPcPSrL
LPA
Durba Sandstone
Woora Woora Formation
McFadden Formation
Tchukardine Formation
Boondawari Formation
Skates Hills Formation
Mundadjini Formation
Coondra Formation
Spearhole Formation
Watch Point Formation
Jilyili Formation
Brassey Range Formation
Glass Spring Formation
Paterson Formation
Yeneena Group
Karara Formation
Cornelia Formation
Kahrban Subgroup
Bangemall Group
Fault
Formation boundary
PSdL
PSoL
PSfL
PStL
PSbL
PSsL
PSmL
PScL
PSpL
PSwL
PSjL
PSrL
PSgL
Pp
PYL
PkL
LPc
LPA
PML
Savory Group Other Units
PYL
Figure 42 Regional geology and structure map (after Williams 1992)
54
120deg 121deg 122deg 123deg
23deg
24deg
25deg
5820
3750
MKS47 180598
nT
50 km
Figure 43 Regional aeromagnetic data total magnetic intensity (BMRAGSO data) gridded at 400 m
Analysis
3D analysis
3D Euler deconvolution was used as the primary depth-determination method The advantage of this approach is that
consistent solutions can be obtained over the entire area with minimal assumptions about source geometries Euler
deconvolution of gridded data is used for positional information and estimation of depth to top of source Euler
55
deconvolution yields a large number of depth solutions which have to be screened to reject spurious solutions Results
are plotted as circles in eight depth ranges with radius proportional to depth and colour coded
The 400 m total magnetic intensity grid was used for the analysis Horizontal gradients in x and y and the vertical
gradient were calculated 3D Euler deconvolution was tested on the 400 m gridded data using windows of 9 times 9 and
11 times 11 and 16 times 16 data points and structural indices 05 (fault) and 10 (sill or dyke) It was concluded that the
16 times 16 window produced the best results overall and final plots were produced for the 16 times 16 window and structural
index 05 (Fig 44) Results were very good over the northern and central parts of the area showing magnetic sources
Figure 44 Depth to magnetic source 3D Euler deconvolution 16 times 16 window of 400 m gridded data structural index 05
56
at several different levels Unfortunately in the extreme south of the area shallow intrasedimentary magnetic sources
(sills and dykes) dominated the inversion and the results contained few basement solutions
In order to reduce these problems the 400 m gridded data were filtered using a separation filter based on
interpretation of the log-energy spectrum The 3D Euler method was run on the filtered data in order to generate more
basement-depth solutions Results for the deep-separation filter data were gridded and presented as a colour image in
Cowan (1995) Attempts to grid the Euler output were unsatisfactory and it is considered safer to interpret the 3D
Euler depth plots The 3D Euler depth results from the separation-filter run should be analysed with care as perfect
separation of the basement can never be achieved and there will always be some contamination from sources at
different levels
The results of original total magnetic intensity 3D Euler depth estimation for structural index 05 using a 16 point
window have been plotted at 1500 000 scale (not included in this publication but available in Cowan (1995) from the
GSWA Library as S10331) and as reduced A4 colour circle plots (Figure 44)
The results of deep-basement 3D Euler depth estimation for structural index 05 using a 16 point window have
been plotted as a colour image at 1500 000 scale and as an A4 image (not included in this publication)
2D analysis
Two equispaced profiles were interpolated with a 50 m station interval from the AGSO-located data profiles for the
BULLEN 1250 000 sheet The interpolated profiles were analysed using 2D Euler deconvolution and Werner
deconvolution Results are included in Cowan (1995) and show the use of these methods for more detailed analysis
Filtered data
In order to reconcile 3D Euler results from shallow basement and intrasedimentary magnetic sources we produced
several separation-filtered maps and images We found the shallow-layer double-separation filter (Figure 45) to be
very effective for shallow sources and the deep-layer standard-separation filter (Figure 46) for the basement layer
Gravity and magnetic data correlation
Both lsquoreduced to the polersquo (RTP) magnetics (Figure 47) and pseudo-gravity data (Figure 48) were produced as part of
the reconciliation of gravity and magnetic signatures In both cases the filtering operations assumed magnetization by
induction in the present Earths field The RTP data are fairly similar to the total magnetic intensity The pseudo-
57
gravity data are dominated by a northwest-trending strong positive anomaly and there is little correlation with the
Bouguer gravity data
The poor magneticgravity correlation is confirmed by cross-correlation of the RTP magnetics and the gravity
gradient The correlation plot in Figure 49 shows little coherent response with numerous zones of positive and
negative correlation
Figure 45 Regional aeromagnetic data shallow layer separation filter (BMRAGSO data) gridded at 400 m
Results
In the north and east of the area on the Wells Foreland Sub-basin trend (refer to Figure 1 main text) we see a range
of quite deep 3D Euler depths and several trend directions with north-northwesterly dominant There are relatively few
shallow intrasedimentary solutions in this zone
The second area of deep 3D Euler solutions lies over the Blake depocentre (Figure 43) with several trend
directions
Elsewhere the 3D Euler results are dominated by shallow intrasedimentary depth solutions reflecting mainly the
dolerite sills dykes and the ring complex However where we do see basement-related solutions in the south and
west of the area they appear to be shallower than those noted for the Wells Foreland Sub-basin and the Blake
depocentre
58
Figure 46 Regional aeromagnetic data deep-layer separation filter (BMRAGSO data) gridded at 400 m
Figure 48 Regional aeromagnetic data pseudo-gravity transform (BMRAGSO data) gridded at 400 m
Figure 47 Regional aeromagnetic data reduced-to-pole (BMRAGSO data) gridded at 400 m
Figure 49 Regional aeromagnetic and gravity data gravitymagnetic correlation using RTP magnetics and gravity gradient (BMRAGSO data) gridded at 4 km
59
This subdivision of the area into two zones of deep solutions is consistent with interpreted depocentres
However the interference between sources at different levels and the complexity of the magnetic response of the
basement rocks precludes more refined interpretation at this stage
The area of deep 3D Euler solutions over the Blake depocentre correlates with the pronounced negative gravity
anomaly discussed in the gravity interpretation section Using a density contrast of -015 gcc the negative gravity
anomaly could indicate up to 6ndash8 km of low-density sedimentary rocks depending on assumptions about the regional
field
The area of deep 3D Euler solutions over the Wells Foreland Sub-basin has a complex gravity expression and no
clear basin structure emerges from inversion of these data As noted previously it is likely that observed gravity
anomalies reflect contrasts in basement density rather than basement topography
Separation filtering applied to the magnetic data helps to enhance the intrasedimentary magnetic signature and to
give a better impression of the basement magnetic signature even though separation of the basement response is not
perfect
Conclusions
Quantitative aeromagnetic interpretation using 3D Euler deconvolution supported by wavenumber filtering and image
processing has been successful in providing structural trend and depth information for the Savory Sub-basin
Quantitative magnetic interpretation has revealed two zones of relatively deep magnetic basement beneath the
Wells Foreland Sub-basin and the Blake depocentre
This analysis of the magnetic data supports interpreted depocentres but the complexity of the basement magnetic
signature and interference from sources at different depths precludes further refinement to a map of basement
topography
Regional gravity proved to be very useful in understanding the regional setting of the area and in providing
support for aspects of the interpretation The gravity data support the interpretation of the Blake depocentre
suggesting up to 6ndash8 km of low-density sedimentary rocks
The deep structure of the Savory Sub-basin area is obviously complex with different areas underlain by
Archaean and Proterozoic basement and with the Capricorn suture occurring in the centre of the area
60
Recommendations
The quantitative magnetic interpretation needs to be reconciled with geological models available for the area
In particular the zones tentatively identified as areas with thick sedimentary rocks the Wells Foreland Sub-
basin and the Blake depocentre need to be investigated
Cross sections should be prepared across the basin for joint magneticgravity modelling especially for the Blake
depocentre It is important to be able to explain the strong negative gravity anomaly in this area
In view of the effects of basement density contrasts on the gravity field for the northern part of the area we think
that additional gravity interpretation and acquisition of new gravity data may not be justified as they will not
contribute significantly to understanding basin evolution and structure
It is recommended that GSWA try to get access to company confidential high-resolution aeromagnetic data
rather than flying new surveys The GSWA might offer to fund flying of new infill areas as a bargaining point
References
The original text of this report by Cowan (1995) and 1500 000 scale maps are filed in the GSWA Library under
S10331
COWAN D 1995 Savory Basin quantitative magnetic interpretation Western Australia Geological Survey S-series
S10331 (unpublished)
VACQUIER V STEENLAND N C HENDERSON R G and ZIETZ I 1951 Interpretation of aeromagnetic
maps The Geological Society of America Memoir 47 151p
WILLIAMS I R 1992 Geology of the Savory Basin Western Australia Western Australia Geological Survey
Bulletin 141 115p
61
Appendix 5
Geochemistry
MKS38 250398
Saturate FractionC12+ GLC
1217
Pr18
Ph
22
31CSR WELL-13 315m Cuttings
Figure 51 Canning Stock Route Well 13 gas chromatograph of extract of auger drill sample
12
17
18
22
31
Pr Ph
LDDH 1 6623m CoreSaturate FractionC12+ GLC
MKS35 240398
Figure 52 Gas chromatograph of extract from core sample at 6623 m LDDH1
62
Table 51 Canning Stock Route Well 13 auger drill samples
GSWA sample Drill depth (m)(a) Comments
135601 150 At watertable 135602 203 (all samples consist 135603 310 of sand mud and water) 135604 315 At total depth
NOTE (a) Datum for drill depth is the top of sediment fill in the well which is 155 m below ground level (ie the total depth of 315 m is 47 m below ground level)
Table 52 Canning Stock Route Well 13 gas chromatography data for 315 m depth sediment sample
Parameter Value
Weight of rock extracted (grams) 945 Total extract (ppm) 519 n-Alkane distribution n-C12 07 n-C13 23 n-C14 26 n-C15 22 n-C16 19 n-C17 14 i-C19 23 n-C18 14 i-C20 08 n-C19 11 n-C20 16 n-C21 25 n-C22 29 n-C23 70 n-C24 42 n-C25 95 n-C26 43 n-C27 83 n-C28 38 n-C29 87 n-C30 31 n-C31 273 Alkane compositional data Pristane phytane ratio 279 Pristane n-C17 ratio 161 Phytane n-C18 ratio 059 CPI (1)(a) 284 CPI (2) 209 (C21 + C22) (C28 + C29) 043
NOTE (a) CPI= Carbon preference index
63
Table 53 LDDH1 extract liquid chromatography data for 6623 m concentration
Rock extracted Total extract (grams) (ppm)
702 313
NOTE ppm= parts per million
Table 54 LDDH1 saturate gas chromatography data of core for 6623 m alkane composition
Pristane Pristane Phytane (a) CPI (1) CPI (2) (C21+C22) Phytane n-C17 n-C18 (C28+C29)
103 026 024 103 102 325
NOTE (a)CPI = carbon preference index
Table 55 LDDH1 saturate gas chromatography data of core for 6623 m n-alkane distributions
Parameter Value
n-C12 17 n-C13 38 n-C14 55 n-C15 60 n-C16 65 n-C17 74 i-C19 19 n-C18 78 i-C20 19 n-C19 80 n-C20 79 n-C21 71 n-C22 64 n-C23 57 n-C25 43 n-C24 38 n-C27 31 n-C28 23 n-C29 19 n-C30 12 n-C31 10
64
Appendix 6
Table 61 Summary of data from Trainor waterbores (TWB) and Bullen waterbores (BWB)
Well AMG Elevation TD Status(b) Completion details Water Salinity Water level Flow rate Depth to consolidated AGD84 GL (m) (m) struck mgl(c) (m) (LHr) lithology aquifer(e) Z51(a) Interval (m) (100 mm PVC) (m) (mgl)(d)
TWB 1 473660E 453 122 comp 0ndash75 plain 63 7 300 24 2 880 12 m 7287404N 75ndash93 slotted (9 260) McFadden Fm 93ndash99 plain TWB 2 472 977E 475 23 abd nil 15 m 7285877N Skates Hills Fm dry TWB 3 473259E 475 50 abd nil 7 m 7285849N Skates Hills Fm dry TWB 4 463225 E 445 50 comp 0ndash22 plain 35 7 200 55 3 600 0 m 7286143N 22ndash34 slotted (8 140) Tertiary sand and gravel 23ndash60 plain TWB 5 463095E 445 31 comp 0ndash19 plain 13 26 000 655 3 600 Tertiary sand and gravel 7277721N 19ndash25 slotted (36 700) 25ndash31 plain TWB 6 457013E 455 50 comp 0ndash42 plain 38 920 119 600 0 m 7274352N 42ndash48 slotted (1 030) Cornelia Fm ss TWB 7 453739E 475 26 susp 0ndash2 plain 11 9 300 48 4 500 0 m 7263891N (10 500) Tertiary sand TWB 8 433893E 535 60 susp 0ndash2 plain 47 8 500 gt46 1 200 0 m 7245991N (10 900) Tertiary sand and Brassey Range Fm ss TWB 9 437219E 505 51 comp 0ndash47 plain 45 1 000 58 600 1 m 7235905N 47ndash51 slotted (990) Brassey Range Fm ss TWB 10 434927E 495 32 susp 0ndash2 plain 235 450 120 0 m 7225875N (500) Dolerite
65
BWB 1 287337E 580 122 abd Nil 1 m 7245861N Jilyili Fm dry BWB 2 288346E 545 50 comp 0ndash26 plain 15 630 3 29 000 0 m 7240423N 26ndash38 slotted (730) Tertiary sand and gravel 38ndash50 plain BWB 3 305637E 545 50 abd 19 8 800 43 7 200 0 m 7240423N (10 550) Tertiary ss BWB 4 320167E 515 445 comp 0ndash20 plain 9 980 445 24 000 0 m 7248097N 20ndash32 slotted (1 190) Tertiary ss 32ndash44 plain BWB 5 353393E 545 20 susp 0ndash2 plain 45 (970) 1 m 7238934N Basalt
NOTES (a) GPS accuracy ~ 150 m (b) Comp = completed abd = abandoned susp = suspended (c) Salinity from conductivity (d) Analysis total dissolved solids (e) Fm = Formation ss = sandstone
20
Table 2 Neoproterozoic formations and hydrocarbon shows in diamond drillholes in the Savory Sub-basin
Drillhole AMG Core TD (m) Approx Formation Depth Formation Depth Formation Depth Shows (AGD84) start (m) GL (m) (m) (m) (m)
LDDH 1 431148E 112 701 350 Tarcunyah 68ndash701 ndash ndash bitumen at 6623 m 7443826N Group Trainor 1 473640E 6 709 455 McFadden 9ndash83 Cornelia Fm 83ndash709 possible bitumen at 4537 m 7287400N Fm Mundadjini 1 319056E 170 600 500 Mundadjini 16ndash361 Spearhole Fm 361ndash600 10 fluorescence at 36102 m 7404844N Fm Boondawari 1 348959E 299 1 367 490 Mundadjini Fm 15ndash312 Spearhole Fm 312ndash1 283 Intrusive 1 283ndash1 367 40 fluorescence at 35364 m 5 7398174N fluorescence at 4963 m Akubra 1 334249E 15 181 530 Mundadjini 15ndash42 Intrusive 42ndash181 None 7401252N Fm
21
50 km
120deg 121deg30 123deg
25deg
24deg
23deg
22deg
Greater Officer Basin
Savory Sub-basin
1
2
3
4
6
8
3 Seismic line (prefixed N83-00)
Aeromagnetic survey
GS
WA
Sav
ory
1995
gra
vity
sur
vey
Gravity survey
MKS34270398
Figure 8 Locations of aeromagnetic and gravity surveys (other than regional BMRAGSO data)
22
sandstones in two petroleum wells in the northwest of the sub-basin and bitumen and oil shows
elsewhere in the region indicate that oil has been generated and migrated through the sub-basin
Source rocks
Source potential is considered to be the major exploration risk in the Savory Sub-basin although
minor oil shows in Mundadjini 1 and Boondawari 1 indicate that at least some oil has been
generated and migrated into potential reservoirs within the sub-basin Sandstone is the
predominant lithology observed in outcrop Outcrops of fine-grained lithologies in the basin are
rare because of intense surface weathering and erosion Only about 8 of the surface area of the
sub-basin is exposed bedrock and recessive lithologies (such as shale evaporite and friable
sandstone) may be present although they rarely outcrop
Outcrops of stromatolitic dolomite with associated cauliflower chert and cubic pseudomorphs
interpreted as being after halite indicate that evaporitic environments are present within the
Mundadjini Skates Hills and Boondawari Formations Evaporitic minerals are also present in
drillhole LDDH1 in the Tarcunyah Group
In 1995 GSWA drilled a continuous-core diamond drillhole (Trainor 1) in the sub-basin on
TRAINOR to a depth of 709 m to test for source rocks thus providing the first such data for the sub-
basin The drillhole intersected flat-lying clastics and carbonates of the McFadden Formation (9ndash
83 m) overlying indurated mudstones of the Cornelia Formation (83ndash709 m total depth) dipping at
about 40deg Of the six samples analysed from the Cornelia Formation in this drillhole the five
located between 375 and 6032 m depth have TOC values exceeding 05 (range 066ndash365)
Rock-Eval pyrolysis of these five samples indicates that they are at best in the dry-gas thermal
stage and as a result of their high level of maturation (Stevens and Adamides in prep) have poor
remaining hydrocarbon-generating potential Although the Cornelia Formation is overmature at
Trainor 1 the high TOC values are encouraging as it is likely that this sequence is less mature
elsewhere in the sub-basin
The Mundadjini Formation contains potential source rocks that comprise marine mudstones
with evaporitic minerals present in parts Thin dark mudstones were intersected in the Mundadjini
Formation in Akubra 1 In Mundadjini 1 and Boondawari 1 however the mudstones appear to be
too oxidized to have source potential
The Boondawari Formation also may be a source rock as it contains black mudstones The
unit is laterally equivalent to the Pertatataka Formation of the Amadeus Basin and the Ungoolya
23
Group of the Officer Basin in South Australia both of which have some source potential
(Summons and Powell 1991 Morton and Drexel 1997) Samples from the Dey Dey Mudstone of
the Ungoolya Group generally have poor TOC values (average 011 range 003ndash081)
moderate hydrogen index (HI) values (100ndash382) and poor to fair genetic potential with a
maximum of 292 kg hydrocarbon per tonne of source rock (Morton and Drexel 1997)
Stromatolitic dolomites and mudstones at the top of the Boondawari Formation and within the
Skates Hills Formation are potential source rocks Stromatolitic dolomite and evaporitic rocks
deposited in a marginal marine to sabkha environment are considered to have good potential to
generate and preserve organic carbon without requiring a deep-water setting (Stevens and Grey
1997) Such conditions are recognized in the Skates Hills Formation and in the upper parts of the
Tarcunyah Group
Maturity
Knowledge of the maturity of sedimentary rocks within the Savory Sub-basin is still limited From
a review of palynological studies Grey and Stevens (1997) report that the thermal maturity
inferred from the Thermal Alteration Index (TAI) of 3+ from Supersequence 1 age palynomorphs
in TWB 6 TWB 9 and LDDH1 is within the hydrocarbon window (Appendix 3) In Phanerozoic
spores and pollen a TAI of 3+ approximately equates to the end of liquid petroleum generation
and the start of dry gas generation and to a vitrinite reflectance of about 13 (Traverse 1988)
However the use of TAI for estimating thermal maturity from Neoproterozoic palynomorphs
requires calibration
In Trainor 1 the Cornelia Formation contains organically rich claystones between 375 and
6032 m depth Based on Rock-Eval maturity data (Stevens and Adamides in prep) and the dark
colour of poorly preserved organic material (Grey 1995de 1996) with TAI 4- to 5 all samples
had a high level of maturation with at best dry-gas generating potential remaining In contrast
drillhole LDDH1 on GUNANYA recorded lower levels of maturity (TAI values of 3+) with two of
sixteen samples from the Tarcunyah Group having greater than 1 TOC (Grey 1995abc Grey
and Cotter 1996) Organic petrology and Rock-Eval maturity data for samples from LDDH1
indicate that the section above 500 m is within the oil-generative window whereas below 500 m
the rocks are within the gas window (Ghori in prep Fig 9 Appendix 5)
Waterbores TWB 1 2 6 and 9 which are located on TRAINOR in the southeast of the sub-
basin all had organic matter with TAI values of 3+ from the McFadden Skates Hills Cornelia
and Brassey Range Formations respectively
24
100
200
300
400
500
600
700
Oil
gene
ratin
g
Gas
gene
ratin
g
Fai
r
Fai
r
Poo
r
Poo
r
Goo
d
Imm
atur
e
Oil
win
dow
Oil
win
dow
Imm
atur
e
01 0110 10 0 150 300 440 480 1
Neo
prot
eroz
oic
TOC S1+S2 mgg Hydrogen Index Tmax degC
Depth(m)
Organicrichness
Generatingpotential
Kerogentype Maturity Maturity
TD=701m
Sandstone
Mudstone
Dolomite
Limestone
Evaporite
Source rock
MKS40 070498
Ro equivalent
Figure 9 Petroleum source potential of rocks in Normandy LDDH1
Small amounts of organic matter associated with basalt and dolerite in cuttings from
waterbore BWB 1 on BULLEN showed high levels of thermal maturity (Grey 1995a Libby 1995)
It is unclear whether all sedimentary rocks on BULLEN are overmature for hydrocarbon generation
or the results from BWB 1 are related to local heating events associated with the volcanic bodies
that are common in the Jilyili Formation
25
Reservoirs
Each of the five depositional sequences of the Savory Group (Table 1) are inferred to contain
significant sandstone reservoirs with the possible exception of depositional sequence C as
discussed above in Stratigraphy The Spearhole Formation was cored in Mundadjini 1 and
Boondawari 1 and visual estimates of porosity vary from generally poor (less than 5) to fair
(approximately 5ndash15) The McFadden Formation in Trainor 1 has porosity values of up to 232
and a maximum permeability of 195 md (Stevens and Adamides in prep) Sandstones from
Neoproterozoic formations form the acquifers in the following waterbores the McFadden
Formation in TWB 1 the Cornelia Formation in TWB 6 and the Brassey Range Formation in
TWB 8 and TWB 9 (Appendix 6 Table 61)
Based on outcrop observations the Durba Sandstone is considered to be the best reservoir of
the Savory Group Similarly some sandstones from the Tarcunyah Group also have good visible
porosity in outcrop
Dolomites occur in several formations in the sub-basin Reservoir potential may exist
particularly where the dolomites are stromatolitic and oolitic However dolomites have not been
drilled in the sub-basin and porosity can only be inferred from the preferential silicification of
some stromatolite bioherms observed in outcrop (Stevens and Grey 1997) Elsewhere in the
Officer Basin porosities of up to10 have been measured in dolomites A limestone breccia
(karst) is described from 663 to 677 m in drillhole LDDH1 (Fig 6 Busbridge 1994)
Seals
Indications of evaporitic environments in the Mundadjini Skates Hills and Boondawari
Formations are described by Williams (1992) In Mundadjini 1 from 287 to 337 m anhydrite and
chert occurs as nodules beds and veins in mudstone of the Mundadjini Formation Evaporitic
minerals (predominantly gypsum) are described in the Tarcunyah Group in LDDH1 The presence
of the Woolnough and Madley salt diapirs in the Officer Basin (approximately 110 km east of the
sub-basin) and halite beds over 25 m thick in the well Hussar 1 (130 km east of the sub-basin)
provide further evidence that evaporite seals may be present in the Savory Sub-basin
Mudstones and shales form only a small proportion of the limited Neoproterozoic outcrop in
the sub-basin but significant thicknesses of mudstone were encountered in the Mundadjini
Formation in Mundadjini 1 and Boondawari 1 the Tarcunyah Group in LDDH1 and in the
26
Cornelia Formation in Trainor 1 These data suggest that mudstones form a significant proportion
of strata in the sub-basin despite their limited outcrop
Traps
Potential structural closures including folds and faults occur at various scales throughout the
Savory Sub-basin However the region has only been mapped at 1250 000 scale and
independently closed structures such as domes have yet to be confirmed The western margin of
the basin contains abundant faults (with a northeast strike) but elsewhere faults are less common
Some anticlines are recognized in outcrop including one with a strike length of up to 45 km
inferred from surface bedding dips in the Mundadjini and Spearhole Formations at approximately
24deg15rsquoS 121deg10rsquoE on BULLEN (Fig 1)
Salt diapirs and other halokinetic structures are recognized in outcrop well and seismic data
in the Officer Basin to the west of the Savory Sub-basin and it is probable that there are
significant thicknesses of evaporitic sedimentary rocks in the sub-basin The gravity field data
suggest there is good potential for salt diapirs and traps related to halokinesis
Although there is potential for stratigraphic traps to be present in the sub-basin insufficient
data are available to assess them
Preservation of hydrocarbons
The range of thermal maturities measured to date and the large periods of time envisaged for
deposition of sediments implies hydrocarbon generation may have occurred a number of times
during the evolution of the Savory Sub-basin Any hydrocarbons that were generated early may
have been trapped in palaeostructures and remigration to younger traps could have taken place
later The Petermann Ranges Orogeny which has been equated with the Paterson Orogeny (Myers
1990) is believed to have occurred in the latest Neoproterozoic to early Cambrian This is the last
major tectonic event recognized in the sub-basin suggesting that it is reasonable to expect that trap
integrity will have been preserved
If the inference of the presence of thick halite beds in the sub-basin is correct the preservation
potential of sub-salt traps should be excellent
27
Reported hydrocarbon shows and oil seep
Amadeus Petroleum recorded minor oil shows in cores from Mundadjini 1 and Boondawari 1 In
Mundadjini 1 at 36102 m (top of the Spearhole Formation) a 3 mm thick zone had 10 moderate
white fluorescence with slow solvent cut This show was in a granular sandstone with visually
estimated porosity of about 10 In Boondawari 1 at 35364 m (within the Spearhole Formation) a
broken surface of sandstone had 40 moderate yellow-white fluorescence with slow solvent cut
Visually estimated porosity is about 5 Because the fluorescing surface was broken during the
drilling process this show could have resulted from contamination A second show occurs in
Boondawari 1 at 4963 m (within the Spearhole Formation) where a 1 cm-thick zone had 5 dull
yellow fluorescence with slow solvent cut in a conglomerate with visually estimated porosity of
about 10 The company intends to further investigate the nature of these occurrences
Minor bitumen is present at 6623 m in drillhole LDDH1 on GUNANYA (Figs 5 and 6) as a
vein in mudstones of the Tarcunyah Group A sample was analysed by gas chromatography
(Ghori in prep) and confirmed that it is natural bitumen (Appendix 5)
Mineral hole OD 23 drilled by Jubilee Gold Mines NL on NABBERU in the Bangemall Basin
immediately to the south of the Savory Sub-basin (Fig 5) encountered bitumen and trace oil in
vugs in dolomite (M Stevens unpublished data) but no further data are available at present
In their popular guide to the Canning Stock Route Gard and Gard (1990 p 218) refer to an
oil seep at Well 13 on TRAINOR (Fig 5) They reported that between 1977 and 1984 lsquonatural oilrsquo
was seen in the well Although the well is now largely filled with sediment four auger drill
samples were collected by the GSWA in 1995 and all four were analysed for oil shows One
sample from 315 m total depth (GSWA sample 135604) yielded just enough extract (519 ppm)
for saturate gas chromatography analysis The gas chromatograph (Appendix 5) shows that the
extract does contain some hydrocarbons probably from recent plant material Because the depth to
the oil was not quoted in Gard and Gard (1990) the hand-augered well may not have been deep
enough to properly test this reported seep
Geological and geophysical databases
Geological and geophysical data available for the Savory Sub-basin are limited The most recently
completed geological maps for the sub-basin were published by the GSWA between 1991 and
1995 (Williams and Tyler 1991 Williams 1992 1995ab)
28
The cores from the five drillholes listed in Table 2 believed to be all of the core available
from the sub-basin are available for inspection at GSWA Mineral exploration reports submitted
to GSWA may be searched using the WAMEX database and open-file reports are available on
microfiche Geophysical data acquired by the mining industry is not required to be filed with
GSWA if acquired over Vacant Crown Land which is the case for much of the sub-basin
Geophysical survey data submitted in mining tenement reports and which extend into Vacant
Crown Land remain confidential to the companies Original regional aeromagnetic and gravity
datasets are available from the Australian Geological Survey Organisation (AGSO)
Data pertinent to oil exploration in the sub-basin such as structural style and salt diapirism
are presented in a review of the hydrocarbon prospectivity of the Officer Basin (Perincek 1998)
Drilling
Significant drillholes in the sub-basin are summarized in Table 2
Petroleum industry data
Amadeus Petroleum drilled three petroleum exploration wells in the central west of the Savory
Sub-basin in late 1997 These wells Mundadjini 1 Boondawari 1 and Akubra 1 were drilled by
continuous diamond coring (Figs 5 and 6) All targeted potential reservoirs within the Spearhole
Formation with the Mundadjini Formation as the proposed seal The wells were located on
structures interpreted from Landsat images and limited geological investigations Both Mundadjini
1 and Boondawari 1 had minor oil shows as discussed above (Reported hydrocarbon shows)
Government data
Stratigraphic drillhole Trainor 1 was drilled by GSWA in 1995 (Stevens and Adamides in prep)
and the main results are discussed above (Source rocks and Maturity)
Mineral industry data
Normandy Exploration drillhole LDDH1 was cored in the Tarcunyah Group to a total depth of
701 m and provided source-rock and maturity data as discussed above
29
Oilmin NL drilled six percussion drillholes (BD 1 3 4 5 8 and 9) through sandstones and
shales in the northern part of the Savory Sub-basin to a maximum depth of 198 m (Fig 5
WAMEX Microfiche File M 26811 I 2610) but only brief geological descriptions are available
Hydrogeological data
Hydrogeological data within the Savory Sub-basin are limited although a long history of water
exploration extends back to the construction of the Canning Stock Route early this century No
detailed geological or wireline logs are available for the older wells along this route A few station
wells have been drilled by various methods on the south and west margins of the basin but data
are unavailable as reports are not required to be filed with the government Depth to watertable
throughout the basin is largely controlled by porosity of the bedrock
The GSWA drilled fifteen waterbores in the winter of 1995 in the southern part of the sub-
basin in preparation for the drilling of Trainor 1 and the proposed Bullen 1 Twelve bores found
water and six of these bores have salinities of less than 1000 mgL (Fig 5 Appendix 6 Table 61)
One waterbore TWB 6 has gamma ray and neutron logs run through PVC casing and these are
available from the GSWA with the digital log data included herein
Seismic data
No geophysical data have been acquired by the petroleum industry in the Savory Sub-basin
Seismic data acquired in the Officer Basin to the east particularly in the Gibson and Yowalga
Sub-basins is pertinent to structural interpretation in the Savory Sub-basin (Perincek 1996a
1998)
Aeromagnetic surveys
Government data
There are over 95 277 line kilometres of aeromagnetic data included in the AGSO dataset There
are three regional aeromagnetic surveys covering the Savory Sub-basin These were flown by the
Bureau of Mineral Resources (BMR now AGSO) in 1984 at a line spacing of 1500 m with 36 740
and 52 587 line kilometres flown and by Aerodata in 1984 at a line spacing of 1000m with 5950
line kilometres flown These data were reprocessed and interpreted for GSWA by Cowan (1995)
An edited copy of this report is included as Appendix 4 and the original report is filed in the
GSWA Library under S-series reports item 10331
30
Mineral industry data
The approximate locations of non-AGSO aeromagnetic surveys are shown in Figure 8 More
detailed information regarding the location of these surveys may be obtained using the GSWA
MAGCAT II database Additional information such as contours of aeromagnetic values may be
obtained by inspecting items on file with the GSWA
Gravity surveys
Government data
The average spacing for gravity data in the Savory Sub-basin is one station per 121 km2 (11 times 11
km grid) These data were principally collected by BMR in the early 1960s There are a few
additional regional gravity traverses across the sub-basin which are also included in the
BMRAGSO dataset These data were reprocessed and interpreted for GSWA (Fig 10) and a
report on this work is also included in Appendix 4
The GSWA completed a large semi-detailed gravity survey in the eastern Savory Sub-basin
utilizing helicopter support and Differential Global Positioning Survey (DGPS) techniques (Fig
8) This gravity survey completed in August 1995 consists of 2300 gravity stations on a 2 times 3 km
grid All stations were acquired by helicopter using Scintrex gravimeters and Ashtek dual
frequency DGPS equipment for determining location This highly efficient system allowed the
acquisition of more than 100 gravity stations per day in remote areas The resolution of this survey
is +30 cm and +05 microms-2 (Daishsat 1995) These data (Fig 11) represent a significant
improvement on the previous regional survey data and are available from GSWA (GSWA
1996ab) The results of the interpretation of these data were presented at the 1997 ASEG
Convention (Carlsen and Shevchenko 1997)
Mineral industry data
Three small gravity surveys were conducted by Oilmin NL (Fig 8) and the relevant WAMEX
reports are M 2681I 2610 I 2435 I 2567 These three surveys are of limited value because height
control was provided by barometers only and the surveys were not tied to the national gravity grid
31
23deg
25deg
120deg 122deg
Trainor 1
SAVORY
SUB-BASIN
MKS54 160498
100 km
1995 SavoryGravity Survey
254
-1056
micromsec2
Figure 10 Regional Bouguer gravity map of the Savory Sub-basin
23deg
24deg
25deg
122deg30 123deg
TRAINOR 1
123deg30
50 km
MKS53 160498
-116
-626
micro msec2
Figure11 Detailed Bouguer gravity map of the
Savory 1995 Gravity Survey from the eastern Savory Sub-basin
32
Government and academic reports
Chronostratigraphy and geochemistry
The understanding of Neoproterozoic organic chemistry palynology and structural evolution is
essential to the interpretation of hydrocarbon prospectivity Pertinent reports are included in the
bibliography (Appendix 1) Unpublished palaeontology reports describe the palynology of wells in
the Savory Sub-basin (Grey 1995andashe 1996a) Grey and Cotter (1996) discussed the potential for
Neoproterozoic palynomorphs to provide a biostratigraphic framework and palaeoenvironmental
interpretation Grey and Stevens (1997) reviewed the results of palynological studies of wells
drilled in the sub-basin and reported that Supersequence 1 palynomorphs are present in TWB 6
TWB 9 and LDDH1 (Appendix 3) Grey (1996b) reported on the use of stromatolites for
correlation in the Neoproterozoic and Stevens and Grey (1997) discussed the application of
stromatolite biostratigraphy in correlating isolated dolomite outcrops in the sub-basin with well
and seismic data in the Officer Basin and Centralian Superbasin
Although geochemical data from the Savory Sub-basin are very limited results mostly
confirm thermal maturities inferred from TAI for LDDH1 and Trainor 1 (Ghori in prep Stevens
and Adamides in prep) Those parts of the Officer Basin in Western Australia which lie to the
east of the Savory Sub-basin are sparsely drilled but Ghori (in prep) reports that most of the
Neoproterozoic succession presently lies within the oil-generative window However his study
has been unable to identify effective source-rock units and the source for oil shows Thin source
rocks are present in the Neoproterozoic in LDDH1 (Fig 9) and in three wells which lie to the east
and southeast of the Savory Sub-basin namely NJD 1 Kanpa 1A and Yowalga 3
Proposed work program
From the above limited information it is concluded that additional research on the hydrocarbon
potential of the sub-basin is justified and proposals are outlined below
bull Additional modelling of gravity and aeromagnetic data from the Savory Sub-basin is required
in light of the results from Trainor 1 and Boondawari 1 Trainor 1 showed that what appeared
to be a structurally simple area based on outcrop aeromagnetic and gravity data was in fact an
area of major structuring Boondawari 1 intersected a dolerite which is in good depth
agreement with aeromagnetic depth to source results showing this technique is useful in
detecting the depth to intrusive bodies
33
bull Additional data from mineral and petroleum exploration bores may become available and
analysis of samples from these wells should be undertaken and interpreted in the context of
their relevance to the Officer Basin
bull Stratigraphic coring in the Blake Fault and Fold Belt and in the Wells Foreland Sub-basin (Fig
1) targeting source rocks is considered essential to the continuing evaluation of the
hydrocarbon prospectivity of the Savory Sub-basin
bull Correlations using at least outcrop well and potential-field data should be prepared to link the
sub-basin with the better known parts of the Officer Basin to the east
bull Remapping is required to clarify boundary positions within the Cornelia Formation this may
resolve some of the current problems of the relationship between this unit and the rest of the
Savory Sub-basin
bull Further work is required to explain the Early Cambrian or Sturtian ages interpreted for the
Cornelia Formation from sedimentary zircon UndashPb dating in drillhole Trainor 1 The
determination of the age of the organically rich but overmature claystones in this well is
critical to assessing the hydrocarbon potential of the region
bull The thin dark mudstones intersected by Akubra 1 in the Mundadjini Formation warrant
geochemical analysis Analyses of the oil shows in Mundadjini 1 and Boondawari 1 are
currently being undertaken by Amadeus Petroleum
bull Geochemical analysis of hydrocarbons in the Bangemall Basin drillhole OD23 has been
performed by Jubilee Gold and the results will be reviewed when they are submitted to
GSWA The possibility of source rocks within the Bangemall Basin charging traps within the
Bangemall Basin and the overlying Savory Sub-basin requires further investigation
Conclusions
The Savory Sub-basin is a frontier region with only three recently drilled petroleum exploration
wells and no seismic data Based on existing geological and geophysical data it is considered too
early to draw conclusions about the hydrocarbon prospectivity of the sub-basin at this stage and
there are several reasons why the area warrants further investigation
34
1 Thick accumulations of sedimentary rocks are present (up to 8 km thickness inferred) which
may contain source reservoir and sealing strata
2 Minor oil shows occur in Mundadjini 1 and Boondawari 1 and bitumen is present in mineral
exploration drillhole LDDH1 suggesting that hydrocarbons have migrated within the
Neoproterozoic sequence of the Savory Sub-basin Oil and bitumen are present in mineral
exploration drillhole OD23 in the Bangemall Basin immediately to the south of the Savory
Sub-basin and it is possible that source rocks from the Bangemall Basin could charge traps in
the overlying Savory Sub-basin
3 The age of sedimentary rocks in the sub-basin is still poorly constrained but some of the
Neoproterozoic sedimentary rocks located on GUNANYA and TRAINOR are within the
hydrocarbon-generation window It is possible that a significant thickness of Phanerozoic
sedimentary rocks may also be present
4 Friable sandstones with visible porosity outcrop extensively suggesting numerous potential
reservoirs
5 Significant but not intense faulting and folding has been mapped implying large structural
traps may be present
6 Evaporitic sedimentary rocks occur in several formations and may provide good source rocks
and excellent seals
35
References
APAK S N and CARLSEN G M 1997 A compilation and review of data pertaining to the
hydrocarbon prospectivity of the Canning Basin Western Australia Geological Survey
Record 199610 103p
BAGAS L GREY K and WILLIAMS I R 1995 Reappraisal of the Paterson Orogen and
Savory Basin Western Australia Geological Survey Annual Review 1994ndash95 p 55ndash63
BUSBRIDGE M 1994 Lake Disappointment Exploration Licence 451064 Third Annual
Report Lake Disappointment Diamond Drill Hole LDDH1 Normandy Exploration Limited
Western Australia Geological Survey M-series Item 7567 A41358 (unpublished)
CARLSEN G M and SHEVCHENKO S I 1997 Petroleum exploration in Proterozoic basins
using potential fields data and stratigraphic coring Australian Society of Exploration
Geophysicists 12th Geophysical Conference Handbook Sydney 1997 Preview no 66 p 83
(abstract only)
COWAN D 1995 Savory Basin quantitative magnetic interpretation Western Australia
Geological Survey S-series S10331 (unpublished)
DAISHSAT PTY LTD 1995 Operational and processing report Savory Basin gravity survey
Western Australia Geological Survey S-series S10332 (unpublished)
GARD E and GARD R 1990 Canning Stock Route a travellerrsquos guide for a journey through
history Perth Western Australia Western Desert Guides 448p
GEOLOGICAL SURVEY OF WESTERN AUSTRALIA 1996a Savory Basin first vertical
derivative of Bouguer gravity image 1250 000 Western Australia Geological Survey
GEOLOGICAL SURVEY OF WESTERN AUSTRALIA 1996b Savory Basin Bouguer gravity
image 1250 000 Western Australia Geological Survey
GHORI K A R in prep Petroleum source rock potential and thermal history Officer Basin
Western Australia Western Australia Geological Survey Record
36
GREY K 1995a Savory Basin drillhole BWB 1 (Bullen waterbore) palynology and thermal
maturation GSWA Palaeontology Report no 199512 (unpublished)
GREY K 1995b Savory Basin drillholes TWB 1 2 6 9 (Trainor waterbores) palynology and
thermal maturation GSWA Palaeontology Report no 199520 (unpublished)
GREY K 1995c Palynology of Normandy-Poseidon Lake Disappointment-1 corehole
Tarcunyah Group Paterson Orogen GSWA Palaeontology Report no 199521 (unpublished)
GREY K 1995d Savory Basin drillhole Trainor 1 (Trainor diamond drilling) palynology and
thermal maturity GSWA Palaeontology Report no 199524 (unpublished)
GREY K 1995e Savory Basin drillhole Trainor 1 (Trainor diamond drilling) Additional
Preparation of two samples GSWA Palaeontology Report no 199528 (unpublished)
GREY K 1995f Neoproterozoic stromatolites from the Skates Hills Formation Savory Basin
Western Australia and a review of the distribution of Acaciella australica Australian Journal
of Earth Sciences v 42 p 123ndash132
GREY K 1996a Savory Basin drillhole Trainor 1 (Trainor diamond drilling) Additional
samples palynology and thermal maturation GSWA Palaeontology Report no 199615
(unpublished)
GREY K 1996b Preliminary stromatolite correlations for the Neoproterozoic of the Officer
Basin and a review of Australia-wide correlations GSWA Palaeontology Report no 199615
(unpublished)
GREY K and COTTER K L 1996 Palynology in the search for Proterozoic hydrocarbons
Western Australia Geological Survey Annual Review for 1995ndash96 p 70ndash80
GREY K and STEVENS M K 1997 Neoproterozoic palynomorphs of the Savory Sub-basin
Western Australia and their relevance to petroleum exploration Western Australia
Geological Survey Annual Review for 1996ndash97 p 49ndash54
HUBBARD R J PAPE J and ROBERTS D G 1985 Depositional sequence mapping as a
technique to establish tectonic and stratigraphic framework and evaluate hydrocarbon
potential on a passive continental margin in Seismic stratigraphy II an integrated approach
37
edited by O R BERG and D G WOOLVERTON American Association of Petroleum
Geologists Memoir 39 p 79ndash91
LIBBY WG 1995 A petrological report on six samples of bore cuttings from the Savory Basin
Western Australia Western Australia Geological Survey S-series S31307 (unpublished)
MORTON JGG and DREXEL JF 1997 The petroleum geology of South Australia Vol 3
Officer Basin South Australia Department of Mines and Energy Resources Report Book
9719
MUHLING P C and BRAKEL A T 1985 Geology of the Bangemall Group mdash the evolution
of an intracratonic Proterozoic basin Western Australia Geological Survey Bulletin 128
219p
MYERS J S 1990 Precambrian tectonic evolution of part of Gondwana southwestern Australia
Geology v18 p 537ndash540
NELSON D R 1997 Compilation of SHRIMP UndashPb zircon data Western Australia Geological
Survey Record 19972 196p
PAYTON C E 1977 Seismic stratigraphy mdash applications to hydrocarbon exploration
American Association of Petroleum Geologists Memoir 26 516p
PERINCEK D 1996a The age of NeoproterozoicndashPalaeozoic sediments within the Officer Basin
of the Centralian Super-basin can be constrained by major sequence-bounding unconformities
APPEA Journal v 36 pt 1 p 350ndash368
PERINCEK D 1996b The stratigraphic and structural development of the Officer Basin
Western Australia a review Western Australia Geological Survey Annual Review 1995ndash
1996 p 135ndash148
PERINCEK D 1998 A compilation and review of data pertaining to the hydrocarbon
prospectivity of the Officer Basin Western Australia Geological Survey Record 19976
POSAMENTIER H W JERSEY M T and VAIL P R 1988 Eustatic controls on clastic
deposition 1 mdash Conceptual framework in Sea-level changes an integrated approach edited by
C K WILGUS B S HASTINGS C G St C KENDALL H W POSAMENTIER
38
C A ROSS and J C VAN WAGONER Society of Economic Paleontologists and
Mineralogists Special Publication no 42
STEVENS M K and ADAMIDES N G in prep GSWA Trainor 1 well completion report
Savory Sub-basin Officer Basin Western Australia with notes on petroleum and mineral
potential Western Australia Geological Survey Record 199612
STEVENS M K and GREY K 1997 Skates Hills Formation and Tarcunyah Group Officer
Basin mdash carbonate cycles stratigraphic position and hydrocarbon prospectivity Western
Australia Geological Survey Annual Review for 1996ndash97 p 55ndash60
SUMMONS RE and POWELL C McA 1991 Petroleum source rocks of the Amadeus Basin
in Geological and geophysical studies in the Amadeus Basin central Australia edited by R J
KORSCH and JM KENNARD Australia BMR Geology and Geophysics Bulletin 236
TRAVERSE A 1988 Palaeopalynology Boston Unwin Hyman 600p
VAIL P R MITCHUM R M Jr TODD R G WIDMIER J M THOMPSON S III
SANGREE J B BUBB J N and HATLELID W G 1977 Seismic stratigraphy and
global changes of sea level in Seismic stratigraphy mdash applications to hydrocarbon
exploration edited by C E PAYTON American Association of Petroleum Geologists
Memoir 26 516p
WALTER M R and GORTER J 1994 The Neoproterozoic Centralian Superbasin in Western
Australia the Savory and Officer Basins in The sedimentary basins of Western Australia
edited by P G PURCELL and R R PURCELL Petroleum Exploration Society of Australia
Symposium Perth WA 1994 Proceedings p851ndash864
WALTER M R GREY K WILLIAMS I R and CALVER C R 1994 Stratigraphy of the
Neoproterozoic to early Palaeozoic Savory Basin and correlation with the Amadeus and
Officer Basins Australian Journal of Earth Sciences v 41 p 533ndash546
WALTER M R VEEVERS J J CALVER C R and GREY K 1995 Neoproterozoic
stratigraphy of the Centralian Superbasin Australia Precambrian Research v 73 p 173ndash195
WILLIAMS I R 1992 Geology of the Savory Basin Western Australia Western Australia
Geological Survey Bulletin 141 115p
39
WILLIAMS I R 1995a Bullen WA (2nd Edition) Western Australia Geological Survey
1250 000 Geological Series Explanatory Notes 23p
WILLIAMS I R 1995b Trainor WA (2nd Edition) Western Australia Geological Survey
1250 000 Geological Series Explanatory Notes 31p
WILLIAMS I R and TYLER I M 1991 Robertson WA (2nd edition) Western Australia
Geological Survey 1250 000 Geological Series Explanatory Notes 36p
40
41
Appendix 1
Bibliography
Reports which are relevant to this investigation but which are not specifically cited are listed
below
BAILLIE P W POWELL C McA LI Z X and RYALL A M 1994 The tectonic
framework of Western Australiarsquos Neoproterozoic to recent sedimentary basins in The
sedimentary basins of Western Australia edited by P G PURCELL and R R PURCELL
Petroleum Exploration Society of Australia Symposium Perth WA 1994 Proceedings p
45ndash62
BRADSHAW M T BRADSHAW J MURRAY A P NEEDHAM D J SPENCER L
SUMMONS R E WILMOT J and WINN S 1994 Petroleum systems in West Australian
basins in The sedimentary basins of Western Australia edited by P G PURCELL and R R
PURCELL Petroleum Exploration Society of Australia Symposium Perth WA 1994
Proceedings p 93ndash118
CLARKE G L 1991 Proterozoic tectonic reworking in the Rudall Complex Western Australia
Australian Journal of Earth Science v38 p 31ndash44
COCKBAIN A E and HOCKING R M 1990 Phanerozoic in Geology and mineral resources
of Western Australia Western Australia Geological Survey Memoir 3 p 750ndash755
ETHERIDGE M and WALL V 1994 Tectonic and structural evolution of the Australian
Proterozoic 12th Australian Geological Convention Geological Society of Australia
Abstracts no 37 p 102ndash103
GOODE A D T 1981 Proterozoic geology of Western Australia in Precambrian of the
Southern Hemisphere Developments in Precambrian geology 2 edited by I R HUNTER
Amsterdam Elsevier p 105ndash203
GREY K and JACKSON M J 1983 A re-assessment of stromatolite evidence for the
correlation of the Late Proterozoic Neale and Ilma Beds Officer Basin Western Australia
Australia BMR Journal of Australian Geology and Geophysics v 8 p 359
42
HICKMAN A H WILLIAMS I R and BAGAS L 1994 Proterozoic geology and
mineralization of the TelferndashRudall region Paterson Orogen Geological Society of Australia
(WA Division) Excursion Guidebook no 5 56p
HOCKING R M MORY A J and WILLIAMS I R 1994 An atlas of Neoproterozoic and
Phanerozoic basins of Western Australia in The sedimentary basins of Western Australia
edited by P G PURCELL and R R PURCELL Petroleum Exploration Society of Australia
Symposium Perth WA 1994 Proceedings p 21ndash 44
JACKSON P R 1966 Geology and review of exploration Officer Basin Western Australia
Hunt Oil Company Western Australia Geological Survey S-series S26 (unpublished)
JACKSON M J 1971 Notes on a geological reconnaissance of the Officer Basin Western
Australia Australia BMR Geology and Geophysics Record 19715 30p
JACKSON M J and van de GRAAFF W J E 1981 Geology of the Officer Basin Western
Australia Australia BMR Geology and Geophysics Bulletin 206 102 p
LOWRY D C JACKSON M J van de GRAAFF W J E and KENNEWELL P J 1971
Preliminary result of geological mapping in the Officer Basin Western Australia Western
Australia Geological Survey Annual Report for 1971 p 50ndash56
MYERS J S 1990 Precambrian in Geology and mineral resources of Western Australia
Western Australia Geological Survey Memoir 3 p 737ndash750
MYERS J S SHAW R D and TYLER I M 1994 Proterozoic tectonic evolution of
Australia 12th Australian Geological Convention Geological Society of Australia Abstracts
no 37 p 312
NEDIN C and JENKINS R J F 1991 Re-evaluation of unconformities separating the
lsquoEdiacaranrsquo and Cambrian systems South Australia Palaios v 6 p 102ndash108
PHILLIPS B J JAMES A W and PHILIP G M 1985 The geology and hydrocarbon
potential of the north-western Officer Basin APEA Journal 25 (1) p 52ndash61
POWELL C McA LI Z X McELHINNY M W MEERT J G and PARK J K 1993
Paleomagnetic constraints on timing of the Neoproterozoic breakup of Rodinia and Cambrian
formation of Gondwana Geology v 21 p 889ndash892
43
POWELL C McA PREISS W V GATEHOUSE C G KRAPEZ B and LI Z X 1994
South Australian record of a Rodinian epicontinental basin and its mid-Neoproterozoic
breakup to form the Palaeo-Pacific Ocean Tectonophysics v 237 no 3ndash4 p 113ndash140
PREISS W V 1976 Proterozoic stromatolites from the Nabberu and Officer Basins Western
Australia and their biostratigraphic significance South Australia Geological Survey Report
of Investigations no 47 p 1ndash51
TOWNSON W G 1985 The subsurface geology of the western Officer Basin mdash results of
Shellrsquos 1980ndash1984 petroleum exploration campaign APEA Journal v 25 (1) p 34ndash51
WATTS K J 1982 The geology of the Townsend Quartzite Upper Proterozoic shallow water
deposit of the Northern Officer Basin Western Australia Perth University of Western
Australia BSc honours thesis (unpublished)
WELLS A T and KENNEWELL P J 1974 Evaporite exploration in the Officer Basin
Western Australia at the Madley Diapirs Australia BMR Record 1974194 (unpublished)
WILLIAMS I R and MYERS J S 1990 Paterson Orogen in Geology and mineral resources
of Western Australia Western Australia Geological Survey Memoir 3 p 274ndash286
WILLIAMS I R 1990 Savory Basin in Geology and mineral resources of Western Australia
Western Australia Geological Survey Memoir 3 p 329ndash334
WILLIAMS I R 1994 The Neoproterozoic Savory Basin Western Australia in The
sedimentary basins of Western Australia edited by P G PURCELL and R R PURCELL
Petroleum Exploration Society of Australia Symposium Perth WA 1994 Proceedings p
841ndash850
WILSON R B 1967 Woolnough Hills and Madley diapiric structures Gibson Desert WA
APEA Journal v 7 p 94ndash102
44
Appendix 2
Meteorological data (from Bureau of Meteorology Perth 1994)
Table 21 Wiluna rainfall (mm)
Year Jan Feb Mar Apr May Jun Jul Aug Sept Oct Nov Dec
1975 0 45 446 309 306 59 276 4 34 886 638 164 1976 16 154 12 138 53 16 34 62 12 238 0 2 1977 44 0 66 74 68 95 24 363 1 58 12 727 1978 234 522 94 16 0 96 367 24 16 353 185 45 1979 19 173 122 88 91 4 0 246 58 0 169 114 1980 148 764 68 1081 259 626 629 06 56 02 174 0 1981 123 476 192 32 196 118 44 74 14 0 28 312 1982 374 705 206 244 1079 92 02 143 368 526 368 118 1983 1 112 928 248 0 212 56 32 5 1 42 496 1984 149 7 342 84 836 0 348 132 224 04 16 172 1985 596 483 0 166 556 0 514 56 0 0 4 0 1986 0 154 35 0 0 1085 23 01 239 137 0 04 1987 1204 119 19 89 17 575 154 126 07 1 0 398 1988 46 202 164 13 388 0 202 104 0 0 224 1309 1989 207 234 26 703 278 536 57 0 01 0 144 02 1990 1035 23 281 46 126 53 94 218 44 9 42 0 1991 48 0 41 45 0 472 297 12 0 1 0 7 1992 112 96 1025 1227 323 65 04 174 0 132 48 4 1993 0 697 0 202 445 0 12 306 18 05 14 33 Mean 25 35 22 27 27 25 18 12 6 13 13 21
JAN FEB MAR APR MAY JUN JUL AUG SEP OCT NOV DEC0
10
20
30
40
Mea
n R
ain
fall
(mm
)
Month
Mean monthly rainfall in Wiluna
MKS41 140498
45
Table 22 Wiluna minimum temperature (degC)
Year Jan Feb Mar Apr May Jun Jul Aug Sept Oct Nov Dec
1975 ndash 23 203 15 94 63 71 62 103 124 169 205 1976 242 229 194 15 10 63 59 73 95 143 16 228 1977 243 25 197 148 96 95 56 86 102 ndash 188 23 1978 241 232 203 18 102 64 76 8 9 152 19 205 1979 255 226 216 167 83 6 59 79 97 145 198 223 1980 255 226 231 155 134 83 68 75 121 108 193 223 1981 245 216 19 182 119 6 54 78 138 159 163 218 1982 232 224 177 16 ndash ndash 37 111 112 164 209 225 1983 235 24 197 147 112 88 39 88 121 162 189 219 1984 241 243 191 156 ndash 72 66 7 95 161 182 211 1985 244 231 ndash 159 98 65 71 73 117 147 205 ndash 1986 ndash 229 226 155 93 96 43 49 10 122 ndash 219 1987 ndash 217 183 175 85 77 68 68 112 ndash ndash 221 1988 238 214 209 178 111 ndash ndash 86 104 157 171 195 1989 ndash 237 199 165 107 67 44 61 107 131 187 ndash 1990 232 ndash 211 155 118 62 57 87 102 149 195 22 1991 26 256 217 168 122 101 78 ndash 113 18 168 219 1992 227 227 214 169 102 98 59 69 ndash 125 159 196 1993 241 218 196 171 103 ndash 49 68 88 128 192 211 Mean 24 23 20 16 10 8 6 8 11 14 18 21
NOTE Dashes indicate data unavailable
JAN FEB MAR APR MAY JUN JUL AUG SEP OCT NOV DEC0
10
20
30
40
Month
MKS43 140498
50
Mean monthly minimum temperatures at Wiluna
Mea
n T
emp
erat
ure
(degC
)
46
Table 23 Wiluna maximum temperature (degC)
Year Jan Feb Mar Apr May Jun Jul Aug Sept Oct Nov Dec
1975 ndash 349 326 281 247 201 197 212 256 248 31 344 1976 374 369 346 297 248 206 208 225 265 287 313 388 1977 397 392 352 296 234 212 222 244 ndash 308 337 383 1978 378 345 346 316 242 195 176 205 231 295 334 356 1979 403 36 364 295 ndash ndash ndash 193 242 318 359 373 1980 392 342 377 275 24 176 179 233 292 288 349 391 1981 385 346 337 342 242 178 201 224 30 326 326 369 1982 372 359 315 307 ndash ndash 196 253 252 305 353 379 1983 381 389 327 272 263 222 187 248 287 321 336 366 1984 378 393 322 299 226 215 178 214 234 ndash 336 364 1985 40 366 ndash 294 224 216 205 212 284 307 355 ndash 1986 ndash 383 372 307 ndash 193 166 196 261 277 ndash 382 1987 ndash 339 328 305 21 202 214 218 275 ndash ndash 374 1988 388 365 353 301 23 ndash ndash 228 283 334 31 33 1989 ndash 375 339 285 238 179 181 219 275 298 336 ndash 1990 368 ndash 36 309 268 19 188 205 274 309 373 393 1991 414 416 363 315 268 206 21 ndash 279 338 332 368 1992 363 383 336 263 213 178 213 197 ndash 285 313 359 1993 396 357 344 301 221 ndash 197 215 253 294 347 362 Mean 39 37 34 30 24 20 20 22 27 30 34 37 NOTE Dashes indicate data unavailable
JAN FEB MAR APR MAY JUN JUL AUG SEP OCT NOV DEC0
10
20
30
40
Month
MKS42 140498
50
Mean monthly maximum temperatures at Wiluna
Mea
n T
emp
erat
ure
(degC
)
47
Appendix 3
Table 31 Summary of palynological results
Drillhole Depth (m) F no(a) GSWA no Lithology Formation Assemblage TAI(b)
BWB 1 74ndash75 F49668 135741 dark-grey siltstone basalt Jilyilli gt5 BWB 1 98ndash100 F49669 135742 dark-grey siltstone basalt Jilyilli gt5 BWB 1 121ndash122 F49670 135743 dark-grey siltstone basalt Jilyilli gt5 TWB 1 86ndash87 F49671 135631 dark-grey siltstone McFadden 3+ TWB 1 104ndash105 F49672 135632 dark-grey siltstone Cornelia 3+ TWB 1 121ndash122 F49673 135633 dark-grey siltstone Cornelia 4 TWB 2 14ndash15 F49674 135634 dark-grey siltstone Skates Hills 3+ TWB 6 49ndash50 F49675 135675 dark-grey siltstone Cornelia 1 3+ TWB 9 49ndash51 F49676 135704 dark-grey siltstone Brassey Range 1 3+ Trainor 1 37497- F49733 138939 black mudstone with Cornelia 5 37509 light-grey siltstone Trainor 1 3809 F49734 138940 dark-grey and black Cornelia 4- laminated mudstone Trainor 1 4170 F49735 138941 black unlaminated mudstone Cornelia 4- Trainor 1 4950 F49851 139501 dark-grey indurated siltstone Cornelia 5 Trainor 1 6032 F49852 139502 dark- and light-grey Cornelia 5 indurated siltstone Trainor 1 6434 F49853 139503 greenish indurated finely Cornelia 5 laminated siltstone LDDH 1 270 F49678 138934 dark-grey siltstone interbeds Waters 1 3+ in enterolithic evaporite Tarcunyah Gp LDDH 1 277 F49679 138935 dark-grey siltstone in cavity Waters 1 3+ in enterolithic evaporite Tarcunyah Gp
NOTES (a) GSWA Fossil Catalogue number (b) TAI = Thermal Alteration Index of Traverse (1988 plate 1)
48
Appendix 4
Savory Sub-basin quantitative magnetic and gravity interpretation (extracted from Cowan 1995)
Summary
A program of quantitative aeromagnetic interpretation has been completed on BMRAGSO data from the Savory Sub-
basin Western Australia Quantitative aeromagnetic interpretation utilized the 3D Euler deconvolution method
supported by wavenumber filtering and image processing The results have provided useful information on structural
trends and depth to magnetic sources in a structurally complex area Depth to magnetic source analysis has provided
information on intra-sedimentary magnetic sources as well as basement rocks
The results of the interpretation support previously identified depocentres However the presence of magnetic
sources at several levels makes it very difficult to produce a reliable magnetic basement depth contour map It is
considered more productive to work with the 3D Euler colour circle plots and images rather than trying to contour the
results It would be necessary to carry out a full-scale interpretation of the BMRAGSO profile data to improve on the
3D Euler results The regional gravity was found to be useful in interpreting the regional setting of the area although
the very wide data spacing limits quantitative use of the data The gravity data show quite a complex picture with
limited consistent correlation between gravity features and basin structures This suggests that gravity anomalies
reflect changes in density of the basement rocks rather than basement topography especially in the northern part of the
basin
It is recommended that the GSWA investigate access to company confidential high-resolution aeromagnetic data
prior to planning further aeromagnetic surveys Private companies have flown large parts of the northern half of the
area as part of their diamond exploration program Additional gravity coverage of the area may be more cost effective
than magnetic surveys as the gravity data provides more information on changes within the sedimentary section
Introduction
The main use of aeromagnetic data in petroleum exploration has been the determination of magnetic basement
topography although there has been increasing interest in analysis of intra-sedimentary magnetic anomalies
intrabasement and suprabasement magnetic anomalies These anomalies are used to determine depth to magnetic
basement rocks and hence determine the thickness of the sedimentary sequence Unfortunately interpretation of the
intrabasement and suprabasement magnetic anomalies is non-unique in terms of position and size of causative sources
because of the inherent ambiguity of potential-field methods However this ambiguity can be reduced by placing
49
constraints on source geometry and magnetization and by using geological and other geophysical data to constrain
the solution
Before 1970 most depth-determination techniques involved graphical determination of slopes of selected
magnetic anomalies and application of various empirical factors to convert the slopes into depth estimates Geological
Society of America Memoir 47 Interpretation of Aeromagnetic Maps by Vacquier et al (1951) was a landmark for
this type of interpretation
Automated interpretation procedures have played an increasingly important role in depth interpretation and a
wide range of techniques have been developed Many of these techniques are designed for application to located data
profiles and assume a two-dimensional geometry However there has been renewed interest in techniques applicable
to gridded data
Two distinct types of method can be recognized In the first case often described as discrete methods individual
isolated magnetic anomalies are interpreted and the results used to produce a map of basement relief In the second
case often described as continuous methods areas of data containing a number of anomalies are interpreted
statistically to produce direct output of basement depths
The discrete methods usually involve a semiautomatic initial phase which generates a large number of possible
depth solutions and an interactive second phase to screen and select acceptable solutions The advantage of this
approach is that the interpreter can select features that are relatively free from interference from adjacent anomalies
and consider all aspects of a particular magnetic anomaly The disadvantage is that interpretation can be very time
consuming as a wide range of depths are usually possible depending on the initial model chosen and a significant
amount of effort is needed to select the correct model In the case of the Savory Sub-basin dataset we encountered
problems in separating basement related effects from the effects of shallower intrasedimentary magnetic sources
Because of these problems we have concentrated on displaying the Euler results accompanied by separation filter
images of the data to show the shallower effects and deeper effects rather than trying to refine a 3D Euler
deconvolution depth-to-crystalline-basement contour
The continuous methods are very direct provided that the rather restrictive assumption can be made that all
anomalies are due to lateral magnetization changes due to basement topography This means that shallow effects and
large intrabasement anomalies must be removed from the data This involves judgement and skill as it is necessary to
distinguish between the lower amplitude suprabasement anomalies due to basement topography and the larger
intrabasement anomalies reflecting magnetization changes within the basement These methods were not considered
suitable for the Savory Sub-basin magnetic dataset but were used to invert the gravity data
50
Limitations of magnetic and gravity interpretation
Interpretation of the area is limited by a shortage of information on the nature and physical properties of the deeper
sedimentary sequence and the underlying basement rocks However using techniques such as cross-correlation of
gravity and pseudo-gravity data it is possible to try to differentiate between anomalies relating to basement and those
related to the sedimentary sequence
Gravity anomalies reflect changes within the sedimentary sequence as well as basement condition These
changes in density of sedimentary rocks produce gravity anomalies without a corresponding magnetic anomaly hence
the complementary nature of gravity and magnetic surveys The main use of magnetics is to determine depth to
magnetic basement and any intra-sedimentary volcanic rocks or intrusives whereas gravity provides much more
general information on the sedimentary sequence
Unfortunately interpretation of gravity anomalies is complicated since they can be due to a number of geological
features including
bull major basement faults
bull basement highs
bull igneous intrusions within the basement
bull sedimentary basins which may or may not be isostatically compensated
bull intra-sedimentary volcanics and associated plutonic centres
Two major problems affect the interpretation of both magnetic and gravity data
1 The inherent ambiguity of potential-field data There is no unique solution to any measured gravity or magnetic
anomaly and theoretically there will be an infinite number of source geometry and magnetizationdensity
combinations which will fit the observed data This means that any a priori information which helps to select a
suitable model is very useful
2 Measured anomalies are the summation of effects from different depths For example an observed gravity profile
may contain contributions from shallow sources (density variations within the sedimentary basin) intermediate
depth sources (density variations due to large igneous intrusions within the basement) and deep sources (crustal
thinning producing a mantle anomaly) Separation of these component responses is the regionalresidual problem
which we solve using spectral analysis and differential upward continuation-based separation filtering
Regional setting and interpretation overview
The area studied includes parts of BALFOUR DOWNS (SF51-9) RUDALL (SF51-10) ROBERTSON (SF51-13) GUNANYA
(SF51-14) COLLIER (SG50-4) BULLEN (SG51-1) TRAINOR (SG51-2) MADLEY (SG51-3) NABBERU (SG50-5)
STANLEY (SG51-6) and HERBERT (SG51-7) 1250 000 sheets Broadly the area lies between latitudes 22deg00rsquondash25deg30rsquoS
and longitudes 119deg30rsquondash123deg30rsquoE
51
Regional gravity
The AGSO regional gravity data (at nominal 11 km spacing) was gridded at a 4 km mesh spacing using a minimum-
curvature algorithm Bouguer gravity values in the area are negative reflecting mass deficiency at depth and range
from -84 mgals to -25 mgals
A Bouguer gravity colour image is shown as Figure 41 A residual grid was produced by removing a fifth-order
orthogonal polynomial from the Bouguer data but did not add to the interpretation
120deg 121deg 122deg 123deg
23deg
24deg
25deg
-25
-84
50 km
MKS46 180598
mgal
Figure 41 Regional Bouguer gravity (BMRAGSO data) gridded at 4 km
52
The data show a complex pattern of positive and negative anomalies with no clearly defined trends Correlations
with aeromagnetic data and known basin structures are poor A vague north-northwest linear trend appears to coincide
with the Marloo Fault (Figure 42) A prominent negative anomaly appears to coincide with the Blake Fold and Fault
Belt depocentre and continues as a narrower negative anomaly to the east until it widens out again near the edge of the
basin Elsewhere the gravity data show little correlation with known basin structures and it is likely that especially in
the north of the area gravity anomalies are due to density changes in the basement rather than changes in basement
topography
Production of wavelength-filtered residual gravity plots and vertical gradient plots showed very patchy aliased
data reflecting poor sampling in much of the area
Regional magnetics
The AGSO regional aeromagnetic data were gridded at a 400 m mesh spacing using a minimum-curvature algorithm
(Figure 43) Most of the data has a line spacing of 1600 m with small areas of 1 km spacing The quality of the data is
acceptable for regional interpretation but is not adequate for detailed analysis The accuracy of the flight path is rather
variable reflecting the vintage of the data and the noise envelope of the data is poor by modern standards Problems
were also encountered in joining different map sheets
The magnetic anomaly pattern over the south and west part of the area shows a strong high frequency signature
reflecting the presence of widespread basic sills and dykes Some of the major north-northeasterly trending dykes can
be traced over considerable distances
Discontinuous high-frequency anomalies extend as a northwest-trending zone through the centre of the area and
this zone includes a conspicuous circular magnetic anomaly which is probably a ring complex
The northern and eastern parts of the area are characterized by long-wavelength deep-seated basement magnetic
anomalies with 120deg and 150deg trends dominant The Marloo and Perentie Faults (Figure 42) appear as distinct linear
zones and offsets A prominent easterly trending negative anomaly in the northwest of the area appears to swing round
to the southeast and may separate different basement blocks One possible interpretation is that this very deep seated
anomaly separates areas of Archaean and Proterozoic basement
Regional geology
The regional geology is described in Williams (1992) The GSWA provided a digitized version of Plate 2 from this
Bulletin the structural interpretation map to use as an overlay (Figure 42)
53
Pp
Pp
PSd
PSd
PSd
PSd
PSd
PSo
PSt
PSt
PSf
PSf
PSf
PSb
PSb
PSb
PSsPSs
PSs
PSb
PSm
PSp
PSc
PSc
PSw
PSw
PSw
PSg
PSr
PSj
PSg
PM
Pk
PY
PY
PSd
L
L
L
L
L
L
L
LL
L
L
L
LL
L
LL
L L
LL
L L
L
L
L
L
L
L
L
LL
L
L
BLAKEDEPOCENTRE
MA
RLO
O
FAU
LT
PERENTIEFAULT
50 km
MKS39120598
120deg 121deg 122deg 123deg
25deg
24deg
23deg
Approximate boundaryof aeromagnetic interpretation
PML
PSgL
PSjL
PML
PSpL
PML
PML
PSfL
PSfL
PSpL
LPc
LPcLPcPSrL
LPA
Durba Sandstone
Woora Woora Formation
McFadden Formation
Tchukardine Formation
Boondawari Formation
Skates Hills Formation
Mundadjini Formation
Coondra Formation
Spearhole Formation
Watch Point Formation
Jilyili Formation
Brassey Range Formation
Glass Spring Formation
Paterson Formation
Yeneena Group
Karara Formation
Cornelia Formation
Kahrban Subgroup
Bangemall Group
Fault
Formation boundary
PSdL
PSoL
PSfL
PStL
PSbL
PSsL
PSmL
PScL
PSpL
PSwL
PSjL
PSrL
PSgL
Pp
PYL
PkL
LPc
LPA
PML
Savory Group Other Units
PYL
Figure 42 Regional geology and structure map (after Williams 1992)
54
120deg 121deg 122deg 123deg
23deg
24deg
25deg
5820
3750
MKS47 180598
nT
50 km
Figure 43 Regional aeromagnetic data total magnetic intensity (BMRAGSO data) gridded at 400 m
Analysis
3D analysis
3D Euler deconvolution was used as the primary depth-determination method The advantage of this approach is that
consistent solutions can be obtained over the entire area with minimal assumptions about source geometries Euler
deconvolution of gridded data is used for positional information and estimation of depth to top of source Euler
55
deconvolution yields a large number of depth solutions which have to be screened to reject spurious solutions Results
are plotted as circles in eight depth ranges with radius proportional to depth and colour coded
The 400 m total magnetic intensity grid was used for the analysis Horizontal gradients in x and y and the vertical
gradient were calculated 3D Euler deconvolution was tested on the 400 m gridded data using windows of 9 times 9 and
11 times 11 and 16 times 16 data points and structural indices 05 (fault) and 10 (sill or dyke) It was concluded that the
16 times 16 window produced the best results overall and final plots were produced for the 16 times 16 window and structural
index 05 (Fig 44) Results were very good over the northern and central parts of the area showing magnetic sources
Figure 44 Depth to magnetic source 3D Euler deconvolution 16 times 16 window of 400 m gridded data structural index 05
56
at several different levels Unfortunately in the extreme south of the area shallow intrasedimentary magnetic sources
(sills and dykes) dominated the inversion and the results contained few basement solutions
In order to reduce these problems the 400 m gridded data were filtered using a separation filter based on
interpretation of the log-energy spectrum The 3D Euler method was run on the filtered data in order to generate more
basement-depth solutions Results for the deep-separation filter data were gridded and presented as a colour image in
Cowan (1995) Attempts to grid the Euler output were unsatisfactory and it is considered safer to interpret the 3D
Euler depth plots The 3D Euler depth results from the separation-filter run should be analysed with care as perfect
separation of the basement can never be achieved and there will always be some contamination from sources at
different levels
The results of original total magnetic intensity 3D Euler depth estimation for structural index 05 using a 16 point
window have been plotted at 1500 000 scale (not included in this publication but available in Cowan (1995) from the
GSWA Library as S10331) and as reduced A4 colour circle plots (Figure 44)
The results of deep-basement 3D Euler depth estimation for structural index 05 using a 16 point window have
been plotted as a colour image at 1500 000 scale and as an A4 image (not included in this publication)
2D analysis
Two equispaced profiles were interpolated with a 50 m station interval from the AGSO-located data profiles for the
BULLEN 1250 000 sheet The interpolated profiles were analysed using 2D Euler deconvolution and Werner
deconvolution Results are included in Cowan (1995) and show the use of these methods for more detailed analysis
Filtered data
In order to reconcile 3D Euler results from shallow basement and intrasedimentary magnetic sources we produced
several separation-filtered maps and images We found the shallow-layer double-separation filter (Figure 45) to be
very effective for shallow sources and the deep-layer standard-separation filter (Figure 46) for the basement layer
Gravity and magnetic data correlation
Both lsquoreduced to the polersquo (RTP) magnetics (Figure 47) and pseudo-gravity data (Figure 48) were produced as part of
the reconciliation of gravity and magnetic signatures In both cases the filtering operations assumed magnetization by
induction in the present Earths field The RTP data are fairly similar to the total magnetic intensity The pseudo-
57
gravity data are dominated by a northwest-trending strong positive anomaly and there is little correlation with the
Bouguer gravity data
The poor magneticgravity correlation is confirmed by cross-correlation of the RTP magnetics and the gravity
gradient The correlation plot in Figure 49 shows little coherent response with numerous zones of positive and
negative correlation
Figure 45 Regional aeromagnetic data shallow layer separation filter (BMRAGSO data) gridded at 400 m
Results
In the north and east of the area on the Wells Foreland Sub-basin trend (refer to Figure 1 main text) we see a range
of quite deep 3D Euler depths and several trend directions with north-northwesterly dominant There are relatively few
shallow intrasedimentary solutions in this zone
The second area of deep 3D Euler solutions lies over the Blake depocentre (Figure 43) with several trend
directions
Elsewhere the 3D Euler results are dominated by shallow intrasedimentary depth solutions reflecting mainly the
dolerite sills dykes and the ring complex However where we do see basement-related solutions in the south and
west of the area they appear to be shallower than those noted for the Wells Foreland Sub-basin and the Blake
depocentre
58
Figure 46 Regional aeromagnetic data deep-layer separation filter (BMRAGSO data) gridded at 400 m
Figure 48 Regional aeromagnetic data pseudo-gravity transform (BMRAGSO data) gridded at 400 m
Figure 47 Regional aeromagnetic data reduced-to-pole (BMRAGSO data) gridded at 400 m
Figure 49 Regional aeromagnetic and gravity data gravitymagnetic correlation using RTP magnetics and gravity gradient (BMRAGSO data) gridded at 4 km
59
This subdivision of the area into two zones of deep solutions is consistent with interpreted depocentres
However the interference between sources at different levels and the complexity of the magnetic response of the
basement rocks precludes more refined interpretation at this stage
The area of deep 3D Euler solutions over the Blake depocentre correlates with the pronounced negative gravity
anomaly discussed in the gravity interpretation section Using a density contrast of -015 gcc the negative gravity
anomaly could indicate up to 6ndash8 km of low-density sedimentary rocks depending on assumptions about the regional
field
The area of deep 3D Euler solutions over the Wells Foreland Sub-basin has a complex gravity expression and no
clear basin structure emerges from inversion of these data As noted previously it is likely that observed gravity
anomalies reflect contrasts in basement density rather than basement topography
Separation filtering applied to the magnetic data helps to enhance the intrasedimentary magnetic signature and to
give a better impression of the basement magnetic signature even though separation of the basement response is not
perfect
Conclusions
Quantitative aeromagnetic interpretation using 3D Euler deconvolution supported by wavenumber filtering and image
processing has been successful in providing structural trend and depth information for the Savory Sub-basin
Quantitative magnetic interpretation has revealed two zones of relatively deep magnetic basement beneath the
Wells Foreland Sub-basin and the Blake depocentre
This analysis of the magnetic data supports interpreted depocentres but the complexity of the basement magnetic
signature and interference from sources at different depths precludes further refinement to a map of basement
topography
Regional gravity proved to be very useful in understanding the regional setting of the area and in providing
support for aspects of the interpretation The gravity data support the interpretation of the Blake depocentre
suggesting up to 6ndash8 km of low-density sedimentary rocks
The deep structure of the Savory Sub-basin area is obviously complex with different areas underlain by
Archaean and Proterozoic basement and with the Capricorn suture occurring in the centre of the area
60
Recommendations
The quantitative magnetic interpretation needs to be reconciled with geological models available for the area
In particular the zones tentatively identified as areas with thick sedimentary rocks the Wells Foreland Sub-
basin and the Blake depocentre need to be investigated
Cross sections should be prepared across the basin for joint magneticgravity modelling especially for the Blake
depocentre It is important to be able to explain the strong negative gravity anomaly in this area
In view of the effects of basement density contrasts on the gravity field for the northern part of the area we think
that additional gravity interpretation and acquisition of new gravity data may not be justified as they will not
contribute significantly to understanding basin evolution and structure
It is recommended that GSWA try to get access to company confidential high-resolution aeromagnetic data
rather than flying new surveys The GSWA might offer to fund flying of new infill areas as a bargaining point
References
The original text of this report by Cowan (1995) and 1500 000 scale maps are filed in the GSWA Library under
S10331
COWAN D 1995 Savory Basin quantitative magnetic interpretation Western Australia Geological Survey S-series
S10331 (unpublished)
VACQUIER V STEENLAND N C HENDERSON R G and ZIETZ I 1951 Interpretation of aeromagnetic
maps The Geological Society of America Memoir 47 151p
WILLIAMS I R 1992 Geology of the Savory Basin Western Australia Western Australia Geological Survey
Bulletin 141 115p
61
Appendix 5
Geochemistry
MKS38 250398
Saturate FractionC12+ GLC
1217
Pr18
Ph
22
31CSR WELL-13 315m Cuttings
Figure 51 Canning Stock Route Well 13 gas chromatograph of extract of auger drill sample
12
17
18
22
31
Pr Ph
LDDH 1 6623m CoreSaturate FractionC12+ GLC
MKS35 240398
Figure 52 Gas chromatograph of extract from core sample at 6623 m LDDH1
62
Table 51 Canning Stock Route Well 13 auger drill samples
GSWA sample Drill depth (m)(a) Comments
135601 150 At watertable 135602 203 (all samples consist 135603 310 of sand mud and water) 135604 315 At total depth
NOTE (a) Datum for drill depth is the top of sediment fill in the well which is 155 m below ground level (ie the total depth of 315 m is 47 m below ground level)
Table 52 Canning Stock Route Well 13 gas chromatography data for 315 m depth sediment sample
Parameter Value
Weight of rock extracted (grams) 945 Total extract (ppm) 519 n-Alkane distribution n-C12 07 n-C13 23 n-C14 26 n-C15 22 n-C16 19 n-C17 14 i-C19 23 n-C18 14 i-C20 08 n-C19 11 n-C20 16 n-C21 25 n-C22 29 n-C23 70 n-C24 42 n-C25 95 n-C26 43 n-C27 83 n-C28 38 n-C29 87 n-C30 31 n-C31 273 Alkane compositional data Pristane phytane ratio 279 Pristane n-C17 ratio 161 Phytane n-C18 ratio 059 CPI (1)(a) 284 CPI (2) 209 (C21 + C22) (C28 + C29) 043
NOTE (a) CPI= Carbon preference index
63
Table 53 LDDH1 extract liquid chromatography data for 6623 m concentration
Rock extracted Total extract (grams) (ppm)
702 313
NOTE ppm= parts per million
Table 54 LDDH1 saturate gas chromatography data of core for 6623 m alkane composition
Pristane Pristane Phytane (a) CPI (1) CPI (2) (C21+C22) Phytane n-C17 n-C18 (C28+C29)
103 026 024 103 102 325
NOTE (a)CPI = carbon preference index
Table 55 LDDH1 saturate gas chromatography data of core for 6623 m n-alkane distributions
Parameter Value
n-C12 17 n-C13 38 n-C14 55 n-C15 60 n-C16 65 n-C17 74 i-C19 19 n-C18 78 i-C20 19 n-C19 80 n-C20 79 n-C21 71 n-C22 64 n-C23 57 n-C25 43 n-C24 38 n-C27 31 n-C28 23 n-C29 19 n-C30 12 n-C31 10
64
Appendix 6
Table 61 Summary of data from Trainor waterbores (TWB) and Bullen waterbores (BWB)
Well AMG Elevation TD Status(b) Completion details Water Salinity Water level Flow rate Depth to consolidated AGD84 GL (m) (m) struck mgl(c) (m) (LHr) lithology aquifer(e) Z51(a) Interval (m) (100 mm PVC) (m) (mgl)(d)
TWB 1 473660E 453 122 comp 0ndash75 plain 63 7 300 24 2 880 12 m 7287404N 75ndash93 slotted (9 260) McFadden Fm 93ndash99 plain TWB 2 472 977E 475 23 abd nil 15 m 7285877N Skates Hills Fm dry TWB 3 473259E 475 50 abd nil 7 m 7285849N Skates Hills Fm dry TWB 4 463225 E 445 50 comp 0ndash22 plain 35 7 200 55 3 600 0 m 7286143N 22ndash34 slotted (8 140) Tertiary sand and gravel 23ndash60 plain TWB 5 463095E 445 31 comp 0ndash19 plain 13 26 000 655 3 600 Tertiary sand and gravel 7277721N 19ndash25 slotted (36 700) 25ndash31 plain TWB 6 457013E 455 50 comp 0ndash42 plain 38 920 119 600 0 m 7274352N 42ndash48 slotted (1 030) Cornelia Fm ss TWB 7 453739E 475 26 susp 0ndash2 plain 11 9 300 48 4 500 0 m 7263891N (10 500) Tertiary sand TWB 8 433893E 535 60 susp 0ndash2 plain 47 8 500 gt46 1 200 0 m 7245991N (10 900) Tertiary sand and Brassey Range Fm ss TWB 9 437219E 505 51 comp 0ndash47 plain 45 1 000 58 600 1 m 7235905N 47ndash51 slotted (990) Brassey Range Fm ss TWB 10 434927E 495 32 susp 0ndash2 plain 235 450 120 0 m 7225875N (500) Dolerite
65
BWB 1 287337E 580 122 abd Nil 1 m 7245861N Jilyili Fm dry BWB 2 288346E 545 50 comp 0ndash26 plain 15 630 3 29 000 0 m 7240423N 26ndash38 slotted (730) Tertiary sand and gravel 38ndash50 plain BWB 3 305637E 545 50 abd 19 8 800 43 7 200 0 m 7240423N (10 550) Tertiary ss BWB 4 320167E 515 445 comp 0ndash20 plain 9 980 445 24 000 0 m 7248097N 20ndash32 slotted (1 190) Tertiary ss 32ndash44 plain BWB 5 353393E 545 20 susp 0ndash2 plain 45 (970) 1 m 7238934N Basalt
NOTES (a) GPS accuracy ~ 150 m (b) Comp = completed abd = abandoned susp = suspended (c) Salinity from conductivity (d) Analysis total dissolved solids (e) Fm = Formation ss = sandstone
21
50 km
120deg 121deg30 123deg
25deg
24deg
23deg
22deg
Greater Officer Basin
Savory Sub-basin
1
2
3
4
6
8
3 Seismic line (prefixed N83-00)
Aeromagnetic survey
GS
WA
Sav
ory
1995
gra
vity
sur
vey
Gravity survey
MKS34270398
Figure 8 Locations of aeromagnetic and gravity surveys (other than regional BMRAGSO data)
22
sandstones in two petroleum wells in the northwest of the sub-basin and bitumen and oil shows
elsewhere in the region indicate that oil has been generated and migrated through the sub-basin
Source rocks
Source potential is considered to be the major exploration risk in the Savory Sub-basin although
minor oil shows in Mundadjini 1 and Boondawari 1 indicate that at least some oil has been
generated and migrated into potential reservoirs within the sub-basin Sandstone is the
predominant lithology observed in outcrop Outcrops of fine-grained lithologies in the basin are
rare because of intense surface weathering and erosion Only about 8 of the surface area of the
sub-basin is exposed bedrock and recessive lithologies (such as shale evaporite and friable
sandstone) may be present although they rarely outcrop
Outcrops of stromatolitic dolomite with associated cauliflower chert and cubic pseudomorphs
interpreted as being after halite indicate that evaporitic environments are present within the
Mundadjini Skates Hills and Boondawari Formations Evaporitic minerals are also present in
drillhole LDDH1 in the Tarcunyah Group
In 1995 GSWA drilled a continuous-core diamond drillhole (Trainor 1) in the sub-basin on
TRAINOR to a depth of 709 m to test for source rocks thus providing the first such data for the sub-
basin The drillhole intersected flat-lying clastics and carbonates of the McFadden Formation (9ndash
83 m) overlying indurated mudstones of the Cornelia Formation (83ndash709 m total depth) dipping at
about 40deg Of the six samples analysed from the Cornelia Formation in this drillhole the five
located between 375 and 6032 m depth have TOC values exceeding 05 (range 066ndash365)
Rock-Eval pyrolysis of these five samples indicates that they are at best in the dry-gas thermal
stage and as a result of their high level of maturation (Stevens and Adamides in prep) have poor
remaining hydrocarbon-generating potential Although the Cornelia Formation is overmature at
Trainor 1 the high TOC values are encouraging as it is likely that this sequence is less mature
elsewhere in the sub-basin
The Mundadjini Formation contains potential source rocks that comprise marine mudstones
with evaporitic minerals present in parts Thin dark mudstones were intersected in the Mundadjini
Formation in Akubra 1 In Mundadjini 1 and Boondawari 1 however the mudstones appear to be
too oxidized to have source potential
The Boondawari Formation also may be a source rock as it contains black mudstones The
unit is laterally equivalent to the Pertatataka Formation of the Amadeus Basin and the Ungoolya
23
Group of the Officer Basin in South Australia both of which have some source potential
(Summons and Powell 1991 Morton and Drexel 1997) Samples from the Dey Dey Mudstone of
the Ungoolya Group generally have poor TOC values (average 011 range 003ndash081)
moderate hydrogen index (HI) values (100ndash382) and poor to fair genetic potential with a
maximum of 292 kg hydrocarbon per tonne of source rock (Morton and Drexel 1997)
Stromatolitic dolomites and mudstones at the top of the Boondawari Formation and within the
Skates Hills Formation are potential source rocks Stromatolitic dolomite and evaporitic rocks
deposited in a marginal marine to sabkha environment are considered to have good potential to
generate and preserve organic carbon without requiring a deep-water setting (Stevens and Grey
1997) Such conditions are recognized in the Skates Hills Formation and in the upper parts of the
Tarcunyah Group
Maturity
Knowledge of the maturity of sedimentary rocks within the Savory Sub-basin is still limited From
a review of palynological studies Grey and Stevens (1997) report that the thermal maturity
inferred from the Thermal Alteration Index (TAI) of 3+ from Supersequence 1 age palynomorphs
in TWB 6 TWB 9 and LDDH1 is within the hydrocarbon window (Appendix 3) In Phanerozoic
spores and pollen a TAI of 3+ approximately equates to the end of liquid petroleum generation
and the start of dry gas generation and to a vitrinite reflectance of about 13 (Traverse 1988)
However the use of TAI for estimating thermal maturity from Neoproterozoic palynomorphs
requires calibration
In Trainor 1 the Cornelia Formation contains organically rich claystones between 375 and
6032 m depth Based on Rock-Eval maturity data (Stevens and Adamides in prep) and the dark
colour of poorly preserved organic material (Grey 1995de 1996) with TAI 4- to 5 all samples
had a high level of maturation with at best dry-gas generating potential remaining In contrast
drillhole LDDH1 on GUNANYA recorded lower levels of maturity (TAI values of 3+) with two of
sixteen samples from the Tarcunyah Group having greater than 1 TOC (Grey 1995abc Grey
and Cotter 1996) Organic petrology and Rock-Eval maturity data for samples from LDDH1
indicate that the section above 500 m is within the oil-generative window whereas below 500 m
the rocks are within the gas window (Ghori in prep Fig 9 Appendix 5)
Waterbores TWB 1 2 6 and 9 which are located on TRAINOR in the southeast of the sub-
basin all had organic matter with TAI values of 3+ from the McFadden Skates Hills Cornelia
and Brassey Range Formations respectively
24
100
200
300
400
500
600
700
Oil
gene
ratin
g
Gas
gene
ratin
g
Fai
r
Fai
r
Poo
r
Poo
r
Goo
d
Imm
atur
e
Oil
win
dow
Oil
win
dow
Imm
atur
e
01 0110 10 0 150 300 440 480 1
Neo
prot
eroz
oic
TOC S1+S2 mgg Hydrogen Index Tmax degC
Depth(m)
Organicrichness
Generatingpotential
Kerogentype Maturity Maturity
TD=701m
Sandstone
Mudstone
Dolomite
Limestone
Evaporite
Source rock
MKS40 070498
Ro equivalent
Figure 9 Petroleum source potential of rocks in Normandy LDDH1
Small amounts of organic matter associated with basalt and dolerite in cuttings from
waterbore BWB 1 on BULLEN showed high levels of thermal maturity (Grey 1995a Libby 1995)
It is unclear whether all sedimentary rocks on BULLEN are overmature for hydrocarbon generation
or the results from BWB 1 are related to local heating events associated with the volcanic bodies
that are common in the Jilyili Formation
25
Reservoirs
Each of the five depositional sequences of the Savory Group (Table 1) are inferred to contain
significant sandstone reservoirs with the possible exception of depositional sequence C as
discussed above in Stratigraphy The Spearhole Formation was cored in Mundadjini 1 and
Boondawari 1 and visual estimates of porosity vary from generally poor (less than 5) to fair
(approximately 5ndash15) The McFadden Formation in Trainor 1 has porosity values of up to 232
and a maximum permeability of 195 md (Stevens and Adamides in prep) Sandstones from
Neoproterozoic formations form the acquifers in the following waterbores the McFadden
Formation in TWB 1 the Cornelia Formation in TWB 6 and the Brassey Range Formation in
TWB 8 and TWB 9 (Appendix 6 Table 61)
Based on outcrop observations the Durba Sandstone is considered to be the best reservoir of
the Savory Group Similarly some sandstones from the Tarcunyah Group also have good visible
porosity in outcrop
Dolomites occur in several formations in the sub-basin Reservoir potential may exist
particularly where the dolomites are stromatolitic and oolitic However dolomites have not been
drilled in the sub-basin and porosity can only be inferred from the preferential silicification of
some stromatolite bioherms observed in outcrop (Stevens and Grey 1997) Elsewhere in the
Officer Basin porosities of up to10 have been measured in dolomites A limestone breccia
(karst) is described from 663 to 677 m in drillhole LDDH1 (Fig 6 Busbridge 1994)
Seals
Indications of evaporitic environments in the Mundadjini Skates Hills and Boondawari
Formations are described by Williams (1992) In Mundadjini 1 from 287 to 337 m anhydrite and
chert occurs as nodules beds and veins in mudstone of the Mundadjini Formation Evaporitic
minerals (predominantly gypsum) are described in the Tarcunyah Group in LDDH1 The presence
of the Woolnough and Madley salt diapirs in the Officer Basin (approximately 110 km east of the
sub-basin) and halite beds over 25 m thick in the well Hussar 1 (130 km east of the sub-basin)
provide further evidence that evaporite seals may be present in the Savory Sub-basin
Mudstones and shales form only a small proportion of the limited Neoproterozoic outcrop in
the sub-basin but significant thicknesses of mudstone were encountered in the Mundadjini
Formation in Mundadjini 1 and Boondawari 1 the Tarcunyah Group in LDDH1 and in the
26
Cornelia Formation in Trainor 1 These data suggest that mudstones form a significant proportion
of strata in the sub-basin despite their limited outcrop
Traps
Potential structural closures including folds and faults occur at various scales throughout the
Savory Sub-basin However the region has only been mapped at 1250 000 scale and
independently closed structures such as domes have yet to be confirmed The western margin of
the basin contains abundant faults (with a northeast strike) but elsewhere faults are less common
Some anticlines are recognized in outcrop including one with a strike length of up to 45 km
inferred from surface bedding dips in the Mundadjini and Spearhole Formations at approximately
24deg15rsquoS 121deg10rsquoE on BULLEN (Fig 1)
Salt diapirs and other halokinetic structures are recognized in outcrop well and seismic data
in the Officer Basin to the west of the Savory Sub-basin and it is probable that there are
significant thicknesses of evaporitic sedimentary rocks in the sub-basin The gravity field data
suggest there is good potential for salt diapirs and traps related to halokinesis
Although there is potential for stratigraphic traps to be present in the sub-basin insufficient
data are available to assess them
Preservation of hydrocarbons
The range of thermal maturities measured to date and the large periods of time envisaged for
deposition of sediments implies hydrocarbon generation may have occurred a number of times
during the evolution of the Savory Sub-basin Any hydrocarbons that were generated early may
have been trapped in palaeostructures and remigration to younger traps could have taken place
later The Petermann Ranges Orogeny which has been equated with the Paterson Orogeny (Myers
1990) is believed to have occurred in the latest Neoproterozoic to early Cambrian This is the last
major tectonic event recognized in the sub-basin suggesting that it is reasonable to expect that trap
integrity will have been preserved
If the inference of the presence of thick halite beds in the sub-basin is correct the preservation
potential of sub-salt traps should be excellent
27
Reported hydrocarbon shows and oil seep
Amadeus Petroleum recorded minor oil shows in cores from Mundadjini 1 and Boondawari 1 In
Mundadjini 1 at 36102 m (top of the Spearhole Formation) a 3 mm thick zone had 10 moderate
white fluorescence with slow solvent cut This show was in a granular sandstone with visually
estimated porosity of about 10 In Boondawari 1 at 35364 m (within the Spearhole Formation) a
broken surface of sandstone had 40 moderate yellow-white fluorescence with slow solvent cut
Visually estimated porosity is about 5 Because the fluorescing surface was broken during the
drilling process this show could have resulted from contamination A second show occurs in
Boondawari 1 at 4963 m (within the Spearhole Formation) where a 1 cm-thick zone had 5 dull
yellow fluorescence with slow solvent cut in a conglomerate with visually estimated porosity of
about 10 The company intends to further investigate the nature of these occurrences
Minor bitumen is present at 6623 m in drillhole LDDH1 on GUNANYA (Figs 5 and 6) as a
vein in mudstones of the Tarcunyah Group A sample was analysed by gas chromatography
(Ghori in prep) and confirmed that it is natural bitumen (Appendix 5)
Mineral hole OD 23 drilled by Jubilee Gold Mines NL on NABBERU in the Bangemall Basin
immediately to the south of the Savory Sub-basin (Fig 5) encountered bitumen and trace oil in
vugs in dolomite (M Stevens unpublished data) but no further data are available at present
In their popular guide to the Canning Stock Route Gard and Gard (1990 p 218) refer to an
oil seep at Well 13 on TRAINOR (Fig 5) They reported that between 1977 and 1984 lsquonatural oilrsquo
was seen in the well Although the well is now largely filled with sediment four auger drill
samples were collected by the GSWA in 1995 and all four were analysed for oil shows One
sample from 315 m total depth (GSWA sample 135604) yielded just enough extract (519 ppm)
for saturate gas chromatography analysis The gas chromatograph (Appendix 5) shows that the
extract does contain some hydrocarbons probably from recent plant material Because the depth to
the oil was not quoted in Gard and Gard (1990) the hand-augered well may not have been deep
enough to properly test this reported seep
Geological and geophysical databases
Geological and geophysical data available for the Savory Sub-basin are limited The most recently
completed geological maps for the sub-basin were published by the GSWA between 1991 and
1995 (Williams and Tyler 1991 Williams 1992 1995ab)
28
The cores from the five drillholes listed in Table 2 believed to be all of the core available
from the sub-basin are available for inspection at GSWA Mineral exploration reports submitted
to GSWA may be searched using the WAMEX database and open-file reports are available on
microfiche Geophysical data acquired by the mining industry is not required to be filed with
GSWA if acquired over Vacant Crown Land which is the case for much of the sub-basin
Geophysical survey data submitted in mining tenement reports and which extend into Vacant
Crown Land remain confidential to the companies Original regional aeromagnetic and gravity
datasets are available from the Australian Geological Survey Organisation (AGSO)
Data pertinent to oil exploration in the sub-basin such as structural style and salt diapirism
are presented in a review of the hydrocarbon prospectivity of the Officer Basin (Perincek 1998)
Drilling
Significant drillholes in the sub-basin are summarized in Table 2
Petroleum industry data
Amadeus Petroleum drilled three petroleum exploration wells in the central west of the Savory
Sub-basin in late 1997 These wells Mundadjini 1 Boondawari 1 and Akubra 1 were drilled by
continuous diamond coring (Figs 5 and 6) All targeted potential reservoirs within the Spearhole
Formation with the Mundadjini Formation as the proposed seal The wells were located on
structures interpreted from Landsat images and limited geological investigations Both Mundadjini
1 and Boondawari 1 had minor oil shows as discussed above (Reported hydrocarbon shows)
Government data
Stratigraphic drillhole Trainor 1 was drilled by GSWA in 1995 (Stevens and Adamides in prep)
and the main results are discussed above (Source rocks and Maturity)
Mineral industry data
Normandy Exploration drillhole LDDH1 was cored in the Tarcunyah Group to a total depth of
701 m and provided source-rock and maturity data as discussed above
29
Oilmin NL drilled six percussion drillholes (BD 1 3 4 5 8 and 9) through sandstones and
shales in the northern part of the Savory Sub-basin to a maximum depth of 198 m (Fig 5
WAMEX Microfiche File M 26811 I 2610) but only brief geological descriptions are available
Hydrogeological data
Hydrogeological data within the Savory Sub-basin are limited although a long history of water
exploration extends back to the construction of the Canning Stock Route early this century No
detailed geological or wireline logs are available for the older wells along this route A few station
wells have been drilled by various methods on the south and west margins of the basin but data
are unavailable as reports are not required to be filed with the government Depth to watertable
throughout the basin is largely controlled by porosity of the bedrock
The GSWA drilled fifteen waterbores in the winter of 1995 in the southern part of the sub-
basin in preparation for the drilling of Trainor 1 and the proposed Bullen 1 Twelve bores found
water and six of these bores have salinities of less than 1000 mgL (Fig 5 Appendix 6 Table 61)
One waterbore TWB 6 has gamma ray and neutron logs run through PVC casing and these are
available from the GSWA with the digital log data included herein
Seismic data
No geophysical data have been acquired by the petroleum industry in the Savory Sub-basin
Seismic data acquired in the Officer Basin to the east particularly in the Gibson and Yowalga
Sub-basins is pertinent to structural interpretation in the Savory Sub-basin (Perincek 1996a
1998)
Aeromagnetic surveys
Government data
There are over 95 277 line kilometres of aeromagnetic data included in the AGSO dataset There
are three regional aeromagnetic surveys covering the Savory Sub-basin These were flown by the
Bureau of Mineral Resources (BMR now AGSO) in 1984 at a line spacing of 1500 m with 36 740
and 52 587 line kilometres flown and by Aerodata in 1984 at a line spacing of 1000m with 5950
line kilometres flown These data were reprocessed and interpreted for GSWA by Cowan (1995)
An edited copy of this report is included as Appendix 4 and the original report is filed in the
GSWA Library under S-series reports item 10331
30
Mineral industry data
The approximate locations of non-AGSO aeromagnetic surveys are shown in Figure 8 More
detailed information regarding the location of these surveys may be obtained using the GSWA
MAGCAT II database Additional information such as contours of aeromagnetic values may be
obtained by inspecting items on file with the GSWA
Gravity surveys
Government data
The average spacing for gravity data in the Savory Sub-basin is one station per 121 km2 (11 times 11
km grid) These data were principally collected by BMR in the early 1960s There are a few
additional regional gravity traverses across the sub-basin which are also included in the
BMRAGSO dataset These data were reprocessed and interpreted for GSWA (Fig 10) and a
report on this work is also included in Appendix 4
The GSWA completed a large semi-detailed gravity survey in the eastern Savory Sub-basin
utilizing helicopter support and Differential Global Positioning Survey (DGPS) techniques (Fig
8) This gravity survey completed in August 1995 consists of 2300 gravity stations on a 2 times 3 km
grid All stations were acquired by helicopter using Scintrex gravimeters and Ashtek dual
frequency DGPS equipment for determining location This highly efficient system allowed the
acquisition of more than 100 gravity stations per day in remote areas The resolution of this survey
is +30 cm and +05 microms-2 (Daishsat 1995) These data (Fig 11) represent a significant
improvement on the previous regional survey data and are available from GSWA (GSWA
1996ab) The results of the interpretation of these data were presented at the 1997 ASEG
Convention (Carlsen and Shevchenko 1997)
Mineral industry data
Three small gravity surveys were conducted by Oilmin NL (Fig 8) and the relevant WAMEX
reports are M 2681I 2610 I 2435 I 2567 These three surveys are of limited value because height
control was provided by barometers only and the surveys were not tied to the national gravity grid
31
23deg
25deg
120deg 122deg
Trainor 1
SAVORY
SUB-BASIN
MKS54 160498
100 km
1995 SavoryGravity Survey
254
-1056
micromsec2
Figure 10 Regional Bouguer gravity map of the Savory Sub-basin
23deg
24deg
25deg
122deg30 123deg
TRAINOR 1
123deg30
50 km
MKS53 160498
-116
-626
micro msec2
Figure11 Detailed Bouguer gravity map of the
Savory 1995 Gravity Survey from the eastern Savory Sub-basin
32
Government and academic reports
Chronostratigraphy and geochemistry
The understanding of Neoproterozoic organic chemistry palynology and structural evolution is
essential to the interpretation of hydrocarbon prospectivity Pertinent reports are included in the
bibliography (Appendix 1) Unpublished palaeontology reports describe the palynology of wells in
the Savory Sub-basin (Grey 1995andashe 1996a) Grey and Cotter (1996) discussed the potential for
Neoproterozoic palynomorphs to provide a biostratigraphic framework and palaeoenvironmental
interpretation Grey and Stevens (1997) reviewed the results of palynological studies of wells
drilled in the sub-basin and reported that Supersequence 1 palynomorphs are present in TWB 6
TWB 9 and LDDH1 (Appendix 3) Grey (1996b) reported on the use of stromatolites for
correlation in the Neoproterozoic and Stevens and Grey (1997) discussed the application of
stromatolite biostratigraphy in correlating isolated dolomite outcrops in the sub-basin with well
and seismic data in the Officer Basin and Centralian Superbasin
Although geochemical data from the Savory Sub-basin are very limited results mostly
confirm thermal maturities inferred from TAI for LDDH1 and Trainor 1 (Ghori in prep Stevens
and Adamides in prep) Those parts of the Officer Basin in Western Australia which lie to the
east of the Savory Sub-basin are sparsely drilled but Ghori (in prep) reports that most of the
Neoproterozoic succession presently lies within the oil-generative window However his study
has been unable to identify effective source-rock units and the source for oil shows Thin source
rocks are present in the Neoproterozoic in LDDH1 (Fig 9) and in three wells which lie to the east
and southeast of the Savory Sub-basin namely NJD 1 Kanpa 1A and Yowalga 3
Proposed work program
From the above limited information it is concluded that additional research on the hydrocarbon
potential of the sub-basin is justified and proposals are outlined below
bull Additional modelling of gravity and aeromagnetic data from the Savory Sub-basin is required
in light of the results from Trainor 1 and Boondawari 1 Trainor 1 showed that what appeared
to be a structurally simple area based on outcrop aeromagnetic and gravity data was in fact an
area of major structuring Boondawari 1 intersected a dolerite which is in good depth
agreement with aeromagnetic depth to source results showing this technique is useful in
detecting the depth to intrusive bodies
33
bull Additional data from mineral and petroleum exploration bores may become available and
analysis of samples from these wells should be undertaken and interpreted in the context of
their relevance to the Officer Basin
bull Stratigraphic coring in the Blake Fault and Fold Belt and in the Wells Foreland Sub-basin (Fig
1) targeting source rocks is considered essential to the continuing evaluation of the
hydrocarbon prospectivity of the Savory Sub-basin
bull Correlations using at least outcrop well and potential-field data should be prepared to link the
sub-basin with the better known parts of the Officer Basin to the east
bull Remapping is required to clarify boundary positions within the Cornelia Formation this may
resolve some of the current problems of the relationship between this unit and the rest of the
Savory Sub-basin
bull Further work is required to explain the Early Cambrian or Sturtian ages interpreted for the
Cornelia Formation from sedimentary zircon UndashPb dating in drillhole Trainor 1 The
determination of the age of the organically rich but overmature claystones in this well is
critical to assessing the hydrocarbon potential of the region
bull The thin dark mudstones intersected by Akubra 1 in the Mundadjini Formation warrant
geochemical analysis Analyses of the oil shows in Mundadjini 1 and Boondawari 1 are
currently being undertaken by Amadeus Petroleum
bull Geochemical analysis of hydrocarbons in the Bangemall Basin drillhole OD23 has been
performed by Jubilee Gold and the results will be reviewed when they are submitted to
GSWA The possibility of source rocks within the Bangemall Basin charging traps within the
Bangemall Basin and the overlying Savory Sub-basin requires further investigation
Conclusions
The Savory Sub-basin is a frontier region with only three recently drilled petroleum exploration
wells and no seismic data Based on existing geological and geophysical data it is considered too
early to draw conclusions about the hydrocarbon prospectivity of the sub-basin at this stage and
there are several reasons why the area warrants further investigation
34
1 Thick accumulations of sedimentary rocks are present (up to 8 km thickness inferred) which
may contain source reservoir and sealing strata
2 Minor oil shows occur in Mundadjini 1 and Boondawari 1 and bitumen is present in mineral
exploration drillhole LDDH1 suggesting that hydrocarbons have migrated within the
Neoproterozoic sequence of the Savory Sub-basin Oil and bitumen are present in mineral
exploration drillhole OD23 in the Bangemall Basin immediately to the south of the Savory
Sub-basin and it is possible that source rocks from the Bangemall Basin could charge traps in
the overlying Savory Sub-basin
3 The age of sedimentary rocks in the sub-basin is still poorly constrained but some of the
Neoproterozoic sedimentary rocks located on GUNANYA and TRAINOR are within the
hydrocarbon-generation window It is possible that a significant thickness of Phanerozoic
sedimentary rocks may also be present
4 Friable sandstones with visible porosity outcrop extensively suggesting numerous potential
reservoirs
5 Significant but not intense faulting and folding has been mapped implying large structural
traps may be present
6 Evaporitic sedimentary rocks occur in several formations and may provide good source rocks
and excellent seals
35
References
APAK S N and CARLSEN G M 1997 A compilation and review of data pertaining to the
hydrocarbon prospectivity of the Canning Basin Western Australia Geological Survey
Record 199610 103p
BAGAS L GREY K and WILLIAMS I R 1995 Reappraisal of the Paterson Orogen and
Savory Basin Western Australia Geological Survey Annual Review 1994ndash95 p 55ndash63
BUSBRIDGE M 1994 Lake Disappointment Exploration Licence 451064 Third Annual
Report Lake Disappointment Diamond Drill Hole LDDH1 Normandy Exploration Limited
Western Australia Geological Survey M-series Item 7567 A41358 (unpublished)
CARLSEN G M and SHEVCHENKO S I 1997 Petroleum exploration in Proterozoic basins
using potential fields data and stratigraphic coring Australian Society of Exploration
Geophysicists 12th Geophysical Conference Handbook Sydney 1997 Preview no 66 p 83
(abstract only)
COWAN D 1995 Savory Basin quantitative magnetic interpretation Western Australia
Geological Survey S-series S10331 (unpublished)
DAISHSAT PTY LTD 1995 Operational and processing report Savory Basin gravity survey
Western Australia Geological Survey S-series S10332 (unpublished)
GARD E and GARD R 1990 Canning Stock Route a travellerrsquos guide for a journey through
history Perth Western Australia Western Desert Guides 448p
GEOLOGICAL SURVEY OF WESTERN AUSTRALIA 1996a Savory Basin first vertical
derivative of Bouguer gravity image 1250 000 Western Australia Geological Survey
GEOLOGICAL SURVEY OF WESTERN AUSTRALIA 1996b Savory Basin Bouguer gravity
image 1250 000 Western Australia Geological Survey
GHORI K A R in prep Petroleum source rock potential and thermal history Officer Basin
Western Australia Western Australia Geological Survey Record
36
GREY K 1995a Savory Basin drillhole BWB 1 (Bullen waterbore) palynology and thermal
maturation GSWA Palaeontology Report no 199512 (unpublished)
GREY K 1995b Savory Basin drillholes TWB 1 2 6 9 (Trainor waterbores) palynology and
thermal maturation GSWA Palaeontology Report no 199520 (unpublished)
GREY K 1995c Palynology of Normandy-Poseidon Lake Disappointment-1 corehole
Tarcunyah Group Paterson Orogen GSWA Palaeontology Report no 199521 (unpublished)
GREY K 1995d Savory Basin drillhole Trainor 1 (Trainor diamond drilling) palynology and
thermal maturity GSWA Palaeontology Report no 199524 (unpublished)
GREY K 1995e Savory Basin drillhole Trainor 1 (Trainor diamond drilling) Additional
Preparation of two samples GSWA Palaeontology Report no 199528 (unpublished)
GREY K 1995f Neoproterozoic stromatolites from the Skates Hills Formation Savory Basin
Western Australia and a review of the distribution of Acaciella australica Australian Journal
of Earth Sciences v 42 p 123ndash132
GREY K 1996a Savory Basin drillhole Trainor 1 (Trainor diamond drilling) Additional
samples palynology and thermal maturation GSWA Palaeontology Report no 199615
(unpublished)
GREY K 1996b Preliminary stromatolite correlations for the Neoproterozoic of the Officer
Basin and a review of Australia-wide correlations GSWA Palaeontology Report no 199615
(unpublished)
GREY K and COTTER K L 1996 Palynology in the search for Proterozoic hydrocarbons
Western Australia Geological Survey Annual Review for 1995ndash96 p 70ndash80
GREY K and STEVENS M K 1997 Neoproterozoic palynomorphs of the Savory Sub-basin
Western Australia and their relevance to petroleum exploration Western Australia
Geological Survey Annual Review for 1996ndash97 p 49ndash54
HUBBARD R J PAPE J and ROBERTS D G 1985 Depositional sequence mapping as a
technique to establish tectonic and stratigraphic framework and evaluate hydrocarbon
potential on a passive continental margin in Seismic stratigraphy II an integrated approach
37
edited by O R BERG and D G WOOLVERTON American Association of Petroleum
Geologists Memoir 39 p 79ndash91
LIBBY WG 1995 A petrological report on six samples of bore cuttings from the Savory Basin
Western Australia Western Australia Geological Survey S-series S31307 (unpublished)
MORTON JGG and DREXEL JF 1997 The petroleum geology of South Australia Vol 3
Officer Basin South Australia Department of Mines and Energy Resources Report Book
9719
MUHLING P C and BRAKEL A T 1985 Geology of the Bangemall Group mdash the evolution
of an intracratonic Proterozoic basin Western Australia Geological Survey Bulletin 128
219p
MYERS J S 1990 Precambrian tectonic evolution of part of Gondwana southwestern Australia
Geology v18 p 537ndash540
NELSON D R 1997 Compilation of SHRIMP UndashPb zircon data Western Australia Geological
Survey Record 19972 196p
PAYTON C E 1977 Seismic stratigraphy mdash applications to hydrocarbon exploration
American Association of Petroleum Geologists Memoir 26 516p
PERINCEK D 1996a The age of NeoproterozoicndashPalaeozoic sediments within the Officer Basin
of the Centralian Super-basin can be constrained by major sequence-bounding unconformities
APPEA Journal v 36 pt 1 p 350ndash368
PERINCEK D 1996b The stratigraphic and structural development of the Officer Basin
Western Australia a review Western Australia Geological Survey Annual Review 1995ndash
1996 p 135ndash148
PERINCEK D 1998 A compilation and review of data pertaining to the hydrocarbon
prospectivity of the Officer Basin Western Australia Geological Survey Record 19976
POSAMENTIER H W JERSEY M T and VAIL P R 1988 Eustatic controls on clastic
deposition 1 mdash Conceptual framework in Sea-level changes an integrated approach edited by
C K WILGUS B S HASTINGS C G St C KENDALL H W POSAMENTIER
38
C A ROSS and J C VAN WAGONER Society of Economic Paleontologists and
Mineralogists Special Publication no 42
STEVENS M K and ADAMIDES N G in prep GSWA Trainor 1 well completion report
Savory Sub-basin Officer Basin Western Australia with notes on petroleum and mineral
potential Western Australia Geological Survey Record 199612
STEVENS M K and GREY K 1997 Skates Hills Formation and Tarcunyah Group Officer
Basin mdash carbonate cycles stratigraphic position and hydrocarbon prospectivity Western
Australia Geological Survey Annual Review for 1996ndash97 p 55ndash60
SUMMONS RE and POWELL C McA 1991 Petroleum source rocks of the Amadeus Basin
in Geological and geophysical studies in the Amadeus Basin central Australia edited by R J
KORSCH and JM KENNARD Australia BMR Geology and Geophysics Bulletin 236
TRAVERSE A 1988 Palaeopalynology Boston Unwin Hyman 600p
VAIL P R MITCHUM R M Jr TODD R G WIDMIER J M THOMPSON S III
SANGREE J B BUBB J N and HATLELID W G 1977 Seismic stratigraphy and
global changes of sea level in Seismic stratigraphy mdash applications to hydrocarbon
exploration edited by C E PAYTON American Association of Petroleum Geologists
Memoir 26 516p
WALTER M R and GORTER J 1994 The Neoproterozoic Centralian Superbasin in Western
Australia the Savory and Officer Basins in The sedimentary basins of Western Australia
edited by P G PURCELL and R R PURCELL Petroleum Exploration Society of Australia
Symposium Perth WA 1994 Proceedings p851ndash864
WALTER M R GREY K WILLIAMS I R and CALVER C R 1994 Stratigraphy of the
Neoproterozoic to early Palaeozoic Savory Basin and correlation with the Amadeus and
Officer Basins Australian Journal of Earth Sciences v 41 p 533ndash546
WALTER M R VEEVERS J J CALVER C R and GREY K 1995 Neoproterozoic
stratigraphy of the Centralian Superbasin Australia Precambrian Research v 73 p 173ndash195
WILLIAMS I R 1992 Geology of the Savory Basin Western Australia Western Australia
Geological Survey Bulletin 141 115p
39
WILLIAMS I R 1995a Bullen WA (2nd Edition) Western Australia Geological Survey
1250 000 Geological Series Explanatory Notes 23p
WILLIAMS I R 1995b Trainor WA (2nd Edition) Western Australia Geological Survey
1250 000 Geological Series Explanatory Notes 31p
WILLIAMS I R and TYLER I M 1991 Robertson WA (2nd edition) Western Australia
Geological Survey 1250 000 Geological Series Explanatory Notes 36p
40
41
Appendix 1
Bibliography
Reports which are relevant to this investigation but which are not specifically cited are listed
below
BAILLIE P W POWELL C McA LI Z X and RYALL A M 1994 The tectonic
framework of Western Australiarsquos Neoproterozoic to recent sedimentary basins in The
sedimentary basins of Western Australia edited by P G PURCELL and R R PURCELL
Petroleum Exploration Society of Australia Symposium Perth WA 1994 Proceedings p
45ndash62
BRADSHAW M T BRADSHAW J MURRAY A P NEEDHAM D J SPENCER L
SUMMONS R E WILMOT J and WINN S 1994 Petroleum systems in West Australian
basins in The sedimentary basins of Western Australia edited by P G PURCELL and R R
PURCELL Petroleum Exploration Society of Australia Symposium Perth WA 1994
Proceedings p 93ndash118
CLARKE G L 1991 Proterozoic tectonic reworking in the Rudall Complex Western Australia
Australian Journal of Earth Science v38 p 31ndash44
COCKBAIN A E and HOCKING R M 1990 Phanerozoic in Geology and mineral resources
of Western Australia Western Australia Geological Survey Memoir 3 p 750ndash755
ETHERIDGE M and WALL V 1994 Tectonic and structural evolution of the Australian
Proterozoic 12th Australian Geological Convention Geological Society of Australia
Abstracts no 37 p 102ndash103
GOODE A D T 1981 Proterozoic geology of Western Australia in Precambrian of the
Southern Hemisphere Developments in Precambrian geology 2 edited by I R HUNTER
Amsterdam Elsevier p 105ndash203
GREY K and JACKSON M J 1983 A re-assessment of stromatolite evidence for the
correlation of the Late Proterozoic Neale and Ilma Beds Officer Basin Western Australia
Australia BMR Journal of Australian Geology and Geophysics v 8 p 359
42
HICKMAN A H WILLIAMS I R and BAGAS L 1994 Proterozoic geology and
mineralization of the TelferndashRudall region Paterson Orogen Geological Society of Australia
(WA Division) Excursion Guidebook no 5 56p
HOCKING R M MORY A J and WILLIAMS I R 1994 An atlas of Neoproterozoic and
Phanerozoic basins of Western Australia in The sedimentary basins of Western Australia
edited by P G PURCELL and R R PURCELL Petroleum Exploration Society of Australia
Symposium Perth WA 1994 Proceedings p 21ndash 44
JACKSON P R 1966 Geology and review of exploration Officer Basin Western Australia
Hunt Oil Company Western Australia Geological Survey S-series S26 (unpublished)
JACKSON M J 1971 Notes on a geological reconnaissance of the Officer Basin Western
Australia Australia BMR Geology and Geophysics Record 19715 30p
JACKSON M J and van de GRAAFF W J E 1981 Geology of the Officer Basin Western
Australia Australia BMR Geology and Geophysics Bulletin 206 102 p
LOWRY D C JACKSON M J van de GRAAFF W J E and KENNEWELL P J 1971
Preliminary result of geological mapping in the Officer Basin Western Australia Western
Australia Geological Survey Annual Report for 1971 p 50ndash56
MYERS J S 1990 Precambrian in Geology and mineral resources of Western Australia
Western Australia Geological Survey Memoir 3 p 737ndash750
MYERS J S SHAW R D and TYLER I M 1994 Proterozoic tectonic evolution of
Australia 12th Australian Geological Convention Geological Society of Australia Abstracts
no 37 p 312
NEDIN C and JENKINS R J F 1991 Re-evaluation of unconformities separating the
lsquoEdiacaranrsquo and Cambrian systems South Australia Palaios v 6 p 102ndash108
PHILLIPS B J JAMES A W and PHILIP G M 1985 The geology and hydrocarbon
potential of the north-western Officer Basin APEA Journal 25 (1) p 52ndash61
POWELL C McA LI Z X McELHINNY M W MEERT J G and PARK J K 1993
Paleomagnetic constraints on timing of the Neoproterozoic breakup of Rodinia and Cambrian
formation of Gondwana Geology v 21 p 889ndash892
43
POWELL C McA PREISS W V GATEHOUSE C G KRAPEZ B and LI Z X 1994
South Australian record of a Rodinian epicontinental basin and its mid-Neoproterozoic
breakup to form the Palaeo-Pacific Ocean Tectonophysics v 237 no 3ndash4 p 113ndash140
PREISS W V 1976 Proterozoic stromatolites from the Nabberu and Officer Basins Western
Australia and their biostratigraphic significance South Australia Geological Survey Report
of Investigations no 47 p 1ndash51
TOWNSON W G 1985 The subsurface geology of the western Officer Basin mdash results of
Shellrsquos 1980ndash1984 petroleum exploration campaign APEA Journal v 25 (1) p 34ndash51
WATTS K J 1982 The geology of the Townsend Quartzite Upper Proterozoic shallow water
deposit of the Northern Officer Basin Western Australia Perth University of Western
Australia BSc honours thesis (unpublished)
WELLS A T and KENNEWELL P J 1974 Evaporite exploration in the Officer Basin
Western Australia at the Madley Diapirs Australia BMR Record 1974194 (unpublished)
WILLIAMS I R and MYERS J S 1990 Paterson Orogen in Geology and mineral resources
of Western Australia Western Australia Geological Survey Memoir 3 p 274ndash286
WILLIAMS I R 1990 Savory Basin in Geology and mineral resources of Western Australia
Western Australia Geological Survey Memoir 3 p 329ndash334
WILLIAMS I R 1994 The Neoproterozoic Savory Basin Western Australia in The
sedimentary basins of Western Australia edited by P G PURCELL and R R PURCELL
Petroleum Exploration Society of Australia Symposium Perth WA 1994 Proceedings p
841ndash850
WILSON R B 1967 Woolnough Hills and Madley diapiric structures Gibson Desert WA
APEA Journal v 7 p 94ndash102
44
Appendix 2
Meteorological data (from Bureau of Meteorology Perth 1994)
Table 21 Wiluna rainfall (mm)
Year Jan Feb Mar Apr May Jun Jul Aug Sept Oct Nov Dec
1975 0 45 446 309 306 59 276 4 34 886 638 164 1976 16 154 12 138 53 16 34 62 12 238 0 2 1977 44 0 66 74 68 95 24 363 1 58 12 727 1978 234 522 94 16 0 96 367 24 16 353 185 45 1979 19 173 122 88 91 4 0 246 58 0 169 114 1980 148 764 68 1081 259 626 629 06 56 02 174 0 1981 123 476 192 32 196 118 44 74 14 0 28 312 1982 374 705 206 244 1079 92 02 143 368 526 368 118 1983 1 112 928 248 0 212 56 32 5 1 42 496 1984 149 7 342 84 836 0 348 132 224 04 16 172 1985 596 483 0 166 556 0 514 56 0 0 4 0 1986 0 154 35 0 0 1085 23 01 239 137 0 04 1987 1204 119 19 89 17 575 154 126 07 1 0 398 1988 46 202 164 13 388 0 202 104 0 0 224 1309 1989 207 234 26 703 278 536 57 0 01 0 144 02 1990 1035 23 281 46 126 53 94 218 44 9 42 0 1991 48 0 41 45 0 472 297 12 0 1 0 7 1992 112 96 1025 1227 323 65 04 174 0 132 48 4 1993 0 697 0 202 445 0 12 306 18 05 14 33 Mean 25 35 22 27 27 25 18 12 6 13 13 21
JAN FEB MAR APR MAY JUN JUL AUG SEP OCT NOV DEC0
10
20
30
40
Mea
n R
ain
fall
(mm
)
Month
Mean monthly rainfall in Wiluna
MKS41 140498
45
Table 22 Wiluna minimum temperature (degC)
Year Jan Feb Mar Apr May Jun Jul Aug Sept Oct Nov Dec
1975 ndash 23 203 15 94 63 71 62 103 124 169 205 1976 242 229 194 15 10 63 59 73 95 143 16 228 1977 243 25 197 148 96 95 56 86 102 ndash 188 23 1978 241 232 203 18 102 64 76 8 9 152 19 205 1979 255 226 216 167 83 6 59 79 97 145 198 223 1980 255 226 231 155 134 83 68 75 121 108 193 223 1981 245 216 19 182 119 6 54 78 138 159 163 218 1982 232 224 177 16 ndash ndash 37 111 112 164 209 225 1983 235 24 197 147 112 88 39 88 121 162 189 219 1984 241 243 191 156 ndash 72 66 7 95 161 182 211 1985 244 231 ndash 159 98 65 71 73 117 147 205 ndash 1986 ndash 229 226 155 93 96 43 49 10 122 ndash 219 1987 ndash 217 183 175 85 77 68 68 112 ndash ndash 221 1988 238 214 209 178 111 ndash ndash 86 104 157 171 195 1989 ndash 237 199 165 107 67 44 61 107 131 187 ndash 1990 232 ndash 211 155 118 62 57 87 102 149 195 22 1991 26 256 217 168 122 101 78 ndash 113 18 168 219 1992 227 227 214 169 102 98 59 69 ndash 125 159 196 1993 241 218 196 171 103 ndash 49 68 88 128 192 211 Mean 24 23 20 16 10 8 6 8 11 14 18 21
NOTE Dashes indicate data unavailable
JAN FEB MAR APR MAY JUN JUL AUG SEP OCT NOV DEC0
10
20
30
40
Month
MKS43 140498
50
Mean monthly minimum temperatures at Wiluna
Mea
n T
emp
erat
ure
(degC
)
46
Table 23 Wiluna maximum temperature (degC)
Year Jan Feb Mar Apr May Jun Jul Aug Sept Oct Nov Dec
1975 ndash 349 326 281 247 201 197 212 256 248 31 344 1976 374 369 346 297 248 206 208 225 265 287 313 388 1977 397 392 352 296 234 212 222 244 ndash 308 337 383 1978 378 345 346 316 242 195 176 205 231 295 334 356 1979 403 36 364 295 ndash ndash ndash 193 242 318 359 373 1980 392 342 377 275 24 176 179 233 292 288 349 391 1981 385 346 337 342 242 178 201 224 30 326 326 369 1982 372 359 315 307 ndash ndash 196 253 252 305 353 379 1983 381 389 327 272 263 222 187 248 287 321 336 366 1984 378 393 322 299 226 215 178 214 234 ndash 336 364 1985 40 366 ndash 294 224 216 205 212 284 307 355 ndash 1986 ndash 383 372 307 ndash 193 166 196 261 277 ndash 382 1987 ndash 339 328 305 21 202 214 218 275 ndash ndash 374 1988 388 365 353 301 23 ndash ndash 228 283 334 31 33 1989 ndash 375 339 285 238 179 181 219 275 298 336 ndash 1990 368 ndash 36 309 268 19 188 205 274 309 373 393 1991 414 416 363 315 268 206 21 ndash 279 338 332 368 1992 363 383 336 263 213 178 213 197 ndash 285 313 359 1993 396 357 344 301 221 ndash 197 215 253 294 347 362 Mean 39 37 34 30 24 20 20 22 27 30 34 37 NOTE Dashes indicate data unavailable
JAN FEB MAR APR MAY JUN JUL AUG SEP OCT NOV DEC0
10
20
30
40
Month
MKS42 140498
50
Mean monthly maximum temperatures at Wiluna
Mea
n T
emp
erat
ure
(degC
)
47
Appendix 3
Table 31 Summary of palynological results
Drillhole Depth (m) F no(a) GSWA no Lithology Formation Assemblage TAI(b)
BWB 1 74ndash75 F49668 135741 dark-grey siltstone basalt Jilyilli gt5 BWB 1 98ndash100 F49669 135742 dark-grey siltstone basalt Jilyilli gt5 BWB 1 121ndash122 F49670 135743 dark-grey siltstone basalt Jilyilli gt5 TWB 1 86ndash87 F49671 135631 dark-grey siltstone McFadden 3+ TWB 1 104ndash105 F49672 135632 dark-grey siltstone Cornelia 3+ TWB 1 121ndash122 F49673 135633 dark-grey siltstone Cornelia 4 TWB 2 14ndash15 F49674 135634 dark-grey siltstone Skates Hills 3+ TWB 6 49ndash50 F49675 135675 dark-grey siltstone Cornelia 1 3+ TWB 9 49ndash51 F49676 135704 dark-grey siltstone Brassey Range 1 3+ Trainor 1 37497- F49733 138939 black mudstone with Cornelia 5 37509 light-grey siltstone Trainor 1 3809 F49734 138940 dark-grey and black Cornelia 4- laminated mudstone Trainor 1 4170 F49735 138941 black unlaminated mudstone Cornelia 4- Trainor 1 4950 F49851 139501 dark-grey indurated siltstone Cornelia 5 Trainor 1 6032 F49852 139502 dark- and light-grey Cornelia 5 indurated siltstone Trainor 1 6434 F49853 139503 greenish indurated finely Cornelia 5 laminated siltstone LDDH 1 270 F49678 138934 dark-grey siltstone interbeds Waters 1 3+ in enterolithic evaporite Tarcunyah Gp LDDH 1 277 F49679 138935 dark-grey siltstone in cavity Waters 1 3+ in enterolithic evaporite Tarcunyah Gp
NOTES (a) GSWA Fossil Catalogue number (b) TAI = Thermal Alteration Index of Traverse (1988 plate 1)
48
Appendix 4
Savory Sub-basin quantitative magnetic and gravity interpretation (extracted from Cowan 1995)
Summary
A program of quantitative aeromagnetic interpretation has been completed on BMRAGSO data from the Savory Sub-
basin Western Australia Quantitative aeromagnetic interpretation utilized the 3D Euler deconvolution method
supported by wavenumber filtering and image processing The results have provided useful information on structural
trends and depth to magnetic sources in a structurally complex area Depth to magnetic source analysis has provided
information on intra-sedimentary magnetic sources as well as basement rocks
The results of the interpretation support previously identified depocentres However the presence of magnetic
sources at several levels makes it very difficult to produce a reliable magnetic basement depth contour map It is
considered more productive to work with the 3D Euler colour circle plots and images rather than trying to contour the
results It would be necessary to carry out a full-scale interpretation of the BMRAGSO profile data to improve on the
3D Euler results The regional gravity was found to be useful in interpreting the regional setting of the area although
the very wide data spacing limits quantitative use of the data The gravity data show quite a complex picture with
limited consistent correlation between gravity features and basin structures This suggests that gravity anomalies
reflect changes in density of the basement rocks rather than basement topography especially in the northern part of the
basin
It is recommended that the GSWA investigate access to company confidential high-resolution aeromagnetic data
prior to planning further aeromagnetic surveys Private companies have flown large parts of the northern half of the
area as part of their diamond exploration program Additional gravity coverage of the area may be more cost effective
than magnetic surveys as the gravity data provides more information on changes within the sedimentary section
Introduction
The main use of aeromagnetic data in petroleum exploration has been the determination of magnetic basement
topography although there has been increasing interest in analysis of intra-sedimentary magnetic anomalies
intrabasement and suprabasement magnetic anomalies These anomalies are used to determine depth to magnetic
basement rocks and hence determine the thickness of the sedimentary sequence Unfortunately interpretation of the
intrabasement and suprabasement magnetic anomalies is non-unique in terms of position and size of causative sources
because of the inherent ambiguity of potential-field methods However this ambiguity can be reduced by placing
49
constraints on source geometry and magnetization and by using geological and other geophysical data to constrain
the solution
Before 1970 most depth-determination techniques involved graphical determination of slopes of selected
magnetic anomalies and application of various empirical factors to convert the slopes into depth estimates Geological
Society of America Memoir 47 Interpretation of Aeromagnetic Maps by Vacquier et al (1951) was a landmark for
this type of interpretation
Automated interpretation procedures have played an increasingly important role in depth interpretation and a
wide range of techniques have been developed Many of these techniques are designed for application to located data
profiles and assume a two-dimensional geometry However there has been renewed interest in techniques applicable
to gridded data
Two distinct types of method can be recognized In the first case often described as discrete methods individual
isolated magnetic anomalies are interpreted and the results used to produce a map of basement relief In the second
case often described as continuous methods areas of data containing a number of anomalies are interpreted
statistically to produce direct output of basement depths
The discrete methods usually involve a semiautomatic initial phase which generates a large number of possible
depth solutions and an interactive second phase to screen and select acceptable solutions The advantage of this
approach is that the interpreter can select features that are relatively free from interference from adjacent anomalies
and consider all aspects of a particular magnetic anomaly The disadvantage is that interpretation can be very time
consuming as a wide range of depths are usually possible depending on the initial model chosen and a significant
amount of effort is needed to select the correct model In the case of the Savory Sub-basin dataset we encountered
problems in separating basement related effects from the effects of shallower intrasedimentary magnetic sources
Because of these problems we have concentrated on displaying the Euler results accompanied by separation filter
images of the data to show the shallower effects and deeper effects rather than trying to refine a 3D Euler
deconvolution depth-to-crystalline-basement contour
The continuous methods are very direct provided that the rather restrictive assumption can be made that all
anomalies are due to lateral magnetization changes due to basement topography This means that shallow effects and
large intrabasement anomalies must be removed from the data This involves judgement and skill as it is necessary to
distinguish between the lower amplitude suprabasement anomalies due to basement topography and the larger
intrabasement anomalies reflecting magnetization changes within the basement These methods were not considered
suitable for the Savory Sub-basin magnetic dataset but were used to invert the gravity data
50
Limitations of magnetic and gravity interpretation
Interpretation of the area is limited by a shortage of information on the nature and physical properties of the deeper
sedimentary sequence and the underlying basement rocks However using techniques such as cross-correlation of
gravity and pseudo-gravity data it is possible to try to differentiate between anomalies relating to basement and those
related to the sedimentary sequence
Gravity anomalies reflect changes within the sedimentary sequence as well as basement condition These
changes in density of sedimentary rocks produce gravity anomalies without a corresponding magnetic anomaly hence
the complementary nature of gravity and magnetic surveys The main use of magnetics is to determine depth to
magnetic basement and any intra-sedimentary volcanic rocks or intrusives whereas gravity provides much more
general information on the sedimentary sequence
Unfortunately interpretation of gravity anomalies is complicated since they can be due to a number of geological
features including
bull major basement faults
bull basement highs
bull igneous intrusions within the basement
bull sedimentary basins which may or may not be isostatically compensated
bull intra-sedimentary volcanics and associated plutonic centres
Two major problems affect the interpretation of both magnetic and gravity data
1 The inherent ambiguity of potential-field data There is no unique solution to any measured gravity or magnetic
anomaly and theoretically there will be an infinite number of source geometry and magnetizationdensity
combinations which will fit the observed data This means that any a priori information which helps to select a
suitable model is very useful
2 Measured anomalies are the summation of effects from different depths For example an observed gravity profile
may contain contributions from shallow sources (density variations within the sedimentary basin) intermediate
depth sources (density variations due to large igneous intrusions within the basement) and deep sources (crustal
thinning producing a mantle anomaly) Separation of these component responses is the regionalresidual problem
which we solve using spectral analysis and differential upward continuation-based separation filtering
Regional setting and interpretation overview
The area studied includes parts of BALFOUR DOWNS (SF51-9) RUDALL (SF51-10) ROBERTSON (SF51-13) GUNANYA
(SF51-14) COLLIER (SG50-4) BULLEN (SG51-1) TRAINOR (SG51-2) MADLEY (SG51-3) NABBERU (SG50-5)
STANLEY (SG51-6) and HERBERT (SG51-7) 1250 000 sheets Broadly the area lies between latitudes 22deg00rsquondash25deg30rsquoS
and longitudes 119deg30rsquondash123deg30rsquoE
51
Regional gravity
The AGSO regional gravity data (at nominal 11 km spacing) was gridded at a 4 km mesh spacing using a minimum-
curvature algorithm Bouguer gravity values in the area are negative reflecting mass deficiency at depth and range
from -84 mgals to -25 mgals
A Bouguer gravity colour image is shown as Figure 41 A residual grid was produced by removing a fifth-order
orthogonal polynomial from the Bouguer data but did not add to the interpretation
120deg 121deg 122deg 123deg
23deg
24deg
25deg
-25
-84
50 km
MKS46 180598
mgal
Figure 41 Regional Bouguer gravity (BMRAGSO data) gridded at 4 km
52
The data show a complex pattern of positive and negative anomalies with no clearly defined trends Correlations
with aeromagnetic data and known basin structures are poor A vague north-northwest linear trend appears to coincide
with the Marloo Fault (Figure 42) A prominent negative anomaly appears to coincide with the Blake Fold and Fault
Belt depocentre and continues as a narrower negative anomaly to the east until it widens out again near the edge of the
basin Elsewhere the gravity data show little correlation with known basin structures and it is likely that especially in
the north of the area gravity anomalies are due to density changes in the basement rather than changes in basement
topography
Production of wavelength-filtered residual gravity plots and vertical gradient plots showed very patchy aliased
data reflecting poor sampling in much of the area
Regional magnetics
The AGSO regional aeromagnetic data were gridded at a 400 m mesh spacing using a minimum-curvature algorithm
(Figure 43) Most of the data has a line spacing of 1600 m with small areas of 1 km spacing The quality of the data is
acceptable for regional interpretation but is not adequate for detailed analysis The accuracy of the flight path is rather
variable reflecting the vintage of the data and the noise envelope of the data is poor by modern standards Problems
were also encountered in joining different map sheets
The magnetic anomaly pattern over the south and west part of the area shows a strong high frequency signature
reflecting the presence of widespread basic sills and dykes Some of the major north-northeasterly trending dykes can
be traced over considerable distances
Discontinuous high-frequency anomalies extend as a northwest-trending zone through the centre of the area and
this zone includes a conspicuous circular magnetic anomaly which is probably a ring complex
The northern and eastern parts of the area are characterized by long-wavelength deep-seated basement magnetic
anomalies with 120deg and 150deg trends dominant The Marloo and Perentie Faults (Figure 42) appear as distinct linear
zones and offsets A prominent easterly trending negative anomaly in the northwest of the area appears to swing round
to the southeast and may separate different basement blocks One possible interpretation is that this very deep seated
anomaly separates areas of Archaean and Proterozoic basement
Regional geology
The regional geology is described in Williams (1992) The GSWA provided a digitized version of Plate 2 from this
Bulletin the structural interpretation map to use as an overlay (Figure 42)
53
Pp
Pp
PSd
PSd
PSd
PSd
PSd
PSo
PSt
PSt
PSf
PSf
PSf
PSb
PSb
PSb
PSsPSs
PSs
PSb
PSm
PSp
PSc
PSc
PSw
PSw
PSw
PSg
PSr
PSj
PSg
PM
Pk
PY
PY
PSd
L
L
L
L
L
L
L
LL
L
L
L
LL
L
LL
L L
LL
L L
L
L
L
L
L
L
L
LL
L
L
BLAKEDEPOCENTRE
MA
RLO
O
FAU
LT
PERENTIEFAULT
50 km
MKS39120598
120deg 121deg 122deg 123deg
25deg
24deg
23deg
Approximate boundaryof aeromagnetic interpretation
PML
PSgL
PSjL
PML
PSpL
PML
PML
PSfL
PSfL
PSpL
LPc
LPcLPcPSrL
LPA
Durba Sandstone
Woora Woora Formation
McFadden Formation
Tchukardine Formation
Boondawari Formation
Skates Hills Formation
Mundadjini Formation
Coondra Formation
Spearhole Formation
Watch Point Formation
Jilyili Formation
Brassey Range Formation
Glass Spring Formation
Paterson Formation
Yeneena Group
Karara Formation
Cornelia Formation
Kahrban Subgroup
Bangemall Group
Fault
Formation boundary
PSdL
PSoL
PSfL
PStL
PSbL
PSsL
PSmL
PScL
PSpL
PSwL
PSjL
PSrL
PSgL
Pp
PYL
PkL
LPc
LPA
PML
Savory Group Other Units
PYL
Figure 42 Regional geology and structure map (after Williams 1992)
54
120deg 121deg 122deg 123deg
23deg
24deg
25deg
5820
3750
MKS47 180598
nT
50 km
Figure 43 Regional aeromagnetic data total magnetic intensity (BMRAGSO data) gridded at 400 m
Analysis
3D analysis
3D Euler deconvolution was used as the primary depth-determination method The advantage of this approach is that
consistent solutions can be obtained over the entire area with minimal assumptions about source geometries Euler
deconvolution of gridded data is used for positional information and estimation of depth to top of source Euler
55
deconvolution yields a large number of depth solutions which have to be screened to reject spurious solutions Results
are plotted as circles in eight depth ranges with radius proportional to depth and colour coded
The 400 m total magnetic intensity grid was used for the analysis Horizontal gradients in x and y and the vertical
gradient were calculated 3D Euler deconvolution was tested on the 400 m gridded data using windows of 9 times 9 and
11 times 11 and 16 times 16 data points and structural indices 05 (fault) and 10 (sill or dyke) It was concluded that the
16 times 16 window produced the best results overall and final plots were produced for the 16 times 16 window and structural
index 05 (Fig 44) Results were very good over the northern and central parts of the area showing magnetic sources
Figure 44 Depth to magnetic source 3D Euler deconvolution 16 times 16 window of 400 m gridded data structural index 05
56
at several different levels Unfortunately in the extreme south of the area shallow intrasedimentary magnetic sources
(sills and dykes) dominated the inversion and the results contained few basement solutions
In order to reduce these problems the 400 m gridded data were filtered using a separation filter based on
interpretation of the log-energy spectrum The 3D Euler method was run on the filtered data in order to generate more
basement-depth solutions Results for the deep-separation filter data were gridded and presented as a colour image in
Cowan (1995) Attempts to grid the Euler output were unsatisfactory and it is considered safer to interpret the 3D
Euler depth plots The 3D Euler depth results from the separation-filter run should be analysed with care as perfect
separation of the basement can never be achieved and there will always be some contamination from sources at
different levels
The results of original total magnetic intensity 3D Euler depth estimation for structural index 05 using a 16 point
window have been plotted at 1500 000 scale (not included in this publication but available in Cowan (1995) from the
GSWA Library as S10331) and as reduced A4 colour circle plots (Figure 44)
The results of deep-basement 3D Euler depth estimation for structural index 05 using a 16 point window have
been plotted as a colour image at 1500 000 scale and as an A4 image (not included in this publication)
2D analysis
Two equispaced profiles were interpolated with a 50 m station interval from the AGSO-located data profiles for the
BULLEN 1250 000 sheet The interpolated profiles were analysed using 2D Euler deconvolution and Werner
deconvolution Results are included in Cowan (1995) and show the use of these methods for more detailed analysis
Filtered data
In order to reconcile 3D Euler results from shallow basement and intrasedimentary magnetic sources we produced
several separation-filtered maps and images We found the shallow-layer double-separation filter (Figure 45) to be
very effective for shallow sources and the deep-layer standard-separation filter (Figure 46) for the basement layer
Gravity and magnetic data correlation
Both lsquoreduced to the polersquo (RTP) magnetics (Figure 47) and pseudo-gravity data (Figure 48) were produced as part of
the reconciliation of gravity and magnetic signatures In both cases the filtering operations assumed magnetization by
induction in the present Earths field The RTP data are fairly similar to the total magnetic intensity The pseudo-
57
gravity data are dominated by a northwest-trending strong positive anomaly and there is little correlation with the
Bouguer gravity data
The poor magneticgravity correlation is confirmed by cross-correlation of the RTP magnetics and the gravity
gradient The correlation plot in Figure 49 shows little coherent response with numerous zones of positive and
negative correlation
Figure 45 Regional aeromagnetic data shallow layer separation filter (BMRAGSO data) gridded at 400 m
Results
In the north and east of the area on the Wells Foreland Sub-basin trend (refer to Figure 1 main text) we see a range
of quite deep 3D Euler depths and several trend directions with north-northwesterly dominant There are relatively few
shallow intrasedimentary solutions in this zone
The second area of deep 3D Euler solutions lies over the Blake depocentre (Figure 43) with several trend
directions
Elsewhere the 3D Euler results are dominated by shallow intrasedimentary depth solutions reflecting mainly the
dolerite sills dykes and the ring complex However where we do see basement-related solutions in the south and
west of the area they appear to be shallower than those noted for the Wells Foreland Sub-basin and the Blake
depocentre
58
Figure 46 Regional aeromagnetic data deep-layer separation filter (BMRAGSO data) gridded at 400 m
Figure 48 Regional aeromagnetic data pseudo-gravity transform (BMRAGSO data) gridded at 400 m
Figure 47 Regional aeromagnetic data reduced-to-pole (BMRAGSO data) gridded at 400 m
Figure 49 Regional aeromagnetic and gravity data gravitymagnetic correlation using RTP magnetics and gravity gradient (BMRAGSO data) gridded at 4 km
59
This subdivision of the area into two zones of deep solutions is consistent with interpreted depocentres
However the interference between sources at different levels and the complexity of the magnetic response of the
basement rocks precludes more refined interpretation at this stage
The area of deep 3D Euler solutions over the Blake depocentre correlates with the pronounced negative gravity
anomaly discussed in the gravity interpretation section Using a density contrast of -015 gcc the negative gravity
anomaly could indicate up to 6ndash8 km of low-density sedimentary rocks depending on assumptions about the regional
field
The area of deep 3D Euler solutions over the Wells Foreland Sub-basin has a complex gravity expression and no
clear basin structure emerges from inversion of these data As noted previously it is likely that observed gravity
anomalies reflect contrasts in basement density rather than basement topography
Separation filtering applied to the magnetic data helps to enhance the intrasedimentary magnetic signature and to
give a better impression of the basement magnetic signature even though separation of the basement response is not
perfect
Conclusions
Quantitative aeromagnetic interpretation using 3D Euler deconvolution supported by wavenumber filtering and image
processing has been successful in providing structural trend and depth information for the Savory Sub-basin
Quantitative magnetic interpretation has revealed two zones of relatively deep magnetic basement beneath the
Wells Foreland Sub-basin and the Blake depocentre
This analysis of the magnetic data supports interpreted depocentres but the complexity of the basement magnetic
signature and interference from sources at different depths precludes further refinement to a map of basement
topography
Regional gravity proved to be very useful in understanding the regional setting of the area and in providing
support for aspects of the interpretation The gravity data support the interpretation of the Blake depocentre
suggesting up to 6ndash8 km of low-density sedimentary rocks
The deep structure of the Savory Sub-basin area is obviously complex with different areas underlain by
Archaean and Proterozoic basement and with the Capricorn suture occurring in the centre of the area
60
Recommendations
The quantitative magnetic interpretation needs to be reconciled with geological models available for the area
In particular the zones tentatively identified as areas with thick sedimentary rocks the Wells Foreland Sub-
basin and the Blake depocentre need to be investigated
Cross sections should be prepared across the basin for joint magneticgravity modelling especially for the Blake
depocentre It is important to be able to explain the strong negative gravity anomaly in this area
In view of the effects of basement density contrasts on the gravity field for the northern part of the area we think
that additional gravity interpretation and acquisition of new gravity data may not be justified as they will not
contribute significantly to understanding basin evolution and structure
It is recommended that GSWA try to get access to company confidential high-resolution aeromagnetic data
rather than flying new surveys The GSWA might offer to fund flying of new infill areas as a bargaining point
References
The original text of this report by Cowan (1995) and 1500 000 scale maps are filed in the GSWA Library under
S10331
COWAN D 1995 Savory Basin quantitative magnetic interpretation Western Australia Geological Survey S-series
S10331 (unpublished)
VACQUIER V STEENLAND N C HENDERSON R G and ZIETZ I 1951 Interpretation of aeromagnetic
maps The Geological Society of America Memoir 47 151p
WILLIAMS I R 1992 Geology of the Savory Basin Western Australia Western Australia Geological Survey
Bulletin 141 115p
61
Appendix 5
Geochemistry
MKS38 250398
Saturate FractionC12+ GLC
1217
Pr18
Ph
22
31CSR WELL-13 315m Cuttings
Figure 51 Canning Stock Route Well 13 gas chromatograph of extract of auger drill sample
12
17
18
22
31
Pr Ph
LDDH 1 6623m CoreSaturate FractionC12+ GLC
MKS35 240398
Figure 52 Gas chromatograph of extract from core sample at 6623 m LDDH1
62
Table 51 Canning Stock Route Well 13 auger drill samples
GSWA sample Drill depth (m)(a) Comments
135601 150 At watertable 135602 203 (all samples consist 135603 310 of sand mud and water) 135604 315 At total depth
NOTE (a) Datum for drill depth is the top of sediment fill in the well which is 155 m below ground level (ie the total depth of 315 m is 47 m below ground level)
Table 52 Canning Stock Route Well 13 gas chromatography data for 315 m depth sediment sample
Parameter Value
Weight of rock extracted (grams) 945 Total extract (ppm) 519 n-Alkane distribution n-C12 07 n-C13 23 n-C14 26 n-C15 22 n-C16 19 n-C17 14 i-C19 23 n-C18 14 i-C20 08 n-C19 11 n-C20 16 n-C21 25 n-C22 29 n-C23 70 n-C24 42 n-C25 95 n-C26 43 n-C27 83 n-C28 38 n-C29 87 n-C30 31 n-C31 273 Alkane compositional data Pristane phytane ratio 279 Pristane n-C17 ratio 161 Phytane n-C18 ratio 059 CPI (1)(a) 284 CPI (2) 209 (C21 + C22) (C28 + C29) 043
NOTE (a) CPI= Carbon preference index
63
Table 53 LDDH1 extract liquid chromatography data for 6623 m concentration
Rock extracted Total extract (grams) (ppm)
702 313
NOTE ppm= parts per million
Table 54 LDDH1 saturate gas chromatography data of core for 6623 m alkane composition
Pristane Pristane Phytane (a) CPI (1) CPI (2) (C21+C22) Phytane n-C17 n-C18 (C28+C29)
103 026 024 103 102 325
NOTE (a)CPI = carbon preference index
Table 55 LDDH1 saturate gas chromatography data of core for 6623 m n-alkane distributions
Parameter Value
n-C12 17 n-C13 38 n-C14 55 n-C15 60 n-C16 65 n-C17 74 i-C19 19 n-C18 78 i-C20 19 n-C19 80 n-C20 79 n-C21 71 n-C22 64 n-C23 57 n-C25 43 n-C24 38 n-C27 31 n-C28 23 n-C29 19 n-C30 12 n-C31 10
64
Appendix 6
Table 61 Summary of data from Trainor waterbores (TWB) and Bullen waterbores (BWB)
Well AMG Elevation TD Status(b) Completion details Water Salinity Water level Flow rate Depth to consolidated AGD84 GL (m) (m) struck mgl(c) (m) (LHr) lithology aquifer(e) Z51(a) Interval (m) (100 mm PVC) (m) (mgl)(d)
TWB 1 473660E 453 122 comp 0ndash75 plain 63 7 300 24 2 880 12 m 7287404N 75ndash93 slotted (9 260) McFadden Fm 93ndash99 plain TWB 2 472 977E 475 23 abd nil 15 m 7285877N Skates Hills Fm dry TWB 3 473259E 475 50 abd nil 7 m 7285849N Skates Hills Fm dry TWB 4 463225 E 445 50 comp 0ndash22 plain 35 7 200 55 3 600 0 m 7286143N 22ndash34 slotted (8 140) Tertiary sand and gravel 23ndash60 plain TWB 5 463095E 445 31 comp 0ndash19 plain 13 26 000 655 3 600 Tertiary sand and gravel 7277721N 19ndash25 slotted (36 700) 25ndash31 plain TWB 6 457013E 455 50 comp 0ndash42 plain 38 920 119 600 0 m 7274352N 42ndash48 slotted (1 030) Cornelia Fm ss TWB 7 453739E 475 26 susp 0ndash2 plain 11 9 300 48 4 500 0 m 7263891N (10 500) Tertiary sand TWB 8 433893E 535 60 susp 0ndash2 plain 47 8 500 gt46 1 200 0 m 7245991N (10 900) Tertiary sand and Brassey Range Fm ss TWB 9 437219E 505 51 comp 0ndash47 plain 45 1 000 58 600 1 m 7235905N 47ndash51 slotted (990) Brassey Range Fm ss TWB 10 434927E 495 32 susp 0ndash2 plain 235 450 120 0 m 7225875N (500) Dolerite
65
BWB 1 287337E 580 122 abd Nil 1 m 7245861N Jilyili Fm dry BWB 2 288346E 545 50 comp 0ndash26 plain 15 630 3 29 000 0 m 7240423N 26ndash38 slotted (730) Tertiary sand and gravel 38ndash50 plain BWB 3 305637E 545 50 abd 19 8 800 43 7 200 0 m 7240423N (10 550) Tertiary ss BWB 4 320167E 515 445 comp 0ndash20 plain 9 980 445 24 000 0 m 7248097N 20ndash32 slotted (1 190) Tertiary ss 32ndash44 plain BWB 5 353393E 545 20 susp 0ndash2 plain 45 (970) 1 m 7238934N Basalt
NOTES (a) GPS accuracy ~ 150 m (b) Comp = completed abd = abandoned susp = suspended (c) Salinity from conductivity (d) Analysis total dissolved solids (e) Fm = Formation ss = sandstone
22
sandstones in two petroleum wells in the northwest of the sub-basin and bitumen and oil shows
elsewhere in the region indicate that oil has been generated and migrated through the sub-basin
Source rocks
Source potential is considered to be the major exploration risk in the Savory Sub-basin although
minor oil shows in Mundadjini 1 and Boondawari 1 indicate that at least some oil has been
generated and migrated into potential reservoirs within the sub-basin Sandstone is the
predominant lithology observed in outcrop Outcrops of fine-grained lithologies in the basin are
rare because of intense surface weathering and erosion Only about 8 of the surface area of the
sub-basin is exposed bedrock and recessive lithologies (such as shale evaporite and friable
sandstone) may be present although they rarely outcrop
Outcrops of stromatolitic dolomite with associated cauliflower chert and cubic pseudomorphs
interpreted as being after halite indicate that evaporitic environments are present within the
Mundadjini Skates Hills and Boondawari Formations Evaporitic minerals are also present in
drillhole LDDH1 in the Tarcunyah Group
In 1995 GSWA drilled a continuous-core diamond drillhole (Trainor 1) in the sub-basin on
TRAINOR to a depth of 709 m to test for source rocks thus providing the first such data for the sub-
basin The drillhole intersected flat-lying clastics and carbonates of the McFadden Formation (9ndash
83 m) overlying indurated mudstones of the Cornelia Formation (83ndash709 m total depth) dipping at
about 40deg Of the six samples analysed from the Cornelia Formation in this drillhole the five
located between 375 and 6032 m depth have TOC values exceeding 05 (range 066ndash365)
Rock-Eval pyrolysis of these five samples indicates that they are at best in the dry-gas thermal
stage and as a result of their high level of maturation (Stevens and Adamides in prep) have poor
remaining hydrocarbon-generating potential Although the Cornelia Formation is overmature at
Trainor 1 the high TOC values are encouraging as it is likely that this sequence is less mature
elsewhere in the sub-basin
The Mundadjini Formation contains potential source rocks that comprise marine mudstones
with evaporitic minerals present in parts Thin dark mudstones were intersected in the Mundadjini
Formation in Akubra 1 In Mundadjini 1 and Boondawari 1 however the mudstones appear to be
too oxidized to have source potential
The Boondawari Formation also may be a source rock as it contains black mudstones The
unit is laterally equivalent to the Pertatataka Formation of the Amadeus Basin and the Ungoolya
23
Group of the Officer Basin in South Australia both of which have some source potential
(Summons and Powell 1991 Morton and Drexel 1997) Samples from the Dey Dey Mudstone of
the Ungoolya Group generally have poor TOC values (average 011 range 003ndash081)
moderate hydrogen index (HI) values (100ndash382) and poor to fair genetic potential with a
maximum of 292 kg hydrocarbon per tonne of source rock (Morton and Drexel 1997)
Stromatolitic dolomites and mudstones at the top of the Boondawari Formation and within the
Skates Hills Formation are potential source rocks Stromatolitic dolomite and evaporitic rocks
deposited in a marginal marine to sabkha environment are considered to have good potential to
generate and preserve organic carbon without requiring a deep-water setting (Stevens and Grey
1997) Such conditions are recognized in the Skates Hills Formation and in the upper parts of the
Tarcunyah Group
Maturity
Knowledge of the maturity of sedimentary rocks within the Savory Sub-basin is still limited From
a review of palynological studies Grey and Stevens (1997) report that the thermal maturity
inferred from the Thermal Alteration Index (TAI) of 3+ from Supersequence 1 age palynomorphs
in TWB 6 TWB 9 and LDDH1 is within the hydrocarbon window (Appendix 3) In Phanerozoic
spores and pollen a TAI of 3+ approximately equates to the end of liquid petroleum generation
and the start of dry gas generation and to a vitrinite reflectance of about 13 (Traverse 1988)
However the use of TAI for estimating thermal maturity from Neoproterozoic palynomorphs
requires calibration
In Trainor 1 the Cornelia Formation contains organically rich claystones between 375 and
6032 m depth Based on Rock-Eval maturity data (Stevens and Adamides in prep) and the dark
colour of poorly preserved organic material (Grey 1995de 1996) with TAI 4- to 5 all samples
had a high level of maturation with at best dry-gas generating potential remaining In contrast
drillhole LDDH1 on GUNANYA recorded lower levels of maturity (TAI values of 3+) with two of
sixteen samples from the Tarcunyah Group having greater than 1 TOC (Grey 1995abc Grey
and Cotter 1996) Organic petrology and Rock-Eval maturity data for samples from LDDH1
indicate that the section above 500 m is within the oil-generative window whereas below 500 m
the rocks are within the gas window (Ghori in prep Fig 9 Appendix 5)
Waterbores TWB 1 2 6 and 9 which are located on TRAINOR in the southeast of the sub-
basin all had organic matter with TAI values of 3+ from the McFadden Skates Hills Cornelia
and Brassey Range Formations respectively
24
100
200
300
400
500
600
700
Oil
gene
ratin
g
Gas
gene
ratin
g
Fai
r
Fai
r
Poo
r
Poo
r
Goo
d
Imm
atur
e
Oil
win
dow
Oil
win
dow
Imm
atur
e
01 0110 10 0 150 300 440 480 1
Neo
prot
eroz
oic
TOC S1+S2 mgg Hydrogen Index Tmax degC
Depth(m)
Organicrichness
Generatingpotential
Kerogentype Maturity Maturity
TD=701m
Sandstone
Mudstone
Dolomite
Limestone
Evaporite
Source rock
MKS40 070498
Ro equivalent
Figure 9 Petroleum source potential of rocks in Normandy LDDH1
Small amounts of organic matter associated with basalt and dolerite in cuttings from
waterbore BWB 1 on BULLEN showed high levels of thermal maturity (Grey 1995a Libby 1995)
It is unclear whether all sedimentary rocks on BULLEN are overmature for hydrocarbon generation
or the results from BWB 1 are related to local heating events associated with the volcanic bodies
that are common in the Jilyili Formation
25
Reservoirs
Each of the five depositional sequences of the Savory Group (Table 1) are inferred to contain
significant sandstone reservoirs with the possible exception of depositional sequence C as
discussed above in Stratigraphy The Spearhole Formation was cored in Mundadjini 1 and
Boondawari 1 and visual estimates of porosity vary from generally poor (less than 5) to fair
(approximately 5ndash15) The McFadden Formation in Trainor 1 has porosity values of up to 232
and a maximum permeability of 195 md (Stevens and Adamides in prep) Sandstones from
Neoproterozoic formations form the acquifers in the following waterbores the McFadden
Formation in TWB 1 the Cornelia Formation in TWB 6 and the Brassey Range Formation in
TWB 8 and TWB 9 (Appendix 6 Table 61)
Based on outcrop observations the Durba Sandstone is considered to be the best reservoir of
the Savory Group Similarly some sandstones from the Tarcunyah Group also have good visible
porosity in outcrop
Dolomites occur in several formations in the sub-basin Reservoir potential may exist
particularly where the dolomites are stromatolitic and oolitic However dolomites have not been
drilled in the sub-basin and porosity can only be inferred from the preferential silicification of
some stromatolite bioherms observed in outcrop (Stevens and Grey 1997) Elsewhere in the
Officer Basin porosities of up to10 have been measured in dolomites A limestone breccia
(karst) is described from 663 to 677 m in drillhole LDDH1 (Fig 6 Busbridge 1994)
Seals
Indications of evaporitic environments in the Mundadjini Skates Hills and Boondawari
Formations are described by Williams (1992) In Mundadjini 1 from 287 to 337 m anhydrite and
chert occurs as nodules beds and veins in mudstone of the Mundadjini Formation Evaporitic
minerals (predominantly gypsum) are described in the Tarcunyah Group in LDDH1 The presence
of the Woolnough and Madley salt diapirs in the Officer Basin (approximately 110 km east of the
sub-basin) and halite beds over 25 m thick in the well Hussar 1 (130 km east of the sub-basin)
provide further evidence that evaporite seals may be present in the Savory Sub-basin
Mudstones and shales form only a small proportion of the limited Neoproterozoic outcrop in
the sub-basin but significant thicknesses of mudstone were encountered in the Mundadjini
Formation in Mundadjini 1 and Boondawari 1 the Tarcunyah Group in LDDH1 and in the
26
Cornelia Formation in Trainor 1 These data suggest that mudstones form a significant proportion
of strata in the sub-basin despite their limited outcrop
Traps
Potential structural closures including folds and faults occur at various scales throughout the
Savory Sub-basin However the region has only been mapped at 1250 000 scale and
independently closed structures such as domes have yet to be confirmed The western margin of
the basin contains abundant faults (with a northeast strike) but elsewhere faults are less common
Some anticlines are recognized in outcrop including one with a strike length of up to 45 km
inferred from surface bedding dips in the Mundadjini and Spearhole Formations at approximately
24deg15rsquoS 121deg10rsquoE on BULLEN (Fig 1)
Salt diapirs and other halokinetic structures are recognized in outcrop well and seismic data
in the Officer Basin to the west of the Savory Sub-basin and it is probable that there are
significant thicknesses of evaporitic sedimentary rocks in the sub-basin The gravity field data
suggest there is good potential for salt diapirs and traps related to halokinesis
Although there is potential for stratigraphic traps to be present in the sub-basin insufficient
data are available to assess them
Preservation of hydrocarbons
The range of thermal maturities measured to date and the large periods of time envisaged for
deposition of sediments implies hydrocarbon generation may have occurred a number of times
during the evolution of the Savory Sub-basin Any hydrocarbons that were generated early may
have been trapped in palaeostructures and remigration to younger traps could have taken place
later The Petermann Ranges Orogeny which has been equated with the Paterson Orogeny (Myers
1990) is believed to have occurred in the latest Neoproterozoic to early Cambrian This is the last
major tectonic event recognized in the sub-basin suggesting that it is reasonable to expect that trap
integrity will have been preserved
If the inference of the presence of thick halite beds in the sub-basin is correct the preservation
potential of sub-salt traps should be excellent
27
Reported hydrocarbon shows and oil seep
Amadeus Petroleum recorded minor oil shows in cores from Mundadjini 1 and Boondawari 1 In
Mundadjini 1 at 36102 m (top of the Spearhole Formation) a 3 mm thick zone had 10 moderate
white fluorescence with slow solvent cut This show was in a granular sandstone with visually
estimated porosity of about 10 In Boondawari 1 at 35364 m (within the Spearhole Formation) a
broken surface of sandstone had 40 moderate yellow-white fluorescence with slow solvent cut
Visually estimated porosity is about 5 Because the fluorescing surface was broken during the
drilling process this show could have resulted from contamination A second show occurs in
Boondawari 1 at 4963 m (within the Spearhole Formation) where a 1 cm-thick zone had 5 dull
yellow fluorescence with slow solvent cut in a conglomerate with visually estimated porosity of
about 10 The company intends to further investigate the nature of these occurrences
Minor bitumen is present at 6623 m in drillhole LDDH1 on GUNANYA (Figs 5 and 6) as a
vein in mudstones of the Tarcunyah Group A sample was analysed by gas chromatography
(Ghori in prep) and confirmed that it is natural bitumen (Appendix 5)
Mineral hole OD 23 drilled by Jubilee Gold Mines NL on NABBERU in the Bangemall Basin
immediately to the south of the Savory Sub-basin (Fig 5) encountered bitumen and trace oil in
vugs in dolomite (M Stevens unpublished data) but no further data are available at present
In their popular guide to the Canning Stock Route Gard and Gard (1990 p 218) refer to an
oil seep at Well 13 on TRAINOR (Fig 5) They reported that between 1977 and 1984 lsquonatural oilrsquo
was seen in the well Although the well is now largely filled with sediment four auger drill
samples were collected by the GSWA in 1995 and all four were analysed for oil shows One
sample from 315 m total depth (GSWA sample 135604) yielded just enough extract (519 ppm)
for saturate gas chromatography analysis The gas chromatograph (Appendix 5) shows that the
extract does contain some hydrocarbons probably from recent plant material Because the depth to
the oil was not quoted in Gard and Gard (1990) the hand-augered well may not have been deep
enough to properly test this reported seep
Geological and geophysical databases
Geological and geophysical data available for the Savory Sub-basin are limited The most recently
completed geological maps for the sub-basin were published by the GSWA between 1991 and
1995 (Williams and Tyler 1991 Williams 1992 1995ab)
28
The cores from the five drillholes listed in Table 2 believed to be all of the core available
from the sub-basin are available for inspection at GSWA Mineral exploration reports submitted
to GSWA may be searched using the WAMEX database and open-file reports are available on
microfiche Geophysical data acquired by the mining industry is not required to be filed with
GSWA if acquired over Vacant Crown Land which is the case for much of the sub-basin
Geophysical survey data submitted in mining tenement reports and which extend into Vacant
Crown Land remain confidential to the companies Original regional aeromagnetic and gravity
datasets are available from the Australian Geological Survey Organisation (AGSO)
Data pertinent to oil exploration in the sub-basin such as structural style and salt diapirism
are presented in a review of the hydrocarbon prospectivity of the Officer Basin (Perincek 1998)
Drilling
Significant drillholes in the sub-basin are summarized in Table 2
Petroleum industry data
Amadeus Petroleum drilled three petroleum exploration wells in the central west of the Savory
Sub-basin in late 1997 These wells Mundadjini 1 Boondawari 1 and Akubra 1 were drilled by
continuous diamond coring (Figs 5 and 6) All targeted potential reservoirs within the Spearhole
Formation with the Mundadjini Formation as the proposed seal The wells were located on
structures interpreted from Landsat images and limited geological investigations Both Mundadjini
1 and Boondawari 1 had minor oil shows as discussed above (Reported hydrocarbon shows)
Government data
Stratigraphic drillhole Trainor 1 was drilled by GSWA in 1995 (Stevens and Adamides in prep)
and the main results are discussed above (Source rocks and Maturity)
Mineral industry data
Normandy Exploration drillhole LDDH1 was cored in the Tarcunyah Group to a total depth of
701 m and provided source-rock and maturity data as discussed above
29
Oilmin NL drilled six percussion drillholes (BD 1 3 4 5 8 and 9) through sandstones and
shales in the northern part of the Savory Sub-basin to a maximum depth of 198 m (Fig 5
WAMEX Microfiche File M 26811 I 2610) but only brief geological descriptions are available
Hydrogeological data
Hydrogeological data within the Savory Sub-basin are limited although a long history of water
exploration extends back to the construction of the Canning Stock Route early this century No
detailed geological or wireline logs are available for the older wells along this route A few station
wells have been drilled by various methods on the south and west margins of the basin but data
are unavailable as reports are not required to be filed with the government Depth to watertable
throughout the basin is largely controlled by porosity of the bedrock
The GSWA drilled fifteen waterbores in the winter of 1995 in the southern part of the sub-
basin in preparation for the drilling of Trainor 1 and the proposed Bullen 1 Twelve bores found
water and six of these bores have salinities of less than 1000 mgL (Fig 5 Appendix 6 Table 61)
One waterbore TWB 6 has gamma ray and neutron logs run through PVC casing and these are
available from the GSWA with the digital log data included herein
Seismic data
No geophysical data have been acquired by the petroleum industry in the Savory Sub-basin
Seismic data acquired in the Officer Basin to the east particularly in the Gibson and Yowalga
Sub-basins is pertinent to structural interpretation in the Savory Sub-basin (Perincek 1996a
1998)
Aeromagnetic surveys
Government data
There are over 95 277 line kilometres of aeromagnetic data included in the AGSO dataset There
are three regional aeromagnetic surveys covering the Savory Sub-basin These were flown by the
Bureau of Mineral Resources (BMR now AGSO) in 1984 at a line spacing of 1500 m with 36 740
and 52 587 line kilometres flown and by Aerodata in 1984 at a line spacing of 1000m with 5950
line kilometres flown These data were reprocessed and interpreted for GSWA by Cowan (1995)
An edited copy of this report is included as Appendix 4 and the original report is filed in the
GSWA Library under S-series reports item 10331
30
Mineral industry data
The approximate locations of non-AGSO aeromagnetic surveys are shown in Figure 8 More
detailed information regarding the location of these surveys may be obtained using the GSWA
MAGCAT II database Additional information such as contours of aeromagnetic values may be
obtained by inspecting items on file with the GSWA
Gravity surveys
Government data
The average spacing for gravity data in the Savory Sub-basin is one station per 121 km2 (11 times 11
km grid) These data were principally collected by BMR in the early 1960s There are a few
additional regional gravity traverses across the sub-basin which are also included in the
BMRAGSO dataset These data were reprocessed and interpreted for GSWA (Fig 10) and a
report on this work is also included in Appendix 4
The GSWA completed a large semi-detailed gravity survey in the eastern Savory Sub-basin
utilizing helicopter support and Differential Global Positioning Survey (DGPS) techniques (Fig
8) This gravity survey completed in August 1995 consists of 2300 gravity stations on a 2 times 3 km
grid All stations were acquired by helicopter using Scintrex gravimeters and Ashtek dual
frequency DGPS equipment for determining location This highly efficient system allowed the
acquisition of more than 100 gravity stations per day in remote areas The resolution of this survey
is +30 cm and +05 microms-2 (Daishsat 1995) These data (Fig 11) represent a significant
improvement on the previous regional survey data and are available from GSWA (GSWA
1996ab) The results of the interpretation of these data were presented at the 1997 ASEG
Convention (Carlsen and Shevchenko 1997)
Mineral industry data
Three small gravity surveys were conducted by Oilmin NL (Fig 8) and the relevant WAMEX
reports are M 2681I 2610 I 2435 I 2567 These three surveys are of limited value because height
control was provided by barometers only and the surveys were not tied to the national gravity grid
31
23deg
25deg
120deg 122deg
Trainor 1
SAVORY
SUB-BASIN
MKS54 160498
100 km
1995 SavoryGravity Survey
254
-1056
micromsec2
Figure 10 Regional Bouguer gravity map of the Savory Sub-basin
23deg
24deg
25deg
122deg30 123deg
TRAINOR 1
123deg30
50 km
MKS53 160498
-116
-626
micro msec2
Figure11 Detailed Bouguer gravity map of the
Savory 1995 Gravity Survey from the eastern Savory Sub-basin
32
Government and academic reports
Chronostratigraphy and geochemistry
The understanding of Neoproterozoic organic chemistry palynology and structural evolution is
essential to the interpretation of hydrocarbon prospectivity Pertinent reports are included in the
bibliography (Appendix 1) Unpublished palaeontology reports describe the palynology of wells in
the Savory Sub-basin (Grey 1995andashe 1996a) Grey and Cotter (1996) discussed the potential for
Neoproterozoic palynomorphs to provide a biostratigraphic framework and palaeoenvironmental
interpretation Grey and Stevens (1997) reviewed the results of palynological studies of wells
drilled in the sub-basin and reported that Supersequence 1 palynomorphs are present in TWB 6
TWB 9 and LDDH1 (Appendix 3) Grey (1996b) reported on the use of stromatolites for
correlation in the Neoproterozoic and Stevens and Grey (1997) discussed the application of
stromatolite biostratigraphy in correlating isolated dolomite outcrops in the sub-basin with well
and seismic data in the Officer Basin and Centralian Superbasin
Although geochemical data from the Savory Sub-basin are very limited results mostly
confirm thermal maturities inferred from TAI for LDDH1 and Trainor 1 (Ghori in prep Stevens
and Adamides in prep) Those parts of the Officer Basin in Western Australia which lie to the
east of the Savory Sub-basin are sparsely drilled but Ghori (in prep) reports that most of the
Neoproterozoic succession presently lies within the oil-generative window However his study
has been unable to identify effective source-rock units and the source for oil shows Thin source
rocks are present in the Neoproterozoic in LDDH1 (Fig 9) and in three wells which lie to the east
and southeast of the Savory Sub-basin namely NJD 1 Kanpa 1A and Yowalga 3
Proposed work program
From the above limited information it is concluded that additional research on the hydrocarbon
potential of the sub-basin is justified and proposals are outlined below
bull Additional modelling of gravity and aeromagnetic data from the Savory Sub-basin is required
in light of the results from Trainor 1 and Boondawari 1 Trainor 1 showed that what appeared
to be a structurally simple area based on outcrop aeromagnetic and gravity data was in fact an
area of major structuring Boondawari 1 intersected a dolerite which is in good depth
agreement with aeromagnetic depth to source results showing this technique is useful in
detecting the depth to intrusive bodies
33
bull Additional data from mineral and petroleum exploration bores may become available and
analysis of samples from these wells should be undertaken and interpreted in the context of
their relevance to the Officer Basin
bull Stratigraphic coring in the Blake Fault and Fold Belt and in the Wells Foreland Sub-basin (Fig
1) targeting source rocks is considered essential to the continuing evaluation of the
hydrocarbon prospectivity of the Savory Sub-basin
bull Correlations using at least outcrop well and potential-field data should be prepared to link the
sub-basin with the better known parts of the Officer Basin to the east
bull Remapping is required to clarify boundary positions within the Cornelia Formation this may
resolve some of the current problems of the relationship between this unit and the rest of the
Savory Sub-basin
bull Further work is required to explain the Early Cambrian or Sturtian ages interpreted for the
Cornelia Formation from sedimentary zircon UndashPb dating in drillhole Trainor 1 The
determination of the age of the organically rich but overmature claystones in this well is
critical to assessing the hydrocarbon potential of the region
bull The thin dark mudstones intersected by Akubra 1 in the Mundadjini Formation warrant
geochemical analysis Analyses of the oil shows in Mundadjini 1 and Boondawari 1 are
currently being undertaken by Amadeus Petroleum
bull Geochemical analysis of hydrocarbons in the Bangemall Basin drillhole OD23 has been
performed by Jubilee Gold and the results will be reviewed when they are submitted to
GSWA The possibility of source rocks within the Bangemall Basin charging traps within the
Bangemall Basin and the overlying Savory Sub-basin requires further investigation
Conclusions
The Savory Sub-basin is a frontier region with only three recently drilled petroleum exploration
wells and no seismic data Based on existing geological and geophysical data it is considered too
early to draw conclusions about the hydrocarbon prospectivity of the sub-basin at this stage and
there are several reasons why the area warrants further investigation
34
1 Thick accumulations of sedimentary rocks are present (up to 8 km thickness inferred) which
may contain source reservoir and sealing strata
2 Minor oil shows occur in Mundadjini 1 and Boondawari 1 and bitumen is present in mineral
exploration drillhole LDDH1 suggesting that hydrocarbons have migrated within the
Neoproterozoic sequence of the Savory Sub-basin Oil and bitumen are present in mineral
exploration drillhole OD23 in the Bangemall Basin immediately to the south of the Savory
Sub-basin and it is possible that source rocks from the Bangemall Basin could charge traps in
the overlying Savory Sub-basin
3 The age of sedimentary rocks in the sub-basin is still poorly constrained but some of the
Neoproterozoic sedimentary rocks located on GUNANYA and TRAINOR are within the
hydrocarbon-generation window It is possible that a significant thickness of Phanerozoic
sedimentary rocks may also be present
4 Friable sandstones with visible porosity outcrop extensively suggesting numerous potential
reservoirs
5 Significant but not intense faulting and folding has been mapped implying large structural
traps may be present
6 Evaporitic sedimentary rocks occur in several formations and may provide good source rocks
and excellent seals
35
References
APAK S N and CARLSEN G M 1997 A compilation and review of data pertaining to the
hydrocarbon prospectivity of the Canning Basin Western Australia Geological Survey
Record 199610 103p
BAGAS L GREY K and WILLIAMS I R 1995 Reappraisal of the Paterson Orogen and
Savory Basin Western Australia Geological Survey Annual Review 1994ndash95 p 55ndash63
BUSBRIDGE M 1994 Lake Disappointment Exploration Licence 451064 Third Annual
Report Lake Disappointment Diamond Drill Hole LDDH1 Normandy Exploration Limited
Western Australia Geological Survey M-series Item 7567 A41358 (unpublished)
CARLSEN G M and SHEVCHENKO S I 1997 Petroleum exploration in Proterozoic basins
using potential fields data and stratigraphic coring Australian Society of Exploration
Geophysicists 12th Geophysical Conference Handbook Sydney 1997 Preview no 66 p 83
(abstract only)
COWAN D 1995 Savory Basin quantitative magnetic interpretation Western Australia
Geological Survey S-series S10331 (unpublished)
DAISHSAT PTY LTD 1995 Operational and processing report Savory Basin gravity survey
Western Australia Geological Survey S-series S10332 (unpublished)
GARD E and GARD R 1990 Canning Stock Route a travellerrsquos guide for a journey through
history Perth Western Australia Western Desert Guides 448p
GEOLOGICAL SURVEY OF WESTERN AUSTRALIA 1996a Savory Basin first vertical
derivative of Bouguer gravity image 1250 000 Western Australia Geological Survey
GEOLOGICAL SURVEY OF WESTERN AUSTRALIA 1996b Savory Basin Bouguer gravity
image 1250 000 Western Australia Geological Survey
GHORI K A R in prep Petroleum source rock potential and thermal history Officer Basin
Western Australia Western Australia Geological Survey Record
36
GREY K 1995a Savory Basin drillhole BWB 1 (Bullen waterbore) palynology and thermal
maturation GSWA Palaeontology Report no 199512 (unpublished)
GREY K 1995b Savory Basin drillholes TWB 1 2 6 9 (Trainor waterbores) palynology and
thermal maturation GSWA Palaeontology Report no 199520 (unpublished)
GREY K 1995c Palynology of Normandy-Poseidon Lake Disappointment-1 corehole
Tarcunyah Group Paterson Orogen GSWA Palaeontology Report no 199521 (unpublished)
GREY K 1995d Savory Basin drillhole Trainor 1 (Trainor diamond drilling) palynology and
thermal maturity GSWA Palaeontology Report no 199524 (unpublished)
GREY K 1995e Savory Basin drillhole Trainor 1 (Trainor diamond drilling) Additional
Preparation of two samples GSWA Palaeontology Report no 199528 (unpublished)
GREY K 1995f Neoproterozoic stromatolites from the Skates Hills Formation Savory Basin
Western Australia and a review of the distribution of Acaciella australica Australian Journal
of Earth Sciences v 42 p 123ndash132
GREY K 1996a Savory Basin drillhole Trainor 1 (Trainor diamond drilling) Additional
samples palynology and thermal maturation GSWA Palaeontology Report no 199615
(unpublished)
GREY K 1996b Preliminary stromatolite correlations for the Neoproterozoic of the Officer
Basin and a review of Australia-wide correlations GSWA Palaeontology Report no 199615
(unpublished)
GREY K and COTTER K L 1996 Palynology in the search for Proterozoic hydrocarbons
Western Australia Geological Survey Annual Review for 1995ndash96 p 70ndash80
GREY K and STEVENS M K 1997 Neoproterozoic palynomorphs of the Savory Sub-basin
Western Australia and their relevance to petroleum exploration Western Australia
Geological Survey Annual Review for 1996ndash97 p 49ndash54
HUBBARD R J PAPE J and ROBERTS D G 1985 Depositional sequence mapping as a
technique to establish tectonic and stratigraphic framework and evaluate hydrocarbon
potential on a passive continental margin in Seismic stratigraphy II an integrated approach
37
edited by O R BERG and D G WOOLVERTON American Association of Petroleum
Geologists Memoir 39 p 79ndash91
LIBBY WG 1995 A petrological report on six samples of bore cuttings from the Savory Basin
Western Australia Western Australia Geological Survey S-series S31307 (unpublished)
MORTON JGG and DREXEL JF 1997 The petroleum geology of South Australia Vol 3
Officer Basin South Australia Department of Mines and Energy Resources Report Book
9719
MUHLING P C and BRAKEL A T 1985 Geology of the Bangemall Group mdash the evolution
of an intracratonic Proterozoic basin Western Australia Geological Survey Bulletin 128
219p
MYERS J S 1990 Precambrian tectonic evolution of part of Gondwana southwestern Australia
Geology v18 p 537ndash540
NELSON D R 1997 Compilation of SHRIMP UndashPb zircon data Western Australia Geological
Survey Record 19972 196p
PAYTON C E 1977 Seismic stratigraphy mdash applications to hydrocarbon exploration
American Association of Petroleum Geologists Memoir 26 516p
PERINCEK D 1996a The age of NeoproterozoicndashPalaeozoic sediments within the Officer Basin
of the Centralian Super-basin can be constrained by major sequence-bounding unconformities
APPEA Journal v 36 pt 1 p 350ndash368
PERINCEK D 1996b The stratigraphic and structural development of the Officer Basin
Western Australia a review Western Australia Geological Survey Annual Review 1995ndash
1996 p 135ndash148
PERINCEK D 1998 A compilation and review of data pertaining to the hydrocarbon
prospectivity of the Officer Basin Western Australia Geological Survey Record 19976
POSAMENTIER H W JERSEY M T and VAIL P R 1988 Eustatic controls on clastic
deposition 1 mdash Conceptual framework in Sea-level changes an integrated approach edited by
C K WILGUS B S HASTINGS C G St C KENDALL H W POSAMENTIER
38
C A ROSS and J C VAN WAGONER Society of Economic Paleontologists and
Mineralogists Special Publication no 42
STEVENS M K and ADAMIDES N G in prep GSWA Trainor 1 well completion report
Savory Sub-basin Officer Basin Western Australia with notes on petroleum and mineral
potential Western Australia Geological Survey Record 199612
STEVENS M K and GREY K 1997 Skates Hills Formation and Tarcunyah Group Officer
Basin mdash carbonate cycles stratigraphic position and hydrocarbon prospectivity Western
Australia Geological Survey Annual Review for 1996ndash97 p 55ndash60
SUMMONS RE and POWELL C McA 1991 Petroleum source rocks of the Amadeus Basin
in Geological and geophysical studies in the Amadeus Basin central Australia edited by R J
KORSCH and JM KENNARD Australia BMR Geology and Geophysics Bulletin 236
TRAVERSE A 1988 Palaeopalynology Boston Unwin Hyman 600p
VAIL P R MITCHUM R M Jr TODD R G WIDMIER J M THOMPSON S III
SANGREE J B BUBB J N and HATLELID W G 1977 Seismic stratigraphy and
global changes of sea level in Seismic stratigraphy mdash applications to hydrocarbon
exploration edited by C E PAYTON American Association of Petroleum Geologists
Memoir 26 516p
WALTER M R and GORTER J 1994 The Neoproterozoic Centralian Superbasin in Western
Australia the Savory and Officer Basins in The sedimentary basins of Western Australia
edited by P G PURCELL and R R PURCELL Petroleum Exploration Society of Australia
Symposium Perth WA 1994 Proceedings p851ndash864
WALTER M R GREY K WILLIAMS I R and CALVER C R 1994 Stratigraphy of the
Neoproterozoic to early Palaeozoic Savory Basin and correlation with the Amadeus and
Officer Basins Australian Journal of Earth Sciences v 41 p 533ndash546
WALTER M R VEEVERS J J CALVER C R and GREY K 1995 Neoproterozoic
stratigraphy of the Centralian Superbasin Australia Precambrian Research v 73 p 173ndash195
WILLIAMS I R 1992 Geology of the Savory Basin Western Australia Western Australia
Geological Survey Bulletin 141 115p
39
WILLIAMS I R 1995a Bullen WA (2nd Edition) Western Australia Geological Survey
1250 000 Geological Series Explanatory Notes 23p
WILLIAMS I R 1995b Trainor WA (2nd Edition) Western Australia Geological Survey
1250 000 Geological Series Explanatory Notes 31p
WILLIAMS I R and TYLER I M 1991 Robertson WA (2nd edition) Western Australia
Geological Survey 1250 000 Geological Series Explanatory Notes 36p
40
41
Appendix 1
Bibliography
Reports which are relevant to this investigation but which are not specifically cited are listed
below
BAILLIE P W POWELL C McA LI Z X and RYALL A M 1994 The tectonic
framework of Western Australiarsquos Neoproterozoic to recent sedimentary basins in The
sedimentary basins of Western Australia edited by P G PURCELL and R R PURCELL
Petroleum Exploration Society of Australia Symposium Perth WA 1994 Proceedings p
45ndash62
BRADSHAW M T BRADSHAW J MURRAY A P NEEDHAM D J SPENCER L
SUMMONS R E WILMOT J and WINN S 1994 Petroleum systems in West Australian
basins in The sedimentary basins of Western Australia edited by P G PURCELL and R R
PURCELL Petroleum Exploration Society of Australia Symposium Perth WA 1994
Proceedings p 93ndash118
CLARKE G L 1991 Proterozoic tectonic reworking in the Rudall Complex Western Australia
Australian Journal of Earth Science v38 p 31ndash44
COCKBAIN A E and HOCKING R M 1990 Phanerozoic in Geology and mineral resources
of Western Australia Western Australia Geological Survey Memoir 3 p 750ndash755
ETHERIDGE M and WALL V 1994 Tectonic and structural evolution of the Australian
Proterozoic 12th Australian Geological Convention Geological Society of Australia
Abstracts no 37 p 102ndash103
GOODE A D T 1981 Proterozoic geology of Western Australia in Precambrian of the
Southern Hemisphere Developments in Precambrian geology 2 edited by I R HUNTER
Amsterdam Elsevier p 105ndash203
GREY K and JACKSON M J 1983 A re-assessment of stromatolite evidence for the
correlation of the Late Proterozoic Neale and Ilma Beds Officer Basin Western Australia
Australia BMR Journal of Australian Geology and Geophysics v 8 p 359
42
HICKMAN A H WILLIAMS I R and BAGAS L 1994 Proterozoic geology and
mineralization of the TelferndashRudall region Paterson Orogen Geological Society of Australia
(WA Division) Excursion Guidebook no 5 56p
HOCKING R M MORY A J and WILLIAMS I R 1994 An atlas of Neoproterozoic and
Phanerozoic basins of Western Australia in The sedimentary basins of Western Australia
edited by P G PURCELL and R R PURCELL Petroleum Exploration Society of Australia
Symposium Perth WA 1994 Proceedings p 21ndash 44
JACKSON P R 1966 Geology and review of exploration Officer Basin Western Australia
Hunt Oil Company Western Australia Geological Survey S-series S26 (unpublished)
JACKSON M J 1971 Notes on a geological reconnaissance of the Officer Basin Western
Australia Australia BMR Geology and Geophysics Record 19715 30p
JACKSON M J and van de GRAAFF W J E 1981 Geology of the Officer Basin Western
Australia Australia BMR Geology and Geophysics Bulletin 206 102 p
LOWRY D C JACKSON M J van de GRAAFF W J E and KENNEWELL P J 1971
Preliminary result of geological mapping in the Officer Basin Western Australia Western
Australia Geological Survey Annual Report for 1971 p 50ndash56
MYERS J S 1990 Precambrian in Geology and mineral resources of Western Australia
Western Australia Geological Survey Memoir 3 p 737ndash750
MYERS J S SHAW R D and TYLER I M 1994 Proterozoic tectonic evolution of
Australia 12th Australian Geological Convention Geological Society of Australia Abstracts
no 37 p 312
NEDIN C and JENKINS R J F 1991 Re-evaluation of unconformities separating the
lsquoEdiacaranrsquo and Cambrian systems South Australia Palaios v 6 p 102ndash108
PHILLIPS B J JAMES A W and PHILIP G M 1985 The geology and hydrocarbon
potential of the north-western Officer Basin APEA Journal 25 (1) p 52ndash61
POWELL C McA LI Z X McELHINNY M W MEERT J G and PARK J K 1993
Paleomagnetic constraints on timing of the Neoproterozoic breakup of Rodinia and Cambrian
formation of Gondwana Geology v 21 p 889ndash892
43
POWELL C McA PREISS W V GATEHOUSE C G KRAPEZ B and LI Z X 1994
South Australian record of a Rodinian epicontinental basin and its mid-Neoproterozoic
breakup to form the Palaeo-Pacific Ocean Tectonophysics v 237 no 3ndash4 p 113ndash140
PREISS W V 1976 Proterozoic stromatolites from the Nabberu and Officer Basins Western
Australia and their biostratigraphic significance South Australia Geological Survey Report
of Investigations no 47 p 1ndash51
TOWNSON W G 1985 The subsurface geology of the western Officer Basin mdash results of
Shellrsquos 1980ndash1984 petroleum exploration campaign APEA Journal v 25 (1) p 34ndash51
WATTS K J 1982 The geology of the Townsend Quartzite Upper Proterozoic shallow water
deposit of the Northern Officer Basin Western Australia Perth University of Western
Australia BSc honours thesis (unpublished)
WELLS A T and KENNEWELL P J 1974 Evaporite exploration in the Officer Basin
Western Australia at the Madley Diapirs Australia BMR Record 1974194 (unpublished)
WILLIAMS I R and MYERS J S 1990 Paterson Orogen in Geology and mineral resources
of Western Australia Western Australia Geological Survey Memoir 3 p 274ndash286
WILLIAMS I R 1990 Savory Basin in Geology and mineral resources of Western Australia
Western Australia Geological Survey Memoir 3 p 329ndash334
WILLIAMS I R 1994 The Neoproterozoic Savory Basin Western Australia in The
sedimentary basins of Western Australia edited by P G PURCELL and R R PURCELL
Petroleum Exploration Society of Australia Symposium Perth WA 1994 Proceedings p
841ndash850
WILSON R B 1967 Woolnough Hills and Madley diapiric structures Gibson Desert WA
APEA Journal v 7 p 94ndash102
44
Appendix 2
Meteorological data (from Bureau of Meteorology Perth 1994)
Table 21 Wiluna rainfall (mm)
Year Jan Feb Mar Apr May Jun Jul Aug Sept Oct Nov Dec
1975 0 45 446 309 306 59 276 4 34 886 638 164 1976 16 154 12 138 53 16 34 62 12 238 0 2 1977 44 0 66 74 68 95 24 363 1 58 12 727 1978 234 522 94 16 0 96 367 24 16 353 185 45 1979 19 173 122 88 91 4 0 246 58 0 169 114 1980 148 764 68 1081 259 626 629 06 56 02 174 0 1981 123 476 192 32 196 118 44 74 14 0 28 312 1982 374 705 206 244 1079 92 02 143 368 526 368 118 1983 1 112 928 248 0 212 56 32 5 1 42 496 1984 149 7 342 84 836 0 348 132 224 04 16 172 1985 596 483 0 166 556 0 514 56 0 0 4 0 1986 0 154 35 0 0 1085 23 01 239 137 0 04 1987 1204 119 19 89 17 575 154 126 07 1 0 398 1988 46 202 164 13 388 0 202 104 0 0 224 1309 1989 207 234 26 703 278 536 57 0 01 0 144 02 1990 1035 23 281 46 126 53 94 218 44 9 42 0 1991 48 0 41 45 0 472 297 12 0 1 0 7 1992 112 96 1025 1227 323 65 04 174 0 132 48 4 1993 0 697 0 202 445 0 12 306 18 05 14 33 Mean 25 35 22 27 27 25 18 12 6 13 13 21
JAN FEB MAR APR MAY JUN JUL AUG SEP OCT NOV DEC0
10
20
30
40
Mea
n R
ain
fall
(mm
)
Month
Mean monthly rainfall in Wiluna
MKS41 140498
45
Table 22 Wiluna minimum temperature (degC)
Year Jan Feb Mar Apr May Jun Jul Aug Sept Oct Nov Dec
1975 ndash 23 203 15 94 63 71 62 103 124 169 205 1976 242 229 194 15 10 63 59 73 95 143 16 228 1977 243 25 197 148 96 95 56 86 102 ndash 188 23 1978 241 232 203 18 102 64 76 8 9 152 19 205 1979 255 226 216 167 83 6 59 79 97 145 198 223 1980 255 226 231 155 134 83 68 75 121 108 193 223 1981 245 216 19 182 119 6 54 78 138 159 163 218 1982 232 224 177 16 ndash ndash 37 111 112 164 209 225 1983 235 24 197 147 112 88 39 88 121 162 189 219 1984 241 243 191 156 ndash 72 66 7 95 161 182 211 1985 244 231 ndash 159 98 65 71 73 117 147 205 ndash 1986 ndash 229 226 155 93 96 43 49 10 122 ndash 219 1987 ndash 217 183 175 85 77 68 68 112 ndash ndash 221 1988 238 214 209 178 111 ndash ndash 86 104 157 171 195 1989 ndash 237 199 165 107 67 44 61 107 131 187 ndash 1990 232 ndash 211 155 118 62 57 87 102 149 195 22 1991 26 256 217 168 122 101 78 ndash 113 18 168 219 1992 227 227 214 169 102 98 59 69 ndash 125 159 196 1993 241 218 196 171 103 ndash 49 68 88 128 192 211 Mean 24 23 20 16 10 8 6 8 11 14 18 21
NOTE Dashes indicate data unavailable
JAN FEB MAR APR MAY JUN JUL AUG SEP OCT NOV DEC0
10
20
30
40
Month
MKS43 140498
50
Mean monthly minimum temperatures at Wiluna
Mea
n T
emp
erat
ure
(degC
)
46
Table 23 Wiluna maximum temperature (degC)
Year Jan Feb Mar Apr May Jun Jul Aug Sept Oct Nov Dec
1975 ndash 349 326 281 247 201 197 212 256 248 31 344 1976 374 369 346 297 248 206 208 225 265 287 313 388 1977 397 392 352 296 234 212 222 244 ndash 308 337 383 1978 378 345 346 316 242 195 176 205 231 295 334 356 1979 403 36 364 295 ndash ndash ndash 193 242 318 359 373 1980 392 342 377 275 24 176 179 233 292 288 349 391 1981 385 346 337 342 242 178 201 224 30 326 326 369 1982 372 359 315 307 ndash ndash 196 253 252 305 353 379 1983 381 389 327 272 263 222 187 248 287 321 336 366 1984 378 393 322 299 226 215 178 214 234 ndash 336 364 1985 40 366 ndash 294 224 216 205 212 284 307 355 ndash 1986 ndash 383 372 307 ndash 193 166 196 261 277 ndash 382 1987 ndash 339 328 305 21 202 214 218 275 ndash ndash 374 1988 388 365 353 301 23 ndash ndash 228 283 334 31 33 1989 ndash 375 339 285 238 179 181 219 275 298 336 ndash 1990 368 ndash 36 309 268 19 188 205 274 309 373 393 1991 414 416 363 315 268 206 21 ndash 279 338 332 368 1992 363 383 336 263 213 178 213 197 ndash 285 313 359 1993 396 357 344 301 221 ndash 197 215 253 294 347 362 Mean 39 37 34 30 24 20 20 22 27 30 34 37 NOTE Dashes indicate data unavailable
JAN FEB MAR APR MAY JUN JUL AUG SEP OCT NOV DEC0
10
20
30
40
Month
MKS42 140498
50
Mean monthly maximum temperatures at Wiluna
Mea
n T
emp
erat
ure
(degC
)
47
Appendix 3
Table 31 Summary of palynological results
Drillhole Depth (m) F no(a) GSWA no Lithology Formation Assemblage TAI(b)
BWB 1 74ndash75 F49668 135741 dark-grey siltstone basalt Jilyilli gt5 BWB 1 98ndash100 F49669 135742 dark-grey siltstone basalt Jilyilli gt5 BWB 1 121ndash122 F49670 135743 dark-grey siltstone basalt Jilyilli gt5 TWB 1 86ndash87 F49671 135631 dark-grey siltstone McFadden 3+ TWB 1 104ndash105 F49672 135632 dark-grey siltstone Cornelia 3+ TWB 1 121ndash122 F49673 135633 dark-grey siltstone Cornelia 4 TWB 2 14ndash15 F49674 135634 dark-grey siltstone Skates Hills 3+ TWB 6 49ndash50 F49675 135675 dark-grey siltstone Cornelia 1 3+ TWB 9 49ndash51 F49676 135704 dark-grey siltstone Brassey Range 1 3+ Trainor 1 37497- F49733 138939 black mudstone with Cornelia 5 37509 light-grey siltstone Trainor 1 3809 F49734 138940 dark-grey and black Cornelia 4- laminated mudstone Trainor 1 4170 F49735 138941 black unlaminated mudstone Cornelia 4- Trainor 1 4950 F49851 139501 dark-grey indurated siltstone Cornelia 5 Trainor 1 6032 F49852 139502 dark- and light-grey Cornelia 5 indurated siltstone Trainor 1 6434 F49853 139503 greenish indurated finely Cornelia 5 laminated siltstone LDDH 1 270 F49678 138934 dark-grey siltstone interbeds Waters 1 3+ in enterolithic evaporite Tarcunyah Gp LDDH 1 277 F49679 138935 dark-grey siltstone in cavity Waters 1 3+ in enterolithic evaporite Tarcunyah Gp
NOTES (a) GSWA Fossil Catalogue number (b) TAI = Thermal Alteration Index of Traverse (1988 plate 1)
48
Appendix 4
Savory Sub-basin quantitative magnetic and gravity interpretation (extracted from Cowan 1995)
Summary
A program of quantitative aeromagnetic interpretation has been completed on BMRAGSO data from the Savory Sub-
basin Western Australia Quantitative aeromagnetic interpretation utilized the 3D Euler deconvolution method
supported by wavenumber filtering and image processing The results have provided useful information on structural
trends and depth to magnetic sources in a structurally complex area Depth to magnetic source analysis has provided
information on intra-sedimentary magnetic sources as well as basement rocks
The results of the interpretation support previously identified depocentres However the presence of magnetic
sources at several levels makes it very difficult to produce a reliable magnetic basement depth contour map It is
considered more productive to work with the 3D Euler colour circle plots and images rather than trying to contour the
results It would be necessary to carry out a full-scale interpretation of the BMRAGSO profile data to improve on the
3D Euler results The regional gravity was found to be useful in interpreting the regional setting of the area although
the very wide data spacing limits quantitative use of the data The gravity data show quite a complex picture with
limited consistent correlation between gravity features and basin structures This suggests that gravity anomalies
reflect changes in density of the basement rocks rather than basement topography especially in the northern part of the
basin
It is recommended that the GSWA investigate access to company confidential high-resolution aeromagnetic data
prior to planning further aeromagnetic surveys Private companies have flown large parts of the northern half of the
area as part of their diamond exploration program Additional gravity coverage of the area may be more cost effective
than magnetic surveys as the gravity data provides more information on changes within the sedimentary section
Introduction
The main use of aeromagnetic data in petroleum exploration has been the determination of magnetic basement
topography although there has been increasing interest in analysis of intra-sedimentary magnetic anomalies
intrabasement and suprabasement magnetic anomalies These anomalies are used to determine depth to magnetic
basement rocks and hence determine the thickness of the sedimentary sequence Unfortunately interpretation of the
intrabasement and suprabasement magnetic anomalies is non-unique in terms of position and size of causative sources
because of the inherent ambiguity of potential-field methods However this ambiguity can be reduced by placing
49
constraints on source geometry and magnetization and by using geological and other geophysical data to constrain
the solution
Before 1970 most depth-determination techniques involved graphical determination of slopes of selected
magnetic anomalies and application of various empirical factors to convert the slopes into depth estimates Geological
Society of America Memoir 47 Interpretation of Aeromagnetic Maps by Vacquier et al (1951) was a landmark for
this type of interpretation
Automated interpretation procedures have played an increasingly important role in depth interpretation and a
wide range of techniques have been developed Many of these techniques are designed for application to located data
profiles and assume a two-dimensional geometry However there has been renewed interest in techniques applicable
to gridded data
Two distinct types of method can be recognized In the first case often described as discrete methods individual
isolated magnetic anomalies are interpreted and the results used to produce a map of basement relief In the second
case often described as continuous methods areas of data containing a number of anomalies are interpreted
statistically to produce direct output of basement depths
The discrete methods usually involve a semiautomatic initial phase which generates a large number of possible
depth solutions and an interactive second phase to screen and select acceptable solutions The advantage of this
approach is that the interpreter can select features that are relatively free from interference from adjacent anomalies
and consider all aspects of a particular magnetic anomaly The disadvantage is that interpretation can be very time
consuming as a wide range of depths are usually possible depending on the initial model chosen and a significant
amount of effort is needed to select the correct model In the case of the Savory Sub-basin dataset we encountered
problems in separating basement related effects from the effects of shallower intrasedimentary magnetic sources
Because of these problems we have concentrated on displaying the Euler results accompanied by separation filter
images of the data to show the shallower effects and deeper effects rather than trying to refine a 3D Euler
deconvolution depth-to-crystalline-basement contour
The continuous methods are very direct provided that the rather restrictive assumption can be made that all
anomalies are due to lateral magnetization changes due to basement topography This means that shallow effects and
large intrabasement anomalies must be removed from the data This involves judgement and skill as it is necessary to
distinguish between the lower amplitude suprabasement anomalies due to basement topography and the larger
intrabasement anomalies reflecting magnetization changes within the basement These methods were not considered
suitable for the Savory Sub-basin magnetic dataset but were used to invert the gravity data
50
Limitations of magnetic and gravity interpretation
Interpretation of the area is limited by a shortage of information on the nature and physical properties of the deeper
sedimentary sequence and the underlying basement rocks However using techniques such as cross-correlation of
gravity and pseudo-gravity data it is possible to try to differentiate between anomalies relating to basement and those
related to the sedimentary sequence
Gravity anomalies reflect changes within the sedimentary sequence as well as basement condition These
changes in density of sedimentary rocks produce gravity anomalies without a corresponding magnetic anomaly hence
the complementary nature of gravity and magnetic surveys The main use of magnetics is to determine depth to
magnetic basement and any intra-sedimentary volcanic rocks or intrusives whereas gravity provides much more
general information on the sedimentary sequence
Unfortunately interpretation of gravity anomalies is complicated since they can be due to a number of geological
features including
bull major basement faults
bull basement highs
bull igneous intrusions within the basement
bull sedimentary basins which may or may not be isostatically compensated
bull intra-sedimentary volcanics and associated plutonic centres
Two major problems affect the interpretation of both magnetic and gravity data
1 The inherent ambiguity of potential-field data There is no unique solution to any measured gravity or magnetic
anomaly and theoretically there will be an infinite number of source geometry and magnetizationdensity
combinations which will fit the observed data This means that any a priori information which helps to select a
suitable model is very useful
2 Measured anomalies are the summation of effects from different depths For example an observed gravity profile
may contain contributions from shallow sources (density variations within the sedimentary basin) intermediate
depth sources (density variations due to large igneous intrusions within the basement) and deep sources (crustal
thinning producing a mantle anomaly) Separation of these component responses is the regionalresidual problem
which we solve using spectral analysis and differential upward continuation-based separation filtering
Regional setting and interpretation overview
The area studied includes parts of BALFOUR DOWNS (SF51-9) RUDALL (SF51-10) ROBERTSON (SF51-13) GUNANYA
(SF51-14) COLLIER (SG50-4) BULLEN (SG51-1) TRAINOR (SG51-2) MADLEY (SG51-3) NABBERU (SG50-5)
STANLEY (SG51-6) and HERBERT (SG51-7) 1250 000 sheets Broadly the area lies between latitudes 22deg00rsquondash25deg30rsquoS
and longitudes 119deg30rsquondash123deg30rsquoE
51
Regional gravity
The AGSO regional gravity data (at nominal 11 km spacing) was gridded at a 4 km mesh spacing using a minimum-
curvature algorithm Bouguer gravity values in the area are negative reflecting mass deficiency at depth and range
from -84 mgals to -25 mgals
A Bouguer gravity colour image is shown as Figure 41 A residual grid was produced by removing a fifth-order
orthogonal polynomial from the Bouguer data but did not add to the interpretation
120deg 121deg 122deg 123deg
23deg
24deg
25deg
-25
-84
50 km
MKS46 180598
mgal
Figure 41 Regional Bouguer gravity (BMRAGSO data) gridded at 4 km
52
The data show a complex pattern of positive and negative anomalies with no clearly defined trends Correlations
with aeromagnetic data and known basin structures are poor A vague north-northwest linear trend appears to coincide
with the Marloo Fault (Figure 42) A prominent negative anomaly appears to coincide with the Blake Fold and Fault
Belt depocentre and continues as a narrower negative anomaly to the east until it widens out again near the edge of the
basin Elsewhere the gravity data show little correlation with known basin structures and it is likely that especially in
the north of the area gravity anomalies are due to density changes in the basement rather than changes in basement
topography
Production of wavelength-filtered residual gravity plots and vertical gradient plots showed very patchy aliased
data reflecting poor sampling in much of the area
Regional magnetics
The AGSO regional aeromagnetic data were gridded at a 400 m mesh spacing using a minimum-curvature algorithm
(Figure 43) Most of the data has a line spacing of 1600 m with small areas of 1 km spacing The quality of the data is
acceptable for regional interpretation but is not adequate for detailed analysis The accuracy of the flight path is rather
variable reflecting the vintage of the data and the noise envelope of the data is poor by modern standards Problems
were also encountered in joining different map sheets
The magnetic anomaly pattern over the south and west part of the area shows a strong high frequency signature
reflecting the presence of widespread basic sills and dykes Some of the major north-northeasterly trending dykes can
be traced over considerable distances
Discontinuous high-frequency anomalies extend as a northwest-trending zone through the centre of the area and
this zone includes a conspicuous circular magnetic anomaly which is probably a ring complex
The northern and eastern parts of the area are characterized by long-wavelength deep-seated basement magnetic
anomalies with 120deg and 150deg trends dominant The Marloo and Perentie Faults (Figure 42) appear as distinct linear
zones and offsets A prominent easterly trending negative anomaly in the northwest of the area appears to swing round
to the southeast and may separate different basement blocks One possible interpretation is that this very deep seated
anomaly separates areas of Archaean and Proterozoic basement
Regional geology
The regional geology is described in Williams (1992) The GSWA provided a digitized version of Plate 2 from this
Bulletin the structural interpretation map to use as an overlay (Figure 42)
53
Pp
Pp
PSd
PSd
PSd
PSd
PSd
PSo
PSt
PSt
PSf
PSf
PSf
PSb
PSb
PSb
PSsPSs
PSs
PSb
PSm
PSp
PSc
PSc
PSw
PSw
PSw
PSg
PSr
PSj
PSg
PM
Pk
PY
PY
PSd
L
L
L
L
L
L
L
LL
L
L
L
LL
L
LL
L L
LL
L L
L
L
L
L
L
L
L
LL
L
L
BLAKEDEPOCENTRE
MA
RLO
O
FAU
LT
PERENTIEFAULT
50 km
MKS39120598
120deg 121deg 122deg 123deg
25deg
24deg
23deg
Approximate boundaryof aeromagnetic interpretation
PML
PSgL
PSjL
PML
PSpL
PML
PML
PSfL
PSfL
PSpL
LPc
LPcLPcPSrL
LPA
Durba Sandstone
Woora Woora Formation
McFadden Formation
Tchukardine Formation
Boondawari Formation
Skates Hills Formation
Mundadjini Formation
Coondra Formation
Spearhole Formation
Watch Point Formation
Jilyili Formation
Brassey Range Formation
Glass Spring Formation
Paterson Formation
Yeneena Group
Karara Formation
Cornelia Formation
Kahrban Subgroup
Bangemall Group
Fault
Formation boundary
PSdL
PSoL
PSfL
PStL
PSbL
PSsL
PSmL
PScL
PSpL
PSwL
PSjL
PSrL
PSgL
Pp
PYL
PkL
LPc
LPA
PML
Savory Group Other Units
PYL
Figure 42 Regional geology and structure map (after Williams 1992)
54
120deg 121deg 122deg 123deg
23deg
24deg
25deg
5820
3750
MKS47 180598
nT
50 km
Figure 43 Regional aeromagnetic data total magnetic intensity (BMRAGSO data) gridded at 400 m
Analysis
3D analysis
3D Euler deconvolution was used as the primary depth-determination method The advantage of this approach is that
consistent solutions can be obtained over the entire area with minimal assumptions about source geometries Euler
deconvolution of gridded data is used for positional information and estimation of depth to top of source Euler
55
deconvolution yields a large number of depth solutions which have to be screened to reject spurious solutions Results
are plotted as circles in eight depth ranges with radius proportional to depth and colour coded
The 400 m total magnetic intensity grid was used for the analysis Horizontal gradients in x and y and the vertical
gradient were calculated 3D Euler deconvolution was tested on the 400 m gridded data using windows of 9 times 9 and
11 times 11 and 16 times 16 data points and structural indices 05 (fault) and 10 (sill or dyke) It was concluded that the
16 times 16 window produced the best results overall and final plots were produced for the 16 times 16 window and structural
index 05 (Fig 44) Results were very good over the northern and central parts of the area showing magnetic sources
Figure 44 Depth to magnetic source 3D Euler deconvolution 16 times 16 window of 400 m gridded data structural index 05
56
at several different levels Unfortunately in the extreme south of the area shallow intrasedimentary magnetic sources
(sills and dykes) dominated the inversion and the results contained few basement solutions
In order to reduce these problems the 400 m gridded data were filtered using a separation filter based on
interpretation of the log-energy spectrum The 3D Euler method was run on the filtered data in order to generate more
basement-depth solutions Results for the deep-separation filter data were gridded and presented as a colour image in
Cowan (1995) Attempts to grid the Euler output were unsatisfactory and it is considered safer to interpret the 3D
Euler depth plots The 3D Euler depth results from the separation-filter run should be analysed with care as perfect
separation of the basement can never be achieved and there will always be some contamination from sources at
different levels
The results of original total magnetic intensity 3D Euler depth estimation for structural index 05 using a 16 point
window have been plotted at 1500 000 scale (not included in this publication but available in Cowan (1995) from the
GSWA Library as S10331) and as reduced A4 colour circle plots (Figure 44)
The results of deep-basement 3D Euler depth estimation for structural index 05 using a 16 point window have
been plotted as a colour image at 1500 000 scale and as an A4 image (not included in this publication)
2D analysis
Two equispaced profiles were interpolated with a 50 m station interval from the AGSO-located data profiles for the
BULLEN 1250 000 sheet The interpolated profiles were analysed using 2D Euler deconvolution and Werner
deconvolution Results are included in Cowan (1995) and show the use of these methods for more detailed analysis
Filtered data
In order to reconcile 3D Euler results from shallow basement and intrasedimentary magnetic sources we produced
several separation-filtered maps and images We found the shallow-layer double-separation filter (Figure 45) to be
very effective for shallow sources and the deep-layer standard-separation filter (Figure 46) for the basement layer
Gravity and magnetic data correlation
Both lsquoreduced to the polersquo (RTP) magnetics (Figure 47) and pseudo-gravity data (Figure 48) were produced as part of
the reconciliation of gravity and magnetic signatures In both cases the filtering operations assumed magnetization by
induction in the present Earths field The RTP data are fairly similar to the total magnetic intensity The pseudo-
57
gravity data are dominated by a northwest-trending strong positive anomaly and there is little correlation with the
Bouguer gravity data
The poor magneticgravity correlation is confirmed by cross-correlation of the RTP magnetics and the gravity
gradient The correlation plot in Figure 49 shows little coherent response with numerous zones of positive and
negative correlation
Figure 45 Regional aeromagnetic data shallow layer separation filter (BMRAGSO data) gridded at 400 m
Results
In the north and east of the area on the Wells Foreland Sub-basin trend (refer to Figure 1 main text) we see a range
of quite deep 3D Euler depths and several trend directions with north-northwesterly dominant There are relatively few
shallow intrasedimentary solutions in this zone
The second area of deep 3D Euler solutions lies over the Blake depocentre (Figure 43) with several trend
directions
Elsewhere the 3D Euler results are dominated by shallow intrasedimentary depth solutions reflecting mainly the
dolerite sills dykes and the ring complex However where we do see basement-related solutions in the south and
west of the area they appear to be shallower than those noted for the Wells Foreland Sub-basin and the Blake
depocentre
58
Figure 46 Regional aeromagnetic data deep-layer separation filter (BMRAGSO data) gridded at 400 m
Figure 48 Regional aeromagnetic data pseudo-gravity transform (BMRAGSO data) gridded at 400 m
Figure 47 Regional aeromagnetic data reduced-to-pole (BMRAGSO data) gridded at 400 m
Figure 49 Regional aeromagnetic and gravity data gravitymagnetic correlation using RTP magnetics and gravity gradient (BMRAGSO data) gridded at 4 km
59
This subdivision of the area into two zones of deep solutions is consistent with interpreted depocentres
However the interference between sources at different levels and the complexity of the magnetic response of the
basement rocks precludes more refined interpretation at this stage
The area of deep 3D Euler solutions over the Blake depocentre correlates with the pronounced negative gravity
anomaly discussed in the gravity interpretation section Using a density contrast of -015 gcc the negative gravity
anomaly could indicate up to 6ndash8 km of low-density sedimentary rocks depending on assumptions about the regional
field
The area of deep 3D Euler solutions over the Wells Foreland Sub-basin has a complex gravity expression and no
clear basin structure emerges from inversion of these data As noted previously it is likely that observed gravity
anomalies reflect contrasts in basement density rather than basement topography
Separation filtering applied to the magnetic data helps to enhance the intrasedimentary magnetic signature and to
give a better impression of the basement magnetic signature even though separation of the basement response is not
perfect
Conclusions
Quantitative aeromagnetic interpretation using 3D Euler deconvolution supported by wavenumber filtering and image
processing has been successful in providing structural trend and depth information for the Savory Sub-basin
Quantitative magnetic interpretation has revealed two zones of relatively deep magnetic basement beneath the
Wells Foreland Sub-basin and the Blake depocentre
This analysis of the magnetic data supports interpreted depocentres but the complexity of the basement magnetic
signature and interference from sources at different depths precludes further refinement to a map of basement
topography
Regional gravity proved to be very useful in understanding the regional setting of the area and in providing
support for aspects of the interpretation The gravity data support the interpretation of the Blake depocentre
suggesting up to 6ndash8 km of low-density sedimentary rocks
The deep structure of the Savory Sub-basin area is obviously complex with different areas underlain by
Archaean and Proterozoic basement and with the Capricorn suture occurring in the centre of the area
60
Recommendations
The quantitative magnetic interpretation needs to be reconciled with geological models available for the area
In particular the zones tentatively identified as areas with thick sedimentary rocks the Wells Foreland Sub-
basin and the Blake depocentre need to be investigated
Cross sections should be prepared across the basin for joint magneticgravity modelling especially for the Blake
depocentre It is important to be able to explain the strong negative gravity anomaly in this area
In view of the effects of basement density contrasts on the gravity field for the northern part of the area we think
that additional gravity interpretation and acquisition of new gravity data may not be justified as they will not
contribute significantly to understanding basin evolution and structure
It is recommended that GSWA try to get access to company confidential high-resolution aeromagnetic data
rather than flying new surveys The GSWA might offer to fund flying of new infill areas as a bargaining point
References
The original text of this report by Cowan (1995) and 1500 000 scale maps are filed in the GSWA Library under
S10331
COWAN D 1995 Savory Basin quantitative magnetic interpretation Western Australia Geological Survey S-series
S10331 (unpublished)
VACQUIER V STEENLAND N C HENDERSON R G and ZIETZ I 1951 Interpretation of aeromagnetic
maps The Geological Society of America Memoir 47 151p
WILLIAMS I R 1992 Geology of the Savory Basin Western Australia Western Australia Geological Survey
Bulletin 141 115p
61
Appendix 5
Geochemistry
MKS38 250398
Saturate FractionC12+ GLC
1217
Pr18
Ph
22
31CSR WELL-13 315m Cuttings
Figure 51 Canning Stock Route Well 13 gas chromatograph of extract of auger drill sample
12
17
18
22
31
Pr Ph
LDDH 1 6623m CoreSaturate FractionC12+ GLC
MKS35 240398
Figure 52 Gas chromatograph of extract from core sample at 6623 m LDDH1
62
Table 51 Canning Stock Route Well 13 auger drill samples
GSWA sample Drill depth (m)(a) Comments
135601 150 At watertable 135602 203 (all samples consist 135603 310 of sand mud and water) 135604 315 At total depth
NOTE (a) Datum for drill depth is the top of sediment fill in the well which is 155 m below ground level (ie the total depth of 315 m is 47 m below ground level)
Table 52 Canning Stock Route Well 13 gas chromatography data for 315 m depth sediment sample
Parameter Value
Weight of rock extracted (grams) 945 Total extract (ppm) 519 n-Alkane distribution n-C12 07 n-C13 23 n-C14 26 n-C15 22 n-C16 19 n-C17 14 i-C19 23 n-C18 14 i-C20 08 n-C19 11 n-C20 16 n-C21 25 n-C22 29 n-C23 70 n-C24 42 n-C25 95 n-C26 43 n-C27 83 n-C28 38 n-C29 87 n-C30 31 n-C31 273 Alkane compositional data Pristane phytane ratio 279 Pristane n-C17 ratio 161 Phytane n-C18 ratio 059 CPI (1)(a) 284 CPI (2) 209 (C21 + C22) (C28 + C29) 043
NOTE (a) CPI= Carbon preference index
63
Table 53 LDDH1 extract liquid chromatography data for 6623 m concentration
Rock extracted Total extract (grams) (ppm)
702 313
NOTE ppm= parts per million
Table 54 LDDH1 saturate gas chromatography data of core for 6623 m alkane composition
Pristane Pristane Phytane (a) CPI (1) CPI (2) (C21+C22) Phytane n-C17 n-C18 (C28+C29)
103 026 024 103 102 325
NOTE (a)CPI = carbon preference index
Table 55 LDDH1 saturate gas chromatography data of core for 6623 m n-alkane distributions
Parameter Value
n-C12 17 n-C13 38 n-C14 55 n-C15 60 n-C16 65 n-C17 74 i-C19 19 n-C18 78 i-C20 19 n-C19 80 n-C20 79 n-C21 71 n-C22 64 n-C23 57 n-C25 43 n-C24 38 n-C27 31 n-C28 23 n-C29 19 n-C30 12 n-C31 10
64
Appendix 6
Table 61 Summary of data from Trainor waterbores (TWB) and Bullen waterbores (BWB)
Well AMG Elevation TD Status(b) Completion details Water Salinity Water level Flow rate Depth to consolidated AGD84 GL (m) (m) struck mgl(c) (m) (LHr) lithology aquifer(e) Z51(a) Interval (m) (100 mm PVC) (m) (mgl)(d)
TWB 1 473660E 453 122 comp 0ndash75 plain 63 7 300 24 2 880 12 m 7287404N 75ndash93 slotted (9 260) McFadden Fm 93ndash99 plain TWB 2 472 977E 475 23 abd nil 15 m 7285877N Skates Hills Fm dry TWB 3 473259E 475 50 abd nil 7 m 7285849N Skates Hills Fm dry TWB 4 463225 E 445 50 comp 0ndash22 plain 35 7 200 55 3 600 0 m 7286143N 22ndash34 slotted (8 140) Tertiary sand and gravel 23ndash60 plain TWB 5 463095E 445 31 comp 0ndash19 plain 13 26 000 655 3 600 Tertiary sand and gravel 7277721N 19ndash25 slotted (36 700) 25ndash31 plain TWB 6 457013E 455 50 comp 0ndash42 plain 38 920 119 600 0 m 7274352N 42ndash48 slotted (1 030) Cornelia Fm ss TWB 7 453739E 475 26 susp 0ndash2 plain 11 9 300 48 4 500 0 m 7263891N (10 500) Tertiary sand TWB 8 433893E 535 60 susp 0ndash2 plain 47 8 500 gt46 1 200 0 m 7245991N (10 900) Tertiary sand and Brassey Range Fm ss TWB 9 437219E 505 51 comp 0ndash47 plain 45 1 000 58 600 1 m 7235905N 47ndash51 slotted (990) Brassey Range Fm ss TWB 10 434927E 495 32 susp 0ndash2 plain 235 450 120 0 m 7225875N (500) Dolerite
65
BWB 1 287337E 580 122 abd Nil 1 m 7245861N Jilyili Fm dry BWB 2 288346E 545 50 comp 0ndash26 plain 15 630 3 29 000 0 m 7240423N 26ndash38 slotted (730) Tertiary sand and gravel 38ndash50 plain BWB 3 305637E 545 50 abd 19 8 800 43 7 200 0 m 7240423N (10 550) Tertiary ss BWB 4 320167E 515 445 comp 0ndash20 plain 9 980 445 24 000 0 m 7248097N 20ndash32 slotted (1 190) Tertiary ss 32ndash44 plain BWB 5 353393E 545 20 susp 0ndash2 plain 45 (970) 1 m 7238934N Basalt
NOTES (a) GPS accuracy ~ 150 m (b) Comp = completed abd = abandoned susp = suspended (c) Salinity from conductivity (d) Analysis total dissolved solids (e) Fm = Formation ss = sandstone
23
Group of the Officer Basin in South Australia both of which have some source potential
(Summons and Powell 1991 Morton and Drexel 1997) Samples from the Dey Dey Mudstone of
the Ungoolya Group generally have poor TOC values (average 011 range 003ndash081)
moderate hydrogen index (HI) values (100ndash382) and poor to fair genetic potential with a
maximum of 292 kg hydrocarbon per tonne of source rock (Morton and Drexel 1997)
Stromatolitic dolomites and mudstones at the top of the Boondawari Formation and within the
Skates Hills Formation are potential source rocks Stromatolitic dolomite and evaporitic rocks
deposited in a marginal marine to sabkha environment are considered to have good potential to
generate and preserve organic carbon without requiring a deep-water setting (Stevens and Grey
1997) Such conditions are recognized in the Skates Hills Formation and in the upper parts of the
Tarcunyah Group
Maturity
Knowledge of the maturity of sedimentary rocks within the Savory Sub-basin is still limited From
a review of palynological studies Grey and Stevens (1997) report that the thermal maturity
inferred from the Thermal Alteration Index (TAI) of 3+ from Supersequence 1 age palynomorphs
in TWB 6 TWB 9 and LDDH1 is within the hydrocarbon window (Appendix 3) In Phanerozoic
spores and pollen a TAI of 3+ approximately equates to the end of liquid petroleum generation
and the start of dry gas generation and to a vitrinite reflectance of about 13 (Traverse 1988)
However the use of TAI for estimating thermal maturity from Neoproterozoic palynomorphs
requires calibration
In Trainor 1 the Cornelia Formation contains organically rich claystones between 375 and
6032 m depth Based on Rock-Eval maturity data (Stevens and Adamides in prep) and the dark
colour of poorly preserved organic material (Grey 1995de 1996) with TAI 4- to 5 all samples
had a high level of maturation with at best dry-gas generating potential remaining In contrast
drillhole LDDH1 on GUNANYA recorded lower levels of maturity (TAI values of 3+) with two of
sixteen samples from the Tarcunyah Group having greater than 1 TOC (Grey 1995abc Grey
and Cotter 1996) Organic petrology and Rock-Eval maturity data for samples from LDDH1
indicate that the section above 500 m is within the oil-generative window whereas below 500 m
the rocks are within the gas window (Ghori in prep Fig 9 Appendix 5)
Waterbores TWB 1 2 6 and 9 which are located on TRAINOR in the southeast of the sub-
basin all had organic matter with TAI values of 3+ from the McFadden Skates Hills Cornelia
and Brassey Range Formations respectively
24
100
200
300
400
500
600
700
Oil
gene
ratin
g
Gas
gene
ratin
g
Fai
r
Fai
r
Poo
r
Poo
r
Goo
d
Imm
atur
e
Oil
win
dow
Oil
win
dow
Imm
atur
e
01 0110 10 0 150 300 440 480 1
Neo
prot
eroz
oic
TOC S1+S2 mgg Hydrogen Index Tmax degC
Depth(m)
Organicrichness
Generatingpotential
Kerogentype Maturity Maturity
TD=701m
Sandstone
Mudstone
Dolomite
Limestone
Evaporite
Source rock
MKS40 070498
Ro equivalent
Figure 9 Petroleum source potential of rocks in Normandy LDDH1
Small amounts of organic matter associated with basalt and dolerite in cuttings from
waterbore BWB 1 on BULLEN showed high levels of thermal maturity (Grey 1995a Libby 1995)
It is unclear whether all sedimentary rocks on BULLEN are overmature for hydrocarbon generation
or the results from BWB 1 are related to local heating events associated with the volcanic bodies
that are common in the Jilyili Formation
25
Reservoirs
Each of the five depositional sequences of the Savory Group (Table 1) are inferred to contain
significant sandstone reservoirs with the possible exception of depositional sequence C as
discussed above in Stratigraphy The Spearhole Formation was cored in Mundadjini 1 and
Boondawari 1 and visual estimates of porosity vary from generally poor (less than 5) to fair
(approximately 5ndash15) The McFadden Formation in Trainor 1 has porosity values of up to 232
and a maximum permeability of 195 md (Stevens and Adamides in prep) Sandstones from
Neoproterozoic formations form the acquifers in the following waterbores the McFadden
Formation in TWB 1 the Cornelia Formation in TWB 6 and the Brassey Range Formation in
TWB 8 and TWB 9 (Appendix 6 Table 61)
Based on outcrop observations the Durba Sandstone is considered to be the best reservoir of
the Savory Group Similarly some sandstones from the Tarcunyah Group also have good visible
porosity in outcrop
Dolomites occur in several formations in the sub-basin Reservoir potential may exist
particularly where the dolomites are stromatolitic and oolitic However dolomites have not been
drilled in the sub-basin and porosity can only be inferred from the preferential silicification of
some stromatolite bioherms observed in outcrop (Stevens and Grey 1997) Elsewhere in the
Officer Basin porosities of up to10 have been measured in dolomites A limestone breccia
(karst) is described from 663 to 677 m in drillhole LDDH1 (Fig 6 Busbridge 1994)
Seals
Indications of evaporitic environments in the Mundadjini Skates Hills and Boondawari
Formations are described by Williams (1992) In Mundadjini 1 from 287 to 337 m anhydrite and
chert occurs as nodules beds and veins in mudstone of the Mundadjini Formation Evaporitic
minerals (predominantly gypsum) are described in the Tarcunyah Group in LDDH1 The presence
of the Woolnough and Madley salt diapirs in the Officer Basin (approximately 110 km east of the
sub-basin) and halite beds over 25 m thick in the well Hussar 1 (130 km east of the sub-basin)
provide further evidence that evaporite seals may be present in the Savory Sub-basin
Mudstones and shales form only a small proportion of the limited Neoproterozoic outcrop in
the sub-basin but significant thicknesses of mudstone were encountered in the Mundadjini
Formation in Mundadjini 1 and Boondawari 1 the Tarcunyah Group in LDDH1 and in the
26
Cornelia Formation in Trainor 1 These data suggest that mudstones form a significant proportion
of strata in the sub-basin despite their limited outcrop
Traps
Potential structural closures including folds and faults occur at various scales throughout the
Savory Sub-basin However the region has only been mapped at 1250 000 scale and
independently closed structures such as domes have yet to be confirmed The western margin of
the basin contains abundant faults (with a northeast strike) but elsewhere faults are less common
Some anticlines are recognized in outcrop including one with a strike length of up to 45 km
inferred from surface bedding dips in the Mundadjini and Spearhole Formations at approximately
24deg15rsquoS 121deg10rsquoE on BULLEN (Fig 1)
Salt diapirs and other halokinetic structures are recognized in outcrop well and seismic data
in the Officer Basin to the west of the Savory Sub-basin and it is probable that there are
significant thicknesses of evaporitic sedimentary rocks in the sub-basin The gravity field data
suggest there is good potential for salt diapirs and traps related to halokinesis
Although there is potential for stratigraphic traps to be present in the sub-basin insufficient
data are available to assess them
Preservation of hydrocarbons
The range of thermal maturities measured to date and the large periods of time envisaged for
deposition of sediments implies hydrocarbon generation may have occurred a number of times
during the evolution of the Savory Sub-basin Any hydrocarbons that were generated early may
have been trapped in palaeostructures and remigration to younger traps could have taken place
later The Petermann Ranges Orogeny which has been equated with the Paterson Orogeny (Myers
1990) is believed to have occurred in the latest Neoproterozoic to early Cambrian This is the last
major tectonic event recognized in the sub-basin suggesting that it is reasonable to expect that trap
integrity will have been preserved
If the inference of the presence of thick halite beds in the sub-basin is correct the preservation
potential of sub-salt traps should be excellent
27
Reported hydrocarbon shows and oil seep
Amadeus Petroleum recorded minor oil shows in cores from Mundadjini 1 and Boondawari 1 In
Mundadjini 1 at 36102 m (top of the Spearhole Formation) a 3 mm thick zone had 10 moderate
white fluorescence with slow solvent cut This show was in a granular sandstone with visually
estimated porosity of about 10 In Boondawari 1 at 35364 m (within the Spearhole Formation) a
broken surface of sandstone had 40 moderate yellow-white fluorescence with slow solvent cut
Visually estimated porosity is about 5 Because the fluorescing surface was broken during the
drilling process this show could have resulted from contamination A second show occurs in
Boondawari 1 at 4963 m (within the Spearhole Formation) where a 1 cm-thick zone had 5 dull
yellow fluorescence with slow solvent cut in a conglomerate with visually estimated porosity of
about 10 The company intends to further investigate the nature of these occurrences
Minor bitumen is present at 6623 m in drillhole LDDH1 on GUNANYA (Figs 5 and 6) as a
vein in mudstones of the Tarcunyah Group A sample was analysed by gas chromatography
(Ghori in prep) and confirmed that it is natural bitumen (Appendix 5)
Mineral hole OD 23 drilled by Jubilee Gold Mines NL on NABBERU in the Bangemall Basin
immediately to the south of the Savory Sub-basin (Fig 5) encountered bitumen and trace oil in
vugs in dolomite (M Stevens unpublished data) but no further data are available at present
In their popular guide to the Canning Stock Route Gard and Gard (1990 p 218) refer to an
oil seep at Well 13 on TRAINOR (Fig 5) They reported that between 1977 and 1984 lsquonatural oilrsquo
was seen in the well Although the well is now largely filled with sediment four auger drill
samples were collected by the GSWA in 1995 and all four were analysed for oil shows One
sample from 315 m total depth (GSWA sample 135604) yielded just enough extract (519 ppm)
for saturate gas chromatography analysis The gas chromatograph (Appendix 5) shows that the
extract does contain some hydrocarbons probably from recent plant material Because the depth to
the oil was not quoted in Gard and Gard (1990) the hand-augered well may not have been deep
enough to properly test this reported seep
Geological and geophysical databases
Geological and geophysical data available for the Savory Sub-basin are limited The most recently
completed geological maps for the sub-basin were published by the GSWA between 1991 and
1995 (Williams and Tyler 1991 Williams 1992 1995ab)
28
The cores from the five drillholes listed in Table 2 believed to be all of the core available
from the sub-basin are available for inspection at GSWA Mineral exploration reports submitted
to GSWA may be searched using the WAMEX database and open-file reports are available on
microfiche Geophysical data acquired by the mining industry is not required to be filed with
GSWA if acquired over Vacant Crown Land which is the case for much of the sub-basin
Geophysical survey data submitted in mining tenement reports and which extend into Vacant
Crown Land remain confidential to the companies Original regional aeromagnetic and gravity
datasets are available from the Australian Geological Survey Organisation (AGSO)
Data pertinent to oil exploration in the sub-basin such as structural style and salt diapirism
are presented in a review of the hydrocarbon prospectivity of the Officer Basin (Perincek 1998)
Drilling
Significant drillholes in the sub-basin are summarized in Table 2
Petroleum industry data
Amadeus Petroleum drilled three petroleum exploration wells in the central west of the Savory
Sub-basin in late 1997 These wells Mundadjini 1 Boondawari 1 and Akubra 1 were drilled by
continuous diamond coring (Figs 5 and 6) All targeted potential reservoirs within the Spearhole
Formation with the Mundadjini Formation as the proposed seal The wells were located on
structures interpreted from Landsat images and limited geological investigations Both Mundadjini
1 and Boondawari 1 had minor oil shows as discussed above (Reported hydrocarbon shows)
Government data
Stratigraphic drillhole Trainor 1 was drilled by GSWA in 1995 (Stevens and Adamides in prep)
and the main results are discussed above (Source rocks and Maturity)
Mineral industry data
Normandy Exploration drillhole LDDH1 was cored in the Tarcunyah Group to a total depth of
701 m and provided source-rock and maturity data as discussed above
29
Oilmin NL drilled six percussion drillholes (BD 1 3 4 5 8 and 9) through sandstones and
shales in the northern part of the Savory Sub-basin to a maximum depth of 198 m (Fig 5
WAMEX Microfiche File M 26811 I 2610) but only brief geological descriptions are available
Hydrogeological data
Hydrogeological data within the Savory Sub-basin are limited although a long history of water
exploration extends back to the construction of the Canning Stock Route early this century No
detailed geological or wireline logs are available for the older wells along this route A few station
wells have been drilled by various methods on the south and west margins of the basin but data
are unavailable as reports are not required to be filed with the government Depth to watertable
throughout the basin is largely controlled by porosity of the bedrock
The GSWA drilled fifteen waterbores in the winter of 1995 in the southern part of the sub-
basin in preparation for the drilling of Trainor 1 and the proposed Bullen 1 Twelve bores found
water and six of these bores have salinities of less than 1000 mgL (Fig 5 Appendix 6 Table 61)
One waterbore TWB 6 has gamma ray and neutron logs run through PVC casing and these are
available from the GSWA with the digital log data included herein
Seismic data
No geophysical data have been acquired by the petroleum industry in the Savory Sub-basin
Seismic data acquired in the Officer Basin to the east particularly in the Gibson and Yowalga
Sub-basins is pertinent to structural interpretation in the Savory Sub-basin (Perincek 1996a
1998)
Aeromagnetic surveys
Government data
There are over 95 277 line kilometres of aeromagnetic data included in the AGSO dataset There
are three regional aeromagnetic surveys covering the Savory Sub-basin These were flown by the
Bureau of Mineral Resources (BMR now AGSO) in 1984 at a line spacing of 1500 m with 36 740
and 52 587 line kilometres flown and by Aerodata in 1984 at a line spacing of 1000m with 5950
line kilometres flown These data were reprocessed and interpreted for GSWA by Cowan (1995)
An edited copy of this report is included as Appendix 4 and the original report is filed in the
GSWA Library under S-series reports item 10331
30
Mineral industry data
The approximate locations of non-AGSO aeromagnetic surveys are shown in Figure 8 More
detailed information regarding the location of these surveys may be obtained using the GSWA
MAGCAT II database Additional information such as contours of aeromagnetic values may be
obtained by inspecting items on file with the GSWA
Gravity surveys
Government data
The average spacing for gravity data in the Savory Sub-basin is one station per 121 km2 (11 times 11
km grid) These data were principally collected by BMR in the early 1960s There are a few
additional regional gravity traverses across the sub-basin which are also included in the
BMRAGSO dataset These data were reprocessed and interpreted for GSWA (Fig 10) and a
report on this work is also included in Appendix 4
The GSWA completed a large semi-detailed gravity survey in the eastern Savory Sub-basin
utilizing helicopter support and Differential Global Positioning Survey (DGPS) techniques (Fig
8) This gravity survey completed in August 1995 consists of 2300 gravity stations on a 2 times 3 km
grid All stations were acquired by helicopter using Scintrex gravimeters and Ashtek dual
frequency DGPS equipment for determining location This highly efficient system allowed the
acquisition of more than 100 gravity stations per day in remote areas The resolution of this survey
is +30 cm and +05 microms-2 (Daishsat 1995) These data (Fig 11) represent a significant
improvement on the previous regional survey data and are available from GSWA (GSWA
1996ab) The results of the interpretation of these data were presented at the 1997 ASEG
Convention (Carlsen and Shevchenko 1997)
Mineral industry data
Three small gravity surveys were conducted by Oilmin NL (Fig 8) and the relevant WAMEX
reports are M 2681I 2610 I 2435 I 2567 These three surveys are of limited value because height
control was provided by barometers only and the surveys were not tied to the national gravity grid
31
23deg
25deg
120deg 122deg
Trainor 1
SAVORY
SUB-BASIN
MKS54 160498
100 km
1995 SavoryGravity Survey
254
-1056
micromsec2
Figure 10 Regional Bouguer gravity map of the Savory Sub-basin
23deg
24deg
25deg
122deg30 123deg
TRAINOR 1
123deg30
50 km
MKS53 160498
-116
-626
micro msec2
Figure11 Detailed Bouguer gravity map of the
Savory 1995 Gravity Survey from the eastern Savory Sub-basin
32
Government and academic reports
Chronostratigraphy and geochemistry
The understanding of Neoproterozoic organic chemistry palynology and structural evolution is
essential to the interpretation of hydrocarbon prospectivity Pertinent reports are included in the
bibliography (Appendix 1) Unpublished palaeontology reports describe the palynology of wells in
the Savory Sub-basin (Grey 1995andashe 1996a) Grey and Cotter (1996) discussed the potential for
Neoproterozoic palynomorphs to provide a biostratigraphic framework and palaeoenvironmental
interpretation Grey and Stevens (1997) reviewed the results of palynological studies of wells
drilled in the sub-basin and reported that Supersequence 1 palynomorphs are present in TWB 6
TWB 9 and LDDH1 (Appendix 3) Grey (1996b) reported on the use of stromatolites for
correlation in the Neoproterozoic and Stevens and Grey (1997) discussed the application of
stromatolite biostratigraphy in correlating isolated dolomite outcrops in the sub-basin with well
and seismic data in the Officer Basin and Centralian Superbasin
Although geochemical data from the Savory Sub-basin are very limited results mostly
confirm thermal maturities inferred from TAI for LDDH1 and Trainor 1 (Ghori in prep Stevens
and Adamides in prep) Those parts of the Officer Basin in Western Australia which lie to the
east of the Savory Sub-basin are sparsely drilled but Ghori (in prep) reports that most of the
Neoproterozoic succession presently lies within the oil-generative window However his study
has been unable to identify effective source-rock units and the source for oil shows Thin source
rocks are present in the Neoproterozoic in LDDH1 (Fig 9) and in three wells which lie to the east
and southeast of the Savory Sub-basin namely NJD 1 Kanpa 1A and Yowalga 3
Proposed work program
From the above limited information it is concluded that additional research on the hydrocarbon
potential of the sub-basin is justified and proposals are outlined below
bull Additional modelling of gravity and aeromagnetic data from the Savory Sub-basin is required
in light of the results from Trainor 1 and Boondawari 1 Trainor 1 showed that what appeared
to be a structurally simple area based on outcrop aeromagnetic and gravity data was in fact an
area of major structuring Boondawari 1 intersected a dolerite which is in good depth
agreement with aeromagnetic depth to source results showing this technique is useful in
detecting the depth to intrusive bodies
33
bull Additional data from mineral and petroleum exploration bores may become available and
analysis of samples from these wells should be undertaken and interpreted in the context of
their relevance to the Officer Basin
bull Stratigraphic coring in the Blake Fault and Fold Belt and in the Wells Foreland Sub-basin (Fig
1) targeting source rocks is considered essential to the continuing evaluation of the
hydrocarbon prospectivity of the Savory Sub-basin
bull Correlations using at least outcrop well and potential-field data should be prepared to link the
sub-basin with the better known parts of the Officer Basin to the east
bull Remapping is required to clarify boundary positions within the Cornelia Formation this may
resolve some of the current problems of the relationship between this unit and the rest of the
Savory Sub-basin
bull Further work is required to explain the Early Cambrian or Sturtian ages interpreted for the
Cornelia Formation from sedimentary zircon UndashPb dating in drillhole Trainor 1 The
determination of the age of the organically rich but overmature claystones in this well is
critical to assessing the hydrocarbon potential of the region
bull The thin dark mudstones intersected by Akubra 1 in the Mundadjini Formation warrant
geochemical analysis Analyses of the oil shows in Mundadjini 1 and Boondawari 1 are
currently being undertaken by Amadeus Petroleum
bull Geochemical analysis of hydrocarbons in the Bangemall Basin drillhole OD23 has been
performed by Jubilee Gold and the results will be reviewed when they are submitted to
GSWA The possibility of source rocks within the Bangemall Basin charging traps within the
Bangemall Basin and the overlying Savory Sub-basin requires further investigation
Conclusions
The Savory Sub-basin is a frontier region with only three recently drilled petroleum exploration
wells and no seismic data Based on existing geological and geophysical data it is considered too
early to draw conclusions about the hydrocarbon prospectivity of the sub-basin at this stage and
there are several reasons why the area warrants further investigation
34
1 Thick accumulations of sedimentary rocks are present (up to 8 km thickness inferred) which
may contain source reservoir and sealing strata
2 Minor oil shows occur in Mundadjini 1 and Boondawari 1 and bitumen is present in mineral
exploration drillhole LDDH1 suggesting that hydrocarbons have migrated within the
Neoproterozoic sequence of the Savory Sub-basin Oil and bitumen are present in mineral
exploration drillhole OD23 in the Bangemall Basin immediately to the south of the Savory
Sub-basin and it is possible that source rocks from the Bangemall Basin could charge traps in
the overlying Savory Sub-basin
3 The age of sedimentary rocks in the sub-basin is still poorly constrained but some of the
Neoproterozoic sedimentary rocks located on GUNANYA and TRAINOR are within the
hydrocarbon-generation window It is possible that a significant thickness of Phanerozoic
sedimentary rocks may also be present
4 Friable sandstones with visible porosity outcrop extensively suggesting numerous potential
reservoirs
5 Significant but not intense faulting and folding has been mapped implying large structural
traps may be present
6 Evaporitic sedimentary rocks occur in several formations and may provide good source rocks
and excellent seals
35
References
APAK S N and CARLSEN G M 1997 A compilation and review of data pertaining to the
hydrocarbon prospectivity of the Canning Basin Western Australia Geological Survey
Record 199610 103p
BAGAS L GREY K and WILLIAMS I R 1995 Reappraisal of the Paterson Orogen and
Savory Basin Western Australia Geological Survey Annual Review 1994ndash95 p 55ndash63
BUSBRIDGE M 1994 Lake Disappointment Exploration Licence 451064 Third Annual
Report Lake Disappointment Diamond Drill Hole LDDH1 Normandy Exploration Limited
Western Australia Geological Survey M-series Item 7567 A41358 (unpublished)
CARLSEN G M and SHEVCHENKO S I 1997 Petroleum exploration in Proterozoic basins
using potential fields data and stratigraphic coring Australian Society of Exploration
Geophysicists 12th Geophysical Conference Handbook Sydney 1997 Preview no 66 p 83
(abstract only)
COWAN D 1995 Savory Basin quantitative magnetic interpretation Western Australia
Geological Survey S-series S10331 (unpublished)
DAISHSAT PTY LTD 1995 Operational and processing report Savory Basin gravity survey
Western Australia Geological Survey S-series S10332 (unpublished)
GARD E and GARD R 1990 Canning Stock Route a travellerrsquos guide for a journey through
history Perth Western Australia Western Desert Guides 448p
GEOLOGICAL SURVEY OF WESTERN AUSTRALIA 1996a Savory Basin first vertical
derivative of Bouguer gravity image 1250 000 Western Australia Geological Survey
GEOLOGICAL SURVEY OF WESTERN AUSTRALIA 1996b Savory Basin Bouguer gravity
image 1250 000 Western Australia Geological Survey
GHORI K A R in prep Petroleum source rock potential and thermal history Officer Basin
Western Australia Western Australia Geological Survey Record
36
GREY K 1995a Savory Basin drillhole BWB 1 (Bullen waterbore) palynology and thermal
maturation GSWA Palaeontology Report no 199512 (unpublished)
GREY K 1995b Savory Basin drillholes TWB 1 2 6 9 (Trainor waterbores) palynology and
thermal maturation GSWA Palaeontology Report no 199520 (unpublished)
GREY K 1995c Palynology of Normandy-Poseidon Lake Disappointment-1 corehole
Tarcunyah Group Paterson Orogen GSWA Palaeontology Report no 199521 (unpublished)
GREY K 1995d Savory Basin drillhole Trainor 1 (Trainor diamond drilling) palynology and
thermal maturity GSWA Palaeontology Report no 199524 (unpublished)
GREY K 1995e Savory Basin drillhole Trainor 1 (Trainor diamond drilling) Additional
Preparation of two samples GSWA Palaeontology Report no 199528 (unpublished)
GREY K 1995f Neoproterozoic stromatolites from the Skates Hills Formation Savory Basin
Western Australia and a review of the distribution of Acaciella australica Australian Journal
of Earth Sciences v 42 p 123ndash132
GREY K 1996a Savory Basin drillhole Trainor 1 (Trainor diamond drilling) Additional
samples palynology and thermal maturation GSWA Palaeontology Report no 199615
(unpublished)
GREY K 1996b Preliminary stromatolite correlations for the Neoproterozoic of the Officer
Basin and a review of Australia-wide correlations GSWA Palaeontology Report no 199615
(unpublished)
GREY K and COTTER K L 1996 Palynology in the search for Proterozoic hydrocarbons
Western Australia Geological Survey Annual Review for 1995ndash96 p 70ndash80
GREY K and STEVENS M K 1997 Neoproterozoic palynomorphs of the Savory Sub-basin
Western Australia and their relevance to petroleum exploration Western Australia
Geological Survey Annual Review for 1996ndash97 p 49ndash54
HUBBARD R J PAPE J and ROBERTS D G 1985 Depositional sequence mapping as a
technique to establish tectonic and stratigraphic framework and evaluate hydrocarbon
potential on a passive continental margin in Seismic stratigraphy II an integrated approach
37
edited by O R BERG and D G WOOLVERTON American Association of Petroleum
Geologists Memoir 39 p 79ndash91
LIBBY WG 1995 A petrological report on six samples of bore cuttings from the Savory Basin
Western Australia Western Australia Geological Survey S-series S31307 (unpublished)
MORTON JGG and DREXEL JF 1997 The petroleum geology of South Australia Vol 3
Officer Basin South Australia Department of Mines and Energy Resources Report Book
9719
MUHLING P C and BRAKEL A T 1985 Geology of the Bangemall Group mdash the evolution
of an intracratonic Proterozoic basin Western Australia Geological Survey Bulletin 128
219p
MYERS J S 1990 Precambrian tectonic evolution of part of Gondwana southwestern Australia
Geology v18 p 537ndash540
NELSON D R 1997 Compilation of SHRIMP UndashPb zircon data Western Australia Geological
Survey Record 19972 196p
PAYTON C E 1977 Seismic stratigraphy mdash applications to hydrocarbon exploration
American Association of Petroleum Geologists Memoir 26 516p
PERINCEK D 1996a The age of NeoproterozoicndashPalaeozoic sediments within the Officer Basin
of the Centralian Super-basin can be constrained by major sequence-bounding unconformities
APPEA Journal v 36 pt 1 p 350ndash368
PERINCEK D 1996b The stratigraphic and structural development of the Officer Basin
Western Australia a review Western Australia Geological Survey Annual Review 1995ndash
1996 p 135ndash148
PERINCEK D 1998 A compilation and review of data pertaining to the hydrocarbon
prospectivity of the Officer Basin Western Australia Geological Survey Record 19976
POSAMENTIER H W JERSEY M T and VAIL P R 1988 Eustatic controls on clastic
deposition 1 mdash Conceptual framework in Sea-level changes an integrated approach edited by
C K WILGUS B S HASTINGS C G St C KENDALL H W POSAMENTIER
38
C A ROSS and J C VAN WAGONER Society of Economic Paleontologists and
Mineralogists Special Publication no 42
STEVENS M K and ADAMIDES N G in prep GSWA Trainor 1 well completion report
Savory Sub-basin Officer Basin Western Australia with notes on petroleum and mineral
potential Western Australia Geological Survey Record 199612
STEVENS M K and GREY K 1997 Skates Hills Formation and Tarcunyah Group Officer
Basin mdash carbonate cycles stratigraphic position and hydrocarbon prospectivity Western
Australia Geological Survey Annual Review for 1996ndash97 p 55ndash60
SUMMONS RE and POWELL C McA 1991 Petroleum source rocks of the Amadeus Basin
in Geological and geophysical studies in the Amadeus Basin central Australia edited by R J
KORSCH and JM KENNARD Australia BMR Geology and Geophysics Bulletin 236
TRAVERSE A 1988 Palaeopalynology Boston Unwin Hyman 600p
VAIL P R MITCHUM R M Jr TODD R G WIDMIER J M THOMPSON S III
SANGREE J B BUBB J N and HATLELID W G 1977 Seismic stratigraphy and
global changes of sea level in Seismic stratigraphy mdash applications to hydrocarbon
exploration edited by C E PAYTON American Association of Petroleum Geologists
Memoir 26 516p
WALTER M R and GORTER J 1994 The Neoproterozoic Centralian Superbasin in Western
Australia the Savory and Officer Basins in The sedimentary basins of Western Australia
edited by P G PURCELL and R R PURCELL Petroleum Exploration Society of Australia
Symposium Perth WA 1994 Proceedings p851ndash864
WALTER M R GREY K WILLIAMS I R and CALVER C R 1994 Stratigraphy of the
Neoproterozoic to early Palaeozoic Savory Basin and correlation with the Amadeus and
Officer Basins Australian Journal of Earth Sciences v 41 p 533ndash546
WALTER M R VEEVERS J J CALVER C R and GREY K 1995 Neoproterozoic
stratigraphy of the Centralian Superbasin Australia Precambrian Research v 73 p 173ndash195
WILLIAMS I R 1992 Geology of the Savory Basin Western Australia Western Australia
Geological Survey Bulletin 141 115p
39
WILLIAMS I R 1995a Bullen WA (2nd Edition) Western Australia Geological Survey
1250 000 Geological Series Explanatory Notes 23p
WILLIAMS I R 1995b Trainor WA (2nd Edition) Western Australia Geological Survey
1250 000 Geological Series Explanatory Notes 31p
WILLIAMS I R and TYLER I M 1991 Robertson WA (2nd edition) Western Australia
Geological Survey 1250 000 Geological Series Explanatory Notes 36p
40
41
Appendix 1
Bibliography
Reports which are relevant to this investigation but which are not specifically cited are listed
below
BAILLIE P W POWELL C McA LI Z X and RYALL A M 1994 The tectonic
framework of Western Australiarsquos Neoproterozoic to recent sedimentary basins in The
sedimentary basins of Western Australia edited by P G PURCELL and R R PURCELL
Petroleum Exploration Society of Australia Symposium Perth WA 1994 Proceedings p
45ndash62
BRADSHAW M T BRADSHAW J MURRAY A P NEEDHAM D J SPENCER L
SUMMONS R E WILMOT J and WINN S 1994 Petroleum systems in West Australian
basins in The sedimentary basins of Western Australia edited by P G PURCELL and R R
PURCELL Petroleum Exploration Society of Australia Symposium Perth WA 1994
Proceedings p 93ndash118
CLARKE G L 1991 Proterozoic tectonic reworking in the Rudall Complex Western Australia
Australian Journal of Earth Science v38 p 31ndash44
COCKBAIN A E and HOCKING R M 1990 Phanerozoic in Geology and mineral resources
of Western Australia Western Australia Geological Survey Memoir 3 p 750ndash755
ETHERIDGE M and WALL V 1994 Tectonic and structural evolution of the Australian
Proterozoic 12th Australian Geological Convention Geological Society of Australia
Abstracts no 37 p 102ndash103
GOODE A D T 1981 Proterozoic geology of Western Australia in Precambrian of the
Southern Hemisphere Developments in Precambrian geology 2 edited by I R HUNTER
Amsterdam Elsevier p 105ndash203
GREY K and JACKSON M J 1983 A re-assessment of stromatolite evidence for the
correlation of the Late Proterozoic Neale and Ilma Beds Officer Basin Western Australia
Australia BMR Journal of Australian Geology and Geophysics v 8 p 359
42
HICKMAN A H WILLIAMS I R and BAGAS L 1994 Proterozoic geology and
mineralization of the TelferndashRudall region Paterson Orogen Geological Society of Australia
(WA Division) Excursion Guidebook no 5 56p
HOCKING R M MORY A J and WILLIAMS I R 1994 An atlas of Neoproterozoic and
Phanerozoic basins of Western Australia in The sedimentary basins of Western Australia
edited by P G PURCELL and R R PURCELL Petroleum Exploration Society of Australia
Symposium Perth WA 1994 Proceedings p 21ndash 44
JACKSON P R 1966 Geology and review of exploration Officer Basin Western Australia
Hunt Oil Company Western Australia Geological Survey S-series S26 (unpublished)
JACKSON M J 1971 Notes on a geological reconnaissance of the Officer Basin Western
Australia Australia BMR Geology and Geophysics Record 19715 30p
JACKSON M J and van de GRAAFF W J E 1981 Geology of the Officer Basin Western
Australia Australia BMR Geology and Geophysics Bulletin 206 102 p
LOWRY D C JACKSON M J van de GRAAFF W J E and KENNEWELL P J 1971
Preliminary result of geological mapping in the Officer Basin Western Australia Western
Australia Geological Survey Annual Report for 1971 p 50ndash56
MYERS J S 1990 Precambrian in Geology and mineral resources of Western Australia
Western Australia Geological Survey Memoir 3 p 737ndash750
MYERS J S SHAW R D and TYLER I M 1994 Proterozoic tectonic evolution of
Australia 12th Australian Geological Convention Geological Society of Australia Abstracts
no 37 p 312
NEDIN C and JENKINS R J F 1991 Re-evaluation of unconformities separating the
lsquoEdiacaranrsquo and Cambrian systems South Australia Palaios v 6 p 102ndash108
PHILLIPS B J JAMES A W and PHILIP G M 1985 The geology and hydrocarbon
potential of the north-western Officer Basin APEA Journal 25 (1) p 52ndash61
POWELL C McA LI Z X McELHINNY M W MEERT J G and PARK J K 1993
Paleomagnetic constraints on timing of the Neoproterozoic breakup of Rodinia and Cambrian
formation of Gondwana Geology v 21 p 889ndash892
43
POWELL C McA PREISS W V GATEHOUSE C G KRAPEZ B and LI Z X 1994
South Australian record of a Rodinian epicontinental basin and its mid-Neoproterozoic
breakup to form the Palaeo-Pacific Ocean Tectonophysics v 237 no 3ndash4 p 113ndash140
PREISS W V 1976 Proterozoic stromatolites from the Nabberu and Officer Basins Western
Australia and their biostratigraphic significance South Australia Geological Survey Report
of Investigations no 47 p 1ndash51
TOWNSON W G 1985 The subsurface geology of the western Officer Basin mdash results of
Shellrsquos 1980ndash1984 petroleum exploration campaign APEA Journal v 25 (1) p 34ndash51
WATTS K J 1982 The geology of the Townsend Quartzite Upper Proterozoic shallow water
deposit of the Northern Officer Basin Western Australia Perth University of Western
Australia BSc honours thesis (unpublished)
WELLS A T and KENNEWELL P J 1974 Evaporite exploration in the Officer Basin
Western Australia at the Madley Diapirs Australia BMR Record 1974194 (unpublished)
WILLIAMS I R and MYERS J S 1990 Paterson Orogen in Geology and mineral resources
of Western Australia Western Australia Geological Survey Memoir 3 p 274ndash286
WILLIAMS I R 1990 Savory Basin in Geology and mineral resources of Western Australia
Western Australia Geological Survey Memoir 3 p 329ndash334
WILLIAMS I R 1994 The Neoproterozoic Savory Basin Western Australia in The
sedimentary basins of Western Australia edited by P G PURCELL and R R PURCELL
Petroleum Exploration Society of Australia Symposium Perth WA 1994 Proceedings p
841ndash850
WILSON R B 1967 Woolnough Hills and Madley diapiric structures Gibson Desert WA
APEA Journal v 7 p 94ndash102
44
Appendix 2
Meteorological data (from Bureau of Meteorology Perth 1994)
Table 21 Wiluna rainfall (mm)
Year Jan Feb Mar Apr May Jun Jul Aug Sept Oct Nov Dec
1975 0 45 446 309 306 59 276 4 34 886 638 164 1976 16 154 12 138 53 16 34 62 12 238 0 2 1977 44 0 66 74 68 95 24 363 1 58 12 727 1978 234 522 94 16 0 96 367 24 16 353 185 45 1979 19 173 122 88 91 4 0 246 58 0 169 114 1980 148 764 68 1081 259 626 629 06 56 02 174 0 1981 123 476 192 32 196 118 44 74 14 0 28 312 1982 374 705 206 244 1079 92 02 143 368 526 368 118 1983 1 112 928 248 0 212 56 32 5 1 42 496 1984 149 7 342 84 836 0 348 132 224 04 16 172 1985 596 483 0 166 556 0 514 56 0 0 4 0 1986 0 154 35 0 0 1085 23 01 239 137 0 04 1987 1204 119 19 89 17 575 154 126 07 1 0 398 1988 46 202 164 13 388 0 202 104 0 0 224 1309 1989 207 234 26 703 278 536 57 0 01 0 144 02 1990 1035 23 281 46 126 53 94 218 44 9 42 0 1991 48 0 41 45 0 472 297 12 0 1 0 7 1992 112 96 1025 1227 323 65 04 174 0 132 48 4 1993 0 697 0 202 445 0 12 306 18 05 14 33 Mean 25 35 22 27 27 25 18 12 6 13 13 21
JAN FEB MAR APR MAY JUN JUL AUG SEP OCT NOV DEC0
10
20
30
40
Mea
n R
ain
fall
(mm
)
Month
Mean monthly rainfall in Wiluna
MKS41 140498
45
Table 22 Wiluna minimum temperature (degC)
Year Jan Feb Mar Apr May Jun Jul Aug Sept Oct Nov Dec
1975 ndash 23 203 15 94 63 71 62 103 124 169 205 1976 242 229 194 15 10 63 59 73 95 143 16 228 1977 243 25 197 148 96 95 56 86 102 ndash 188 23 1978 241 232 203 18 102 64 76 8 9 152 19 205 1979 255 226 216 167 83 6 59 79 97 145 198 223 1980 255 226 231 155 134 83 68 75 121 108 193 223 1981 245 216 19 182 119 6 54 78 138 159 163 218 1982 232 224 177 16 ndash ndash 37 111 112 164 209 225 1983 235 24 197 147 112 88 39 88 121 162 189 219 1984 241 243 191 156 ndash 72 66 7 95 161 182 211 1985 244 231 ndash 159 98 65 71 73 117 147 205 ndash 1986 ndash 229 226 155 93 96 43 49 10 122 ndash 219 1987 ndash 217 183 175 85 77 68 68 112 ndash ndash 221 1988 238 214 209 178 111 ndash ndash 86 104 157 171 195 1989 ndash 237 199 165 107 67 44 61 107 131 187 ndash 1990 232 ndash 211 155 118 62 57 87 102 149 195 22 1991 26 256 217 168 122 101 78 ndash 113 18 168 219 1992 227 227 214 169 102 98 59 69 ndash 125 159 196 1993 241 218 196 171 103 ndash 49 68 88 128 192 211 Mean 24 23 20 16 10 8 6 8 11 14 18 21
NOTE Dashes indicate data unavailable
JAN FEB MAR APR MAY JUN JUL AUG SEP OCT NOV DEC0
10
20
30
40
Month
MKS43 140498
50
Mean monthly minimum temperatures at Wiluna
Mea
n T
emp
erat
ure
(degC
)
46
Table 23 Wiluna maximum temperature (degC)
Year Jan Feb Mar Apr May Jun Jul Aug Sept Oct Nov Dec
1975 ndash 349 326 281 247 201 197 212 256 248 31 344 1976 374 369 346 297 248 206 208 225 265 287 313 388 1977 397 392 352 296 234 212 222 244 ndash 308 337 383 1978 378 345 346 316 242 195 176 205 231 295 334 356 1979 403 36 364 295 ndash ndash ndash 193 242 318 359 373 1980 392 342 377 275 24 176 179 233 292 288 349 391 1981 385 346 337 342 242 178 201 224 30 326 326 369 1982 372 359 315 307 ndash ndash 196 253 252 305 353 379 1983 381 389 327 272 263 222 187 248 287 321 336 366 1984 378 393 322 299 226 215 178 214 234 ndash 336 364 1985 40 366 ndash 294 224 216 205 212 284 307 355 ndash 1986 ndash 383 372 307 ndash 193 166 196 261 277 ndash 382 1987 ndash 339 328 305 21 202 214 218 275 ndash ndash 374 1988 388 365 353 301 23 ndash ndash 228 283 334 31 33 1989 ndash 375 339 285 238 179 181 219 275 298 336 ndash 1990 368 ndash 36 309 268 19 188 205 274 309 373 393 1991 414 416 363 315 268 206 21 ndash 279 338 332 368 1992 363 383 336 263 213 178 213 197 ndash 285 313 359 1993 396 357 344 301 221 ndash 197 215 253 294 347 362 Mean 39 37 34 30 24 20 20 22 27 30 34 37 NOTE Dashes indicate data unavailable
JAN FEB MAR APR MAY JUN JUL AUG SEP OCT NOV DEC0
10
20
30
40
Month
MKS42 140498
50
Mean monthly maximum temperatures at Wiluna
Mea
n T
emp
erat
ure
(degC
)
47
Appendix 3
Table 31 Summary of palynological results
Drillhole Depth (m) F no(a) GSWA no Lithology Formation Assemblage TAI(b)
BWB 1 74ndash75 F49668 135741 dark-grey siltstone basalt Jilyilli gt5 BWB 1 98ndash100 F49669 135742 dark-grey siltstone basalt Jilyilli gt5 BWB 1 121ndash122 F49670 135743 dark-grey siltstone basalt Jilyilli gt5 TWB 1 86ndash87 F49671 135631 dark-grey siltstone McFadden 3+ TWB 1 104ndash105 F49672 135632 dark-grey siltstone Cornelia 3+ TWB 1 121ndash122 F49673 135633 dark-grey siltstone Cornelia 4 TWB 2 14ndash15 F49674 135634 dark-grey siltstone Skates Hills 3+ TWB 6 49ndash50 F49675 135675 dark-grey siltstone Cornelia 1 3+ TWB 9 49ndash51 F49676 135704 dark-grey siltstone Brassey Range 1 3+ Trainor 1 37497- F49733 138939 black mudstone with Cornelia 5 37509 light-grey siltstone Trainor 1 3809 F49734 138940 dark-grey and black Cornelia 4- laminated mudstone Trainor 1 4170 F49735 138941 black unlaminated mudstone Cornelia 4- Trainor 1 4950 F49851 139501 dark-grey indurated siltstone Cornelia 5 Trainor 1 6032 F49852 139502 dark- and light-grey Cornelia 5 indurated siltstone Trainor 1 6434 F49853 139503 greenish indurated finely Cornelia 5 laminated siltstone LDDH 1 270 F49678 138934 dark-grey siltstone interbeds Waters 1 3+ in enterolithic evaporite Tarcunyah Gp LDDH 1 277 F49679 138935 dark-grey siltstone in cavity Waters 1 3+ in enterolithic evaporite Tarcunyah Gp
NOTES (a) GSWA Fossil Catalogue number (b) TAI = Thermal Alteration Index of Traverse (1988 plate 1)
48
Appendix 4
Savory Sub-basin quantitative magnetic and gravity interpretation (extracted from Cowan 1995)
Summary
A program of quantitative aeromagnetic interpretation has been completed on BMRAGSO data from the Savory Sub-
basin Western Australia Quantitative aeromagnetic interpretation utilized the 3D Euler deconvolution method
supported by wavenumber filtering and image processing The results have provided useful information on structural
trends and depth to magnetic sources in a structurally complex area Depth to magnetic source analysis has provided
information on intra-sedimentary magnetic sources as well as basement rocks
The results of the interpretation support previously identified depocentres However the presence of magnetic
sources at several levels makes it very difficult to produce a reliable magnetic basement depth contour map It is
considered more productive to work with the 3D Euler colour circle plots and images rather than trying to contour the
results It would be necessary to carry out a full-scale interpretation of the BMRAGSO profile data to improve on the
3D Euler results The regional gravity was found to be useful in interpreting the regional setting of the area although
the very wide data spacing limits quantitative use of the data The gravity data show quite a complex picture with
limited consistent correlation between gravity features and basin structures This suggests that gravity anomalies
reflect changes in density of the basement rocks rather than basement topography especially in the northern part of the
basin
It is recommended that the GSWA investigate access to company confidential high-resolution aeromagnetic data
prior to planning further aeromagnetic surveys Private companies have flown large parts of the northern half of the
area as part of their diamond exploration program Additional gravity coverage of the area may be more cost effective
than magnetic surveys as the gravity data provides more information on changes within the sedimentary section
Introduction
The main use of aeromagnetic data in petroleum exploration has been the determination of magnetic basement
topography although there has been increasing interest in analysis of intra-sedimentary magnetic anomalies
intrabasement and suprabasement magnetic anomalies These anomalies are used to determine depth to magnetic
basement rocks and hence determine the thickness of the sedimentary sequence Unfortunately interpretation of the
intrabasement and suprabasement magnetic anomalies is non-unique in terms of position and size of causative sources
because of the inherent ambiguity of potential-field methods However this ambiguity can be reduced by placing
49
constraints on source geometry and magnetization and by using geological and other geophysical data to constrain
the solution
Before 1970 most depth-determination techniques involved graphical determination of slopes of selected
magnetic anomalies and application of various empirical factors to convert the slopes into depth estimates Geological
Society of America Memoir 47 Interpretation of Aeromagnetic Maps by Vacquier et al (1951) was a landmark for
this type of interpretation
Automated interpretation procedures have played an increasingly important role in depth interpretation and a
wide range of techniques have been developed Many of these techniques are designed for application to located data
profiles and assume a two-dimensional geometry However there has been renewed interest in techniques applicable
to gridded data
Two distinct types of method can be recognized In the first case often described as discrete methods individual
isolated magnetic anomalies are interpreted and the results used to produce a map of basement relief In the second
case often described as continuous methods areas of data containing a number of anomalies are interpreted
statistically to produce direct output of basement depths
The discrete methods usually involve a semiautomatic initial phase which generates a large number of possible
depth solutions and an interactive second phase to screen and select acceptable solutions The advantage of this
approach is that the interpreter can select features that are relatively free from interference from adjacent anomalies
and consider all aspects of a particular magnetic anomaly The disadvantage is that interpretation can be very time
consuming as a wide range of depths are usually possible depending on the initial model chosen and a significant
amount of effort is needed to select the correct model In the case of the Savory Sub-basin dataset we encountered
problems in separating basement related effects from the effects of shallower intrasedimentary magnetic sources
Because of these problems we have concentrated on displaying the Euler results accompanied by separation filter
images of the data to show the shallower effects and deeper effects rather than trying to refine a 3D Euler
deconvolution depth-to-crystalline-basement contour
The continuous methods are very direct provided that the rather restrictive assumption can be made that all
anomalies are due to lateral magnetization changes due to basement topography This means that shallow effects and
large intrabasement anomalies must be removed from the data This involves judgement and skill as it is necessary to
distinguish between the lower amplitude suprabasement anomalies due to basement topography and the larger
intrabasement anomalies reflecting magnetization changes within the basement These methods were not considered
suitable for the Savory Sub-basin magnetic dataset but were used to invert the gravity data
50
Limitations of magnetic and gravity interpretation
Interpretation of the area is limited by a shortage of information on the nature and physical properties of the deeper
sedimentary sequence and the underlying basement rocks However using techniques such as cross-correlation of
gravity and pseudo-gravity data it is possible to try to differentiate between anomalies relating to basement and those
related to the sedimentary sequence
Gravity anomalies reflect changes within the sedimentary sequence as well as basement condition These
changes in density of sedimentary rocks produce gravity anomalies without a corresponding magnetic anomaly hence
the complementary nature of gravity and magnetic surveys The main use of magnetics is to determine depth to
magnetic basement and any intra-sedimentary volcanic rocks or intrusives whereas gravity provides much more
general information on the sedimentary sequence
Unfortunately interpretation of gravity anomalies is complicated since they can be due to a number of geological
features including
bull major basement faults
bull basement highs
bull igneous intrusions within the basement
bull sedimentary basins which may or may not be isostatically compensated
bull intra-sedimentary volcanics and associated plutonic centres
Two major problems affect the interpretation of both magnetic and gravity data
1 The inherent ambiguity of potential-field data There is no unique solution to any measured gravity or magnetic
anomaly and theoretically there will be an infinite number of source geometry and magnetizationdensity
combinations which will fit the observed data This means that any a priori information which helps to select a
suitable model is very useful
2 Measured anomalies are the summation of effects from different depths For example an observed gravity profile
may contain contributions from shallow sources (density variations within the sedimentary basin) intermediate
depth sources (density variations due to large igneous intrusions within the basement) and deep sources (crustal
thinning producing a mantle anomaly) Separation of these component responses is the regionalresidual problem
which we solve using spectral analysis and differential upward continuation-based separation filtering
Regional setting and interpretation overview
The area studied includes parts of BALFOUR DOWNS (SF51-9) RUDALL (SF51-10) ROBERTSON (SF51-13) GUNANYA
(SF51-14) COLLIER (SG50-4) BULLEN (SG51-1) TRAINOR (SG51-2) MADLEY (SG51-3) NABBERU (SG50-5)
STANLEY (SG51-6) and HERBERT (SG51-7) 1250 000 sheets Broadly the area lies between latitudes 22deg00rsquondash25deg30rsquoS
and longitudes 119deg30rsquondash123deg30rsquoE
51
Regional gravity
The AGSO regional gravity data (at nominal 11 km spacing) was gridded at a 4 km mesh spacing using a minimum-
curvature algorithm Bouguer gravity values in the area are negative reflecting mass deficiency at depth and range
from -84 mgals to -25 mgals
A Bouguer gravity colour image is shown as Figure 41 A residual grid was produced by removing a fifth-order
orthogonal polynomial from the Bouguer data but did not add to the interpretation
120deg 121deg 122deg 123deg
23deg
24deg
25deg
-25
-84
50 km
MKS46 180598
mgal
Figure 41 Regional Bouguer gravity (BMRAGSO data) gridded at 4 km
52
The data show a complex pattern of positive and negative anomalies with no clearly defined trends Correlations
with aeromagnetic data and known basin structures are poor A vague north-northwest linear trend appears to coincide
with the Marloo Fault (Figure 42) A prominent negative anomaly appears to coincide with the Blake Fold and Fault
Belt depocentre and continues as a narrower negative anomaly to the east until it widens out again near the edge of the
basin Elsewhere the gravity data show little correlation with known basin structures and it is likely that especially in
the north of the area gravity anomalies are due to density changes in the basement rather than changes in basement
topography
Production of wavelength-filtered residual gravity plots and vertical gradient plots showed very patchy aliased
data reflecting poor sampling in much of the area
Regional magnetics
The AGSO regional aeromagnetic data were gridded at a 400 m mesh spacing using a minimum-curvature algorithm
(Figure 43) Most of the data has a line spacing of 1600 m with small areas of 1 km spacing The quality of the data is
acceptable for regional interpretation but is not adequate for detailed analysis The accuracy of the flight path is rather
variable reflecting the vintage of the data and the noise envelope of the data is poor by modern standards Problems
were also encountered in joining different map sheets
The magnetic anomaly pattern over the south and west part of the area shows a strong high frequency signature
reflecting the presence of widespread basic sills and dykes Some of the major north-northeasterly trending dykes can
be traced over considerable distances
Discontinuous high-frequency anomalies extend as a northwest-trending zone through the centre of the area and
this zone includes a conspicuous circular magnetic anomaly which is probably a ring complex
The northern and eastern parts of the area are characterized by long-wavelength deep-seated basement magnetic
anomalies with 120deg and 150deg trends dominant The Marloo and Perentie Faults (Figure 42) appear as distinct linear
zones and offsets A prominent easterly trending negative anomaly in the northwest of the area appears to swing round
to the southeast and may separate different basement blocks One possible interpretation is that this very deep seated
anomaly separates areas of Archaean and Proterozoic basement
Regional geology
The regional geology is described in Williams (1992) The GSWA provided a digitized version of Plate 2 from this
Bulletin the structural interpretation map to use as an overlay (Figure 42)
53
Pp
Pp
PSd
PSd
PSd
PSd
PSd
PSo
PSt
PSt
PSf
PSf
PSf
PSb
PSb
PSb
PSsPSs
PSs
PSb
PSm
PSp
PSc
PSc
PSw
PSw
PSw
PSg
PSr
PSj
PSg
PM
Pk
PY
PY
PSd
L
L
L
L
L
L
L
LL
L
L
L
LL
L
LL
L L
LL
L L
L
L
L
L
L
L
L
LL
L
L
BLAKEDEPOCENTRE
MA
RLO
O
FAU
LT
PERENTIEFAULT
50 km
MKS39120598
120deg 121deg 122deg 123deg
25deg
24deg
23deg
Approximate boundaryof aeromagnetic interpretation
PML
PSgL
PSjL
PML
PSpL
PML
PML
PSfL
PSfL
PSpL
LPc
LPcLPcPSrL
LPA
Durba Sandstone
Woora Woora Formation
McFadden Formation
Tchukardine Formation
Boondawari Formation
Skates Hills Formation
Mundadjini Formation
Coondra Formation
Spearhole Formation
Watch Point Formation
Jilyili Formation
Brassey Range Formation
Glass Spring Formation
Paterson Formation
Yeneena Group
Karara Formation
Cornelia Formation
Kahrban Subgroup
Bangemall Group
Fault
Formation boundary
PSdL
PSoL
PSfL
PStL
PSbL
PSsL
PSmL
PScL
PSpL
PSwL
PSjL
PSrL
PSgL
Pp
PYL
PkL
LPc
LPA
PML
Savory Group Other Units
PYL
Figure 42 Regional geology and structure map (after Williams 1992)
54
120deg 121deg 122deg 123deg
23deg
24deg
25deg
5820
3750
MKS47 180598
nT
50 km
Figure 43 Regional aeromagnetic data total magnetic intensity (BMRAGSO data) gridded at 400 m
Analysis
3D analysis
3D Euler deconvolution was used as the primary depth-determination method The advantage of this approach is that
consistent solutions can be obtained over the entire area with minimal assumptions about source geometries Euler
deconvolution of gridded data is used for positional information and estimation of depth to top of source Euler
55
deconvolution yields a large number of depth solutions which have to be screened to reject spurious solutions Results
are plotted as circles in eight depth ranges with radius proportional to depth and colour coded
The 400 m total magnetic intensity grid was used for the analysis Horizontal gradients in x and y and the vertical
gradient were calculated 3D Euler deconvolution was tested on the 400 m gridded data using windows of 9 times 9 and
11 times 11 and 16 times 16 data points and structural indices 05 (fault) and 10 (sill or dyke) It was concluded that the
16 times 16 window produced the best results overall and final plots were produced for the 16 times 16 window and structural
index 05 (Fig 44) Results were very good over the northern and central parts of the area showing magnetic sources
Figure 44 Depth to magnetic source 3D Euler deconvolution 16 times 16 window of 400 m gridded data structural index 05
56
at several different levels Unfortunately in the extreme south of the area shallow intrasedimentary magnetic sources
(sills and dykes) dominated the inversion and the results contained few basement solutions
In order to reduce these problems the 400 m gridded data were filtered using a separation filter based on
interpretation of the log-energy spectrum The 3D Euler method was run on the filtered data in order to generate more
basement-depth solutions Results for the deep-separation filter data were gridded and presented as a colour image in
Cowan (1995) Attempts to grid the Euler output were unsatisfactory and it is considered safer to interpret the 3D
Euler depth plots The 3D Euler depth results from the separation-filter run should be analysed with care as perfect
separation of the basement can never be achieved and there will always be some contamination from sources at
different levels
The results of original total magnetic intensity 3D Euler depth estimation for structural index 05 using a 16 point
window have been plotted at 1500 000 scale (not included in this publication but available in Cowan (1995) from the
GSWA Library as S10331) and as reduced A4 colour circle plots (Figure 44)
The results of deep-basement 3D Euler depth estimation for structural index 05 using a 16 point window have
been plotted as a colour image at 1500 000 scale and as an A4 image (not included in this publication)
2D analysis
Two equispaced profiles were interpolated with a 50 m station interval from the AGSO-located data profiles for the
BULLEN 1250 000 sheet The interpolated profiles were analysed using 2D Euler deconvolution and Werner
deconvolution Results are included in Cowan (1995) and show the use of these methods for more detailed analysis
Filtered data
In order to reconcile 3D Euler results from shallow basement and intrasedimentary magnetic sources we produced
several separation-filtered maps and images We found the shallow-layer double-separation filter (Figure 45) to be
very effective for shallow sources and the deep-layer standard-separation filter (Figure 46) for the basement layer
Gravity and magnetic data correlation
Both lsquoreduced to the polersquo (RTP) magnetics (Figure 47) and pseudo-gravity data (Figure 48) were produced as part of
the reconciliation of gravity and magnetic signatures In both cases the filtering operations assumed magnetization by
induction in the present Earths field The RTP data are fairly similar to the total magnetic intensity The pseudo-
57
gravity data are dominated by a northwest-trending strong positive anomaly and there is little correlation with the
Bouguer gravity data
The poor magneticgravity correlation is confirmed by cross-correlation of the RTP magnetics and the gravity
gradient The correlation plot in Figure 49 shows little coherent response with numerous zones of positive and
negative correlation
Figure 45 Regional aeromagnetic data shallow layer separation filter (BMRAGSO data) gridded at 400 m
Results
In the north and east of the area on the Wells Foreland Sub-basin trend (refer to Figure 1 main text) we see a range
of quite deep 3D Euler depths and several trend directions with north-northwesterly dominant There are relatively few
shallow intrasedimentary solutions in this zone
The second area of deep 3D Euler solutions lies over the Blake depocentre (Figure 43) with several trend
directions
Elsewhere the 3D Euler results are dominated by shallow intrasedimentary depth solutions reflecting mainly the
dolerite sills dykes and the ring complex However where we do see basement-related solutions in the south and
west of the area they appear to be shallower than those noted for the Wells Foreland Sub-basin and the Blake
depocentre
58
Figure 46 Regional aeromagnetic data deep-layer separation filter (BMRAGSO data) gridded at 400 m
Figure 48 Regional aeromagnetic data pseudo-gravity transform (BMRAGSO data) gridded at 400 m
Figure 47 Regional aeromagnetic data reduced-to-pole (BMRAGSO data) gridded at 400 m
Figure 49 Regional aeromagnetic and gravity data gravitymagnetic correlation using RTP magnetics and gravity gradient (BMRAGSO data) gridded at 4 km
59
This subdivision of the area into two zones of deep solutions is consistent with interpreted depocentres
However the interference between sources at different levels and the complexity of the magnetic response of the
basement rocks precludes more refined interpretation at this stage
The area of deep 3D Euler solutions over the Blake depocentre correlates with the pronounced negative gravity
anomaly discussed in the gravity interpretation section Using a density contrast of -015 gcc the negative gravity
anomaly could indicate up to 6ndash8 km of low-density sedimentary rocks depending on assumptions about the regional
field
The area of deep 3D Euler solutions over the Wells Foreland Sub-basin has a complex gravity expression and no
clear basin structure emerges from inversion of these data As noted previously it is likely that observed gravity
anomalies reflect contrasts in basement density rather than basement topography
Separation filtering applied to the magnetic data helps to enhance the intrasedimentary magnetic signature and to
give a better impression of the basement magnetic signature even though separation of the basement response is not
perfect
Conclusions
Quantitative aeromagnetic interpretation using 3D Euler deconvolution supported by wavenumber filtering and image
processing has been successful in providing structural trend and depth information for the Savory Sub-basin
Quantitative magnetic interpretation has revealed two zones of relatively deep magnetic basement beneath the
Wells Foreland Sub-basin and the Blake depocentre
This analysis of the magnetic data supports interpreted depocentres but the complexity of the basement magnetic
signature and interference from sources at different depths precludes further refinement to a map of basement
topography
Regional gravity proved to be very useful in understanding the regional setting of the area and in providing
support for aspects of the interpretation The gravity data support the interpretation of the Blake depocentre
suggesting up to 6ndash8 km of low-density sedimentary rocks
The deep structure of the Savory Sub-basin area is obviously complex with different areas underlain by
Archaean and Proterozoic basement and with the Capricorn suture occurring in the centre of the area
60
Recommendations
The quantitative magnetic interpretation needs to be reconciled with geological models available for the area
In particular the zones tentatively identified as areas with thick sedimentary rocks the Wells Foreland Sub-
basin and the Blake depocentre need to be investigated
Cross sections should be prepared across the basin for joint magneticgravity modelling especially for the Blake
depocentre It is important to be able to explain the strong negative gravity anomaly in this area
In view of the effects of basement density contrasts on the gravity field for the northern part of the area we think
that additional gravity interpretation and acquisition of new gravity data may not be justified as they will not
contribute significantly to understanding basin evolution and structure
It is recommended that GSWA try to get access to company confidential high-resolution aeromagnetic data
rather than flying new surveys The GSWA might offer to fund flying of new infill areas as a bargaining point
References
The original text of this report by Cowan (1995) and 1500 000 scale maps are filed in the GSWA Library under
S10331
COWAN D 1995 Savory Basin quantitative magnetic interpretation Western Australia Geological Survey S-series
S10331 (unpublished)
VACQUIER V STEENLAND N C HENDERSON R G and ZIETZ I 1951 Interpretation of aeromagnetic
maps The Geological Society of America Memoir 47 151p
WILLIAMS I R 1992 Geology of the Savory Basin Western Australia Western Australia Geological Survey
Bulletin 141 115p
61
Appendix 5
Geochemistry
MKS38 250398
Saturate FractionC12+ GLC
1217
Pr18
Ph
22
31CSR WELL-13 315m Cuttings
Figure 51 Canning Stock Route Well 13 gas chromatograph of extract of auger drill sample
12
17
18
22
31
Pr Ph
LDDH 1 6623m CoreSaturate FractionC12+ GLC
MKS35 240398
Figure 52 Gas chromatograph of extract from core sample at 6623 m LDDH1
62
Table 51 Canning Stock Route Well 13 auger drill samples
GSWA sample Drill depth (m)(a) Comments
135601 150 At watertable 135602 203 (all samples consist 135603 310 of sand mud and water) 135604 315 At total depth
NOTE (a) Datum for drill depth is the top of sediment fill in the well which is 155 m below ground level (ie the total depth of 315 m is 47 m below ground level)
Table 52 Canning Stock Route Well 13 gas chromatography data for 315 m depth sediment sample
Parameter Value
Weight of rock extracted (grams) 945 Total extract (ppm) 519 n-Alkane distribution n-C12 07 n-C13 23 n-C14 26 n-C15 22 n-C16 19 n-C17 14 i-C19 23 n-C18 14 i-C20 08 n-C19 11 n-C20 16 n-C21 25 n-C22 29 n-C23 70 n-C24 42 n-C25 95 n-C26 43 n-C27 83 n-C28 38 n-C29 87 n-C30 31 n-C31 273 Alkane compositional data Pristane phytane ratio 279 Pristane n-C17 ratio 161 Phytane n-C18 ratio 059 CPI (1)(a) 284 CPI (2) 209 (C21 + C22) (C28 + C29) 043
NOTE (a) CPI= Carbon preference index
63
Table 53 LDDH1 extract liquid chromatography data for 6623 m concentration
Rock extracted Total extract (grams) (ppm)
702 313
NOTE ppm= parts per million
Table 54 LDDH1 saturate gas chromatography data of core for 6623 m alkane composition
Pristane Pristane Phytane (a) CPI (1) CPI (2) (C21+C22) Phytane n-C17 n-C18 (C28+C29)
103 026 024 103 102 325
NOTE (a)CPI = carbon preference index
Table 55 LDDH1 saturate gas chromatography data of core for 6623 m n-alkane distributions
Parameter Value
n-C12 17 n-C13 38 n-C14 55 n-C15 60 n-C16 65 n-C17 74 i-C19 19 n-C18 78 i-C20 19 n-C19 80 n-C20 79 n-C21 71 n-C22 64 n-C23 57 n-C25 43 n-C24 38 n-C27 31 n-C28 23 n-C29 19 n-C30 12 n-C31 10
64
Appendix 6
Table 61 Summary of data from Trainor waterbores (TWB) and Bullen waterbores (BWB)
Well AMG Elevation TD Status(b) Completion details Water Salinity Water level Flow rate Depth to consolidated AGD84 GL (m) (m) struck mgl(c) (m) (LHr) lithology aquifer(e) Z51(a) Interval (m) (100 mm PVC) (m) (mgl)(d)
TWB 1 473660E 453 122 comp 0ndash75 plain 63 7 300 24 2 880 12 m 7287404N 75ndash93 slotted (9 260) McFadden Fm 93ndash99 plain TWB 2 472 977E 475 23 abd nil 15 m 7285877N Skates Hills Fm dry TWB 3 473259E 475 50 abd nil 7 m 7285849N Skates Hills Fm dry TWB 4 463225 E 445 50 comp 0ndash22 plain 35 7 200 55 3 600 0 m 7286143N 22ndash34 slotted (8 140) Tertiary sand and gravel 23ndash60 plain TWB 5 463095E 445 31 comp 0ndash19 plain 13 26 000 655 3 600 Tertiary sand and gravel 7277721N 19ndash25 slotted (36 700) 25ndash31 plain TWB 6 457013E 455 50 comp 0ndash42 plain 38 920 119 600 0 m 7274352N 42ndash48 slotted (1 030) Cornelia Fm ss TWB 7 453739E 475 26 susp 0ndash2 plain 11 9 300 48 4 500 0 m 7263891N (10 500) Tertiary sand TWB 8 433893E 535 60 susp 0ndash2 plain 47 8 500 gt46 1 200 0 m 7245991N (10 900) Tertiary sand and Brassey Range Fm ss TWB 9 437219E 505 51 comp 0ndash47 plain 45 1 000 58 600 1 m 7235905N 47ndash51 slotted (990) Brassey Range Fm ss TWB 10 434927E 495 32 susp 0ndash2 plain 235 450 120 0 m 7225875N (500) Dolerite
65
BWB 1 287337E 580 122 abd Nil 1 m 7245861N Jilyili Fm dry BWB 2 288346E 545 50 comp 0ndash26 plain 15 630 3 29 000 0 m 7240423N 26ndash38 slotted (730) Tertiary sand and gravel 38ndash50 plain BWB 3 305637E 545 50 abd 19 8 800 43 7 200 0 m 7240423N (10 550) Tertiary ss BWB 4 320167E 515 445 comp 0ndash20 plain 9 980 445 24 000 0 m 7248097N 20ndash32 slotted (1 190) Tertiary ss 32ndash44 plain BWB 5 353393E 545 20 susp 0ndash2 plain 45 (970) 1 m 7238934N Basalt
NOTES (a) GPS accuracy ~ 150 m (b) Comp = completed abd = abandoned susp = suspended (c) Salinity from conductivity (d) Analysis total dissolved solids (e) Fm = Formation ss = sandstone
24
100
200
300
400
500
600
700
Oil
gene
ratin
g
Gas
gene
ratin
g
Fai
r
Fai
r
Poo
r
Poo
r
Goo
d
Imm
atur
e
Oil
win
dow
Oil
win
dow
Imm
atur
e
01 0110 10 0 150 300 440 480 1
Neo
prot
eroz
oic
TOC S1+S2 mgg Hydrogen Index Tmax degC
Depth(m)
Organicrichness
Generatingpotential
Kerogentype Maturity Maturity
TD=701m
Sandstone
Mudstone
Dolomite
Limestone
Evaporite
Source rock
MKS40 070498
Ro equivalent
Figure 9 Petroleum source potential of rocks in Normandy LDDH1
Small amounts of organic matter associated with basalt and dolerite in cuttings from
waterbore BWB 1 on BULLEN showed high levels of thermal maturity (Grey 1995a Libby 1995)
It is unclear whether all sedimentary rocks on BULLEN are overmature for hydrocarbon generation
or the results from BWB 1 are related to local heating events associated with the volcanic bodies
that are common in the Jilyili Formation
25
Reservoirs
Each of the five depositional sequences of the Savory Group (Table 1) are inferred to contain
significant sandstone reservoirs with the possible exception of depositional sequence C as
discussed above in Stratigraphy The Spearhole Formation was cored in Mundadjini 1 and
Boondawari 1 and visual estimates of porosity vary from generally poor (less than 5) to fair
(approximately 5ndash15) The McFadden Formation in Trainor 1 has porosity values of up to 232
and a maximum permeability of 195 md (Stevens and Adamides in prep) Sandstones from
Neoproterozoic formations form the acquifers in the following waterbores the McFadden
Formation in TWB 1 the Cornelia Formation in TWB 6 and the Brassey Range Formation in
TWB 8 and TWB 9 (Appendix 6 Table 61)
Based on outcrop observations the Durba Sandstone is considered to be the best reservoir of
the Savory Group Similarly some sandstones from the Tarcunyah Group also have good visible
porosity in outcrop
Dolomites occur in several formations in the sub-basin Reservoir potential may exist
particularly where the dolomites are stromatolitic and oolitic However dolomites have not been
drilled in the sub-basin and porosity can only be inferred from the preferential silicification of
some stromatolite bioherms observed in outcrop (Stevens and Grey 1997) Elsewhere in the
Officer Basin porosities of up to10 have been measured in dolomites A limestone breccia
(karst) is described from 663 to 677 m in drillhole LDDH1 (Fig 6 Busbridge 1994)
Seals
Indications of evaporitic environments in the Mundadjini Skates Hills and Boondawari
Formations are described by Williams (1992) In Mundadjini 1 from 287 to 337 m anhydrite and
chert occurs as nodules beds and veins in mudstone of the Mundadjini Formation Evaporitic
minerals (predominantly gypsum) are described in the Tarcunyah Group in LDDH1 The presence
of the Woolnough and Madley salt diapirs in the Officer Basin (approximately 110 km east of the
sub-basin) and halite beds over 25 m thick in the well Hussar 1 (130 km east of the sub-basin)
provide further evidence that evaporite seals may be present in the Savory Sub-basin
Mudstones and shales form only a small proportion of the limited Neoproterozoic outcrop in
the sub-basin but significant thicknesses of mudstone were encountered in the Mundadjini
Formation in Mundadjini 1 and Boondawari 1 the Tarcunyah Group in LDDH1 and in the
26
Cornelia Formation in Trainor 1 These data suggest that mudstones form a significant proportion
of strata in the sub-basin despite their limited outcrop
Traps
Potential structural closures including folds and faults occur at various scales throughout the
Savory Sub-basin However the region has only been mapped at 1250 000 scale and
independently closed structures such as domes have yet to be confirmed The western margin of
the basin contains abundant faults (with a northeast strike) but elsewhere faults are less common
Some anticlines are recognized in outcrop including one with a strike length of up to 45 km
inferred from surface bedding dips in the Mundadjini and Spearhole Formations at approximately
24deg15rsquoS 121deg10rsquoE on BULLEN (Fig 1)
Salt diapirs and other halokinetic structures are recognized in outcrop well and seismic data
in the Officer Basin to the west of the Savory Sub-basin and it is probable that there are
significant thicknesses of evaporitic sedimentary rocks in the sub-basin The gravity field data
suggest there is good potential for salt diapirs and traps related to halokinesis
Although there is potential for stratigraphic traps to be present in the sub-basin insufficient
data are available to assess them
Preservation of hydrocarbons
The range of thermal maturities measured to date and the large periods of time envisaged for
deposition of sediments implies hydrocarbon generation may have occurred a number of times
during the evolution of the Savory Sub-basin Any hydrocarbons that were generated early may
have been trapped in palaeostructures and remigration to younger traps could have taken place
later The Petermann Ranges Orogeny which has been equated with the Paterson Orogeny (Myers
1990) is believed to have occurred in the latest Neoproterozoic to early Cambrian This is the last
major tectonic event recognized in the sub-basin suggesting that it is reasonable to expect that trap
integrity will have been preserved
If the inference of the presence of thick halite beds in the sub-basin is correct the preservation
potential of sub-salt traps should be excellent
27
Reported hydrocarbon shows and oil seep
Amadeus Petroleum recorded minor oil shows in cores from Mundadjini 1 and Boondawari 1 In
Mundadjini 1 at 36102 m (top of the Spearhole Formation) a 3 mm thick zone had 10 moderate
white fluorescence with slow solvent cut This show was in a granular sandstone with visually
estimated porosity of about 10 In Boondawari 1 at 35364 m (within the Spearhole Formation) a
broken surface of sandstone had 40 moderate yellow-white fluorescence with slow solvent cut
Visually estimated porosity is about 5 Because the fluorescing surface was broken during the
drilling process this show could have resulted from contamination A second show occurs in
Boondawari 1 at 4963 m (within the Spearhole Formation) where a 1 cm-thick zone had 5 dull
yellow fluorescence with slow solvent cut in a conglomerate with visually estimated porosity of
about 10 The company intends to further investigate the nature of these occurrences
Minor bitumen is present at 6623 m in drillhole LDDH1 on GUNANYA (Figs 5 and 6) as a
vein in mudstones of the Tarcunyah Group A sample was analysed by gas chromatography
(Ghori in prep) and confirmed that it is natural bitumen (Appendix 5)
Mineral hole OD 23 drilled by Jubilee Gold Mines NL on NABBERU in the Bangemall Basin
immediately to the south of the Savory Sub-basin (Fig 5) encountered bitumen and trace oil in
vugs in dolomite (M Stevens unpublished data) but no further data are available at present
In their popular guide to the Canning Stock Route Gard and Gard (1990 p 218) refer to an
oil seep at Well 13 on TRAINOR (Fig 5) They reported that between 1977 and 1984 lsquonatural oilrsquo
was seen in the well Although the well is now largely filled with sediment four auger drill
samples were collected by the GSWA in 1995 and all four were analysed for oil shows One
sample from 315 m total depth (GSWA sample 135604) yielded just enough extract (519 ppm)
for saturate gas chromatography analysis The gas chromatograph (Appendix 5) shows that the
extract does contain some hydrocarbons probably from recent plant material Because the depth to
the oil was not quoted in Gard and Gard (1990) the hand-augered well may not have been deep
enough to properly test this reported seep
Geological and geophysical databases
Geological and geophysical data available for the Savory Sub-basin are limited The most recently
completed geological maps for the sub-basin were published by the GSWA between 1991 and
1995 (Williams and Tyler 1991 Williams 1992 1995ab)
28
The cores from the five drillholes listed in Table 2 believed to be all of the core available
from the sub-basin are available for inspection at GSWA Mineral exploration reports submitted
to GSWA may be searched using the WAMEX database and open-file reports are available on
microfiche Geophysical data acquired by the mining industry is not required to be filed with
GSWA if acquired over Vacant Crown Land which is the case for much of the sub-basin
Geophysical survey data submitted in mining tenement reports and which extend into Vacant
Crown Land remain confidential to the companies Original regional aeromagnetic and gravity
datasets are available from the Australian Geological Survey Organisation (AGSO)
Data pertinent to oil exploration in the sub-basin such as structural style and salt diapirism
are presented in a review of the hydrocarbon prospectivity of the Officer Basin (Perincek 1998)
Drilling
Significant drillholes in the sub-basin are summarized in Table 2
Petroleum industry data
Amadeus Petroleum drilled three petroleum exploration wells in the central west of the Savory
Sub-basin in late 1997 These wells Mundadjini 1 Boondawari 1 and Akubra 1 were drilled by
continuous diamond coring (Figs 5 and 6) All targeted potential reservoirs within the Spearhole
Formation with the Mundadjini Formation as the proposed seal The wells were located on
structures interpreted from Landsat images and limited geological investigations Both Mundadjini
1 and Boondawari 1 had minor oil shows as discussed above (Reported hydrocarbon shows)
Government data
Stratigraphic drillhole Trainor 1 was drilled by GSWA in 1995 (Stevens and Adamides in prep)
and the main results are discussed above (Source rocks and Maturity)
Mineral industry data
Normandy Exploration drillhole LDDH1 was cored in the Tarcunyah Group to a total depth of
701 m and provided source-rock and maturity data as discussed above
29
Oilmin NL drilled six percussion drillholes (BD 1 3 4 5 8 and 9) through sandstones and
shales in the northern part of the Savory Sub-basin to a maximum depth of 198 m (Fig 5
WAMEX Microfiche File M 26811 I 2610) but only brief geological descriptions are available
Hydrogeological data
Hydrogeological data within the Savory Sub-basin are limited although a long history of water
exploration extends back to the construction of the Canning Stock Route early this century No
detailed geological or wireline logs are available for the older wells along this route A few station
wells have been drilled by various methods on the south and west margins of the basin but data
are unavailable as reports are not required to be filed with the government Depth to watertable
throughout the basin is largely controlled by porosity of the bedrock
The GSWA drilled fifteen waterbores in the winter of 1995 in the southern part of the sub-
basin in preparation for the drilling of Trainor 1 and the proposed Bullen 1 Twelve bores found
water and six of these bores have salinities of less than 1000 mgL (Fig 5 Appendix 6 Table 61)
One waterbore TWB 6 has gamma ray and neutron logs run through PVC casing and these are
available from the GSWA with the digital log data included herein
Seismic data
No geophysical data have been acquired by the petroleum industry in the Savory Sub-basin
Seismic data acquired in the Officer Basin to the east particularly in the Gibson and Yowalga
Sub-basins is pertinent to structural interpretation in the Savory Sub-basin (Perincek 1996a
1998)
Aeromagnetic surveys
Government data
There are over 95 277 line kilometres of aeromagnetic data included in the AGSO dataset There
are three regional aeromagnetic surveys covering the Savory Sub-basin These were flown by the
Bureau of Mineral Resources (BMR now AGSO) in 1984 at a line spacing of 1500 m with 36 740
and 52 587 line kilometres flown and by Aerodata in 1984 at a line spacing of 1000m with 5950
line kilometres flown These data were reprocessed and interpreted for GSWA by Cowan (1995)
An edited copy of this report is included as Appendix 4 and the original report is filed in the
GSWA Library under S-series reports item 10331
30
Mineral industry data
The approximate locations of non-AGSO aeromagnetic surveys are shown in Figure 8 More
detailed information regarding the location of these surveys may be obtained using the GSWA
MAGCAT II database Additional information such as contours of aeromagnetic values may be
obtained by inspecting items on file with the GSWA
Gravity surveys
Government data
The average spacing for gravity data in the Savory Sub-basin is one station per 121 km2 (11 times 11
km grid) These data were principally collected by BMR in the early 1960s There are a few
additional regional gravity traverses across the sub-basin which are also included in the
BMRAGSO dataset These data were reprocessed and interpreted for GSWA (Fig 10) and a
report on this work is also included in Appendix 4
The GSWA completed a large semi-detailed gravity survey in the eastern Savory Sub-basin
utilizing helicopter support and Differential Global Positioning Survey (DGPS) techniques (Fig
8) This gravity survey completed in August 1995 consists of 2300 gravity stations on a 2 times 3 km
grid All stations were acquired by helicopter using Scintrex gravimeters and Ashtek dual
frequency DGPS equipment for determining location This highly efficient system allowed the
acquisition of more than 100 gravity stations per day in remote areas The resolution of this survey
is +30 cm and +05 microms-2 (Daishsat 1995) These data (Fig 11) represent a significant
improvement on the previous regional survey data and are available from GSWA (GSWA
1996ab) The results of the interpretation of these data were presented at the 1997 ASEG
Convention (Carlsen and Shevchenko 1997)
Mineral industry data
Three small gravity surveys were conducted by Oilmin NL (Fig 8) and the relevant WAMEX
reports are M 2681I 2610 I 2435 I 2567 These three surveys are of limited value because height
control was provided by barometers only and the surveys were not tied to the national gravity grid
31
23deg
25deg
120deg 122deg
Trainor 1
SAVORY
SUB-BASIN
MKS54 160498
100 km
1995 SavoryGravity Survey
254
-1056
micromsec2
Figure 10 Regional Bouguer gravity map of the Savory Sub-basin
23deg
24deg
25deg
122deg30 123deg
TRAINOR 1
123deg30
50 km
MKS53 160498
-116
-626
micro msec2
Figure11 Detailed Bouguer gravity map of the
Savory 1995 Gravity Survey from the eastern Savory Sub-basin
32
Government and academic reports
Chronostratigraphy and geochemistry
The understanding of Neoproterozoic organic chemistry palynology and structural evolution is
essential to the interpretation of hydrocarbon prospectivity Pertinent reports are included in the
bibliography (Appendix 1) Unpublished palaeontology reports describe the palynology of wells in
the Savory Sub-basin (Grey 1995andashe 1996a) Grey and Cotter (1996) discussed the potential for
Neoproterozoic palynomorphs to provide a biostratigraphic framework and palaeoenvironmental
interpretation Grey and Stevens (1997) reviewed the results of palynological studies of wells
drilled in the sub-basin and reported that Supersequence 1 palynomorphs are present in TWB 6
TWB 9 and LDDH1 (Appendix 3) Grey (1996b) reported on the use of stromatolites for
correlation in the Neoproterozoic and Stevens and Grey (1997) discussed the application of
stromatolite biostratigraphy in correlating isolated dolomite outcrops in the sub-basin with well
and seismic data in the Officer Basin and Centralian Superbasin
Although geochemical data from the Savory Sub-basin are very limited results mostly
confirm thermal maturities inferred from TAI for LDDH1 and Trainor 1 (Ghori in prep Stevens
and Adamides in prep) Those parts of the Officer Basin in Western Australia which lie to the
east of the Savory Sub-basin are sparsely drilled but Ghori (in prep) reports that most of the
Neoproterozoic succession presently lies within the oil-generative window However his study
has been unable to identify effective source-rock units and the source for oil shows Thin source
rocks are present in the Neoproterozoic in LDDH1 (Fig 9) and in three wells which lie to the east
and southeast of the Savory Sub-basin namely NJD 1 Kanpa 1A and Yowalga 3
Proposed work program
From the above limited information it is concluded that additional research on the hydrocarbon
potential of the sub-basin is justified and proposals are outlined below
bull Additional modelling of gravity and aeromagnetic data from the Savory Sub-basin is required
in light of the results from Trainor 1 and Boondawari 1 Trainor 1 showed that what appeared
to be a structurally simple area based on outcrop aeromagnetic and gravity data was in fact an
area of major structuring Boondawari 1 intersected a dolerite which is in good depth
agreement with aeromagnetic depth to source results showing this technique is useful in
detecting the depth to intrusive bodies
33
bull Additional data from mineral and petroleum exploration bores may become available and
analysis of samples from these wells should be undertaken and interpreted in the context of
their relevance to the Officer Basin
bull Stratigraphic coring in the Blake Fault and Fold Belt and in the Wells Foreland Sub-basin (Fig
1) targeting source rocks is considered essential to the continuing evaluation of the
hydrocarbon prospectivity of the Savory Sub-basin
bull Correlations using at least outcrop well and potential-field data should be prepared to link the
sub-basin with the better known parts of the Officer Basin to the east
bull Remapping is required to clarify boundary positions within the Cornelia Formation this may
resolve some of the current problems of the relationship between this unit and the rest of the
Savory Sub-basin
bull Further work is required to explain the Early Cambrian or Sturtian ages interpreted for the
Cornelia Formation from sedimentary zircon UndashPb dating in drillhole Trainor 1 The
determination of the age of the organically rich but overmature claystones in this well is
critical to assessing the hydrocarbon potential of the region
bull The thin dark mudstones intersected by Akubra 1 in the Mundadjini Formation warrant
geochemical analysis Analyses of the oil shows in Mundadjini 1 and Boondawari 1 are
currently being undertaken by Amadeus Petroleum
bull Geochemical analysis of hydrocarbons in the Bangemall Basin drillhole OD23 has been
performed by Jubilee Gold and the results will be reviewed when they are submitted to
GSWA The possibility of source rocks within the Bangemall Basin charging traps within the
Bangemall Basin and the overlying Savory Sub-basin requires further investigation
Conclusions
The Savory Sub-basin is a frontier region with only three recently drilled petroleum exploration
wells and no seismic data Based on existing geological and geophysical data it is considered too
early to draw conclusions about the hydrocarbon prospectivity of the sub-basin at this stage and
there are several reasons why the area warrants further investigation
34
1 Thick accumulations of sedimentary rocks are present (up to 8 km thickness inferred) which
may contain source reservoir and sealing strata
2 Minor oil shows occur in Mundadjini 1 and Boondawari 1 and bitumen is present in mineral
exploration drillhole LDDH1 suggesting that hydrocarbons have migrated within the
Neoproterozoic sequence of the Savory Sub-basin Oil and bitumen are present in mineral
exploration drillhole OD23 in the Bangemall Basin immediately to the south of the Savory
Sub-basin and it is possible that source rocks from the Bangemall Basin could charge traps in
the overlying Savory Sub-basin
3 The age of sedimentary rocks in the sub-basin is still poorly constrained but some of the
Neoproterozoic sedimentary rocks located on GUNANYA and TRAINOR are within the
hydrocarbon-generation window It is possible that a significant thickness of Phanerozoic
sedimentary rocks may also be present
4 Friable sandstones with visible porosity outcrop extensively suggesting numerous potential
reservoirs
5 Significant but not intense faulting and folding has been mapped implying large structural
traps may be present
6 Evaporitic sedimentary rocks occur in several formations and may provide good source rocks
and excellent seals
35
References
APAK S N and CARLSEN G M 1997 A compilation and review of data pertaining to the
hydrocarbon prospectivity of the Canning Basin Western Australia Geological Survey
Record 199610 103p
BAGAS L GREY K and WILLIAMS I R 1995 Reappraisal of the Paterson Orogen and
Savory Basin Western Australia Geological Survey Annual Review 1994ndash95 p 55ndash63
BUSBRIDGE M 1994 Lake Disappointment Exploration Licence 451064 Third Annual
Report Lake Disappointment Diamond Drill Hole LDDH1 Normandy Exploration Limited
Western Australia Geological Survey M-series Item 7567 A41358 (unpublished)
CARLSEN G M and SHEVCHENKO S I 1997 Petroleum exploration in Proterozoic basins
using potential fields data and stratigraphic coring Australian Society of Exploration
Geophysicists 12th Geophysical Conference Handbook Sydney 1997 Preview no 66 p 83
(abstract only)
COWAN D 1995 Savory Basin quantitative magnetic interpretation Western Australia
Geological Survey S-series S10331 (unpublished)
DAISHSAT PTY LTD 1995 Operational and processing report Savory Basin gravity survey
Western Australia Geological Survey S-series S10332 (unpublished)
GARD E and GARD R 1990 Canning Stock Route a travellerrsquos guide for a journey through
history Perth Western Australia Western Desert Guides 448p
GEOLOGICAL SURVEY OF WESTERN AUSTRALIA 1996a Savory Basin first vertical
derivative of Bouguer gravity image 1250 000 Western Australia Geological Survey
GEOLOGICAL SURVEY OF WESTERN AUSTRALIA 1996b Savory Basin Bouguer gravity
image 1250 000 Western Australia Geological Survey
GHORI K A R in prep Petroleum source rock potential and thermal history Officer Basin
Western Australia Western Australia Geological Survey Record
36
GREY K 1995a Savory Basin drillhole BWB 1 (Bullen waterbore) palynology and thermal
maturation GSWA Palaeontology Report no 199512 (unpublished)
GREY K 1995b Savory Basin drillholes TWB 1 2 6 9 (Trainor waterbores) palynology and
thermal maturation GSWA Palaeontology Report no 199520 (unpublished)
GREY K 1995c Palynology of Normandy-Poseidon Lake Disappointment-1 corehole
Tarcunyah Group Paterson Orogen GSWA Palaeontology Report no 199521 (unpublished)
GREY K 1995d Savory Basin drillhole Trainor 1 (Trainor diamond drilling) palynology and
thermal maturity GSWA Palaeontology Report no 199524 (unpublished)
GREY K 1995e Savory Basin drillhole Trainor 1 (Trainor diamond drilling) Additional
Preparation of two samples GSWA Palaeontology Report no 199528 (unpublished)
GREY K 1995f Neoproterozoic stromatolites from the Skates Hills Formation Savory Basin
Western Australia and a review of the distribution of Acaciella australica Australian Journal
of Earth Sciences v 42 p 123ndash132
GREY K 1996a Savory Basin drillhole Trainor 1 (Trainor diamond drilling) Additional
samples palynology and thermal maturation GSWA Palaeontology Report no 199615
(unpublished)
GREY K 1996b Preliminary stromatolite correlations for the Neoproterozoic of the Officer
Basin and a review of Australia-wide correlations GSWA Palaeontology Report no 199615
(unpublished)
GREY K and COTTER K L 1996 Palynology in the search for Proterozoic hydrocarbons
Western Australia Geological Survey Annual Review for 1995ndash96 p 70ndash80
GREY K and STEVENS M K 1997 Neoproterozoic palynomorphs of the Savory Sub-basin
Western Australia and their relevance to petroleum exploration Western Australia
Geological Survey Annual Review for 1996ndash97 p 49ndash54
HUBBARD R J PAPE J and ROBERTS D G 1985 Depositional sequence mapping as a
technique to establish tectonic and stratigraphic framework and evaluate hydrocarbon
potential on a passive continental margin in Seismic stratigraphy II an integrated approach
37
edited by O R BERG and D G WOOLVERTON American Association of Petroleum
Geologists Memoir 39 p 79ndash91
LIBBY WG 1995 A petrological report on six samples of bore cuttings from the Savory Basin
Western Australia Western Australia Geological Survey S-series S31307 (unpublished)
MORTON JGG and DREXEL JF 1997 The petroleum geology of South Australia Vol 3
Officer Basin South Australia Department of Mines and Energy Resources Report Book
9719
MUHLING P C and BRAKEL A T 1985 Geology of the Bangemall Group mdash the evolution
of an intracratonic Proterozoic basin Western Australia Geological Survey Bulletin 128
219p
MYERS J S 1990 Precambrian tectonic evolution of part of Gondwana southwestern Australia
Geology v18 p 537ndash540
NELSON D R 1997 Compilation of SHRIMP UndashPb zircon data Western Australia Geological
Survey Record 19972 196p
PAYTON C E 1977 Seismic stratigraphy mdash applications to hydrocarbon exploration
American Association of Petroleum Geologists Memoir 26 516p
PERINCEK D 1996a The age of NeoproterozoicndashPalaeozoic sediments within the Officer Basin
of the Centralian Super-basin can be constrained by major sequence-bounding unconformities
APPEA Journal v 36 pt 1 p 350ndash368
PERINCEK D 1996b The stratigraphic and structural development of the Officer Basin
Western Australia a review Western Australia Geological Survey Annual Review 1995ndash
1996 p 135ndash148
PERINCEK D 1998 A compilation and review of data pertaining to the hydrocarbon
prospectivity of the Officer Basin Western Australia Geological Survey Record 19976
POSAMENTIER H W JERSEY M T and VAIL P R 1988 Eustatic controls on clastic
deposition 1 mdash Conceptual framework in Sea-level changes an integrated approach edited by
C K WILGUS B S HASTINGS C G St C KENDALL H W POSAMENTIER
38
C A ROSS and J C VAN WAGONER Society of Economic Paleontologists and
Mineralogists Special Publication no 42
STEVENS M K and ADAMIDES N G in prep GSWA Trainor 1 well completion report
Savory Sub-basin Officer Basin Western Australia with notes on petroleum and mineral
potential Western Australia Geological Survey Record 199612
STEVENS M K and GREY K 1997 Skates Hills Formation and Tarcunyah Group Officer
Basin mdash carbonate cycles stratigraphic position and hydrocarbon prospectivity Western
Australia Geological Survey Annual Review for 1996ndash97 p 55ndash60
SUMMONS RE and POWELL C McA 1991 Petroleum source rocks of the Amadeus Basin
in Geological and geophysical studies in the Amadeus Basin central Australia edited by R J
KORSCH and JM KENNARD Australia BMR Geology and Geophysics Bulletin 236
TRAVERSE A 1988 Palaeopalynology Boston Unwin Hyman 600p
VAIL P R MITCHUM R M Jr TODD R G WIDMIER J M THOMPSON S III
SANGREE J B BUBB J N and HATLELID W G 1977 Seismic stratigraphy and
global changes of sea level in Seismic stratigraphy mdash applications to hydrocarbon
exploration edited by C E PAYTON American Association of Petroleum Geologists
Memoir 26 516p
WALTER M R and GORTER J 1994 The Neoproterozoic Centralian Superbasin in Western
Australia the Savory and Officer Basins in The sedimentary basins of Western Australia
edited by P G PURCELL and R R PURCELL Petroleum Exploration Society of Australia
Symposium Perth WA 1994 Proceedings p851ndash864
WALTER M R GREY K WILLIAMS I R and CALVER C R 1994 Stratigraphy of the
Neoproterozoic to early Palaeozoic Savory Basin and correlation with the Amadeus and
Officer Basins Australian Journal of Earth Sciences v 41 p 533ndash546
WALTER M R VEEVERS J J CALVER C R and GREY K 1995 Neoproterozoic
stratigraphy of the Centralian Superbasin Australia Precambrian Research v 73 p 173ndash195
WILLIAMS I R 1992 Geology of the Savory Basin Western Australia Western Australia
Geological Survey Bulletin 141 115p
39
WILLIAMS I R 1995a Bullen WA (2nd Edition) Western Australia Geological Survey
1250 000 Geological Series Explanatory Notes 23p
WILLIAMS I R 1995b Trainor WA (2nd Edition) Western Australia Geological Survey
1250 000 Geological Series Explanatory Notes 31p
WILLIAMS I R and TYLER I M 1991 Robertson WA (2nd edition) Western Australia
Geological Survey 1250 000 Geological Series Explanatory Notes 36p
40
41
Appendix 1
Bibliography
Reports which are relevant to this investigation but which are not specifically cited are listed
below
BAILLIE P W POWELL C McA LI Z X and RYALL A M 1994 The tectonic
framework of Western Australiarsquos Neoproterozoic to recent sedimentary basins in The
sedimentary basins of Western Australia edited by P G PURCELL and R R PURCELL
Petroleum Exploration Society of Australia Symposium Perth WA 1994 Proceedings p
45ndash62
BRADSHAW M T BRADSHAW J MURRAY A P NEEDHAM D J SPENCER L
SUMMONS R E WILMOT J and WINN S 1994 Petroleum systems in West Australian
basins in The sedimentary basins of Western Australia edited by P G PURCELL and R R
PURCELL Petroleum Exploration Society of Australia Symposium Perth WA 1994
Proceedings p 93ndash118
CLARKE G L 1991 Proterozoic tectonic reworking in the Rudall Complex Western Australia
Australian Journal of Earth Science v38 p 31ndash44
COCKBAIN A E and HOCKING R M 1990 Phanerozoic in Geology and mineral resources
of Western Australia Western Australia Geological Survey Memoir 3 p 750ndash755
ETHERIDGE M and WALL V 1994 Tectonic and structural evolution of the Australian
Proterozoic 12th Australian Geological Convention Geological Society of Australia
Abstracts no 37 p 102ndash103
GOODE A D T 1981 Proterozoic geology of Western Australia in Precambrian of the
Southern Hemisphere Developments in Precambrian geology 2 edited by I R HUNTER
Amsterdam Elsevier p 105ndash203
GREY K and JACKSON M J 1983 A re-assessment of stromatolite evidence for the
correlation of the Late Proterozoic Neale and Ilma Beds Officer Basin Western Australia
Australia BMR Journal of Australian Geology and Geophysics v 8 p 359
42
HICKMAN A H WILLIAMS I R and BAGAS L 1994 Proterozoic geology and
mineralization of the TelferndashRudall region Paterson Orogen Geological Society of Australia
(WA Division) Excursion Guidebook no 5 56p
HOCKING R M MORY A J and WILLIAMS I R 1994 An atlas of Neoproterozoic and
Phanerozoic basins of Western Australia in The sedimentary basins of Western Australia
edited by P G PURCELL and R R PURCELL Petroleum Exploration Society of Australia
Symposium Perth WA 1994 Proceedings p 21ndash 44
JACKSON P R 1966 Geology and review of exploration Officer Basin Western Australia
Hunt Oil Company Western Australia Geological Survey S-series S26 (unpublished)
JACKSON M J 1971 Notes on a geological reconnaissance of the Officer Basin Western
Australia Australia BMR Geology and Geophysics Record 19715 30p
JACKSON M J and van de GRAAFF W J E 1981 Geology of the Officer Basin Western
Australia Australia BMR Geology and Geophysics Bulletin 206 102 p
LOWRY D C JACKSON M J van de GRAAFF W J E and KENNEWELL P J 1971
Preliminary result of geological mapping in the Officer Basin Western Australia Western
Australia Geological Survey Annual Report for 1971 p 50ndash56
MYERS J S 1990 Precambrian in Geology and mineral resources of Western Australia
Western Australia Geological Survey Memoir 3 p 737ndash750
MYERS J S SHAW R D and TYLER I M 1994 Proterozoic tectonic evolution of
Australia 12th Australian Geological Convention Geological Society of Australia Abstracts
no 37 p 312
NEDIN C and JENKINS R J F 1991 Re-evaluation of unconformities separating the
lsquoEdiacaranrsquo and Cambrian systems South Australia Palaios v 6 p 102ndash108
PHILLIPS B J JAMES A W and PHILIP G M 1985 The geology and hydrocarbon
potential of the north-western Officer Basin APEA Journal 25 (1) p 52ndash61
POWELL C McA LI Z X McELHINNY M W MEERT J G and PARK J K 1993
Paleomagnetic constraints on timing of the Neoproterozoic breakup of Rodinia and Cambrian
formation of Gondwana Geology v 21 p 889ndash892
43
POWELL C McA PREISS W V GATEHOUSE C G KRAPEZ B and LI Z X 1994
South Australian record of a Rodinian epicontinental basin and its mid-Neoproterozoic
breakup to form the Palaeo-Pacific Ocean Tectonophysics v 237 no 3ndash4 p 113ndash140
PREISS W V 1976 Proterozoic stromatolites from the Nabberu and Officer Basins Western
Australia and their biostratigraphic significance South Australia Geological Survey Report
of Investigations no 47 p 1ndash51
TOWNSON W G 1985 The subsurface geology of the western Officer Basin mdash results of
Shellrsquos 1980ndash1984 petroleum exploration campaign APEA Journal v 25 (1) p 34ndash51
WATTS K J 1982 The geology of the Townsend Quartzite Upper Proterozoic shallow water
deposit of the Northern Officer Basin Western Australia Perth University of Western
Australia BSc honours thesis (unpublished)
WELLS A T and KENNEWELL P J 1974 Evaporite exploration in the Officer Basin
Western Australia at the Madley Diapirs Australia BMR Record 1974194 (unpublished)
WILLIAMS I R and MYERS J S 1990 Paterson Orogen in Geology and mineral resources
of Western Australia Western Australia Geological Survey Memoir 3 p 274ndash286
WILLIAMS I R 1990 Savory Basin in Geology and mineral resources of Western Australia
Western Australia Geological Survey Memoir 3 p 329ndash334
WILLIAMS I R 1994 The Neoproterozoic Savory Basin Western Australia in The
sedimentary basins of Western Australia edited by P G PURCELL and R R PURCELL
Petroleum Exploration Society of Australia Symposium Perth WA 1994 Proceedings p
841ndash850
WILSON R B 1967 Woolnough Hills and Madley diapiric structures Gibson Desert WA
APEA Journal v 7 p 94ndash102
44
Appendix 2
Meteorological data (from Bureau of Meteorology Perth 1994)
Table 21 Wiluna rainfall (mm)
Year Jan Feb Mar Apr May Jun Jul Aug Sept Oct Nov Dec
1975 0 45 446 309 306 59 276 4 34 886 638 164 1976 16 154 12 138 53 16 34 62 12 238 0 2 1977 44 0 66 74 68 95 24 363 1 58 12 727 1978 234 522 94 16 0 96 367 24 16 353 185 45 1979 19 173 122 88 91 4 0 246 58 0 169 114 1980 148 764 68 1081 259 626 629 06 56 02 174 0 1981 123 476 192 32 196 118 44 74 14 0 28 312 1982 374 705 206 244 1079 92 02 143 368 526 368 118 1983 1 112 928 248 0 212 56 32 5 1 42 496 1984 149 7 342 84 836 0 348 132 224 04 16 172 1985 596 483 0 166 556 0 514 56 0 0 4 0 1986 0 154 35 0 0 1085 23 01 239 137 0 04 1987 1204 119 19 89 17 575 154 126 07 1 0 398 1988 46 202 164 13 388 0 202 104 0 0 224 1309 1989 207 234 26 703 278 536 57 0 01 0 144 02 1990 1035 23 281 46 126 53 94 218 44 9 42 0 1991 48 0 41 45 0 472 297 12 0 1 0 7 1992 112 96 1025 1227 323 65 04 174 0 132 48 4 1993 0 697 0 202 445 0 12 306 18 05 14 33 Mean 25 35 22 27 27 25 18 12 6 13 13 21
JAN FEB MAR APR MAY JUN JUL AUG SEP OCT NOV DEC0
10
20
30
40
Mea
n R
ain
fall
(mm
)
Month
Mean monthly rainfall in Wiluna
MKS41 140498
45
Table 22 Wiluna minimum temperature (degC)
Year Jan Feb Mar Apr May Jun Jul Aug Sept Oct Nov Dec
1975 ndash 23 203 15 94 63 71 62 103 124 169 205 1976 242 229 194 15 10 63 59 73 95 143 16 228 1977 243 25 197 148 96 95 56 86 102 ndash 188 23 1978 241 232 203 18 102 64 76 8 9 152 19 205 1979 255 226 216 167 83 6 59 79 97 145 198 223 1980 255 226 231 155 134 83 68 75 121 108 193 223 1981 245 216 19 182 119 6 54 78 138 159 163 218 1982 232 224 177 16 ndash ndash 37 111 112 164 209 225 1983 235 24 197 147 112 88 39 88 121 162 189 219 1984 241 243 191 156 ndash 72 66 7 95 161 182 211 1985 244 231 ndash 159 98 65 71 73 117 147 205 ndash 1986 ndash 229 226 155 93 96 43 49 10 122 ndash 219 1987 ndash 217 183 175 85 77 68 68 112 ndash ndash 221 1988 238 214 209 178 111 ndash ndash 86 104 157 171 195 1989 ndash 237 199 165 107 67 44 61 107 131 187 ndash 1990 232 ndash 211 155 118 62 57 87 102 149 195 22 1991 26 256 217 168 122 101 78 ndash 113 18 168 219 1992 227 227 214 169 102 98 59 69 ndash 125 159 196 1993 241 218 196 171 103 ndash 49 68 88 128 192 211 Mean 24 23 20 16 10 8 6 8 11 14 18 21
NOTE Dashes indicate data unavailable
JAN FEB MAR APR MAY JUN JUL AUG SEP OCT NOV DEC0
10
20
30
40
Month
MKS43 140498
50
Mean monthly minimum temperatures at Wiluna
Mea
n T
emp
erat
ure
(degC
)
46
Table 23 Wiluna maximum temperature (degC)
Year Jan Feb Mar Apr May Jun Jul Aug Sept Oct Nov Dec
1975 ndash 349 326 281 247 201 197 212 256 248 31 344 1976 374 369 346 297 248 206 208 225 265 287 313 388 1977 397 392 352 296 234 212 222 244 ndash 308 337 383 1978 378 345 346 316 242 195 176 205 231 295 334 356 1979 403 36 364 295 ndash ndash ndash 193 242 318 359 373 1980 392 342 377 275 24 176 179 233 292 288 349 391 1981 385 346 337 342 242 178 201 224 30 326 326 369 1982 372 359 315 307 ndash ndash 196 253 252 305 353 379 1983 381 389 327 272 263 222 187 248 287 321 336 366 1984 378 393 322 299 226 215 178 214 234 ndash 336 364 1985 40 366 ndash 294 224 216 205 212 284 307 355 ndash 1986 ndash 383 372 307 ndash 193 166 196 261 277 ndash 382 1987 ndash 339 328 305 21 202 214 218 275 ndash ndash 374 1988 388 365 353 301 23 ndash ndash 228 283 334 31 33 1989 ndash 375 339 285 238 179 181 219 275 298 336 ndash 1990 368 ndash 36 309 268 19 188 205 274 309 373 393 1991 414 416 363 315 268 206 21 ndash 279 338 332 368 1992 363 383 336 263 213 178 213 197 ndash 285 313 359 1993 396 357 344 301 221 ndash 197 215 253 294 347 362 Mean 39 37 34 30 24 20 20 22 27 30 34 37 NOTE Dashes indicate data unavailable
JAN FEB MAR APR MAY JUN JUL AUG SEP OCT NOV DEC0
10
20
30
40
Month
MKS42 140498
50
Mean monthly maximum temperatures at Wiluna
Mea
n T
emp
erat
ure
(degC
)
47
Appendix 3
Table 31 Summary of palynological results
Drillhole Depth (m) F no(a) GSWA no Lithology Formation Assemblage TAI(b)
BWB 1 74ndash75 F49668 135741 dark-grey siltstone basalt Jilyilli gt5 BWB 1 98ndash100 F49669 135742 dark-grey siltstone basalt Jilyilli gt5 BWB 1 121ndash122 F49670 135743 dark-grey siltstone basalt Jilyilli gt5 TWB 1 86ndash87 F49671 135631 dark-grey siltstone McFadden 3+ TWB 1 104ndash105 F49672 135632 dark-grey siltstone Cornelia 3+ TWB 1 121ndash122 F49673 135633 dark-grey siltstone Cornelia 4 TWB 2 14ndash15 F49674 135634 dark-grey siltstone Skates Hills 3+ TWB 6 49ndash50 F49675 135675 dark-grey siltstone Cornelia 1 3+ TWB 9 49ndash51 F49676 135704 dark-grey siltstone Brassey Range 1 3+ Trainor 1 37497- F49733 138939 black mudstone with Cornelia 5 37509 light-grey siltstone Trainor 1 3809 F49734 138940 dark-grey and black Cornelia 4- laminated mudstone Trainor 1 4170 F49735 138941 black unlaminated mudstone Cornelia 4- Trainor 1 4950 F49851 139501 dark-grey indurated siltstone Cornelia 5 Trainor 1 6032 F49852 139502 dark- and light-grey Cornelia 5 indurated siltstone Trainor 1 6434 F49853 139503 greenish indurated finely Cornelia 5 laminated siltstone LDDH 1 270 F49678 138934 dark-grey siltstone interbeds Waters 1 3+ in enterolithic evaporite Tarcunyah Gp LDDH 1 277 F49679 138935 dark-grey siltstone in cavity Waters 1 3+ in enterolithic evaporite Tarcunyah Gp
NOTES (a) GSWA Fossil Catalogue number (b) TAI = Thermal Alteration Index of Traverse (1988 plate 1)
48
Appendix 4
Savory Sub-basin quantitative magnetic and gravity interpretation (extracted from Cowan 1995)
Summary
A program of quantitative aeromagnetic interpretation has been completed on BMRAGSO data from the Savory Sub-
basin Western Australia Quantitative aeromagnetic interpretation utilized the 3D Euler deconvolution method
supported by wavenumber filtering and image processing The results have provided useful information on structural
trends and depth to magnetic sources in a structurally complex area Depth to magnetic source analysis has provided
information on intra-sedimentary magnetic sources as well as basement rocks
The results of the interpretation support previously identified depocentres However the presence of magnetic
sources at several levels makes it very difficult to produce a reliable magnetic basement depth contour map It is
considered more productive to work with the 3D Euler colour circle plots and images rather than trying to contour the
results It would be necessary to carry out a full-scale interpretation of the BMRAGSO profile data to improve on the
3D Euler results The regional gravity was found to be useful in interpreting the regional setting of the area although
the very wide data spacing limits quantitative use of the data The gravity data show quite a complex picture with
limited consistent correlation between gravity features and basin structures This suggests that gravity anomalies
reflect changes in density of the basement rocks rather than basement topography especially in the northern part of the
basin
It is recommended that the GSWA investigate access to company confidential high-resolution aeromagnetic data
prior to planning further aeromagnetic surveys Private companies have flown large parts of the northern half of the
area as part of their diamond exploration program Additional gravity coverage of the area may be more cost effective
than magnetic surveys as the gravity data provides more information on changes within the sedimentary section
Introduction
The main use of aeromagnetic data in petroleum exploration has been the determination of magnetic basement
topography although there has been increasing interest in analysis of intra-sedimentary magnetic anomalies
intrabasement and suprabasement magnetic anomalies These anomalies are used to determine depth to magnetic
basement rocks and hence determine the thickness of the sedimentary sequence Unfortunately interpretation of the
intrabasement and suprabasement magnetic anomalies is non-unique in terms of position and size of causative sources
because of the inherent ambiguity of potential-field methods However this ambiguity can be reduced by placing
49
constraints on source geometry and magnetization and by using geological and other geophysical data to constrain
the solution
Before 1970 most depth-determination techniques involved graphical determination of slopes of selected
magnetic anomalies and application of various empirical factors to convert the slopes into depth estimates Geological
Society of America Memoir 47 Interpretation of Aeromagnetic Maps by Vacquier et al (1951) was a landmark for
this type of interpretation
Automated interpretation procedures have played an increasingly important role in depth interpretation and a
wide range of techniques have been developed Many of these techniques are designed for application to located data
profiles and assume a two-dimensional geometry However there has been renewed interest in techniques applicable
to gridded data
Two distinct types of method can be recognized In the first case often described as discrete methods individual
isolated magnetic anomalies are interpreted and the results used to produce a map of basement relief In the second
case often described as continuous methods areas of data containing a number of anomalies are interpreted
statistically to produce direct output of basement depths
The discrete methods usually involve a semiautomatic initial phase which generates a large number of possible
depth solutions and an interactive second phase to screen and select acceptable solutions The advantage of this
approach is that the interpreter can select features that are relatively free from interference from adjacent anomalies
and consider all aspects of a particular magnetic anomaly The disadvantage is that interpretation can be very time
consuming as a wide range of depths are usually possible depending on the initial model chosen and a significant
amount of effort is needed to select the correct model In the case of the Savory Sub-basin dataset we encountered
problems in separating basement related effects from the effects of shallower intrasedimentary magnetic sources
Because of these problems we have concentrated on displaying the Euler results accompanied by separation filter
images of the data to show the shallower effects and deeper effects rather than trying to refine a 3D Euler
deconvolution depth-to-crystalline-basement contour
The continuous methods are very direct provided that the rather restrictive assumption can be made that all
anomalies are due to lateral magnetization changes due to basement topography This means that shallow effects and
large intrabasement anomalies must be removed from the data This involves judgement and skill as it is necessary to
distinguish between the lower amplitude suprabasement anomalies due to basement topography and the larger
intrabasement anomalies reflecting magnetization changes within the basement These methods were not considered
suitable for the Savory Sub-basin magnetic dataset but were used to invert the gravity data
50
Limitations of magnetic and gravity interpretation
Interpretation of the area is limited by a shortage of information on the nature and physical properties of the deeper
sedimentary sequence and the underlying basement rocks However using techniques such as cross-correlation of
gravity and pseudo-gravity data it is possible to try to differentiate between anomalies relating to basement and those
related to the sedimentary sequence
Gravity anomalies reflect changes within the sedimentary sequence as well as basement condition These
changes in density of sedimentary rocks produce gravity anomalies without a corresponding magnetic anomaly hence
the complementary nature of gravity and magnetic surveys The main use of magnetics is to determine depth to
magnetic basement and any intra-sedimentary volcanic rocks or intrusives whereas gravity provides much more
general information on the sedimentary sequence
Unfortunately interpretation of gravity anomalies is complicated since they can be due to a number of geological
features including
bull major basement faults
bull basement highs
bull igneous intrusions within the basement
bull sedimentary basins which may or may not be isostatically compensated
bull intra-sedimentary volcanics and associated plutonic centres
Two major problems affect the interpretation of both magnetic and gravity data
1 The inherent ambiguity of potential-field data There is no unique solution to any measured gravity or magnetic
anomaly and theoretically there will be an infinite number of source geometry and magnetizationdensity
combinations which will fit the observed data This means that any a priori information which helps to select a
suitable model is very useful
2 Measured anomalies are the summation of effects from different depths For example an observed gravity profile
may contain contributions from shallow sources (density variations within the sedimentary basin) intermediate
depth sources (density variations due to large igneous intrusions within the basement) and deep sources (crustal
thinning producing a mantle anomaly) Separation of these component responses is the regionalresidual problem
which we solve using spectral analysis and differential upward continuation-based separation filtering
Regional setting and interpretation overview
The area studied includes parts of BALFOUR DOWNS (SF51-9) RUDALL (SF51-10) ROBERTSON (SF51-13) GUNANYA
(SF51-14) COLLIER (SG50-4) BULLEN (SG51-1) TRAINOR (SG51-2) MADLEY (SG51-3) NABBERU (SG50-5)
STANLEY (SG51-6) and HERBERT (SG51-7) 1250 000 sheets Broadly the area lies between latitudes 22deg00rsquondash25deg30rsquoS
and longitudes 119deg30rsquondash123deg30rsquoE
51
Regional gravity
The AGSO regional gravity data (at nominal 11 km spacing) was gridded at a 4 km mesh spacing using a minimum-
curvature algorithm Bouguer gravity values in the area are negative reflecting mass deficiency at depth and range
from -84 mgals to -25 mgals
A Bouguer gravity colour image is shown as Figure 41 A residual grid was produced by removing a fifth-order
orthogonal polynomial from the Bouguer data but did not add to the interpretation
120deg 121deg 122deg 123deg
23deg
24deg
25deg
-25
-84
50 km
MKS46 180598
mgal
Figure 41 Regional Bouguer gravity (BMRAGSO data) gridded at 4 km
52
The data show a complex pattern of positive and negative anomalies with no clearly defined trends Correlations
with aeromagnetic data and known basin structures are poor A vague north-northwest linear trend appears to coincide
with the Marloo Fault (Figure 42) A prominent negative anomaly appears to coincide with the Blake Fold and Fault
Belt depocentre and continues as a narrower negative anomaly to the east until it widens out again near the edge of the
basin Elsewhere the gravity data show little correlation with known basin structures and it is likely that especially in
the north of the area gravity anomalies are due to density changes in the basement rather than changes in basement
topography
Production of wavelength-filtered residual gravity plots and vertical gradient plots showed very patchy aliased
data reflecting poor sampling in much of the area
Regional magnetics
The AGSO regional aeromagnetic data were gridded at a 400 m mesh spacing using a minimum-curvature algorithm
(Figure 43) Most of the data has a line spacing of 1600 m with small areas of 1 km spacing The quality of the data is
acceptable for regional interpretation but is not adequate for detailed analysis The accuracy of the flight path is rather
variable reflecting the vintage of the data and the noise envelope of the data is poor by modern standards Problems
were also encountered in joining different map sheets
The magnetic anomaly pattern over the south and west part of the area shows a strong high frequency signature
reflecting the presence of widespread basic sills and dykes Some of the major north-northeasterly trending dykes can
be traced over considerable distances
Discontinuous high-frequency anomalies extend as a northwest-trending zone through the centre of the area and
this zone includes a conspicuous circular magnetic anomaly which is probably a ring complex
The northern and eastern parts of the area are characterized by long-wavelength deep-seated basement magnetic
anomalies with 120deg and 150deg trends dominant The Marloo and Perentie Faults (Figure 42) appear as distinct linear
zones and offsets A prominent easterly trending negative anomaly in the northwest of the area appears to swing round
to the southeast and may separate different basement blocks One possible interpretation is that this very deep seated
anomaly separates areas of Archaean and Proterozoic basement
Regional geology
The regional geology is described in Williams (1992) The GSWA provided a digitized version of Plate 2 from this
Bulletin the structural interpretation map to use as an overlay (Figure 42)
53
Pp
Pp
PSd
PSd
PSd
PSd
PSd
PSo
PSt
PSt
PSf
PSf
PSf
PSb
PSb
PSb
PSsPSs
PSs
PSb
PSm
PSp
PSc
PSc
PSw
PSw
PSw
PSg
PSr
PSj
PSg
PM
Pk
PY
PY
PSd
L
L
L
L
L
L
L
LL
L
L
L
LL
L
LL
L L
LL
L L
L
L
L
L
L
L
L
LL
L
L
BLAKEDEPOCENTRE
MA
RLO
O
FAU
LT
PERENTIEFAULT
50 km
MKS39120598
120deg 121deg 122deg 123deg
25deg
24deg
23deg
Approximate boundaryof aeromagnetic interpretation
PML
PSgL
PSjL
PML
PSpL
PML
PML
PSfL
PSfL
PSpL
LPc
LPcLPcPSrL
LPA
Durba Sandstone
Woora Woora Formation
McFadden Formation
Tchukardine Formation
Boondawari Formation
Skates Hills Formation
Mundadjini Formation
Coondra Formation
Spearhole Formation
Watch Point Formation
Jilyili Formation
Brassey Range Formation
Glass Spring Formation
Paterson Formation
Yeneena Group
Karara Formation
Cornelia Formation
Kahrban Subgroup
Bangemall Group
Fault
Formation boundary
PSdL
PSoL
PSfL
PStL
PSbL
PSsL
PSmL
PScL
PSpL
PSwL
PSjL
PSrL
PSgL
Pp
PYL
PkL
LPc
LPA
PML
Savory Group Other Units
PYL
Figure 42 Regional geology and structure map (after Williams 1992)
54
120deg 121deg 122deg 123deg
23deg
24deg
25deg
5820
3750
MKS47 180598
nT
50 km
Figure 43 Regional aeromagnetic data total magnetic intensity (BMRAGSO data) gridded at 400 m
Analysis
3D analysis
3D Euler deconvolution was used as the primary depth-determination method The advantage of this approach is that
consistent solutions can be obtained over the entire area with minimal assumptions about source geometries Euler
deconvolution of gridded data is used for positional information and estimation of depth to top of source Euler
55
deconvolution yields a large number of depth solutions which have to be screened to reject spurious solutions Results
are plotted as circles in eight depth ranges with radius proportional to depth and colour coded
The 400 m total magnetic intensity grid was used for the analysis Horizontal gradients in x and y and the vertical
gradient were calculated 3D Euler deconvolution was tested on the 400 m gridded data using windows of 9 times 9 and
11 times 11 and 16 times 16 data points and structural indices 05 (fault) and 10 (sill or dyke) It was concluded that the
16 times 16 window produced the best results overall and final plots were produced for the 16 times 16 window and structural
index 05 (Fig 44) Results were very good over the northern and central parts of the area showing magnetic sources
Figure 44 Depth to magnetic source 3D Euler deconvolution 16 times 16 window of 400 m gridded data structural index 05
56
at several different levels Unfortunately in the extreme south of the area shallow intrasedimentary magnetic sources
(sills and dykes) dominated the inversion and the results contained few basement solutions
In order to reduce these problems the 400 m gridded data were filtered using a separation filter based on
interpretation of the log-energy spectrum The 3D Euler method was run on the filtered data in order to generate more
basement-depth solutions Results for the deep-separation filter data were gridded and presented as a colour image in
Cowan (1995) Attempts to grid the Euler output were unsatisfactory and it is considered safer to interpret the 3D
Euler depth plots The 3D Euler depth results from the separation-filter run should be analysed with care as perfect
separation of the basement can never be achieved and there will always be some contamination from sources at
different levels
The results of original total magnetic intensity 3D Euler depth estimation for structural index 05 using a 16 point
window have been plotted at 1500 000 scale (not included in this publication but available in Cowan (1995) from the
GSWA Library as S10331) and as reduced A4 colour circle plots (Figure 44)
The results of deep-basement 3D Euler depth estimation for structural index 05 using a 16 point window have
been plotted as a colour image at 1500 000 scale and as an A4 image (not included in this publication)
2D analysis
Two equispaced profiles were interpolated with a 50 m station interval from the AGSO-located data profiles for the
BULLEN 1250 000 sheet The interpolated profiles were analysed using 2D Euler deconvolution and Werner
deconvolution Results are included in Cowan (1995) and show the use of these methods for more detailed analysis
Filtered data
In order to reconcile 3D Euler results from shallow basement and intrasedimentary magnetic sources we produced
several separation-filtered maps and images We found the shallow-layer double-separation filter (Figure 45) to be
very effective for shallow sources and the deep-layer standard-separation filter (Figure 46) for the basement layer
Gravity and magnetic data correlation
Both lsquoreduced to the polersquo (RTP) magnetics (Figure 47) and pseudo-gravity data (Figure 48) were produced as part of
the reconciliation of gravity and magnetic signatures In both cases the filtering operations assumed magnetization by
induction in the present Earths field The RTP data are fairly similar to the total magnetic intensity The pseudo-
57
gravity data are dominated by a northwest-trending strong positive anomaly and there is little correlation with the
Bouguer gravity data
The poor magneticgravity correlation is confirmed by cross-correlation of the RTP magnetics and the gravity
gradient The correlation plot in Figure 49 shows little coherent response with numerous zones of positive and
negative correlation
Figure 45 Regional aeromagnetic data shallow layer separation filter (BMRAGSO data) gridded at 400 m
Results
In the north and east of the area on the Wells Foreland Sub-basin trend (refer to Figure 1 main text) we see a range
of quite deep 3D Euler depths and several trend directions with north-northwesterly dominant There are relatively few
shallow intrasedimentary solutions in this zone
The second area of deep 3D Euler solutions lies over the Blake depocentre (Figure 43) with several trend
directions
Elsewhere the 3D Euler results are dominated by shallow intrasedimentary depth solutions reflecting mainly the
dolerite sills dykes and the ring complex However where we do see basement-related solutions in the south and
west of the area they appear to be shallower than those noted for the Wells Foreland Sub-basin and the Blake
depocentre
58
Figure 46 Regional aeromagnetic data deep-layer separation filter (BMRAGSO data) gridded at 400 m
Figure 48 Regional aeromagnetic data pseudo-gravity transform (BMRAGSO data) gridded at 400 m
Figure 47 Regional aeromagnetic data reduced-to-pole (BMRAGSO data) gridded at 400 m
Figure 49 Regional aeromagnetic and gravity data gravitymagnetic correlation using RTP magnetics and gravity gradient (BMRAGSO data) gridded at 4 km
59
This subdivision of the area into two zones of deep solutions is consistent with interpreted depocentres
However the interference between sources at different levels and the complexity of the magnetic response of the
basement rocks precludes more refined interpretation at this stage
The area of deep 3D Euler solutions over the Blake depocentre correlates with the pronounced negative gravity
anomaly discussed in the gravity interpretation section Using a density contrast of -015 gcc the negative gravity
anomaly could indicate up to 6ndash8 km of low-density sedimentary rocks depending on assumptions about the regional
field
The area of deep 3D Euler solutions over the Wells Foreland Sub-basin has a complex gravity expression and no
clear basin structure emerges from inversion of these data As noted previously it is likely that observed gravity
anomalies reflect contrasts in basement density rather than basement topography
Separation filtering applied to the magnetic data helps to enhance the intrasedimentary magnetic signature and to
give a better impression of the basement magnetic signature even though separation of the basement response is not
perfect
Conclusions
Quantitative aeromagnetic interpretation using 3D Euler deconvolution supported by wavenumber filtering and image
processing has been successful in providing structural trend and depth information for the Savory Sub-basin
Quantitative magnetic interpretation has revealed two zones of relatively deep magnetic basement beneath the
Wells Foreland Sub-basin and the Blake depocentre
This analysis of the magnetic data supports interpreted depocentres but the complexity of the basement magnetic
signature and interference from sources at different depths precludes further refinement to a map of basement
topography
Regional gravity proved to be very useful in understanding the regional setting of the area and in providing
support for aspects of the interpretation The gravity data support the interpretation of the Blake depocentre
suggesting up to 6ndash8 km of low-density sedimentary rocks
The deep structure of the Savory Sub-basin area is obviously complex with different areas underlain by
Archaean and Proterozoic basement and with the Capricorn suture occurring in the centre of the area
60
Recommendations
The quantitative magnetic interpretation needs to be reconciled with geological models available for the area
In particular the zones tentatively identified as areas with thick sedimentary rocks the Wells Foreland Sub-
basin and the Blake depocentre need to be investigated
Cross sections should be prepared across the basin for joint magneticgravity modelling especially for the Blake
depocentre It is important to be able to explain the strong negative gravity anomaly in this area
In view of the effects of basement density contrasts on the gravity field for the northern part of the area we think
that additional gravity interpretation and acquisition of new gravity data may not be justified as they will not
contribute significantly to understanding basin evolution and structure
It is recommended that GSWA try to get access to company confidential high-resolution aeromagnetic data
rather than flying new surveys The GSWA might offer to fund flying of new infill areas as a bargaining point
References
The original text of this report by Cowan (1995) and 1500 000 scale maps are filed in the GSWA Library under
S10331
COWAN D 1995 Savory Basin quantitative magnetic interpretation Western Australia Geological Survey S-series
S10331 (unpublished)
VACQUIER V STEENLAND N C HENDERSON R G and ZIETZ I 1951 Interpretation of aeromagnetic
maps The Geological Society of America Memoir 47 151p
WILLIAMS I R 1992 Geology of the Savory Basin Western Australia Western Australia Geological Survey
Bulletin 141 115p
61
Appendix 5
Geochemistry
MKS38 250398
Saturate FractionC12+ GLC
1217
Pr18
Ph
22
31CSR WELL-13 315m Cuttings
Figure 51 Canning Stock Route Well 13 gas chromatograph of extract of auger drill sample
12
17
18
22
31
Pr Ph
LDDH 1 6623m CoreSaturate FractionC12+ GLC
MKS35 240398
Figure 52 Gas chromatograph of extract from core sample at 6623 m LDDH1
62
Table 51 Canning Stock Route Well 13 auger drill samples
GSWA sample Drill depth (m)(a) Comments
135601 150 At watertable 135602 203 (all samples consist 135603 310 of sand mud and water) 135604 315 At total depth
NOTE (a) Datum for drill depth is the top of sediment fill in the well which is 155 m below ground level (ie the total depth of 315 m is 47 m below ground level)
Table 52 Canning Stock Route Well 13 gas chromatography data for 315 m depth sediment sample
Parameter Value
Weight of rock extracted (grams) 945 Total extract (ppm) 519 n-Alkane distribution n-C12 07 n-C13 23 n-C14 26 n-C15 22 n-C16 19 n-C17 14 i-C19 23 n-C18 14 i-C20 08 n-C19 11 n-C20 16 n-C21 25 n-C22 29 n-C23 70 n-C24 42 n-C25 95 n-C26 43 n-C27 83 n-C28 38 n-C29 87 n-C30 31 n-C31 273 Alkane compositional data Pristane phytane ratio 279 Pristane n-C17 ratio 161 Phytane n-C18 ratio 059 CPI (1)(a) 284 CPI (2) 209 (C21 + C22) (C28 + C29) 043
NOTE (a) CPI= Carbon preference index
63
Table 53 LDDH1 extract liquid chromatography data for 6623 m concentration
Rock extracted Total extract (grams) (ppm)
702 313
NOTE ppm= parts per million
Table 54 LDDH1 saturate gas chromatography data of core for 6623 m alkane composition
Pristane Pristane Phytane (a) CPI (1) CPI (2) (C21+C22) Phytane n-C17 n-C18 (C28+C29)
103 026 024 103 102 325
NOTE (a)CPI = carbon preference index
Table 55 LDDH1 saturate gas chromatography data of core for 6623 m n-alkane distributions
Parameter Value
n-C12 17 n-C13 38 n-C14 55 n-C15 60 n-C16 65 n-C17 74 i-C19 19 n-C18 78 i-C20 19 n-C19 80 n-C20 79 n-C21 71 n-C22 64 n-C23 57 n-C25 43 n-C24 38 n-C27 31 n-C28 23 n-C29 19 n-C30 12 n-C31 10
64
Appendix 6
Table 61 Summary of data from Trainor waterbores (TWB) and Bullen waterbores (BWB)
Well AMG Elevation TD Status(b) Completion details Water Salinity Water level Flow rate Depth to consolidated AGD84 GL (m) (m) struck mgl(c) (m) (LHr) lithology aquifer(e) Z51(a) Interval (m) (100 mm PVC) (m) (mgl)(d)
TWB 1 473660E 453 122 comp 0ndash75 plain 63 7 300 24 2 880 12 m 7287404N 75ndash93 slotted (9 260) McFadden Fm 93ndash99 plain TWB 2 472 977E 475 23 abd nil 15 m 7285877N Skates Hills Fm dry TWB 3 473259E 475 50 abd nil 7 m 7285849N Skates Hills Fm dry TWB 4 463225 E 445 50 comp 0ndash22 plain 35 7 200 55 3 600 0 m 7286143N 22ndash34 slotted (8 140) Tertiary sand and gravel 23ndash60 plain TWB 5 463095E 445 31 comp 0ndash19 plain 13 26 000 655 3 600 Tertiary sand and gravel 7277721N 19ndash25 slotted (36 700) 25ndash31 plain TWB 6 457013E 455 50 comp 0ndash42 plain 38 920 119 600 0 m 7274352N 42ndash48 slotted (1 030) Cornelia Fm ss TWB 7 453739E 475 26 susp 0ndash2 plain 11 9 300 48 4 500 0 m 7263891N (10 500) Tertiary sand TWB 8 433893E 535 60 susp 0ndash2 plain 47 8 500 gt46 1 200 0 m 7245991N (10 900) Tertiary sand and Brassey Range Fm ss TWB 9 437219E 505 51 comp 0ndash47 plain 45 1 000 58 600 1 m 7235905N 47ndash51 slotted (990) Brassey Range Fm ss TWB 10 434927E 495 32 susp 0ndash2 plain 235 450 120 0 m 7225875N (500) Dolerite
65
BWB 1 287337E 580 122 abd Nil 1 m 7245861N Jilyili Fm dry BWB 2 288346E 545 50 comp 0ndash26 plain 15 630 3 29 000 0 m 7240423N 26ndash38 slotted (730) Tertiary sand and gravel 38ndash50 plain BWB 3 305637E 545 50 abd 19 8 800 43 7 200 0 m 7240423N (10 550) Tertiary ss BWB 4 320167E 515 445 comp 0ndash20 plain 9 980 445 24 000 0 m 7248097N 20ndash32 slotted (1 190) Tertiary ss 32ndash44 plain BWB 5 353393E 545 20 susp 0ndash2 plain 45 (970) 1 m 7238934N Basalt
NOTES (a) GPS accuracy ~ 150 m (b) Comp = completed abd = abandoned susp = suspended (c) Salinity from conductivity (d) Analysis total dissolved solids (e) Fm = Formation ss = sandstone
25
Reservoirs
Each of the five depositional sequences of the Savory Group (Table 1) are inferred to contain
significant sandstone reservoirs with the possible exception of depositional sequence C as
discussed above in Stratigraphy The Spearhole Formation was cored in Mundadjini 1 and
Boondawari 1 and visual estimates of porosity vary from generally poor (less than 5) to fair
(approximately 5ndash15) The McFadden Formation in Trainor 1 has porosity values of up to 232
and a maximum permeability of 195 md (Stevens and Adamides in prep) Sandstones from
Neoproterozoic formations form the acquifers in the following waterbores the McFadden
Formation in TWB 1 the Cornelia Formation in TWB 6 and the Brassey Range Formation in
TWB 8 and TWB 9 (Appendix 6 Table 61)
Based on outcrop observations the Durba Sandstone is considered to be the best reservoir of
the Savory Group Similarly some sandstones from the Tarcunyah Group also have good visible
porosity in outcrop
Dolomites occur in several formations in the sub-basin Reservoir potential may exist
particularly where the dolomites are stromatolitic and oolitic However dolomites have not been
drilled in the sub-basin and porosity can only be inferred from the preferential silicification of
some stromatolite bioherms observed in outcrop (Stevens and Grey 1997) Elsewhere in the
Officer Basin porosities of up to10 have been measured in dolomites A limestone breccia
(karst) is described from 663 to 677 m in drillhole LDDH1 (Fig 6 Busbridge 1994)
Seals
Indications of evaporitic environments in the Mundadjini Skates Hills and Boondawari
Formations are described by Williams (1992) In Mundadjini 1 from 287 to 337 m anhydrite and
chert occurs as nodules beds and veins in mudstone of the Mundadjini Formation Evaporitic
minerals (predominantly gypsum) are described in the Tarcunyah Group in LDDH1 The presence
of the Woolnough and Madley salt diapirs in the Officer Basin (approximately 110 km east of the
sub-basin) and halite beds over 25 m thick in the well Hussar 1 (130 km east of the sub-basin)
provide further evidence that evaporite seals may be present in the Savory Sub-basin
Mudstones and shales form only a small proportion of the limited Neoproterozoic outcrop in
the sub-basin but significant thicknesses of mudstone were encountered in the Mundadjini
Formation in Mundadjini 1 and Boondawari 1 the Tarcunyah Group in LDDH1 and in the
26
Cornelia Formation in Trainor 1 These data suggest that mudstones form a significant proportion
of strata in the sub-basin despite their limited outcrop
Traps
Potential structural closures including folds and faults occur at various scales throughout the
Savory Sub-basin However the region has only been mapped at 1250 000 scale and
independently closed structures such as domes have yet to be confirmed The western margin of
the basin contains abundant faults (with a northeast strike) but elsewhere faults are less common
Some anticlines are recognized in outcrop including one with a strike length of up to 45 km
inferred from surface bedding dips in the Mundadjini and Spearhole Formations at approximately
24deg15rsquoS 121deg10rsquoE on BULLEN (Fig 1)
Salt diapirs and other halokinetic structures are recognized in outcrop well and seismic data
in the Officer Basin to the west of the Savory Sub-basin and it is probable that there are
significant thicknesses of evaporitic sedimentary rocks in the sub-basin The gravity field data
suggest there is good potential for salt diapirs and traps related to halokinesis
Although there is potential for stratigraphic traps to be present in the sub-basin insufficient
data are available to assess them
Preservation of hydrocarbons
The range of thermal maturities measured to date and the large periods of time envisaged for
deposition of sediments implies hydrocarbon generation may have occurred a number of times
during the evolution of the Savory Sub-basin Any hydrocarbons that were generated early may
have been trapped in palaeostructures and remigration to younger traps could have taken place
later The Petermann Ranges Orogeny which has been equated with the Paterson Orogeny (Myers
1990) is believed to have occurred in the latest Neoproterozoic to early Cambrian This is the last
major tectonic event recognized in the sub-basin suggesting that it is reasonable to expect that trap
integrity will have been preserved
If the inference of the presence of thick halite beds in the sub-basin is correct the preservation
potential of sub-salt traps should be excellent
27
Reported hydrocarbon shows and oil seep
Amadeus Petroleum recorded minor oil shows in cores from Mundadjini 1 and Boondawari 1 In
Mundadjini 1 at 36102 m (top of the Spearhole Formation) a 3 mm thick zone had 10 moderate
white fluorescence with slow solvent cut This show was in a granular sandstone with visually
estimated porosity of about 10 In Boondawari 1 at 35364 m (within the Spearhole Formation) a
broken surface of sandstone had 40 moderate yellow-white fluorescence with slow solvent cut
Visually estimated porosity is about 5 Because the fluorescing surface was broken during the
drilling process this show could have resulted from contamination A second show occurs in
Boondawari 1 at 4963 m (within the Spearhole Formation) where a 1 cm-thick zone had 5 dull
yellow fluorescence with slow solvent cut in a conglomerate with visually estimated porosity of
about 10 The company intends to further investigate the nature of these occurrences
Minor bitumen is present at 6623 m in drillhole LDDH1 on GUNANYA (Figs 5 and 6) as a
vein in mudstones of the Tarcunyah Group A sample was analysed by gas chromatography
(Ghori in prep) and confirmed that it is natural bitumen (Appendix 5)
Mineral hole OD 23 drilled by Jubilee Gold Mines NL on NABBERU in the Bangemall Basin
immediately to the south of the Savory Sub-basin (Fig 5) encountered bitumen and trace oil in
vugs in dolomite (M Stevens unpublished data) but no further data are available at present
In their popular guide to the Canning Stock Route Gard and Gard (1990 p 218) refer to an
oil seep at Well 13 on TRAINOR (Fig 5) They reported that between 1977 and 1984 lsquonatural oilrsquo
was seen in the well Although the well is now largely filled with sediment four auger drill
samples were collected by the GSWA in 1995 and all four were analysed for oil shows One
sample from 315 m total depth (GSWA sample 135604) yielded just enough extract (519 ppm)
for saturate gas chromatography analysis The gas chromatograph (Appendix 5) shows that the
extract does contain some hydrocarbons probably from recent plant material Because the depth to
the oil was not quoted in Gard and Gard (1990) the hand-augered well may not have been deep
enough to properly test this reported seep
Geological and geophysical databases
Geological and geophysical data available for the Savory Sub-basin are limited The most recently
completed geological maps for the sub-basin were published by the GSWA between 1991 and
1995 (Williams and Tyler 1991 Williams 1992 1995ab)
28
The cores from the five drillholes listed in Table 2 believed to be all of the core available
from the sub-basin are available for inspection at GSWA Mineral exploration reports submitted
to GSWA may be searched using the WAMEX database and open-file reports are available on
microfiche Geophysical data acquired by the mining industry is not required to be filed with
GSWA if acquired over Vacant Crown Land which is the case for much of the sub-basin
Geophysical survey data submitted in mining tenement reports and which extend into Vacant
Crown Land remain confidential to the companies Original regional aeromagnetic and gravity
datasets are available from the Australian Geological Survey Organisation (AGSO)
Data pertinent to oil exploration in the sub-basin such as structural style and salt diapirism
are presented in a review of the hydrocarbon prospectivity of the Officer Basin (Perincek 1998)
Drilling
Significant drillholes in the sub-basin are summarized in Table 2
Petroleum industry data
Amadeus Petroleum drilled three petroleum exploration wells in the central west of the Savory
Sub-basin in late 1997 These wells Mundadjini 1 Boondawari 1 and Akubra 1 were drilled by
continuous diamond coring (Figs 5 and 6) All targeted potential reservoirs within the Spearhole
Formation with the Mundadjini Formation as the proposed seal The wells were located on
structures interpreted from Landsat images and limited geological investigations Both Mundadjini
1 and Boondawari 1 had minor oil shows as discussed above (Reported hydrocarbon shows)
Government data
Stratigraphic drillhole Trainor 1 was drilled by GSWA in 1995 (Stevens and Adamides in prep)
and the main results are discussed above (Source rocks and Maturity)
Mineral industry data
Normandy Exploration drillhole LDDH1 was cored in the Tarcunyah Group to a total depth of
701 m and provided source-rock and maturity data as discussed above
29
Oilmin NL drilled six percussion drillholes (BD 1 3 4 5 8 and 9) through sandstones and
shales in the northern part of the Savory Sub-basin to a maximum depth of 198 m (Fig 5
WAMEX Microfiche File M 26811 I 2610) but only brief geological descriptions are available
Hydrogeological data
Hydrogeological data within the Savory Sub-basin are limited although a long history of water
exploration extends back to the construction of the Canning Stock Route early this century No
detailed geological or wireline logs are available for the older wells along this route A few station
wells have been drilled by various methods on the south and west margins of the basin but data
are unavailable as reports are not required to be filed with the government Depth to watertable
throughout the basin is largely controlled by porosity of the bedrock
The GSWA drilled fifteen waterbores in the winter of 1995 in the southern part of the sub-
basin in preparation for the drilling of Trainor 1 and the proposed Bullen 1 Twelve bores found
water and six of these bores have salinities of less than 1000 mgL (Fig 5 Appendix 6 Table 61)
One waterbore TWB 6 has gamma ray and neutron logs run through PVC casing and these are
available from the GSWA with the digital log data included herein
Seismic data
No geophysical data have been acquired by the petroleum industry in the Savory Sub-basin
Seismic data acquired in the Officer Basin to the east particularly in the Gibson and Yowalga
Sub-basins is pertinent to structural interpretation in the Savory Sub-basin (Perincek 1996a
1998)
Aeromagnetic surveys
Government data
There are over 95 277 line kilometres of aeromagnetic data included in the AGSO dataset There
are three regional aeromagnetic surveys covering the Savory Sub-basin These were flown by the
Bureau of Mineral Resources (BMR now AGSO) in 1984 at a line spacing of 1500 m with 36 740
and 52 587 line kilometres flown and by Aerodata in 1984 at a line spacing of 1000m with 5950
line kilometres flown These data were reprocessed and interpreted for GSWA by Cowan (1995)
An edited copy of this report is included as Appendix 4 and the original report is filed in the
GSWA Library under S-series reports item 10331
30
Mineral industry data
The approximate locations of non-AGSO aeromagnetic surveys are shown in Figure 8 More
detailed information regarding the location of these surveys may be obtained using the GSWA
MAGCAT II database Additional information such as contours of aeromagnetic values may be
obtained by inspecting items on file with the GSWA
Gravity surveys
Government data
The average spacing for gravity data in the Savory Sub-basin is one station per 121 km2 (11 times 11
km grid) These data were principally collected by BMR in the early 1960s There are a few
additional regional gravity traverses across the sub-basin which are also included in the
BMRAGSO dataset These data were reprocessed and interpreted for GSWA (Fig 10) and a
report on this work is also included in Appendix 4
The GSWA completed a large semi-detailed gravity survey in the eastern Savory Sub-basin
utilizing helicopter support and Differential Global Positioning Survey (DGPS) techniques (Fig
8) This gravity survey completed in August 1995 consists of 2300 gravity stations on a 2 times 3 km
grid All stations were acquired by helicopter using Scintrex gravimeters and Ashtek dual
frequency DGPS equipment for determining location This highly efficient system allowed the
acquisition of more than 100 gravity stations per day in remote areas The resolution of this survey
is +30 cm and +05 microms-2 (Daishsat 1995) These data (Fig 11) represent a significant
improvement on the previous regional survey data and are available from GSWA (GSWA
1996ab) The results of the interpretation of these data were presented at the 1997 ASEG
Convention (Carlsen and Shevchenko 1997)
Mineral industry data
Three small gravity surveys were conducted by Oilmin NL (Fig 8) and the relevant WAMEX
reports are M 2681I 2610 I 2435 I 2567 These three surveys are of limited value because height
control was provided by barometers only and the surveys were not tied to the national gravity grid
31
23deg
25deg
120deg 122deg
Trainor 1
SAVORY
SUB-BASIN
MKS54 160498
100 km
1995 SavoryGravity Survey
254
-1056
micromsec2
Figure 10 Regional Bouguer gravity map of the Savory Sub-basin
23deg
24deg
25deg
122deg30 123deg
TRAINOR 1
123deg30
50 km
MKS53 160498
-116
-626
micro msec2
Figure11 Detailed Bouguer gravity map of the
Savory 1995 Gravity Survey from the eastern Savory Sub-basin
32
Government and academic reports
Chronostratigraphy and geochemistry
The understanding of Neoproterozoic organic chemistry palynology and structural evolution is
essential to the interpretation of hydrocarbon prospectivity Pertinent reports are included in the
bibliography (Appendix 1) Unpublished palaeontology reports describe the palynology of wells in
the Savory Sub-basin (Grey 1995andashe 1996a) Grey and Cotter (1996) discussed the potential for
Neoproterozoic palynomorphs to provide a biostratigraphic framework and palaeoenvironmental
interpretation Grey and Stevens (1997) reviewed the results of palynological studies of wells
drilled in the sub-basin and reported that Supersequence 1 palynomorphs are present in TWB 6
TWB 9 and LDDH1 (Appendix 3) Grey (1996b) reported on the use of stromatolites for
correlation in the Neoproterozoic and Stevens and Grey (1997) discussed the application of
stromatolite biostratigraphy in correlating isolated dolomite outcrops in the sub-basin with well
and seismic data in the Officer Basin and Centralian Superbasin
Although geochemical data from the Savory Sub-basin are very limited results mostly
confirm thermal maturities inferred from TAI for LDDH1 and Trainor 1 (Ghori in prep Stevens
and Adamides in prep) Those parts of the Officer Basin in Western Australia which lie to the
east of the Savory Sub-basin are sparsely drilled but Ghori (in prep) reports that most of the
Neoproterozoic succession presently lies within the oil-generative window However his study
has been unable to identify effective source-rock units and the source for oil shows Thin source
rocks are present in the Neoproterozoic in LDDH1 (Fig 9) and in three wells which lie to the east
and southeast of the Savory Sub-basin namely NJD 1 Kanpa 1A and Yowalga 3
Proposed work program
From the above limited information it is concluded that additional research on the hydrocarbon
potential of the sub-basin is justified and proposals are outlined below
bull Additional modelling of gravity and aeromagnetic data from the Savory Sub-basin is required
in light of the results from Trainor 1 and Boondawari 1 Trainor 1 showed that what appeared
to be a structurally simple area based on outcrop aeromagnetic and gravity data was in fact an
area of major structuring Boondawari 1 intersected a dolerite which is in good depth
agreement with aeromagnetic depth to source results showing this technique is useful in
detecting the depth to intrusive bodies
33
bull Additional data from mineral and petroleum exploration bores may become available and
analysis of samples from these wells should be undertaken and interpreted in the context of
their relevance to the Officer Basin
bull Stratigraphic coring in the Blake Fault and Fold Belt and in the Wells Foreland Sub-basin (Fig
1) targeting source rocks is considered essential to the continuing evaluation of the
hydrocarbon prospectivity of the Savory Sub-basin
bull Correlations using at least outcrop well and potential-field data should be prepared to link the
sub-basin with the better known parts of the Officer Basin to the east
bull Remapping is required to clarify boundary positions within the Cornelia Formation this may
resolve some of the current problems of the relationship between this unit and the rest of the
Savory Sub-basin
bull Further work is required to explain the Early Cambrian or Sturtian ages interpreted for the
Cornelia Formation from sedimentary zircon UndashPb dating in drillhole Trainor 1 The
determination of the age of the organically rich but overmature claystones in this well is
critical to assessing the hydrocarbon potential of the region
bull The thin dark mudstones intersected by Akubra 1 in the Mundadjini Formation warrant
geochemical analysis Analyses of the oil shows in Mundadjini 1 and Boondawari 1 are
currently being undertaken by Amadeus Petroleum
bull Geochemical analysis of hydrocarbons in the Bangemall Basin drillhole OD23 has been
performed by Jubilee Gold and the results will be reviewed when they are submitted to
GSWA The possibility of source rocks within the Bangemall Basin charging traps within the
Bangemall Basin and the overlying Savory Sub-basin requires further investigation
Conclusions
The Savory Sub-basin is a frontier region with only three recently drilled petroleum exploration
wells and no seismic data Based on existing geological and geophysical data it is considered too
early to draw conclusions about the hydrocarbon prospectivity of the sub-basin at this stage and
there are several reasons why the area warrants further investigation
34
1 Thick accumulations of sedimentary rocks are present (up to 8 km thickness inferred) which
may contain source reservoir and sealing strata
2 Minor oil shows occur in Mundadjini 1 and Boondawari 1 and bitumen is present in mineral
exploration drillhole LDDH1 suggesting that hydrocarbons have migrated within the
Neoproterozoic sequence of the Savory Sub-basin Oil and bitumen are present in mineral
exploration drillhole OD23 in the Bangemall Basin immediately to the south of the Savory
Sub-basin and it is possible that source rocks from the Bangemall Basin could charge traps in
the overlying Savory Sub-basin
3 The age of sedimentary rocks in the sub-basin is still poorly constrained but some of the
Neoproterozoic sedimentary rocks located on GUNANYA and TRAINOR are within the
hydrocarbon-generation window It is possible that a significant thickness of Phanerozoic
sedimentary rocks may also be present
4 Friable sandstones with visible porosity outcrop extensively suggesting numerous potential
reservoirs
5 Significant but not intense faulting and folding has been mapped implying large structural
traps may be present
6 Evaporitic sedimentary rocks occur in several formations and may provide good source rocks
and excellent seals
35
References
APAK S N and CARLSEN G M 1997 A compilation and review of data pertaining to the
hydrocarbon prospectivity of the Canning Basin Western Australia Geological Survey
Record 199610 103p
BAGAS L GREY K and WILLIAMS I R 1995 Reappraisal of the Paterson Orogen and
Savory Basin Western Australia Geological Survey Annual Review 1994ndash95 p 55ndash63
BUSBRIDGE M 1994 Lake Disappointment Exploration Licence 451064 Third Annual
Report Lake Disappointment Diamond Drill Hole LDDH1 Normandy Exploration Limited
Western Australia Geological Survey M-series Item 7567 A41358 (unpublished)
CARLSEN G M and SHEVCHENKO S I 1997 Petroleum exploration in Proterozoic basins
using potential fields data and stratigraphic coring Australian Society of Exploration
Geophysicists 12th Geophysical Conference Handbook Sydney 1997 Preview no 66 p 83
(abstract only)
COWAN D 1995 Savory Basin quantitative magnetic interpretation Western Australia
Geological Survey S-series S10331 (unpublished)
DAISHSAT PTY LTD 1995 Operational and processing report Savory Basin gravity survey
Western Australia Geological Survey S-series S10332 (unpublished)
GARD E and GARD R 1990 Canning Stock Route a travellerrsquos guide for a journey through
history Perth Western Australia Western Desert Guides 448p
GEOLOGICAL SURVEY OF WESTERN AUSTRALIA 1996a Savory Basin first vertical
derivative of Bouguer gravity image 1250 000 Western Australia Geological Survey
GEOLOGICAL SURVEY OF WESTERN AUSTRALIA 1996b Savory Basin Bouguer gravity
image 1250 000 Western Australia Geological Survey
GHORI K A R in prep Petroleum source rock potential and thermal history Officer Basin
Western Australia Western Australia Geological Survey Record
36
GREY K 1995a Savory Basin drillhole BWB 1 (Bullen waterbore) palynology and thermal
maturation GSWA Palaeontology Report no 199512 (unpublished)
GREY K 1995b Savory Basin drillholes TWB 1 2 6 9 (Trainor waterbores) palynology and
thermal maturation GSWA Palaeontology Report no 199520 (unpublished)
GREY K 1995c Palynology of Normandy-Poseidon Lake Disappointment-1 corehole
Tarcunyah Group Paterson Orogen GSWA Palaeontology Report no 199521 (unpublished)
GREY K 1995d Savory Basin drillhole Trainor 1 (Trainor diamond drilling) palynology and
thermal maturity GSWA Palaeontology Report no 199524 (unpublished)
GREY K 1995e Savory Basin drillhole Trainor 1 (Trainor diamond drilling) Additional
Preparation of two samples GSWA Palaeontology Report no 199528 (unpublished)
GREY K 1995f Neoproterozoic stromatolites from the Skates Hills Formation Savory Basin
Western Australia and a review of the distribution of Acaciella australica Australian Journal
of Earth Sciences v 42 p 123ndash132
GREY K 1996a Savory Basin drillhole Trainor 1 (Trainor diamond drilling) Additional
samples palynology and thermal maturation GSWA Palaeontology Report no 199615
(unpublished)
GREY K 1996b Preliminary stromatolite correlations for the Neoproterozoic of the Officer
Basin and a review of Australia-wide correlations GSWA Palaeontology Report no 199615
(unpublished)
GREY K and COTTER K L 1996 Palynology in the search for Proterozoic hydrocarbons
Western Australia Geological Survey Annual Review for 1995ndash96 p 70ndash80
GREY K and STEVENS M K 1997 Neoproterozoic palynomorphs of the Savory Sub-basin
Western Australia and their relevance to petroleum exploration Western Australia
Geological Survey Annual Review for 1996ndash97 p 49ndash54
HUBBARD R J PAPE J and ROBERTS D G 1985 Depositional sequence mapping as a
technique to establish tectonic and stratigraphic framework and evaluate hydrocarbon
potential on a passive continental margin in Seismic stratigraphy II an integrated approach
37
edited by O R BERG and D G WOOLVERTON American Association of Petroleum
Geologists Memoir 39 p 79ndash91
LIBBY WG 1995 A petrological report on six samples of bore cuttings from the Savory Basin
Western Australia Western Australia Geological Survey S-series S31307 (unpublished)
MORTON JGG and DREXEL JF 1997 The petroleum geology of South Australia Vol 3
Officer Basin South Australia Department of Mines and Energy Resources Report Book
9719
MUHLING P C and BRAKEL A T 1985 Geology of the Bangemall Group mdash the evolution
of an intracratonic Proterozoic basin Western Australia Geological Survey Bulletin 128
219p
MYERS J S 1990 Precambrian tectonic evolution of part of Gondwana southwestern Australia
Geology v18 p 537ndash540
NELSON D R 1997 Compilation of SHRIMP UndashPb zircon data Western Australia Geological
Survey Record 19972 196p
PAYTON C E 1977 Seismic stratigraphy mdash applications to hydrocarbon exploration
American Association of Petroleum Geologists Memoir 26 516p
PERINCEK D 1996a The age of NeoproterozoicndashPalaeozoic sediments within the Officer Basin
of the Centralian Super-basin can be constrained by major sequence-bounding unconformities
APPEA Journal v 36 pt 1 p 350ndash368
PERINCEK D 1996b The stratigraphic and structural development of the Officer Basin
Western Australia a review Western Australia Geological Survey Annual Review 1995ndash
1996 p 135ndash148
PERINCEK D 1998 A compilation and review of data pertaining to the hydrocarbon
prospectivity of the Officer Basin Western Australia Geological Survey Record 19976
POSAMENTIER H W JERSEY M T and VAIL P R 1988 Eustatic controls on clastic
deposition 1 mdash Conceptual framework in Sea-level changes an integrated approach edited by
C K WILGUS B S HASTINGS C G St C KENDALL H W POSAMENTIER
38
C A ROSS and J C VAN WAGONER Society of Economic Paleontologists and
Mineralogists Special Publication no 42
STEVENS M K and ADAMIDES N G in prep GSWA Trainor 1 well completion report
Savory Sub-basin Officer Basin Western Australia with notes on petroleum and mineral
potential Western Australia Geological Survey Record 199612
STEVENS M K and GREY K 1997 Skates Hills Formation and Tarcunyah Group Officer
Basin mdash carbonate cycles stratigraphic position and hydrocarbon prospectivity Western
Australia Geological Survey Annual Review for 1996ndash97 p 55ndash60
SUMMONS RE and POWELL C McA 1991 Petroleum source rocks of the Amadeus Basin
in Geological and geophysical studies in the Amadeus Basin central Australia edited by R J
KORSCH and JM KENNARD Australia BMR Geology and Geophysics Bulletin 236
TRAVERSE A 1988 Palaeopalynology Boston Unwin Hyman 600p
VAIL P R MITCHUM R M Jr TODD R G WIDMIER J M THOMPSON S III
SANGREE J B BUBB J N and HATLELID W G 1977 Seismic stratigraphy and
global changes of sea level in Seismic stratigraphy mdash applications to hydrocarbon
exploration edited by C E PAYTON American Association of Petroleum Geologists
Memoir 26 516p
WALTER M R and GORTER J 1994 The Neoproterozoic Centralian Superbasin in Western
Australia the Savory and Officer Basins in The sedimentary basins of Western Australia
edited by P G PURCELL and R R PURCELL Petroleum Exploration Society of Australia
Symposium Perth WA 1994 Proceedings p851ndash864
WALTER M R GREY K WILLIAMS I R and CALVER C R 1994 Stratigraphy of the
Neoproterozoic to early Palaeozoic Savory Basin and correlation with the Amadeus and
Officer Basins Australian Journal of Earth Sciences v 41 p 533ndash546
WALTER M R VEEVERS J J CALVER C R and GREY K 1995 Neoproterozoic
stratigraphy of the Centralian Superbasin Australia Precambrian Research v 73 p 173ndash195
WILLIAMS I R 1992 Geology of the Savory Basin Western Australia Western Australia
Geological Survey Bulletin 141 115p
39
WILLIAMS I R 1995a Bullen WA (2nd Edition) Western Australia Geological Survey
1250 000 Geological Series Explanatory Notes 23p
WILLIAMS I R 1995b Trainor WA (2nd Edition) Western Australia Geological Survey
1250 000 Geological Series Explanatory Notes 31p
WILLIAMS I R and TYLER I M 1991 Robertson WA (2nd edition) Western Australia
Geological Survey 1250 000 Geological Series Explanatory Notes 36p
40
41
Appendix 1
Bibliography
Reports which are relevant to this investigation but which are not specifically cited are listed
below
BAILLIE P W POWELL C McA LI Z X and RYALL A M 1994 The tectonic
framework of Western Australiarsquos Neoproterozoic to recent sedimentary basins in The
sedimentary basins of Western Australia edited by P G PURCELL and R R PURCELL
Petroleum Exploration Society of Australia Symposium Perth WA 1994 Proceedings p
45ndash62
BRADSHAW M T BRADSHAW J MURRAY A P NEEDHAM D J SPENCER L
SUMMONS R E WILMOT J and WINN S 1994 Petroleum systems in West Australian
basins in The sedimentary basins of Western Australia edited by P G PURCELL and R R
PURCELL Petroleum Exploration Society of Australia Symposium Perth WA 1994
Proceedings p 93ndash118
CLARKE G L 1991 Proterozoic tectonic reworking in the Rudall Complex Western Australia
Australian Journal of Earth Science v38 p 31ndash44
COCKBAIN A E and HOCKING R M 1990 Phanerozoic in Geology and mineral resources
of Western Australia Western Australia Geological Survey Memoir 3 p 750ndash755
ETHERIDGE M and WALL V 1994 Tectonic and structural evolution of the Australian
Proterozoic 12th Australian Geological Convention Geological Society of Australia
Abstracts no 37 p 102ndash103
GOODE A D T 1981 Proterozoic geology of Western Australia in Precambrian of the
Southern Hemisphere Developments in Precambrian geology 2 edited by I R HUNTER
Amsterdam Elsevier p 105ndash203
GREY K and JACKSON M J 1983 A re-assessment of stromatolite evidence for the
correlation of the Late Proterozoic Neale and Ilma Beds Officer Basin Western Australia
Australia BMR Journal of Australian Geology and Geophysics v 8 p 359
42
HICKMAN A H WILLIAMS I R and BAGAS L 1994 Proterozoic geology and
mineralization of the TelferndashRudall region Paterson Orogen Geological Society of Australia
(WA Division) Excursion Guidebook no 5 56p
HOCKING R M MORY A J and WILLIAMS I R 1994 An atlas of Neoproterozoic and
Phanerozoic basins of Western Australia in The sedimentary basins of Western Australia
edited by P G PURCELL and R R PURCELL Petroleum Exploration Society of Australia
Symposium Perth WA 1994 Proceedings p 21ndash 44
JACKSON P R 1966 Geology and review of exploration Officer Basin Western Australia
Hunt Oil Company Western Australia Geological Survey S-series S26 (unpublished)
JACKSON M J 1971 Notes on a geological reconnaissance of the Officer Basin Western
Australia Australia BMR Geology and Geophysics Record 19715 30p
JACKSON M J and van de GRAAFF W J E 1981 Geology of the Officer Basin Western
Australia Australia BMR Geology and Geophysics Bulletin 206 102 p
LOWRY D C JACKSON M J van de GRAAFF W J E and KENNEWELL P J 1971
Preliminary result of geological mapping in the Officer Basin Western Australia Western
Australia Geological Survey Annual Report for 1971 p 50ndash56
MYERS J S 1990 Precambrian in Geology and mineral resources of Western Australia
Western Australia Geological Survey Memoir 3 p 737ndash750
MYERS J S SHAW R D and TYLER I M 1994 Proterozoic tectonic evolution of
Australia 12th Australian Geological Convention Geological Society of Australia Abstracts
no 37 p 312
NEDIN C and JENKINS R J F 1991 Re-evaluation of unconformities separating the
lsquoEdiacaranrsquo and Cambrian systems South Australia Palaios v 6 p 102ndash108
PHILLIPS B J JAMES A W and PHILIP G M 1985 The geology and hydrocarbon
potential of the north-western Officer Basin APEA Journal 25 (1) p 52ndash61
POWELL C McA LI Z X McELHINNY M W MEERT J G and PARK J K 1993
Paleomagnetic constraints on timing of the Neoproterozoic breakup of Rodinia and Cambrian
formation of Gondwana Geology v 21 p 889ndash892
43
POWELL C McA PREISS W V GATEHOUSE C G KRAPEZ B and LI Z X 1994
South Australian record of a Rodinian epicontinental basin and its mid-Neoproterozoic
breakup to form the Palaeo-Pacific Ocean Tectonophysics v 237 no 3ndash4 p 113ndash140
PREISS W V 1976 Proterozoic stromatolites from the Nabberu and Officer Basins Western
Australia and their biostratigraphic significance South Australia Geological Survey Report
of Investigations no 47 p 1ndash51
TOWNSON W G 1985 The subsurface geology of the western Officer Basin mdash results of
Shellrsquos 1980ndash1984 petroleum exploration campaign APEA Journal v 25 (1) p 34ndash51
WATTS K J 1982 The geology of the Townsend Quartzite Upper Proterozoic shallow water
deposit of the Northern Officer Basin Western Australia Perth University of Western
Australia BSc honours thesis (unpublished)
WELLS A T and KENNEWELL P J 1974 Evaporite exploration in the Officer Basin
Western Australia at the Madley Diapirs Australia BMR Record 1974194 (unpublished)
WILLIAMS I R and MYERS J S 1990 Paterson Orogen in Geology and mineral resources
of Western Australia Western Australia Geological Survey Memoir 3 p 274ndash286
WILLIAMS I R 1990 Savory Basin in Geology and mineral resources of Western Australia
Western Australia Geological Survey Memoir 3 p 329ndash334
WILLIAMS I R 1994 The Neoproterozoic Savory Basin Western Australia in The
sedimentary basins of Western Australia edited by P G PURCELL and R R PURCELL
Petroleum Exploration Society of Australia Symposium Perth WA 1994 Proceedings p
841ndash850
WILSON R B 1967 Woolnough Hills and Madley diapiric structures Gibson Desert WA
APEA Journal v 7 p 94ndash102
44
Appendix 2
Meteorological data (from Bureau of Meteorology Perth 1994)
Table 21 Wiluna rainfall (mm)
Year Jan Feb Mar Apr May Jun Jul Aug Sept Oct Nov Dec
1975 0 45 446 309 306 59 276 4 34 886 638 164 1976 16 154 12 138 53 16 34 62 12 238 0 2 1977 44 0 66 74 68 95 24 363 1 58 12 727 1978 234 522 94 16 0 96 367 24 16 353 185 45 1979 19 173 122 88 91 4 0 246 58 0 169 114 1980 148 764 68 1081 259 626 629 06 56 02 174 0 1981 123 476 192 32 196 118 44 74 14 0 28 312 1982 374 705 206 244 1079 92 02 143 368 526 368 118 1983 1 112 928 248 0 212 56 32 5 1 42 496 1984 149 7 342 84 836 0 348 132 224 04 16 172 1985 596 483 0 166 556 0 514 56 0 0 4 0 1986 0 154 35 0 0 1085 23 01 239 137 0 04 1987 1204 119 19 89 17 575 154 126 07 1 0 398 1988 46 202 164 13 388 0 202 104 0 0 224 1309 1989 207 234 26 703 278 536 57 0 01 0 144 02 1990 1035 23 281 46 126 53 94 218 44 9 42 0 1991 48 0 41 45 0 472 297 12 0 1 0 7 1992 112 96 1025 1227 323 65 04 174 0 132 48 4 1993 0 697 0 202 445 0 12 306 18 05 14 33 Mean 25 35 22 27 27 25 18 12 6 13 13 21
JAN FEB MAR APR MAY JUN JUL AUG SEP OCT NOV DEC0
10
20
30
40
Mea
n R
ain
fall
(mm
)
Month
Mean monthly rainfall in Wiluna
MKS41 140498
45
Table 22 Wiluna minimum temperature (degC)
Year Jan Feb Mar Apr May Jun Jul Aug Sept Oct Nov Dec
1975 ndash 23 203 15 94 63 71 62 103 124 169 205 1976 242 229 194 15 10 63 59 73 95 143 16 228 1977 243 25 197 148 96 95 56 86 102 ndash 188 23 1978 241 232 203 18 102 64 76 8 9 152 19 205 1979 255 226 216 167 83 6 59 79 97 145 198 223 1980 255 226 231 155 134 83 68 75 121 108 193 223 1981 245 216 19 182 119 6 54 78 138 159 163 218 1982 232 224 177 16 ndash ndash 37 111 112 164 209 225 1983 235 24 197 147 112 88 39 88 121 162 189 219 1984 241 243 191 156 ndash 72 66 7 95 161 182 211 1985 244 231 ndash 159 98 65 71 73 117 147 205 ndash 1986 ndash 229 226 155 93 96 43 49 10 122 ndash 219 1987 ndash 217 183 175 85 77 68 68 112 ndash ndash 221 1988 238 214 209 178 111 ndash ndash 86 104 157 171 195 1989 ndash 237 199 165 107 67 44 61 107 131 187 ndash 1990 232 ndash 211 155 118 62 57 87 102 149 195 22 1991 26 256 217 168 122 101 78 ndash 113 18 168 219 1992 227 227 214 169 102 98 59 69 ndash 125 159 196 1993 241 218 196 171 103 ndash 49 68 88 128 192 211 Mean 24 23 20 16 10 8 6 8 11 14 18 21
NOTE Dashes indicate data unavailable
JAN FEB MAR APR MAY JUN JUL AUG SEP OCT NOV DEC0
10
20
30
40
Month
MKS43 140498
50
Mean monthly minimum temperatures at Wiluna
Mea
n T
emp
erat
ure
(degC
)
46
Table 23 Wiluna maximum temperature (degC)
Year Jan Feb Mar Apr May Jun Jul Aug Sept Oct Nov Dec
1975 ndash 349 326 281 247 201 197 212 256 248 31 344 1976 374 369 346 297 248 206 208 225 265 287 313 388 1977 397 392 352 296 234 212 222 244 ndash 308 337 383 1978 378 345 346 316 242 195 176 205 231 295 334 356 1979 403 36 364 295 ndash ndash ndash 193 242 318 359 373 1980 392 342 377 275 24 176 179 233 292 288 349 391 1981 385 346 337 342 242 178 201 224 30 326 326 369 1982 372 359 315 307 ndash ndash 196 253 252 305 353 379 1983 381 389 327 272 263 222 187 248 287 321 336 366 1984 378 393 322 299 226 215 178 214 234 ndash 336 364 1985 40 366 ndash 294 224 216 205 212 284 307 355 ndash 1986 ndash 383 372 307 ndash 193 166 196 261 277 ndash 382 1987 ndash 339 328 305 21 202 214 218 275 ndash ndash 374 1988 388 365 353 301 23 ndash ndash 228 283 334 31 33 1989 ndash 375 339 285 238 179 181 219 275 298 336 ndash 1990 368 ndash 36 309 268 19 188 205 274 309 373 393 1991 414 416 363 315 268 206 21 ndash 279 338 332 368 1992 363 383 336 263 213 178 213 197 ndash 285 313 359 1993 396 357 344 301 221 ndash 197 215 253 294 347 362 Mean 39 37 34 30 24 20 20 22 27 30 34 37 NOTE Dashes indicate data unavailable
JAN FEB MAR APR MAY JUN JUL AUG SEP OCT NOV DEC0
10
20
30
40
Month
MKS42 140498
50
Mean monthly maximum temperatures at Wiluna
Mea
n T
emp
erat
ure
(degC
)
47
Appendix 3
Table 31 Summary of palynological results
Drillhole Depth (m) F no(a) GSWA no Lithology Formation Assemblage TAI(b)
BWB 1 74ndash75 F49668 135741 dark-grey siltstone basalt Jilyilli gt5 BWB 1 98ndash100 F49669 135742 dark-grey siltstone basalt Jilyilli gt5 BWB 1 121ndash122 F49670 135743 dark-grey siltstone basalt Jilyilli gt5 TWB 1 86ndash87 F49671 135631 dark-grey siltstone McFadden 3+ TWB 1 104ndash105 F49672 135632 dark-grey siltstone Cornelia 3+ TWB 1 121ndash122 F49673 135633 dark-grey siltstone Cornelia 4 TWB 2 14ndash15 F49674 135634 dark-grey siltstone Skates Hills 3+ TWB 6 49ndash50 F49675 135675 dark-grey siltstone Cornelia 1 3+ TWB 9 49ndash51 F49676 135704 dark-grey siltstone Brassey Range 1 3+ Trainor 1 37497- F49733 138939 black mudstone with Cornelia 5 37509 light-grey siltstone Trainor 1 3809 F49734 138940 dark-grey and black Cornelia 4- laminated mudstone Trainor 1 4170 F49735 138941 black unlaminated mudstone Cornelia 4- Trainor 1 4950 F49851 139501 dark-grey indurated siltstone Cornelia 5 Trainor 1 6032 F49852 139502 dark- and light-grey Cornelia 5 indurated siltstone Trainor 1 6434 F49853 139503 greenish indurated finely Cornelia 5 laminated siltstone LDDH 1 270 F49678 138934 dark-grey siltstone interbeds Waters 1 3+ in enterolithic evaporite Tarcunyah Gp LDDH 1 277 F49679 138935 dark-grey siltstone in cavity Waters 1 3+ in enterolithic evaporite Tarcunyah Gp
NOTES (a) GSWA Fossil Catalogue number (b) TAI = Thermal Alteration Index of Traverse (1988 plate 1)
48
Appendix 4
Savory Sub-basin quantitative magnetic and gravity interpretation (extracted from Cowan 1995)
Summary
A program of quantitative aeromagnetic interpretation has been completed on BMRAGSO data from the Savory Sub-
basin Western Australia Quantitative aeromagnetic interpretation utilized the 3D Euler deconvolution method
supported by wavenumber filtering and image processing The results have provided useful information on structural
trends and depth to magnetic sources in a structurally complex area Depth to magnetic source analysis has provided
information on intra-sedimentary magnetic sources as well as basement rocks
The results of the interpretation support previously identified depocentres However the presence of magnetic
sources at several levels makes it very difficult to produce a reliable magnetic basement depth contour map It is
considered more productive to work with the 3D Euler colour circle plots and images rather than trying to contour the
results It would be necessary to carry out a full-scale interpretation of the BMRAGSO profile data to improve on the
3D Euler results The regional gravity was found to be useful in interpreting the regional setting of the area although
the very wide data spacing limits quantitative use of the data The gravity data show quite a complex picture with
limited consistent correlation between gravity features and basin structures This suggests that gravity anomalies
reflect changes in density of the basement rocks rather than basement topography especially in the northern part of the
basin
It is recommended that the GSWA investigate access to company confidential high-resolution aeromagnetic data
prior to planning further aeromagnetic surveys Private companies have flown large parts of the northern half of the
area as part of their diamond exploration program Additional gravity coverage of the area may be more cost effective
than magnetic surveys as the gravity data provides more information on changes within the sedimentary section
Introduction
The main use of aeromagnetic data in petroleum exploration has been the determination of magnetic basement
topography although there has been increasing interest in analysis of intra-sedimentary magnetic anomalies
intrabasement and suprabasement magnetic anomalies These anomalies are used to determine depth to magnetic
basement rocks and hence determine the thickness of the sedimentary sequence Unfortunately interpretation of the
intrabasement and suprabasement magnetic anomalies is non-unique in terms of position and size of causative sources
because of the inherent ambiguity of potential-field methods However this ambiguity can be reduced by placing
49
constraints on source geometry and magnetization and by using geological and other geophysical data to constrain
the solution
Before 1970 most depth-determination techniques involved graphical determination of slopes of selected
magnetic anomalies and application of various empirical factors to convert the slopes into depth estimates Geological
Society of America Memoir 47 Interpretation of Aeromagnetic Maps by Vacquier et al (1951) was a landmark for
this type of interpretation
Automated interpretation procedures have played an increasingly important role in depth interpretation and a
wide range of techniques have been developed Many of these techniques are designed for application to located data
profiles and assume a two-dimensional geometry However there has been renewed interest in techniques applicable
to gridded data
Two distinct types of method can be recognized In the first case often described as discrete methods individual
isolated magnetic anomalies are interpreted and the results used to produce a map of basement relief In the second
case often described as continuous methods areas of data containing a number of anomalies are interpreted
statistically to produce direct output of basement depths
The discrete methods usually involve a semiautomatic initial phase which generates a large number of possible
depth solutions and an interactive second phase to screen and select acceptable solutions The advantage of this
approach is that the interpreter can select features that are relatively free from interference from adjacent anomalies
and consider all aspects of a particular magnetic anomaly The disadvantage is that interpretation can be very time
consuming as a wide range of depths are usually possible depending on the initial model chosen and a significant
amount of effort is needed to select the correct model In the case of the Savory Sub-basin dataset we encountered
problems in separating basement related effects from the effects of shallower intrasedimentary magnetic sources
Because of these problems we have concentrated on displaying the Euler results accompanied by separation filter
images of the data to show the shallower effects and deeper effects rather than trying to refine a 3D Euler
deconvolution depth-to-crystalline-basement contour
The continuous methods are very direct provided that the rather restrictive assumption can be made that all
anomalies are due to lateral magnetization changes due to basement topography This means that shallow effects and
large intrabasement anomalies must be removed from the data This involves judgement and skill as it is necessary to
distinguish between the lower amplitude suprabasement anomalies due to basement topography and the larger
intrabasement anomalies reflecting magnetization changes within the basement These methods were not considered
suitable for the Savory Sub-basin magnetic dataset but were used to invert the gravity data
50
Limitations of magnetic and gravity interpretation
Interpretation of the area is limited by a shortage of information on the nature and physical properties of the deeper
sedimentary sequence and the underlying basement rocks However using techniques such as cross-correlation of
gravity and pseudo-gravity data it is possible to try to differentiate between anomalies relating to basement and those
related to the sedimentary sequence
Gravity anomalies reflect changes within the sedimentary sequence as well as basement condition These
changes in density of sedimentary rocks produce gravity anomalies without a corresponding magnetic anomaly hence
the complementary nature of gravity and magnetic surveys The main use of magnetics is to determine depth to
magnetic basement and any intra-sedimentary volcanic rocks or intrusives whereas gravity provides much more
general information on the sedimentary sequence
Unfortunately interpretation of gravity anomalies is complicated since they can be due to a number of geological
features including
bull major basement faults
bull basement highs
bull igneous intrusions within the basement
bull sedimentary basins which may or may not be isostatically compensated
bull intra-sedimentary volcanics and associated plutonic centres
Two major problems affect the interpretation of both magnetic and gravity data
1 The inherent ambiguity of potential-field data There is no unique solution to any measured gravity or magnetic
anomaly and theoretically there will be an infinite number of source geometry and magnetizationdensity
combinations which will fit the observed data This means that any a priori information which helps to select a
suitable model is very useful
2 Measured anomalies are the summation of effects from different depths For example an observed gravity profile
may contain contributions from shallow sources (density variations within the sedimentary basin) intermediate
depth sources (density variations due to large igneous intrusions within the basement) and deep sources (crustal
thinning producing a mantle anomaly) Separation of these component responses is the regionalresidual problem
which we solve using spectral analysis and differential upward continuation-based separation filtering
Regional setting and interpretation overview
The area studied includes parts of BALFOUR DOWNS (SF51-9) RUDALL (SF51-10) ROBERTSON (SF51-13) GUNANYA
(SF51-14) COLLIER (SG50-4) BULLEN (SG51-1) TRAINOR (SG51-2) MADLEY (SG51-3) NABBERU (SG50-5)
STANLEY (SG51-6) and HERBERT (SG51-7) 1250 000 sheets Broadly the area lies between latitudes 22deg00rsquondash25deg30rsquoS
and longitudes 119deg30rsquondash123deg30rsquoE
51
Regional gravity
The AGSO regional gravity data (at nominal 11 km spacing) was gridded at a 4 km mesh spacing using a minimum-
curvature algorithm Bouguer gravity values in the area are negative reflecting mass deficiency at depth and range
from -84 mgals to -25 mgals
A Bouguer gravity colour image is shown as Figure 41 A residual grid was produced by removing a fifth-order
orthogonal polynomial from the Bouguer data but did not add to the interpretation
120deg 121deg 122deg 123deg
23deg
24deg
25deg
-25
-84
50 km
MKS46 180598
mgal
Figure 41 Regional Bouguer gravity (BMRAGSO data) gridded at 4 km
52
The data show a complex pattern of positive and negative anomalies with no clearly defined trends Correlations
with aeromagnetic data and known basin structures are poor A vague north-northwest linear trend appears to coincide
with the Marloo Fault (Figure 42) A prominent negative anomaly appears to coincide with the Blake Fold and Fault
Belt depocentre and continues as a narrower negative anomaly to the east until it widens out again near the edge of the
basin Elsewhere the gravity data show little correlation with known basin structures and it is likely that especially in
the north of the area gravity anomalies are due to density changes in the basement rather than changes in basement
topography
Production of wavelength-filtered residual gravity plots and vertical gradient plots showed very patchy aliased
data reflecting poor sampling in much of the area
Regional magnetics
The AGSO regional aeromagnetic data were gridded at a 400 m mesh spacing using a minimum-curvature algorithm
(Figure 43) Most of the data has a line spacing of 1600 m with small areas of 1 km spacing The quality of the data is
acceptable for regional interpretation but is not adequate for detailed analysis The accuracy of the flight path is rather
variable reflecting the vintage of the data and the noise envelope of the data is poor by modern standards Problems
were also encountered in joining different map sheets
The magnetic anomaly pattern over the south and west part of the area shows a strong high frequency signature
reflecting the presence of widespread basic sills and dykes Some of the major north-northeasterly trending dykes can
be traced over considerable distances
Discontinuous high-frequency anomalies extend as a northwest-trending zone through the centre of the area and
this zone includes a conspicuous circular magnetic anomaly which is probably a ring complex
The northern and eastern parts of the area are characterized by long-wavelength deep-seated basement magnetic
anomalies with 120deg and 150deg trends dominant The Marloo and Perentie Faults (Figure 42) appear as distinct linear
zones and offsets A prominent easterly trending negative anomaly in the northwest of the area appears to swing round
to the southeast and may separate different basement blocks One possible interpretation is that this very deep seated
anomaly separates areas of Archaean and Proterozoic basement
Regional geology
The regional geology is described in Williams (1992) The GSWA provided a digitized version of Plate 2 from this
Bulletin the structural interpretation map to use as an overlay (Figure 42)
53
Pp
Pp
PSd
PSd
PSd
PSd
PSd
PSo
PSt
PSt
PSf
PSf
PSf
PSb
PSb
PSb
PSsPSs
PSs
PSb
PSm
PSp
PSc
PSc
PSw
PSw
PSw
PSg
PSr
PSj
PSg
PM
Pk
PY
PY
PSd
L
L
L
L
L
L
L
LL
L
L
L
LL
L
LL
L L
LL
L L
L
L
L
L
L
L
L
LL
L
L
BLAKEDEPOCENTRE
MA
RLO
O
FAU
LT
PERENTIEFAULT
50 km
MKS39120598
120deg 121deg 122deg 123deg
25deg
24deg
23deg
Approximate boundaryof aeromagnetic interpretation
PML
PSgL
PSjL
PML
PSpL
PML
PML
PSfL
PSfL
PSpL
LPc
LPcLPcPSrL
LPA
Durba Sandstone
Woora Woora Formation
McFadden Formation
Tchukardine Formation
Boondawari Formation
Skates Hills Formation
Mundadjini Formation
Coondra Formation
Spearhole Formation
Watch Point Formation
Jilyili Formation
Brassey Range Formation
Glass Spring Formation
Paterson Formation
Yeneena Group
Karara Formation
Cornelia Formation
Kahrban Subgroup
Bangemall Group
Fault
Formation boundary
PSdL
PSoL
PSfL
PStL
PSbL
PSsL
PSmL
PScL
PSpL
PSwL
PSjL
PSrL
PSgL
Pp
PYL
PkL
LPc
LPA
PML
Savory Group Other Units
PYL
Figure 42 Regional geology and structure map (after Williams 1992)
54
120deg 121deg 122deg 123deg
23deg
24deg
25deg
5820
3750
MKS47 180598
nT
50 km
Figure 43 Regional aeromagnetic data total magnetic intensity (BMRAGSO data) gridded at 400 m
Analysis
3D analysis
3D Euler deconvolution was used as the primary depth-determination method The advantage of this approach is that
consistent solutions can be obtained over the entire area with minimal assumptions about source geometries Euler
deconvolution of gridded data is used for positional information and estimation of depth to top of source Euler
55
deconvolution yields a large number of depth solutions which have to be screened to reject spurious solutions Results
are plotted as circles in eight depth ranges with radius proportional to depth and colour coded
The 400 m total magnetic intensity grid was used for the analysis Horizontal gradients in x and y and the vertical
gradient were calculated 3D Euler deconvolution was tested on the 400 m gridded data using windows of 9 times 9 and
11 times 11 and 16 times 16 data points and structural indices 05 (fault) and 10 (sill or dyke) It was concluded that the
16 times 16 window produced the best results overall and final plots were produced for the 16 times 16 window and structural
index 05 (Fig 44) Results were very good over the northern and central parts of the area showing magnetic sources
Figure 44 Depth to magnetic source 3D Euler deconvolution 16 times 16 window of 400 m gridded data structural index 05
56
at several different levels Unfortunately in the extreme south of the area shallow intrasedimentary magnetic sources
(sills and dykes) dominated the inversion and the results contained few basement solutions
In order to reduce these problems the 400 m gridded data were filtered using a separation filter based on
interpretation of the log-energy spectrum The 3D Euler method was run on the filtered data in order to generate more
basement-depth solutions Results for the deep-separation filter data were gridded and presented as a colour image in
Cowan (1995) Attempts to grid the Euler output were unsatisfactory and it is considered safer to interpret the 3D
Euler depth plots The 3D Euler depth results from the separation-filter run should be analysed with care as perfect
separation of the basement can never be achieved and there will always be some contamination from sources at
different levels
The results of original total magnetic intensity 3D Euler depth estimation for structural index 05 using a 16 point
window have been plotted at 1500 000 scale (not included in this publication but available in Cowan (1995) from the
GSWA Library as S10331) and as reduced A4 colour circle plots (Figure 44)
The results of deep-basement 3D Euler depth estimation for structural index 05 using a 16 point window have
been plotted as a colour image at 1500 000 scale and as an A4 image (not included in this publication)
2D analysis
Two equispaced profiles were interpolated with a 50 m station interval from the AGSO-located data profiles for the
BULLEN 1250 000 sheet The interpolated profiles were analysed using 2D Euler deconvolution and Werner
deconvolution Results are included in Cowan (1995) and show the use of these methods for more detailed analysis
Filtered data
In order to reconcile 3D Euler results from shallow basement and intrasedimentary magnetic sources we produced
several separation-filtered maps and images We found the shallow-layer double-separation filter (Figure 45) to be
very effective for shallow sources and the deep-layer standard-separation filter (Figure 46) for the basement layer
Gravity and magnetic data correlation
Both lsquoreduced to the polersquo (RTP) magnetics (Figure 47) and pseudo-gravity data (Figure 48) were produced as part of
the reconciliation of gravity and magnetic signatures In both cases the filtering operations assumed magnetization by
induction in the present Earths field The RTP data are fairly similar to the total magnetic intensity The pseudo-
57
gravity data are dominated by a northwest-trending strong positive anomaly and there is little correlation with the
Bouguer gravity data
The poor magneticgravity correlation is confirmed by cross-correlation of the RTP magnetics and the gravity
gradient The correlation plot in Figure 49 shows little coherent response with numerous zones of positive and
negative correlation
Figure 45 Regional aeromagnetic data shallow layer separation filter (BMRAGSO data) gridded at 400 m
Results
In the north and east of the area on the Wells Foreland Sub-basin trend (refer to Figure 1 main text) we see a range
of quite deep 3D Euler depths and several trend directions with north-northwesterly dominant There are relatively few
shallow intrasedimentary solutions in this zone
The second area of deep 3D Euler solutions lies over the Blake depocentre (Figure 43) with several trend
directions
Elsewhere the 3D Euler results are dominated by shallow intrasedimentary depth solutions reflecting mainly the
dolerite sills dykes and the ring complex However where we do see basement-related solutions in the south and
west of the area they appear to be shallower than those noted for the Wells Foreland Sub-basin and the Blake
depocentre
58
Figure 46 Regional aeromagnetic data deep-layer separation filter (BMRAGSO data) gridded at 400 m
Figure 48 Regional aeromagnetic data pseudo-gravity transform (BMRAGSO data) gridded at 400 m
Figure 47 Regional aeromagnetic data reduced-to-pole (BMRAGSO data) gridded at 400 m
Figure 49 Regional aeromagnetic and gravity data gravitymagnetic correlation using RTP magnetics and gravity gradient (BMRAGSO data) gridded at 4 km
59
This subdivision of the area into two zones of deep solutions is consistent with interpreted depocentres
However the interference between sources at different levels and the complexity of the magnetic response of the
basement rocks precludes more refined interpretation at this stage
The area of deep 3D Euler solutions over the Blake depocentre correlates with the pronounced negative gravity
anomaly discussed in the gravity interpretation section Using a density contrast of -015 gcc the negative gravity
anomaly could indicate up to 6ndash8 km of low-density sedimentary rocks depending on assumptions about the regional
field
The area of deep 3D Euler solutions over the Wells Foreland Sub-basin has a complex gravity expression and no
clear basin structure emerges from inversion of these data As noted previously it is likely that observed gravity
anomalies reflect contrasts in basement density rather than basement topography
Separation filtering applied to the magnetic data helps to enhance the intrasedimentary magnetic signature and to
give a better impression of the basement magnetic signature even though separation of the basement response is not
perfect
Conclusions
Quantitative aeromagnetic interpretation using 3D Euler deconvolution supported by wavenumber filtering and image
processing has been successful in providing structural trend and depth information for the Savory Sub-basin
Quantitative magnetic interpretation has revealed two zones of relatively deep magnetic basement beneath the
Wells Foreland Sub-basin and the Blake depocentre
This analysis of the magnetic data supports interpreted depocentres but the complexity of the basement magnetic
signature and interference from sources at different depths precludes further refinement to a map of basement
topography
Regional gravity proved to be very useful in understanding the regional setting of the area and in providing
support for aspects of the interpretation The gravity data support the interpretation of the Blake depocentre
suggesting up to 6ndash8 km of low-density sedimentary rocks
The deep structure of the Savory Sub-basin area is obviously complex with different areas underlain by
Archaean and Proterozoic basement and with the Capricorn suture occurring in the centre of the area
60
Recommendations
The quantitative magnetic interpretation needs to be reconciled with geological models available for the area
In particular the zones tentatively identified as areas with thick sedimentary rocks the Wells Foreland Sub-
basin and the Blake depocentre need to be investigated
Cross sections should be prepared across the basin for joint magneticgravity modelling especially for the Blake
depocentre It is important to be able to explain the strong negative gravity anomaly in this area
In view of the effects of basement density contrasts on the gravity field for the northern part of the area we think
that additional gravity interpretation and acquisition of new gravity data may not be justified as they will not
contribute significantly to understanding basin evolution and structure
It is recommended that GSWA try to get access to company confidential high-resolution aeromagnetic data
rather than flying new surveys The GSWA might offer to fund flying of new infill areas as a bargaining point
References
The original text of this report by Cowan (1995) and 1500 000 scale maps are filed in the GSWA Library under
S10331
COWAN D 1995 Savory Basin quantitative magnetic interpretation Western Australia Geological Survey S-series
S10331 (unpublished)
VACQUIER V STEENLAND N C HENDERSON R G and ZIETZ I 1951 Interpretation of aeromagnetic
maps The Geological Society of America Memoir 47 151p
WILLIAMS I R 1992 Geology of the Savory Basin Western Australia Western Australia Geological Survey
Bulletin 141 115p
61
Appendix 5
Geochemistry
MKS38 250398
Saturate FractionC12+ GLC
1217
Pr18
Ph
22
31CSR WELL-13 315m Cuttings
Figure 51 Canning Stock Route Well 13 gas chromatograph of extract of auger drill sample
12
17
18
22
31
Pr Ph
LDDH 1 6623m CoreSaturate FractionC12+ GLC
MKS35 240398
Figure 52 Gas chromatograph of extract from core sample at 6623 m LDDH1
62
Table 51 Canning Stock Route Well 13 auger drill samples
GSWA sample Drill depth (m)(a) Comments
135601 150 At watertable 135602 203 (all samples consist 135603 310 of sand mud and water) 135604 315 At total depth
NOTE (a) Datum for drill depth is the top of sediment fill in the well which is 155 m below ground level (ie the total depth of 315 m is 47 m below ground level)
Table 52 Canning Stock Route Well 13 gas chromatography data for 315 m depth sediment sample
Parameter Value
Weight of rock extracted (grams) 945 Total extract (ppm) 519 n-Alkane distribution n-C12 07 n-C13 23 n-C14 26 n-C15 22 n-C16 19 n-C17 14 i-C19 23 n-C18 14 i-C20 08 n-C19 11 n-C20 16 n-C21 25 n-C22 29 n-C23 70 n-C24 42 n-C25 95 n-C26 43 n-C27 83 n-C28 38 n-C29 87 n-C30 31 n-C31 273 Alkane compositional data Pristane phytane ratio 279 Pristane n-C17 ratio 161 Phytane n-C18 ratio 059 CPI (1)(a) 284 CPI (2) 209 (C21 + C22) (C28 + C29) 043
NOTE (a) CPI= Carbon preference index
63
Table 53 LDDH1 extract liquid chromatography data for 6623 m concentration
Rock extracted Total extract (grams) (ppm)
702 313
NOTE ppm= parts per million
Table 54 LDDH1 saturate gas chromatography data of core for 6623 m alkane composition
Pristane Pristane Phytane (a) CPI (1) CPI (2) (C21+C22) Phytane n-C17 n-C18 (C28+C29)
103 026 024 103 102 325
NOTE (a)CPI = carbon preference index
Table 55 LDDH1 saturate gas chromatography data of core for 6623 m n-alkane distributions
Parameter Value
n-C12 17 n-C13 38 n-C14 55 n-C15 60 n-C16 65 n-C17 74 i-C19 19 n-C18 78 i-C20 19 n-C19 80 n-C20 79 n-C21 71 n-C22 64 n-C23 57 n-C25 43 n-C24 38 n-C27 31 n-C28 23 n-C29 19 n-C30 12 n-C31 10
64
Appendix 6
Table 61 Summary of data from Trainor waterbores (TWB) and Bullen waterbores (BWB)
Well AMG Elevation TD Status(b) Completion details Water Salinity Water level Flow rate Depth to consolidated AGD84 GL (m) (m) struck mgl(c) (m) (LHr) lithology aquifer(e) Z51(a) Interval (m) (100 mm PVC) (m) (mgl)(d)
TWB 1 473660E 453 122 comp 0ndash75 plain 63 7 300 24 2 880 12 m 7287404N 75ndash93 slotted (9 260) McFadden Fm 93ndash99 plain TWB 2 472 977E 475 23 abd nil 15 m 7285877N Skates Hills Fm dry TWB 3 473259E 475 50 abd nil 7 m 7285849N Skates Hills Fm dry TWB 4 463225 E 445 50 comp 0ndash22 plain 35 7 200 55 3 600 0 m 7286143N 22ndash34 slotted (8 140) Tertiary sand and gravel 23ndash60 plain TWB 5 463095E 445 31 comp 0ndash19 plain 13 26 000 655 3 600 Tertiary sand and gravel 7277721N 19ndash25 slotted (36 700) 25ndash31 plain TWB 6 457013E 455 50 comp 0ndash42 plain 38 920 119 600 0 m 7274352N 42ndash48 slotted (1 030) Cornelia Fm ss TWB 7 453739E 475 26 susp 0ndash2 plain 11 9 300 48 4 500 0 m 7263891N (10 500) Tertiary sand TWB 8 433893E 535 60 susp 0ndash2 plain 47 8 500 gt46 1 200 0 m 7245991N (10 900) Tertiary sand and Brassey Range Fm ss TWB 9 437219E 505 51 comp 0ndash47 plain 45 1 000 58 600 1 m 7235905N 47ndash51 slotted (990) Brassey Range Fm ss TWB 10 434927E 495 32 susp 0ndash2 plain 235 450 120 0 m 7225875N (500) Dolerite
65
BWB 1 287337E 580 122 abd Nil 1 m 7245861N Jilyili Fm dry BWB 2 288346E 545 50 comp 0ndash26 plain 15 630 3 29 000 0 m 7240423N 26ndash38 slotted (730) Tertiary sand and gravel 38ndash50 plain BWB 3 305637E 545 50 abd 19 8 800 43 7 200 0 m 7240423N (10 550) Tertiary ss BWB 4 320167E 515 445 comp 0ndash20 plain 9 980 445 24 000 0 m 7248097N 20ndash32 slotted (1 190) Tertiary ss 32ndash44 plain BWB 5 353393E 545 20 susp 0ndash2 plain 45 (970) 1 m 7238934N Basalt
NOTES (a) GPS accuracy ~ 150 m (b) Comp = completed abd = abandoned susp = suspended (c) Salinity from conductivity (d) Analysis total dissolved solids (e) Fm = Formation ss = sandstone
26
Cornelia Formation in Trainor 1 These data suggest that mudstones form a significant proportion
of strata in the sub-basin despite their limited outcrop
Traps
Potential structural closures including folds and faults occur at various scales throughout the
Savory Sub-basin However the region has only been mapped at 1250 000 scale and
independently closed structures such as domes have yet to be confirmed The western margin of
the basin contains abundant faults (with a northeast strike) but elsewhere faults are less common
Some anticlines are recognized in outcrop including one with a strike length of up to 45 km
inferred from surface bedding dips in the Mundadjini and Spearhole Formations at approximately
24deg15rsquoS 121deg10rsquoE on BULLEN (Fig 1)
Salt diapirs and other halokinetic structures are recognized in outcrop well and seismic data
in the Officer Basin to the west of the Savory Sub-basin and it is probable that there are
significant thicknesses of evaporitic sedimentary rocks in the sub-basin The gravity field data
suggest there is good potential for salt diapirs and traps related to halokinesis
Although there is potential for stratigraphic traps to be present in the sub-basin insufficient
data are available to assess them
Preservation of hydrocarbons
The range of thermal maturities measured to date and the large periods of time envisaged for
deposition of sediments implies hydrocarbon generation may have occurred a number of times
during the evolution of the Savory Sub-basin Any hydrocarbons that were generated early may
have been trapped in palaeostructures and remigration to younger traps could have taken place
later The Petermann Ranges Orogeny which has been equated with the Paterson Orogeny (Myers
1990) is believed to have occurred in the latest Neoproterozoic to early Cambrian This is the last
major tectonic event recognized in the sub-basin suggesting that it is reasonable to expect that trap
integrity will have been preserved
If the inference of the presence of thick halite beds in the sub-basin is correct the preservation
potential of sub-salt traps should be excellent
27
Reported hydrocarbon shows and oil seep
Amadeus Petroleum recorded minor oil shows in cores from Mundadjini 1 and Boondawari 1 In
Mundadjini 1 at 36102 m (top of the Spearhole Formation) a 3 mm thick zone had 10 moderate
white fluorescence with slow solvent cut This show was in a granular sandstone with visually
estimated porosity of about 10 In Boondawari 1 at 35364 m (within the Spearhole Formation) a
broken surface of sandstone had 40 moderate yellow-white fluorescence with slow solvent cut
Visually estimated porosity is about 5 Because the fluorescing surface was broken during the
drilling process this show could have resulted from contamination A second show occurs in
Boondawari 1 at 4963 m (within the Spearhole Formation) where a 1 cm-thick zone had 5 dull
yellow fluorescence with slow solvent cut in a conglomerate with visually estimated porosity of
about 10 The company intends to further investigate the nature of these occurrences
Minor bitumen is present at 6623 m in drillhole LDDH1 on GUNANYA (Figs 5 and 6) as a
vein in mudstones of the Tarcunyah Group A sample was analysed by gas chromatography
(Ghori in prep) and confirmed that it is natural bitumen (Appendix 5)
Mineral hole OD 23 drilled by Jubilee Gold Mines NL on NABBERU in the Bangemall Basin
immediately to the south of the Savory Sub-basin (Fig 5) encountered bitumen and trace oil in
vugs in dolomite (M Stevens unpublished data) but no further data are available at present
In their popular guide to the Canning Stock Route Gard and Gard (1990 p 218) refer to an
oil seep at Well 13 on TRAINOR (Fig 5) They reported that between 1977 and 1984 lsquonatural oilrsquo
was seen in the well Although the well is now largely filled with sediment four auger drill
samples were collected by the GSWA in 1995 and all four were analysed for oil shows One
sample from 315 m total depth (GSWA sample 135604) yielded just enough extract (519 ppm)
for saturate gas chromatography analysis The gas chromatograph (Appendix 5) shows that the
extract does contain some hydrocarbons probably from recent plant material Because the depth to
the oil was not quoted in Gard and Gard (1990) the hand-augered well may not have been deep
enough to properly test this reported seep
Geological and geophysical databases
Geological and geophysical data available for the Savory Sub-basin are limited The most recently
completed geological maps for the sub-basin were published by the GSWA between 1991 and
1995 (Williams and Tyler 1991 Williams 1992 1995ab)
28
The cores from the five drillholes listed in Table 2 believed to be all of the core available
from the sub-basin are available for inspection at GSWA Mineral exploration reports submitted
to GSWA may be searched using the WAMEX database and open-file reports are available on
microfiche Geophysical data acquired by the mining industry is not required to be filed with
GSWA if acquired over Vacant Crown Land which is the case for much of the sub-basin
Geophysical survey data submitted in mining tenement reports and which extend into Vacant
Crown Land remain confidential to the companies Original regional aeromagnetic and gravity
datasets are available from the Australian Geological Survey Organisation (AGSO)
Data pertinent to oil exploration in the sub-basin such as structural style and salt diapirism
are presented in a review of the hydrocarbon prospectivity of the Officer Basin (Perincek 1998)
Drilling
Significant drillholes in the sub-basin are summarized in Table 2
Petroleum industry data
Amadeus Petroleum drilled three petroleum exploration wells in the central west of the Savory
Sub-basin in late 1997 These wells Mundadjini 1 Boondawari 1 and Akubra 1 were drilled by
continuous diamond coring (Figs 5 and 6) All targeted potential reservoirs within the Spearhole
Formation with the Mundadjini Formation as the proposed seal The wells were located on
structures interpreted from Landsat images and limited geological investigations Both Mundadjini
1 and Boondawari 1 had minor oil shows as discussed above (Reported hydrocarbon shows)
Government data
Stratigraphic drillhole Trainor 1 was drilled by GSWA in 1995 (Stevens and Adamides in prep)
and the main results are discussed above (Source rocks and Maturity)
Mineral industry data
Normandy Exploration drillhole LDDH1 was cored in the Tarcunyah Group to a total depth of
701 m and provided source-rock and maturity data as discussed above
29
Oilmin NL drilled six percussion drillholes (BD 1 3 4 5 8 and 9) through sandstones and
shales in the northern part of the Savory Sub-basin to a maximum depth of 198 m (Fig 5
WAMEX Microfiche File M 26811 I 2610) but only brief geological descriptions are available
Hydrogeological data
Hydrogeological data within the Savory Sub-basin are limited although a long history of water
exploration extends back to the construction of the Canning Stock Route early this century No
detailed geological or wireline logs are available for the older wells along this route A few station
wells have been drilled by various methods on the south and west margins of the basin but data
are unavailable as reports are not required to be filed with the government Depth to watertable
throughout the basin is largely controlled by porosity of the bedrock
The GSWA drilled fifteen waterbores in the winter of 1995 in the southern part of the sub-
basin in preparation for the drilling of Trainor 1 and the proposed Bullen 1 Twelve bores found
water and six of these bores have salinities of less than 1000 mgL (Fig 5 Appendix 6 Table 61)
One waterbore TWB 6 has gamma ray and neutron logs run through PVC casing and these are
available from the GSWA with the digital log data included herein
Seismic data
No geophysical data have been acquired by the petroleum industry in the Savory Sub-basin
Seismic data acquired in the Officer Basin to the east particularly in the Gibson and Yowalga
Sub-basins is pertinent to structural interpretation in the Savory Sub-basin (Perincek 1996a
1998)
Aeromagnetic surveys
Government data
There are over 95 277 line kilometres of aeromagnetic data included in the AGSO dataset There
are three regional aeromagnetic surveys covering the Savory Sub-basin These were flown by the
Bureau of Mineral Resources (BMR now AGSO) in 1984 at a line spacing of 1500 m with 36 740
and 52 587 line kilometres flown and by Aerodata in 1984 at a line spacing of 1000m with 5950
line kilometres flown These data were reprocessed and interpreted for GSWA by Cowan (1995)
An edited copy of this report is included as Appendix 4 and the original report is filed in the
GSWA Library under S-series reports item 10331
30
Mineral industry data
The approximate locations of non-AGSO aeromagnetic surveys are shown in Figure 8 More
detailed information regarding the location of these surveys may be obtained using the GSWA
MAGCAT II database Additional information such as contours of aeromagnetic values may be
obtained by inspecting items on file with the GSWA
Gravity surveys
Government data
The average spacing for gravity data in the Savory Sub-basin is one station per 121 km2 (11 times 11
km grid) These data were principally collected by BMR in the early 1960s There are a few
additional regional gravity traverses across the sub-basin which are also included in the
BMRAGSO dataset These data were reprocessed and interpreted for GSWA (Fig 10) and a
report on this work is also included in Appendix 4
The GSWA completed a large semi-detailed gravity survey in the eastern Savory Sub-basin
utilizing helicopter support and Differential Global Positioning Survey (DGPS) techniques (Fig
8) This gravity survey completed in August 1995 consists of 2300 gravity stations on a 2 times 3 km
grid All stations were acquired by helicopter using Scintrex gravimeters and Ashtek dual
frequency DGPS equipment for determining location This highly efficient system allowed the
acquisition of more than 100 gravity stations per day in remote areas The resolution of this survey
is +30 cm and +05 microms-2 (Daishsat 1995) These data (Fig 11) represent a significant
improvement on the previous regional survey data and are available from GSWA (GSWA
1996ab) The results of the interpretation of these data were presented at the 1997 ASEG
Convention (Carlsen and Shevchenko 1997)
Mineral industry data
Three small gravity surveys were conducted by Oilmin NL (Fig 8) and the relevant WAMEX
reports are M 2681I 2610 I 2435 I 2567 These three surveys are of limited value because height
control was provided by barometers only and the surveys were not tied to the national gravity grid
31
23deg
25deg
120deg 122deg
Trainor 1
SAVORY
SUB-BASIN
MKS54 160498
100 km
1995 SavoryGravity Survey
254
-1056
micromsec2
Figure 10 Regional Bouguer gravity map of the Savory Sub-basin
23deg
24deg
25deg
122deg30 123deg
TRAINOR 1
123deg30
50 km
MKS53 160498
-116
-626
micro msec2
Figure11 Detailed Bouguer gravity map of the
Savory 1995 Gravity Survey from the eastern Savory Sub-basin
32
Government and academic reports
Chronostratigraphy and geochemistry
The understanding of Neoproterozoic organic chemistry palynology and structural evolution is
essential to the interpretation of hydrocarbon prospectivity Pertinent reports are included in the
bibliography (Appendix 1) Unpublished palaeontology reports describe the palynology of wells in
the Savory Sub-basin (Grey 1995andashe 1996a) Grey and Cotter (1996) discussed the potential for
Neoproterozoic palynomorphs to provide a biostratigraphic framework and palaeoenvironmental
interpretation Grey and Stevens (1997) reviewed the results of palynological studies of wells
drilled in the sub-basin and reported that Supersequence 1 palynomorphs are present in TWB 6
TWB 9 and LDDH1 (Appendix 3) Grey (1996b) reported on the use of stromatolites for
correlation in the Neoproterozoic and Stevens and Grey (1997) discussed the application of
stromatolite biostratigraphy in correlating isolated dolomite outcrops in the sub-basin with well
and seismic data in the Officer Basin and Centralian Superbasin
Although geochemical data from the Savory Sub-basin are very limited results mostly
confirm thermal maturities inferred from TAI for LDDH1 and Trainor 1 (Ghori in prep Stevens
and Adamides in prep) Those parts of the Officer Basin in Western Australia which lie to the
east of the Savory Sub-basin are sparsely drilled but Ghori (in prep) reports that most of the
Neoproterozoic succession presently lies within the oil-generative window However his study
has been unable to identify effective source-rock units and the source for oil shows Thin source
rocks are present in the Neoproterozoic in LDDH1 (Fig 9) and in three wells which lie to the east
and southeast of the Savory Sub-basin namely NJD 1 Kanpa 1A and Yowalga 3
Proposed work program
From the above limited information it is concluded that additional research on the hydrocarbon
potential of the sub-basin is justified and proposals are outlined below
bull Additional modelling of gravity and aeromagnetic data from the Savory Sub-basin is required
in light of the results from Trainor 1 and Boondawari 1 Trainor 1 showed that what appeared
to be a structurally simple area based on outcrop aeromagnetic and gravity data was in fact an
area of major structuring Boondawari 1 intersected a dolerite which is in good depth
agreement with aeromagnetic depth to source results showing this technique is useful in
detecting the depth to intrusive bodies
33
bull Additional data from mineral and petroleum exploration bores may become available and
analysis of samples from these wells should be undertaken and interpreted in the context of
their relevance to the Officer Basin
bull Stratigraphic coring in the Blake Fault and Fold Belt and in the Wells Foreland Sub-basin (Fig
1) targeting source rocks is considered essential to the continuing evaluation of the
hydrocarbon prospectivity of the Savory Sub-basin
bull Correlations using at least outcrop well and potential-field data should be prepared to link the
sub-basin with the better known parts of the Officer Basin to the east
bull Remapping is required to clarify boundary positions within the Cornelia Formation this may
resolve some of the current problems of the relationship between this unit and the rest of the
Savory Sub-basin
bull Further work is required to explain the Early Cambrian or Sturtian ages interpreted for the
Cornelia Formation from sedimentary zircon UndashPb dating in drillhole Trainor 1 The
determination of the age of the organically rich but overmature claystones in this well is
critical to assessing the hydrocarbon potential of the region
bull The thin dark mudstones intersected by Akubra 1 in the Mundadjini Formation warrant
geochemical analysis Analyses of the oil shows in Mundadjini 1 and Boondawari 1 are
currently being undertaken by Amadeus Petroleum
bull Geochemical analysis of hydrocarbons in the Bangemall Basin drillhole OD23 has been
performed by Jubilee Gold and the results will be reviewed when they are submitted to
GSWA The possibility of source rocks within the Bangemall Basin charging traps within the
Bangemall Basin and the overlying Savory Sub-basin requires further investigation
Conclusions
The Savory Sub-basin is a frontier region with only three recently drilled petroleum exploration
wells and no seismic data Based on existing geological and geophysical data it is considered too
early to draw conclusions about the hydrocarbon prospectivity of the sub-basin at this stage and
there are several reasons why the area warrants further investigation
34
1 Thick accumulations of sedimentary rocks are present (up to 8 km thickness inferred) which
may contain source reservoir and sealing strata
2 Minor oil shows occur in Mundadjini 1 and Boondawari 1 and bitumen is present in mineral
exploration drillhole LDDH1 suggesting that hydrocarbons have migrated within the
Neoproterozoic sequence of the Savory Sub-basin Oil and bitumen are present in mineral
exploration drillhole OD23 in the Bangemall Basin immediately to the south of the Savory
Sub-basin and it is possible that source rocks from the Bangemall Basin could charge traps in
the overlying Savory Sub-basin
3 The age of sedimentary rocks in the sub-basin is still poorly constrained but some of the
Neoproterozoic sedimentary rocks located on GUNANYA and TRAINOR are within the
hydrocarbon-generation window It is possible that a significant thickness of Phanerozoic
sedimentary rocks may also be present
4 Friable sandstones with visible porosity outcrop extensively suggesting numerous potential
reservoirs
5 Significant but not intense faulting and folding has been mapped implying large structural
traps may be present
6 Evaporitic sedimentary rocks occur in several formations and may provide good source rocks
and excellent seals
35
References
APAK S N and CARLSEN G M 1997 A compilation and review of data pertaining to the
hydrocarbon prospectivity of the Canning Basin Western Australia Geological Survey
Record 199610 103p
BAGAS L GREY K and WILLIAMS I R 1995 Reappraisal of the Paterson Orogen and
Savory Basin Western Australia Geological Survey Annual Review 1994ndash95 p 55ndash63
BUSBRIDGE M 1994 Lake Disappointment Exploration Licence 451064 Third Annual
Report Lake Disappointment Diamond Drill Hole LDDH1 Normandy Exploration Limited
Western Australia Geological Survey M-series Item 7567 A41358 (unpublished)
CARLSEN G M and SHEVCHENKO S I 1997 Petroleum exploration in Proterozoic basins
using potential fields data and stratigraphic coring Australian Society of Exploration
Geophysicists 12th Geophysical Conference Handbook Sydney 1997 Preview no 66 p 83
(abstract only)
COWAN D 1995 Savory Basin quantitative magnetic interpretation Western Australia
Geological Survey S-series S10331 (unpublished)
DAISHSAT PTY LTD 1995 Operational and processing report Savory Basin gravity survey
Western Australia Geological Survey S-series S10332 (unpublished)
GARD E and GARD R 1990 Canning Stock Route a travellerrsquos guide for a journey through
history Perth Western Australia Western Desert Guides 448p
GEOLOGICAL SURVEY OF WESTERN AUSTRALIA 1996a Savory Basin first vertical
derivative of Bouguer gravity image 1250 000 Western Australia Geological Survey
GEOLOGICAL SURVEY OF WESTERN AUSTRALIA 1996b Savory Basin Bouguer gravity
image 1250 000 Western Australia Geological Survey
GHORI K A R in prep Petroleum source rock potential and thermal history Officer Basin
Western Australia Western Australia Geological Survey Record
36
GREY K 1995a Savory Basin drillhole BWB 1 (Bullen waterbore) palynology and thermal
maturation GSWA Palaeontology Report no 199512 (unpublished)
GREY K 1995b Savory Basin drillholes TWB 1 2 6 9 (Trainor waterbores) palynology and
thermal maturation GSWA Palaeontology Report no 199520 (unpublished)
GREY K 1995c Palynology of Normandy-Poseidon Lake Disappointment-1 corehole
Tarcunyah Group Paterson Orogen GSWA Palaeontology Report no 199521 (unpublished)
GREY K 1995d Savory Basin drillhole Trainor 1 (Trainor diamond drilling) palynology and
thermal maturity GSWA Palaeontology Report no 199524 (unpublished)
GREY K 1995e Savory Basin drillhole Trainor 1 (Trainor diamond drilling) Additional
Preparation of two samples GSWA Palaeontology Report no 199528 (unpublished)
GREY K 1995f Neoproterozoic stromatolites from the Skates Hills Formation Savory Basin
Western Australia and a review of the distribution of Acaciella australica Australian Journal
of Earth Sciences v 42 p 123ndash132
GREY K 1996a Savory Basin drillhole Trainor 1 (Trainor diamond drilling) Additional
samples palynology and thermal maturation GSWA Palaeontology Report no 199615
(unpublished)
GREY K 1996b Preliminary stromatolite correlations for the Neoproterozoic of the Officer
Basin and a review of Australia-wide correlations GSWA Palaeontology Report no 199615
(unpublished)
GREY K and COTTER K L 1996 Palynology in the search for Proterozoic hydrocarbons
Western Australia Geological Survey Annual Review for 1995ndash96 p 70ndash80
GREY K and STEVENS M K 1997 Neoproterozoic palynomorphs of the Savory Sub-basin
Western Australia and their relevance to petroleum exploration Western Australia
Geological Survey Annual Review for 1996ndash97 p 49ndash54
HUBBARD R J PAPE J and ROBERTS D G 1985 Depositional sequence mapping as a
technique to establish tectonic and stratigraphic framework and evaluate hydrocarbon
potential on a passive continental margin in Seismic stratigraphy II an integrated approach
37
edited by O R BERG and D G WOOLVERTON American Association of Petroleum
Geologists Memoir 39 p 79ndash91
LIBBY WG 1995 A petrological report on six samples of bore cuttings from the Savory Basin
Western Australia Western Australia Geological Survey S-series S31307 (unpublished)
MORTON JGG and DREXEL JF 1997 The petroleum geology of South Australia Vol 3
Officer Basin South Australia Department of Mines and Energy Resources Report Book
9719
MUHLING P C and BRAKEL A T 1985 Geology of the Bangemall Group mdash the evolution
of an intracratonic Proterozoic basin Western Australia Geological Survey Bulletin 128
219p
MYERS J S 1990 Precambrian tectonic evolution of part of Gondwana southwestern Australia
Geology v18 p 537ndash540
NELSON D R 1997 Compilation of SHRIMP UndashPb zircon data Western Australia Geological
Survey Record 19972 196p
PAYTON C E 1977 Seismic stratigraphy mdash applications to hydrocarbon exploration
American Association of Petroleum Geologists Memoir 26 516p
PERINCEK D 1996a The age of NeoproterozoicndashPalaeozoic sediments within the Officer Basin
of the Centralian Super-basin can be constrained by major sequence-bounding unconformities
APPEA Journal v 36 pt 1 p 350ndash368
PERINCEK D 1996b The stratigraphic and structural development of the Officer Basin
Western Australia a review Western Australia Geological Survey Annual Review 1995ndash
1996 p 135ndash148
PERINCEK D 1998 A compilation and review of data pertaining to the hydrocarbon
prospectivity of the Officer Basin Western Australia Geological Survey Record 19976
POSAMENTIER H W JERSEY M T and VAIL P R 1988 Eustatic controls on clastic
deposition 1 mdash Conceptual framework in Sea-level changes an integrated approach edited by
C K WILGUS B S HASTINGS C G St C KENDALL H W POSAMENTIER
38
C A ROSS and J C VAN WAGONER Society of Economic Paleontologists and
Mineralogists Special Publication no 42
STEVENS M K and ADAMIDES N G in prep GSWA Trainor 1 well completion report
Savory Sub-basin Officer Basin Western Australia with notes on petroleum and mineral
potential Western Australia Geological Survey Record 199612
STEVENS M K and GREY K 1997 Skates Hills Formation and Tarcunyah Group Officer
Basin mdash carbonate cycles stratigraphic position and hydrocarbon prospectivity Western
Australia Geological Survey Annual Review for 1996ndash97 p 55ndash60
SUMMONS RE and POWELL C McA 1991 Petroleum source rocks of the Amadeus Basin
in Geological and geophysical studies in the Amadeus Basin central Australia edited by R J
KORSCH and JM KENNARD Australia BMR Geology and Geophysics Bulletin 236
TRAVERSE A 1988 Palaeopalynology Boston Unwin Hyman 600p
VAIL P R MITCHUM R M Jr TODD R G WIDMIER J M THOMPSON S III
SANGREE J B BUBB J N and HATLELID W G 1977 Seismic stratigraphy and
global changes of sea level in Seismic stratigraphy mdash applications to hydrocarbon
exploration edited by C E PAYTON American Association of Petroleum Geologists
Memoir 26 516p
WALTER M R and GORTER J 1994 The Neoproterozoic Centralian Superbasin in Western
Australia the Savory and Officer Basins in The sedimentary basins of Western Australia
edited by P G PURCELL and R R PURCELL Petroleum Exploration Society of Australia
Symposium Perth WA 1994 Proceedings p851ndash864
WALTER M R GREY K WILLIAMS I R and CALVER C R 1994 Stratigraphy of the
Neoproterozoic to early Palaeozoic Savory Basin and correlation with the Amadeus and
Officer Basins Australian Journal of Earth Sciences v 41 p 533ndash546
WALTER M R VEEVERS J J CALVER C R and GREY K 1995 Neoproterozoic
stratigraphy of the Centralian Superbasin Australia Precambrian Research v 73 p 173ndash195
WILLIAMS I R 1992 Geology of the Savory Basin Western Australia Western Australia
Geological Survey Bulletin 141 115p
39
WILLIAMS I R 1995a Bullen WA (2nd Edition) Western Australia Geological Survey
1250 000 Geological Series Explanatory Notes 23p
WILLIAMS I R 1995b Trainor WA (2nd Edition) Western Australia Geological Survey
1250 000 Geological Series Explanatory Notes 31p
WILLIAMS I R and TYLER I M 1991 Robertson WA (2nd edition) Western Australia
Geological Survey 1250 000 Geological Series Explanatory Notes 36p
40
41
Appendix 1
Bibliography
Reports which are relevant to this investigation but which are not specifically cited are listed
below
BAILLIE P W POWELL C McA LI Z X and RYALL A M 1994 The tectonic
framework of Western Australiarsquos Neoproterozoic to recent sedimentary basins in The
sedimentary basins of Western Australia edited by P G PURCELL and R R PURCELL
Petroleum Exploration Society of Australia Symposium Perth WA 1994 Proceedings p
45ndash62
BRADSHAW M T BRADSHAW J MURRAY A P NEEDHAM D J SPENCER L
SUMMONS R E WILMOT J and WINN S 1994 Petroleum systems in West Australian
basins in The sedimentary basins of Western Australia edited by P G PURCELL and R R
PURCELL Petroleum Exploration Society of Australia Symposium Perth WA 1994
Proceedings p 93ndash118
CLARKE G L 1991 Proterozoic tectonic reworking in the Rudall Complex Western Australia
Australian Journal of Earth Science v38 p 31ndash44
COCKBAIN A E and HOCKING R M 1990 Phanerozoic in Geology and mineral resources
of Western Australia Western Australia Geological Survey Memoir 3 p 750ndash755
ETHERIDGE M and WALL V 1994 Tectonic and structural evolution of the Australian
Proterozoic 12th Australian Geological Convention Geological Society of Australia
Abstracts no 37 p 102ndash103
GOODE A D T 1981 Proterozoic geology of Western Australia in Precambrian of the
Southern Hemisphere Developments in Precambrian geology 2 edited by I R HUNTER
Amsterdam Elsevier p 105ndash203
GREY K and JACKSON M J 1983 A re-assessment of stromatolite evidence for the
correlation of the Late Proterozoic Neale and Ilma Beds Officer Basin Western Australia
Australia BMR Journal of Australian Geology and Geophysics v 8 p 359
42
HICKMAN A H WILLIAMS I R and BAGAS L 1994 Proterozoic geology and
mineralization of the TelferndashRudall region Paterson Orogen Geological Society of Australia
(WA Division) Excursion Guidebook no 5 56p
HOCKING R M MORY A J and WILLIAMS I R 1994 An atlas of Neoproterozoic and
Phanerozoic basins of Western Australia in The sedimentary basins of Western Australia
edited by P G PURCELL and R R PURCELL Petroleum Exploration Society of Australia
Symposium Perth WA 1994 Proceedings p 21ndash 44
JACKSON P R 1966 Geology and review of exploration Officer Basin Western Australia
Hunt Oil Company Western Australia Geological Survey S-series S26 (unpublished)
JACKSON M J 1971 Notes on a geological reconnaissance of the Officer Basin Western
Australia Australia BMR Geology and Geophysics Record 19715 30p
JACKSON M J and van de GRAAFF W J E 1981 Geology of the Officer Basin Western
Australia Australia BMR Geology and Geophysics Bulletin 206 102 p
LOWRY D C JACKSON M J van de GRAAFF W J E and KENNEWELL P J 1971
Preliminary result of geological mapping in the Officer Basin Western Australia Western
Australia Geological Survey Annual Report for 1971 p 50ndash56
MYERS J S 1990 Precambrian in Geology and mineral resources of Western Australia
Western Australia Geological Survey Memoir 3 p 737ndash750
MYERS J S SHAW R D and TYLER I M 1994 Proterozoic tectonic evolution of
Australia 12th Australian Geological Convention Geological Society of Australia Abstracts
no 37 p 312
NEDIN C and JENKINS R J F 1991 Re-evaluation of unconformities separating the
lsquoEdiacaranrsquo and Cambrian systems South Australia Palaios v 6 p 102ndash108
PHILLIPS B J JAMES A W and PHILIP G M 1985 The geology and hydrocarbon
potential of the north-western Officer Basin APEA Journal 25 (1) p 52ndash61
POWELL C McA LI Z X McELHINNY M W MEERT J G and PARK J K 1993
Paleomagnetic constraints on timing of the Neoproterozoic breakup of Rodinia and Cambrian
formation of Gondwana Geology v 21 p 889ndash892
43
POWELL C McA PREISS W V GATEHOUSE C G KRAPEZ B and LI Z X 1994
South Australian record of a Rodinian epicontinental basin and its mid-Neoproterozoic
breakup to form the Palaeo-Pacific Ocean Tectonophysics v 237 no 3ndash4 p 113ndash140
PREISS W V 1976 Proterozoic stromatolites from the Nabberu and Officer Basins Western
Australia and their biostratigraphic significance South Australia Geological Survey Report
of Investigations no 47 p 1ndash51
TOWNSON W G 1985 The subsurface geology of the western Officer Basin mdash results of
Shellrsquos 1980ndash1984 petroleum exploration campaign APEA Journal v 25 (1) p 34ndash51
WATTS K J 1982 The geology of the Townsend Quartzite Upper Proterozoic shallow water
deposit of the Northern Officer Basin Western Australia Perth University of Western
Australia BSc honours thesis (unpublished)
WELLS A T and KENNEWELL P J 1974 Evaporite exploration in the Officer Basin
Western Australia at the Madley Diapirs Australia BMR Record 1974194 (unpublished)
WILLIAMS I R and MYERS J S 1990 Paterson Orogen in Geology and mineral resources
of Western Australia Western Australia Geological Survey Memoir 3 p 274ndash286
WILLIAMS I R 1990 Savory Basin in Geology and mineral resources of Western Australia
Western Australia Geological Survey Memoir 3 p 329ndash334
WILLIAMS I R 1994 The Neoproterozoic Savory Basin Western Australia in The
sedimentary basins of Western Australia edited by P G PURCELL and R R PURCELL
Petroleum Exploration Society of Australia Symposium Perth WA 1994 Proceedings p
841ndash850
WILSON R B 1967 Woolnough Hills and Madley diapiric structures Gibson Desert WA
APEA Journal v 7 p 94ndash102
44
Appendix 2
Meteorological data (from Bureau of Meteorology Perth 1994)
Table 21 Wiluna rainfall (mm)
Year Jan Feb Mar Apr May Jun Jul Aug Sept Oct Nov Dec
1975 0 45 446 309 306 59 276 4 34 886 638 164 1976 16 154 12 138 53 16 34 62 12 238 0 2 1977 44 0 66 74 68 95 24 363 1 58 12 727 1978 234 522 94 16 0 96 367 24 16 353 185 45 1979 19 173 122 88 91 4 0 246 58 0 169 114 1980 148 764 68 1081 259 626 629 06 56 02 174 0 1981 123 476 192 32 196 118 44 74 14 0 28 312 1982 374 705 206 244 1079 92 02 143 368 526 368 118 1983 1 112 928 248 0 212 56 32 5 1 42 496 1984 149 7 342 84 836 0 348 132 224 04 16 172 1985 596 483 0 166 556 0 514 56 0 0 4 0 1986 0 154 35 0 0 1085 23 01 239 137 0 04 1987 1204 119 19 89 17 575 154 126 07 1 0 398 1988 46 202 164 13 388 0 202 104 0 0 224 1309 1989 207 234 26 703 278 536 57 0 01 0 144 02 1990 1035 23 281 46 126 53 94 218 44 9 42 0 1991 48 0 41 45 0 472 297 12 0 1 0 7 1992 112 96 1025 1227 323 65 04 174 0 132 48 4 1993 0 697 0 202 445 0 12 306 18 05 14 33 Mean 25 35 22 27 27 25 18 12 6 13 13 21
JAN FEB MAR APR MAY JUN JUL AUG SEP OCT NOV DEC0
10
20
30
40
Mea
n R
ain
fall
(mm
)
Month
Mean monthly rainfall in Wiluna
MKS41 140498
45
Table 22 Wiluna minimum temperature (degC)
Year Jan Feb Mar Apr May Jun Jul Aug Sept Oct Nov Dec
1975 ndash 23 203 15 94 63 71 62 103 124 169 205 1976 242 229 194 15 10 63 59 73 95 143 16 228 1977 243 25 197 148 96 95 56 86 102 ndash 188 23 1978 241 232 203 18 102 64 76 8 9 152 19 205 1979 255 226 216 167 83 6 59 79 97 145 198 223 1980 255 226 231 155 134 83 68 75 121 108 193 223 1981 245 216 19 182 119 6 54 78 138 159 163 218 1982 232 224 177 16 ndash ndash 37 111 112 164 209 225 1983 235 24 197 147 112 88 39 88 121 162 189 219 1984 241 243 191 156 ndash 72 66 7 95 161 182 211 1985 244 231 ndash 159 98 65 71 73 117 147 205 ndash 1986 ndash 229 226 155 93 96 43 49 10 122 ndash 219 1987 ndash 217 183 175 85 77 68 68 112 ndash ndash 221 1988 238 214 209 178 111 ndash ndash 86 104 157 171 195 1989 ndash 237 199 165 107 67 44 61 107 131 187 ndash 1990 232 ndash 211 155 118 62 57 87 102 149 195 22 1991 26 256 217 168 122 101 78 ndash 113 18 168 219 1992 227 227 214 169 102 98 59 69 ndash 125 159 196 1993 241 218 196 171 103 ndash 49 68 88 128 192 211 Mean 24 23 20 16 10 8 6 8 11 14 18 21
NOTE Dashes indicate data unavailable
JAN FEB MAR APR MAY JUN JUL AUG SEP OCT NOV DEC0
10
20
30
40
Month
MKS43 140498
50
Mean monthly minimum temperatures at Wiluna
Mea
n T
emp
erat
ure
(degC
)
46
Table 23 Wiluna maximum temperature (degC)
Year Jan Feb Mar Apr May Jun Jul Aug Sept Oct Nov Dec
1975 ndash 349 326 281 247 201 197 212 256 248 31 344 1976 374 369 346 297 248 206 208 225 265 287 313 388 1977 397 392 352 296 234 212 222 244 ndash 308 337 383 1978 378 345 346 316 242 195 176 205 231 295 334 356 1979 403 36 364 295 ndash ndash ndash 193 242 318 359 373 1980 392 342 377 275 24 176 179 233 292 288 349 391 1981 385 346 337 342 242 178 201 224 30 326 326 369 1982 372 359 315 307 ndash ndash 196 253 252 305 353 379 1983 381 389 327 272 263 222 187 248 287 321 336 366 1984 378 393 322 299 226 215 178 214 234 ndash 336 364 1985 40 366 ndash 294 224 216 205 212 284 307 355 ndash 1986 ndash 383 372 307 ndash 193 166 196 261 277 ndash 382 1987 ndash 339 328 305 21 202 214 218 275 ndash ndash 374 1988 388 365 353 301 23 ndash ndash 228 283 334 31 33 1989 ndash 375 339 285 238 179 181 219 275 298 336 ndash 1990 368 ndash 36 309 268 19 188 205 274 309 373 393 1991 414 416 363 315 268 206 21 ndash 279 338 332 368 1992 363 383 336 263 213 178 213 197 ndash 285 313 359 1993 396 357 344 301 221 ndash 197 215 253 294 347 362 Mean 39 37 34 30 24 20 20 22 27 30 34 37 NOTE Dashes indicate data unavailable
JAN FEB MAR APR MAY JUN JUL AUG SEP OCT NOV DEC0
10
20
30
40
Month
MKS42 140498
50
Mean monthly maximum temperatures at Wiluna
Mea
n T
emp
erat
ure
(degC
)
47
Appendix 3
Table 31 Summary of palynological results
Drillhole Depth (m) F no(a) GSWA no Lithology Formation Assemblage TAI(b)
BWB 1 74ndash75 F49668 135741 dark-grey siltstone basalt Jilyilli gt5 BWB 1 98ndash100 F49669 135742 dark-grey siltstone basalt Jilyilli gt5 BWB 1 121ndash122 F49670 135743 dark-grey siltstone basalt Jilyilli gt5 TWB 1 86ndash87 F49671 135631 dark-grey siltstone McFadden 3+ TWB 1 104ndash105 F49672 135632 dark-grey siltstone Cornelia 3+ TWB 1 121ndash122 F49673 135633 dark-grey siltstone Cornelia 4 TWB 2 14ndash15 F49674 135634 dark-grey siltstone Skates Hills 3+ TWB 6 49ndash50 F49675 135675 dark-grey siltstone Cornelia 1 3+ TWB 9 49ndash51 F49676 135704 dark-grey siltstone Brassey Range 1 3+ Trainor 1 37497- F49733 138939 black mudstone with Cornelia 5 37509 light-grey siltstone Trainor 1 3809 F49734 138940 dark-grey and black Cornelia 4- laminated mudstone Trainor 1 4170 F49735 138941 black unlaminated mudstone Cornelia 4- Trainor 1 4950 F49851 139501 dark-grey indurated siltstone Cornelia 5 Trainor 1 6032 F49852 139502 dark- and light-grey Cornelia 5 indurated siltstone Trainor 1 6434 F49853 139503 greenish indurated finely Cornelia 5 laminated siltstone LDDH 1 270 F49678 138934 dark-grey siltstone interbeds Waters 1 3+ in enterolithic evaporite Tarcunyah Gp LDDH 1 277 F49679 138935 dark-grey siltstone in cavity Waters 1 3+ in enterolithic evaporite Tarcunyah Gp
NOTES (a) GSWA Fossil Catalogue number (b) TAI = Thermal Alteration Index of Traverse (1988 plate 1)
48
Appendix 4
Savory Sub-basin quantitative magnetic and gravity interpretation (extracted from Cowan 1995)
Summary
A program of quantitative aeromagnetic interpretation has been completed on BMRAGSO data from the Savory Sub-
basin Western Australia Quantitative aeromagnetic interpretation utilized the 3D Euler deconvolution method
supported by wavenumber filtering and image processing The results have provided useful information on structural
trends and depth to magnetic sources in a structurally complex area Depth to magnetic source analysis has provided
information on intra-sedimentary magnetic sources as well as basement rocks
The results of the interpretation support previously identified depocentres However the presence of magnetic
sources at several levels makes it very difficult to produce a reliable magnetic basement depth contour map It is
considered more productive to work with the 3D Euler colour circle plots and images rather than trying to contour the
results It would be necessary to carry out a full-scale interpretation of the BMRAGSO profile data to improve on the
3D Euler results The regional gravity was found to be useful in interpreting the regional setting of the area although
the very wide data spacing limits quantitative use of the data The gravity data show quite a complex picture with
limited consistent correlation between gravity features and basin structures This suggests that gravity anomalies
reflect changes in density of the basement rocks rather than basement topography especially in the northern part of the
basin
It is recommended that the GSWA investigate access to company confidential high-resolution aeromagnetic data
prior to planning further aeromagnetic surveys Private companies have flown large parts of the northern half of the
area as part of their diamond exploration program Additional gravity coverage of the area may be more cost effective
than magnetic surveys as the gravity data provides more information on changes within the sedimentary section
Introduction
The main use of aeromagnetic data in petroleum exploration has been the determination of magnetic basement
topography although there has been increasing interest in analysis of intra-sedimentary magnetic anomalies
intrabasement and suprabasement magnetic anomalies These anomalies are used to determine depth to magnetic
basement rocks and hence determine the thickness of the sedimentary sequence Unfortunately interpretation of the
intrabasement and suprabasement magnetic anomalies is non-unique in terms of position and size of causative sources
because of the inherent ambiguity of potential-field methods However this ambiguity can be reduced by placing
49
constraints on source geometry and magnetization and by using geological and other geophysical data to constrain
the solution
Before 1970 most depth-determination techniques involved graphical determination of slopes of selected
magnetic anomalies and application of various empirical factors to convert the slopes into depth estimates Geological
Society of America Memoir 47 Interpretation of Aeromagnetic Maps by Vacquier et al (1951) was a landmark for
this type of interpretation
Automated interpretation procedures have played an increasingly important role in depth interpretation and a
wide range of techniques have been developed Many of these techniques are designed for application to located data
profiles and assume a two-dimensional geometry However there has been renewed interest in techniques applicable
to gridded data
Two distinct types of method can be recognized In the first case often described as discrete methods individual
isolated magnetic anomalies are interpreted and the results used to produce a map of basement relief In the second
case often described as continuous methods areas of data containing a number of anomalies are interpreted
statistically to produce direct output of basement depths
The discrete methods usually involve a semiautomatic initial phase which generates a large number of possible
depth solutions and an interactive second phase to screen and select acceptable solutions The advantage of this
approach is that the interpreter can select features that are relatively free from interference from adjacent anomalies
and consider all aspects of a particular magnetic anomaly The disadvantage is that interpretation can be very time
consuming as a wide range of depths are usually possible depending on the initial model chosen and a significant
amount of effort is needed to select the correct model In the case of the Savory Sub-basin dataset we encountered
problems in separating basement related effects from the effects of shallower intrasedimentary magnetic sources
Because of these problems we have concentrated on displaying the Euler results accompanied by separation filter
images of the data to show the shallower effects and deeper effects rather than trying to refine a 3D Euler
deconvolution depth-to-crystalline-basement contour
The continuous methods are very direct provided that the rather restrictive assumption can be made that all
anomalies are due to lateral magnetization changes due to basement topography This means that shallow effects and
large intrabasement anomalies must be removed from the data This involves judgement and skill as it is necessary to
distinguish between the lower amplitude suprabasement anomalies due to basement topography and the larger
intrabasement anomalies reflecting magnetization changes within the basement These methods were not considered
suitable for the Savory Sub-basin magnetic dataset but were used to invert the gravity data
50
Limitations of magnetic and gravity interpretation
Interpretation of the area is limited by a shortage of information on the nature and physical properties of the deeper
sedimentary sequence and the underlying basement rocks However using techniques such as cross-correlation of
gravity and pseudo-gravity data it is possible to try to differentiate between anomalies relating to basement and those
related to the sedimentary sequence
Gravity anomalies reflect changes within the sedimentary sequence as well as basement condition These
changes in density of sedimentary rocks produce gravity anomalies without a corresponding magnetic anomaly hence
the complementary nature of gravity and magnetic surveys The main use of magnetics is to determine depth to
magnetic basement and any intra-sedimentary volcanic rocks or intrusives whereas gravity provides much more
general information on the sedimentary sequence
Unfortunately interpretation of gravity anomalies is complicated since they can be due to a number of geological
features including
bull major basement faults
bull basement highs
bull igneous intrusions within the basement
bull sedimentary basins which may or may not be isostatically compensated
bull intra-sedimentary volcanics and associated plutonic centres
Two major problems affect the interpretation of both magnetic and gravity data
1 The inherent ambiguity of potential-field data There is no unique solution to any measured gravity or magnetic
anomaly and theoretically there will be an infinite number of source geometry and magnetizationdensity
combinations which will fit the observed data This means that any a priori information which helps to select a
suitable model is very useful
2 Measured anomalies are the summation of effects from different depths For example an observed gravity profile
may contain contributions from shallow sources (density variations within the sedimentary basin) intermediate
depth sources (density variations due to large igneous intrusions within the basement) and deep sources (crustal
thinning producing a mantle anomaly) Separation of these component responses is the regionalresidual problem
which we solve using spectral analysis and differential upward continuation-based separation filtering
Regional setting and interpretation overview
The area studied includes parts of BALFOUR DOWNS (SF51-9) RUDALL (SF51-10) ROBERTSON (SF51-13) GUNANYA
(SF51-14) COLLIER (SG50-4) BULLEN (SG51-1) TRAINOR (SG51-2) MADLEY (SG51-3) NABBERU (SG50-5)
STANLEY (SG51-6) and HERBERT (SG51-7) 1250 000 sheets Broadly the area lies between latitudes 22deg00rsquondash25deg30rsquoS
and longitudes 119deg30rsquondash123deg30rsquoE
51
Regional gravity
The AGSO regional gravity data (at nominal 11 km spacing) was gridded at a 4 km mesh spacing using a minimum-
curvature algorithm Bouguer gravity values in the area are negative reflecting mass deficiency at depth and range
from -84 mgals to -25 mgals
A Bouguer gravity colour image is shown as Figure 41 A residual grid was produced by removing a fifth-order
orthogonal polynomial from the Bouguer data but did not add to the interpretation
120deg 121deg 122deg 123deg
23deg
24deg
25deg
-25
-84
50 km
MKS46 180598
mgal
Figure 41 Regional Bouguer gravity (BMRAGSO data) gridded at 4 km
52
The data show a complex pattern of positive and negative anomalies with no clearly defined trends Correlations
with aeromagnetic data and known basin structures are poor A vague north-northwest linear trend appears to coincide
with the Marloo Fault (Figure 42) A prominent negative anomaly appears to coincide with the Blake Fold and Fault
Belt depocentre and continues as a narrower negative anomaly to the east until it widens out again near the edge of the
basin Elsewhere the gravity data show little correlation with known basin structures and it is likely that especially in
the north of the area gravity anomalies are due to density changes in the basement rather than changes in basement
topography
Production of wavelength-filtered residual gravity plots and vertical gradient plots showed very patchy aliased
data reflecting poor sampling in much of the area
Regional magnetics
The AGSO regional aeromagnetic data were gridded at a 400 m mesh spacing using a minimum-curvature algorithm
(Figure 43) Most of the data has a line spacing of 1600 m with small areas of 1 km spacing The quality of the data is
acceptable for regional interpretation but is not adequate for detailed analysis The accuracy of the flight path is rather
variable reflecting the vintage of the data and the noise envelope of the data is poor by modern standards Problems
were also encountered in joining different map sheets
The magnetic anomaly pattern over the south and west part of the area shows a strong high frequency signature
reflecting the presence of widespread basic sills and dykes Some of the major north-northeasterly trending dykes can
be traced over considerable distances
Discontinuous high-frequency anomalies extend as a northwest-trending zone through the centre of the area and
this zone includes a conspicuous circular magnetic anomaly which is probably a ring complex
The northern and eastern parts of the area are characterized by long-wavelength deep-seated basement magnetic
anomalies with 120deg and 150deg trends dominant The Marloo and Perentie Faults (Figure 42) appear as distinct linear
zones and offsets A prominent easterly trending negative anomaly in the northwest of the area appears to swing round
to the southeast and may separate different basement blocks One possible interpretation is that this very deep seated
anomaly separates areas of Archaean and Proterozoic basement
Regional geology
The regional geology is described in Williams (1992) The GSWA provided a digitized version of Plate 2 from this
Bulletin the structural interpretation map to use as an overlay (Figure 42)
53
Pp
Pp
PSd
PSd
PSd
PSd
PSd
PSo
PSt
PSt
PSf
PSf
PSf
PSb
PSb
PSb
PSsPSs
PSs
PSb
PSm
PSp
PSc
PSc
PSw
PSw
PSw
PSg
PSr
PSj
PSg
PM
Pk
PY
PY
PSd
L
L
L
L
L
L
L
LL
L
L
L
LL
L
LL
L L
LL
L L
L
L
L
L
L
L
L
LL
L
L
BLAKEDEPOCENTRE
MA
RLO
O
FAU
LT
PERENTIEFAULT
50 km
MKS39120598
120deg 121deg 122deg 123deg
25deg
24deg
23deg
Approximate boundaryof aeromagnetic interpretation
PML
PSgL
PSjL
PML
PSpL
PML
PML
PSfL
PSfL
PSpL
LPc
LPcLPcPSrL
LPA
Durba Sandstone
Woora Woora Formation
McFadden Formation
Tchukardine Formation
Boondawari Formation
Skates Hills Formation
Mundadjini Formation
Coondra Formation
Spearhole Formation
Watch Point Formation
Jilyili Formation
Brassey Range Formation
Glass Spring Formation
Paterson Formation
Yeneena Group
Karara Formation
Cornelia Formation
Kahrban Subgroup
Bangemall Group
Fault
Formation boundary
PSdL
PSoL
PSfL
PStL
PSbL
PSsL
PSmL
PScL
PSpL
PSwL
PSjL
PSrL
PSgL
Pp
PYL
PkL
LPc
LPA
PML
Savory Group Other Units
PYL
Figure 42 Regional geology and structure map (after Williams 1992)
54
120deg 121deg 122deg 123deg
23deg
24deg
25deg
5820
3750
MKS47 180598
nT
50 km
Figure 43 Regional aeromagnetic data total magnetic intensity (BMRAGSO data) gridded at 400 m
Analysis
3D analysis
3D Euler deconvolution was used as the primary depth-determination method The advantage of this approach is that
consistent solutions can be obtained over the entire area with minimal assumptions about source geometries Euler
deconvolution of gridded data is used for positional information and estimation of depth to top of source Euler
55
deconvolution yields a large number of depth solutions which have to be screened to reject spurious solutions Results
are plotted as circles in eight depth ranges with radius proportional to depth and colour coded
The 400 m total magnetic intensity grid was used for the analysis Horizontal gradients in x and y and the vertical
gradient were calculated 3D Euler deconvolution was tested on the 400 m gridded data using windows of 9 times 9 and
11 times 11 and 16 times 16 data points and structural indices 05 (fault) and 10 (sill or dyke) It was concluded that the
16 times 16 window produced the best results overall and final plots were produced for the 16 times 16 window and structural
index 05 (Fig 44) Results were very good over the northern and central parts of the area showing magnetic sources
Figure 44 Depth to magnetic source 3D Euler deconvolution 16 times 16 window of 400 m gridded data structural index 05
56
at several different levels Unfortunately in the extreme south of the area shallow intrasedimentary magnetic sources
(sills and dykes) dominated the inversion and the results contained few basement solutions
In order to reduce these problems the 400 m gridded data were filtered using a separation filter based on
interpretation of the log-energy spectrum The 3D Euler method was run on the filtered data in order to generate more
basement-depth solutions Results for the deep-separation filter data were gridded and presented as a colour image in
Cowan (1995) Attempts to grid the Euler output were unsatisfactory and it is considered safer to interpret the 3D
Euler depth plots The 3D Euler depth results from the separation-filter run should be analysed with care as perfect
separation of the basement can never be achieved and there will always be some contamination from sources at
different levels
The results of original total magnetic intensity 3D Euler depth estimation for structural index 05 using a 16 point
window have been plotted at 1500 000 scale (not included in this publication but available in Cowan (1995) from the
GSWA Library as S10331) and as reduced A4 colour circle plots (Figure 44)
The results of deep-basement 3D Euler depth estimation for structural index 05 using a 16 point window have
been plotted as a colour image at 1500 000 scale and as an A4 image (not included in this publication)
2D analysis
Two equispaced profiles were interpolated with a 50 m station interval from the AGSO-located data profiles for the
BULLEN 1250 000 sheet The interpolated profiles were analysed using 2D Euler deconvolution and Werner
deconvolution Results are included in Cowan (1995) and show the use of these methods for more detailed analysis
Filtered data
In order to reconcile 3D Euler results from shallow basement and intrasedimentary magnetic sources we produced
several separation-filtered maps and images We found the shallow-layer double-separation filter (Figure 45) to be
very effective for shallow sources and the deep-layer standard-separation filter (Figure 46) for the basement layer
Gravity and magnetic data correlation
Both lsquoreduced to the polersquo (RTP) magnetics (Figure 47) and pseudo-gravity data (Figure 48) were produced as part of
the reconciliation of gravity and magnetic signatures In both cases the filtering operations assumed magnetization by
induction in the present Earths field The RTP data are fairly similar to the total magnetic intensity The pseudo-
57
gravity data are dominated by a northwest-trending strong positive anomaly and there is little correlation with the
Bouguer gravity data
The poor magneticgravity correlation is confirmed by cross-correlation of the RTP magnetics and the gravity
gradient The correlation plot in Figure 49 shows little coherent response with numerous zones of positive and
negative correlation
Figure 45 Regional aeromagnetic data shallow layer separation filter (BMRAGSO data) gridded at 400 m
Results
In the north and east of the area on the Wells Foreland Sub-basin trend (refer to Figure 1 main text) we see a range
of quite deep 3D Euler depths and several trend directions with north-northwesterly dominant There are relatively few
shallow intrasedimentary solutions in this zone
The second area of deep 3D Euler solutions lies over the Blake depocentre (Figure 43) with several trend
directions
Elsewhere the 3D Euler results are dominated by shallow intrasedimentary depth solutions reflecting mainly the
dolerite sills dykes and the ring complex However where we do see basement-related solutions in the south and
west of the area they appear to be shallower than those noted for the Wells Foreland Sub-basin and the Blake
depocentre
58
Figure 46 Regional aeromagnetic data deep-layer separation filter (BMRAGSO data) gridded at 400 m
Figure 48 Regional aeromagnetic data pseudo-gravity transform (BMRAGSO data) gridded at 400 m
Figure 47 Regional aeromagnetic data reduced-to-pole (BMRAGSO data) gridded at 400 m
Figure 49 Regional aeromagnetic and gravity data gravitymagnetic correlation using RTP magnetics and gravity gradient (BMRAGSO data) gridded at 4 km
59
This subdivision of the area into two zones of deep solutions is consistent with interpreted depocentres
However the interference between sources at different levels and the complexity of the magnetic response of the
basement rocks precludes more refined interpretation at this stage
The area of deep 3D Euler solutions over the Blake depocentre correlates with the pronounced negative gravity
anomaly discussed in the gravity interpretation section Using a density contrast of -015 gcc the negative gravity
anomaly could indicate up to 6ndash8 km of low-density sedimentary rocks depending on assumptions about the regional
field
The area of deep 3D Euler solutions over the Wells Foreland Sub-basin has a complex gravity expression and no
clear basin structure emerges from inversion of these data As noted previously it is likely that observed gravity
anomalies reflect contrasts in basement density rather than basement topography
Separation filtering applied to the magnetic data helps to enhance the intrasedimentary magnetic signature and to
give a better impression of the basement magnetic signature even though separation of the basement response is not
perfect
Conclusions
Quantitative aeromagnetic interpretation using 3D Euler deconvolution supported by wavenumber filtering and image
processing has been successful in providing structural trend and depth information for the Savory Sub-basin
Quantitative magnetic interpretation has revealed two zones of relatively deep magnetic basement beneath the
Wells Foreland Sub-basin and the Blake depocentre
This analysis of the magnetic data supports interpreted depocentres but the complexity of the basement magnetic
signature and interference from sources at different depths precludes further refinement to a map of basement
topography
Regional gravity proved to be very useful in understanding the regional setting of the area and in providing
support for aspects of the interpretation The gravity data support the interpretation of the Blake depocentre
suggesting up to 6ndash8 km of low-density sedimentary rocks
The deep structure of the Savory Sub-basin area is obviously complex with different areas underlain by
Archaean and Proterozoic basement and with the Capricorn suture occurring in the centre of the area
60
Recommendations
The quantitative magnetic interpretation needs to be reconciled with geological models available for the area
In particular the zones tentatively identified as areas with thick sedimentary rocks the Wells Foreland Sub-
basin and the Blake depocentre need to be investigated
Cross sections should be prepared across the basin for joint magneticgravity modelling especially for the Blake
depocentre It is important to be able to explain the strong negative gravity anomaly in this area
In view of the effects of basement density contrasts on the gravity field for the northern part of the area we think
that additional gravity interpretation and acquisition of new gravity data may not be justified as they will not
contribute significantly to understanding basin evolution and structure
It is recommended that GSWA try to get access to company confidential high-resolution aeromagnetic data
rather than flying new surveys The GSWA might offer to fund flying of new infill areas as a bargaining point
References
The original text of this report by Cowan (1995) and 1500 000 scale maps are filed in the GSWA Library under
S10331
COWAN D 1995 Savory Basin quantitative magnetic interpretation Western Australia Geological Survey S-series
S10331 (unpublished)
VACQUIER V STEENLAND N C HENDERSON R G and ZIETZ I 1951 Interpretation of aeromagnetic
maps The Geological Society of America Memoir 47 151p
WILLIAMS I R 1992 Geology of the Savory Basin Western Australia Western Australia Geological Survey
Bulletin 141 115p
61
Appendix 5
Geochemistry
MKS38 250398
Saturate FractionC12+ GLC
1217
Pr18
Ph
22
31CSR WELL-13 315m Cuttings
Figure 51 Canning Stock Route Well 13 gas chromatograph of extract of auger drill sample
12
17
18
22
31
Pr Ph
LDDH 1 6623m CoreSaturate FractionC12+ GLC
MKS35 240398
Figure 52 Gas chromatograph of extract from core sample at 6623 m LDDH1
62
Table 51 Canning Stock Route Well 13 auger drill samples
GSWA sample Drill depth (m)(a) Comments
135601 150 At watertable 135602 203 (all samples consist 135603 310 of sand mud and water) 135604 315 At total depth
NOTE (a) Datum for drill depth is the top of sediment fill in the well which is 155 m below ground level (ie the total depth of 315 m is 47 m below ground level)
Table 52 Canning Stock Route Well 13 gas chromatography data for 315 m depth sediment sample
Parameter Value
Weight of rock extracted (grams) 945 Total extract (ppm) 519 n-Alkane distribution n-C12 07 n-C13 23 n-C14 26 n-C15 22 n-C16 19 n-C17 14 i-C19 23 n-C18 14 i-C20 08 n-C19 11 n-C20 16 n-C21 25 n-C22 29 n-C23 70 n-C24 42 n-C25 95 n-C26 43 n-C27 83 n-C28 38 n-C29 87 n-C30 31 n-C31 273 Alkane compositional data Pristane phytane ratio 279 Pristane n-C17 ratio 161 Phytane n-C18 ratio 059 CPI (1)(a) 284 CPI (2) 209 (C21 + C22) (C28 + C29) 043
NOTE (a) CPI= Carbon preference index
63
Table 53 LDDH1 extract liquid chromatography data for 6623 m concentration
Rock extracted Total extract (grams) (ppm)
702 313
NOTE ppm= parts per million
Table 54 LDDH1 saturate gas chromatography data of core for 6623 m alkane composition
Pristane Pristane Phytane (a) CPI (1) CPI (2) (C21+C22) Phytane n-C17 n-C18 (C28+C29)
103 026 024 103 102 325
NOTE (a)CPI = carbon preference index
Table 55 LDDH1 saturate gas chromatography data of core for 6623 m n-alkane distributions
Parameter Value
n-C12 17 n-C13 38 n-C14 55 n-C15 60 n-C16 65 n-C17 74 i-C19 19 n-C18 78 i-C20 19 n-C19 80 n-C20 79 n-C21 71 n-C22 64 n-C23 57 n-C25 43 n-C24 38 n-C27 31 n-C28 23 n-C29 19 n-C30 12 n-C31 10
64
Appendix 6
Table 61 Summary of data from Trainor waterbores (TWB) and Bullen waterbores (BWB)
Well AMG Elevation TD Status(b) Completion details Water Salinity Water level Flow rate Depth to consolidated AGD84 GL (m) (m) struck mgl(c) (m) (LHr) lithology aquifer(e) Z51(a) Interval (m) (100 mm PVC) (m) (mgl)(d)
TWB 1 473660E 453 122 comp 0ndash75 plain 63 7 300 24 2 880 12 m 7287404N 75ndash93 slotted (9 260) McFadden Fm 93ndash99 plain TWB 2 472 977E 475 23 abd nil 15 m 7285877N Skates Hills Fm dry TWB 3 473259E 475 50 abd nil 7 m 7285849N Skates Hills Fm dry TWB 4 463225 E 445 50 comp 0ndash22 plain 35 7 200 55 3 600 0 m 7286143N 22ndash34 slotted (8 140) Tertiary sand and gravel 23ndash60 plain TWB 5 463095E 445 31 comp 0ndash19 plain 13 26 000 655 3 600 Tertiary sand and gravel 7277721N 19ndash25 slotted (36 700) 25ndash31 plain TWB 6 457013E 455 50 comp 0ndash42 plain 38 920 119 600 0 m 7274352N 42ndash48 slotted (1 030) Cornelia Fm ss TWB 7 453739E 475 26 susp 0ndash2 plain 11 9 300 48 4 500 0 m 7263891N (10 500) Tertiary sand TWB 8 433893E 535 60 susp 0ndash2 plain 47 8 500 gt46 1 200 0 m 7245991N (10 900) Tertiary sand and Brassey Range Fm ss TWB 9 437219E 505 51 comp 0ndash47 plain 45 1 000 58 600 1 m 7235905N 47ndash51 slotted (990) Brassey Range Fm ss TWB 10 434927E 495 32 susp 0ndash2 plain 235 450 120 0 m 7225875N (500) Dolerite
65
BWB 1 287337E 580 122 abd Nil 1 m 7245861N Jilyili Fm dry BWB 2 288346E 545 50 comp 0ndash26 plain 15 630 3 29 000 0 m 7240423N 26ndash38 slotted (730) Tertiary sand and gravel 38ndash50 plain BWB 3 305637E 545 50 abd 19 8 800 43 7 200 0 m 7240423N (10 550) Tertiary ss BWB 4 320167E 515 445 comp 0ndash20 plain 9 980 445 24 000 0 m 7248097N 20ndash32 slotted (1 190) Tertiary ss 32ndash44 plain BWB 5 353393E 545 20 susp 0ndash2 plain 45 (970) 1 m 7238934N Basalt
NOTES (a) GPS accuracy ~ 150 m (b) Comp = completed abd = abandoned susp = suspended (c) Salinity from conductivity (d) Analysis total dissolved solids (e) Fm = Formation ss = sandstone
27
Reported hydrocarbon shows and oil seep
Amadeus Petroleum recorded minor oil shows in cores from Mundadjini 1 and Boondawari 1 In
Mundadjini 1 at 36102 m (top of the Spearhole Formation) a 3 mm thick zone had 10 moderate
white fluorescence with slow solvent cut This show was in a granular sandstone with visually
estimated porosity of about 10 In Boondawari 1 at 35364 m (within the Spearhole Formation) a
broken surface of sandstone had 40 moderate yellow-white fluorescence with slow solvent cut
Visually estimated porosity is about 5 Because the fluorescing surface was broken during the
drilling process this show could have resulted from contamination A second show occurs in
Boondawari 1 at 4963 m (within the Spearhole Formation) where a 1 cm-thick zone had 5 dull
yellow fluorescence with slow solvent cut in a conglomerate with visually estimated porosity of
about 10 The company intends to further investigate the nature of these occurrences
Minor bitumen is present at 6623 m in drillhole LDDH1 on GUNANYA (Figs 5 and 6) as a
vein in mudstones of the Tarcunyah Group A sample was analysed by gas chromatography
(Ghori in prep) and confirmed that it is natural bitumen (Appendix 5)
Mineral hole OD 23 drilled by Jubilee Gold Mines NL on NABBERU in the Bangemall Basin
immediately to the south of the Savory Sub-basin (Fig 5) encountered bitumen and trace oil in
vugs in dolomite (M Stevens unpublished data) but no further data are available at present
In their popular guide to the Canning Stock Route Gard and Gard (1990 p 218) refer to an
oil seep at Well 13 on TRAINOR (Fig 5) They reported that between 1977 and 1984 lsquonatural oilrsquo
was seen in the well Although the well is now largely filled with sediment four auger drill
samples were collected by the GSWA in 1995 and all four were analysed for oil shows One
sample from 315 m total depth (GSWA sample 135604) yielded just enough extract (519 ppm)
for saturate gas chromatography analysis The gas chromatograph (Appendix 5) shows that the
extract does contain some hydrocarbons probably from recent plant material Because the depth to
the oil was not quoted in Gard and Gard (1990) the hand-augered well may not have been deep
enough to properly test this reported seep
Geological and geophysical databases
Geological and geophysical data available for the Savory Sub-basin are limited The most recently
completed geological maps for the sub-basin were published by the GSWA between 1991 and
1995 (Williams and Tyler 1991 Williams 1992 1995ab)
28
The cores from the five drillholes listed in Table 2 believed to be all of the core available
from the sub-basin are available for inspection at GSWA Mineral exploration reports submitted
to GSWA may be searched using the WAMEX database and open-file reports are available on
microfiche Geophysical data acquired by the mining industry is not required to be filed with
GSWA if acquired over Vacant Crown Land which is the case for much of the sub-basin
Geophysical survey data submitted in mining tenement reports and which extend into Vacant
Crown Land remain confidential to the companies Original regional aeromagnetic and gravity
datasets are available from the Australian Geological Survey Organisation (AGSO)
Data pertinent to oil exploration in the sub-basin such as structural style and salt diapirism
are presented in a review of the hydrocarbon prospectivity of the Officer Basin (Perincek 1998)
Drilling
Significant drillholes in the sub-basin are summarized in Table 2
Petroleum industry data
Amadeus Petroleum drilled three petroleum exploration wells in the central west of the Savory
Sub-basin in late 1997 These wells Mundadjini 1 Boondawari 1 and Akubra 1 were drilled by
continuous diamond coring (Figs 5 and 6) All targeted potential reservoirs within the Spearhole
Formation with the Mundadjini Formation as the proposed seal The wells were located on
structures interpreted from Landsat images and limited geological investigations Both Mundadjini
1 and Boondawari 1 had minor oil shows as discussed above (Reported hydrocarbon shows)
Government data
Stratigraphic drillhole Trainor 1 was drilled by GSWA in 1995 (Stevens and Adamides in prep)
and the main results are discussed above (Source rocks and Maturity)
Mineral industry data
Normandy Exploration drillhole LDDH1 was cored in the Tarcunyah Group to a total depth of
701 m and provided source-rock and maturity data as discussed above
29
Oilmin NL drilled six percussion drillholes (BD 1 3 4 5 8 and 9) through sandstones and
shales in the northern part of the Savory Sub-basin to a maximum depth of 198 m (Fig 5
WAMEX Microfiche File M 26811 I 2610) but only brief geological descriptions are available
Hydrogeological data
Hydrogeological data within the Savory Sub-basin are limited although a long history of water
exploration extends back to the construction of the Canning Stock Route early this century No
detailed geological or wireline logs are available for the older wells along this route A few station
wells have been drilled by various methods on the south and west margins of the basin but data
are unavailable as reports are not required to be filed with the government Depth to watertable
throughout the basin is largely controlled by porosity of the bedrock
The GSWA drilled fifteen waterbores in the winter of 1995 in the southern part of the sub-
basin in preparation for the drilling of Trainor 1 and the proposed Bullen 1 Twelve bores found
water and six of these bores have salinities of less than 1000 mgL (Fig 5 Appendix 6 Table 61)
One waterbore TWB 6 has gamma ray and neutron logs run through PVC casing and these are
available from the GSWA with the digital log data included herein
Seismic data
No geophysical data have been acquired by the petroleum industry in the Savory Sub-basin
Seismic data acquired in the Officer Basin to the east particularly in the Gibson and Yowalga
Sub-basins is pertinent to structural interpretation in the Savory Sub-basin (Perincek 1996a
1998)
Aeromagnetic surveys
Government data
There are over 95 277 line kilometres of aeromagnetic data included in the AGSO dataset There
are three regional aeromagnetic surveys covering the Savory Sub-basin These were flown by the
Bureau of Mineral Resources (BMR now AGSO) in 1984 at a line spacing of 1500 m with 36 740
and 52 587 line kilometres flown and by Aerodata in 1984 at a line spacing of 1000m with 5950
line kilometres flown These data were reprocessed and interpreted for GSWA by Cowan (1995)
An edited copy of this report is included as Appendix 4 and the original report is filed in the
GSWA Library under S-series reports item 10331
30
Mineral industry data
The approximate locations of non-AGSO aeromagnetic surveys are shown in Figure 8 More
detailed information regarding the location of these surveys may be obtained using the GSWA
MAGCAT II database Additional information such as contours of aeromagnetic values may be
obtained by inspecting items on file with the GSWA
Gravity surveys
Government data
The average spacing for gravity data in the Savory Sub-basin is one station per 121 km2 (11 times 11
km grid) These data were principally collected by BMR in the early 1960s There are a few
additional regional gravity traverses across the sub-basin which are also included in the
BMRAGSO dataset These data were reprocessed and interpreted for GSWA (Fig 10) and a
report on this work is also included in Appendix 4
The GSWA completed a large semi-detailed gravity survey in the eastern Savory Sub-basin
utilizing helicopter support and Differential Global Positioning Survey (DGPS) techniques (Fig
8) This gravity survey completed in August 1995 consists of 2300 gravity stations on a 2 times 3 km
grid All stations were acquired by helicopter using Scintrex gravimeters and Ashtek dual
frequency DGPS equipment for determining location This highly efficient system allowed the
acquisition of more than 100 gravity stations per day in remote areas The resolution of this survey
is +30 cm and +05 microms-2 (Daishsat 1995) These data (Fig 11) represent a significant
improvement on the previous regional survey data and are available from GSWA (GSWA
1996ab) The results of the interpretation of these data were presented at the 1997 ASEG
Convention (Carlsen and Shevchenko 1997)
Mineral industry data
Three small gravity surveys were conducted by Oilmin NL (Fig 8) and the relevant WAMEX
reports are M 2681I 2610 I 2435 I 2567 These three surveys are of limited value because height
control was provided by barometers only and the surveys were not tied to the national gravity grid
31
23deg
25deg
120deg 122deg
Trainor 1
SAVORY
SUB-BASIN
MKS54 160498
100 km
1995 SavoryGravity Survey
254
-1056
micromsec2
Figure 10 Regional Bouguer gravity map of the Savory Sub-basin
23deg
24deg
25deg
122deg30 123deg
TRAINOR 1
123deg30
50 km
MKS53 160498
-116
-626
micro msec2
Figure11 Detailed Bouguer gravity map of the
Savory 1995 Gravity Survey from the eastern Savory Sub-basin
32
Government and academic reports
Chronostratigraphy and geochemistry
The understanding of Neoproterozoic organic chemistry palynology and structural evolution is
essential to the interpretation of hydrocarbon prospectivity Pertinent reports are included in the
bibliography (Appendix 1) Unpublished palaeontology reports describe the palynology of wells in
the Savory Sub-basin (Grey 1995andashe 1996a) Grey and Cotter (1996) discussed the potential for
Neoproterozoic palynomorphs to provide a biostratigraphic framework and palaeoenvironmental
interpretation Grey and Stevens (1997) reviewed the results of palynological studies of wells
drilled in the sub-basin and reported that Supersequence 1 palynomorphs are present in TWB 6
TWB 9 and LDDH1 (Appendix 3) Grey (1996b) reported on the use of stromatolites for
correlation in the Neoproterozoic and Stevens and Grey (1997) discussed the application of
stromatolite biostratigraphy in correlating isolated dolomite outcrops in the sub-basin with well
and seismic data in the Officer Basin and Centralian Superbasin
Although geochemical data from the Savory Sub-basin are very limited results mostly
confirm thermal maturities inferred from TAI for LDDH1 and Trainor 1 (Ghori in prep Stevens
and Adamides in prep) Those parts of the Officer Basin in Western Australia which lie to the
east of the Savory Sub-basin are sparsely drilled but Ghori (in prep) reports that most of the
Neoproterozoic succession presently lies within the oil-generative window However his study
has been unable to identify effective source-rock units and the source for oil shows Thin source
rocks are present in the Neoproterozoic in LDDH1 (Fig 9) and in three wells which lie to the east
and southeast of the Savory Sub-basin namely NJD 1 Kanpa 1A and Yowalga 3
Proposed work program
From the above limited information it is concluded that additional research on the hydrocarbon
potential of the sub-basin is justified and proposals are outlined below
bull Additional modelling of gravity and aeromagnetic data from the Savory Sub-basin is required
in light of the results from Trainor 1 and Boondawari 1 Trainor 1 showed that what appeared
to be a structurally simple area based on outcrop aeromagnetic and gravity data was in fact an
area of major structuring Boondawari 1 intersected a dolerite which is in good depth
agreement with aeromagnetic depth to source results showing this technique is useful in
detecting the depth to intrusive bodies
33
bull Additional data from mineral and petroleum exploration bores may become available and
analysis of samples from these wells should be undertaken and interpreted in the context of
their relevance to the Officer Basin
bull Stratigraphic coring in the Blake Fault and Fold Belt and in the Wells Foreland Sub-basin (Fig
1) targeting source rocks is considered essential to the continuing evaluation of the
hydrocarbon prospectivity of the Savory Sub-basin
bull Correlations using at least outcrop well and potential-field data should be prepared to link the
sub-basin with the better known parts of the Officer Basin to the east
bull Remapping is required to clarify boundary positions within the Cornelia Formation this may
resolve some of the current problems of the relationship between this unit and the rest of the
Savory Sub-basin
bull Further work is required to explain the Early Cambrian or Sturtian ages interpreted for the
Cornelia Formation from sedimentary zircon UndashPb dating in drillhole Trainor 1 The
determination of the age of the organically rich but overmature claystones in this well is
critical to assessing the hydrocarbon potential of the region
bull The thin dark mudstones intersected by Akubra 1 in the Mundadjini Formation warrant
geochemical analysis Analyses of the oil shows in Mundadjini 1 and Boondawari 1 are
currently being undertaken by Amadeus Petroleum
bull Geochemical analysis of hydrocarbons in the Bangemall Basin drillhole OD23 has been
performed by Jubilee Gold and the results will be reviewed when they are submitted to
GSWA The possibility of source rocks within the Bangemall Basin charging traps within the
Bangemall Basin and the overlying Savory Sub-basin requires further investigation
Conclusions
The Savory Sub-basin is a frontier region with only three recently drilled petroleum exploration
wells and no seismic data Based on existing geological and geophysical data it is considered too
early to draw conclusions about the hydrocarbon prospectivity of the sub-basin at this stage and
there are several reasons why the area warrants further investigation
34
1 Thick accumulations of sedimentary rocks are present (up to 8 km thickness inferred) which
may contain source reservoir and sealing strata
2 Minor oil shows occur in Mundadjini 1 and Boondawari 1 and bitumen is present in mineral
exploration drillhole LDDH1 suggesting that hydrocarbons have migrated within the
Neoproterozoic sequence of the Savory Sub-basin Oil and bitumen are present in mineral
exploration drillhole OD23 in the Bangemall Basin immediately to the south of the Savory
Sub-basin and it is possible that source rocks from the Bangemall Basin could charge traps in
the overlying Savory Sub-basin
3 The age of sedimentary rocks in the sub-basin is still poorly constrained but some of the
Neoproterozoic sedimentary rocks located on GUNANYA and TRAINOR are within the
hydrocarbon-generation window It is possible that a significant thickness of Phanerozoic
sedimentary rocks may also be present
4 Friable sandstones with visible porosity outcrop extensively suggesting numerous potential
reservoirs
5 Significant but not intense faulting and folding has been mapped implying large structural
traps may be present
6 Evaporitic sedimentary rocks occur in several formations and may provide good source rocks
and excellent seals
35
References
APAK S N and CARLSEN G M 1997 A compilation and review of data pertaining to the
hydrocarbon prospectivity of the Canning Basin Western Australia Geological Survey
Record 199610 103p
BAGAS L GREY K and WILLIAMS I R 1995 Reappraisal of the Paterson Orogen and
Savory Basin Western Australia Geological Survey Annual Review 1994ndash95 p 55ndash63
BUSBRIDGE M 1994 Lake Disappointment Exploration Licence 451064 Third Annual
Report Lake Disappointment Diamond Drill Hole LDDH1 Normandy Exploration Limited
Western Australia Geological Survey M-series Item 7567 A41358 (unpublished)
CARLSEN G M and SHEVCHENKO S I 1997 Petroleum exploration in Proterozoic basins
using potential fields data and stratigraphic coring Australian Society of Exploration
Geophysicists 12th Geophysical Conference Handbook Sydney 1997 Preview no 66 p 83
(abstract only)
COWAN D 1995 Savory Basin quantitative magnetic interpretation Western Australia
Geological Survey S-series S10331 (unpublished)
DAISHSAT PTY LTD 1995 Operational and processing report Savory Basin gravity survey
Western Australia Geological Survey S-series S10332 (unpublished)
GARD E and GARD R 1990 Canning Stock Route a travellerrsquos guide for a journey through
history Perth Western Australia Western Desert Guides 448p
GEOLOGICAL SURVEY OF WESTERN AUSTRALIA 1996a Savory Basin first vertical
derivative of Bouguer gravity image 1250 000 Western Australia Geological Survey
GEOLOGICAL SURVEY OF WESTERN AUSTRALIA 1996b Savory Basin Bouguer gravity
image 1250 000 Western Australia Geological Survey
GHORI K A R in prep Petroleum source rock potential and thermal history Officer Basin
Western Australia Western Australia Geological Survey Record
36
GREY K 1995a Savory Basin drillhole BWB 1 (Bullen waterbore) palynology and thermal
maturation GSWA Palaeontology Report no 199512 (unpublished)
GREY K 1995b Savory Basin drillholes TWB 1 2 6 9 (Trainor waterbores) palynology and
thermal maturation GSWA Palaeontology Report no 199520 (unpublished)
GREY K 1995c Palynology of Normandy-Poseidon Lake Disappointment-1 corehole
Tarcunyah Group Paterson Orogen GSWA Palaeontology Report no 199521 (unpublished)
GREY K 1995d Savory Basin drillhole Trainor 1 (Trainor diamond drilling) palynology and
thermal maturity GSWA Palaeontology Report no 199524 (unpublished)
GREY K 1995e Savory Basin drillhole Trainor 1 (Trainor diamond drilling) Additional
Preparation of two samples GSWA Palaeontology Report no 199528 (unpublished)
GREY K 1995f Neoproterozoic stromatolites from the Skates Hills Formation Savory Basin
Western Australia and a review of the distribution of Acaciella australica Australian Journal
of Earth Sciences v 42 p 123ndash132
GREY K 1996a Savory Basin drillhole Trainor 1 (Trainor diamond drilling) Additional
samples palynology and thermal maturation GSWA Palaeontology Report no 199615
(unpublished)
GREY K 1996b Preliminary stromatolite correlations for the Neoproterozoic of the Officer
Basin and a review of Australia-wide correlations GSWA Palaeontology Report no 199615
(unpublished)
GREY K and COTTER K L 1996 Palynology in the search for Proterozoic hydrocarbons
Western Australia Geological Survey Annual Review for 1995ndash96 p 70ndash80
GREY K and STEVENS M K 1997 Neoproterozoic palynomorphs of the Savory Sub-basin
Western Australia and their relevance to petroleum exploration Western Australia
Geological Survey Annual Review for 1996ndash97 p 49ndash54
HUBBARD R J PAPE J and ROBERTS D G 1985 Depositional sequence mapping as a
technique to establish tectonic and stratigraphic framework and evaluate hydrocarbon
potential on a passive continental margin in Seismic stratigraphy II an integrated approach
37
edited by O R BERG and D G WOOLVERTON American Association of Petroleum
Geologists Memoir 39 p 79ndash91
LIBBY WG 1995 A petrological report on six samples of bore cuttings from the Savory Basin
Western Australia Western Australia Geological Survey S-series S31307 (unpublished)
MORTON JGG and DREXEL JF 1997 The petroleum geology of South Australia Vol 3
Officer Basin South Australia Department of Mines and Energy Resources Report Book
9719
MUHLING P C and BRAKEL A T 1985 Geology of the Bangemall Group mdash the evolution
of an intracratonic Proterozoic basin Western Australia Geological Survey Bulletin 128
219p
MYERS J S 1990 Precambrian tectonic evolution of part of Gondwana southwestern Australia
Geology v18 p 537ndash540
NELSON D R 1997 Compilation of SHRIMP UndashPb zircon data Western Australia Geological
Survey Record 19972 196p
PAYTON C E 1977 Seismic stratigraphy mdash applications to hydrocarbon exploration
American Association of Petroleum Geologists Memoir 26 516p
PERINCEK D 1996a The age of NeoproterozoicndashPalaeozoic sediments within the Officer Basin
of the Centralian Super-basin can be constrained by major sequence-bounding unconformities
APPEA Journal v 36 pt 1 p 350ndash368
PERINCEK D 1996b The stratigraphic and structural development of the Officer Basin
Western Australia a review Western Australia Geological Survey Annual Review 1995ndash
1996 p 135ndash148
PERINCEK D 1998 A compilation and review of data pertaining to the hydrocarbon
prospectivity of the Officer Basin Western Australia Geological Survey Record 19976
POSAMENTIER H W JERSEY M T and VAIL P R 1988 Eustatic controls on clastic
deposition 1 mdash Conceptual framework in Sea-level changes an integrated approach edited by
C K WILGUS B S HASTINGS C G St C KENDALL H W POSAMENTIER
38
C A ROSS and J C VAN WAGONER Society of Economic Paleontologists and
Mineralogists Special Publication no 42
STEVENS M K and ADAMIDES N G in prep GSWA Trainor 1 well completion report
Savory Sub-basin Officer Basin Western Australia with notes on petroleum and mineral
potential Western Australia Geological Survey Record 199612
STEVENS M K and GREY K 1997 Skates Hills Formation and Tarcunyah Group Officer
Basin mdash carbonate cycles stratigraphic position and hydrocarbon prospectivity Western
Australia Geological Survey Annual Review for 1996ndash97 p 55ndash60
SUMMONS RE and POWELL C McA 1991 Petroleum source rocks of the Amadeus Basin
in Geological and geophysical studies in the Amadeus Basin central Australia edited by R J
KORSCH and JM KENNARD Australia BMR Geology and Geophysics Bulletin 236
TRAVERSE A 1988 Palaeopalynology Boston Unwin Hyman 600p
VAIL P R MITCHUM R M Jr TODD R G WIDMIER J M THOMPSON S III
SANGREE J B BUBB J N and HATLELID W G 1977 Seismic stratigraphy and
global changes of sea level in Seismic stratigraphy mdash applications to hydrocarbon
exploration edited by C E PAYTON American Association of Petroleum Geologists
Memoir 26 516p
WALTER M R and GORTER J 1994 The Neoproterozoic Centralian Superbasin in Western
Australia the Savory and Officer Basins in The sedimentary basins of Western Australia
edited by P G PURCELL and R R PURCELL Petroleum Exploration Society of Australia
Symposium Perth WA 1994 Proceedings p851ndash864
WALTER M R GREY K WILLIAMS I R and CALVER C R 1994 Stratigraphy of the
Neoproterozoic to early Palaeozoic Savory Basin and correlation with the Amadeus and
Officer Basins Australian Journal of Earth Sciences v 41 p 533ndash546
WALTER M R VEEVERS J J CALVER C R and GREY K 1995 Neoproterozoic
stratigraphy of the Centralian Superbasin Australia Precambrian Research v 73 p 173ndash195
WILLIAMS I R 1992 Geology of the Savory Basin Western Australia Western Australia
Geological Survey Bulletin 141 115p
39
WILLIAMS I R 1995a Bullen WA (2nd Edition) Western Australia Geological Survey
1250 000 Geological Series Explanatory Notes 23p
WILLIAMS I R 1995b Trainor WA (2nd Edition) Western Australia Geological Survey
1250 000 Geological Series Explanatory Notes 31p
WILLIAMS I R and TYLER I M 1991 Robertson WA (2nd edition) Western Australia
Geological Survey 1250 000 Geological Series Explanatory Notes 36p
40
41
Appendix 1
Bibliography
Reports which are relevant to this investigation but which are not specifically cited are listed
below
BAILLIE P W POWELL C McA LI Z X and RYALL A M 1994 The tectonic
framework of Western Australiarsquos Neoproterozoic to recent sedimentary basins in The
sedimentary basins of Western Australia edited by P G PURCELL and R R PURCELL
Petroleum Exploration Society of Australia Symposium Perth WA 1994 Proceedings p
45ndash62
BRADSHAW M T BRADSHAW J MURRAY A P NEEDHAM D J SPENCER L
SUMMONS R E WILMOT J and WINN S 1994 Petroleum systems in West Australian
basins in The sedimentary basins of Western Australia edited by P G PURCELL and R R
PURCELL Petroleum Exploration Society of Australia Symposium Perth WA 1994
Proceedings p 93ndash118
CLARKE G L 1991 Proterozoic tectonic reworking in the Rudall Complex Western Australia
Australian Journal of Earth Science v38 p 31ndash44
COCKBAIN A E and HOCKING R M 1990 Phanerozoic in Geology and mineral resources
of Western Australia Western Australia Geological Survey Memoir 3 p 750ndash755
ETHERIDGE M and WALL V 1994 Tectonic and structural evolution of the Australian
Proterozoic 12th Australian Geological Convention Geological Society of Australia
Abstracts no 37 p 102ndash103
GOODE A D T 1981 Proterozoic geology of Western Australia in Precambrian of the
Southern Hemisphere Developments in Precambrian geology 2 edited by I R HUNTER
Amsterdam Elsevier p 105ndash203
GREY K and JACKSON M J 1983 A re-assessment of stromatolite evidence for the
correlation of the Late Proterozoic Neale and Ilma Beds Officer Basin Western Australia
Australia BMR Journal of Australian Geology and Geophysics v 8 p 359
42
HICKMAN A H WILLIAMS I R and BAGAS L 1994 Proterozoic geology and
mineralization of the TelferndashRudall region Paterson Orogen Geological Society of Australia
(WA Division) Excursion Guidebook no 5 56p
HOCKING R M MORY A J and WILLIAMS I R 1994 An atlas of Neoproterozoic and
Phanerozoic basins of Western Australia in The sedimentary basins of Western Australia
edited by P G PURCELL and R R PURCELL Petroleum Exploration Society of Australia
Symposium Perth WA 1994 Proceedings p 21ndash 44
JACKSON P R 1966 Geology and review of exploration Officer Basin Western Australia
Hunt Oil Company Western Australia Geological Survey S-series S26 (unpublished)
JACKSON M J 1971 Notes on a geological reconnaissance of the Officer Basin Western
Australia Australia BMR Geology and Geophysics Record 19715 30p
JACKSON M J and van de GRAAFF W J E 1981 Geology of the Officer Basin Western
Australia Australia BMR Geology and Geophysics Bulletin 206 102 p
LOWRY D C JACKSON M J van de GRAAFF W J E and KENNEWELL P J 1971
Preliminary result of geological mapping in the Officer Basin Western Australia Western
Australia Geological Survey Annual Report for 1971 p 50ndash56
MYERS J S 1990 Precambrian in Geology and mineral resources of Western Australia
Western Australia Geological Survey Memoir 3 p 737ndash750
MYERS J S SHAW R D and TYLER I M 1994 Proterozoic tectonic evolution of
Australia 12th Australian Geological Convention Geological Society of Australia Abstracts
no 37 p 312
NEDIN C and JENKINS R J F 1991 Re-evaluation of unconformities separating the
lsquoEdiacaranrsquo and Cambrian systems South Australia Palaios v 6 p 102ndash108
PHILLIPS B J JAMES A W and PHILIP G M 1985 The geology and hydrocarbon
potential of the north-western Officer Basin APEA Journal 25 (1) p 52ndash61
POWELL C McA LI Z X McELHINNY M W MEERT J G and PARK J K 1993
Paleomagnetic constraints on timing of the Neoproterozoic breakup of Rodinia and Cambrian
formation of Gondwana Geology v 21 p 889ndash892
43
POWELL C McA PREISS W V GATEHOUSE C G KRAPEZ B and LI Z X 1994
South Australian record of a Rodinian epicontinental basin and its mid-Neoproterozoic
breakup to form the Palaeo-Pacific Ocean Tectonophysics v 237 no 3ndash4 p 113ndash140
PREISS W V 1976 Proterozoic stromatolites from the Nabberu and Officer Basins Western
Australia and their biostratigraphic significance South Australia Geological Survey Report
of Investigations no 47 p 1ndash51
TOWNSON W G 1985 The subsurface geology of the western Officer Basin mdash results of
Shellrsquos 1980ndash1984 petroleum exploration campaign APEA Journal v 25 (1) p 34ndash51
WATTS K J 1982 The geology of the Townsend Quartzite Upper Proterozoic shallow water
deposit of the Northern Officer Basin Western Australia Perth University of Western
Australia BSc honours thesis (unpublished)
WELLS A T and KENNEWELL P J 1974 Evaporite exploration in the Officer Basin
Western Australia at the Madley Diapirs Australia BMR Record 1974194 (unpublished)
WILLIAMS I R and MYERS J S 1990 Paterson Orogen in Geology and mineral resources
of Western Australia Western Australia Geological Survey Memoir 3 p 274ndash286
WILLIAMS I R 1990 Savory Basin in Geology and mineral resources of Western Australia
Western Australia Geological Survey Memoir 3 p 329ndash334
WILLIAMS I R 1994 The Neoproterozoic Savory Basin Western Australia in The
sedimentary basins of Western Australia edited by P G PURCELL and R R PURCELL
Petroleum Exploration Society of Australia Symposium Perth WA 1994 Proceedings p
841ndash850
WILSON R B 1967 Woolnough Hills and Madley diapiric structures Gibson Desert WA
APEA Journal v 7 p 94ndash102
44
Appendix 2
Meteorological data (from Bureau of Meteorology Perth 1994)
Table 21 Wiluna rainfall (mm)
Year Jan Feb Mar Apr May Jun Jul Aug Sept Oct Nov Dec
1975 0 45 446 309 306 59 276 4 34 886 638 164 1976 16 154 12 138 53 16 34 62 12 238 0 2 1977 44 0 66 74 68 95 24 363 1 58 12 727 1978 234 522 94 16 0 96 367 24 16 353 185 45 1979 19 173 122 88 91 4 0 246 58 0 169 114 1980 148 764 68 1081 259 626 629 06 56 02 174 0 1981 123 476 192 32 196 118 44 74 14 0 28 312 1982 374 705 206 244 1079 92 02 143 368 526 368 118 1983 1 112 928 248 0 212 56 32 5 1 42 496 1984 149 7 342 84 836 0 348 132 224 04 16 172 1985 596 483 0 166 556 0 514 56 0 0 4 0 1986 0 154 35 0 0 1085 23 01 239 137 0 04 1987 1204 119 19 89 17 575 154 126 07 1 0 398 1988 46 202 164 13 388 0 202 104 0 0 224 1309 1989 207 234 26 703 278 536 57 0 01 0 144 02 1990 1035 23 281 46 126 53 94 218 44 9 42 0 1991 48 0 41 45 0 472 297 12 0 1 0 7 1992 112 96 1025 1227 323 65 04 174 0 132 48 4 1993 0 697 0 202 445 0 12 306 18 05 14 33 Mean 25 35 22 27 27 25 18 12 6 13 13 21
JAN FEB MAR APR MAY JUN JUL AUG SEP OCT NOV DEC0
10
20
30
40
Mea
n R
ain
fall
(mm
)
Month
Mean monthly rainfall in Wiluna
MKS41 140498
45
Table 22 Wiluna minimum temperature (degC)
Year Jan Feb Mar Apr May Jun Jul Aug Sept Oct Nov Dec
1975 ndash 23 203 15 94 63 71 62 103 124 169 205 1976 242 229 194 15 10 63 59 73 95 143 16 228 1977 243 25 197 148 96 95 56 86 102 ndash 188 23 1978 241 232 203 18 102 64 76 8 9 152 19 205 1979 255 226 216 167 83 6 59 79 97 145 198 223 1980 255 226 231 155 134 83 68 75 121 108 193 223 1981 245 216 19 182 119 6 54 78 138 159 163 218 1982 232 224 177 16 ndash ndash 37 111 112 164 209 225 1983 235 24 197 147 112 88 39 88 121 162 189 219 1984 241 243 191 156 ndash 72 66 7 95 161 182 211 1985 244 231 ndash 159 98 65 71 73 117 147 205 ndash 1986 ndash 229 226 155 93 96 43 49 10 122 ndash 219 1987 ndash 217 183 175 85 77 68 68 112 ndash ndash 221 1988 238 214 209 178 111 ndash ndash 86 104 157 171 195 1989 ndash 237 199 165 107 67 44 61 107 131 187 ndash 1990 232 ndash 211 155 118 62 57 87 102 149 195 22 1991 26 256 217 168 122 101 78 ndash 113 18 168 219 1992 227 227 214 169 102 98 59 69 ndash 125 159 196 1993 241 218 196 171 103 ndash 49 68 88 128 192 211 Mean 24 23 20 16 10 8 6 8 11 14 18 21
NOTE Dashes indicate data unavailable
JAN FEB MAR APR MAY JUN JUL AUG SEP OCT NOV DEC0
10
20
30
40
Month
MKS43 140498
50
Mean monthly minimum temperatures at Wiluna
Mea
n T
emp
erat
ure
(degC
)
46
Table 23 Wiluna maximum temperature (degC)
Year Jan Feb Mar Apr May Jun Jul Aug Sept Oct Nov Dec
1975 ndash 349 326 281 247 201 197 212 256 248 31 344 1976 374 369 346 297 248 206 208 225 265 287 313 388 1977 397 392 352 296 234 212 222 244 ndash 308 337 383 1978 378 345 346 316 242 195 176 205 231 295 334 356 1979 403 36 364 295 ndash ndash ndash 193 242 318 359 373 1980 392 342 377 275 24 176 179 233 292 288 349 391 1981 385 346 337 342 242 178 201 224 30 326 326 369 1982 372 359 315 307 ndash ndash 196 253 252 305 353 379 1983 381 389 327 272 263 222 187 248 287 321 336 366 1984 378 393 322 299 226 215 178 214 234 ndash 336 364 1985 40 366 ndash 294 224 216 205 212 284 307 355 ndash 1986 ndash 383 372 307 ndash 193 166 196 261 277 ndash 382 1987 ndash 339 328 305 21 202 214 218 275 ndash ndash 374 1988 388 365 353 301 23 ndash ndash 228 283 334 31 33 1989 ndash 375 339 285 238 179 181 219 275 298 336 ndash 1990 368 ndash 36 309 268 19 188 205 274 309 373 393 1991 414 416 363 315 268 206 21 ndash 279 338 332 368 1992 363 383 336 263 213 178 213 197 ndash 285 313 359 1993 396 357 344 301 221 ndash 197 215 253 294 347 362 Mean 39 37 34 30 24 20 20 22 27 30 34 37 NOTE Dashes indicate data unavailable
JAN FEB MAR APR MAY JUN JUL AUG SEP OCT NOV DEC0
10
20
30
40
Month
MKS42 140498
50
Mean monthly maximum temperatures at Wiluna
Mea
n T
emp
erat
ure
(degC
)
47
Appendix 3
Table 31 Summary of palynological results
Drillhole Depth (m) F no(a) GSWA no Lithology Formation Assemblage TAI(b)
BWB 1 74ndash75 F49668 135741 dark-grey siltstone basalt Jilyilli gt5 BWB 1 98ndash100 F49669 135742 dark-grey siltstone basalt Jilyilli gt5 BWB 1 121ndash122 F49670 135743 dark-grey siltstone basalt Jilyilli gt5 TWB 1 86ndash87 F49671 135631 dark-grey siltstone McFadden 3+ TWB 1 104ndash105 F49672 135632 dark-grey siltstone Cornelia 3+ TWB 1 121ndash122 F49673 135633 dark-grey siltstone Cornelia 4 TWB 2 14ndash15 F49674 135634 dark-grey siltstone Skates Hills 3+ TWB 6 49ndash50 F49675 135675 dark-grey siltstone Cornelia 1 3+ TWB 9 49ndash51 F49676 135704 dark-grey siltstone Brassey Range 1 3+ Trainor 1 37497- F49733 138939 black mudstone with Cornelia 5 37509 light-grey siltstone Trainor 1 3809 F49734 138940 dark-grey and black Cornelia 4- laminated mudstone Trainor 1 4170 F49735 138941 black unlaminated mudstone Cornelia 4- Trainor 1 4950 F49851 139501 dark-grey indurated siltstone Cornelia 5 Trainor 1 6032 F49852 139502 dark- and light-grey Cornelia 5 indurated siltstone Trainor 1 6434 F49853 139503 greenish indurated finely Cornelia 5 laminated siltstone LDDH 1 270 F49678 138934 dark-grey siltstone interbeds Waters 1 3+ in enterolithic evaporite Tarcunyah Gp LDDH 1 277 F49679 138935 dark-grey siltstone in cavity Waters 1 3+ in enterolithic evaporite Tarcunyah Gp
NOTES (a) GSWA Fossil Catalogue number (b) TAI = Thermal Alteration Index of Traverse (1988 plate 1)
48
Appendix 4
Savory Sub-basin quantitative magnetic and gravity interpretation (extracted from Cowan 1995)
Summary
A program of quantitative aeromagnetic interpretation has been completed on BMRAGSO data from the Savory Sub-
basin Western Australia Quantitative aeromagnetic interpretation utilized the 3D Euler deconvolution method
supported by wavenumber filtering and image processing The results have provided useful information on structural
trends and depth to magnetic sources in a structurally complex area Depth to magnetic source analysis has provided
information on intra-sedimentary magnetic sources as well as basement rocks
The results of the interpretation support previously identified depocentres However the presence of magnetic
sources at several levels makes it very difficult to produce a reliable magnetic basement depth contour map It is
considered more productive to work with the 3D Euler colour circle plots and images rather than trying to contour the
results It would be necessary to carry out a full-scale interpretation of the BMRAGSO profile data to improve on the
3D Euler results The regional gravity was found to be useful in interpreting the regional setting of the area although
the very wide data spacing limits quantitative use of the data The gravity data show quite a complex picture with
limited consistent correlation between gravity features and basin structures This suggests that gravity anomalies
reflect changes in density of the basement rocks rather than basement topography especially in the northern part of the
basin
It is recommended that the GSWA investigate access to company confidential high-resolution aeromagnetic data
prior to planning further aeromagnetic surveys Private companies have flown large parts of the northern half of the
area as part of their diamond exploration program Additional gravity coverage of the area may be more cost effective
than magnetic surveys as the gravity data provides more information on changes within the sedimentary section
Introduction
The main use of aeromagnetic data in petroleum exploration has been the determination of magnetic basement
topography although there has been increasing interest in analysis of intra-sedimentary magnetic anomalies
intrabasement and suprabasement magnetic anomalies These anomalies are used to determine depth to magnetic
basement rocks and hence determine the thickness of the sedimentary sequence Unfortunately interpretation of the
intrabasement and suprabasement magnetic anomalies is non-unique in terms of position and size of causative sources
because of the inherent ambiguity of potential-field methods However this ambiguity can be reduced by placing
49
constraints on source geometry and magnetization and by using geological and other geophysical data to constrain
the solution
Before 1970 most depth-determination techniques involved graphical determination of slopes of selected
magnetic anomalies and application of various empirical factors to convert the slopes into depth estimates Geological
Society of America Memoir 47 Interpretation of Aeromagnetic Maps by Vacquier et al (1951) was a landmark for
this type of interpretation
Automated interpretation procedures have played an increasingly important role in depth interpretation and a
wide range of techniques have been developed Many of these techniques are designed for application to located data
profiles and assume a two-dimensional geometry However there has been renewed interest in techniques applicable
to gridded data
Two distinct types of method can be recognized In the first case often described as discrete methods individual
isolated magnetic anomalies are interpreted and the results used to produce a map of basement relief In the second
case often described as continuous methods areas of data containing a number of anomalies are interpreted
statistically to produce direct output of basement depths
The discrete methods usually involve a semiautomatic initial phase which generates a large number of possible
depth solutions and an interactive second phase to screen and select acceptable solutions The advantage of this
approach is that the interpreter can select features that are relatively free from interference from adjacent anomalies
and consider all aspects of a particular magnetic anomaly The disadvantage is that interpretation can be very time
consuming as a wide range of depths are usually possible depending on the initial model chosen and a significant
amount of effort is needed to select the correct model In the case of the Savory Sub-basin dataset we encountered
problems in separating basement related effects from the effects of shallower intrasedimentary magnetic sources
Because of these problems we have concentrated on displaying the Euler results accompanied by separation filter
images of the data to show the shallower effects and deeper effects rather than trying to refine a 3D Euler
deconvolution depth-to-crystalline-basement contour
The continuous methods are very direct provided that the rather restrictive assumption can be made that all
anomalies are due to lateral magnetization changes due to basement topography This means that shallow effects and
large intrabasement anomalies must be removed from the data This involves judgement and skill as it is necessary to
distinguish between the lower amplitude suprabasement anomalies due to basement topography and the larger
intrabasement anomalies reflecting magnetization changes within the basement These methods were not considered
suitable for the Savory Sub-basin magnetic dataset but were used to invert the gravity data
50
Limitations of magnetic and gravity interpretation
Interpretation of the area is limited by a shortage of information on the nature and physical properties of the deeper
sedimentary sequence and the underlying basement rocks However using techniques such as cross-correlation of
gravity and pseudo-gravity data it is possible to try to differentiate between anomalies relating to basement and those
related to the sedimentary sequence
Gravity anomalies reflect changes within the sedimentary sequence as well as basement condition These
changes in density of sedimentary rocks produce gravity anomalies without a corresponding magnetic anomaly hence
the complementary nature of gravity and magnetic surveys The main use of magnetics is to determine depth to
magnetic basement and any intra-sedimentary volcanic rocks or intrusives whereas gravity provides much more
general information on the sedimentary sequence
Unfortunately interpretation of gravity anomalies is complicated since they can be due to a number of geological
features including
bull major basement faults
bull basement highs
bull igneous intrusions within the basement
bull sedimentary basins which may or may not be isostatically compensated
bull intra-sedimentary volcanics and associated plutonic centres
Two major problems affect the interpretation of both magnetic and gravity data
1 The inherent ambiguity of potential-field data There is no unique solution to any measured gravity or magnetic
anomaly and theoretically there will be an infinite number of source geometry and magnetizationdensity
combinations which will fit the observed data This means that any a priori information which helps to select a
suitable model is very useful
2 Measured anomalies are the summation of effects from different depths For example an observed gravity profile
may contain contributions from shallow sources (density variations within the sedimentary basin) intermediate
depth sources (density variations due to large igneous intrusions within the basement) and deep sources (crustal
thinning producing a mantle anomaly) Separation of these component responses is the regionalresidual problem
which we solve using spectral analysis and differential upward continuation-based separation filtering
Regional setting and interpretation overview
The area studied includes parts of BALFOUR DOWNS (SF51-9) RUDALL (SF51-10) ROBERTSON (SF51-13) GUNANYA
(SF51-14) COLLIER (SG50-4) BULLEN (SG51-1) TRAINOR (SG51-2) MADLEY (SG51-3) NABBERU (SG50-5)
STANLEY (SG51-6) and HERBERT (SG51-7) 1250 000 sheets Broadly the area lies between latitudes 22deg00rsquondash25deg30rsquoS
and longitudes 119deg30rsquondash123deg30rsquoE
51
Regional gravity
The AGSO regional gravity data (at nominal 11 km spacing) was gridded at a 4 km mesh spacing using a minimum-
curvature algorithm Bouguer gravity values in the area are negative reflecting mass deficiency at depth and range
from -84 mgals to -25 mgals
A Bouguer gravity colour image is shown as Figure 41 A residual grid was produced by removing a fifth-order
orthogonal polynomial from the Bouguer data but did not add to the interpretation
120deg 121deg 122deg 123deg
23deg
24deg
25deg
-25
-84
50 km
MKS46 180598
mgal
Figure 41 Regional Bouguer gravity (BMRAGSO data) gridded at 4 km
52
The data show a complex pattern of positive and negative anomalies with no clearly defined trends Correlations
with aeromagnetic data and known basin structures are poor A vague north-northwest linear trend appears to coincide
with the Marloo Fault (Figure 42) A prominent negative anomaly appears to coincide with the Blake Fold and Fault
Belt depocentre and continues as a narrower negative anomaly to the east until it widens out again near the edge of the
basin Elsewhere the gravity data show little correlation with known basin structures and it is likely that especially in
the north of the area gravity anomalies are due to density changes in the basement rather than changes in basement
topography
Production of wavelength-filtered residual gravity plots and vertical gradient plots showed very patchy aliased
data reflecting poor sampling in much of the area
Regional magnetics
The AGSO regional aeromagnetic data were gridded at a 400 m mesh spacing using a minimum-curvature algorithm
(Figure 43) Most of the data has a line spacing of 1600 m with small areas of 1 km spacing The quality of the data is
acceptable for regional interpretation but is not adequate for detailed analysis The accuracy of the flight path is rather
variable reflecting the vintage of the data and the noise envelope of the data is poor by modern standards Problems
were also encountered in joining different map sheets
The magnetic anomaly pattern over the south and west part of the area shows a strong high frequency signature
reflecting the presence of widespread basic sills and dykes Some of the major north-northeasterly trending dykes can
be traced over considerable distances
Discontinuous high-frequency anomalies extend as a northwest-trending zone through the centre of the area and
this zone includes a conspicuous circular magnetic anomaly which is probably a ring complex
The northern and eastern parts of the area are characterized by long-wavelength deep-seated basement magnetic
anomalies with 120deg and 150deg trends dominant The Marloo and Perentie Faults (Figure 42) appear as distinct linear
zones and offsets A prominent easterly trending negative anomaly in the northwest of the area appears to swing round
to the southeast and may separate different basement blocks One possible interpretation is that this very deep seated
anomaly separates areas of Archaean and Proterozoic basement
Regional geology
The regional geology is described in Williams (1992) The GSWA provided a digitized version of Plate 2 from this
Bulletin the structural interpretation map to use as an overlay (Figure 42)
53
Pp
Pp
PSd
PSd
PSd
PSd
PSd
PSo
PSt
PSt
PSf
PSf
PSf
PSb
PSb
PSb
PSsPSs
PSs
PSb
PSm
PSp
PSc
PSc
PSw
PSw
PSw
PSg
PSr
PSj
PSg
PM
Pk
PY
PY
PSd
L
L
L
L
L
L
L
LL
L
L
L
LL
L
LL
L L
LL
L L
L
L
L
L
L
L
L
LL
L
L
BLAKEDEPOCENTRE
MA
RLO
O
FAU
LT
PERENTIEFAULT
50 km
MKS39120598
120deg 121deg 122deg 123deg
25deg
24deg
23deg
Approximate boundaryof aeromagnetic interpretation
PML
PSgL
PSjL
PML
PSpL
PML
PML
PSfL
PSfL
PSpL
LPc
LPcLPcPSrL
LPA
Durba Sandstone
Woora Woora Formation
McFadden Formation
Tchukardine Formation
Boondawari Formation
Skates Hills Formation
Mundadjini Formation
Coondra Formation
Spearhole Formation
Watch Point Formation
Jilyili Formation
Brassey Range Formation
Glass Spring Formation
Paterson Formation
Yeneena Group
Karara Formation
Cornelia Formation
Kahrban Subgroup
Bangemall Group
Fault
Formation boundary
PSdL
PSoL
PSfL
PStL
PSbL
PSsL
PSmL
PScL
PSpL
PSwL
PSjL
PSrL
PSgL
Pp
PYL
PkL
LPc
LPA
PML
Savory Group Other Units
PYL
Figure 42 Regional geology and structure map (after Williams 1992)
54
120deg 121deg 122deg 123deg
23deg
24deg
25deg
5820
3750
MKS47 180598
nT
50 km
Figure 43 Regional aeromagnetic data total magnetic intensity (BMRAGSO data) gridded at 400 m
Analysis
3D analysis
3D Euler deconvolution was used as the primary depth-determination method The advantage of this approach is that
consistent solutions can be obtained over the entire area with minimal assumptions about source geometries Euler
deconvolution of gridded data is used for positional information and estimation of depth to top of source Euler
55
deconvolution yields a large number of depth solutions which have to be screened to reject spurious solutions Results
are plotted as circles in eight depth ranges with radius proportional to depth and colour coded
The 400 m total magnetic intensity grid was used for the analysis Horizontal gradients in x and y and the vertical
gradient were calculated 3D Euler deconvolution was tested on the 400 m gridded data using windows of 9 times 9 and
11 times 11 and 16 times 16 data points and structural indices 05 (fault) and 10 (sill or dyke) It was concluded that the
16 times 16 window produced the best results overall and final plots were produced for the 16 times 16 window and structural
index 05 (Fig 44) Results were very good over the northern and central parts of the area showing magnetic sources
Figure 44 Depth to magnetic source 3D Euler deconvolution 16 times 16 window of 400 m gridded data structural index 05
56
at several different levels Unfortunately in the extreme south of the area shallow intrasedimentary magnetic sources
(sills and dykes) dominated the inversion and the results contained few basement solutions
In order to reduce these problems the 400 m gridded data were filtered using a separation filter based on
interpretation of the log-energy spectrum The 3D Euler method was run on the filtered data in order to generate more
basement-depth solutions Results for the deep-separation filter data were gridded and presented as a colour image in
Cowan (1995) Attempts to grid the Euler output were unsatisfactory and it is considered safer to interpret the 3D
Euler depth plots The 3D Euler depth results from the separation-filter run should be analysed with care as perfect
separation of the basement can never be achieved and there will always be some contamination from sources at
different levels
The results of original total magnetic intensity 3D Euler depth estimation for structural index 05 using a 16 point
window have been plotted at 1500 000 scale (not included in this publication but available in Cowan (1995) from the
GSWA Library as S10331) and as reduced A4 colour circle plots (Figure 44)
The results of deep-basement 3D Euler depth estimation for structural index 05 using a 16 point window have
been plotted as a colour image at 1500 000 scale and as an A4 image (not included in this publication)
2D analysis
Two equispaced profiles were interpolated with a 50 m station interval from the AGSO-located data profiles for the
BULLEN 1250 000 sheet The interpolated profiles were analysed using 2D Euler deconvolution and Werner
deconvolution Results are included in Cowan (1995) and show the use of these methods for more detailed analysis
Filtered data
In order to reconcile 3D Euler results from shallow basement and intrasedimentary magnetic sources we produced
several separation-filtered maps and images We found the shallow-layer double-separation filter (Figure 45) to be
very effective for shallow sources and the deep-layer standard-separation filter (Figure 46) for the basement layer
Gravity and magnetic data correlation
Both lsquoreduced to the polersquo (RTP) magnetics (Figure 47) and pseudo-gravity data (Figure 48) were produced as part of
the reconciliation of gravity and magnetic signatures In both cases the filtering operations assumed magnetization by
induction in the present Earths field The RTP data are fairly similar to the total magnetic intensity The pseudo-
57
gravity data are dominated by a northwest-trending strong positive anomaly and there is little correlation with the
Bouguer gravity data
The poor magneticgravity correlation is confirmed by cross-correlation of the RTP magnetics and the gravity
gradient The correlation plot in Figure 49 shows little coherent response with numerous zones of positive and
negative correlation
Figure 45 Regional aeromagnetic data shallow layer separation filter (BMRAGSO data) gridded at 400 m
Results
In the north and east of the area on the Wells Foreland Sub-basin trend (refer to Figure 1 main text) we see a range
of quite deep 3D Euler depths and several trend directions with north-northwesterly dominant There are relatively few
shallow intrasedimentary solutions in this zone
The second area of deep 3D Euler solutions lies over the Blake depocentre (Figure 43) with several trend
directions
Elsewhere the 3D Euler results are dominated by shallow intrasedimentary depth solutions reflecting mainly the
dolerite sills dykes and the ring complex However where we do see basement-related solutions in the south and
west of the area they appear to be shallower than those noted for the Wells Foreland Sub-basin and the Blake
depocentre
58
Figure 46 Regional aeromagnetic data deep-layer separation filter (BMRAGSO data) gridded at 400 m
Figure 48 Regional aeromagnetic data pseudo-gravity transform (BMRAGSO data) gridded at 400 m
Figure 47 Regional aeromagnetic data reduced-to-pole (BMRAGSO data) gridded at 400 m
Figure 49 Regional aeromagnetic and gravity data gravitymagnetic correlation using RTP magnetics and gravity gradient (BMRAGSO data) gridded at 4 km
59
This subdivision of the area into two zones of deep solutions is consistent with interpreted depocentres
However the interference between sources at different levels and the complexity of the magnetic response of the
basement rocks precludes more refined interpretation at this stage
The area of deep 3D Euler solutions over the Blake depocentre correlates with the pronounced negative gravity
anomaly discussed in the gravity interpretation section Using a density contrast of -015 gcc the negative gravity
anomaly could indicate up to 6ndash8 km of low-density sedimentary rocks depending on assumptions about the regional
field
The area of deep 3D Euler solutions over the Wells Foreland Sub-basin has a complex gravity expression and no
clear basin structure emerges from inversion of these data As noted previously it is likely that observed gravity
anomalies reflect contrasts in basement density rather than basement topography
Separation filtering applied to the magnetic data helps to enhance the intrasedimentary magnetic signature and to
give a better impression of the basement magnetic signature even though separation of the basement response is not
perfect
Conclusions
Quantitative aeromagnetic interpretation using 3D Euler deconvolution supported by wavenumber filtering and image
processing has been successful in providing structural trend and depth information for the Savory Sub-basin
Quantitative magnetic interpretation has revealed two zones of relatively deep magnetic basement beneath the
Wells Foreland Sub-basin and the Blake depocentre
This analysis of the magnetic data supports interpreted depocentres but the complexity of the basement magnetic
signature and interference from sources at different depths precludes further refinement to a map of basement
topography
Regional gravity proved to be very useful in understanding the regional setting of the area and in providing
support for aspects of the interpretation The gravity data support the interpretation of the Blake depocentre
suggesting up to 6ndash8 km of low-density sedimentary rocks
The deep structure of the Savory Sub-basin area is obviously complex with different areas underlain by
Archaean and Proterozoic basement and with the Capricorn suture occurring in the centre of the area
60
Recommendations
The quantitative magnetic interpretation needs to be reconciled with geological models available for the area
In particular the zones tentatively identified as areas with thick sedimentary rocks the Wells Foreland Sub-
basin and the Blake depocentre need to be investigated
Cross sections should be prepared across the basin for joint magneticgravity modelling especially for the Blake
depocentre It is important to be able to explain the strong negative gravity anomaly in this area
In view of the effects of basement density contrasts on the gravity field for the northern part of the area we think
that additional gravity interpretation and acquisition of new gravity data may not be justified as they will not
contribute significantly to understanding basin evolution and structure
It is recommended that GSWA try to get access to company confidential high-resolution aeromagnetic data
rather than flying new surveys The GSWA might offer to fund flying of new infill areas as a bargaining point
References
The original text of this report by Cowan (1995) and 1500 000 scale maps are filed in the GSWA Library under
S10331
COWAN D 1995 Savory Basin quantitative magnetic interpretation Western Australia Geological Survey S-series
S10331 (unpublished)
VACQUIER V STEENLAND N C HENDERSON R G and ZIETZ I 1951 Interpretation of aeromagnetic
maps The Geological Society of America Memoir 47 151p
WILLIAMS I R 1992 Geology of the Savory Basin Western Australia Western Australia Geological Survey
Bulletin 141 115p
61
Appendix 5
Geochemistry
MKS38 250398
Saturate FractionC12+ GLC
1217
Pr18
Ph
22
31CSR WELL-13 315m Cuttings
Figure 51 Canning Stock Route Well 13 gas chromatograph of extract of auger drill sample
12
17
18
22
31
Pr Ph
LDDH 1 6623m CoreSaturate FractionC12+ GLC
MKS35 240398
Figure 52 Gas chromatograph of extract from core sample at 6623 m LDDH1
62
Table 51 Canning Stock Route Well 13 auger drill samples
GSWA sample Drill depth (m)(a) Comments
135601 150 At watertable 135602 203 (all samples consist 135603 310 of sand mud and water) 135604 315 At total depth
NOTE (a) Datum for drill depth is the top of sediment fill in the well which is 155 m below ground level (ie the total depth of 315 m is 47 m below ground level)
Table 52 Canning Stock Route Well 13 gas chromatography data for 315 m depth sediment sample
Parameter Value
Weight of rock extracted (grams) 945 Total extract (ppm) 519 n-Alkane distribution n-C12 07 n-C13 23 n-C14 26 n-C15 22 n-C16 19 n-C17 14 i-C19 23 n-C18 14 i-C20 08 n-C19 11 n-C20 16 n-C21 25 n-C22 29 n-C23 70 n-C24 42 n-C25 95 n-C26 43 n-C27 83 n-C28 38 n-C29 87 n-C30 31 n-C31 273 Alkane compositional data Pristane phytane ratio 279 Pristane n-C17 ratio 161 Phytane n-C18 ratio 059 CPI (1)(a) 284 CPI (2) 209 (C21 + C22) (C28 + C29) 043
NOTE (a) CPI= Carbon preference index
63
Table 53 LDDH1 extract liquid chromatography data for 6623 m concentration
Rock extracted Total extract (grams) (ppm)
702 313
NOTE ppm= parts per million
Table 54 LDDH1 saturate gas chromatography data of core for 6623 m alkane composition
Pristane Pristane Phytane (a) CPI (1) CPI (2) (C21+C22) Phytane n-C17 n-C18 (C28+C29)
103 026 024 103 102 325
NOTE (a)CPI = carbon preference index
Table 55 LDDH1 saturate gas chromatography data of core for 6623 m n-alkane distributions
Parameter Value
n-C12 17 n-C13 38 n-C14 55 n-C15 60 n-C16 65 n-C17 74 i-C19 19 n-C18 78 i-C20 19 n-C19 80 n-C20 79 n-C21 71 n-C22 64 n-C23 57 n-C25 43 n-C24 38 n-C27 31 n-C28 23 n-C29 19 n-C30 12 n-C31 10
64
Appendix 6
Table 61 Summary of data from Trainor waterbores (TWB) and Bullen waterbores (BWB)
Well AMG Elevation TD Status(b) Completion details Water Salinity Water level Flow rate Depth to consolidated AGD84 GL (m) (m) struck mgl(c) (m) (LHr) lithology aquifer(e) Z51(a) Interval (m) (100 mm PVC) (m) (mgl)(d)
TWB 1 473660E 453 122 comp 0ndash75 plain 63 7 300 24 2 880 12 m 7287404N 75ndash93 slotted (9 260) McFadden Fm 93ndash99 plain TWB 2 472 977E 475 23 abd nil 15 m 7285877N Skates Hills Fm dry TWB 3 473259E 475 50 abd nil 7 m 7285849N Skates Hills Fm dry TWB 4 463225 E 445 50 comp 0ndash22 plain 35 7 200 55 3 600 0 m 7286143N 22ndash34 slotted (8 140) Tertiary sand and gravel 23ndash60 plain TWB 5 463095E 445 31 comp 0ndash19 plain 13 26 000 655 3 600 Tertiary sand and gravel 7277721N 19ndash25 slotted (36 700) 25ndash31 plain TWB 6 457013E 455 50 comp 0ndash42 plain 38 920 119 600 0 m 7274352N 42ndash48 slotted (1 030) Cornelia Fm ss TWB 7 453739E 475 26 susp 0ndash2 plain 11 9 300 48 4 500 0 m 7263891N (10 500) Tertiary sand TWB 8 433893E 535 60 susp 0ndash2 plain 47 8 500 gt46 1 200 0 m 7245991N (10 900) Tertiary sand and Brassey Range Fm ss TWB 9 437219E 505 51 comp 0ndash47 plain 45 1 000 58 600 1 m 7235905N 47ndash51 slotted (990) Brassey Range Fm ss TWB 10 434927E 495 32 susp 0ndash2 plain 235 450 120 0 m 7225875N (500) Dolerite
65
BWB 1 287337E 580 122 abd Nil 1 m 7245861N Jilyili Fm dry BWB 2 288346E 545 50 comp 0ndash26 plain 15 630 3 29 000 0 m 7240423N 26ndash38 slotted (730) Tertiary sand and gravel 38ndash50 plain BWB 3 305637E 545 50 abd 19 8 800 43 7 200 0 m 7240423N (10 550) Tertiary ss BWB 4 320167E 515 445 comp 0ndash20 plain 9 980 445 24 000 0 m 7248097N 20ndash32 slotted (1 190) Tertiary ss 32ndash44 plain BWB 5 353393E 545 20 susp 0ndash2 plain 45 (970) 1 m 7238934N Basalt
NOTES (a) GPS accuracy ~ 150 m (b) Comp = completed abd = abandoned susp = suspended (c) Salinity from conductivity (d) Analysis total dissolved solids (e) Fm = Formation ss = sandstone
28
The cores from the five drillholes listed in Table 2 believed to be all of the core available
from the sub-basin are available for inspection at GSWA Mineral exploration reports submitted
to GSWA may be searched using the WAMEX database and open-file reports are available on
microfiche Geophysical data acquired by the mining industry is not required to be filed with
GSWA if acquired over Vacant Crown Land which is the case for much of the sub-basin
Geophysical survey data submitted in mining tenement reports and which extend into Vacant
Crown Land remain confidential to the companies Original regional aeromagnetic and gravity
datasets are available from the Australian Geological Survey Organisation (AGSO)
Data pertinent to oil exploration in the sub-basin such as structural style and salt diapirism
are presented in a review of the hydrocarbon prospectivity of the Officer Basin (Perincek 1998)
Drilling
Significant drillholes in the sub-basin are summarized in Table 2
Petroleum industry data
Amadeus Petroleum drilled three petroleum exploration wells in the central west of the Savory
Sub-basin in late 1997 These wells Mundadjini 1 Boondawari 1 and Akubra 1 were drilled by
continuous diamond coring (Figs 5 and 6) All targeted potential reservoirs within the Spearhole
Formation with the Mundadjini Formation as the proposed seal The wells were located on
structures interpreted from Landsat images and limited geological investigations Both Mundadjini
1 and Boondawari 1 had minor oil shows as discussed above (Reported hydrocarbon shows)
Government data
Stratigraphic drillhole Trainor 1 was drilled by GSWA in 1995 (Stevens and Adamides in prep)
and the main results are discussed above (Source rocks and Maturity)
Mineral industry data
Normandy Exploration drillhole LDDH1 was cored in the Tarcunyah Group to a total depth of
701 m and provided source-rock and maturity data as discussed above
29
Oilmin NL drilled six percussion drillholes (BD 1 3 4 5 8 and 9) through sandstones and
shales in the northern part of the Savory Sub-basin to a maximum depth of 198 m (Fig 5
WAMEX Microfiche File M 26811 I 2610) but only brief geological descriptions are available
Hydrogeological data
Hydrogeological data within the Savory Sub-basin are limited although a long history of water
exploration extends back to the construction of the Canning Stock Route early this century No
detailed geological or wireline logs are available for the older wells along this route A few station
wells have been drilled by various methods on the south and west margins of the basin but data
are unavailable as reports are not required to be filed with the government Depth to watertable
throughout the basin is largely controlled by porosity of the bedrock
The GSWA drilled fifteen waterbores in the winter of 1995 in the southern part of the sub-
basin in preparation for the drilling of Trainor 1 and the proposed Bullen 1 Twelve bores found
water and six of these bores have salinities of less than 1000 mgL (Fig 5 Appendix 6 Table 61)
One waterbore TWB 6 has gamma ray and neutron logs run through PVC casing and these are
available from the GSWA with the digital log data included herein
Seismic data
No geophysical data have been acquired by the petroleum industry in the Savory Sub-basin
Seismic data acquired in the Officer Basin to the east particularly in the Gibson and Yowalga
Sub-basins is pertinent to structural interpretation in the Savory Sub-basin (Perincek 1996a
1998)
Aeromagnetic surveys
Government data
There are over 95 277 line kilometres of aeromagnetic data included in the AGSO dataset There
are three regional aeromagnetic surveys covering the Savory Sub-basin These were flown by the
Bureau of Mineral Resources (BMR now AGSO) in 1984 at a line spacing of 1500 m with 36 740
and 52 587 line kilometres flown and by Aerodata in 1984 at a line spacing of 1000m with 5950
line kilometres flown These data were reprocessed and interpreted for GSWA by Cowan (1995)
An edited copy of this report is included as Appendix 4 and the original report is filed in the
GSWA Library under S-series reports item 10331
30
Mineral industry data
The approximate locations of non-AGSO aeromagnetic surveys are shown in Figure 8 More
detailed information regarding the location of these surveys may be obtained using the GSWA
MAGCAT II database Additional information such as contours of aeromagnetic values may be
obtained by inspecting items on file with the GSWA
Gravity surveys
Government data
The average spacing for gravity data in the Savory Sub-basin is one station per 121 km2 (11 times 11
km grid) These data were principally collected by BMR in the early 1960s There are a few
additional regional gravity traverses across the sub-basin which are also included in the
BMRAGSO dataset These data were reprocessed and interpreted for GSWA (Fig 10) and a
report on this work is also included in Appendix 4
The GSWA completed a large semi-detailed gravity survey in the eastern Savory Sub-basin
utilizing helicopter support and Differential Global Positioning Survey (DGPS) techniques (Fig
8) This gravity survey completed in August 1995 consists of 2300 gravity stations on a 2 times 3 km
grid All stations were acquired by helicopter using Scintrex gravimeters and Ashtek dual
frequency DGPS equipment for determining location This highly efficient system allowed the
acquisition of more than 100 gravity stations per day in remote areas The resolution of this survey
is +30 cm and +05 microms-2 (Daishsat 1995) These data (Fig 11) represent a significant
improvement on the previous regional survey data and are available from GSWA (GSWA
1996ab) The results of the interpretation of these data were presented at the 1997 ASEG
Convention (Carlsen and Shevchenko 1997)
Mineral industry data
Three small gravity surveys were conducted by Oilmin NL (Fig 8) and the relevant WAMEX
reports are M 2681I 2610 I 2435 I 2567 These three surveys are of limited value because height
control was provided by barometers only and the surveys were not tied to the national gravity grid
31
23deg
25deg
120deg 122deg
Trainor 1
SAVORY
SUB-BASIN
MKS54 160498
100 km
1995 SavoryGravity Survey
254
-1056
micromsec2
Figure 10 Regional Bouguer gravity map of the Savory Sub-basin
23deg
24deg
25deg
122deg30 123deg
TRAINOR 1
123deg30
50 km
MKS53 160498
-116
-626
micro msec2
Figure11 Detailed Bouguer gravity map of the
Savory 1995 Gravity Survey from the eastern Savory Sub-basin
32
Government and academic reports
Chronostratigraphy and geochemistry
The understanding of Neoproterozoic organic chemistry palynology and structural evolution is
essential to the interpretation of hydrocarbon prospectivity Pertinent reports are included in the
bibliography (Appendix 1) Unpublished palaeontology reports describe the palynology of wells in
the Savory Sub-basin (Grey 1995andashe 1996a) Grey and Cotter (1996) discussed the potential for
Neoproterozoic palynomorphs to provide a biostratigraphic framework and palaeoenvironmental
interpretation Grey and Stevens (1997) reviewed the results of palynological studies of wells
drilled in the sub-basin and reported that Supersequence 1 palynomorphs are present in TWB 6
TWB 9 and LDDH1 (Appendix 3) Grey (1996b) reported on the use of stromatolites for
correlation in the Neoproterozoic and Stevens and Grey (1997) discussed the application of
stromatolite biostratigraphy in correlating isolated dolomite outcrops in the sub-basin with well
and seismic data in the Officer Basin and Centralian Superbasin
Although geochemical data from the Savory Sub-basin are very limited results mostly
confirm thermal maturities inferred from TAI for LDDH1 and Trainor 1 (Ghori in prep Stevens
and Adamides in prep) Those parts of the Officer Basin in Western Australia which lie to the
east of the Savory Sub-basin are sparsely drilled but Ghori (in prep) reports that most of the
Neoproterozoic succession presently lies within the oil-generative window However his study
has been unable to identify effective source-rock units and the source for oil shows Thin source
rocks are present in the Neoproterozoic in LDDH1 (Fig 9) and in three wells which lie to the east
and southeast of the Savory Sub-basin namely NJD 1 Kanpa 1A and Yowalga 3
Proposed work program
From the above limited information it is concluded that additional research on the hydrocarbon
potential of the sub-basin is justified and proposals are outlined below
bull Additional modelling of gravity and aeromagnetic data from the Savory Sub-basin is required
in light of the results from Trainor 1 and Boondawari 1 Trainor 1 showed that what appeared
to be a structurally simple area based on outcrop aeromagnetic and gravity data was in fact an
area of major structuring Boondawari 1 intersected a dolerite which is in good depth
agreement with aeromagnetic depth to source results showing this technique is useful in
detecting the depth to intrusive bodies
33
bull Additional data from mineral and petroleum exploration bores may become available and
analysis of samples from these wells should be undertaken and interpreted in the context of
their relevance to the Officer Basin
bull Stratigraphic coring in the Blake Fault and Fold Belt and in the Wells Foreland Sub-basin (Fig
1) targeting source rocks is considered essential to the continuing evaluation of the
hydrocarbon prospectivity of the Savory Sub-basin
bull Correlations using at least outcrop well and potential-field data should be prepared to link the
sub-basin with the better known parts of the Officer Basin to the east
bull Remapping is required to clarify boundary positions within the Cornelia Formation this may
resolve some of the current problems of the relationship between this unit and the rest of the
Savory Sub-basin
bull Further work is required to explain the Early Cambrian or Sturtian ages interpreted for the
Cornelia Formation from sedimentary zircon UndashPb dating in drillhole Trainor 1 The
determination of the age of the organically rich but overmature claystones in this well is
critical to assessing the hydrocarbon potential of the region
bull The thin dark mudstones intersected by Akubra 1 in the Mundadjini Formation warrant
geochemical analysis Analyses of the oil shows in Mundadjini 1 and Boondawari 1 are
currently being undertaken by Amadeus Petroleum
bull Geochemical analysis of hydrocarbons in the Bangemall Basin drillhole OD23 has been
performed by Jubilee Gold and the results will be reviewed when they are submitted to
GSWA The possibility of source rocks within the Bangemall Basin charging traps within the
Bangemall Basin and the overlying Savory Sub-basin requires further investigation
Conclusions
The Savory Sub-basin is a frontier region with only three recently drilled petroleum exploration
wells and no seismic data Based on existing geological and geophysical data it is considered too
early to draw conclusions about the hydrocarbon prospectivity of the sub-basin at this stage and
there are several reasons why the area warrants further investigation
34
1 Thick accumulations of sedimentary rocks are present (up to 8 km thickness inferred) which
may contain source reservoir and sealing strata
2 Minor oil shows occur in Mundadjini 1 and Boondawari 1 and bitumen is present in mineral
exploration drillhole LDDH1 suggesting that hydrocarbons have migrated within the
Neoproterozoic sequence of the Savory Sub-basin Oil and bitumen are present in mineral
exploration drillhole OD23 in the Bangemall Basin immediately to the south of the Savory
Sub-basin and it is possible that source rocks from the Bangemall Basin could charge traps in
the overlying Savory Sub-basin
3 The age of sedimentary rocks in the sub-basin is still poorly constrained but some of the
Neoproterozoic sedimentary rocks located on GUNANYA and TRAINOR are within the
hydrocarbon-generation window It is possible that a significant thickness of Phanerozoic
sedimentary rocks may also be present
4 Friable sandstones with visible porosity outcrop extensively suggesting numerous potential
reservoirs
5 Significant but not intense faulting and folding has been mapped implying large structural
traps may be present
6 Evaporitic sedimentary rocks occur in several formations and may provide good source rocks
and excellent seals
35
References
APAK S N and CARLSEN G M 1997 A compilation and review of data pertaining to the
hydrocarbon prospectivity of the Canning Basin Western Australia Geological Survey
Record 199610 103p
BAGAS L GREY K and WILLIAMS I R 1995 Reappraisal of the Paterson Orogen and
Savory Basin Western Australia Geological Survey Annual Review 1994ndash95 p 55ndash63
BUSBRIDGE M 1994 Lake Disappointment Exploration Licence 451064 Third Annual
Report Lake Disappointment Diamond Drill Hole LDDH1 Normandy Exploration Limited
Western Australia Geological Survey M-series Item 7567 A41358 (unpublished)
CARLSEN G M and SHEVCHENKO S I 1997 Petroleum exploration in Proterozoic basins
using potential fields data and stratigraphic coring Australian Society of Exploration
Geophysicists 12th Geophysical Conference Handbook Sydney 1997 Preview no 66 p 83
(abstract only)
COWAN D 1995 Savory Basin quantitative magnetic interpretation Western Australia
Geological Survey S-series S10331 (unpublished)
DAISHSAT PTY LTD 1995 Operational and processing report Savory Basin gravity survey
Western Australia Geological Survey S-series S10332 (unpublished)
GARD E and GARD R 1990 Canning Stock Route a travellerrsquos guide for a journey through
history Perth Western Australia Western Desert Guides 448p
GEOLOGICAL SURVEY OF WESTERN AUSTRALIA 1996a Savory Basin first vertical
derivative of Bouguer gravity image 1250 000 Western Australia Geological Survey
GEOLOGICAL SURVEY OF WESTERN AUSTRALIA 1996b Savory Basin Bouguer gravity
image 1250 000 Western Australia Geological Survey
GHORI K A R in prep Petroleum source rock potential and thermal history Officer Basin
Western Australia Western Australia Geological Survey Record
36
GREY K 1995a Savory Basin drillhole BWB 1 (Bullen waterbore) palynology and thermal
maturation GSWA Palaeontology Report no 199512 (unpublished)
GREY K 1995b Savory Basin drillholes TWB 1 2 6 9 (Trainor waterbores) palynology and
thermal maturation GSWA Palaeontology Report no 199520 (unpublished)
GREY K 1995c Palynology of Normandy-Poseidon Lake Disappointment-1 corehole
Tarcunyah Group Paterson Orogen GSWA Palaeontology Report no 199521 (unpublished)
GREY K 1995d Savory Basin drillhole Trainor 1 (Trainor diamond drilling) palynology and
thermal maturity GSWA Palaeontology Report no 199524 (unpublished)
GREY K 1995e Savory Basin drillhole Trainor 1 (Trainor diamond drilling) Additional
Preparation of two samples GSWA Palaeontology Report no 199528 (unpublished)
GREY K 1995f Neoproterozoic stromatolites from the Skates Hills Formation Savory Basin
Western Australia and a review of the distribution of Acaciella australica Australian Journal
of Earth Sciences v 42 p 123ndash132
GREY K 1996a Savory Basin drillhole Trainor 1 (Trainor diamond drilling) Additional
samples palynology and thermal maturation GSWA Palaeontology Report no 199615
(unpublished)
GREY K 1996b Preliminary stromatolite correlations for the Neoproterozoic of the Officer
Basin and a review of Australia-wide correlations GSWA Palaeontology Report no 199615
(unpublished)
GREY K and COTTER K L 1996 Palynology in the search for Proterozoic hydrocarbons
Western Australia Geological Survey Annual Review for 1995ndash96 p 70ndash80
GREY K and STEVENS M K 1997 Neoproterozoic palynomorphs of the Savory Sub-basin
Western Australia and their relevance to petroleum exploration Western Australia
Geological Survey Annual Review for 1996ndash97 p 49ndash54
HUBBARD R J PAPE J and ROBERTS D G 1985 Depositional sequence mapping as a
technique to establish tectonic and stratigraphic framework and evaluate hydrocarbon
potential on a passive continental margin in Seismic stratigraphy II an integrated approach
37
edited by O R BERG and D G WOOLVERTON American Association of Petroleum
Geologists Memoir 39 p 79ndash91
LIBBY WG 1995 A petrological report on six samples of bore cuttings from the Savory Basin
Western Australia Western Australia Geological Survey S-series S31307 (unpublished)
MORTON JGG and DREXEL JF 1997 The petroleum geology of South Australia Vol 3
Officer Basin South Australia Department of Mines and Energy Resources Report Book
9719
MUHLING P C and BRAKEL A T 1985 Geology of the Bangemall Group mdash the evolution
of an intracratonic Proterozoic basin Western Australia Geological Survey Bulletin 128
219p
MYERS J S 1990 Precambrian tectonic evolution of part of Gondwana southwestern Australia
Geology v18 p 537ndash540
NELSON D R 1997 Compilation of SHRIMP UndashPb zircon data Western Australia Geological
Survey Record 19972 196p
PAYTON C E 1977 Seismic stratigraphy mdash applications to hydrocarbon exploration
American Association of Petroleum Geologists Memoir 26 516p
PERINCEK D 1996a The age of NeoproterozoicndashPalaeozoic sediments within the Officer Basin
of the Centralian Super-basin can be constrained by major sequence-bounding unconformities
APPEA Journal v 36 pt 1 p 350ndash368
PERINCEK D 1996b The stratigraphic and structural development of the Officer Basin
Western Australia a review Western Australia Geological Survey Annual Review 1995ndash
1996 p 135ndash148
PERINCEK D 1998 A compilation and review of data pertaining to the hydrocarbon
prospectivity of the Officer Basin Western Australia Geological Survey Record 19976
POSAMENTIER H W JERSEY M T and VAIL P R 1988 Eustatic controls on clastic
deposition 1 mdash Conceptual framework in Sea-level changes an integrated approach edited by
C K WILGUS B S HASTINGS C G St C KENDALL H W POSAMENTIER
38
C A ROSS and J C VAN WAGONER Society of Economic Paleontologists and
Mineralogists Special Publication no 42
STEVENS M K and ADAMIDES N G in prep GSWA Trainor 1 well completion report
Savory Sub-basin Officer Basin Western Australia with notes on petroleum and mineral
potential Western Australia Geological Survey Record 199612
STEVENS M K and GREY K 1997 Skates Hills Formation and Tarcunyah Group Officer
Basin mdash carbonate cycles stratigraphic position and hydrocarbon prospectivity Western
Australia Geological Survey Annual Review for 1996ndash97 p 55ndash60
SUMMONS RE and POWELL C McA 1991 Petroleum source rocks of the Amadeus Basin
in Geological and geophysical studies in the Amadeus Basin central Australia edited by R J
KORSCH and JM KENNARD Australia BMR Geology and Geophysics Bulletin 236
TRAVERSE A 1988 Palaeopalynology Boston Unwin Hyman 600p
VAIL P R MITCHUM R M Jr TODD R G WIDMIER J M THOMPSON S III
SANGREE J B BUBB J N and HATLELID W G 1977 Seismic stratigraphy and
global changes of sea level in Seismic stratigraphy mdash applications to hydrocarbon
exploration edited by C E PAYTON American Association of Petroleum Geologists
Memoir 26 516p
WALTER M R and GORTER J 1994 The Neoproterozoic Centralian Superbasin in Western
Australia the Savory and Officer Basins in The sedimentary basins of Western Australia
edited by P G PURCELL and R R PURCELL Petroleum Exploration Society of Australia
Symposium Perth WA 1994 Proceedings p851ndash864
WALTER M R GREY K WILLIAMS I R and CALVER C R 1994 Stratigraphy of the
Neoproterozoic to early Palaeozoic Savory Basin and correlation with the Amadeus and
Officer Basins Australian Journal of Earth Sciences v 41 p 533ndash546
WALTER M R VEEVERS J J CALVER C R and GREY K 1995 Neoproterozoic
stratigraphy of the Centralian Superbasin Australia Precambrian Research v 73 p 173ndash195
WILLIAMS I R 1992 Geology of the Savory Basin Western Australia Western Australia
Geological Survey Bulletin 141 115p
39
WILLIAMS I R 1995a Bullen WA (2nd Edition) Western Australia Geological Survey
1250 000 Geological Series Explanatory Notes 23p
WILLIAMS I R 1995b Trainor WA (2nd Edition) Western Australia Geological Survey
1250 000 Geological Series Explanatory Notes 31p
WILLIAMS I R and TYLER I M 1991 Robertson WA (2nd edition) Western Australia
Geological Survey 1250 000 Geological Series Explanatory Notes 36p
40
41
Appendix 1
Bibliography
Reports which are relevant to this investigation but which are not specifically cited are listed
below
BAILLIE P W POWELL C McA LI Z X and RYALL A M 1994 The tectonic
framework of Western Australiarsquos Neoproterozoic to recent sedimentary basins in The
sedimentary basins of Western Australia edited by P G PURCELL and R R PURCELL
Petroleum Exploration Society of Australia Symposium Perth WA 1994 Proceedings p
45ndash62
BRADSHAW M T BRADSHAW J MURRAY A P NEEDHAM D J SPENCER L
SUMMONS R E WILMOT J and WINN S 1994 Petroleum systems in West Australian
basins in The sedimentary basins of Western Australia edited by P G PURCELL and R R
PURCELL Petroleum Exploration Society of Australia Symposium Perth WA 1994
Proceedings p 93ndash118
CLARKE G L 1991 Proterozoic tectonic reworking in the Rudall Complex Western Australia
Australian Journal of Earth Science v38 p 31ndash44
COCKBAIN A E and HOCKING R M 1990 Phanerozoic in Geology and mineral resources
of Western Australia Western Australia Geological Survey Memoir 3 p 750ndash755
ETHERIDGE M and WALL V 1994 Tectonic and structural evolution of the Australian
Proterozoic 12th Australian Geological Convention Geological Society of Australia
Abstracts no 37 p 102ndash103
GOODE A D T 1981 Proterozoic geology of Western Australia in Precambrian of the
Southern Hemisphere Developments in Precambrian geology 2 edited by I R HUNTER
Amsterdam Elsevier p 105ndash203
GREY K and JACKSON M J 1983 A re-assessment of stromatolite evidence for the
correlation of the Late Proterozoic Neale and Ilma Beds Officer Basin Western Australia
Australia BMR Journal of Australian Geology and Geophysics v 8 p 359
42
HICKMAN A H WILLIAMS I R and BAGAS L 1994 Proterozoic geology and
mineralization of the TelferndashRudall region Paterson Orogen Geological Society of Australia
(WA Division) Excursion Guidebook no 5 56p
HOCKING R M MORY A J and WILLIAMS I R 1994 An atlas of Neoproterozoic and
Phanerozoic basins of Western Australia in The sedimentary basins of Western Australia
edited by P G PURCELL and R R PURCELL Petroleum Exploration Society of Australia
Symposium Perth WA 1994 Proceedings p 21ndash 44
JACKSON P R 1966 Geology and review of exploration Officer Basin Western Australia
Hunt Oil Company Western Australia Geological Survey S-series S26 (unpublished)
JACKSON M J 1971 Notes on a geological reconnaissance of the Officer Basin Western
Australia Australia BMR Geology and Geophysics Record 19715 30p
JACKSON M J and van de GRAAFF W J E 1981 Geology of the Officer Basin Western
Australia Australia BMR Geology and Geophysics Bulletin 206 102 p
LOWRY D C JACKSON M J van de GRAAFF W J E and KENNEWELL P J 1971
Preliminary result of geological mapping in the Officer Basin Western Australia Western
Australia Geological Survey Annual Report for 1971 p 50ndash56
MYERS J S 1990 Precambrian in Geology and mineral resources of Western Australia
Western Australia Geological Survey Memoir 3 p 737ndash750
MYERS J S SHAW R D and TYLER I M 1994 Proterozoic tectonic evolution of
Australia 12th Australian Geological Convention Geological Society of Australia Abstracts
no 37 p 312
NEDIN C and JENKINS R J F 1991 Re-evaluation of unconformities separating the
lsquoEdiacaranrsquo and Cambrian systems South Australia Palaios v 6 p 102ndash108
PHILLIPS B J JAMES A W and PHILIP G M 1985 The geology and hydrocarbon
potential of the north-western Officer Basin APEA Journal 25 (1) p 52ndash61
POWELL C McA LI Z X McELHINNY M W MEERT J G and PARK J K 1993
Paleomagnetic constraints on timing of the Neoproterozoic breakup of Rodinia and Cambrian
formation of Gondwana Geology v 21 p 889ndash892
43
POWELL C McA PREISS W V GATEHOUSE C G KRAPEZ B and LI Z X 1994
South Australian record of a Rodinian epicontinental basin and its mid-Neoproterozoic
breakup to form the Palaeo-Pacific Ocean Tectonophysics v 237 no 3ndash4 p 113ndash140
PREISS W V 1976 Proterozoic stromatolites from the Nabberu and Officer Basins Western
Australia and their biostratigraphic significance South Australia Geological Survey Report
of Investigations no 47 p 1ndash51
TOWNSON W G 1985 The subsurface geology of the western Officer Basin mdash results of
Shellrsquos 1980ndash1984 petroleum exploration campaign APEA Journal v 25 (1) p 34ndash51
WATTS K J 1982 The geology of the Townsend Quartzite Upper Proterozoic shallow water
deposit of the Northern Officer Basin Western Australia Perth University of Western
Australia BSc honours thesis (unpublished)
WELLS A T and KENNEWELL P J 1974 Evaporite exploration in the Officer Basin
Western Australia at the Madley Diapirs Australia BMR Record 1974194 (unpublished)
WILLIAMS I R and MYERS J S 1990 Paterson Orogen in Geology and mineral resources
of Western Australia Western Australia Geological Survey Memoir 3 p 274ndash286
WILLIAMS I R 1990 Savory Basin in Geology and mineral resources of Western Australia
Western Australia Geological Survey Memoir 3 p 329ndash334
WILLIAMS I R 1994 The Neoproterozoic Savory Basin Western Australia in The
sedimentary basins of Western Australia edited by P G PURCELL and R R PURCELL
Petroleum Exploration Society of Australia Symposium Perth WA 1994 Proceedings p
841ndash850
WILSON R B 1967 Woolnough Hills and Madley diapiric structures Gibson Desert WA
APEA Journal v 7 p 94ndash102
44
Appendix 2
Meteorological data (from Bureau of Meteorology Perth 1994)
Table 21 Wiluna rainfall (mm)
Year Jan Feb Mar Apr May Jun Jul Aug Sept Oct Nov Dec
1975 0 45 446 309 306 59 276 4 34 886 638 164 1976 16 154 12 138 53 16 34 62 12 238 0 2 1977 44 0 66 74 68 95 24 363 1 58 12 727 1978 234 522 94 16 0 96 367 24 16 353 185 45 1979 19 173 122 88 91 4 0 246 58 0 169 114 1980 148 764 68 1081 259 626 629 06 56 02 174 0 1981 123 476 192 32 196 118 44 74 14 0 28 312 1982 374 705 206 244 1079 92 02 143 368 526 368 118 1983 1 112 928 248 0 212 56 32 5 1 42 496 1984 149 7 342 84 836 0 348 132 224 04 16 172 1985 596 483 0 166 556 0 514 56 0 0 4 0 1986 0 154 35 0 0 1085 23 01 239 137 0 04 1987 1204 119 19 89 17 575 154 126 07 1 0 398 1988 46 202 164 13 388 0 202 104 0 0 224 1309 1989 207 234 26 703 278 536 57 0 01 0 144 02 1990 1035 23 281 46 126 53 94 218 44 9 42 0 1991 48 0 41 45 0 472 297 12 0 1 0 7 1992 112 96 1025 1227 323 65 04 174 0 132 48 4 1993 0 697 0 202 445 0 12 306 18 05 14 33 Mean 25 35 22 27 27 25 18 12 6 13 13 21
JAN FEB MAR APR MAY JUN JUL AUG SEP OCT NOV DEC0
10
20
30
40
Mea
n R
ain
fall
(mm
)
Month
Mean monthly rainfall in Wiluna
MKS41 140498
45
Table 22 Wiluna minimum temperature (degC)
Year Jan Feb Mar Apr May Jun Jul Aug Sept Oct Nov Dec
1975 ndash 23 203 15 94 63 71 62 103 124 169 205 1976 242 229 194 15 10 63 59 73 95 143 16 228 1977 243 25 197 148 96 95 56 86 102 ndash 188 23 1978 241 232 203 18 102 64 76 8 9 152 19 205 1979 255 226 216 167 83 6 59 79 97 145 198 223 1980 255 226 231 155 134 83 68 75 121 108 193 223 1981 245 216 19 182 119 6 54 78 138 159 163 218 1982 232 224 177 16 ndash ndash 37 111 112 164 209 225 1983 235 24 197 147 112 88 39 88 121 162 189 219 1984 241 243 191 156 ndash 72 66 7 95 161 182 211 1985 244 231 ndash 159 98 65 71 73 117 147 205 ndash 1986 ndash 229 226 155 93 96 43 49 10 122 ndash 219 1987 ndash 217 183 175 85 77 68 68 112 ndash ndash 221 1988 238 214 209 178 111 ndash ndash 86 104 157 171 195 1989 ndash 237 199 165 107 67 44 61 107 131 187 ndash 1990 232 ndash 211 155 118 62 57 87 102 149 195 22 1991 26 256 217 168 122 101 78 ndash 113 18 168 219 1992 227 227 214 169 102 98 59 69 ndash 125 159 196 1993 241 218 196 171 103 ndash 49 68 88 128 192 211 Mean 24 23 20 16 10 8 6 8 11 14 18 21
NOTE Dashes indicate data unavailable
JAN FEB MAR APR MAY JUN JUL AUG SEP OCT NOV DEC0
10
20
30
40
Month
MKS43 140498
50
Mean monthly minimum temperatures at Wiluna
Mea
n T
emp
erat
ure
(degC
)
46
Table 23 Wiluna maximum temperature (degC)
Year Jan Feb Mar Apr May Jun Jul Aug Sept Oct Nov Dec
1975 ndash 349 326 281 247 201 197 212 256 248 31 344 1976 374 369 346 297 248 206 208 225 265 287 313 388 1977 397 392 352 296 234 212 222 244 ndash 308 337 383 1978 378 345 346 316 242 195 176 205 231 295 334 356 1979 403 36 364 295 ndash ndash ndash 193 242 318 359 373 1980 392 342 377 275 24 176 179 233 292 288 349 391 1981 385 346 337 342 242 178 201 224 30 326 326 369 1982 372 359 315 307 ndash ndash 196 253 252 305 353 379 1983 381 389 327 272 263 222 187 248 287 321 336 366 1984 378 393 322 299 226 215 178 214 234 ndash 336 364 1985 40 366 ndash 294 224 216 205 212 284 307 355 ndash 1986 ndash 383 372 307 ndash 193 166 196 261 277 ndash 382 1987 ndash 339 328 305 21 202 214 218 275 ndash ndash 374 1988 388 365 353 301 23 ndash ndash 228 283 334 31 33 1989 ndash 375 339 285 238 179 181 219 275 298 336 ndash 1990 368 ndash 36 309 268 19 188 205 274 309 373 393 1991 414 416 363 315 268 206 21 ndash 279 338 332 368 1992 363 383 336 263 213 178 213 197 ndash 285 313 359 1993 396 357 344 301 221 ndash 197 215 253 294 347 362 Mean 39 37 34 30 24 20 20 22 27 30 34 37 NOTE Dashes indicate data unavailable
JAN FEB MAR APR MAY JUN JUL AUG SEP OCT NOV DEC0
10
20
30
40
Month
MKS42 140498
50
Mean monthly maximum temperatures at Wiluna
Mea
n T
emp
erat
ure
(degC
)
47
Appendix 3
Table 31 Summary of palynological results
Drillhole Depth (m) F no(a) GSWA no Lithology Formation Assemblage TAI(b)
BWB 1 74ndash75 F49668 135741 dark-grey siltstone basalt Jilyilli gt5 BWB 1 98ndash100 F49669 135742 dark-grey siltstone basalt Jilyilli gt5 BWB 1 121ndash122 F49670 135743 dark-grey siltstone basalt Jilyilli gt5 TWB 1 86ndash87 F49671 135631 dark-grey siltstone McFadden 3+ TWB 1 104ndash105 F49672 135632 dark-grey siltstone Cornelia 3+ TWB 1 121ndash122 F49673 135633 dark-grey siltstone Cornelia 4 TWB 2 14ndash15 F49674 135634 dark-grey siltstone Skates Hills 3+ TWB 6 49ndash50 F49675 135675 dark-grey siltstone Cornelia 1 3+ TWB 9 49ndash51 F49676 135704 dark-grey siltstone Brassey Range 1 3+ Trainor 1 37497- F49733 138939 black mudstone with Cornelia 5 37509 light-grey siltstone Trainor 1 3809 F49734 138940 dark-grey and black Cornelia 4- laminated mudstone Trainor 1 4170 F49735 138941 black unlaminated mudstone Cornelia 4- Trainor 1 4950 F49851 139501 dark-grey indurated siltstone Cornelia 5 Trainor 1 6032 F49852 139502 dark- and light-grey Cornelia 5 indurated siltstone Trainor 1 6434 F49853 139503 greenish indurated finely Cornelia 5 laminated siltstone LDDH 1 270 F49678 138934 dark-grey siltstone interbeds Waters 1 3+ in enterolithic evaporite Tarcunyah Gp LDDH 1 277 F49679 138935 dark-grey siltstone in cavity Waters 1 3+ in enterolithic evaporite Tarcunyah Gp
NOTES (a) GSWA Fossil Catalogue number (b) TAI = Thermal Alteration Index of Traverse (1988 plate 1)
48
Appendix 4
Savory Sub-basin quantitative magnetic and gravity interpretation (extracted from Cowan 1995)
Summary
A program of quantitative aeromagnetic interpretation has been completed on BMRAGSO data from the Savory Sub-
basin Western Australia Quantitative aeromagnetic interpretation utilized the 3D Euler deconvolution method
supported by wavenumber filtering and image processing The results have provided useful information on structural
trends and depth to magnetic sources in a structurally complex area Depth to magnetic source analysis has provided
information on intra-sedimentary magnetic sources as well as basement rocks
The results of the interpretation support previously identified depocentres However the presence of magnetic
sources at several levels makes it very difficult to produce a reliable magnetic basement depth contour map It is
considered more productive to work with the 3D Euler colour circle plots and images rather than trying to contour the
results It would be necessary to carry out a full-scale interpretation of the BMRAGSO profile data to improve on the
3D Euler results The regional gravity was found to be useful in interpreting the regional setting of the area although
the very wide data spacing limits quantitative use of the data The gravity data show quite a complex picture with
limited consistent correlation between gravity features and basin structures This suggests that gravity anomalies
reflect changes in density of the basement rocks rather than basement topography especially in the northern part of the
basin
It is recommended that the GSWA investigate access to company confidential high-resolution aeromagnetic data
prior to planning further aeromagnetic surveys Private companies have flown large parts of the northern half of the
area as part of their diamond exploration program Additional gravity coverage of the area may be more cost effective
than magnetic surveys as the gravity data provides more information on changes within the sedimentary section
Introduction
The main use of aeromagnetic data in petroleum exploration has been the determination of magnetic basement
topography although there has been increasing interest in analysis of intra-sedimentary magnetic anomalies
intrabasement and suprabasement magnetic anomalies These anomalies are used to determine depth to magnetic
basement rocks and hence determine the thickness of the sedimentary sequence Unfortunately interpretation of the
intrabasement and suprabasement magnetic anomalies is non-unique in terms of position and size of causative sources
because of the inherent ambiguity of potential-field methods However this ambiguity can be reduced by placing
49
constraints on source geometry and magnetization and by using geological and other geophysical data to constrain
the solution
Before 1970 most depth-determination techniques involved graphical determination of slopes of selected
magnetic anomalies and application of various empirical factors to convert the slopes into depth estimates Geological
Society of America Memoir 47 Interpretation of Aeromagnetic Maps by Vacquier et al (1951) was a landmark for
this type of interpretation
Automated interpretation procedures have played an increasingly important role in depth interpretation and a
wide range of techniques have been developed Many of these techniques are designed for application to located data
profiles and assume a two-dimensional geometry However there has been renewed interest in techniques applicable
to gridded data
Two distinct types of method can be recognized In the first case often described as discrete methods individual
isolated magnetic anomalies are interpreted and the results used to produce a map of basement relief In the second
case often described as continuous methods areas of data containing a number of anomalies are interpreted
statistically to produce direct output of basement depths
The discrete methods usually involve a semiautomatic initial phase which generates a large number of possible
depth solutions and an interactive second phase to screen and select acceptable solutions The advantage of this
approach is that the interpreter can select features that are relatively free from interference from adjacent anomalies
and consider all aspects of a particular magnetic anomaly The disadvantage is that interpretation can be very time
consuming as a wide range of depths are usually possible depending on the initial model chosen and a significant
amount of effort is needed to select the correct model In the case of the Savory Sub-basin dataset we encountered
problems in separating basement related effects from the effects of shallower intrasedimentary magnetic sources
Because of these problems we have concentrated on displaying the Euler results accompanied by separation filter
images of the data to show the shallower effects and deeper effects rather than trying to refine a 3D Euler
deconvolution depth-to-crystalline-basement contour
The continuous methods are very direct provided that the rather restrictive assumption can be made that all
anomalies are due to lateral magnetization changes due to basement topography This means that shallow effects and
large intrabasement anomalies must be removed from the data This involves judgement and skill as it is necessary to
distinguish between the lower amplitude suprabasement anomalies due to basement topography and the larger
intrabasement anomalies reflecting magnetization changes within the basement These methods were not considered
suitable for the Savory Sub-basin magnetic dataset but were used to invert the gravity data
50
Limitations of magnetic and gravity interpretation
Interpretation of the area is limited by a shortage of information on the nature and physical properties of the deeper
sedimentary sequence and the underlying basement rocks However using techniques such as cross-correlation of
gravity and pseudo-gravity data it is possible to try to differentiate between anomalies relating to basement and those
related to the sedimentary sequence
Gravity anomalies reflect changes within the sedimentary sequence as well as basement condition These
changes in density of sedimentary rocks produce gravity anomalies without a corresponding magnetic anomaly hence
the complementary nature of gravity and magnetic surveys The main use of magnetics is to determine depth to
magnetic basement and any intra-sedimentary volcanic rocks or intrusives whereas gravity provides much more
general information on the sedimentary sequence
Unfortunately interpretation of gravity anomalies is complicated since they can be due to a number of geological
features including
bull major basement faults
bull basement highs
bull igneous intrusions within the basement
bull sedimentary basins which may or may not be isostatically compensated
bull intra-sedimentary volcanics and associated plutonic centres
Two major problems affect the interpretation of both magnetic and gravity data
1 The inherent ambiguity of potential-field data There is no unique solution to any measured gravity or magnetic
anomaly and theoretically there will be an infinite number of source geometry and magnetizationdensity
combinations which will fit the observed data This means that any a priori information which helps to select a
suitable model is very useful
2 Measured anomalies are the summation of effects from different depths For example an observed gravity profile
may contain contributions from shallow sources (density variations within the sedimentary basin) intermediate
depth sources (density variations due to large igneous intrusions within the basement) and deep sources (crustal
thinning producing a mantle anomaly) Separation of these component responses is the regionalresidual problem
which we solve using spectral analysis and differential upward continuation-based separation filtering
Regional setting and interpretation overview
The area studied includes parts of BALFOUR DOWNS (SF51-9) RUDALL (SF51-10) ROBERTSON (SF51-13) GUNANYA
(SF51-14) COLLIER (SG50-4) BULLEN (SG51-1) TRAINOR (SG51-2) MADLEY (SG51-3) NABBERU (SG50-5)
STANLEY (SG51-6) and HERBERT (SG51-7) 1250 000 sheets Broadly the area lies between latitudes 22deg00rsquondash25deg30rsquoS
and longitudes 119deg30rsquondash123deg30rsquoE
51
Regional gravity
The AGSO regional gravity data (at nominal 11 km spacing) was gridded at a 4 km mesh spacing using a minimum-
curvature algorithm Bouguer gravity values in the area are negative reflecting mass deficiency at depth and range
from -84 mgals to -25 mgals
A Bouguer gravity colour image is shown as Figure 41 A residual grid was produced by removing a fifth-order
orthogonal polynomial from the Bouguer data but did not add to the interpretation
120deg 121deg 122deg 123deg
23deg
24deg
25deg
-25
-84
50 km
MKS46 180598
mgal
Figure 41 Regional Bouguer gravity (BMRAGSO data) gridded at 4 km
52
The data show a complex pattern of positive and negative anomalies with no clearly defined trends Correlations
with aeromagnetic data and known basin structures are poor A vague north-northwest linear trend appears to coincide
with the Marloo Fault (Figure 42) A prominent negative anomaly appears to coincide with the Blake Fold and Fault
Belt depocentre and continues as a narrower negative anomaly to the east until it widens out again near the edge of the
basin Elsewhere the gravity data show little correlation with known basin structures and it is likely that especially in
the north of the area gravity anomalies are due to density changes in the basement rather than changes in basement
topography
Production of wavelength-filtered residual gravity plots and vertical gradient plots showed very patchy aliased
data reflecting poor sampling in much of the area
Regional magnetics
The AGSO regional aeromagnetic data were gridded at a 400 m mesh spacing using a minimum-curvature algorithm
(Figure 43) Most of the data has a line spacing of 1600 m with small areas of 1 km spacing The quality of the data is
acceptable for regional interpretation but is not adequate for detailed analysis The accuracy of the flight path is rather
variable reflecting the vintage of the data and the noise envelope of the data is poor by modern standards Problems
were also encountered in joining different map sheets
The magnetic anomaly pattern over the south and west part of the area shows a strong high frequency signature
reflecting the presence of widespread basic sills and dykes Some of the major north-northeasterly trending dykes can
be traced over considerable distances
Discontinuous high-frequency anomalies extend as a northwest-trending zone through the centre of the area and
this zone includes a conspicuous circular magnetic anomaly which is probably a ring complex
The northern and eastern parts of the area are characterized by long-wavelength deep-seated basement magnetic
anomalies with 120deg and 150deg trends dominant The Marloo and Perentie Faults (Figure 42) appear as distinct linear
zones and offsets A prominent easterly trending negative anomaly in the northwest of the area appears to swing round
to the southeast and may separate different basement blocks One possible interpretation is that this very deep seated
anomaly separates areas of Archaean and Proterozoic basement
Regional geology
The regional geology is described in Williams (1992) The GSWA provided a digitized version of Plate 2 from this
Bulletin the structural interpretation map to use as an overlay (Figure 42)
53
Pp
Pp
PSd
PSd
PSd
PSd
PSd
PSo
PSt
PSt
PSf
PSf
PSf
PSb
PSb
PSb
PSsPSs
PSs
PSb
PSm
PSp
PSc
PSc
PSw
PSw
PSw
PSg
PSr
PSj
PSg
PM
Pk
PY
PY
PSd
L
L
L
L
L
L
L
LL
L
L
L
LL
L
LL
L L
LL
L L
L
L
L
L
L
L
L
LL
L
L
BLAKEDEPOCENTRE
MA
RLO
O
FAU
LT
PERENTIEFAULT
50 km
MKS39120598
120deg 121deg 122deg 123deg
25deg
24deg
23deg
Approximate boundaryof aeromagnetic interpretation
PML
PSgL
PSjL
PML
PSpL
PML
PML
PSfL
PSfL
PSpL
LPc
LPcLPcPSrL
LPA
Durba Sandstone
Woora Woora Formation
McFadden Formation
Tchukardine Formation
Boondawari Formation
Skates Hills Formation
Mundadjini Formation
Coondra Formation
Spearhole Formation
Watch Point Formation
Jilyili Formation
Brassey Range Formation
Glass Spring Formation
Paterson Formation
Yeneena Group
Karara Formation
Cornelia Formation
Kahrban Subgroup
Bangemall Group
Fault
Formation boundary
PSdL
PSoL
PSfL
PStL
PSbL
PSsL
PSmL
PScL
PSpL
PSwL
PSjL
PSrL
PSgL
Pp
PYL
PkL
LPc
LPA
PML
Savory Group Other Units
PYL
Figure 42 Regional geology and structure map (after Williams 1992)
54
120deg 121deg 122deg 123deg
23deg
24deg
25deg
5820
3750
MKS47 180598
nT
50 km
Figure 43 Regional aeromagnetic data total magnetic intensity (BMRAGSO data) gridded at 400 m
Analysis
3D analysis
3D Euler deconvolution was used as the primary depth-determination method The advantage of this approach is that
consistent solutions can be obtained over the entire area with minimal assumptions about source geometries Euler
deconvolution of gridded data is used for positional information and estimation of depth to top of source Euler
55
deconvolution yields a large number of depth solutions which have to be screened to reject spurious solutions Results
are plotted as circles in eight depth ranges with radius proportional to depth and colour coded
The 400 m total magnetic intensity grid was used for the analysis Horizontal gradients in x and y and the vertical
gradient were calculated 3D Euler deconvolution was tested on the 400 m gridded data using windows of 9 times 9 and
11 times 11 and 16 times 16 data points and structural indices 05 (fault) and 10 (sill or dyke) It was concluded that the
16 times 16 window produced the best results overall and final plots were produced for the 16 times 16 window and structural
index 05 (Fig 44) Results were very good over the northern and central parts of the area showing magnetic sources
Figure 44 Depth to magnetic source 3D Euler deconvolution 16 times 16 window of 400 m gridded data structural index 05
56
at several different levels Unfortunately in the extreme south of the area shallow intrasedimentary magnetic sources
(sills and dykes) dominated the inversion and the results contained few basement solutions
In order to reduce these problems the 400 m gridded data were filtered using a separation filter based on
interpretation of the log-energy spectrum The 3D Euler method was run on the filtered data in order to generate more
basement-depth solutions Results for the deep-separation filter data were gridded and presented as a colour image in
Cowan (1995) Attempts to grid the Euler output were unsatisfactory and it is considered safer to interpret the 3D
Euler depth plots The 3D Euler depth results from the separation-filter run should be analysed with care as perfect
separation of the basement can never be achieved and there will always be some contamination from sources at
different levels
The results of original total magnetic intensity 3D Euler depth estimation for structural index 05 using a 16 point
window have been plotted at 1500 000 scale (not included in this publication but available in Cowan (1995) from the
GSWA Library as S10331) and as reduced A4 colour circle plots (Figure 44)
The results of deep-basement 3D Euler depth estimation for structural index 05 using a 16 point window have
been plotted as a colour image at 1500 000 scale and as an A4 image (not included in this publication)
2D analysis
Two equispaced profiles were interpolated with a 50 m station interval from the AGSO-located data profiles for the
BULLEN 1250 000 sheet The interpolated profiles were analysed using 2D Euler deconvolution and Werner
deconvolution Results are included in Cowan (1995) and show the use of these methods for more detailed analysis
Filtered data
In order to reconcile 3D Euler results from shallow basement and intrasedimentary magnetic sources we produced
several separation-filtered maps and images We found the shallow-layer double-separation filter (Figure 45) to be
very effective for shallow sources and the deep-layer standard-separation filter (Figure 46) for the basement layer
Gravity and magnetic data correlation
Both lsquoreduced to the polersquo (RTP) magnetics (Figure 47) and pseudo-gravity data (Figure 48) were produced as part of
the reconciliation of gravity and magnetic signatures In both cases the filtering operations assumed magnetization by
induction in the present Earths field The RTP data are fairly similar to the total magnetic intensity The pseudo-
57
gravity data are dominated by a northwest-trending strong positive anomaly and there is little correlation with the
Bouguer gravity data
The poor magneticgravity correlation is confirmed by cross-correlation of the RTP magnetics and the gravity
gradient The correlation plot in Figure 49 shows little coherent response with numerous zones of positive and
negative correlation
Figure 45 Regional aeromagnetic data shallow layer separation filter (BMRAGSO data) gridded at 400 m
Results
In the north and east of the area on the Wells Foreland Sub-basin trend (refer to Figure 1 main text) we see a range
of quite deep 3D Euler depths and several trend directions with north-northwesterly dominant There are relatively few
shallow intrasedimentary solutions in this zone
The second area of deep 3D Euler solutions lies over the Blake depocentre (Figure 43) with several trend
directions
Elsewhere the 3D Euler results are dominated by shallow intrasedimentary depth solutions reflecting mainly the
dolerite sills dykes and the ring complex However where we do see basement-related solutions in the south and
west of the area they appear to be shallower than those noted for the Wells Foreland Sub-basin and the Blake
depocentre
58
Figure 46 Regional aeromagnetic data deep-layer separation filter (BMRAGSO data) gridded at 400 m
Figure 48 Regional aeromagnetic data pseudo-gravity transform (BMRAGSO data) gridded at 400 m
Figure 47 Regional aeromagnetic data reduced-to-pole (BMRAGSO data) gridded at 400 m
Figure 49 Regional aeromagnetic and gravity data gravitymagnetic correlation using RTP magnetics and gravity gradient (BMRAGSO data) gridded at 4 km
59
This subdivision of the area into two zones of deep solutions is consistent with interpreted depocentres
However the interference between sources at different levels and the complexity of the magnetic response of the
basement rocks precludes more refined interpretation at this stage
The area of deep 3D Euler solutions over the Blake depocentre correlates with the pronounced negative gravity
anomaly discussed in the gravity interpretation section Using a density contrast of -015 gcc the negative gravity
anomaly could indicate up to 6ndash8 km of low-density sedimentary rocks depending on assumptions about the regional
field
The area of deep 3D Euler solutions over the Wells Foreland Sub-basin has a complex gravity expression and no
clear basin structure emerges from inversion of these data As noted previously it is likely that observed gravity
anomalies reflect contrasts in basement density rather than basement topography
Separation filtering applied to the magnetic data helps to enhance the intrasedimentary magnetic signature and to
give a better impression of the basement magnetic signature even though separation of the basement response is not
perfect
Conclusions
Quantitative aeromagnetic interpretation using 3D Euler deconvolution supported by wavenumber filtering and image
processing has been successful in providing structural trend and depth information for the Savory Sub-basin
Quantitative magnetic interpretation has revealed two zones of relatively deep magnetic basement beneath the
Wells Foreland Sub-basin and the Blake depocentre
This analysis of the magnetic data supports interpreted depocentres but the complexity of the basement magnetic
signature and interference from sources at different depths precludes further refinement to a map of basement
topography
Regional gravity proved to be very useful in understanding the regional setting of the area and in providing
support for aspects of the interpretation The gravity data support the interpretation of the Blake depocentre
suggesting up to 6ndash8 km of low-density sedimentary rocks
The deep structure of the Savory Sub-basin area is obviously complex with different areas underlain by
Archaean and Proterozoic basement and with the Capricorn suture occurring in the centre of the area
60
Recommendations
The quantitative magnetic interpretation needs to be reconciled with geological models available for the area
In particular the zones tentatively identified as areas with thick sedimentary rocks the Wells Foreland Sub-
basin and the Blake depocentre need to be investigated
Cross sections should be prepared across the basin for joint magneticgravity modelling especially for the Blake
depocentre It is important to be able to explain the strong negative gravity anomaly in this area
In view of the effects of basement density contrasts on the gravity field for the northern part of the area we think
that additional gravity interpretation and acquisition of new gravity data may not be justified as they will not
contribute significantly to understanding basin evolution and structure
It is recommended that GSWA try to get access to company confidential high-resolution aeromagnetic data
rather than flying new surveys The GSWA might offer to fund flying of new infill areas as a bargaining point
References
The original text of this report by Cowan (1995) and 1500 000 scale maps are filed in the GSWA Library under
S10331
COWAN D 1995 Savory Basin quantitative magnetic interpretation Western Australia Geological Survey S-series
S10331 (unpublished)
VACQUIER V STEENLAND N C HENDERSON R G and ZIETZ I 1951 Interpretation of aeromagnetic
maps The Geological Society of America Memoir 47 151p
WILLIAMS I R 1992 Geology of the Savory Basin Western Australia Western Australia Geological Survey
Bulletin 141 115p
61
Appendix 5
Geochemistry
MKS38 250398
Saturate FractionC12+ GLC
1217
Pr18
Ph
22
31CSR WELL-13 315m Cuttings
Figure 51 Canning Stock Route Well 13 gas chromatograph of extract of auger drill sample
12
17
18
22
31
Pr Ph
LDDH 1 6623m CoreSaturate FractionC12+ GLC
MKS35 240398
Figure 52 Gas chromatograph of extract from core sample at 6623 m LDDH1
62
Table 51 Canning Stock Route Well 13 auger drill samples
GSWA sample Drill depth (m)(a) Comments
135601 150 At watertable 135602 203 (all samples consist 135603 310 of sand mud and water) 135604 315 At total depth
NOTE (a) Datum for drill depth is the top of sediment fill in the well which is 155 m below ground level (ie the total depth of 315 m is 47 m below ground level)
Table 52 Canning Stock Route Well 13 gas chromatography data for 315 m depth sediment sample
Parameter Value
Weight of rock extracted (grams) 945 Total extract (ppm) 519 n-Alkane distribution n-C12 07 n-C13 23 n-C14 26 n-C15 22 n-C16 19 n-C17 14 i-C19 23 n-C18 14 i-C20 08 n-C19 11 n-C20 16 n-C21 25 n-C22 29 n-C23 70 n-C24 42 n-C25 95 n-C26 43 n-C27 83 n-C28 38 n-C29 87 n-C30 31 n-C31 273 Alkane compositional data Pristane phytane ratio 279 Pristane n-C17 ratio 161 Phytane n-C18 ratio 059 CPI (1)(a) 284 CPI (2) 209 (C21 + C22) (C28 + C29) 043
NOTE (a) CPI= Carbon preference index
63
Table 53 LDDH1 extract liquid chromatography data for 6623 m concentration
Rock extracted Total extract (grams) (ppm)
702 313
NOTE ppm= parts per million
Table 54 LDDH1 saturate gas chromatography data of core for 6623 m alkane composition
Pristane Pristane Phytane (a) CPI (1) CPI (2) (C21+C22) Phytane n-C17 n-C18 (C28+C29)
103 026 024 103 102 325
NOTE (a)CPI = carbon preference index
Table 55 LDDH1 saturate gas chromatography data of core for 6623 m n-alkane distributions
Parameter Value
n-C12 17 n-C13 38 n-C14 55 n-C15 60 n-C16 65 n-C17 74 i-C19 19 n-C18 78 i-C20 19 n-C19 80 n-C20 79 n-C21 71 n-C22 64 n-C23 57 n-C25 43 n-C24 38 n-C27 31 n-C28 23 n-C29 19 n-C30 12 n-C31 10
64
Appendix 6
Table 61 Summary of data from Trainor waterbores (TWB) and Bullen waterbores (BWB)
Well AMG Elevation TD Status(b) Completion details Water Salinity Water level Flow rate Depth to consolidated AGD84 GL (m) (m) struck mgl(c) (m) (LHr) lithology aquifer(e) Z51(a) Interval (m) (100 mm PVC) (m) (mgl)(d)
TWB 1 473660E 453 122 comp 0ndash75 plain 63 7 300 24 2 880 12 m 7287404N 75ndash93 slotted (9 260) McFadden Fm 93ndash99 plain TWB 2 472 977E 475 23 abd nil 15 m 7285877N Skates Hills Fm dry TWB 3 473259E 475 50 abd nil 7 m 7285849N Skates Hills Fm dry TWB 4 463225 E 445 50 comp 0ndash22 plain 35 7 200 55 3 600 0 m 7286143N 22ndash34 slotted (8 140) Tertiary sand and gravel 23ndash60 plain TWB 5 463095E 445 31 comp 0ndash19 plain 13 26 000 655 3 600 Tertiary sand and gravel 7277721N 19ndash25 slotted (36 700) 25ndash31 plain TWB 6 457013E 455 50 comp 0ndash42 plain 38 920 119 600 0 m 7274352N 42ndash48 slotted (1 030) Cornelia Fm ss TWB 7 453739E 475 26 susp 0ndash2 plain 11 9 300 48 4 500 0 m 7263891N (10 500) Tertiary sand TWB 8 433893E 535 60 susp 0ndash2 plain 47 8 500 gt46 1 200 0 m 7245991N (10 900) Tertiary sand and Brassey Range Fm ss TWB 9 437219E 505 51 comp 0ndash47 plain 45 1 000 58 600 1 m 7235905N 47ndash51 slotted (990) Brassey Range Fm ss TWB 10 434927E 495 32 susp 0ndash2 plain 235 450 120 0 m 7225875N (500) Dolerite
65
BWB 1 287337E 580 122 abd Nil 1 m 7245861N Jilyili Fm dry BWB 2 288346E 545 50 comp 0ndash26 plain 15 630 3 29 000 0 m 7240423N 26ndash38 slotted (730) Tertiary sand and gravel 38ndash50 plain BWB 3 305637E 545 50 abd 19 8 800 43 7 200 0 m 7240423N (10 550) Tertiary ss BWB 4 320167E 515 445 comp 0ndash20 plain 9 980 445 24 000 0 m 7248097N 20ndash32 slotted (1 190) Tertiary ss 32ndash44 plain BWB 5 353393E 545 20 susp 0ndash2 plain 45 (970) 1 m 7238934N Basalt
NOTES (a) GPS accuracy ~ 150 m (b) Comp = completed abd = abandoned susp = suspended (c) Salinity from conductivity (d) Analysis total dissolved solids (e) Fm = Formation ss = sandstone
29
Oilmin NL drilled six percussion drillholes (BD 1 3 4 5 8 and 9) through sandstones and
shales in the northern part of the Savory Sub-basin to a maximum depth of 198 m (Fig 5
WAMEX Microfiche File M 26811 I 2610) but only brief geological descriptions are available
Hydrogeological data
Hydrogeological data within the Savory Sub-basin are limited although a long history of water
exploration extends back to the construction of the Canning Stock Route early this century No
detailed geological or wireline logs are available for the older wells along this route A few station
wells have been drilled by various methods on the south and west margins of the basin but data
are unavailable as reports are not required to be filed with the government Depth to watertable
throughout the basin is largely controlled by porosity of the bedrock
The GSWA drilled fifteen waterbores in the winter of 1995 in the southern part of the sub-
basin in preparation for the drilling of Trainor 1 and the proposed Bullen 1 Twelve bores found
water and six of these bores have salinities of less than 1000 mgL (Fig 5 Appendix 6 Table 61)
One waterbore TWB 6 has gamma ray and neutron logs run through PVC casing and these are
available from the GSWA with the digital log data included herein
Seismic data
No geophysical data have been acquired by the petroleum industry in the Savory Sub-basin
Seismic data acquired in the Officer Basin to the east particularly in the Gibson and Yowalga
Sub-basins is pertinent to structural interpretation in the Savory Sub-basin (Perincek 1996a
1998)
Aeromagnetic surveys
Government data
There are over 95 277 line kilometres of aeromagnetic data included in the AGSO dataset There
are three regional aeromagnetic surveys covering the Savory Sub-basin These were flown by the
Bureau of Mineral Resources (BMR now AGSO) in 1984 at a line spacing of 1500 m with 36 740
and 52 587 line kilometres flown and by Aerodata in 1984 at a line spacing of 1000m with 5950
line kilometres flown These data were reprocessed and interpreted for GSWA by Cowan (1995)
An edited copy of this report is included as Appendix 4 and the original report is filed in the
GSWA Library under S-series reports item 10331
30
Mineral industry data
The approximate locations of non-AGSO aeromagnetic surveys are shown in Figure 8 More
detailed information regarding the location of these surveys may be obtained using the GSWA
MAGCAT II database Additional information such as contours of aeromagnetic values may be
obtained by inspecting items on file with the GSWA
Gravity surveys
Government data
The average spacing for gravity data in the Savory Sub-basin is one station per 121 km2 (11 times 11
km grid) These data were principally collected by BMR in the early 1960s There are a few
additional regional gravity traverses across the sub-basin which are also included in the
BMRAGSO dataset These data were reprocessed and interpreted for GSWA (Fig 10) and a
report on this work is also included in Appendix 4
The GSWA completed a large semi-detailed gravity survey in the eastern Savory Sub-basin
utilizing helicopter support and Differential Global Positioning Survey (DGPS) techniques (Fig
8) This gravity survey completed in August 1995 consists of 2300 gravity stations on a 2 times 3 km
grid All stations were acquired by helicopter using Scintrex gravimeters and Ashtek dual
frequency DGPS equipment for determining location This highly efficient system allowed the
acquisition of more than 100 gravity stations per day in remote areas The resolution of this survey
is +30 cm and +05 microms-2 (Daishsat 1995) These data (Fig 11) represent a significant
improvement on the previous regional survey data and are available from GSWA (GSWA
1996ab) The results of the interpretation of these data were presented at the 1997 ASEG
Convention (Carlsen and Shevchenko 1997)
Mineral industry data
Three small gravity surveys were conducted by Oilmin NL (Fig 8) and the relevant WAMEX
reports are M 2681I 2610 I 2435 I 2567 These three surveys are of limited value because height
control was provided by barometers only and the surveys were not tied to the national gravity grid
31
23deg
25deg
120deg 122deg
Trainor 1
SAVORY
SUB-BASIN
MKS54 160498
100 km
1995 SavoryGravity Survey
254
-1056
micromsec2
Figure 10 Regional Bouguer gravity map of the Savory Sub-basin
23deg
24deg
25deg
122deg30 123deg
TRAINOR 1
123deg30
50 km
MKS53 160498
-116
-626
micro msec2
Figure11 Detailed Bouguer gravity map of the
Savory 1995 Gravity Survey from the eastern Savory Sub-basin
32
Government and academic reports
Chronostratigraphy and geochemistry
The understanding of Neoproterozoic organic chemistry palynology and structural evolution is
essential to the interpretation of hydrocarbon prospectivity Pertinent reports are included in the
bibliography (Appendix 1) Unpublished palaeontology reports describe the palynology of wells in
the Savory Sub-basin (Grey 1995andashe 1996a) Grey and Cotter (1996) discussed the potential for
Neoproterozoic palynomorphs to provide a biostratigraphic framework and palaeoenvironmental
interpretation Grey and Stevens (1997) reviewed the results of palynological studies of wells
drilled in the sub-basin and reported that Supersequence 1 palynomorphs are present in TWB 6
TWB 9 and LDDH1 (Appendix 3) Grey (1996b) reported on the use of stromatolites for
correlation in the Neoproterozoic and Stevens and Grey (1997) discussed the application of
stromatolite biostratigraphy in correlating isolated dolomite outcrops in the sub-basin with well
and seismic data in the Officer Basin and Centralian Superbasin
Although geochemical data from the Savory Sub-basin are very limited results mostly
confirm thermal maturities inferred from TAI for LDDH1 and Trainor 1 (Ghori in prep Stevens
and Adamides in prep) Those parts of the Officer Basin in Western Australia which lie to the
east of the Savory Sub-basin are sparsely drilled but Ghori (in prep) reports that most of the
Neoproterozoic succession presently lies within the oil-generative window However his study
has been unable to identify effective source-rock units and the source for oil shows Thin source
rocks are present in the Neoproterozoic in LDDH1 (Fig 9) and in three wells which lie to the east
and southeast of the Savory Sub-basin namely NJD 1 Kanpa 1A and Yowalga 3
Proposed work program
From the above limited information it is concluded that additional research on the hydrocarbon
potential of the sub-basin is justified and proposals are outlined below
bull Additional modelling of gravity and aeromagnetic data from the Savory Sub-basin is required
in light of the results from Trainor 1 and Boondawari 1 Trainor 1 showed that what appeared
to be a structurally simple area based on outcrop aeromagnetic and gravity data was in fact an
area of major structuring Boondawari 1 intersected a dolerite which is in good depth
agreement with aeromagnetic depth to source results showing this technique is useful in
detecting the depth to intrusive bodies
33
bull Additional data from mineral and petroleum exploration bores may become available and
analysis of samples from these wells should be undertaken and interpreted in the context of
their relevance to the Officer Basin
bull Stratigraphic coring in the Blake Fault and Fold Belt and in the Wells Foreland Sub-basin (Fig
1) targeting source rocks is considered essential to the continuing evaluation of the
hydrocarbon prospectivity of the Savory Sub-basin
bull Correlations using at least outcrop well and potential-field data should be prepared to link the
sub-basin with the better known parts of the Officer Basin to the east
bull Remapping is required to clarify boundary positions within the Cornelia Formation this may
resolve some of the current problems of the relationship between this unit and the rest of the
Savory Sub-basin
bull Further work is required to explain the Early Cambrian or Sturtian ages interpreted for the
Cornelia Formation from sedimentary zircon UndashPb dating in drillhole Trainor 1 The
determination of the age of the organically rich but overmature claystones in this well is
critical to assessing the hydrocarbon potential of the region
bull The thin dark mudstones intersected by Akubra 1 in the Mundadjini Formation warrant
geochemical analysis Analyses of the oil shows in Mundadjini 1 and Boondawari 1 are
currently being undertaken by Amadeus Petroleum
bull Geochemical analysis of hydrocarbons in the Bangemall Basin drillhole OD23 has been
performed by Jubilee Gold and the results will be reviewed when they are submitted to
GSWA The possibility of source rocks within the Bangemall Basin charging traps within the
Bangemall Basin and the overlying Savory Sub-basin requires further investigation
Conclusions
The Savory Sub-basin is a frontier region with only three recently drilled petroleum exploration
wells and no seismic data Based on existing geological and geophysical data it is considered too
early to draw conclusions about the hydrocarbon prospectivity of the sub-basin at this stage and
there are several reasons why the area warrants further investigation
34
1 Thick accumulations of sedimentary rocks are present (up to 8 km thickness inferred) which
may contain source reservoir and sealing strata
2 Minor oil shows occur in Mundadjini 1 and Boondawari 1 and bitumen is present in mineral
exploration drillhole LDDH1 suggesting that hydrocarbons have migrated within the
Neoproterozoic sequence of the Savory Sub-basin Oil and bitumen are present in mineral
exploration drillhole OD23 in the Bangemall Basin immediately to the south of the Savory
Sub-basin and it is possible that source rocks from the Bangemall Basin could charge traps in
the overlying Savory Sub-basin
3 The age of sedimentary rocks in the sub-basin is still poorly constrained but some of the
Neoproterozoic sedimentary rocks located on GUNANYA and TRAINOR are within the
hydrocarbon-generation window It is possible that a significant thickness of Phanerozoic
sedimentary rocks may also be present
4 Friable sandstones with visible porosity outcrop extensively suggesting numerous potential
reservoirs
5 Significant but not intense faulting and folding has been mapped implying large structural
traps may be present
6 Evaporitic sedimentary rocks occur in several formations and may provide good source rocks
and excellent seals
35
References
APAK S N and CARLSEN G M 1997 A compilation and review of data pertaining to the
hydrocarbon prospectivity of the Canning Basin Western Australia Geological Survey
Record 199610 103p
BAGAS L GREY K and WILLIAMS I R 1995 Reappraisal of the Paterson Orogen and
Savory Basin Western Australia Geological Survey Annual Review 1994ndash95 p 55ndash63
BUSBRIDGE M 1994 Lake Disappointment Exploration Licence 451064 Third Annual
Report Lake Disappointment Diamond Drill Hole LDDH1 Normandy Exploration Limited
Western Australia Geological Survey M-series Item 7567 A41358 (unpublished)
CARLSEN G M and SHEVCHENKO S I 1997 Petroleum exploration in Proterozoic basins
using potential fields data and stratigraphic coring Australian Society of Exploration
Geophysicists 12th Geophysical Conference Handbook Sydney 1997 Preview no 66 p 83
(abstract only)
COWAN D 1995 Savory Basin quantitative magnetic interpretation Western Australia
Geological Survey S-series S10331 (unpublished)
DAISHSAT PTY LTD 1995 Operational and processing report Savory Basin gravity survey
Western Australia Geological Survey S-series S10332 (unpublished)
GARD E and GARD R 1990 Canning Stock Route a travellerrsquos guide for a journey through
history Perth Western Australia Western Desert Guides 448p
GEOLOGICAL SURVEY OF WESTERN AUSTRALIA 1996a Savory Basin first vertical
derivative of Bouguer gravity image 1250 000 Western Australia Geological Survey
GEOLOGICAL SURVEY OF WESTERN AUSTRALIA 1996b Savory Basin Bouguer gravity
image 1250 000 Western Australia Geological Survey
GHORI K A R in prep Petroleum source rock potential and thermal history Officer Basin
Western Australia Western Australia Geological Survey Record
36
GREY K 1995a Savory Basin drillhole BWB 1 (Bullen waterbore) palynology and thermal
maturation GSWA Palaeontology Report no 199512 (unpublished)
GREY K 1995b Savory Basin drillholes TWB 1 2 6 9 (Trainor waterbores) palynology and
thermal maturation GSWA Palaeontology Report no 199520 (unpublished)
GREY K 1995c Palynology of Normandy-Poseidon Lake Disappointment-1 corehole
Tarcunyah Group Paterson Orogen GSWA Palaeontology Report no 199521 (unpublished)
GREY K 1995d Savory Basin drillhole Trainor 1 (Trainor diamond drilling) palynology and
thermal maturity GSWA Palaeontology Report no 199524 (unpublished)
GREY K 1995e Savory Basin drillhole Trainor 1 (Trainor diamond drilling) Additional
Preparation of two samples GSWA Palaeontology Report no 199528 (unpublished)
GREY K 1995f Neoproterozoic stromatolites from the Skates Hills Formation Savory Basin
Western Australia and a review of the distribution of Acaciella australica Australian Journal
of Earth Sciences v 42 p 123ndash132
GREY K 1996a Savory Basin drillhole Trainor 1 (Trainor diamond drilling) Additional
samples palynology and thermal maturation GSWA Palaeontology Report no 199615
(unpublished)
GREY K 1996b Preliminary stromatolite correlations for the Neoproterozoic of the Officer
Basin and a review of Australia-wide correlations GSWA Palaeontology Report no 199615
(unpublished)
GREY K and COTTER K L 1996 Palynology in the search for Proterozoic hydrocarbons
Western Australia Geological Survey Annual Review for 1995ndash96 p 70ndash80
GREY K and STEVENS M K 1997 Neoproterozoic palynomorphs of the Savory Sub-basin
Western Australia and their relevance to petroleum exploration Western Australia
Geological Survey Annual Review for 1996ndash97 p 49ndash54
HUBBARD R J PAPE J and ROBERTS D G 1985 Depositional sequence mapping as a
technique to establish tectonic and stratigraphic framework and evaluate hydrocarbon
potential on a passive continental margin in Seismic stratigraphy II an integrated approach
37
edited by O R BERG and D G WOOLVERTON American Association of Petroleum
Geologists Memoir 39 p 79ndash91
LIBBY WG 1995 A petrological report on six samples of bore cuttings from the Savory Basin
Western Australia Western Australia Geological Survey S-series S31307 (unpublished)
MORTON JGG and DREXEL JF 1997 The petroleum geology of South Australia Vol 3
Officer Basin South Australia Department of Mines and Energy Resources Report Book
9719
MUHLING P C and BRAKEL A T 1985 Geology of the Bangemall Group mdash the evolution
of an intracratonic Proterozoic basin Western Australia Geological Survey Bulletin 128
219p
MYERS J S 1990 Precambrian tectonic evolution of part of Gondwana southwestern Australia
Geology v18 p 537ndash540
NELSON D R 1997 Compilation of SHRIMP UndashPb zircon data Western Australia Geological
Survey Record 19972 196p
PAYTON C E 1977 Seismic stratigraphy mdash applications to hydrocarbon exploration
American Association of Petroleum Geologists Memoir 26 516p
PERINCEK D 1996a The age of NeoproterozoicndashPalaeozoic sediments within the Officer Basin
of the Centralian Super-basin can be constrained by major sequence-bounding unconformities
APPEA Journal v 36 pt 1 p 350ndash368
PERINCEK D 1996b The stratigraphic and structural development of the Officer Basin
Western Australia a review Western Australia Geological Survey Annual Review 1995ndash
1996 p 135ndash148
PERINCEK D 1998 A compilation and review of data pertaining to the hydrocarbon
prospectivity of the Officer Basin Western Australia Geological Survey Record 19976
POSAMENTIER H W JERSEY M T and VAIL P R 1988 Eustatic controls on clastic
deposition 1 mdash Conceptual framework in Sea-level changes an integrated approach edited by
C K WILGUS B S HASTINGS C G St C KENDALL H W POSAMENTIER
38
C A ROSS and J C VAN WAGONER Society of Economic Paleontologists and
Mineralogists Special Publication no 42
STEVENS M K and ADAMIDES N G in prep GSWA Trainor 1 well completion report
Savory Sub-basin Officer Basin Western Australia with notes on petroleum and mineral
potential Western Australia Geological Survey Record 199612
STEVENS M K and GREY K 1997 Skates Hills Formation and Tarcunyah Group Officer
Basin mdash carbonate cycles stratigraphic position and hydrocarbon prospectivity Western
Australia Geological Survey Annual Review for 1996ndash97 p 55ndash60
SUMMONS RE and POWELL C McA 1991 Petroleum source rocks of the Amadeus Basin
in Geological and geophysical studies in the Amadeus Basin central Australia edited by R J
KORSCH and JM KENNARD Australia BMR Geology and Geophysics Bulletin 236
TRAVERSE A 1988 Palaeopalynology Boston Unwin Hyman 600p
VAIL P R MITCHUM R M Jr TODD R G WIDMIER J M THOMPSON S III
SANGREE J B BUBB J N and HATLELID W G 1977 Seismic stratigraphy and
global changes of sea level in Seismic stratigraphy mdash applications to hydrocarbon
exploration edited by C E PAYTON American Association of Petroleum Geologists
Memoir 26 516p
WALTER M R and GORTER J 1994 The Neoproterozoic Centralian Superbasin in Western
Australia the Savory and Officer Basins in The sedimentary basins of Western Australia
edited by P G PURCELL and R R PURCELL Petroleum Exploration Society of Australia
Symposium Perth WA 1994 Proceedings p851ndash864
WALTER M R GREY K WILLIAMS I R and CALVER C R 1994 Stratigraphy of the
Neoproterozoic to early Palaeozoic Savory Basin and correlation with the Amadeus and
Officer Basins Australian Journal of Earth Sciences v 41 p 533ndash546
WALTER M R VEEVERS J J CALVER C R and GREY K 1995 Neoproterozoic
stratigraphy of the Centralian Superbasin Australia Precambrian Research v 73 p 173ndash195
WILLIAMS I R 1992 Geology of the Savory Basin Western Australia Western Australia
Geological Survey Bulletin 141 115p
39
WILLIAMS I R 1995a Bullen WA (2nd Edition) Western Australia Geological Survey
1250 000 Geological Series Explanatory Notes 23p
WILLIAMS I R 1995b Trainor WA (2nd Edition) Western Australia Geological Survey
1250 000 Geological Series Explanatory Notes 31p
WILLIAMS I R and TYLER I M 1991 Robertson WA (2nd edition) Western Australia
Geological Survey 1250 000 Geological Series Explanatory Notes 36p
40
41
Appendix 1
Bibliography
Reports which are relevant to this investigation but which are not specifically cited are listed
below
BAILLIE P W POWELL C McA LI Z X and RYALL A M 1994 The tectonic
framework of Western Australiarsquos Neoproterozoic to recent sedimentary basins in The
sedimentary basins of Western Australia edited by P G PURCELL and R R PURCELL
Petroleum Exploration Society of Australia Symposium Perth WA 1994 Proceedings p
45ndash62
BRADSHAW M T BRADSHAW J MURRAY A P NEEDHAM D J SPENCER L
SUMMONS R E WILMOT J and WINN S 1994 Petroleum systems in West Australian
basins in The sedimentary basins of Western Australia edited by P G PURCELL and R R
PURCELL Petroleum Exploration Society of Australia Symposium Perth WA 1994
Proceedings p 93ndash118
CLARKE G L 1991 Proterozoic tectonic reworking in the Rudall Complex Western Australia
Australian Journal of Earth Science v38 p 31ndash44
COCKBAIN A E and HOCKING R M 1990 Phanerozoic in Geology and mineral resources
of Western Australia Western Australia Geological Survey Memoir 3 p 750ndash755
ETHERIDGE M and WALL V 1994 Tectonic and structural evolution of the Australian
Proterozoic 12th Australian Geological Convention Geological Society of Australia
Abstracts no 37 p 102ndash103
GOODE A D T 1981 Proterozoic geology of Western Australia in Precambrian of the
Southern Hemisphere Developments in Precambrian geology 2 edited by I R HUNTER
Amsterdam Elsevier p 105ndash203
GREY K and JACKSON M J 1983 A re-assessment of stromatolite evidence for the
correlation of the Late Proterozoic Neale and Ilma Beds Officer Basin Western Australia
Australia BMR Journal of Australian Geology and Geophysics v 8 p 359
42
HICKMAN A H WILLIAMS I R and BAGAS L 1994 Proterozoic geology and
mineralization of the TelferndashRudall region Paterson Orogen Geological Society of Australia
(WA Division) Excursion Guidebook no 5 56p
HOCKING R M MORY A J and WILLIAMS I R 1994 An atlas of Neoproterozoic and
Phanerozoic basins of Western Australia in The sedimentary basins of Western Australia
edited by P G PURCELL and R R PURCELL Petroleum Exploration Society of Australia
Symposium Perth WA 1994 Proceedings p 21ndash 44
JACKSON P R 1966 Geology and review of exploration Officer Basin Western Australia
Hunt Oil Company Western Australia Geological Survey S-series S26 (unpublished)
JACKSON M J 1971 Notes on a geological reconnaissance of the Officer Basin Western
Australia Australia BMR Geology and Geophysics Record 19715 30p
JACKSON M J and van de GRAAFF W J E 1981 Geology of the Officer Basin Western
Australia Australia BMR Geology and Geophysics Bulletin 206 102 p
LOWRY D C JACKSON M J van de GRAAFF W J E and KENNEWELL P J 1971
Preliminary result of geological mapping in the Officer Basin Western Australia Western
Australia Geological Survey Annual Report for 1971 p 50ndash56
MYERS J S 1990 Precambrian in Geology and mineral resources of Western Australia
Western Australia Geological Survey Memoir 3 p 737ndash750
MYERS J S SHAW R D and TYLER I M 1994 Proterozoic tectonic evolution of
Australia 12th Australian Geological Convention Geological Society of Australia Abstracts
no 37 p 312
NEDIN C and JENKINS R J F 1991 Re-evaluation of unconformities separating the
lsquoEdiacaranrsquo and Cambrian systems South Australia Palaios v 6 p 102ndash108
PHILLIPS B J JAMES A W and PHILIP G M 1985 The geology and hydrocarbon
potential of the north-western Officer Basin APEA Journal 25 (1) p 52ndash61
POWELL C McA LI Z X McELHINNY M W MEERT J G and PARK J K 1993
Paleomagnetic constraints on timing of the Neoproterozoic breakup of Rodinia and Cambrian
formation of Gondwana Geology v 21 p 889ndash892
43
POWELL C McA PREISS W V GATEHOUSE C G KRAPEZ B and LI Z X 1994
South Australian record of a Rodinian epicontinental basin and its mid-Neoproterozoic
breakup to form the Palaeo-Pacific Ocean Tectonophysics v 237 no 3ndash4 p 113ndash140
PREISS W V 1976 Proterozoic stromatolites from the Nabberu and Officer Basins Western
Australia and their biostratigraphic significance South Australia Geological Survey Report
of Investigations no 47 p 1ndash51
TOWNSON W G 1985 The subsurface geology of the western Officer Basin mdash results of
Shellrsquos 1980ndash1984 petroleum exploration campaign APEA Journal v 25 (1) p 34ndash51
WATTS K J 1982 The geology of the Townsend Quartzite Upper Proterozoic shallow water
deposit of the Northern Officer Basin Western Australia Perth University of Western
Australia BSc honours thesis (unpublished)
WELLS A T and KENNEWELL P J 1974 Evaporite exploration in the Officer Basin
Western Australia at the Madley Diapirs Australia BMR Record 1974194 (unpublished)
WILLIAMS I R and MYERS J S 1990 Paterson Orogen in Geology and mineral resources
of Western Australia Western Australia Geological Survey Memoir 3 p 274ndash286
WILLIAMS I R 1990 Savory Basin in Geology and mineral resources of Western Australia
Western Australia Geological Survey Memoir 3 p 329ndash334
WILLIAMS I R 1994 The Neoproterozoic Savory Basin Western Australia in The
sedimentary basins of Western Australia edited by P G PURCELL and R R PURCELL
Petroleum Exploration Society of Australia Symposium Perth WA 1994 Proceedings p
841ndash850
WILSON R B 1967 Woolnough Hills and Madley diapiric structures Gibson Desert WA
APEA Journal v 7 p 94ndash102
44
Appendix 2
Meteorological data (from Bureau of Meteorology Perth 1994)
Table 21 Wiluna rainfall (mm)
Year Jan Feb Mar Apr May Jun Jul Aug Sept Oct Nov Dec
1975 0 45 446 309 306 59 276 4 34 886 638 164 1976 16 154 12 138 53 16 34 62 12 238 0 2 1977 44 0 66 74 68 95 24 363 1 58 12 727 1978 234 522 94 16 0 96 367 24 16 353 185 45 1979 19 173 122 88 91 4 0 246 58 0 169 114 1980 148 764 68 1081 259 626 629 06 56 02 174 0 1981 123 476 192 32 196 118 44 74 14 0 28 312 1982 374 705 206 244 1079 92 02 143 368 526 368 118 1983 1 112 928 248 0 212 56 32 5 1 42 496 1984 149 7 342 84 836 0 348 132 224 04 16 172 1985 596 483 0 166 556 0 514 56 0 0 4 0 1986 0 154 35 0 0 1085 23 01 239 137 0 04 1987 1204 119 19 89 17 575 154 126 07 1 0 398 1988 46 202 164 13 388 0 202 104 0 0 224 1309 1989 207 234 26 703 278 536 57 0 01 0 144 02 1990 1035 23 281 46 126 53 94 218 44 9 42 0 1991 48 0 41 45 0 472 297 12 0 1 0 7 1992 112 96 1025 1227 323 65 04 174 0 132 48 4 1993 0 697 0 202 445 0 12 306 18 05 14 33 Mean 25 35 22 27 27 25 18 12 6 13 13 21
JAN FEB MAR APR MAY JUN JUL AUG SEP OCT NOV DEC0
10
20
30
40
Mea
n R
ain
fall
(mm
)
Month
Mean monthly rainfall in Wiluna
MKS41 140498
45
Table 22 Wiluna minimum temperature (degC)
Year Jan Feb Mar Apr May Jun Jul Aug Sept Oct Nov Dec
1975 ndash 23 203 15 94 63 71 62 103 124 169 205 1976 242 229 194 15 10 63 59 73 95 143 16 228 1977 243 25 197 148 96 95 56 86 102 ndash 188 23 1978 241 232 203 18 102 64 76 8 9 152 19 205 1979 255 226 216 167 83 6 59 79 97 145 198 223 1980 255 226 231 155 134 83 68 75 121 108 193 223 1981 245 216 19 182 119 6 54 78 138 159 163 218 1982 232 224 177 16 ndash ndash 37 111 112 164 209 225 1983 235 24 197 147 112 88 39 88 121 162 189 219 1984 241 243 191 156 ndash 72 66 7 95 161 182 211 1985 244 231 ndash 159 98 65 71 73 117 147 205 ndash 1986 ndash 229 226 155 93 96 43 49 10 122 ndash 219 1987 ndash 217 183 175 85 77 68 68 112 ndash ndash 221 1988 238 214 209 178 111 ndash ndash 86 104 157 171 195 1989 ndash 237 199 165 107 67 44 61 107 131 187 ndash 1990 232 ndash 211 155 118 62 57 87 102 149 195 22 1991 26 256 217 168 122 101 78 ndash 113 18 168 219 1992 227 227 214 169 102 98 59 69 ndash 125 159 196 1993 241 218 196 171 103 ndash 49 68 88 128 192 211 Mean 24 23 20 16 10 8 6 8 11 14 18 21
NOTE Dashes indicate data unavailable
JAN FEB MAR APR MAY JUN JUL AUG SEP OCT NOV DEC0
10
20
30
40
Month
MKS43 140498
50
Mean monthly minimum temperatures at Wiluna
Mea
n T
emp
erat
ure
(degC
)
46
Table 23 Wiluna maximum temperature (degC)
Year Jan Feb Mar Apr May Jun Jul Aug Sept Oct Nov Dec
1975 ndash 349 326 281 247 201 197 212 256 248 31 344 1976 374 369 346 297 248 206 208 225 265 287 313 388 1977 397 392 352 296 234 212 222 244 ndash 308 337 383 1978 378 345 346 316 242 195 176 205 231 295 334 356 1979 403 36 364 295 ndash ndash ndash 193 242 318 359 373 1980 392 342 377 275 24 176 179 233 292 288 349 391 1981 385 346 337 342 242 178 201 224 30 326 326 369 1982 372 359 315 307 ndash ndash 196 253 252 305 353 379 1983 381 389 327 272 263 222 187 248 287 321 336 366 1984 378 393 322 299 226 215 178 214 234 ndash 336 364 1985 40 366 ndash 294 224 216 205 212 284 307 355 ndash 1986 ndash 383 372 307 ndash 193 166 196 261 277 ndash 382 1987 ndash 339 328 305 21 202 214 218 275 ndash ndash 374 1988 388 365 353 301 23 ndash ndash 228 283 334 31 33 1989 ndash 375 339 285 238 179 181 219 275 298 336 ndash 1990 368 ndash 36 309 268 19 188 205 274 309 373 393 1991 414 416 363 315 268 206 21 ndash 279 338 332 368 1992 363 383 336 263 213 178 213 197 ndash 285 313 359 1993 396 357 344 301 221 ndash 197 215 253 294 347 362 Mean 39 37 34 30 24 20 20 22 27 30 34 37 NOTE Dashes indicate data unavailable
JAN FEB MAR APR MAY JUN JUL AUG SEP OCT NOV DEC0
10
20
30
40
Month
MKS42 140498
50
Mean monthly maximum temperatures at Wiluna
Mea
n T
emp
erat
ure
(degC
)
47
Appendix 3
Table 31 Summary of palynological results
Drillhole Depth (m) F no(a) GSWA no Lithology Formation Assemblage TAI(b)
BWB 1 74ndash75 F49668 135741 dark-grey siltstone basalt Jilyilli gt5 BWB 1 98ndash100 F49669 135742 dark-grey siltstone basalt Jilyilli gt5 BWB 1 121ndash122 F49670 135743 dark-grey siltstone basalt Jilyilli gt5 TWB 1 86ndash87 F49671 135631 dark-grey siltstone McFadden 3+ TWB 1 104ndash105 F49672 135632 dark-grey siltstone Cornelia 3+ TWB 1 121ndash122 F49673 135633 dark-grey siltstone Cornelia 4 TWB 2 14ndash15 F49674 135634 dark-grey siltstone Skates Hills 3+ TWB 6 49ndash50 F49675 135675 dark-grey siltstone Cornelia 1 3+ TWB 9 49ndash51 F49676 135704 dark-grey siltstone Brassey Range 1 3+ Trainor 1 37497- F49733 138939 black mudstone with Cornelia 5 37509 light-grey siltstone Trainor 1 3809 F49734 138940 dark-grey and black Cornelia 4- laminated mudstone Trainor 1 4170 F49735 138941 black unlaminated mudstone Cornelia 4- Trainor 1 4950 F49851 139501 dark-grey indurated siltstone Cornelia 5 Trainor 1 6032 F49852 139502 dark- and light-grey Cornelia 5 indurated siltstone Trainor 1 6434 F49853 139503 greenish indurated finely Cornelia 5 laminated siltstone LDDH 1 270 F49678 138934 dark-grey siltstone interbeds Waters 1 3+ in enterolithic evaporite Tarcunyah Gp LDDH 1 277 F49679 138935 dark-grey siltstone in cavity Waters 1 3+ in enterolithic evaporite Tarcunyah Gp
NOTES (a) GSWA Fossil Catalogue number (b) TAI = Thermal Alteration Index of Traverse (1988 plate 1)
48
Appendix 4
Savory Sub-basin quantitative magnetic and gravity interpretation (extracted from Cowan 1995)
Summary
A program of quantitative aeromagnetic interpretation has been completed on BMRAGSO data from the Savory Sub-
basin Western Australia Quantitative aeromagnetic interpretation utilized the 3D Euler deconvolution method
supported by wavenumber filtering and image processing The results have provided useful information on structural
trends and depth to magnetic sources in a structurally complex area Depth to magnetic source analysis has provided
information on intra-sedimentary magnetic sources as well as basement rocks
The results of the interpretation support previously identified depocentres However the presence of magnetic
sources at several levels makes it very difficult to produce a reliable magnetic basement depth contour map It is
considered more productive to work with the 3D Euler colour circle plots and images rather than trying to contour the
results It would be necessary to carry out a full-scale interpretation of the BMRAGSO profile data to improve on the
3D Euler results The regional gravity was found to be useful in interpreting the regional setting of the area although
the very wide data spacing limits quantitative use of the data The gravity data show quite a complex picture with
limited consistent correlation between gravity features and basin structures This suggests that gravity anomalies
reflect changes in density of the basement rocks rather than basement topography especially in the northern part of the
basin
It is recommended that the GSWA investigate access to company confidential high-resolution aeromagnetic data
prior to planning further aeromagnetic surveys Private companies have flown large parts of the northern half of the
area as part of their diamond exploration program Additional gravity coverage of the area may be more cost effective
than magnetic surveys as the gravity data provides more information on changes within the sedimentary section
Introduction
The main use of aeromagnetic data in petroleum exploration has been the determination of magnetic basement
topography although there has been increasing interest in analysis of intra-sedimentary magnetic anomalies
intrabasement and suprabasement magnetic anomalies These anomalies are used to determine depth to magnetic
basement rocks and hence determine the thickness of the sedimentary sequence Unfortunately interpretation of the
intrabasement and suprabasement magnetic anomalies is non-unique in terms of position and size of causative sources
because of the inherent ambiguity of potential-field methods However this ambiguity can be reduced by placing
49
constraints on source geometry and magnetization and by using geological and other geophysical data to constrain
the solution
Before 1970 most depth-determination techniques involved graphical determination of slopes of selected
magnetic anomalies and application of various empirical factors to convert the slopes into depth estimates Geological
Society of America Memoir 47 Interpretation of Aeromagnetic Maps by Vacquier et al (1951) was a landmark for
this type of interpretation
Automated interpretation procedures have played an increasingly important role in depth interpretation and a
wide range of techniques have been developed Many of these techniques are designed for application to located data
profiles and assume a two-dimensional geometry However there has been renewed interest in techniques applicable
to gridded data
Two distinct types of method can be recognized In the first case often described as discrete methods individual
isolated magnetic anomalies are interpreted and the results used to produce a map of basement relief In the second
case often described as continuous methods areas of data containing a number of anomalies are interpreted
statistically to produce direct output of basement depths
The discrete methods usually involve a semiautomatic initial phase which generates a large number of possible
depth solutions and an interactive second phase to screen and select acceptable solutions The advantage of this
approach is that the interpreter can select features that are relatively free from interference from adjacent anomalies
and consider all aspects of a particular magnetic anomaly The disadvantage is that interpretation can be very time
consuming as a wide range of depths are usually possible depending on the initial model chosen and a significant
amount of effort is needed to select the correct model In the case of the Savory Sub-basin dataset we encountered
problems in separating basement related effects from the effects of shallower intrasedimentary magnetic sources
Because of these problems we have concentrated on displaying the Euler results accompanied by separation filter
images of the data to show the shallower effects and deeper effects rather than trying to refine a 3D Euler
deconvolution depth-to-crystalline-basement contour
The continuous methods are very direct provided that the rather restrictive assumption can be made that all
anomalies are due to lateral magnetization changes due to basement topography This means that shallow effects and
large intrabasement anomalies must be removed from the data This involves judgement and skill as it is necessary to
distinguish between the lower amplitude suprabasement anomalies due to basement topography and the larger
intrabasement anomalies reflecting magnetization changes within the basement These methods were not considered
suitable for the Savory Sub-basin magnetic dataset but were used to invert the gravity data
50
Limitations of magnetic and gravity interpretation
Interpretation of the area is limited by a shortage of information on the nature and physical properties of the deeper
sedimentary sequence and the underlying basement rocks However using techniques such as cross-correlation of
gravity and pseudo-gravity data it is possible to try to differentiate between anomalies relating to basement and those
related to the sedimentary sequence
Gravity anomalies reflect changes within the sedimentary sequence as well as basement condition These
changes in density of sedimentary rocks produce gravity anomalies without a corresponding magnetic anomaly hence
the complementary nature of gravity and magnetic surveys The main use of magnetics is to determine depth to
magnetic basement and any intra-sedimentary volcanic rocks or intrusives whereas gravity provides much more
general information on the sedimentary sequence
Unfortunately interpretation of gravity anomalies is complicated since they can be due to a number of geological
features including
bull major basement faults
bull basement highs
bull igneous intrusions within the basement
bull sedimentary basins which may or may not be isostatically compensated
bull intra-sedimentary volcanics and associated plutonic centres
Two major problems affect the interpretation of both magnetic and gravity data
1 The inherent ambiguity of potential-field data There is no unique solution to any measured gravity or magnetic
anomaly and theoretically there will be an infinite number of source geometry and magnetizationdensity
combinations which will fit the observed data This means that any a priori information which helps to select a
suitable model is very useful
2 Measured anomalies are the summation of effects from different depths For example an observed gravity profile
may contain contributions from shallow sources (density variations within the sedimentary basin) intermediate
depth sources (density variations due to large igneous intrusions within the basement) and deep sources (crustal
thinning producing a mantle anomaly) Separation of these component responses is the regionalresidual problem
which we solve using spectral analysis and differential upward continuation-based separation filtering
Regional setting and interpretation overview
The area studied includes parts of BALFOUR DOWNS (SF51-9) RUDALL (SF51-10) ROBERTSON (SF51-13) GUNANYA
(SF51-14) COLLIER (SG50-4) BULLEN (SG51-1) TRAINOR (SG51-2) MADLEY (SG51-3) NABBERU (SG50-5)
STANLEY (SG51-6) and HERBERT (SG51-7) 1250 000 sheets Broadly the area lies between latitudes 22deg00rsquondash25deg30rsquoS
and longitudes 119deg30rsquondash123deg30rsquoE
51
Regional gravity
The AGSO regional gravity data (at nominal 11 km spacing) was gridded at a 4 km mesh spacing using a minimum-
curvature algorithm Bouguer gravity values in the area are negative reflecting mass deficiency at depth and range
from -84 mgals to -25 mgals
A Bouguer gravity colour image is shown as Figure 41 A residual grid was produced by removing a fifth-order
orthogonal polynomial from the Bouguer data but did not add to the interpretation
120deg 121deg 122deg 123deg
23deg
24deg
25deg
-25
-84
50 km
MKS46 180598
mgal
Figure 41 Regional Bouguer gravity (BMRAGSO data) gridded at 4 km
52
The data show a complex pattern of positive and negative anomalies with no clearly defined trends Correlations
with aeromagnetic data and known basin structures are poor A vague north-northwest linear trend appears to coincide
with the Marloo Fault (Figure 42) A prominent negative anomaly appears to coincide with the Blake Fold and Fault
Belt depocentre and continues as a narrower negative anomaly to the east until it widens out again near the edge of the
basin Elsewhere the gravity data show little correlation with known basin structures and it is likely that especially in
the north of the area gravity anomalies are due to density changes in the basement rather than changes in basement
topography
Production of wavelength-filtered residual gravity plots and vertical gradient plots showed very patchy aliased
data reflecting poor sampling in much of the area
Regional magnetics
The AGSO regional aeromagnetic data were gridded at a 400 m mesh spacing using a minimum-curvature algorithm
(Figure 43) Most of the data has a line spacing of 1600 m with small areas of 1 km spacing The quality of the data is
acceptable for regional interpretation but is not adequate for detailed analysis The accuracy of the flight path is rather
variable reflecting the vintage of the data and the noise envelope of the data is poor by modern standards Problems
were also encountered in joining different map sheets
The magnetic anomaly pattern over the south and west part of the area shows a strong high frequency signature
reflecting the presence of widespread basic sills and dykes Some of the major north-northeasterly trending dykes can
be traced over considerable distances
Discontinuous high-frequency anomalies extend as a northwest-trending zone through the centre of the area and
this zone includes a conspicuous circular magnetic anomaly which is probably a ring complex
The northern and eastern parts of the area are characterized by long-wavelength deep-seated basement magnetic
anomalies with 120deg and 150deg trends dominant The Marloo and Perentie Faults (Figure 42) appear as distinct linear
zones and offsets A prominent easterly trending negative anomaly in the northwest of the area appears to swing round
to the southeast and may separate different basement blocks One possible interpretation is that this very deep seated
anomaly separates areas of Archaean and Proterozoic basement
Regional geology
The regional geology is described in Williams (1992) The GSWA provided a digitized version of Plate 2 from this
Bulletin the structural interpretation map to use as an overlay (Figure 42)
53
Pp
Pp
PSd
PSd
PSd
PSd
PSd
PSo
PSt
PSt
PSf
PSf
PSf
PSb
PSb
PSb
PSsPSs
PSs
PSb
PSm
PSp
PSc
PSc
PSw
PSw
PSw
PSg
PSr
PSj
PSg
PM
Pk
PY
PY
PSd
L
L
L
L
L
L
L
LL
L
L
L
LL
L
LL
L L
LL
L L
L
L
L
L
L
L
L
LL
L
L
BLAKEDEPOCENTRE
MA
RLO
O
FAU
LT
PERENTIEFAULT
50 km
MKS39120598
120deg 121deg 122deg 123deg
25deg
24deg
23deg
Approximate boundaryof aeromagnetic interpretation
PML
PSgL
PSjL
PML
PSpL
PML
PML
PSfL
PSfL
PSpL
LPc
LPcLPcPSrL
LPA
Durba Sandstone
Woora Woora Formation
McFadden Formation
Tchukardine Formation
Boondawari Formation
Skates Hills Formation
Mundadjini Formation
Coondra Formation
Spearhole Formation
Watch Point Formation
Jilyili Formation
Brassey Range Formation
Glass Spring Formation
Paterson Formation
Yeneena Group
Karara Formation
Cornelia Formation
Kahrban Subgroup
Bangemall Group
Fault
Formation boundary
PSdL
PSoL
PSfL
PStL
PSbL
PSsL
PSmL
PScL
PSpL
PSwL
PSjL
PSrL
PSgL
Pp
PYL
PkL
LPc
LPA
PML
Savory Group Other Units
PYL
Figure 42 Regional geology and structure map (after Williams 1992)
54
120deg 121deg 122deg 123deg
23deg
24deg
25deg
5820
3750
MKS47 180598
nT
50 km
Figure 43 Regional aeromagnetic data total magnetic intensity (BMRAGSO data) gridded at 400 m
Analysis
3D analysis
3D Euler deconvolution was used as the primary depth-determination method The advantage of this approach is that
consistent solutions can be obtained over the entire area with minimal assumptions about source geometries Euler
deconvolution of gridded data is used for positional information and estimation of depth to top of source Euler
55
deconvolution yields a large number of depth solutions which have to be screened to reject spurious solutions Results
are plotted as circles in eight depth ranges with radius proportional to depth and colour coded
The 400 m total magnetic intensity grid was used for the analysis Horizontal gradients in x and y and the vertical
gradient were calculated 3D Euler deconvolution was tested on the 400 m gridded data using windows of 9 times 9 and
11 times 11 and 16 times 16 data points and structural indices 05 (fault) and 10 (sill or dyke) It was concluded that the
16 times 16 window produced the best results overall and final plots were produced for the 16 times 16 window and structural
index 05 (Fig 44) Results were very good over the northern and central parts of the area showing magnetic sources
Figure 44 Depth to magnetic source 3D Euler deconvolution 16 times 16 window of 400 m gridded data structural index 05
56
at several different levels Unfortunately in the extreme south of the area shallow intrasedimentary magnetic sources
(sills and dykes) dominated the inversion and the results contained few basement solutions
In order to reduce these problems the 400 m gridded data were filtered using a separation filter based on
interpretation of the log-energy spectrum The 3D Euler method was run on the filtered data in order to generate more
basement-depth solutions Results for the deep-separation filter data were gridded and presented as a colour image in
Cowan (1995) Attempts to grid the Euler output were unsatisfactory and it is considered safer to interpret the 3D
Euler depth plots The 3D Euler depth results from the separation-filter run should be analysed with care as perfect
separation of the basement can never be achieved and there will always be some contamination from sources at
different levels
The results of original total magnetic intensity 3D Euler depth estimation for structural index 05 using a 16 point
window have been plotted at 1500 000 scale (not included in this publication but available in Cowan (1995) from the
GSWA Library as S10331) and as reduced A4 colour circle plots (Figure 44)
The results of deep-basement 3D Euler depth estimation for structural index 05 using a 16 point window have
been plotted as a colour image at 1500 000 scale and as an A4 image (not included in this publication)
2D analysis
Two equispaced profiles were interpolated with a 50 m station interval from the AGSO-located data profiles for the
BULLEN 1250 000 sheet The interpolated profiles were analysed using 2D Euler deconvolution and Werner
deconvolution Results are included in Cowan (1995) and show the use of these methods for more detailed analysis
Filtered data
In order to reconcile 3D Euler results from shallow basement and intrasedimentary magnetic sources we produced
several separation-filtered maps and images We found the shallow-layer double-separation filter (Figure 45) to be
very effective for shallow sources and the deep-layer standard-separation filter (Figure 46) for the basement layer
Gravity and magnetic data correlation
Both lsquoreduced to the polersquo (RTP) magnetics (Figure 47) and pseudo-gravity data (Figure 48) were produced as part of
the reconciliation of gravity and magnetic signatures In both cases the filtering operations assumed magnetization by
induction in the present Earths field The RTP data are fairly similar to the total magnetic intensity The pseudo-
57
gravity data are dominated by a northwest-trending strong positive anomaly and there is little correlation with the
Bouguer gravity data
The poor magneticgravity correlation is confirmed by cross-correlation of the RTP magnetics and the gravity
gradient The correlation plot in Figure 49 shows little coherent response with numerous zones of positive and
negative correlation
Figure 45 Regional aeromagnetic data shallow layer separation filter (BMRAGSO data) gridded at 400 m
Results
In the north and east of the area on the Wells Foreland Sub-basin trend (refer to Figure 1 main text) we see a range
of quite deep 3D Euler depths and several trend directions with north-northwesterly dominant There are relatively few
shallow intrasedimentary solutions in this zone
The second area of deep 3D Euler solutions lies over the Blake depocentre (Figure 43) with several trend
directions
Elsewhere the 3D Euler results are dominated by shallow intrasedimentary depth solutions reflecting mainly the
dolerite sills dykes and the ring complex However where we do see basement-related solutions in the south and
west of the area they appear to be shallower than those noted for the Wells Foreland Sub-basin and the Blake
depocentre
58
Figure 46 Regional aeromagnetic data deep-layer separation filter (BMRAGSO data) gridded at 400 m
Figure 48 Regional aeromagnetic data pseudo-gravity transform (BMRAGSO data) gridded at 400 m
Figure 47 Regional aeromagnetic data reduced-to-pole (BMRAGSO data) gridded at 400 m
Figure 49 Regional aeromagnetic and gravity data gravitymagnetic correlation using RTP magnetics and gravity gradient (BMRAGSO data) gridded at 4 km
59
This subdivision of the area into two zones of deep solutions is consistent with interpreted depocentres
However the interference between sources at different levels and the complexity of the magnetic response of the
basement rocks precludes more refined interpretation at this stage
The area of deep 3D Euler solutions over the Blake depocentre correlates with the pronounced negative gravity
anomaly discussed in the gravity interpretation section Using a density contrast of -015 gcc the negative gravity
anomaly could indicate up to 6ndash8 km of low-density sedimentary rocks depending on assumptions about the regional
field
The area of deep 3D Euler solutions over the Wells Foreland Sub-basin has a complex gravity expression and no
clear basin structure emerges from inversion of these data As noted previously it is likely that observed gravity
anomalies reflect contrasts in basement density rather than basement topography
Separation filtering applied to the magnetic data helps to enhance the intrasedimentary magnetic signature and to
give a better impression of the basement magnetic signature even though separation of the basement response is not
perfect
Conclusions
Quantitative aeromagnetic interpretation using 3D Euler deconvolution supported by wavenumber filtering and image
processing has been successful in providing structural trend and depth information for the Savory Sub-basin
Quantitative magnetic interpretation has revealed two zones of relatively deep magnetic basement beneath the
Wells Foreland Sub-basin and the Blake depocentre
This analysis of the magnetic data supports interpreted depocentres but the complexity of the basement magnetic
signature and interference from sources at different depths precludes further refinement to a map of basement
topography
Regional gravity proved to be very useful in understanding the regional setting of the area and in providing
support for aspects of the interpretation The gravity data support the interpretation of the Blake depocentre
suggesting up to 6ndash8 km of low-density sedimentary rocks
The deep structure of the Savory Sub-basin area is obviously complex with different areas underlain by
Archaean and Proterozoic basement and with the Capricorn suture occurring in the centre of the area
60
Recommendations
The quantitative magnetic interpretation needs to be reconciled with geological models available for the area
In particular the zones tentatively identified as areas with thick sedimentary rocks the Wells Foreland Sub-
basin and the Blake depocentre need to be investigated
Cross sections should be prepared across the basin for joint magneticgravity modelling especially for the Blake
depocentre It is important to be able to explain the strong negative gravity anomaly in this area
In view of the effects of basement density contrasts on the gravity field for the northern part of the area we think
that additional gravity interpretation and acquisition of new gravity data may not be justified as they will not
contribute significantly to understanding basin evolution and structure
It is recommended that GSWA try to get access to company confidential high-resolution aeromagnetic data
rather than flying new surveys The GSWA might offer to fund flying of new infill areas as a bargaining point
References
The original text of this report by Cowan (1995) and 1500 000 scale maps are filed in the GSWA Library under
S10331
COWAN D 1995 Savory Basin quantitative magnetic interpretation Western Australia Geological Survey S-series
S10331 (unpublished)
VACQUIER V STEENLAND N C HENDERSON R G and ZIETZ I 1951 Interpretation of aeromagnetic
maps The Geological Society of America Memoir 47 151p
WILLIAMS I R 1992 Geology of the Savory Basin Western Australia Western Australia Geological Survey
Bulletin 141 115p
61
Appendix 5
Geochemistry
MKS38 250398
Saturate FractionC12+ GLC
1217
Pr18
Ph
22
31CSR WELL-13 315m Cuttings
Figure 51 Canning Stock Route Well 13 gas chromatograph of extract of auger drill sample
12
17
18
22
31
Pr Ph
LDDH 1 6623m CoreSaturate FractionC12+ GLC
MKS35 240398
Figure 52 Gas chromatograph of extract from core sample at 6623 m LDDH1
62
Table 51 Canning Stock Route Well 13 auger drill samples
GSWA sample Drill depth (m)(a) Comments
135601 150 At watertable 135602 203 (all samples consist 135603 310 of sand mud and water) 135604 315 At total depth
NOTE (a) Datum for drill depth is the top of sediment fill in the well which is 155 m below ground level (ie the total depth of 315 m is 47 m below ground level)
Table 52 Canning Stock Route Well 13 gas chromatography data for 315 m depth sediment sample
Parameter Value
Weight of rock extracted (grams) 945 Total extract (ppm) 519 n-Alkane distribution n-C12 07 n-C13 23 n-C14 26 n-C15 22 n-C16 19 n-C17 14 i-C19 23 n-C18 14 i-C20 08 n-C19 11 n-C20 16 n-C21 25 n-C22 29 n-C23 70 n-C24 42 n-C25 95 n-C26 43 n-C27 83 n-C28 38 n-C29 87 n-C30 31 n-C31 273 Alkane compositional data Pristane phytane ratio 279 Pristane n-C17 ratio 161 Phytane n-C18 ratio 059 CPI (1)(a) 284 CPI (2) 209 (C21 + C22) (C28 + C29) 043
NOTE (a) CPI= Carbon preference index
63
Table 53 LDDH1 extract liquid chromatography data for 6623 m concentration
Rock extracted Total extract (grams) (ppm)
702 313
NOTE ppm= parts per million
Table 54 LDDH1 saturate gas chromatography data of core for 6623 m alkane composition
Pristane Pristane Phytane (a) CPI (1) CPI (2) (C21+C22) Phytane n-C17 n-C18 (C28+C29)
103 026 024 103 102 325
NOTE (a)CPI = carbon preference index
Table 55 LDDH1 saturate gas chromatography data of core for 6623 m n-alkane distributions
Parameter Value
n-C12 17 n-C13 38 n-C14 55 n-C15 60 n-C16 65 n-C17 74 i-C19 19 n-C18 78 i-C20 19 n-C19 80 n-C20 79 n-C21 71 n-C22 64 n-C23 57 n-C25 43 n-C24 38 n-C27 31 n-C28 23 n-C29 19 n-C30 12 n-C31 10
64
Appendix 6
Table 61 Summary of data from Trainor waterbores (TWB) and Bullen waterbores (BWB)
Well AMG Elevation TD Status(b) Completion details Water Salinity Water level Flow rate Depth to consolidated AGD84 GL (m) (m) struck mgl(c) (m) (LHr) lithology aquifer(e) Z51(a) Interval (m) (100 mm PVC) (m) (mgl)(d)
TWB 1 473660E 453 122 comp 0ndash75 plain 63 7 300 24 2 880 12 m 7287404N 75ndash93 slotted (9 260) McFadden Fm 93ndash99 plain TWB 2 472 977E 475 23 abd nil 15 m 7285877N Skates Hills Fm dry TWB 3 473259E 475 50 abd nil 7 m 7285849N Skates Hills Fm dry TWB 4 463225 E 445 50 comp 0ndash22 plain 35 7 200 55 3 600 0 m 7286143N 22ndash34 slotted (8 140) Tertiary sand and gravel 23ndash60 plain TWB 5 463095E 445 31 comp 0ndash19 plain 13 26 000 655 3 600 Tertiary sand and gravel 7277721N 19ndash25 slotted (36 700) 25ndash31 plain TWB 6 457013E 455 50 comp 0ndash42 plain 38 920 119 600 0 m 7274352N 42ndash48 slotted (1 030) Cornelia Fm ss TWB 7 453739E 475 26 susp 0ndash2 plain 11 9 300 48 4 500 0 m 7263891N (10 500) Tertiary sand TWB 8 433893E 535 60 susp 0ndash2 plain 47 8 500 gt46 1 200 0 m 7245991N (10 900) Tertiary sand and Brassey Range Fm ss TWB 9 437219E 505 51 comp 0ndash47 plain 45 1 000 58 600 1 m 7235905N 47ndash51 slotted (990) Brassey Range Fm ss TWB 10 434927E 495 32 susp 0ndash2 plain 235 450 120 0 m 7225875N (500) Dolerite
65
BWB 1 287337E 580 122 abd Nil 1 m 7245861N Jilyili Fm dry BWB 2 288346E 545 50 comp 0ndash26 plain 15 630 3 29 000 0 m 7240423N 26ndash38 slotted (730) Tertiary sand and gravel 38ndash50 plain BWB 3 305637E 545 50 abd 19 8 800 43 7 200 0 m 7240423N (10 550) Tertiary ss BWB 4 320167E 515 445 comp 0ndash20 plain 9 980 445 24 000 0 m 7248097N 20ndash32 slotted (1 190) Tertiary ss 32ndash44 plain BWB 5 353393E 545 20 susp 0ndash2 plain 45 (970) 1 m 7238934N Basalt
NOTES (a) GPS accuracy ~ 150 m (b) Comp = completed abd = abandoned susp = suspended (c) Salinity from conductivity (d) Analysis total dissolved solids (e) Fm = Formation ss = sandstone
30
Mineral industry data
The approximate locations of non-AGSO aeromagnetic surveys are shown in Figure 8 More
detailed information regarding the location of these surveys may be obtained using the GSWA
MAGCAT II database Additional information such as contours of aeromagnetic values may be
obtained by inspecting items on file with the GSWA
Gravity surveys
Government data
The average spacing for gravity data in the Savory Sub-basin is one station per 121 km2 (11 times 11
km grid) These data were principally collected by BMR in the early 1960s There are a few
additional regional gravity traverses across the sub-basin which are also included in the
BMRAGSO dataset These data were reprocessed and interpreted for GSWA (Fig 10) and a
report on this work is also included in Appendix 4
The GSWA completed a large semi-detailed gravity survey in the eastern Savory Sub-basin
utilizing helicopter support and Differential Global Positioning Survey (DGPS) techniques (Fig
8) This gravity survey completed in August 1995 consists of 2300 gravity stations on a 2 times 3 km
grid All stations were acquired by helicopter using Scintrex gravimeters and Ashtek dual
frequency DGPS equipment for determining location This highly efficient system allowed the
acquisition of more than 100 gravity stations per day in remote areas The resolution of this survey
is +30 cm and +05 microms-2 (Daishsat 1995) These data (Fig 11) represent a significant
improvement on the previous regional survey data and are available from GSWA (GSWA
1996ab) The results of the interpretation of these data were presented at the 1997 ASEG
Convention (Carlsen and Shevchenko 1997)
Mineral industry data
Three small gravity surveys were conducted by Oilmin NL (Fig 8) and the relevant WAMEX
reports are M 2681I 2610 I 2435 I 2567 These three surveys are of limited value because height
control was provided by barometers only and the surveys were not tied to the national gravity grid
31
23deg
25deg
120deg 122deg
Trainor 1
SAVORY
SUB-BASIN
MKS54 160498
100 km
1995 SavoryGravity Survey
254
-1056
micromsec2
Figure 10 Regional Bouguer gravity map of the Savory Sub-basin
23deg
24deg
25deg
122deg30 123deg
TRAINOR 1
123deg30
50 km
MKS53 160498
-116
-626
micro msec2
Figure11 Detailed Bouguer gravity map of the
Savory 1995 Gravity Survey from the eastern Savory Sub-basin
32
Government and academic reports
Chronostratigraphy and geochemistry
The understanding of Neoproterozoic organic chemistry palynology and structural evolution is
essential to the interpretation of hydrocarbon prospectivity Pertinent reports are included in the
bibliography (Appendix 1) Unpublished palaeontology reports describe the palynology of wells in
the Savory Sub-basin (Grey 1995andashe 1996a) Grey and Cotter (1996) discussed the potential for
Neoproterozoic palynomorphs to provide a biostratigraphic framework and palaeoenvironmental
interpretation Grey and Stevens (1997) reviewed the results of palynological studies of wells
drilled in the sub-basin and reported that Supersequence 1 palynomorphs are present in TWB 6
TWB 9 and LDDH1 (Appendix 3) Grey (1996b) reported on the use of stromatolites for
correlation in the Neoproterozoic and Stevens and Grey (1997) discussed the application of
stromatolite biostratigraphy in correlating isolated dolomite outcrops in the sub-basin with well
and seismic data in the Officer Basin and Centralian Superbasin
Although geochemical data from the Savory Sub-basin are very limited results mostly
confirm thermal maturities inferred from TAI for LDDH1 and Trainor 1 (Ghori in prep Stevens
and Adamides in prep) Those parts of the Officer Basin in Western Australia which lie to the
east of the Savory Sub-basin are sparsely drilled but Ghori (in prep) reports that most of the
Neoproterozoic succession presently lies within the oil-generative window However his study
has been unable to identify effective source-rock units and the source for oil shows Thin source
rocks are present in the Neoproterozoic in LDDH1 (Fig 9) and in three wells which lie to the east
and southeast of the Savory Sub-basin namely NJD 1 Kanpa 1A and Yowalga 3
Proposed work program
From the above limited information it is concluded that additional research on the hydrocarbon
potential of the sub-basin is justified and proposals are outlined below
bull Additional modelling of gravity and aeromagnetic data from the Savory Sub-basin is required
in light of the results from Trainor 1 and Boondawari 1 Trainor 1 showed that what appeared
to be a structurally simple area based on outcrop aeromagnetic and gravity data was in fact an
area of major structuring Boondawari 1 intersected a dolerite which is in good depth
agreement with aeromagnetic depth to source results showing this technique is useful in
detecting the depth to intrusive bodies
33
bull Additional data from mineral and petroleum exploration bores may become available and
analysis of samples from these wells should be undertaken and interpreted in the context of
their relevance to the Officer Basin
bull Stratigraphic coring in the Blake Fault and Fold Belt and in the Wells Foreland Sub-basin (Fig
1) targeting source rocks is considered essential to the continuing evaluation of the
hydrocarbon prospectivity of the Savory Sub-basin
bull Correlations using at least outcrop well and potential-field data should be prepared to link the
sub-basin with the better known parts of the Officer Basin to the east
bull Remapping is required to clarify boundary positions within the Cornelia Formation this may
resolve some of the current problems of the relationship between this unit and the rest of the
Savory Sub-basin
bull Further work is required to explain the Early Cambrian or Sturtian ages interpreted for the
Cornelia Formation from sedimentary zircon UndashPb dating in drillhole Trainor 1 The
determination of the age of the organically rich but overmature claystones in this well is
critical to assessing the hydrocarbon potential of the region
bull The thin dark mudstones intersected by Akubra 1 in the Mundadjini Formation warrant
geochemical analysis Analyses of the oil shows in Mundadjini 1 and Boondawari 1 are
currently being undertaken by Amadeus Petroleum
bull Geochemical analysis of hydrocarbons in the Bangemall Basin drillhole OD23 has been
performed by Jubilee Gold and the results will be reviewed when they are submitted to
GSWA The possibility of source rocks within the Bangemall Basin charging traps within the
Bangemall Basin and the overlying Savory Sub-basin requires further investigation
Conclusions
The Savory Sub-basin is a frontier region with only three recently drilled petroleum exploration
wells and no seismic data Based on existing geological and geophysical data it is considered too
early to draw conclusions about the hydrocarbon prospectivity of the sub-basin at this stage and
there are several reasons why the area warrants further investigation
34
1 Thick accumulations of sedimentary rocks are present (up to 8 km thickness inferred) which
may contain source reservoir and sealing strata
2 Minor oil shows occur in Mundadjini 1 and Boondawari 1 and bitumen is present in mineral
exploration drillhole LDDH1 suggesting that hydrocarbons have migrated within the
Neoproterozoic sequence of the Savory Sub-basin Oil and bitumen are present in mineral
exploration drillhole OD23 in the Bangemall Basin immediately to the south of the Savory
Sub-basin and it is possible that source rocks from the Bangemall Basin could charge traps in
the overlying Savory Sub-basin
3 The age of sedimentary rocks in the sub-basin is still poorly constrained but some of the
Neoproterozoic sedimentary rocks located on GUNANYA and TRAINOR are within the
hydrocarbon-generation window It is possible that a significant thickness of Phanerozoic
sedimentary rocks may also be present
4 Friable sandstones with visible porosity outcrop extensively suggesting numerous potential
reservoirs
5 Significant but not intense faulting and folding has been mapped implying large structural
traps may be present
6 Evaporitic sedimentary rocks occur in several formations and may provide good source rocks
and excellent seals
35
References
APAK S N and CARLSEN G M 1997 A compilation and review of data pertaining to the
hydrocarbon prospectivity of the Canning Basin Western Australia Geological Survey
Record 199610 103p
BAGAS L GREY K and WILLIAMS I R 1995 Reappraisal of the Paterson Orogen and
Savory Basin Western Australia Geological Survey Annual Review 1994ndash95 p 55ndash63
BUSBRIDGE M 1994 Lake Disappointment Exploration Licence 451064 Third Annual
Report Lake Disappointment Diamond Drill Hole LDDH1 Normandy Exploration Limited
Western Australia Geological Survey M-series Item 7567 A41358 (unpublished)
CARLSEN G M and SHEVCHENKO S I 1997 Petroleum exploration in Proterozoic basins
using potential fields data and stratigraphic coring Australian Society of Exploration
Geophysicists 12th Geophysical Conference Handbook Sydney 1997 Preview no 66 p 83
(abstract only)
COWAN D 1995 Savory Basin quantitative magnetic interpretation Western Australia
Geological Survey S-series S10331 (unpublished)
DAISHSAT PTY LTD 1995 Operational and processing report Savory Basin gravity survey
Western Australia Geological Survey S-series S10332 (unpublished)
GARD E and GARD R 1990 Canning Stock Route a travellerrsquos guide for a journey through
history Perth Western Australia Western Desert Guides 448p
GEOLOGICAL SURVEY OF WESTERN AUSTRALIA 1996a Savory Basin first vertical
derivative of Bouguer gravity image 1250 000 Western Australia Geological Survey
GEOLOGICAL SURVEY OF WESTERN AUSTRALIA 1996b Savory Basin Bouguer gravity
image 1250 000 Western Australia Geological Survey
GHORI K A R in prep Petroleum source rock potential and thermal history Officer Basin
Western Australia Western Australia Geological Survey Record
36
GREY K 1995a Savory Basin drillhole BWB 1 (Bullen waterbore) palynology and thermal
maturation GSWA Palaeontology Report no 199512 (unpublished)
GREY K 1995b Savory Basin drillholes TWB 1 2 6 9 (Trainor waterbores) palynology and
thermal maturation GSWA Palaeontology Report no 199520 (unpublished)
GREY K 1995c Palynology of Normandy-Poseidon Lake Disappointment-1 corehole
Tarcunyah Group Paterson Orogen GSWA Palaeontology Report no 199521 (unpublished)
GREY K 1995d Savory Basin drillhole Trainor 1 (Trainor diamond drilling) palynology and
thermal maturity GSWA Palaeontology Report no 199524 (unpublished)
GREY K 1995e Savory Basin drillhole Trainor 1 (Trainor diamond drilling) Additional
Preparation of two samples GSWA Palaeontology Report no 199528 (unpublished)
GREY K 1995f Neoproterozoic stromatolites from the Skates Hills Formation Savory Basin
Western Australia and a review of the distribution of Acaciella australica Australian Journal
of Earth Sciences v 42 p 123ndash132
GREY K 1996a Savory Basin drillhole Trainor 1 (Trainor diamond drilling) Additional
samples palynology and thermal maturation GSWA Palaeontology Report no 199615
(unpublished)
GREY K 1996b Preliminary stromatolite correlations for the Neoproterozoic of the Officer
Basin and a review of Australia-wide correlations GSWA Palaeontology Report no 199615
(unpublished)
GREY K and COTTER K L 1996 Palynology in the search for Proterozoic hydrocarbons
Western Australia Geological Survey Annual Review for 1995ndash96 p 70ndash80
GREY K and STEVENS M K 1997 Neoproterozoic palynomorphs of the Savory Sub-basin
Western Australia and their relevance to petroleum exploration Western Australia
Geological Survey Annual Review for 1996ndash97 p 49ndash54
HUBBARD R J PAPE J and ROBERTS D G 1985 Depositional sequence mapping as a
technique to establish tectonic and stratigraphic framework and evaluate hydrocarbon
potential on a passive continental margin in Seismic stratigraphy II an integrated approach
37
edited by O R BERG and D G WOOLVERTON American Association of Petroleum
Geologists Memoir 39 p 79ndash91
LIBBY WG 1995 A petrological report on six samples of bore cuttings from the Savory Basin
Western Australia Western Australia Geological Survey S-series S31307 (unpublished)
MORTON JGG and DREXEL JF 1997 The petroleum geology of South Australia Vol 3
Officer Basin South Australia Department of Mines and Energy Resources Report Book
9719
MUHLING P C and BRAKEL A T 1985 Geology of the Bangemall Group mdash the evolution
of an intracratonic Proterozoic basin Western Australia Geological Survey Bulletin 128
219p
MYERS J S 1990 Precambrian tectonic evolution of part of Gondwana southwestern Australia
Geology v18 p 537ndash540
NELSON D R 1997 Compilation of SHRIMP UndashPb zircon data Western Australia Geological
Survey Record 19972 196p
PAYTON C E 1977 Seismic stratigraphy mdash applications to hydrocarbon exploration
American Association of Petroleum Geologists Memoir 26 516p
PERINCEK D 1996a The age of NeoproterozoicndashPalaeozoic sediments within the Officer Basin
of the Centralian Super-basin can be constrained by major sequence-bounding unconformities
APPEA Journal v 36 pt 1 p 350ndash368
PERINCEK D 1996b The stratigraphic and structural development of the Officer Basin
Western Australia a review Western Australia Geological Survey Annual Review 1995ndash
1996 p 135ndash148
PERINCEK D 1998 A compilation and review of data pertaining to the hydrocarbon
prospectivity of the Officer Basin Western Australia Geological Survey Record 19976
POSAMENTIER H W JERSEY M T and VAIL P R 1988 Eustatic controls on clastic
deposition 1 mdash Conceptual framework in Sea-level changes an integrated approach edited by
C K WILGUS B S HASTINGS C G St C KENDALL H W POSAMENTIER
38
C A ROSS and J C VAN WAGONER Society of Economic Paleontologists and
Mineralogists Special Publication no 42
STEVENS M K and ADAMIDES N G in prep GSWA Trainor 1 well completion report
Savory Sub-basin Officer Basin Western Australia with notes on petroleum and mineral
potential Western Australia Geological Survey Record 199612
STEVENS M K and GREY K 1997 Skates Hills Formation and Tarcunyah Group Officer
Basin mdash carbonate cycles stratigraphic position and hydrocarbon prospectivity Western
Australia Geological Survey Annual Review for 1996ndash97 p 55ndash60
SUMMONS RE and POWELL C McA 1991 Petroleum source rocks of the Amadeus Basin
in Geological and geophysical studies in the Amadeus Basin central Australia edited by R J
KORSCH and JM KENNARD Australia BMR Geology and Geophysics Bulletin 236
TRAVERSE A 1988 Palaeopalynology Boston Unwin Hyman 600p
VAIL P R MITCHUM R M Jr TODD R G WIDMIER J M THOMPSON S III
SANGREE J B BUBB J N and HATLELID W G 1977 Seismic stratigraphy and
global changes of sea level in Seismic stratigraphy mdash applications to hydrocarbon
exploration edited by C E PAYTON American Association of Petroleum Geologists
Memoir 26 516p
WALTER M R and GORTER J 1994 The Neoproterozoic Centralian Superbasin in Western
Australia the Savory and Officer Basins in The sedimentary basins of Western Australia
edited by P G PURCELL and R R PURCELL Petroleum Exploration Society of Australia
Symposium Perth WA 1994 Proceedings p851ndash864
WALTER M R GREY K WILLIAMS I R and CALVER C R 1994 Stratigraphy of the
Neoproterozoic to early Palaeozoic Savory Basin and correlation with the Amadeus and
Officer Basins Australian Journal of Earth Sciences v 41 p 533ndash546
WALTER M R VEEVERS J J CALVER C R and GREY K 1995 Neoproterozoic
stratigraphy of the Centralian Superbasin Australia Precambrian Research v 73 p 173ndash195
WILLIAMS I R 1992 Geology of the Savory Basin Western Australia Western Australia
Geological Survey Bulletin 141 115p
39
WILLIAMS I R 1995a Bullen WA (2nd Edition) Western Australia Geological Survey
1250 000 Geological Series Explanatory Notes 23p
WILLIAMS I R 1995b Trainor WA (2nd Edition) Western Australia Geological Survey
1250 000 Geological Series Explanatory Notes 31p
WILLIAMS I R and TYLER I M 1991 Robertson WA (2nd edition) Western Australia
Geological Survey 1250 000 Geological Series Explanatory Notes 36p
40
41
Appendix 1
Bibliography
Reports which are relevant to this investigation but which are not specifically cited are listed
below
BAILLIE P W POWELL C McA LI Z X and RYALL A M 1994 The tectonic
framework of Western Australiarsquos Neoproterozoic to recent sedimentary basins in The
sedimentary basins of Western Australia edited by P G PURCELL and R R PURCELL
Petroleum Exploration Society of Australia Symposium Perth WA 1994 Proceedings p
45ndash62
BRADSHAW M T BRADSHAW J MURRAY A P NEEDHAM D J SPENCER L
SUMMONS R E WILMOT J and WINN S 1994 Petroleum systems in West Australian
basins in The sedimentary basins of Western Australia edited by P G PURCELL and R R
PURCELL Petroleum Exploration Society of Australia Symposium Perth WA 1994
Proceedings p 93ndash118
CLARKE G L 1991 Proterozoic tectonic reworking in the Rudall Complex Western Australia
Australian Journal of Earth Science v38 p 31ndash44
COCKBAIN A E and HOCKING R M 1990 Phanerozoic in Geology and mineral resources
of Western Australia Western Australia Geological Survey Memoir 3 p 750ndash755
ETHERIDGE M and WALL V 1994 Tectonic and structural evolution of the Australian
Proterozoic 12th Australian Geological Convention Geological Society of Australia
Abstracts no 37 p 102ndash103
GOODE A D T 1981 Proterozoic geology of Western Australia in Precambrian of the
Southern Hemisphere Developments in Precambrian geology 2 edited by I R HUNTER
Amsterdam Elsevier p 105ndash203
GREY K and JACKSON M J 1983 A re-assessment of stromatolite evidence for the
correlation of the Late Proterozoic Neale and Ilma Beds Officer Basin Western Australia
Australia BMR Journal of Australian Geology and Geophysics v 8 p 359
42
HICKMAN A H WILLIAMS I R and BAGAS L 1994 Proterozoic geology and
mineralization of the TelferndashRudall region Paterson Orogen Geological Society of Australia
(WA Division) Excursion Guidebook no 5 56p
HOCKING R M MORY A J and WILLIAMS I R 1994 An atlas of Neoproterozoic and
Phanerozoic basins of Western Australia in The sedimentary basins of Western Australia
edited by P G PURCELL and R R PURCELL Petroleum Exploration Society of Australia
Symposium Perth WA 1994 Proceedings p 21ndash 44
JACKSON P R 1966 Geology and review of exploration Officer Basin Western Australia
Hunt Oil Company Western Australia Geological Survey S-series S26 (unpublished)
JACKSON M J 1971 Notes on a geological reconnaissance of the Officer Basin Western
Australia Australia BMR Geology and Geophysics Record 19715 30p
JACKSON M J and van de GRAAFF W J E 1981 Geology of the Officer Basin Western
Australia Australia BMR Geology and Geophysics Bulletin 206 102 p
LOWRY D C JACKSON M J van de GRAAFF W J E and KENNEWELL P J 1971
Preliminary result of geological mapping in the Officer Basin Western Australia Western
Australia Geological Survey Annual Report for 1971 p 50ndash56
MYERS J S 1990 Precambrian in Geology and mineral resources of Western Australia
Western Australia Geological Survey Memoir 3 p 737ndash750
MYERS J S SHAW R D and TYLER I M 1994 Proterozoic tectonic evolution of
Australia 12th Australian Geological Convention Geological Society of Australia Abstracts
no 37 p 312
NEDIN C and JENKINS R J F 1991 Re-evaluation of unconformities separating the
lsquoEdiacaranrsquo and Cambrian systems South Australia Palaios v 6 p 102ndash108
PHILLIPS B J JAMES A W and PHILIP G M 1985 The geology and hydrocarbon
potential of the north-western Officer Basin APEA Journal 25 (1) p 52ndash61
POWELL C McA LI Z X McELHINNY M W MEERT J G and PARK J K 1993
Paleomagnetic constraints on timing of the Neoproterozoic breakup of Rodinia and Cambrian
formation of Gondwana Geology v 21 p 889ndash892
43
POWELL C McA PREISS W V GATEHOUSE C G KRAPEZ B and LI Z X 1994
South Australian record of a Rodinian epicontinental basin and its mid-Neoproterozoic
breakup to form the Palaeo-Pacific Ocean Tectonophysics v 237 no 3ndash4 p 113ndash140
PREISS W V 1976 Proterozoic stromatolites from the Nabberu and Officer Basins Western
Australia and their biostratigraphic significance South Australia Geological Survey Report
of Investigations no 47 p 1ndash51
TOWNSON W G 1985 The subsurface geology of the western Officer Basin mdash results of
Shellrsquos 1980ndash1984 petroleum exploration campaign APEA Journal v 25 (1) p 34ndash51
WATTS K J 1982 The geology of the Townsend Quartzite Upper Proterozoic shallow water
deposit of the Northern Officer Basin Western Australia Perth University of Western
Australia BSc honours thesis (unpublished)
WELLS A T and KENNEWELL P J 1974 Evaporite exploration in the Officer Basin
Western Australia at the Madley Diapirs Australia BMR Record 1974194 (unpublished)
WILLIAMS I R and MYERS J S 1990 Paterson Orogen in Geology and mineral resources
of Western Australia Western Australia Geological Survey Memoir 3 p 274ndash286
WILLIAMS I R 1990 Savory Basin in Geology and mineral resources of Western Australia
Western Australia Geological Survey Memoir 3 p 329ndash334
WILLIAMS I R 1994 The Neoproterozoic Savory Basin Western Australia in The
sedimentary basins of Western Australia edited by P G PURCELL and R R PURCELL
Petroleum Exploration Society of Australia Symposium Perth WA 1994 Proceedings p
841ndash850
WILSON R B 1967 Woolnough Hills and Madley diapiric structures Gibson Desert WA
APEA Journal v 7 p 94ndash102
44
Appendix 2
Meteorological data (from Bureau of Meteorology Perth 1994)
Table 21 Wiluna rainfall (mm)
Year Jan Feb Mar Apr May Jun Jul Aug Sept Oct Nov Dec
1975 0 45 446 309 306 59 276 4 34 886 638 164 1976 16 154 12 138 53 16 34 62 12 238 0 2 1977 44 0 66 74 68 95 24 363 1 58 12 727 1978 234 522 94 16 0 96 367 24 16 353 185 45 1979 19 173 122 88 91 4 0 246 58 0 169 114 1980 148 764 68 1081 259 626 629 06 56 02 174 0 1981 123 476 192 32 196 118 44 74 14 0 28 312 1982 374 705 206 244 1079 92 02 143 368 526 368 118 1983 1 112 928 248 0 212 56 32 5 1 42 496 1984 149 7 342 84 836 0 348 132 224 04 16 172 1985 596 483 0 166 556 0 514 56 0 0 4 0 1986 0 154 35 0 0 1085 23 01 239 137 0 04 1987 1204 119 19 89 17 575 154 126 07 1 0 398 1988 46 202 164 13 388 0 202 104 0 0 224 1309 1989 207 234 26 703 278 536 57 0 01 0 144 02 1990 1035 23 281 46 126 53 94 218 44 9 42 0 1991 48 0 41 45 0 472 297 12 0 1 0 7 1992 112 96 1025 1227 323 65 04 174 0 132 48 4 1993 0 697 0 202 445 0 12 306 18 05 14 33 Mean 25 35 22 27 27 25 18 12 6 13 13 21
JAN FEB MAR APR MAY JUN JUL AUG SEP OCT NOV DEC0
10
20
30
40
Mea
n R
ain
fall
(mm
)
Month
Mean monthly rainfall in Wiluna
MKS41 140498
45
Table 22 Wiluna minimum temperature (degC)
Year Jan Feb Mar Apr May Jun Jul Aug Sept Oct Nov Dec
1975 ndash 23 203 15 94 63 71 62 103 124 169 205 1976 242 229 194 15 10 63 59 73 95 143 16 228 1977 243 25 197 148 96 95 56 86 102 ndash 188 23 1978 241 232 203 18 102 64 76 8 9 152 19 205 1979 255 226 216 167 83 6 59 79 97 145 198 223 1980 255 226 231 155 134 83 68 75 121 108 193 223 1981 245 216 19 182 119 6 54 78 138 159 163 218 1982 232 224 177 16 ndash ndash 37 111 112 164 209 225 1983 235 24 197 147 112 88 39 88 121 162 189 219 1984 241 243 191 156 ndash 72 66 7 95 161 182 211 1985 244 231 ndash 159 98 65 71 73 117 147 205 ndash 1986 ndash 229 226 155 93 96 43 49 10 122 ndash 219 1987 ndash 217 183 175 85 77 68 68 112 ndash ndash 221 1988 238 214 209 178 111 ndash ndash 86 104 157 171 195 1989 ndash 237 199 165 107 67 44 61 107 131 187 ndash 1990 232 ndash 211 155 118 62 57 87 102 149 195 22 1991 26 256 217 168 122 101 78 ndash 113 18 168 219 1992 227 227 214 169 102 98 59 69 ndash 125 159 196 1993 241 218 196 171 103 ndash 49 68 88 128 192 211 Mean 24 23 20 16 10 8 6 8 11 14 18 21
NOTE Dashes indicate data unavailable
JAN FEB MAR APR MAY JUN JUL AUG SEP OCT NOV DEC0
10
20
30
40
Month
MKS43 140498
50
Mean monthly minimum temperatures at Wiluna
Mea
n T
emp
erat
ure
(degC
)
46
Table 23 Wiluna maximum temperature (degC)
Year Jan Feb Mar Apr May Jun Jul Aug Sept Oct Nov Dec
1975 ndash 349 326 281 247 201 197 212 256 248 31 344 1976 374 369 346 297 248 206 208 225 265 287 313 388 1977 397 392 352 296 234 212 222 244 ndash 308 337 383 1978 378 345 346 316 242 195 176 205 231 295 334 356 1979 403 36 364 295 ndash ndash ndash 193 242 318 359 373 1980 392 342 377 275 24 176 179 233 292 288 349 391 1981 385 346 337 342 242 178 201 224 30 326 326 369 1982 372 359 315 307 ndash ndash 196 253 252 305 353 379 1983 381 389 327 272 263 222 187 248 287 321 336 366 1984 378 393 322 299 226 215 178 214 234 ndash 336 364 1985 40 366 ndash 294 224 216 205 212 284 307 355 ndash 1986 ndash 383 372 307 ndash 193 166 196 261 277 ndash 382 1987 ndash 339 328 305 21 202 214 218 275 ndash ndash 374 1988 388 365 353 301 23 ndash ndash 228 283 334 31 33 1989 ndash 375 339 285 238 179 181 219 275 298 336 ndash 1990 368 ndash 36 309 268 19 188 205 274 309 373 393 1991 414 416 363 315 268 206 21 ndash 279 338 332 368 1992 363 383 336 263 213 178 213 197 ndash 285 313 359 1993 396 357 344 301 221 ndash 197 215 253 294 347 362 Mean 39 37 34 30 24 20 20 22 27 30 34 37 NOTE Dashes indicate data unavailable
JAN FEB MAR APR MAY JUN JUL AUG SEP OCT NOV DEC0
10
20
30
40
Month
MKS42 140498
50
Mean monthly maximum temperatures at Wiluna
Mea
n T
emp
erat
ure
(degC
)
47
Appendix 3
Table 31 Summary of palynological results
Drillhole Depth (m) F no(a) GSWA no Lithology Formation Assemblage TAI(b)
BWB 1 74ndash75 F49668 135741 dark-grey siltstone basalt Jilyilli gt5 BWB 1 98ndash100 F49669 135742 dark-grey siltstone basalt Jilyilli gt5 BWB 1 121ndash122 F49670 135743 dark-grey siltstone basalt Jilyilli gt5 TWB 1 86ndash87 F49671 135631 dark-grey siltstone McFadden 3+ TWB 1 104ndash105 F49672 135632 dark-grey siltstone Cornelia 3+ TWB 1 121ndash122 F49673 135633 dark-grey siltstone Cornelia 4 TWB 2 14ndash15 F49674 135634 dark-grey siltstone Skates Hills 3+ TWB 6 49ndash50 F49675 135675 dark-grey siltstone Cornelia 1 3+ TWB 9 49ndash51 F49676 135704 dark-grey siltstone Brassey Range 1 3+ Trainor 1 37497- F49733 138939 black mudstone with Cornelia 5 37509 light-grey siltstone Trainor 1 3809 F49734 138940 dark-grey and black Cornelia 4- laminated mudstone Trainor 1 4170 F49735 138941 black unlaminated mudstone Cornelia 4- Trainor 1 4950 F49851 139501 dark-grey indurated siltstone Cornelia 5 Trainor 1 6032 F49852 139502 dark- and light-grey Cornelia 5 indurated siltstone Trainor 1 6434 F49853 139503 greenish indurated finely Cornelia 5 laminated siltstone LDDH 1 270 F49678 138934 dark-grey siltstone interbeds Waters 1 3+ in enterolithic evaporite Tarcunyah Gp LDDH 1 277 F49679 138935 dark-grey siltstone in cavity Waters 1 3+ in enterolithic evaporite Tarcunyah Gp
NOTES (a) GSWA Fossil Catalogue number (b) TAI = Thermal Alteration Index of Traverse (1988 plate 1)
48
Appendix 4
Savory Sub-basin quantitative magnetic and gravity interpretation (extracted from Cowan 1995)
Summary
A program of quantitative aeromagnetic interpretation has been completed on BMRAGSO data from the Savory Sub-
basin Western Australia Quantitative aeromagnetic interpretation utilized the 3D Euler deconvolution method
supported by wavenumber filtering and image processing The results have provided useful information on structural
trends and depth to magnetic sources in a structurally complex area Depth to magnetic source analysis has provided
information on intra-sedimentary magnetic sources as well as basement rocks
The results of the interpretation support previously identified depocentres However the presence of magnetic
sources at several levels makes it very difficult to produce a reliable magnetic basement depth contour map It is
considered more productive to work with the 3D Euler colour circle plots and images rather than trying to contour the
results It would be necessary to carry out a full-scale interpretation of the BMRAGSO profile data to improve on the
3D Euler results The regional gravity was found to be useful in interpreting the regional setting of the area although
the very wide data spacing limits quantitative use of the data The gravity data show quite a complex picture with
limited consistent correlation between gravity features and basin structures This suggests that gravity anomalies
reflect changes in density of the basement rocks rather than basement topography especially in the northern part of the
basin
It is recommended that the GSWA investigate access to company confidential high-resolution aeromagnetic data
prior to planning further aeromagnetic surveys Private companies have flown large parts of the northern half of the
area as part of their diamond exploration program Additional gravity coverage of the area may be more cost effective
than magnetic surveys as the gravity data provides more information on changes within the sedimentary section
Introduction
The main use of aeromagnetic data in petroleum exploration has been the determination of magnetic basement
topography although there has been increasing interest in analysis of intra-sedimentary magnetic anomalies
intrabasement and suprabasement magnetic anomalies These anomalies are used to determine depth to magnetic
basement rocks and hence determine the thickness of the sedimentary sequence Unfortunately interpretation of the
intrabasement and suprabasement magnetic anomalies is non-unique in terms of position and size of causative sources
because of the inherent ambiguity of potential-field methods However this ambiguity can be reduced by placing
49
constraints on source geometry and magnetization and by using geological and other geophysical data to constrain
the solution
Before 1970 most depth-determination techniques involved graphical determination of slopes of selected
magnetic anomalies and application of various empirical factors to convert the slopes into depth estimates Geological
Society of America Memoir 47 Interpretation of Aeromagnetic Maps by Vacquier et al (1951) was a landmark for
this type of interpretation
Automated interpretation procedures have played an increasingly important role in depth interpretation and a
wide range of techniques have been developed Many of these techniques are designed for application to located data
profiles and assume a two-dimensional geometry However there has been renewed interest in techniques applicable
to gridded data
Two distinct types of method can be recognized In the first case often described as discrete methods individual
isolated magnetic anomalies are interpreted and the results used to produce a map of basement relief In the second
case often described as continuous methods areas of data containing a number of anomalies are interpreted
statistically to produce direct output of basement depths
The discrete methods usually involve a semiautomatic initial phase which generates a large number of possible
depth solutions and an interactive second phase to screen and select acceptable solutions The advantage of this
approach is that the interpreter can select features that are relatively free from interference from adjacent anomalies
and consider all aspects of a particular magnetic anomaly The disadvantage is that interpretation can be very time
consuming as a wide range of depths are usually possible depending on the initial model chosen and a significant
amount of effort is needed to select the correct model In the case of the Savory Sub-basin dataset we encountered
problems in separating basement related effects from the effects of shallower intrasedimentary magnetic sources
Because of these problems we have concentrated on displaying the Euler results accompanied by separation filter
images of the data to show the shallower effects and deeper effects rather than trying to refine a 3D Euler
deconvolution depth-to-crystalline-basement contour
The continuous methods are very direct provided that the rather restrictive assumption can be made that all
anomalies are due to lateral magnetization changes due to basement topography This means that shallow effects and
large intrabasement anomalies must be removed from the data This involves judgement and skill as it is necessary to
distinguish between the lower amplitude suprabasement anomalies due to basement topography and the larger
intrabasement anomalies reflecting magnetization changes within the basement These methods were not considered
suitable for the Savory Sub-basin magnetic dataset but were used to invert the gravity data
50
Limitations of magnetic and gravity interpretation
Interpretation of the area is limited by a shortage of information on the nature and physical properties of the deeper
sedimentary sequence and the underlying basement rocks However using techniques such as cross-correlation of
gravity and pseudo-gravity data it is possible to try to differentiate between anomalies relating to basement and those
related to the sedimentary sequence
Gravity anomalies reflect changes within the sedimentary sequence as well as basement condition These
changes in density of sedimentary rocks produce gravity anomalies without a corresponding magnetic anomaly hence
the complementary nature of gravity and magnetic surveys The main use of magnetics is to determine depth to
magnetic basement and any intra-sedimentary volcanic rocks or intrusives whereas gravity provides much more
general information on the sedimentary sequence
Unfortunately interpretation of gravity anomalies is complicated since they can be due to a number of geological
features including
bull major basement faults
bull basement highs
bull igneous intrusions within the basement
bull sedimentary basins which may or may not be isostatically compensated
bull intra-sedimentary volcanics and associated plutonic centres
Two major problems affect the interpretation of both magnetic and gravity data
1 The inherent ambiguity of potential-field data There is no unique solution to any measured gravity or magnetic
anomaly and theoretically there will be an infinite number of source geometry and magnetizationdensity
combinations which will fit the observed data This means that any a priori information which helps to select a
suitable model is very useful
2 Measured anomalies are the summation of effects from different depths For example an observed gravity profile
may contain contributions from shallow sources (density variations within the sedimentary basin) intermediate
depth sources (density variations due to large igneous intrusions within the basement) and deep sources (crustal
thinning producing a mantle anomaly) Separation of these component responses is the regionalresidual problem
which we solve using spectral analysis and differential upward continuation-based separation filtering
Regional setting and interpretation overview
The area studied includes parts of BALFOUR DOWNS (SF51-9) RUDALL (SF51-10) ROBERTSON (SF51-13) GUNANYA
(SF51-14) COLLIER (SG50-4) BULLEN (SG51-1) TRAINOR (SG51-2) MADLEY (SG51-3) NABBERU (SG50-5)
STANLEY (SG51-6) and HERBERT (SG51-7) 1250 000 sheets Broadly the area lies between latitudes 22deg00rsquondash25deg30rsquoS
and longitudes 119deg30rsquondash123deg30rsquoE
51
Regional gravity
The AGSO regional gravity data (at nominal 11 km spacing) was gridded at a 4 km mesh spacing using a minimum-
curvature algorithm Bouguer gravity values in the area are negative reflecting mass deficiency at depth and range
from -84 mgals to -25 mgals
A Bouguer gravity colour image is shown as Figure 41 A residual grid was produced by removing a fifth-order
orthogonal polynomial from the Bouguer data but did not add to the interpretation
120deg 121deg 122deg 123deg
23deg
24deg
25deg
-25
-84
50 km
MKS46 180598
mgal
Figure 41 Regional Bouguer gravity (BMRAGSO data) gridded at 4 km
52
The data show a complex pattern of positive and negative anomalies with no clearly defined trends Correlations
with aeromagnetic data and known basin structures are poor A vague north-northwest linear trend appears to coincide
with the Marloo Fault (Figure 42) A prominent negative anomaly appears to coincide with the Blake Fold and Fault
Belt depocentre and continues as a narrower negative anomaly to the east until it widens out again near the edge of the
basin Elsewhere the gravity data show little correlation with known basin structures and it is likely that especially in
the north of the area gravity anomalies are due to density changes in the basement rather than changes in basement
topography
Production of wavelength-filtered residual gravity plots and vertical gradient plots showed very patchy aliased
data reflecting poor sampling in much of the area
Regional magnetics
The AGSO regional aeromagnetic data were gridded at a 400 m mesh spacing using a minimum-curvature algorithm
(Figure 43) Most of the data has a line spacing of 1600 m with small areas of 1 km spacing The quality of the data is
acceptable for regional interpretation but is not adequate for detailed analysis The accuracy of the flight path is rather
variable reflecting the vintage of the data and the noise envelope of the data is poor by modern standards Problems
were also encountered in joining different map sheets
The magnetic anomaly pattern over the south and west part of the area shows a strong high frequency signature
reflecting the presence of widespread basic sills and dykes Some of the major north-northeasterly trending dykes can
be traced over considerable distances
Discontinuous high-frequency anomalies extend as a northwest-trending zone through the centre of the area and
this zone includes a conspicuous circular magnetic anomaly which is probably a ring complex
The northern and eastern parts of the area are characterized by long-wavelength deep-seated basement magnetic
anomalies with 120deg and 150deg trends dominant The Marloo and Perentie Faults (Figure 42) appear as distinct linear
zones and offsets A prominent easterly trending negative anomaly in the northwest of the area appears to swing round
to the southeast and may separate different basement blocks One possible interpretation is that this very deep seated
anomaly separates areas of Archaean and Proterozoic basement
Regional geology
The regional geology is described in Williams (1992) The GSWA provided a digitized version of Plate 2 from this
Bulletin the structural interpretation map to use as an overlay (Figure 42)
53
Pp
Pp
PSd
PSd
PSd
PSd
PSd
PSo
PSt
PSt
PSf
PSf
PSf
PSb
PSb
PSb
PSsPSs
PSs
PSb
PSm
PSp
PSc
PSc
PSw
PSw
PSw
PSg
PSr
PSj
PSg
PM
Pk
PY
PY
PSd
L
L
L
L
L
L
L
LL
L
L
L
LL
L
LL
L L
LL
L L
L
L
L
L
L
L
L
LL
L
L
BLAKEDEPOCENTRE
MA
RLO
O
FAU
LT
PERENTIEFAULT
50 km
MKS39120598
120deg 121deg 122deg 123deg
25deg
24deg
23deg
Approximate boundaryof aeromagnetic interpretation
PML
PSgL
PSjL
PML
PSpL
PML
PML
PSfL
PSfL
PSpL
LPc
LPcLPcPSrL
LPA
Durba Sandstone
Woora Woora Formation
McFadden Formation
Tchukardine Formation
Boondawari Formation
Skates Hills Formation
Mundadjini Formation
Coondra Formation
Spearhole Formation
Watch Point Formation
Jilyili Formation
Brassey Range Formation
Glass Spring Formation
Paterson Formation
Yeneena Group
Karara Formation
Cornelia Formation
Kahrban Subgroup
Bangemall Group
Fault
Formation boundary
PSdL
PSoL
PSfL
PStL
PSbL
PSsL
PSmL
PScL
PSpL
PSwL
PSjL
PSrL
PSgL
Pp
PYL
PkL
LPc
LPA
PML
Savory Group Other Units
PYL
Figure 42 Regional geology and structure map (after Williams 1992)
54
120deg 121deg 122deg 123deg
23deg
24deg
25deg
5820
3750
MKS47 180598
nT
50 km
Figure 43 Regional aeromagnetic data total magnetic intensity (BMRAGSO data) gridded at 400 m
Analysis
3D analysis
3D Euler deconvolution was used as the primary depth-determination method The advantage of this approach is that
consistent solutions can be obtained over the entire area with minimal assumptions about source geometries Euler
deconvolution of gridded data is used for positional information and estimation of depth to top of source Euler
55
deconvolution yields a large number of depth solutions which have to be screened to reject spurious solutions Results
are plotted as circles in eight depth ranges with radius proportional to depth and colour coded
The 400 m total magnetic intensity grid was used for the analysis Horizontal gradients in x and y and the vertical
gradient were calculated 3D Euler deconvolution was tested on the 400 m gridded data using windows of 9 times 9 and
11 times 11 and 16 times 16 data points and structural indices 05 (fault) and 10 (sill or dyke) It was concluded that the
16 times 16 window produced the best results overall and final plots were produced for the 16 times 16 window and structural
index 05 (Fig 44) Results were very good over the northern and central parts of the area showing magnetic sources
Figure 44 Depth to magnetic source 3D Euler deconvolution 16 times 16 window of 400 m gridded data structural index 05
56
at several different levels Unfortunately in the extreme south of the area shallow intrasedimentary magnetic sources
(sills and dykes) dominated the inversion and the results contained few basement solutions
In order to reduce these problems the 400 m gridded data were filtered using a separation filter based on
interpretation of the log-energy spectrum The 3D Euler method was run on the filtered data in order to generate more
basement-depth solutions Results for the deep-separation filter data were gridded and presented as a colour image in
Cowan (1995) Attempts to grid the Euler output were unsatisfactory and it is considered safer to interpret the 3D
Euler depth plots The 3D Euler depth results from the separation-filter run should be analysed with care as perfect
separation of the basement can never be achieved and there will always be some contamination from sources at
different levels
The results of original total magnetic intensity 3D Euler depth estimation for structural index 05 using a 16 point
window have been plotted at 1500 000 scale (not included in this publication but available in Cowan (1995) from the
GSWA Library as S10331) and as reduced A4 colour circle plots (Figure 44)
The results of deep-basement 3D Euler depth estimation for structural index 05 using a 16 point window have
been plotted as a colour image at 1500 000 scale and as an A4 image (not included in this publication)
2D analysis
Two equispaced profiles were interpolated with a 50 m station interval from the AGSO-located data profiles for the
BULLEN 1250 000 sheet The interpolated profiles were analysed using 2D Euler deconvolution and Werner
deconvolution Results are included in Cowan (1995) and show the use of these methods for more detailed analysis
Filtered data
In order to reconcile 3D Euler results from shallow basement and intrasedimentary magnetic sources we produced
several separation-filtered maps and images We found the shallow-layer double-separation filter (Figure 45) to be
very effective for shallow sources and the deep-layer standard-separation filter (Figure 46) for the basement layer
Gravity and magnetic data correlation
Both lsquoreduced to the polersquo (RTP) magnetics (Figure 47) and pseudo-gravity data (Figure 48) were produced as part of
the reconciliation of gravity and magnetic signatures In both cases the filtering operations assumed magnetization by
induction in the present Earths field The RTP data are fairly similar to the total magnetic intensity The pseudo-
57
gravity data are dominated by a northwest-trending strong positive anomaly and there is little correlation with the
Bouguer gravity data
The poor magneticgravity correlation is confirmed by cross-correlation of the RTP magnetics and the gravity
gradient The correlation plot in Figure 49 shows little coherent response with numerous zones of positive and
negative correlation
Figure 45 Regional aeromagnetic data shallow layer separation filter (BMRAGSO data) gridded at 400 m
Results
In the north and east of the area on the Wells Foreland Sub-basin trend (refer to Figure 1 main text) we see a range
of quite deep 3D Euler depths and several trend directions with north-northwesterly dominant There are relatively few
shallow intrasedimentary solutions in this zone
The second area of deep 3D Euler solutions lies over the Blake depocentre (Figure 43) with several trend
directions
Elsewhere the 3D Euler results are dominated by shallow intrasedimentary depth solutions reflecting mainly the
dolerite sills dykes and the ring complex However where we do see basement-related solutions in the south and
west of the area they appear to be shallower than those noted for the Wells Foreland Sub-basin and the Blake
depocentre
58
Figure 46 Regional aeromagnetic data deep-layer separation filter (BMRAGSO data) gridded at 400 m
Figure 48 Regional aeromagnetic data pseudo-gravity transform (BMRAGSO data) gridded at 400 m
Figure 47 Regional aeromagnetic data reduced-to-pole (BMRAGSO data) gridded at 400 m
Figure 49 Regional aeromagnetic and gravity data gravitymagnetic correlation using RTP magnetics and gravity gradient (BMRAGSO data) gridded at 4 km
59
This subdivision of the area into two zones of deep solutions is consistent with interpreted depocentres
However the interference between sources at different levels and the complexity of the magnetic response of the
basement rocks precludes more refined interpretation at this stage
The area of deep 3D Euler solutions over the Blake depocentre correlates with the pronounced negative gravity
anomaly discussed in the gravity interpretation section Using a density contrast of -015 gcc the negative gravity
anomaly could indicate up to 6ndash8 km of low-density sedimentary rocks depending on assumptions about the regional
field
The area of deep 3D Euler solutions over the Wells Foreland Sub-basin has a complex gravity expression and no
clear basin structure emerges from inversion of these data As noted previously it is likely that observed gravity
anomalies reflect contrasts in basement density rather than basement topography
Separation filtering applied to the magnetic data helps to enhance the intrasedimentary magnetic signature and to
give a better impression of the basement magnetic signature even though separation of the basement response is not
perfect
Conclusions
Quantitative aeromagnetic interpretation using 3D Euler deconvolution supported by wavenumber filtering and image
processing has been successful in providing structural trend and depth information for the Savory Sub-basin
Quantitative magnetic interpretation has revealed two zones of relatively deep magnetic basement beneath the
Wells Foreland Sub-basin and the Blake depocentre
This analysis of the magnetic data supports interpreted depocentres but the complexity of the basement magnetic
signature and interference from sources at different depths precludes further refinement to a map of basement
topography
Regional gravity proved to be very useful in understanding the regional setting of the area and in providing
support for aspects of the interpretation The gravity data support the interpretation of the Blake depocentre
suggesting up to 6ndash8 km of low-density sedimentary rocks
The deep structure of the Savory Sub-basin area is obviously complex with different areas underlain by
Archaean and Proterozoic basement and with the Capricorn suture occurring in the centre of the area
60
Recommendations
The quantitative magnetic interpretation needs to be reconciled with geological models available for the area
In particular the zones tentatively identified as areas with thick sedimentary rocks the Wells Foreland Sub-
basin and the Blake depocentre need to be investigated
Cross sections should be prepared across the basin for joint magneticgravity modelling especially for the Blake
depocentre It is important to be able to explain the strong negative gravity anomaly in this area
In view of the effects of basement density contrasts on the gravity field for the northern part of the area we think
that additional gravity interpretation and acquisition of new gravity data may not be justified as they will not
contribute significantly to understanding basin evolution and structure
It is recommended that GSWA try to get access to company confidential high-resolution aeromagnetic data
rather than flying new surveys The GSWA might offer to fund flying of new infill areas as a bargaining point
References
The original text of this report by Cowan (1995) and 1500 000 scale maps are filed in the GSWA Library under
S10331
COWAN D 1995 Savory Basin quantitative magnetic interpretation Western Australia Geological Survey S-series
S10331 (unpublished)
VACQUIER V STEENLAND N C HENDERSON R G and ZIETZ I 1951 Interpretation of aeromagnetic
maps The Geological Society of America Memoir 47 151p
WILLIAMS I R 1992 Geology of the Savory Basin Western Australia Western Australia Geological Survey
Bulletin 141 115p
61
Appendix 5
Geochemistry
MKS38 250398
Saturate FractionC12+ GLC
1217
Pr18
Ph
22
31CSR WELL-13 315m Cuttings
Figure 51 Canning Stock Route Well 13 gas chromatograph of extract of auger drill sample
12
17
18
22
31
Pr Ph
LDDH 1 6623m CoreSaturate FractionC12+ GLC
MKS35 240398
Figure 52 Gas chromatograph of extract from core sample at 6623 m LDDH1
62
Table 51 Canning Stock Route Well 13 auger drill samples
GSWA sample Drill depth (m)(a) Comments
135601 150 At watertable 135602 203 (all samples consist 135603 310 of sand mud and water) 135604 315 At total depth
NOTE (a) Datum for drill depth is the top of sediment fill in the well which is 155 m below ground level (ie the total depth of 315 m is 47 m below ground level)
Table 52 Canning Stock Route Well 13 gas chromatography data for 315 m depth sediment sample
Parameter Value
Weight of rock extracted (grams) 945 Total extract (ppm) 519 n-Alkane distribution n-C12 07 n-C13 23 n-C14 26 n-C15 22 n-C16 19 n-C17 14 i-C19 23 n-C18 14 i-C20 08 n-C19 11 n-C20 16 n-C21 25 n-C22 29 n-C23 70 n-C24 42 n-C25 95 n-C26 43 n-C27 83 n-C28 38 n-C29 87 n-C30 31 n-C31 273 Alkane compositional data Pristane phytane ratio 279 Pristane n-C17 ratio 161 Phytane n-C18 ratio 059 CPI (1)(a) 284 CPI (2) 209 (C21 + C22) (C28 + C29) 043
NOTE (a) CPI= Carbon preference index
63
Table 53 LDDH1 extract liquid chromatography data for 6623 m concentration
Rock extracted Total extract (grams) (ppm)
702 313
NOTE ppm= parts per million
Table 54 LDDH1 saturate gas chromatography data of core for 6623 m alkane composition
Pristane Pristane Phytane (a) CPI (1) CPI (2) (C21+C22) Phytane n-C17 n-C18 (C28+C29)
103 026 024 103 102 325
NOTE (a)CPI = carbon preference index
Table 55 LDDH1 saturate gas chromatography data of core for 6623 m n-alkane distributions
Parameter Value
n-C12 17 n-C13 38 n-C14 55 n-C15 60 n-C16 65 n-C17 74 i-C19 19 n-C18 78 i-C20 19 n-C19 80 n-C20 79 n-C21 71 n-C22 64 n-C23 57 n-C25 43 n-C24 38 n-C27 31 n-C28 23 n-C29 19 n-C30 12 n-C31 10
64
Appendix 6
Table 61 Summary of data from Trainor waterbores (TWB) and Bullen waterbores (BWB)
Well AMG Elevation TD Status(b) Completion details Water Salinity Water level Flow rate Depth to consolidated AGD84 GL (m) (m) struck mgl(c) (m) (LHr) lithology aquifer(e) Z51(a) Interval (m) (100 mm PVC) (m) (mgl)(d)
TWB 1 473660E 453 122 comp 0ndash75 plain 63 7 300 24 2 880 12 m 7287404N 75ndash93 slotted (9 260) McFadden Fm 93ndash99 plain TWB 2 472 977E 475 23 abd nil 15 m 7285877N Skates Hills Fm dry TWB 3 473259E 475 50 abd nil 7 m 7285849N Skates Hills Fm dry TWB 4 463225 E 445 50 comp 0ndash22 plain 35 7 200 55 3 600 0 m 7286143N 22ndash34 slotted (8 140) Tertiary sand and gravel 23ndash60 plain TWB 5 463095E 445 31 comp 0ndash19 plain 13 26 000 655 3 600 Tertiary sand and gravel 7277721N 19ndash25 slotted (36 700) 25ndash31 plain TWB 6 457013E 455 50 comp 0ndash42 plain 38 920 119 600 0 m 7274352N 42ndash48 slotted (1 030) Cornelia Fm ss TWB 7 453739E 475 26 susp 0ndash2 plain 11 9 300 48 4 500 0 m 7263891N (10 500) Tertiary sand TWB 8 433893E 535 60 susp 0ndash2 plain 47 8 500 gt46 1 200 0 m 7245991N (10 900) Tertiary sand and Brassey Range Fm ss TWB 9 437219E 505 51 comp 0ndash47 plain 45 1 000 58 600 1 m 7235905N 47ndash51 slotted (990) Brassey Range Fm ss TWB 10 434927E 495 32 susp 0ndash2 plain 235 450 120 0 m 7225875N (500) Dolerite
65
BWB 1 287337E 580 122 abd Nil 1 m 7245861N Jilyili Fm dry BWB 2 288346E 545 50 comp 0ndash26 plain 15 630 3 29 000 0 m 7240423N 26ndash38 slotted (730) Tertiary sand and gravel 38ndash50 plain BWB 3 305637E 545 50 abd 19 8 800 43 7 200 0 m 7240423N (10 550) Tertiary ss BWB 4 320167E 515 445 comp 0ndash20 plain 9 980 445 24 000 0 m 7248097N 20ndash32 slotted (1 190) Tertiary ss 32ndash44 plain BWB 5 353393E 545 20 susp 0ndash2 plain 45 (970) 1 m 7238934N Basalt
NOTES (a) GPS accuracy ~ 150 m (b) Comp = completed abd = abandoned susp = suspended (c) Salinity from conductivity (d) Analysis total dissolved solids (e) Fm = Formation ss = sandstone
31
23deg
25deg
120deg 122deg
Trainor 1
SAVORY
SUB-BASIN
MKS54 160498
100 km
1995 SavoryGravity Survey
254
-1056
micromsec2
Figure 10 Regional Bouguer gravity map of the Savory Sub-basin
23deg
24deg
25deg
122deg30 123deg
TRAINOR 1
123deg30
50 km
MKS53 160498
-116
-626
micro msec2
Figure11 Detailed Bouguer gravity map of the
Savory 1995 Gravity Survey from the eastern Savory Sub-basin
32
Government and academic reports
Chronostratigraphy and geochemistry
The understanding of Neoproterozoic organic chemistry palynology and structural evolution is
essential to the interpretation of hydrocarbon prospectivity Pertinent reports are included in the
bibliography (Appendix 1) Unpublished palaeontology reports describe the palynology of wells in
the Savory Sub-basin (Grey 1995andashe 1996a) Grey and Cotter (1996) discussed the potential for
Neoproterozoic palynomorphs to provide a biostratigraphic framework and palaeoenvironmental
interpretation Grey and Stevens (1997) reviewed the results of palynological studies of wells
drilled in the sub-basin and reported that Supersequence 1 palynomorphs are present in TWB 6
TWB 9 and LDDH1 (Appendix 3) Grey (1996b) reported on the use of stromatolites for
correlation in the Neoproterozoic and Stevens and Grey (1997) discussed the application of
stromatolite biostratigraphy in correlating isolated dolomite outcrops in the sub-basin with well
and seismic data in the Officer Basin and Centralian Superbasin
Although geochemical data from the Savory Sub-basin are very limited results mostly
confirm thermal maturities inferred from TAI for LDDH1 and Trainor 1 (Ghori in prep Stevens
and Adamides in prep) Those parts of the Officer Basin in Western Australia which lie to the
east of the Savory Sub-basin are sparsely drilled but Ghori (in prep) reports that most of the
Neoproterozoic succession presently lies within the oil-generative window However his study
has been unable to identify effective source-rock units and the source for oil shows Thin source
rocks are present in the Neoproterozoic in LDDH1 (Fig 9) and in three wells which lie to the east
and southeast of the Savory Sub-basin namely NJD 1 Kanpa 1A and Yowalga 3
Proposed work program
From the above limited information it is concluded that additional research on the hydrocarbon
potential of the sub-basin is justified and proposals are outlined below
bull Additional modelling of gravity and aeromagnetic data from the Savory Sub-basin is required
in light of the results from Trainor 1 and Boondawari 1 Trainor 1 showed that what appeared
to be a structurally simple area based on outcrop aeromagnetic and gravity data was in fact an
area of major structuring Boondawari 1 intersected a dolerite which is in good depth
agreement with aeromagnetic depth to source results showing this technique is useful in
detecting the depth to intrusive bodies
33
bull Additional data from mineral and petroleum exploration bores may become available and
analysis of samples from these wells should be undertaken and interpreted in the context of
their relevance to the Officer Basin
bull Stratigraphic coring in the Blake Fault and Fold Belt and in the Wells Foreland Sub-basin (Fig
1) targeting source rocks is considered essential to the continuing evaluation of the
hydrocarbon prospectivity of the Savory Sub-basin
bull Correlations using at least outcrop well and potential-field data should be prepared to link the
sub-basin with the better known parts of the Officer Basin to the east
bull Remapping is required to clarify boundary positions within the Cornelia Formation this may
resolve some of the current problems of the relationship between this unit and the rest of the
Savory Sub-basin
bull Further work is required to explain the Early Cambrian or Sturtian ages interpreted for the
Cornelia Formation from sedimentary zircon UndashPb dating in drillhole Trainor 1 The
determination of the age of the organically rich but overmature claystones in this well is
critical to assessing the hydrocarbon potential of the region
bull The thin dark mudstones intersected by Akubra 1 in the Mundadjini Formation warrant
geochemical analysis Analyses of the oil shows in Mundadjini 1 and Boondawari 1 are
currently being undertaken by Amadeus Petroleum
bull Geochemical analysis of hydrocarbons in the Bangemall Basin drillhole OD23 has been
performed by Jubilee Gold and the results will be reviewed when they are submitted to
GSWA The possibility of source rocks within the Bangemall Basin charging traps within the
Bangemall Basin and the overlying Savory Sub-basin requires further investigation
Conclusions
The Savory Sub-basin is a frontier region with only three recently drilled petroleum exploration
wells and no seismic data Based on existing geological and geophysical data it is considered too
early to draw conclusions about the hydrocarbon prospectivity of the sub-basin at this stage and
there are several reasons why the area warrants further investigation
34
1 Thick accumulations of sedimentary rocks are present (up to 8 km thickness inferred) which
may contain source reservoir and sealing strata
2 Minor oil shows occur in Mundadjini 1 and Boondawari 1 and bitumen is present in mineral
exploration drillhole LDDH1 suggesting that hydrocarbons have migrated within the
Neoproterozoic sequence of the Savory Sub-basin Oil and bitumen are present in mineral
exploration drillhole OD23 in the Bangemall Basin immediately to the south of the Savory
Sub-basin and it is possible that source rocks from the Bangemall Basin could charge traps in
the overlying Savory Sub-basin
3 The age of sedimentary rocks in the sub-basin is still poorly constrained but some of the
Neoproterozoic sedimentary rocks located on GUNANYA and TRAINOR are within the
hydrocarbon-generation window It is possible that a significant thickness of Phanerozoic
sedimentary rocks may also be present
4 Friable sandstones with visible porosity outcrop extensively suggesting numerous potential
reservoirs
5 Significant but not intense faulting and folding has been mapped implying large structural
traps may be present
6 Evaporitic sedimentary rocks occur in several formations and may provide good source rocks
and excellent seals
35
References
APAK S N and CARLSEN G M 1997 A compilation and review of data pertaining to the
hydrocarbon prospectivity of the Canning Basin Western Australia Geological Survey
Record 199610 103p
BAGAS L GREY K and WILLIAMS I R 1995 Reappraisal of the Paterson Orogen and
Savory Basin Western Australia Geological Survey Annual Review 1994ndash95 p 55ndash63
BUSBRIDGE M 1994 Lake Disappointment Exploration Licence 451064 Third Annual
Report Lake Disappointment Diamond Drill Hole LDDH1 Normandy Exploration Limited
Western Australia Geological Survey M-series Item 7567 A41358 (unpublished)
CARLSEN G M and SHEVCHENKO S I 1997 Petroleum exploration in Proterozoic basins
using potential fields data and stratigraphic coring Australian Society of Exploration
Geophysicists 12th Geophysical Conference Handbook Sydney 1997 Preview no 66 p 83
(abstract only)
COWAN D 1995 Savory Basin quantitative magnetic interpretation Western Australia
Geological Survey S-series S10331 (unpublished)
DAISHSAT PTY LTD 1995 Operational and processing report Savory Basin gravity survey
Western Australia Geological Survey S-series S10332 (unpublished)
GARD E and GARD R 1990 Canning Stock Route a travellerrsquos guide for a journey through
history Perth Western Australia Western Desert Guides 448p
GEOLOGICAL SURVEY OF WESTERN AUSTRALIA 1996a Savory Basin first vertical
derivative of Bouguer gravity image 1250 000 Western Australia Geological Survey
GEOLOGICAL SURVEY OF WESTERN AUSTRALIA 1996b Savory Basin Bouguer gravity
image 1250 000 Western Australia Geological Survey
GHORI K A R in prep Petroleum source rock potential and thermal history Officer Basin
Western Australia Western Australia Geological Survey Record
36
GREY K 1995a Savory Basin drillhole BWB 1 (Bullen waterbore) palynology and thermal
maturation GSWA Palaeontology Report no 199512 (unpublished)
GREY K 1995b Savory Basin drillholes TWB 1 2 6 9 (Trainor waterbores) palynology and
thermal maturation GSWA Palaeontology Report no 199520 (unpublished)
GREY K 1995c Palynology of Normandy-Poseidon Lake Disappointment-1 corehole
Tarcunyah Group Paterson Orogen GSWA Palaeontology Report no 199521 (unpublished)
GREY K 1995d Savory Basin drillhole Trainor 1 (Trainor diamond drilling) palynology and
thermal maturity GSWA Palaeontology Report no 199524 (unpublished)
GREY K 1995e Savory Basin drillhole Trainor 1 (Trainor diamond drilling) Additional
Preparation of two samples GSWA Palaeontology Report no 199528 (unpublished)
GREY K 1995f Neoproterozoic stromatolites from the Skates Hills Formation Savory Basin
Western Australia and a review of the distribution of Acaciella australica Australian Journal
of Earth Sciences v 42 p 123ndash132
GREY K 1996a Savory Basin drillhole Trainor 1 (Trainor diamond drilling) Additional
samples palynology and thermal maturation GSWA Palaeontology Report no 199615
(unpublished)
GREY K 1996b Preliminary stromatolite correlations for the Neoproterozoic of the Officer
Basin and a review of Australia-wide correlations GSWA Palaeontology Report no 199615
(unpublished)
GREY K and COTTER K L 1996 Palynology in the search for Proterozoic hydrocarbons
Western Australia Geological Survey Annual Review for 1995ndash96 p 70ndash80
GREY K and STEVENS M K 1997 Neoproterozoic palynomorphs of the Savory Sub-basin
Western Australia and their relevance to petroleum exploration Western Australia
Geological Survey Annual Review for 1996ndash97 p 49ndash54
HUBBARD R J PAPE J and ROBERTS D G 1985 Depositional sequence mapping as a
technique to establish tectonic and stratigraphic framework and evaluate hydrocarbon
potential on a passive continental margin in Seismic stratigraphy II an integrated approach
37
edited by O R BERG and D G WOOLVERTON American Association of Petroleum
Geologists Memoir 39 p 79ndash91
LIBBY WG 1995 A petrological report on six samples of bore cuttings from the Savory Basin
Western Australia Western Australia Geological Survey S-series S31307 (unpublished)
MORTON JGG and DREXEL JF 1997 The petroleum geology of South Australia Vol 3
Officer Basin South Australia Department of Mines and Energy Resources Report Book
9719
MUHLING P C and BRAKEL A T 1985 Geology of the Bangemall Group mdash the evolution
of an intracratonic Proterozoic basin Western Australia Geological Survey Bulletin 128
219p
MYERS J S 1990 Precambrian tectonic evolution of part of Gondwana southwestern Australia
Geology v18 p 537ndash540
NELSON D R 1997 Compilation of SHRIMP UndashPb zircon data Western Australia Geological
Survey Record 19972 196p
PAYTON C E 1977 Seismic stratigraphy mdash applications to hydrocarbon exploration
American Association of Petroleum Geologists Memoir 26 516p
PERINCEK D 1996a The age of NeoproterozoicndashPalaeozoic sediments within the Officer Basin
of the Centralian Super-basin can be constrained by major sequence-bounding unconformities
APPEA Journal v 36 pt 1 p 350ndash368
PERINCEK D 1996b The stratigraphic and structural development of the Officer Basin
Western Australia a review Western Australia Geological Survey Annual Review 1995ndash
1996 p 135ndash148
PERINCEK D 1998 A compilation and review of data pertaining to the hydrocarbon
prospectivity of the Officer Basin Western Australia Geological Survey Record 19976
POSAMENTIER H W JERSEY M T and VAIL P R 1988 Eustatic controls on clastic
deposition 1 mdash Conceptual framework in Sea-level changes an integrated approach edited by
C K WILGUS B S HASTINGS C G St C KENDALL H W POSAMENTIER
38
C A ROSS and J C VAN WAGONER Society of Economic Paleontologists and
Mineralogists Special Publication no 42
STEVENS M K and ADAMIDES N G in prep GSWA Trainor 1 well completion report
Savory Sub-basin Officer Basin Western Australia with notes on petroleum and mineral
potential Western Australia Geological Survey Record 199612
STEVENS M K and GREY K 1997 Skates Hills Formation and Tarcunyah Group Officer
Basin mdash carbonate cycles stratigraphic position and hydrocarbon prospectivity Western
Australia Geological Survey Annual Review for 1996ndash97 p 55ndash60
SUMMONS RE and POWELL C McA 1991 Petroleum source rocks of the Amadeus Basin
in Geological and geophysical studies in the Amadeus Basin central Australia edited by R J
KORSCH and JM KENNARD Australia BMR Geology and Geophysics Bulletin 236
TRAVERSE A 1988 Palaeopalynology Boston Unwin Hyman 600p
VAIL P R MITCHUM R M Jr TODD R G WIDMIER J M THOMPSON S III
SANGREE J B BUBB J N and HATLELID W G 1977 Seismic stratigraphy and
global changes of sea level in Seismic stratigraphy mdash applications to hydrocarbon
exploration edited by C E PAYTON American Association of Petroleum Geologists
Memoir 26 516p
WALTER M R and GORTER J 1994 The Neoproterozoic Centralian Superbasin in Western
Australia the Savory and Officer Basins in The sedimentary basins of Western Australia
edited by P G PURCELL and R R PURCELL Petroleum Exploration Society of Australia
Symposium Perth WA 1994 Proceedings p851ndash864
WALTER M R GREY K WILLIAMS I R and CALVER C R 1994 Stratigraphy of the
Neoproterozoic to early Palaeozoic Savory Basin and correlation with the Amadeus and
Officer Basins Australian Journal of Earth Sciences v 41 p 533ndash546
WALTER M R VEEVERS J J CALVER C R and GREY K 1995 Neoproterozoic
stratigraphy of the Centralian Superbasin Australia Precambrian Research v 73 p 173ndash195
WILLIAMS I R 1992 Geology of the Savory Basin Western Australia Western Australia
Geological Survey Bulletin 141 115p
39
WILLIAMS I R 1995a Bullen WA (2nd Edition) Western Australia Geological Survey
1250 000 Geological Series Explanatory Notes 23p
WILLIAMS I R 1995b Trainor WA (2nd Edition) Western Australia Geological Survey
1250 000 Geological Series Explanatory Notes 31p
WILLIAMS I R and TYLER I M 1991 Robertson WA (2nd edition) Western Australia
Geological Survey 1250 000 Geological Series Explanatory Notes 36p
40
41
Appendix 1
Bibliography
Reports which are relevant to this investigation but which are not specifically cited are listed
below
BAILLIE P W POWELL C McA LI Z X and RYALL A M 1994 The tectonic
framework of Western Australiarsquos Neoproterozoic to recent sedimentary basins in The
sedimentary basins of Western Australia edited by P G PURCELL and R R PURCELL
Petroleum Exploration Society of Australia Symposium Perth WA 1994 Proceedings p
45ndash62
BRADSHAW M T BRADSHAW J MURRAY A P NEEDHAM D J SPENCER L
SUMMONS R E WILMOT J and WINN S 1994 Petroleum systems in West Australian
basins in The sedimentary basins of Western Australia edited by P G PURCELL and R R
PURCELL Petroleum Exploration Society of Australia Symposium Perth WA 1994
Proceedings p 93ndash118
CLARKE G L 1991 Proterozoic tectonic reworking in the Rudall Complex Western Australia
Australian Journal of Earth Science v38 p 31ndash44
COCKBAIN A E and HOCKING R M 1990 Phanerozoic in Geology and mineral resources
of Western Australia Western Australia Geological Survey Memoir 3 p 750ndash755
ETHERIDGE M and WALL V 1994 Tectonic and structural evolution of the Australian
Proterozoic 12th Australian Geological Convention Geological Society of Australia
Abstracts no 37 p 102ndash103
GOODE A D T 1981 Proterozoic geology of Western Australia in Precambrian of the
Southern Hemisphere Developments in Precambrian geology 2 edited by I R HUNTER
Amsterdam Elsevier p 105ndash203
GREY K and JACKSON M J 1983 A re-assessment of stromatolite evidence for the
correlation of the Late Proterozoic Neale and Ilma Beds Officer Basin Western Australia
Australia BMR Journal of Australian Geology and Geophysics v 8 p 359
42
HICKMAN A H WILLIAMS I R and BAGAS L 1994 Proterozoic geology and
mineralization of the TelferndashRudall region Paterson Orogen Geological Society of Australia
(WA Division) Excursion Guidebook no 5 56p
HOCKING R M MORY A J and WILLIAMS I R 1994 An atlas of Neoproterozoic and
Phanerozoic basins of Western Australia in The sedimentary basins of Western Australia
edited by P G PURCELL and R R PURCELL Petroleum Exploration Society of Australia
Symposium Perth WA 1994 Proceedings p 21ndash 44
JACKSON P R 1966 Geology and review of exploration Officer Basin Western Australia
Hunt Oil Company Western Australia Geological Survey S-series S26 (unpublished)
JACKSON M J 1971 Notes on a geological reconnaissance of the Officer Basin Western
Australia Australia BMR Geology and Geophysics Record 19715 30p
JACKSON M J and van de GRAAFF W J E 1981 Geology of the Officer Basin Western
Australia Australia BMR Geology and Geophysics Bulletin 206 102 p
LOWRY D C JACKSON M J van de GRAAFF W J E and KENNEWELL P J 1971
Preliminary result of geological mapping in the Officer Basin Western Australia Western
Australia Geological Survey Annual Report for 1971 p 50ndash56
MYERS J S 1990 Precambrian in Geology and mineral resources of Western Australia
Western Australia Geological Survey Memoir 3 p 737ndash750
MYERS J S SHAW R D and TYLER I M 1994 Proterozoic tectonic evolution of
Australia 12th Australian Geological Convention Geological Society of Australia Abstracts
no 37 p 312
NEDIN C and JENKINS R J F 1991 Re-evaluation of unconformities separating the
lsquoEdiacaranrsquo and Cambrian systems South Australia Palaios v 6 p 102ndash108
PHILLIPS B J JAMES A W and PHILIP G M 1985 The geology and hydrocarbon
potential of the north-western Officer Basin APEA Journal 25 (1) p 52ndash61
POWELL C McA LI Z X McELHINNY M W MEERT J G and PARK J K 1993
Paleomagnetic constraints on timing of the Neoproterozoic breakup of Rodinia and Cambrian
formation of Gondwana Geology v 21 p 889ndash892
43
POWELL C McA PREISS W V GATEHOUSE C G KRAPEZ B and LI Z X 1994
South Australian record of a Rodinian epicontinental basin and its mid-Neoproterozoic
breakup to form the Palaeo-Pacific Ocean Tectonophysics v 237 no 3ndash4 p 113ndash140
PREISS W V 1976 Proterozoic stromatolites from the Nabberu and Officer Basins Western
Australia and their biostratigraphic significance South Australia Geological Survey Report
of Investigations no 47 p 1ndash51
TOWNSON W G 1985 The subsurface geology of the western Officer Basin mdash results of
Shellrsquos 1980ndash1984 petroleum exploration campaign APEA Journal v 25 (1) p 34ndash51
WATTS K J 1982 The geology of the Townsend Quartzite Upper Proterozoic shallow water
deposit of the Northern Officer Basin Western Australia Perth University of Western
Australia BSc honours thesis (unpublished)
WELLS A T and KENNEWELL P J 1974 Evaporite exploration in the Officer Basin
Western Australia at the Madley Diapirs Australia BMR Record 1974194 (unpublished)
WILLIAMS I R and MYERS J S 1990 Paterson Orogen in Geology and mineral resources
of Western Australia Western Australia Geological Survey Memoir 3 p 274ndash286
WILLIAMS I R 1990 Savory Basin in Geology and mineral resources of Western Australia
Western Australia Geological Survey Memoir 3 p 329ndash334
WILLIAMS I R 1994 The Neoproterozoic Savory Basin Western Australia in The
sedimentary basins of Western Australia edited by P G PURCELL and R R PURCELL
Petroleum Exploration Society of Australia Symposium Perth WA 1994 Proceedings p
841ndash850
WILSON R B 1967 Woolnough Hills and Madley diapiric structures Gibson Desert WA
APEA Journal v 7 p 94ndash102
44
Appendix 2
Meteorological data (from Bureau of Meteorology Perth 1994)
Table 21 Wiluna rainfall (mm)
Year Jan Feb Mar Apr May Jun Jul Aug Sept Oct Nov Dec
1975 0 45 446 309 306 59 276 4 34 886 638 164 1976 16 154 12 138 53 16 34 62 12 238 0 2 1977 44 0 66 74 68 95 24 363 1 58 12 727 1978 234 522 94 16 0 96 367 24 16 353 185 45 1979 19 173 122 88 91 4 0 246 58 0 169 114 1980 148 764 68 1081 259 626 629 06 56 02 174 0 1981 123 476 192 32 196 118 44 74 14 0 28 312 1982 374 705 206 244 1079 92 02 143 368 526 368 118 1983 1 112 928 248 0 212 56 32 5 1 42 496 1984 149 7 342 84 836 0 348 132 224 04 16 172 1985 596 483 0 166 556 0 514 56 0 0 4 0 1986 0 154 35 0 0 1085 23 01 239 137 0 04 1987 1204 119 19 89 17 575 154 126 07 1 0 398 1988 46 202 164 13 388 0 202 104 0 0 224 1309 1989 207 234 26 703 278 536 57 0 01 0 144 02 1990 1035 23 281 46 126 53 94 218 44 9 42 0 1991 48 0 41 45 0 472 297 12 0 1 0 7 1992 112 96 1025 1227 323 65 04 174 0 132 48 4 1993 0 697 0 202 445 0 12 306 18 05 14 33 Mean 25 35 22 27 27 25 18 12 6 13 13 21
JAN FEB MAR APR MAY JUN JUL AUG SEP OCT NOV DEC0
10
20
30
40
Mea
n R
ain
fall
(mm
)
Month
Mean monthly rainfall in Wiluna
MKS41 140498
45
Table 22 Wiluna minimum temperature (degC)
Year Jan Feb Mar Apr May Jun Jul Aug Sept Oct Nov Dec
1975 ndash 23 203 15 94 63 71 62 103 124 169 205 1976 242 229 194 15 10 63 59 73 95 143 16 228 1977 243 25 197 148 96 95 56 86 102 ndash 188 23 1978 241 232 203 18 102 64 76 8 9 152 19 205 1979 255 226 216 167 83 6 59 79 97 145 198 223 1980 255 226 231 155 134 83 68 75 121 108 193 223 1981 245 216 19 182 119 6 54 78 138 159 163 218 1982 232 224 177 16 ndash ndash 37 111 112 164 209 225 1983 235 24 197 147 112 88 39 88 121 162 189 219 1984 241 243 191 156 ndash 72 66 7 95 161 182 211 1985 244 231 ndash 159 98 65 71 73 117 147 205 ndash 1986 ndash 229 226 155 93 96 43 49 10 122 ndash 219 1987 ndash 217 183 175 85 77 68 68 112 ndash ndash 221 1988 238 214 209 178 111 ndash ndash 86 104 157 171 195 1989 ndash 237 199 165 107 67 44 61 107 131 187 ndash 1990 232 ndash 211 155 118 62 57 87 102 149 195 22 1991 26 256 217 168 122 101 78 ndash 113 18 168 219 1992 227 227 214 169 102 98 59 69 ndash 125 159 196 1993 241 218 196 171 103 ndash 49 68 88 128 192 211 Mean 24 23 20 16 10 8 6 8 11 14 18 21
NOTE Dashes indicate data unavailable
JAN FEB MAR APR MAY JUN JUL AUG SEP OCT NOV DEC0
10
20
30
40
Month
MKS43 140498
50
Mean monthly minimum temperatures at Wiluna
Mea
n T
emp
erat
ure
(degC
)
46
Table 23 Wiluna maximum temperature (degC)
Year Jan Feb Mar Apr May Jun Jul Aug Sept Oct Nov Dec
1975 ndash 349 326 281 247 201 197 212 256 248 31 344 1976 374 369 346 297 248 206 208 225 265 287 313 388 1977 397 392 352 296 234 212 222 244 ndash 308 337 383 1978 378 345 346 316 242 195 176 205 231 295 334 356 1979 403 36 364 295 ndash ndash ndash 193 242 318 359 373 1980 392 342 377 275 24 176 179 233 292 288 349 391 1981 385 346 337 342 242 178 201 224 30 326 326 369 1982 372 359 315 307 ndash ndash 196 253 252 305 353 379 1983 381 389 327 272 263 222 187 248 287 321 336 366 1984 378 393 322 299 226 215 178 214 234 ndash 336 364 1985 40 366 ndash 294 224 216 205 212 284 307 355 ndash 1986 ndash 383 372 307 ndash 193 166 196 261 277 ndash 382 1987 ndash 339 328 305 21 202 214 218 275 ndash ndash 374 1988 388 365 353 301 23 ndash ndash 228 283 334 31 33 1989 ndash 375 339 285 238 179 181 219 275 298 336 ndash 1990 368 ndash 36 309 268 19 188 205 274 309 373 393 1991 414 416 363 315 268 206 21 ndash 279 338 332 368 1992 363 383 336 263 213 178 213 197 ndash 285 313 359 1993 396 357 344 301 221 ndash 197 215 253 294 347 362 Mean 39 37 34 30 24 20 20 22 27 30 34 37 NOTE Dashes indicate data unavailable
JAN FEB MAR APR MAY JUN JUL AUG SEP OCT NOV DEC0
10
20
30
40
Month
MKS42 140498
50
Mean monthly maximum temperatures at Wiluna
Mea
n T
emp
erat
ure
(degC
)
47
Appendix 3
Table 31 Summary of palynological results
Drillhole Depth (m) F no(a) GSWA no Lithology Formation Assemblage TAI(b)
BWB 1 74ndash75 F49668 135741 dark-grey siltstone basalt Jilyilli gt5 BWB 1 98ndash100 F49669 135742 dark-grey siltstone basalt Jilyilli gt5 BWB 1 121ndash122 F49670 135743 dark-grey siltstone basalt Jilyilli gt5 TWB 1 86ndash87 F49671 135631 dark-grey siltstone McFadden 3+ TWB 1 104ndash105 F49672 135632 dark-grey siltstone Cornelia 3+ TWB 1 121ndash122 F49673 135633 dark-grey siltstone Cornelia 4 TWB 2 14ndash15 F49674 135634 dark-grey siltstone Skates Hills 3+ TWB 6 49ndash50 F49675 135675 dark-grey siltstone Cornelia 1 3+ TWB 9 49ndash51 F49676 135704 dark-grey siltstone Brassey Range 1 3+ Trainor 1 37497- F49733 138939 black mudstone with Cornelia 5 37509 light-grey siltstone Trainor 1 3809 F49734 138940 dark-grey and black Cornelia 4- laminated mudstone Trainor 1 4170 F49735 138941 black unlaminated mudstone Cornelia 4- Trainor 1 4950 F49851 139501 dark-grey indurated siltstone Cornelia 5 Trainor 1 6032 F49852 139502 dark- and light-grey Cornelia 5 indurated siltstone Trainor 1 6434 F49853 139503 greenish indurated finely Cornelia 5 laminated siltstone LDDH 1 270 F49678 138934 dark-grey siltstone interbeds Waters 1 3+ in enterolithic evaporite Tarcunyah Gp LDDH 1 277 F49679 138935 dark-grey siltstone in cavity Waters 1 3+ in enterolithic evaporite Tarcunyah Gp
NOTES (a) GSWA Fossil Catalogue number (b) TAI = Thermal Alteration Index of Traverse (1988 plate 1)
48
Appendix 4
Savory Sub-basin quantitative magnetic and gravity interpretation (extracted from Cowan 1995)
Summary
A program of quantitative aeromagnetic interpretation has been completed on BMRAGSO data from the Savory Sub-
basin Western Australia Quantitative aeromagnetic interpretation utilized the 3D Euler deconvolution method
supported by wavenumber filtering and image processing The results have provided useful information on structural
trends and depth to magnetic sources in a structurally complex area Depth to magnetic source analysis has provided
information on intra-sedimentary magnetic sources as well as basement rocks
The results of the interpretation support previously identified depocentres However the presence of magnetic
sources at several levels makes it very difficult to produce a reliable magnetic basement depth contour map It is
considered more productive to work with the 3D Euler colour circle plots and images rather than trying to contour the
results It would be necessary to carry out a full-scale interpretation of the BMRAGSO profile data to improve on the
3D Euler results The regional gravity was found to be useful in interpreting the regional setting of the area although
the very wide data spacing limits quantitative use of the data The gravity data show quite a complex picture with
limited consistent correlation between gravity features and basin structures This suggests that gravity anomalies
reflect changes in density of the basement rocks rather than basement topography especially in the northern part of the
basin
It is recommended that the GSWA investigate access to company confidential high-resolution aeromagnetic data
prior to planning further aeromagnetic surveys Private companies have flown large parts of the northern half of the
area as part of their diamond exploration program Additional gravity coverage of the area may be more cost effective
than magnetic surveys as the gravity data provides more information on changes within the sedimentary section
Introduction
The main use of aeromagnetic data in petroleum exploration has been the determination of magnetic basement
topography although there has been increasing interest in analysis of intra-sedimentary magnetic anomalies
intrabasement and suprabasement magnetic anomalies These anomalies are used to determine depth to magnetic
basement rocks and hence determine the thickness of the sedimentary sequence Unfortunately interpretation of the
intrabasement and suprabasement magnetic anomalies is non-unique in terms of position and size of causative sources
because of the inherent ambiguity of potential-field methods However this ambiguity can be reduced by placing
49
constraints on source geometry and magnetization and by using geological and other geophysical data to constrain
the solution
Before 1970 most depth-determination techniques involved graphical determination of slopes of selected
magnetic anomalies and application of various empirical factors to convert the slopes into depth estimates Geological
Society of America Memoir 47 Interpretation of Aeromagnetic Maps by Vacquier et al (1951) was a landmark for
this type of interpretation
Automated interpretation procedures have played an increasingly important role in depth interpretation and a
wide range of techniques have been developed Many of these techniques are designed for application to located data
profiles and assume a two-dimensional geometry However there has been renewed interest in techniques applicable
to gridded data
Two distinct types of method can be recognized In the first case often described as discrete methods individual
isolated magnetic anomalies are interpreted and the results used to produce a map of basement relief In the second
case often described as continuous methods areas of data containing a number of anomalies are interpreted
statistically to produce direct output of basement depths
The discrete methods usually involve a semiautomatic initial phase which generates a large number of possible
depth solutions and an interactive second phase to screen and select acceptable solutions The advantage of this
approach is that the interpreter can select features that are relatively free from interference from adjacent anomalies
and consider all aspects of a particular magnetic anomaly The disadvantage is that interpretation can be very time
consuming as a wide range of depths are usually possible depending on the initial model chosen and a significant
amount of effort is needed to select the correct model In the case of the Savory Sub-basin dataset we encountered
problems in separating basement related effects from the effects of shallower intrasedimentary magnetic sources
Because of these problems we have concentrated on displaying the Euler results accompanied by separation filter
images of the data to show the shallower effects and deeper effects rather than trying to refine a 3D Euler
deconvolution depth-to-crystalline-basement contour
The continuous methods are very direct provided that the rather restrictive assumption can be made that all
anomalies are due to lateral magnetization changes due to basement topography This means that shallow effects and
large intrabasement anomalies must be removed from the data This involves judgement and skill as it is necessary to
distinguish between the lower amplitude suprabasement anomalies due to basement topography and the larger
intrabasement anomalies reflecting magnetization changes within the basement These methods were not considered
suitable for the Savory Sub-basin magnetic dataset but were used to invert the gravity data
50
Limitations of magnetic and gravity interpretation
Interpretation of the area is limited by a shortage of information on the nature and physical properties of the deeper
sedimentary sequence and the underlying basement rocks However using techniques such as cross-correlation of
gravity and pseudo-gravity data it is possible to try to differentiate between anomalies relating to basement and those
related to the sedimentary sequence
Gravity anomalies reflect changes within the sedimentary sequence as well as basement condition These
changes in density of sedimentary rocks produce gravity anomalies without a corresponding magnetic anomaly hence
the complementary nature of gravity and magnetic surveys The main use of magnetics is to determine depth to
magnetic basement and any intra-sedimentary volcanic rocks or intrusives whereas gravity provides much more
general information on the sedimentary sequence
Unfortunately interpretation of gravity anomalies is complicated since they can be due to a number of geological
features including
bull major basement faults
bull basement highs
bull igneous intrusions within the basement
bull sedimentary basins which may or may not be isostatically compensated
bull intra-sedimentary volcanics and associated plutonic centres
Two major problems affect the interpretation of both magnetic and gravity data
1 The inherent ambiguity of potential-field data There is no unique solution to any measured gravity or magnetic
anomaly and theoretically there will be an infinite number of source geometry and magnetizationdensity
combinations which will fit the observed data This means that any a priori information which helps to select a
suitable model is very useful
2 Measured anomalies are the summation of effects from different depths For example an observed gravity profile
may contain contributions from shallow sources (density variations within the sedimentary basin) intermediate
depth sources (density variations due to large igneous intrusions within the basement) and deep sources (crustal
thinning producing a mantle anomaly) Separation of these component responses is the regionalresidual problem
which we solve using spectral analysis and differential upward continuation-based separation filtering
Regional setting and interpretation overview
The area studied includes parts of BALFOUR DOWNS (SF51-9) RUDALL (SF51-10) ROBERTSON (SF51-13) GUNANYA
(SF51-14) COLLIER (SG50-4) BULLEN (SG51-1) TRAINOR (SG51-2) MADLEY (SG51-3) NABBERU (SG50-5)
STANLEY (SG51-6) and HERBERT (SG51-7) 1250 000 sheets Broadly the area lies between latitudes 22deg00rsquondash25deg30rsquoS
and longitudes 119deg30rsquondash123deg30rsquoE
51
Regional gravity
The AGSO regional gravity data (at nominal 11 km spacing) was gridded at a 4 km mesh spacing using a minimum-
curvature algorithm Bouguer gravity values in the area are negative reflecting mass deficiency at depth and range
from -84 mgals to -25 mgals
A Bouguer gravity colour image is shown as Figure 41 A residual grid was produced by removing a fifth-order
orthogonal polynomial from the Bouguer data but did not add to the interpretation
120deg 121deg 122deg 123deg
23deg
24deg
25deg
-25
-84
50 km
MKS46 180598
mgal
Figure 41 Regional Bouguer gravity (BMRAGSO data) gridded at 4 km
52
The data show a complex pattern of positive and negative anomalies with no clearly defined trends Correlations
with aeromagnetic data and known basin structures are poor A vague north-northwest linear trend appears to coincide
with the Marloo Fault (Figure 42) A prominent negative anomaly appears to coincide with the Blake Fold and Fault
Belt depocentre and continues as a narrower negative anomaly to the east until it widens out again near the edge of the
basin Elsewhere the gravity data show little correlation with known basin structures and it is likely that especially in
the north of the area gravity anomalies are due to density changes in the basement rather than changes in basement
topography
Production of wavelength-filtered residual gravity plots and vertical gradient plots showed very patchy aliased
data reflecting poor sampling in much of the area
Regional magnetics
The AGSO regional aeromagnetic data were gridded at a 400 m mesh spacing using a minimum-curvature algorithm
(Figure 43) Most of the data has a line spacing of 1600 m with small areas of 1 km spacing The quality of the data is
acceptable for regional interpretation but is not adequate for detailed analysis The accuracy of the flight path is rather
variable reflecting the vintage of the data and the noise envelope of the data is poor by modern standards Problems
were also encountered in joining different map sheets
The magnetic anomaly pattern over the south and west part of the area shows a strong high frequency signature
reflecting the presence of widespread basic sills and dykes Some of the major north-northeasterly trending dykes can
be traced over considerable distances
Discontinuous high-frequency anomalies extend as a northwest-trending zone through the centre of the area and
this zone includes a conspicuous circular magnetic anomaly which is probably a ring complex
The northern and eastern parts of the area are characterized by long-wavelength deep-seated basement magnetic
anomalies with 120deg and 150deg trends dominant The Marloo and Perentie Faults (Figure 42) appear as distinct linear
zones and offsets A prominent easterly trending negative anomaly in the northwest of the area appears to swing round
to the southeast and may separate different basement blocks One possible interpretation is that this very deep seated
anomaly separates areas of Archaean and Proterozoic basement
Regional geology
The regional geology is described in Williams (1992) The GSWA provided a digitized version of Plate 2 from this
Bulletin the structural interpretation map to use as an overlay (Figure 42)
53
Pp
Pp
PSd
PSd
PSd
PSd
PSd
PSo
PSt
PSt
PSf
PSf
PSf
PSb
PSb
PSb
PSsPSs
PSs
PSb
PSm
PSp
PSc
PSc
PSw
PSw
PSw
PSg
PSr
PSj
PSg
PM
Pk
PY
PY
PSd
L
L
L
L
L
L
L
LL
L
L
L
LL
L
LL
L L
LL
L L
L
L
L
L
L
L
L
LL
L
L
BLAKEDEPOCENTRE
MA
RLO
O
FAU
LT
PERENTIEFAULT
50 km
MKS39120598
120deg 121deg 122deg 123deg
25deg
24deg
23deg
Approximate boundaryof aeromagnetic interpretation
PML
PSgL
PSjL
PML
PSpL
PML
PML
PSfL
PSfL
PSpL
LPc
LPcLPcPSrL
LPA
Durba Sandstone
Woora Woora Formation
McFadden Formation
Tchukardine Formation
Boondawari Formation
Skates Hills Formation
Mundadjini Formation
Coondra Formation
Spearhole Formation
Watch Point Formation
Jilyili Formation
Brassey Range Formation
Glass Spring Formation
Paterson Formation
Yeneena Group
Karara Formation
Cornelia Formation
Kahrban Subgroup
Bangemall Group
Fault
Formation boundary
PSdL
PSoL
PSfL
PStL
PSbL
PSsL
PSmL
PScL
PSpL
PSwL
PSjL
PSrL
PSgL
Pp
PYL
PkL
LPc
LPA
PML
Savory Group Other Units
PYL
Figure 42 Regional geology and structure map (after Williams 1992)
54
120deg 121deg 122deg 123deg
23deg
24deg
25deg
5820
3750
MKS47 180598
nT
50 km
Figure 43 Regional aeromagnetic data total magnetic intensity (BMRAGSO data) gridded at 400 m
Analysis
3D analysis
3D Euler deconvolution was used as the primary depth-determination method The advantage of this approach is that
consistent solutions can be obtained over the entire area with minimal assumptions about source geometries Euler
deconvolution of gridded data is used for positional information and estimation of depth to top of source Euler
55
deconvolution yields a large number of depth solutions which have to be screened to reject spurious solutions Results
are plotted as circles in eight depth ranges with radius proportional to depth and colour coded
The 400 m total magnetic intensity grid was used for the analysis Horizontal gradients in x and y and the vertical
gradient were calculated 3D Euler deconvolution was tested on the 400 m gridded data using windows of 9 times 9 and
11 times 11 and 16 times 16 data points and structural indices 05 (fault) and 10 (sill or dyke) It was concluded that the
16 times 16 window produced the best results overall and final plots were produced for the 16 times 16 window and structural
index 05 (Fig 44) Results were very good over the northern and central parts of the area showing magnetic sources
Figure 44 Depth to magnetic source 3D Euler deconvolution 16 times 16 window of 400 m gridded data structural index 05
56
at several different levels Unfortunately in the extreme south of the area shallow intrasedimentary magnetic sources
(sills and dykes) dominated the inversion and the results contained few basement solutions
In order to reduce these problems the 400 m gridded data were filtered using a separation filter based on
interpretation of the log-energy spectrum The 3D Euler method was run on the filtered data in order to generate more
basement-depth solutions Results for the deep-separation filter data were gridded and presented as a colour image in
Cowan (1995) Attempts to grid the Euler output were unsatisfactory and it is considered safer to interpret the 3D
Euler depth plots The 3D Euler depth results from the separation-filter run should be analysed with care as perfect
separation of the basement can never be achieved and there will always be some contamination from sources at
different levels
The results of original total magnetic intensity 3D Euler depth estimation for structural index 05 using a 16 point
window have been plotted at 1500 000 scale (not included in this publication but available in Cowan (1995) from the
GSWA Library as S10331) and as reduced A4 colour circle plots (Figure 44)
The results of deep-basement 3D Euler depth estimation for structural index 05 using a 16 point window have
been plotted as a colour image at 1500 000 scale and as an A4 image (not included in this publication)
2D analysis
Two equispaced profiles were interpolated with a 50 m station interval from the AGSO-located data profiles for the
BULLEN 1250 000 sheet The interpolated profiles were analysed using 2D Euler deconvolution and Werner
deconvolution Results are included in Cowan (1995) and show the use of these methods for more detailed analysis
Filtered data
In order to reconcile 3D Euler results from shallow basement and intrasedimentary magnetic sources we produced
several separation-filtered maps and images We found the shallow-layer double-separation filter (Figure 45) to be
very effective for shallow sources and the deep-layer standard-separation filter (Figure 46) for the basement layer
Gravity and magnetic data correlation
Both lsquoreduced to the polersquo (RTP) magnetics (Figure 47) and pseudo-gravity data (Figure 48) were produced as part of
the reconciliation of gravity and magnetic signatures In both cases the filtering operations assumed magnetization by
induction in the present Earths field The RTP data are fairly similar to the total magnetic intensity The pseudo-
57
gravity data are dominated by a northwest-trending strong positive anomaly and there is little correlation with the
Bouguer gravity data
The poor magneticgravity correlation is confirmed by cross-correlation of the RTP magnetics and the gravity
gradient The correlation plot in Figure 49 shows little coherent response with numerous zones of positive and
negative correlation
Figure 45 Regional aeromagnetic data shallow layer separation filter (BMRAGSO data) gridded at 400 m
Results
In the north and east of the area on the Wells Foreland Sub-basin trend (refer to Figure 1 main text) we see a range
of quite deep 3D Euler depths and several trend directions with north-northwesterly dominant There are relatively few
shallow intrasedimentary solutions in this zone
The second area of deep 3D Euler solutions lies over the Blake depocentre (Figure 43) with several trend
directions
Elsewhere the 3D Euler results are dominated by shallow intrasedimentary depth solutions reflecting mainly the
dolerite sills dykes and the ring complex However where we do see basement-related solutions in the south and
west of the area they appear to be shallower than those noted for the Wells Foreland Sub-basin and the Blake
depocentre
58
Figure 46 Regional aeromagnetic data deep-layer separation filter (BMRAGSO data) gridded at 400 m
Figure 48 Regional aeromagnetic data pseudo-gravity transform (BMRAGSO data) gridded at 400 m
Figure 47 Regional aeromagnetic data reduced-to-pole (BMRAGSO data) gridded at 400 m
Figure 49 Regional aeromagnetic and gravity data gravitymagnetic correlation using RTP magnetics and gravity gradient (BMRAGSO data) gridded at 4 km
59
This subdivision of the area into two zones of deep solutions is consistent with interpreted depocentres
However the interference between sources at different levels and the complexity of the magnetic response of the
basement rocks precludes more refined interpretation at this stage
The area of deep 3D Euler solutions over the Blake depocentre correlates with the pronounced negative gravity
anomaly discussed in the gravity interpretation section Using a density contrast of -015 gcc the negative gravity
anomaly could indicate up to 6ndash8 km of low-density sedimentary rocks depending on assumptions about the regional
field
The area of deep 3D Euler solutions over the Wells Foreland Sub-basin has a complex gravity expression and no
clear basin structure emerges from inversion of these data As noted previously it is likely that observed gravity
anomalies reflect contrasts in basement density rather than basement topography
Separation filtering applied to the magnetic data helps to enhance the intrasedimentary magnetic signature and to
give a better impression of the basement magnetic signature even though separation of the basement response is not
perfect
Conclusions
Quantitative aeromagnetic interpretation using 3D Euler deconvolution supported by wavenumber filtering and image
processing has been successful in providing structural trend and depth information for the Savory Sub-basin
Quantitative magnetic interpretation has revealed two zones of relatively deep magnetic basement beneath the
Wells Foreland Sub-basin and the Blake depocentre
This analysis of the magnetic data supports interpreted depocentres but the complexity of the basement magnetic
signature and interference from sources at different depths precludes further refinement to a map of basement
topography
Regional gravity proved to be very useful in understanding the regional setting of the area and in providing
support for aspects of the interpretation The gravity data support the interpretation of the Blake depocentre
suggesting up to 6ndash8 km of low-density sedimentary rocks
The deep structure of the Savory Sub-basin area is obviously complex with different areas underlain by
Archaean and Proterozoic basement and with the Capricorn suture occurring in the centre of the area
60
Recommendations
The quantitative magnetic interpretation needs to be reconciled with geological models available for the area
In particular the zones tentatively identified as areas with thick sedimentary rocks the Wells Foreland Sub-
basin and the Blake depocentre need to be investigated
Cross sections should be prepared across the basin for joint magneticgravity modelling especially for the Blake
depocentre It is important to be able to explain the strong negative gravity anomaly in this area
In view of the effects of basement density contrasts on the gravity field for the northern part of the area we think
that additional gravity interpretation and acquisition of new gravity data may not be justified as they will not
contribute significantly to understanding basin evolution and structure
It is recommended that GSWA try to get access to company confidential high-resolution aeromagnetic data
rather than flying new surveys The GSWA might offer to fund flying of new infill areas as a bargaining point
References
The original text of this report by Cowan (1995) and 1500 000 scale maps are filed in the GSWA Library under
S10331
COWAN D 1995 Savory Basin quantitative magnetic interpretation Western Australia Geological Survey S-series
S10331 (unpublished)
VACQUIER V STEENLAND N C HENDERSON R G and ZIETZ I 1951 Interpretation of aeromagnetic
maps The Geological Society of America Memoir 47 151p
WILLIAMS I R 1992 Geology of the Savory Basin Western Australia Western Australia Geological Survey
Bulletin 141 115p
61
Appendix 5
Geochemistry
MKS38 250398
Saturate FractionC12+ GLC
1217
Pr18
Ph
22
31CSR WELL-13 315m Cuttings
Figure 51 Canning Stock Route Well 13 gas chromatograph of extract of auger drill sample
12
17
18
22
31
Pr Ph
LDDH 1 6623m CoreSaturate FractionC12+ GLC
MKS35 240398
Figure 52 Gas chromatograph of extract from core sample at 6623 m LDDH1
62
Table 51 Canning Stock Route Well 13 auger drill samples
GSWA sample Drill depth (m)(a) Comments
135601 150 At watertable 135602 203 (all samples consist 135603 310 of sand mud and water) 135604 315 At total depth
NOTE (a) Datum for drill depth is the top of sediment fill in the well which is 155 m below ground level (ie the total depth of 315 m is 47 m below ground level)
Table 52 Canning Stock Route Well 13 gas chromatography data for 315 m depth sediment sample
Parameter Value
Weight of rock extracted (grams) 945 Total extract (ppm) 519 n-Alkane distribution n-C12 07 n-C13 23 n-C14 26 n-C15 22 n-C16 19 n-C17 14 i-C19 23 n-C18 14 i-C20 08 n-C19 11 n-C20 16 n-C21 25 n-C22 29 n-C23 70 n-C24 42 n-C25 95 n-C26 43 n-C27 83 n-C28 38 n-C29 87 n-C30 31 n-C31 273 Alkane compositional data Pristane phytane ratio 279 Pristane n-C17 ratio 161 Phytane n-C18 ratio 059 CPI (1)(a) 284 CPI (2) 209 (C21 + C22) (C28 + C29) 043
NOTE (a) CPI= Carbon preference index
63
Table 53 LDDH1 extract liquid chromatography data for 6623 m concentration
Rock extracted Total extract (grams) (ppm)
702 313
NOTE ppm= parts per million
Table 54 LDDH1 saturate gas chromatography data of core for 6623 m alkane composition
Pristane Pristane Phytane (a) CPI (1) CPI (2) (C21+C22) Phytane n-C17 n-C18 (C28+C29)
103 026 024 103 102 325
NOTE (a)CPI = carbon preference index
Table 55 LDDH1 saturate gas chromatography data of core for 6623 m n-alkane distributions
Parameter Value
n-C12 17 n-C13 38 n-C14 55 n-C15 60 n-C16 65 n-C17 74 i-C19 19 n-C18 78 i-C20 19 n-C19 80 n-C20 79 n-C21 71 n-C22 64 n-C23 57 n-C25 43 n-C24 38 n-C27 31 n-C28 23 n-C29 19 n-C30 12 n-C31 10
64
Appendix 6
Table 61 Summary of data from Trainor waterbores (TWB) and Bullen waterbores (BWB)
Well AMG Elevation TD Status(b) Completion details Water Salinity Water level Flow rate Depth to consolidated AGD84 GL (m) (m) struck mgl(c) (m) (LHr) lithology aquifer(e) Z51(a) Interval (m) (100 mm PVC) (m) (mgl)(d)
TWB 1 473660E 453 122 comp 0ndash75 plain 63 7 300 24 2 880 12 m 7287404N 75ndash93 slotted (9 260) McFadden Fm 93ndash99 plain TWB 2 472 977E 475 23 abd nil 15 m 7285877N Skates Hills Fm dry TWB 3 473259E 475 50 abd nil 7 m 7285849N Skates Hills Fm dry TWB 4 463225 E 445 50 comp 0ndash22 plain 35 7 200 55 3 600 0 m 7286143N 22ndash34 slotted (8 140) Tertiary sand and gravel 23ndash60 plain TWB 5 463095E 445 31 comp 0ndash19 plain 13 26 000 655 3 600 Tertiary sand and gravel 7277721N 19ndash25 slotted (36 700) 25ndash31 plain TWB 6 457013E 455 50 comp 0ndash42 plain 38 920 119 600 0 m 7274352N 42ndash48 slotted (1 030) Cornelia Fm ss TWB 7 453739E 475 26 susp 0ndash2 plain 11 9 300 48 4 500 0 m 7263891N (10 500) Tertiary sand TWB 8 433893E 535 60 susp 0ndash2 plain 47 8 500 gt46 1 200 0 m 7245991N (10 900) Tertiary sand and Brassey Range Fm ss TWB 9 437219E 505 51 comp 0ndash47 plain 45 1 000 58 600 1 m 7235905N 47ndash51 slotted (990) Brassey Range Fm ss TWB 10 434927E 495 32 susp 0ndash2 plain 235 450 120 0 m 7225875N (500) Dolerite
65
BWB 1 287337E 580 122 abd Nil 1 m 7245861N Jilyili Fm dry BWB 2 288346E 545 50 comp 0ndash26 plain 15 630 3 29 000 0 m 7240423N 26ndash38 slotted (730) Tertiary sand and gravel 38ndash50 plain BWB 3 305637E 545 50 abd 19 8 800 43 7 200 0 m 7240423N (10 550) Tertiary ss BWB 4 320167E 515 445 comp 0ndash20 plain 9 980 445 24 000 0 m 7248097N 20ndash32 slotted (1 190) Tertiary ss 32ndash44 plain BWB 5 353393E 545 20 susp 0ndash2 plain 45 (970) 1 m 7238934N Basalt
NOTES (a) GPS accuracy ~ 150 m (b) Comp = completed abd = abandoned susp = suspended (c) Salinity from conductivity (d) Analysis total dissolved solids (e) Fm = Formation ss = sandstone
32
Government and academic reports
Chronostratigraphy and geochemistry
The understanding of Neoproterozoic organic chemistry palynology and structural evolution is
essential to the interpretation of hydrocarbon prospectivity Pertinent reports are included in the
bibliography (Appendix 1) Unpublished palaeontology reports describe the palynology of wells in
the Savory Sub-basin (Grey 1995andashe 1996a) Grey and Cotter (1996) discussed the potential for
Neoproterozoic palynomorphs to provide a biostratigraphic framework and palaeoenvironmental
interpretation Grey and Stevens (1997) reviewed the results of palynological studies of wells
drilled in the sub-basin and reported that Supersequence 1 palynomorphs are present in TWB 6
TWB 9 and LDDH1 (Appendix 3) Grey (1996b) reported on the use of stromatolites for
correlation in the Neoproterozoic and Stevens and Grey (1997) discussed the application of
stromatolite biostratigraphy in correlating isolated dolomite outcrops in the sub-basin with well
and seismic data in the Officer Basin and Centralian Superbasin
Although geochemical data from the Savory Sub-basin are very limited results mostly
confirm thermal maturities inferred from TAI for LDDH1 and Trainor 1 (Ghori in prep Stevens
and Adamides in prep) Those parts of the Officer Basin in Western Australia which lie to the
east of the Savory Sub-basin are sparsely drilled but Ghori (in prep) reports that most of the
Neoproterozoic succession presently lies within the oil-generative window However his study
has been unable to identify effective source-rock units and the source for oil shows Thin source
rocks are present in the Neoproterozoic in LDDH1 (Fig 9) and in three wells which lie to the east
and southeast of the Savory Sub-basin namely NJD 1 Kanpa 1A and Yowalga 3
Proposed work program
From the above limited information it is concluded that additional research on the hydrocarbon
potential of the sub-basin is justified and proposals are outlined below
bull Additional modelling of gravity and aeromagnetic data from the Savory Sub-basin is required
in light of the results from Trainor 1 and Boondawari 1 Trainor 1 showed that what appeared
to be a structurally simple area based on outcrop aeromagnetic and gravity data was in fact an
area of major structuring Boondawari 1 intersected a dolerite which is in good depth
agreement with aeromagnetic depth to source results showing this technique is useful in
detecting the depth to intrusive bodies
33
bull Additional data from mineral and petroleum exploration bores may become available and
analysis of samples from these wells should be undertaken and interpreted in the context of
their relevance to the Officer Basin
bull Stratigraphic coring in the Blake Fault and Fold Belt and in the Wells Foreland Sub-basin (Fig
1) targeting source rocks is considered essential to the continuing evaluation of the
hydrocarbon prospectivity of the Savory Sub-basin
bull Correlations using at least outcrop well and potential-field data should be prepared to link the
sub-basin with the better known parts of the Officer Basin to the east
bull Remapping is required to clarify boundary positions within the Cornelia Formation this may
resolve some of the current problems of the relationship between this unit and the rest of the
Savory Sub-basin
bull Further work is required to explain the Early Cambrian or Sturtian ages interpreted for the
Cornelia Formation from sedimentary zircon UndashPb dating in drillhole Trainor 1 The
determination of the age of the organically rich but overmature claystones in this well is
critical to assessing the hydrocarbon potential of the region
bull The thin dark mudstones intersected by Akubra 1 in the Mundadjini Formation warrant
geochemical analysis Analyses of the oil shows in Mundadjini 1 and Boondawari 1 are
currently being undertaken by Amadeus Petroleum
bull Geochemical analysis of hydrocarbons in the Bangemall Basin drillhole OD23 has been
performed by Jubilee Gold and the results will be reviewed when they are submitted to
GSWA The possibility of source rocks within the Bangemall Basin charging traps within the
Bangemall Basin and the overlying Savory Sub-basin requires further investigation
Conclusions
The Savory Sub-basin is a frontier region with only three recently drilled petroleum exploration
wells and no seismic data Based on existing geological and geophysical data it is considered too
early to draw conclusions about the hydrocarbon prospectivity of the sub-basin at this stage and
there are several reasons why the area warrants further investigation
34
1 Thick accumulations of sedimentary rocks are present (up to 8 km thickness inferred) which
may contain source reservoir and sealing strata
2 Minor oil shows occur in Mundadjini 1 and Boondawari 1 and bitumen is present in mineral
exploration drillhole LDDH1 suggesting that hydrocarbons have migrated within the
Neoproterozoic sequence of the Savory Sub-basin Oil and bitumen are present in mineral
exploration drillhole OD23 in the Bangemall Basin immediately to the south of the Savory
Sub-basin and it is possible that source rocks from the Bangemall Basin could charge traps in
the overlying Savory Sub-basin
3 The age of sedimentary rocks in the sub-basin is still poorly constrained but some of the
Neoproterozoic sedimentary rocks located on GUNANYA and TRAINOR are within the
hydrocarbon-generation window It is possible that a significant thickness of Phanerozoic
sedimentary rocks may also be present
4 Friable sandstones with visible porosity outcrop extensively suggesting numerous potential
reservoirs
5 Significant but not intense faulting and folding has been mapped implying large structural
traps may be present
6 Evaporitic sedimentary rocks occur in several formations and may provide good source rocks
and excellent seals
35
References
APAK S N and CARLSEN G M 1997 A compilation and review of data pertaining to the
hydrocarbon prospectivity of the Canning Basin Western Australia Geological Survey
Record 199610 103p
BAGAS L GREY K and WILLIAMS I R 1995 Reappraisal of the Paterson Orogen and
Savory Basin Western Australia Geological Survey Annual Review 1994ndash95 p 55ndash63
BUSBRIDGE M 1994 Lake Disappointment Exploration Licence 451064 Third Annual
Report Lake Disappointment Diamond Drill Hole LDDH1 Normandy Exploration Limited
Western Australia Geological Survey M-series Item 7567 A41358 (unpublished)
CARLSEN G M and SHEVCHENKO S I 1997 Petroleum exploration in Proterozoic basins
using potential fields data and stratigraphic coring Australian Society of Exploration
Geophysicists 12th Geophysical Conference Handbook Sydney 1997 Preview no 66 p 83
(abstract only)
COWAN D 1995 Savory Basin quantitative magnetic interpretation Western Australia
Geological Survey S-series S10331 (unpublished)
DAISHSAT PTY LTD 1995 Operational and processing report Savory Basin gravity survey
Western Australia Geological Survey S-series S10332 (unpublished)
GARD E and GARD R 1990 Canning Stock Route a travellerrsquos guide for a journey through
history Perth Western Australia Western Desert Guides 448p
GEOLOGICAL SURVEY OF WESTERN AUSTRALIA 1996a Savory Basin first vertical
derivative of Bouguer gravity image 1250 000 Western Australia Geological Survey
GEOLOGICAL SURVEY OF WESTERN AUSTRALIA 1996b Savory Basin Bouguer gravity
image 1250 000 Western Australia Geological Survey
GHORI K A R in prep Petroleum source rock potential and thermal history Officer Basin
Western Australia Western Australia Geological Survey Record
36
GREY K 1995a Savory Basin drillhole BWB 1 (Bullen waterbore) palynology and thermal
maturation GSWA Palaeontology Report no 199512 (unpublished)
GREY K 1995b Savory Basin drillholes TWB 1 2 6 9 (Trainor waterbores) palynology and
thermal maturation GSWA Palaeontology Report no 199520 (unpublished)
GREY K 1995c Palynology of Normandy-Poseidon Lake Disappointment-1 corehole
Tarcunyah Group Paterson Orogen GSWA Palaeontology Report no 199521 (unpublished)
GREY K 1995d Savory Basin drillhole Trainor 1 (Trainor diamond drilling) palynology and
thermal maturity GSWA Palaeontology Report no 199524 (unpublished)
GREY K 1995e Savory Basin drillhole Trainor 1 (Trainor diamond drilling) Additional
Preparation of two samples GSWA Palaeontology Report no 199528 (unpublished)
GREY K 1995f Neoproterozoic stromatolites from the Skates Hills Formation Savory Basin
Western Australia and a review of the distribution of Acaciella australica Australian Journal
of Earth Sciences v 42 p 123ndash132
GREY K 1996a Savory Basin drillhole Trainor 1 (Trainor diamond drilling) Additional
samples palynology and thermal maturation GSWA Palaeontology Report no 199615
(unpublished)
GREY K 1996b Preliminary stromatolite correlations for the Neoproterozoic of the Officer
Basin and a review of Australia-wide correlations GSWA Palaeontology Report no 199615
(unpublished)
GREY K and COTTER K L 1996 Palynology in the search for Proterozoic hydrocarbons
Western Australia Geological Survey Annual Review for 1995ndash96 p 70ndash80
GREY K and STEVENS M K 1997 Neoproterozoic palynomorphs of the Savory Sub-basin
Western Australia and their relevance to petroleum exploration Western Australia
Geological Survey Annual Review for 1996ndash97 p 49ndash54
HUBBARD R J PAPE J and ROBERTS D G 1985 Depositional sequence mapping as a
technique to establish tectonic and stratigraphic framework and evaluate hydrocarbon
potential on a passive continental margin in Seismic stratigraphy II an integrated approach
37
edited by O R BERG and D G WOOLVERTON American Association of Petroleum
Geologists Memoir 39 p 79ndash91
LIBBY WG 1995 A petrological report on six samples of bore cuttings from the Savory Basin
Western Australia Western Australia Geological Survey S-series S31307 (unpublished)
MORTON JGG and DREXEL JF 1997 The petroleum geology of South Australia Vol 3
Officer Basin South Australia Department of Mines and Energy Resources Report Book
9719
MUHLING P C and BRAKEL A T 1985 Geology of the Bangemall Group mdash the evolution
of an intracratonic Proterozoic basin Western Australia Geological Survey Bulletin 128
219p
MYERS J S 1990 Precambrian tectonic evolution of part of Gondwana southwestern Australia
Geology v18 p 537ndash540
NELSON D R 1997 Compilation of SHRIMP UndashPb zircon data Western Australia Geological
Survey Record 19972 196p
PAYTON C E 1977 Seismic stratigraphy mdash applications to hydrocarbon exploration
American Association of Petroleum Geologists Memoir 26 516p
PERINCEK D 1996a The age of NeoproterozoicndashPalaeozoic sediments within the Officer Basin
of the Centralian Super-basin can be constrained by major sequence-bounding unconformities
APPEA Journal v 36 pt 1 p 350ndash368
PERINCEK D 1996b The stratigraphic and structural development of the Officer Basin
Western Australia a review Western Australia Geological Survey Annual Review 1995ndash
1996 p 135ndash148
PERINCEK D 1998 A compilation and review of data pertaining to the hydrocarbon
prospectivity of the Officer Basin Western Australia Geological Survey Record 19976
POSAMENTIER H W JERSEY M T and VAIL P R 1988 Eustatic controls on clastic
deposition 1 mdash Conceptual framework in Sea-level changes an integrated approach edited by
C K WILGUS B S HASTINGS C G St C KENDALL H W POSAMENTIER
38
C A ROSS and J C VAN WAGONER Society of Economic Paleontologists and
Mineralogists Special Publication no 42
STEVENS M K and ADAMIDES N G in prep GSWA Trainor 1 well completion report
Savory Sub-basin Officer Basin Western Australia with notes on petroleum and mineral
potential Western Australia Geological Survey Record 199612
STEVENS M K and GREY K 1997 Skates Hills Formation and Tarcunyah Group Officer
Basin mdash carbonate cycles stratigraphic position and hydrocarbon prospectivity Western
Australia Geological Survey Annual Review for 1996ndash97 p 55ndash60
SUMMONS RE and POWELL C McA 1991 Petroleum source rocks of the Amadeus Basin
in Geological and geophysical studies in the Amadeus Basin central Australia edited by R J
KORSCH and JM KENNARD Australia BMR Geology and Geophysics Bulletin 236
TRAVERSE A 1988 Palaeopalynology Boston Unwin Hyman 600p
VAIL P R MITCHUM R M Jr TODD R G WIDMIER J M THOMPSON S III
SANGREE J B BUBB J N and HATLELID W G 1977 Seismic stratigraphy and
global changes of sea level in Seismic stratigraphy mdash applications to hydrocarbon
exploration edited by C E PAYTON American Association of Petroleum Geologists
Memoir 26 516p
WALTER M R and GORTER J 1994 The Neoproterozoic Centralian Superbasin in Western
Australia the Savory and Officer Basins in The sedimentary basins of Western Australia
edited by P G PURCELL and R R PURCELL Petroleum Exploration Society of Australia
Symposium Perth WA 1994 Proceedings p851ndash864
WALTER M R GREY K WILLIAMS I R and CALVER C R 1994 Stratigraphy of the
Neoproterozoic to early Palaeozoic Savory Basin and correlation with the Amadeus and
Officer Basins Australian Journal of Earth Sciences v 41 p 533ndash546
WALTER M R VEEVERS J J CALVER C R and GREY K 1995 Neoproterozoic
stratigraphy of the Centralian Superbasin Australia Precambrian Research v 73 p 173ndash195
WILLIAMS I R 1992 Geology of the Savory Basin Western Australia Western Australia
Geological Survey Bulletin 141 115p
39
WILLIAMS I R 1995a Bullen WA (2nd Edition) Western Australia Geological Survey
1250 000 Geological Series Explanatory Notes 23p
WILLIAMS I R 1995b Trainor WA (2nd Edition) Western Australia Geological Survey
1250 000 Geological Series Explanatory Notes 31p
WILLIAMS I R and TYLER I M 1991 Robertson WA (2nd edition) Western Australia
Geological Survey 1250 000 Geological Series Explanatory Notes 36p
40
41
Appendix 1
Bibliography
Reports which are relevant to this investigation but which are not specifically cited are listed
below
BAILLIE P W POWELL C McA LI Z X and RYALL A M 1994 The tectonic
framework of Western Australiarsquos Neoproterozoic to recent sedimentary basins in The
sedimentary basins of Western Australia edited by P G PURCELL and R R PURCELL
Petroleum Exploration Society of Australia Symposium Perth WA 1994 Proceedings p
45ndash62
BRADSHAW M T BRADSHAW J MURRAY A P NEEDHAM D J SPENCER L
SUMMONS R E WILMOT J and WINN S 1994 Petroleum systems in West Australian
basins in The sedimentary basins of Western Australia edited by P G PURCELL and R R
PURCELL Petroleum Exploration Society of Australia Symposium Perth WA 1994
Proceedings p 93ndash118
CLARKE G L 1991 Proterozoic tectonic reworking in the Rudall Complex Western Australia
Australian Journal of Earth Science v38 p 31ndash44
COCKBAIN A E and HOCKING R M 1990 Phanerozoic in Geology and mineral resources
of Western Australia Western Australia Geological Survey Memoir 3 p 750ndash755
ETHERIDGE M and WALL V 1994 Tectonic and structural evolution of the Australian
Proterozoic 12th Australian Geological Convention Geological Society of Australia
Abstracts no 37 p 102ndash103
GOODE A D T 1981 Proterozoic geology of Western Australia in Precambrian of the
Southern Hemisphere Developments in Precambrian geology 2 edited by I R HUNTER
Amsterdam Elsevier p 105ndash203
GREY K and JACKSON M J 1983 A re-assessment of stromatolite evidence for the
correlation of the Late Proterozoic Neale and Ilma Beds Officer Basin Western Australia
Australia BMR Journal of Australian Geology and Geophysics v 8 p 359
42
HICKMAN A H WILLIAMS I R and BAGAS L 1994 Proterozoic geology and
mineralization of the TelferndashRudall region Paterson Orogen Geological Society of Australia
(WA Division) Excursion Guidebook no 5 56p
HOCKING R M MORY A J and WILLIAMS I R 1994 An atlas of Neoproterozoic and
Phanerozoic basins of Western Australia in The sedimentary basins of Western Australia
edited by P G PURCELL and R R PURCELL Petroleum Exploration Society of Australia
Symposium Perth WA 1994 Proceedings p 21ndash 44
JACKSON P R 1966 Geology and review of exploration Officer Basin Western Australia
Hunt Oil Company Western Australia Geological Survey S-series S26 (unpublished)
JACKSON M J 1971 Notes on a geological reconnaissance of the Officer Basin Western
Australia Australia BMR Geology and Geophysics Record 19715 30p
JACKSON M J and van de GRAAFF W J E 1981 Geology of the Officer Basin Western
Australia Australia BMR Geology and Geophysics Bulletin 206 102 p
LOWRY D C JACKSON M J van de GRAAFF W J E and KENNEWELL P J 1971
Preliminary result of geological mapping in the Officer Basin Western Australia Western
Australia Geological Survey Annual Report for 1971 p 50ndash56
MYERS J S 1990 Precambrian in Geology and mineral resources of Western Australia
Western Australia Geological Survey Memoir 3 p 737ndash750
MYERS J S SHAW R D and TYLER I M 1994 Proterozoic tectonic evolution of
Australia 12th Australian Geological Convention Geological Society of Australia Abstracts
no 37 p 312
NEDIN C and JENKINS R J F 1991 Re-evaluation of unconformities separating the
lsquoEdiacaranrsquo and Cambrian systems South Australia Palaios v 6 p 102ndash108
PHILLIPS B J JAMES A W and PHILIP G M 1985 The geology and hydrocarbon
potential of the north-western Officer Basin APEA Journal 25 (1) p 52ndash61
POWELL C McA LI Z X McELHINNY M W MEERT J G and PARK J K 1993
Paleomagnetic constraints on timing of the Neoproterozoic breakup of Rodinia and Cambrian
formation of Gondwana Geology v 21 p 889ndash892
43
POWELL C McA PREISS W V GATEHOUSE C G KRAPEZ B and LI Z X 1994
South Australian record of a Rodinian epicontinental basin and its mid-Neoproterozoic
breakup to form the Palaeo-Pacific Ocean Tectonophysics v 237 no 3ndash4 p 113ndash140
PREISS W V 1976 Proterozoic stromatolites from the Nabberu and Officer Basins Western
Australia and their biostratigraphic significance South Australia Geological Survey Report
of Investigations no 47 p 1ndash51
TOWNSON W G 1985 The subsurface geology of the western Officer Basin mdash results of
Shellrsquos 1980ndash1984 petroleum exploration campaign APEA Journal v 25 (1) p 34ndash51
WATTS K J 1982 The geology of the Townsend Quartzite Upper Proterozoic shallow water
deposit of the Northern Officer Basin Western Australia Perth University of Western
Australia BSc honours thesis (unpublished)
WELLS A T and KENNEWELL P J 1974 Evaporite exploration in the Officer Basin
Western Australia at the Madley Diapirs Australia BMR Record 1974194 (unpublished)
WILLIAMS I R and MYERS J S 1990 Paterson Orogen in Geology and mineral resources
of Western Australia Western Australia Geological Survey Memoir 3 p 274ndash286
WILLIAMS I R 1990 Savory Basin in Geology and mineral resources of Western Australia
Western Australia Geological Survey Memoir 3 p 329ndash334
WILLIAMS I R 1994 The Neoproterozoic Savory Basin Western Australia in The
sedimentary basins of Western Australia edited by P G PURCELL and R R PURCELL
Petroleum Exploration Society of Australia Symposium Perth WA 1994 Proceedings p
841ndash850
WILSON R B 1967 Woolnough Hills and Madley diapiric structures Gibson Desert WA
APEA Journal v 7 p 94ndash102
44
Appendix 2
Meteorological data (from Bureau of Meteorology Perth 1994)
Table 21 Wiluna rainfall (mm)
Year Jan Feb Mar Apr May Jun Jul Aug Sept Oct Nov Dec
1975 0 45 446 309 306 59 276 4 34 886 638 164 1976 16 154 12 138 53 16 34 62 12 238 0 2 1977 44 0 66 74 68 95 24 363 1 58 12 727 1978 234 522 94 16 0 96 367 24 16 353 185 45 1979 19 173 122 88 91 4 0 246 58 0 169 114 1980 148 764 68 1081 259 626 629 06 56 02 174 0 1981 123 476 192 32 196 118 44 74 14 0 28 312 1982 374 705 206 244 1079 92 02 143 368 526 368 118 1983 1 112 928 248 0 212 56 32 5 1 42 496 1984 149 7 342 84 836 0 348 132 224 04 16 172 1985 596 483 0 166 556 0 514 56 0 0 4 0 1986 0 154 35 0 0 1085 23 01 239 137 0 04 1987 1204 119 19 89 17 575 154 126 07 1 0 398 1988 46 202 164 13 388 0 202 104 0 0 224 1309 1989 207 234 26 703 278 536 57 0 01 0 144 02 1990 1035 23 281 46 126 53 94 218 44 9 42 0 1991 48 0 41 45 0 472 297 12 0 1 0 7 1992 112 96 1025 1227 323 65 04 174 0 132 48 4 1993 0 697 0 202 445 0 12 306 18 05 14 33 Mean 25 35 22 27 27 25 18 12 6 13 13 21
JAN FEB MAR APR MAY JUN JUL AUG SEP OCT NOV DEC0
10
20
30
40
Mea
n R
ain
fall
(mm
)
Month
Mean monthly rainfall in Wiluna
MKS41 140498
45
Table 22 Wiluna minimum temperature (degC)
Year Jan Feb Mar Apr May Jun Jul Aug Sept Oct Nov Dec
1975 ndash 23 203 15 94 63 71 62 103 124 169 205 1976 242 229 194 15 10 63 59 73 95 143 16 228 1977 243 25 197 148 96 95 56 86 102 ndash 188 23 1978 241 232 203 18 102 64 76 8 9 152 19 205 1979 255 226 216 167 83 6 59 79 97 145 198 223 1980 255 226 231 155 134 83 68 75 121 108 193 223 1981 245 216 19 182 119 6 54 78 138 159 163 218 1982 232 224 177 16 ndash ndash 37 111 112 164 209 225 1983 235 24 197 147 112 88 39 88 121 162 189 219 1984 241 243 191 156 ndash 72 66 7 95 161 182 211 1985 244 231 ndash 159 98 65 71 73 117 147 205 ndash 1986 ndash 229 226 155 93 96 43 49 10 122 ndash 219 1987 ndash 217 183 175 85 77 68 68 112 ndash ndash 221 1988 238 214 209 178 111 ndash ndash 86 104 157 171 195 1989 ndash 237 199 165 107 67 44 61 107 131 187 ndash 1990 232 ndash 211 155 118 62 57 87 102 149 195 22 1991 26 256 217 168 122 101 78 ndash 113 18 168 219 1992 227 227 214 169 102 98 59 69 ndash 125 159 196 1993 241 218 196 171 103 ndash 49 68 88 128 192 211 Mean 24 23 20 16 10 8 6 8 11 14 18 21
NOTE Dashes indicate data unavailable
JAN FEB MAR APR MAY JUN JUL AUG SEP OCT NOV DEC0
10
20
30
40
Month
MKS43 140498
50
Mean monthly minimum temperatures at Wiluna
Mea
n T
emp
erat
ure
(degC
)
46
Table 23 Wiluna maximum temperature (degC)
Year Jan Feb Mar Apr May Jun Jul Aug Sept Oct Nov Dec
1975 ndash 349 326 281 247 201 197 212 256 248 31 344 1976 374 369 346 297 248 206 208 225 265 287 313 388 1977 397 392 352 296 234 212 222 244 ndash 308 337 383 1978 378 345 346 316 242 195 176 205 231 295 334 356 1979 403 36 364 295 ndash ndash ndash 193 242 318 359 373 1980 392 342 377 275 24 176 179 233 292 288 349 391 1981 385 346 337 342 242 178 201 224 30 326 326 369 1982 372 359 315 307 ndash ndash 196 253 252 305 353 379 1983 381 389 327 272 263 222 187 248 287 321 336 366 1984 378 393 322 299 226 215 178 214 234 ndash 336 364 1985 40 366 ndash 294 224 216 205 212 284 307 355 ndash 1986 ndash 383 372 307 ndash 193 166 196 261 277 ndash 382 1987 ndash 339 328 305 21 202 214 218 275 ndash ndash 374 1988 388 365 353 301 23 ndash ndash 228 283 334 31 33 1989 ndash 375 339 285 238 179 181 219 275 298 336 ndash 1990 368 ndash 36 309 268 19 188 205 274 309 373 393 1991 414 416 363 315 268 206 21 ndash 279 338 332 368 1992 363 383 336 263 213 178 213 197 ndash 285 313 359 1993 396 357 344 301 221 ndash 197 215 253 294 347 362 Mean 39 37 34 30 24 20 20 22 27 30 34 37 NOTE Dashes indicate data unavailable
JAN FEB MAR APR MAY JUN JUL AUG SEP OCT NOV DEC0
10
20
30
40
Month
MKS42 140498
50
Mean monthly maximum temperatures at Wiluna
Mea
n T
emp
erat
ure
(degC
)
47
Appendix 3
Table 31 Summary of palynological results
Drillhole Depth (m) F no(a) GSWA no Lithology Formation Assemblage TAI(b)
BWB 1 74ndash75 F49668 135741 dark-grey siltstone basalt Jilyilli gt5 BWB 1 98ndash100 F49669 135742 dark-grey siltstone basalt Jilyilli gt5 BWB 1 121ndash122 F49670 135743 dark-grey siltstone basalt Jilyilli gt5 TWB 1 86ndash87 F49671 135631 dark-grey siltstone McFadden 3+ TWB 1 104ndash105 F49672 135632 dark-grey siltstone Cornelia 3+ TWB 1 121ndash122 F49673 135633 dark-grey siltstone Cornelia 4 TWB 2 14ndash15 F49674 135634 dark-grey siltstone Skates Hills 3+ TWB 6 49ndash50 F49675 135675 dark-grey siltstone Cornelia 1 3+ TWB 9 49ndash51 F49676 135704 dark-grey siltstone Brassey Range 1 3+ Trainor 1 37497- F49733 138939 black mudstone with Cornelia 5 37509 light-grey siltstone Trainor 1 3809 F49734 138940 dark-grey and black Cornelia 4- laminated mudstone Trainor 1 4170 F49735 138941 black unlaminated mudstone Cornelia 4- Trainor 1 4950 F49851 139501 dark-grey indurated siltstone Cornelia 5 Trainor 1 6032 F49852 139502 dark- and light-grey Cornelia 5 indurated siltstone Trainor 1 6434 F49853 139503 greenish indurated finely Cornelia 5 laminated siltstone LDDH 1 270 F49678 138934 dark-grey siltstone interbeds Waters 1 3+ in enterolithic evaporite Tarcunyah Gp LDDH 1 277 F49679 138935 dark-grey siltstone in cavity Waters 1 3+ in enterolithic evaporite Tarcunyah Gp
NOTES (a) GSWA Fossil Catalogue number (b) TAI = Thermal Alteration Index of Traverse (1988 plate 1)
48
Appendix 4
Savory Sub-basin quantitative magnetic and gravity interpretation (extracted from Cowan 1995)
Summary
A program of quantitative aeromagnetic interpretation has been completed on BMRAGSO data from the Savory Sub-
basin Western Australia Quantitative aeromagnetic interpretation utilized the 3D Euler deconvolution method
supported by wavenumber filtering and image processing The results have provided useful information on structural
trends and depth to magnetic sources in a structurally complex area Depth to magnetic source analysis has provided
information on intra-sedimentary magnetic sources as well as basement rocks
The results of the interpretation support previously identified depocentres However the presence of magnetic
sources at several levels makes it very difficult to produce a reliable magnetic basement depth contour map It is
considered more productive to work with the 3D Euler colour circle plots and images rather than trying to contour the
results It would be necessary to carry out a full-scale interpretation of the BMRAGSO profile data to improve on the
3D Euler results The regional gravity was found to be useful in interpreting the regional setting of the area although
the very wide data spacing limits quantitative use of the data The gravity data show quite a complex picture with
limited consistent correlation between gravity features and basin structures This suggests that gravity anomalies
reflect changes in density of the basement rocks rather than basement topography especially in the northern part of the
basin
It is recommended that the GSWA investigate access to company confidential high-resolution aeromagnetic data
prior to planning further aeromagnetic surveys Private companies have flown large parts of the northern half of the
area as part of their diamond exploration program Additional gravity coverage of the area may be more cost effective
than magnetic surveys as the gravity data provides more information on changes within the sedimentary section
Introduction
The main use of aeromagnetic data in petroleum exploration has been the determination of magnetic basement
topography although there has been increasing interest in analysis of intra-sedimentary magnetic anomalies
intrabasement and suprabasement magnetic anomalies These anomalies are used to determine depth to magnetic
basement rocks and hence determine the thickness of the sedimentary sequence Unfortunately interpretation of the
intrabasement and suprabasement magnetic anomalies is non-unique in terms of position and size of causative sources
because of the inherent ambiguity of potential-field methods However this ambiguity can be reduced by placing
49
constraints on source geometry and magnetization and by using geological and other geophysical data to constrain
the solution
Before 1970 most depth-determination techniques involved graphical determination of slopes of selected
magnetic anomalies and application of various empirical factors to convert the slopes into depth estimates Geological
Society of America Memoir 47 Interpretation of Aeromagnetic Maps by Vacquier et al (1951) was a landmark for
this type of interpretation
Automated interpretation procedures have played an increasingly important role in depth interpretation and a
wide range of techniques have been developed Many of these techniques are designed for application to located data
profiles and assume a two-dimensional geometry However there has been renewed interest in techniques applicable
to gridded data
Two distinct types of method can be recognized In the first case often described as discrete methods individual
isolated magnetic anomalies are interpreted and the results used to produce a map of basement relief In the second
case often described as continuous methods areas of data containing a number of anomalies are interpreted
statistically to produce direct output of basement depths
The discrete methods usually involve a semiautomatic initial phase which generates a large number of possible
depth solutions and an interactive second phase to screen and select acceptable solutions The advantage of this
approach is that the interpreter can select features that are relatively free from interference from adjacent anomalies
and consider all aspects of a particular magnetic anomaly The disadvantage is that interpretation can be very time
consuming as a wide range of depths are usually possible depending on the initial model chosen and a significant
amount of effort is needed to select the correct model In the case of the Savory Sub-basin dataset we encountered
problems in separating basement related effects from the effects of shallower intrasedimentary magnetic sources
Because of these problems we have concentrated on displaying the Euler results accompanied by separation filter
images of the data to show the shallower effects and deeper effects rather than trying to refine a 3D Euler
deconvolution depth-to-crystalline-basement contour
The continuous methods are very direct provided that the rather restrictive assumption can be made that all
anomalies are due to lateral magnetization changes due to basement topography This means that shallow effects and
large intrabasement anomalies must be removed from the data This involves judgement and skill as it is necessary to
distinguish between the lower amplitude suprabasement anomalies due to basement topography and the larger
intrabasement anomalies reflecting magnetization changes within the basement These methods were not considered
suitable for the Savory Sub-basin magnetic dataset but were used to invert the gravity data
50
Limitations of magnetic and gravity interpretation
Interpretation of the area is limited by a shortage of information on the nature and physical properties of the deeper
sedimentary sequence and the underlying basement rocks However using techniques such as cross-correlation of
gravity and pseudo-gravity data it is possible to try to differentiate between anomalies relating to basement and those
related to the sedimentary sequence
Gravity anomalies reflect changes within the sedimentary sequence as well as basement condition These
changes in density of sedimentary rocks produce gravity anomalies without a corresponding magnetic anomaly hence
the complementary nature of gravity and magnetic surveys The main use of magnetics is to determine depth to
magnetic basement and any intra-sedimentary volcanic rocks or intrusives whereas gravity provides much more
general information on the sedimentary sequence
Unfortunately interpretation of gravity anomalies is complicated since they can be due to a number of geological
features including
bull major basement faults
bull basement highs
bull igneous intrusions within the basement
bull sedimentary basins which may or may not be isostatically compensated
bull intra-sedimentary volcanics and associated plutonic centres
Two major problems affect the interpretation of both magnetic and gravity data
1 The inherent ambiguity of potential-field data There is no unique solution to any measured gravity or magnetic
anomaly and theoretically there will be an infinite number of source geometry and magnetizationdensity
combinations which will fit the observed data This means that any a priori information which helps to select a
suitable model is very useful
2 Measured anomalies are the summation of effects from different depths For example an observed gravity profile
may contain contributions from shallow sources (density variations within the sedimentary basin) intermediate
depth sources (density variations due to large igneous intrusions within the basement) and deep sources (crustal
thinning producing a mantle anomaly) Separation of these component responses is the regionalresidual problem
which we solve using spectral analysis and differential upward continuation-based separation filtering
Regional setting and interpretation overview
The area studied includes parts of BALFOUR DOWNS (SF51-9) RUDALL (SF51-10) ROBERTSON (SF51-13) GUNANYA
(SF51-14) COLLIER (SG50-4) BULLEN (SG51-1) TRAINOR (SG51-2) MADLEY (SG51-3) NABBERU (SG50-5)
STANLEY (SG51-6) and HERBERT (SG51-7) 1250 000 sheets Broadly the area lies between latitudes 22deg00rsquondash25deg30rsquoS
and longitudes 119deg30rsquondash123deg30rsquoE
51
Regional gravity
The AGSO regional gravity data (at nominal 11 km spacing) was gridded at a 4 km mesh spacing using a minimum-
curvature algorithm Bouguer gravity values in the area are negative reflecting mass deficiency at depth and range
from -84 mgals to -25 mgals
A Bouguer gravity colour image is shown as Figure 41 A residual grid was produced by removing a fifth-order
orthogonal polynomial from the Bouguer data but did not add to the interpretation
120deg 121deg 122deg 123deg
23deg
24deg
25deg
-25
-84
50 km
MKS46 180598
mgal
Figure 41 Regional Bouguer gravity (BMRAGSO data) gridded at 4 km
52
The data show a complex pattern of positive and negative anomalies with no clearly defined trends Correlations
with aeromagnetic data and known basin structures are poor A vague north-northwest linear trend appears to coincide
with the Marloo Fault (Figure 42) A prominent negative anomaly appears to coincide with the Blake Fold and Fault
Belt depocentre and continues as a narrower negative anomaly to the east until it widens out again near the edge of the
basin Elsewhere the gravity data show little correlation with known basin structures and it is likely that especially in
the north of the area gravity anomalies are due to density changes in the basement rather than changes in basement
topography
Production of wavelength-filtered residual gravity plots and vertical gradient plots showed very patchy aliased
data reflecting poor sampling in much of the area
Regional magnetics
The AGSO regional aeromagnetic data were gridded at a 400 m mesh spacing using a minimum-curvature algorithm
(Figure 43) Most of the data has a line spacing of 1600 m with small areas of 1 km spacing The quality of the data is
acceptable for regional interpretation but is not adequate for detailed analysis The accuracy of the flight path is rather
variable reflecting the vintage of the data and the noise envelope of the data is poor by modern standards Problems
were also encountered in joining different map sheets
The magnetic anomaly pattern over the south and west part of the area shows a strong high frequency signature
reflecting the presence of widespread basic sills and dykes Some of the major north-northeasterly trending dykes can
be traced over considerable distances
Discontinuous high-frequency anomalies extend as a northwest-trending zone through the centre of the area and
this zone includes a conspicuous circular magnetic anomaly which is probably a ring complex
The northern and eastern parts of the area are characterized by long-wavelength deep-seated basement magnetic
anomalies with 120deg and 150deg trends dominant The Marloo and Perentie Faults (Figure 42) appear as distinct linear
zones and offsets A prominent easterly trending negative anomaly in the northwest of the area appears to swing round
to the southeast and may separate different basement blocks One possible interpretation is that this very deep seated
anomaly separates areas of Archaean and Proterozoic basement
Regional geology
The regional geology is described in Williams (1992) The GSWA provided a digitized version of Plate 2 from this
Bulletin the structural interpretation map to use as an overlay (Figure 42)
53
Pp
Pp
PSd
PSd
PSd
PSd
PSd
PSo
PSt
PSt
PSf
PSf
PSf
PSb
PSb
PSb
PSsPSs
PSs
PSb
PSm
PSp
PSc
PSc
PSw
PSw
PSw
PSg
PSr
PSj
PSg
PM
Pk
PY
PY
PSd
L
L
L
L
L
L
L
LL
L
L
L
LL
L
LL
L L
LL
L L
L
L
L
L
L
L
L
LL
L
L
BLAKEDEPOCENTRE
MA
RLO
O
FAU
LT
PERENTIEFAULT
50 km
MKS39120598
120deg 121deg 122deg 123deg
25deg
24deg
23deg
Approximate boundaryof aeromagnetic interpretation
PML
PSgL
PSjL
PML
PSpL
PML
PML
PSfL
PSfL
PSpL
LPc
LPcLPcPSrL
LPA
Durba Sandstone
Woora Woora Formation
McFadden Formation
Tchukardine Formation
Boondawari Formation
Skates Hills Formation
Mundadjini Formation
Coondra Formation
Spearhole Formation
Watch Point Formation
Jilyili Formation
Brassey Range Formation
Glass Spring Formation
Paterson Formation
Yeneena Group
Karara Formation
Cornelia Formation
Kahrban Subgroup
Bangemall Group
Fault
Formation boundary
PSdL
PSoL
PSfL
PStL
PSbL
PSsL
PSmL
PScL
PSpL
PSwL
PSjL
PSrL
PSgL
Pp
PYL
PkL
LPc
LPA
PML
Savory Group Other Units
PYL
Figure 42 Regional geology and structure map (after Williams 1992)
54
120deg 121deg 122deg 123deg
23deg
24deg
25deg
5820
3750
MKS47 180598
nT
50 km
Figure 43 Regional aeromagnetic data total magnetic intensity (BMRAGSO data) gridded at 400 m
Analysis
3D analysis
3D Euler deconvolution was used as the primary depth-determination method The advantage of this approach is that
consistent solutions can be obtained over the entire area with minimal assumptions about source geometries Euler
deconvolution of gridded data is used for positional information and estimation of depth to top of source Euler
55
deconvolution yields a large number of depth solutions which have to be screened to reject spurious solutions Results
are plotted as circles in eight depth ranges with radius proportional to depth and colour coded
The 400 m total magnetic intensity grid was used for the analysis Horizontal gradients in x and y and the vertical
gradient were calculated 3D Euler deconvolution was tested on the 400 m gridded data using windows of 9 times 9 and
11 times 11 and 16 times 16 data points and structural indices 05 (fault) and 10 (sill or dyke) It was concluded that the
16 times 16 window produced the best results overall and final plots were produced for the 16 times 16 window and structural
index 05 (Fig 44) Results were very good over the northern and central parts of the area showing magnetic sources
Figure 44 Depth to magnetic source 3D Euler deconvolution 16 times 16 window of 400 m gridded data structural index 05
56
at several different levels Unfortunately in the extreme south of the area shallow intrasedimentary magnetic sources
(sills and dykes) dominated the inversion and the results contained few basement solutions
In order to reduce these problems the 400 m gridded data were filtered using a separation filter based on
interpretation of the log-energy spectrum The 3D Euler method was run on the filtered data in order to generate more
basement-depth solutions Results for the deep-separation filter data were gridded and presented as a colour image in
Cowan (1995) Attempts to grid the Euler output were unsatisfactory and it is considered safer to interpret the 3D
Euler depth plots The 3D Euler depth results from the separation-filter run should be analysed with care as perfect
separation of the basement can never be achieved and there will always be some contamination from sources at
different levels
The results of original total magnetic intensity 3D Euler depth estimation for structural index 05 using a 16 point
window have been plotted at 1500 000 scale (not included in this publication but available in Cowan (1995) from the
GSWA Library as S10331) and as reduced A4 colour circle plots (Figure 44)
The results of deep-basement 3D Euler depth estimation for structural index 05 using a 16 point window have
been plotted as a colour image at 1500 000 scale and as an A4 image (not included in this publication)
2D analysis
Two equispaced profiles were interpolated with a 50 m station interval from the AGSO-located data profiles for the
BULLEN 1250 000 sheet The interpolated profiles were analysed using 2D Euler deconvolution and Werner
deconvolution Results are included in Cowan (1995) and show the use of these methods for more detailed analysis
Filtered data
In order to reconcile 3D Euler results from shallow basement and intrasedimentary magnetic sources we produced
several separation-filtered maps and images We found the shallow-layer double-separation filter (Figure 45) to be
very effective for shallow sources and the deep-layer standard-separation filter (Figure 46) for the basement layer
Gravity and magnetic data correlation
Both lsquoreduced to the polersquo (RTP) magnetics (Figure 47) and pseudo-gravity data (Figure 48) were produced as part of
the reconciliation of gravity and magnetic signatures In both cases the filtering operations assumed magnetization by
induction in the present Earths field The RTP data are fairly similar to the total magnetic intensity The pseudo-
57
gravity data are dominated by a northwest-trending strong positive anomaly and there is little correlation with the
Bouguer gravity data
The poor magneticgravity correlation is confirmed by cross-correlation of the RTP magnetics and the gravity
gradient The correlation plot in Figure 49 shows little coherent response with numerous zones of positive and
negative correlation
Figure 45 Regional aeromagnetic data shallow layer separation filter (BMRAGSO data) gridded at 400 m
Results
In the north and east of the area on the Wells Foreland Sub-basin trend (refer to Figure 1 main text) we see a range
of quite deep 3D Euler depths and several trend directions with north-northwesterly dominant There are relatively few
shallow intrasedimentary solutions in this zone
The second area of deep 3D Euler solutions lies over the Blake depocentre (Figure 43) with several trend
directions
Elsewhere the 3D Euler results are dominated by shallow intrasedimentary depth solutions reflecting mainly the
dolerite sills dykes and the ring complex However where we do see basement-related solutions in the south and
west of the area they appear to be shallower than those noted for the Wells Foreland Sub-basin and the Blake
depocentre
58
Figure 46 Regional aeromagnetic data deep-layer separation filter (BMRAGSO data) gridded at 400 m
Figure 48 Regional aeromagnetic data pseudo-gravity transform (BMRAGSO data) gridded at 400 m
Figure 47 Regional aeromagnetic data reduced-to-pole (BMRAGSO data) gridded at 400 m
Figure 49 Regional aeromagnetic and gravity data gravitymagnetic correlation using RTP magnetics and gravity gradient (BMRAGSO data) gridded at 4 km
59
This subdivision of the area into two zones of deep solutions is consistent with interpreted depocentres
However the interference between sources at different levels and the complexity of the magnetic response of the
basement rocks precludes more refined interpretation at this stage
The area of deep 3D Euler solutions over the Blake depocentre correlates with the pronounced negative gravity
anomaly discussed in the gravity interpretation section Using a density contrast of -015 gcc the negative gravity
anomaly could indicate up to 6ndash8 km of low-density sedimentary rocks depending on assumptions about the regional
field
The area of deep 3D Euler solutions over the Wells Foreland Sub-basin has a complex gravity expression and no
clear basin structure emerges from inversion of these data As noted previously it is likely that observed gravity
anomalies reflect contrasts in basement density rather than basement topography
Separation filtering applied to the magnetic data helps to enhance the intrasedimentary magnetic signature and to
give a better impression of the basement magnetic signature even though separation of the basement response is not
perfect
Conclusions
Quantitative aeromagnetic interpretation using 3D Euler deconvolution supported by wavenumber filtering and image
processing has been successful in providing structural trend and depth information for the Savory Sub-basin
Quantitative magnetic interpretation has revealed two zones of relatively deep magnetic basement beneath the
Wells Foreland Sub-basin and the Blake depocentre
This analysis of the magnetic data supports interpreted depocentres but the complexity of the basement magnetic
signature and interference from sources at different depths precludes further refinement to a map of basement
topography
Regional gravity proved to be very useful in understanding the regional setting of the area and in providing
support for aspects of the interpretation The gravity data support the interpretation of the Blake depocentre
suggesting up to 6ndash8 km of low-density sedimentary rocks
The deep structure of the Savory Sub-basin area is obviously complex with different areas underlain by
Archaean and Proterozoic basement and with the Capricorn suture occurring in the centre of the area
60
Recommendations
The quantitative magnetic interpretation needs to be reconciled with geological models available for the area
In particular the zones tentatively identified as areas with thick sedimentary rocks the Wells Foreland Sub-
basin and the Blake depocentre need to be investigated
Cross sections should be prepared across the basin for joint magneticgravity modelling especially for the Blake
depocentre It is important to be able to explain the strong negative gravity anomaly in this area
In view of the effects of basement density contrasts on the gravity field for the northern part of the area we think
that additional gravity interpretation and acquisition of new gravity data may not be justified as they will not
contribute significantly to understanding basin evolution and structure
It is recommended that GSWA try to get access to company confidential high-resolution aeromagnetic data
rather than flying new surveys The GSWA might offer to fund flying of new infill areas as a bargaining point
References
The original text of this report by Cowan (1995) and 1500 000 scale maps are filed in the GSWA Library under
S10331
COWAN D 1995 Savory Basin quantitative magnetic interpretation Western Australia Geological Survey S-series
S10331 (unpublished)
VACQUIER V STEENLAND N C HENDERSON R G and ZIETZ I 1951 Interpretation of aeromagnetic
maps The Geological Society of America Memoir 47 151p
WILLIAMS I R 1992 Geology of the Savory Basin Western Australia Western Australia Geological Survey
Bulletin 141 115p
61
Appendix 5
Geochemistry
MKS38 250398
Saturate FractionC12+ GLC
1217
Pr18
Ph
22
31CSR WELL-13 315m Cuttings
Figure 51 Canning Stock Route Well 13 gas chromatograph of extract of auger drill sample
12
17
18
22
31
Pr Ph
LDDH 1 6623m CoreSaturate FractionC12+ GLC
MKS35 240398
Figure 52 Gas chromatograph of extract from core sample at 6623 m LDDH1
62
Table 51 Canning Stock Route Well 13 auger drill samples
GSWA sample Drill depth (m)(a) Comments
135601 150 At watertable 135602 203 (all samples consist 135603 310 of sand mud and water) 135604 315 At total depth
NOTE (a) Datum for drill depth is the top of sediment fill in the well which is 155 m below ground level (ie the total depth of 315 m is 47 m below ground level)
Table 52 Canning Stock Route Well 13 gas chromatography data for 315 m depth sediment sample
Parameter Value
Weight of rock extracted (grams) 945 Total extract (ppm) 519 n-Alkane distribution n-C12 07 n-C13 23 n-C14 26 n-C15 22 n-C16 19 n-C17 14 i-C19 23 n-C18 14 i-C20 08 n-C19 11 n-C20 16 n-C21 25 n-C22 29 n-C23 70 n-C24 42 n-C25 95 n-C26 43 n-C27 83 n-C28 38 n-C29 87 n-C30 31 n-C31 273 Alkane compositional data Pristane phytane ratio 279 Pristane n-C17 ratio 161 Phytane n-C18 ratio 059 CPI (1)(a) 284 CPI (2) 209 (C21 + C22) (C28 + C29) 043
NOTE (a) CPI= Carbon preference index
63
Table 53 LDDH1 extract liquid chromatography data for 6623 m concentration
Rock extracted Total extract (grams) (ppm)
702 313
NOTE ppm= parts per million
Table 54 LDDH1 saturate gas chromatography data of core for 6623 m alkane composition
Pristane Pristane Phytane (a) CPI (1) CPI (2) (C21+C22) Phytane n-C17 n-C18 (C28+C29)
103 026 024 103 102 325
NOTE (a)CPI = carbon preference index
Table 55 LDDH1 saturate gas chromatography data of core for 6623 m n-alkane distributions
Parameter Value
n-C12 17 n-C13 38 n-C14 55 n-C15 60 n-C16 65 n-C17 74 i-C19 19 n-C18 78 i-C20 19 n-C19 80 n-C20 79 n-C21 71 n-C22 64 n-C23 57 n-C25 43 n-C24 38 n-C27 31 n-C28 23 n-C29 19 n-C30 12 n-C31 10
64
Appendix 6
Table 61 Summary of data from Trainor waterbores (TWB) and Bullen waterbores (BWB)
Well AMG Elevation TD Status(b) Completion details Water Salinity Water level Flow rate Depth to consolidated AGD84 GL (m) (m) struck mgl(c) (m) (LHr) lithology aquifer(e) Z51(a) Interval (m) (100 mm PVC) (m) (mgl)(d)
TWB 1 473660E 453 122 comp 0ndash75 plain 63 7 300 24 2 880 12 m 7287404N 75ndash93 slotted (9 260) McFadden Fm 93ndash99 plain TWB 2 472 977E 475 23 abd nil 15 m 7285877N Skates Hills Fm dry TWB 3 473259E 475 50 abd nil 7 m 7285849N Skates Hills Fm dry TWB 4 463225 E 445 50 comp 0ndash22 plain 35 7 200 55 3 600 0 m 7286143N 22ndash34 slotted (8 140) Tertiary sand and gravel 23ndash60 plain TWB 5 463095E 445 31 comp 0ndash19 plain 13 26 000 655 3 600 Tertiary sand and gravel 7277721N 19ndash25 slotted (36 700) 25ndash31 plain TWB 6 457013E 455 50 comp 0ndash42 plain 38 920 119 600 0 m 7274352N 42ndash48 slotted (1 030) Cornelia Fm ss TWB 7 453739E 475 26 susp 0ndash2 plain 11 9 300 48 4 500 0 m 7263891N (10 500) Tertiary sand TWB 8 433893E 535 60 susp 0ndash2 plain 47 8 500 gt46 1 200 0 m 7245991N (10 900) Tertiary sand and Brassey Range Fm ss TWB 9 437219E 505 51 comp 0ndash47 plain 45 1 000 58 600 1 m 7235905N 47ndash51 slotted (990) Brassey Range Fm ss TWB 10 434927E 495 32 susp 0ndash2 plain 235 450 120 0 m 7225875N (500) Dolerite
65
BWB 1 287337E 580 122 abd Nil 1 m 7245861N Jilyili Fm dry BWB 2 288346E 545 50 comp 0ndash26 plain 15 630 3 29 000 0 m 7240423N 26ndash38 slotted (730) Tertiary sand and gravel 38ndash50 plain BWB 3 305637E 545 50 abd 19 8 800 43 7 200 0 m 7240423N (10 550) Tertiary ss BWB 4 320167E 515 445 comp 0ndash20 plain 9 980 445 24 000 0 m 7248097N 20ndash32 slotted (1 190) Tertiary ss 32ndash44 plain BWB 5 353393E 545 20 susp 0ndash2 plain 45 (970) 1 m 7238934N Basalt
NOTES (a) GPS accuracy ~ 150 m (b) Comp = completed abd = abandoned susp = suspended (c) Salinity from conductivity (d) Analysis total dissolved solids (e) Fm = Formation ss = sandstone
33
bull Additional data from mineral and petroleum exploration bores may become available and
analysis of samples from these wells should be undertaken and interpreted in the context of
their relevance to the Officer Basin
bull Stratigraphic coring in the Blake Fault and Fold Belt and in the Wells Foreland Sub-basin (Fig
1) targeting source rocks is considered essential to the continuing evaluation of the
hydrocarbon prospectivity of the Savory Sub-basin
bull Correlations using at least outcrop well and potential-field data should be prepared to link the
sub-basin with the better known parts of the Officer Basin to the east
bull Remapping is required to clarify boundary positions within the Cornelia Formation this may
resolve some of the current problems of the relationship between this unit and the rest of the
Savory Sub-basin
bull Further work is required to explain the Early Cambrian or Sturtian ages interpreted for the
Cornelia Formation from sedimentary zircon UndashPb dating in drillhole Trainor 1 The
determination of the age of the organically rich but overmature claystones in this well is
critical to assessing the hydrocarbon potential of the region
bull The thin dark mudstones intersected by Akubra 1 in the Mundadjini Formation warrant
geochemical analysis Analyses of the oil shows in Mundadjini 1 and Boondawari 1 are
currently being undertaken by Amadeus Petroleum
bull Geochemical analysis of hydrocarbons in the Bangemall Basin drillhole OD23 has been
performed by Jubilee Gold and the results will be reviewed when they are submitted to
GSWA The possibility of source rocks within the Bangemall Basin charging traps within the
Bangemall Basin and the overlying Savory Sub-basin requires further investigation
Conclusions
The Savory Sub-basin is a frontier region with only three recently drilled petroleum exploration
wells and no seismic data Based on existing geological and geophysical data it is considered too
early to draw conclusions about the hydrocarbon prospectivity of the sub-basin at this stage and
there are several reasons why the area warrants further investigation
34
1 Thick accumulations of sedimentary rocks are present (up to 8 km thickness inferred) which
may contain source reservoir and sealing strata
2 Minor oil shows occur in Mundadjini 1 and Boondawari 1 and bitumen is present in mineral
exploration drillhole LDDH1 suggesting that hydrocarbons have migrated within the
Neoproterozoic sequence of the Savory Sub-basin Oil and bitumen are present in mineral
exploration drillhole OD23 in the Bangemall Basin immediately to the south of the Savory
Sub-basin and it is possible that source rocks from the Bangemall Basin could charge traps in
the overlying Savory Sub-basin
3 The age of sedimentary rocks in the sub-basin is still poorly constrained but some of the
Neoproterozoic sedimentary rocks located on GUNANYA and TRAINOR are within the
hydrocarbon-generation window It is possible that a significant thickness of Phanerozoic
sedimentary rocks may also be present
4 Friable sandstones with visible porosity outcrop extensively suggesting numerous potential
reservoirs
5 Significant but not intense faulting and folding has been mapped implying large structural
traps may be present
6 Evaporitic sedimentary rocks occur in several formations and may provide good source rocks
and excellent seals
35
References
APAK S N and CARLSEN G M 1997 A compilation and review of data pertaining to the
hydrocarbon prospectivity of the Canning Basin Western Australia Geological Survey
Record 199610 103p
BAGAS L GREY K and WILLIAMS I R 1995 Reappraisal of the Paterson Orogen and
Savory Basin Western Australia Geological Survey Annual Review 1994ndash95 p 55ndash63
BUSBRIDGE M 1994 Lake Disappointment Exploration Licence 451064 Third Annual
Report Lake Disappointment Diamond Drill Hole LDDH1 Normandy Exploration Limited
Western Australia Geological Survey M-series Item 7567 A41358 (unpublished)
CARLSEN G M and SHEVCHENKO S I 1997 Petroleum exploration in Proterozoic basins
using potential fields data and stratigraphic coring Australian Society of Exploration
Geophysicists 12th Geophysical Conference Handbook Sydney 1997 Preview no 66 p 83
(abstract only)
COWAN D 1995 Savory Basin quantitative magnetic interpretation Western Australia
Geological Survey S-series S10331 (unpublished)
DAISHSAT PTY LTD 1995 Operational and processing report Savory Basin gravity survey
Western Australia Geological Survey S-series S10332 (unpublished)
GARD E and GARD R 1990 Canning Stock Route a travellerrsquos guide for a journey through
history Perth Western Australia Western Desert Guides 448p
GEOLOGICAL SURVEY OF WESTERN AUSTRALIA 1996a Savory Basin first vertical
derivative of Bouguer gravity image 1250 000 Western Australia Geological Survey
GEOLOGICAL SURVEY OF WESTERN AUSTRALIA 1996b Savory Basin Bouguer gravity
image 1250 000 Western Australia Geological Survey
GHORI K A R in prep Petroleum source rock potential and thermal history Officer Basin
Western Australia Western Australia Geological Survey Record
36
GREY K 1995a Savory Basin drillhole BWB 1 (Bullen waterbore) palynology and thermal
maturation GSWA Palaeontology Report no 199512 (unpublished)
GREY K 1995b Savory Basin drillholes TWB 1 2 6 9 (Trainor waterbores) palynology and
thermal maturation GSWA Palaeontology Report no 199520 (unpublished)
GREY K 1995c Palynology of Normandy-Poseidon Lake Disappointment-1 corehole
Tarcunyah Group Paterson Orogen GSWA Palaeontology Report no 199521 (unpublished)
GREY K 1995d Savory Basin drillhole Trainor 1 (Trainor diamond drilling) palynology and
thermal maturity GSWA Palaeontology Report no 199524 (unpublished)
GREY K 1995e Savory Basin drillhole Trainor 1 (Trainor diamond drilling) Additional
Preparation of two samples GSWA Palaeontology Report no 199528 (unpublished)
GREY K 1995f Neoproterozoic stromatolites from the Skates Hills Formation Savory Basin
Western Australia and a review of the distribution of Acaciella australica Australian Journal
of Earth Sciences v 42 p 123ndash132
GREY K 1996a Savory Basin drillhole Trainor 1 (Trainor diamond drilling) Additional
samples palynology and thermal maturation GSWA Palaeontology Report no 199615
(unpublished)
GREY K 1996b Preliminary stromatolite correlations for the Neoproterozoic of the Officer
Basin and a review of Australia-wide correlations GSWA Palaeontology Report no 199615
(unpublished)
GREY K and COTTER K L 1996 Palynology in the search for Proterozoic hydrocarbons
Western Australia Geological Survey Annual Review for 1995ndash96 p 70ndash80
GREY K and STEVENS M K 1997 Neoproterozoic palynomorphs of the Savory Sub-basin
Western Australia and their relevance to petroleum exploration Western Australia
Geological Survey Annual Review for 1996ndash97 p 49ndash54
HUBBARD R J PAPE J and ROBERTS D G 1985 Depositional sequence mapping as a
technique to establish tectonic and stratigraphic framework and evaluate hydrocarbon
potential on a passive continental margin in Seismic stratigraphy II an integrated approach
37
edited by O R BERG and D G WOOLVERTON American Association of Petroleum
Geologists Memoir 39 p 79ndash91
LIBBY WG 1995 A petrological report on six samples of bore cuttings from the Savory Basin
Western Australia Western Australia Geological Survey S-series S31307 (unpublished)
MORTON JGG and DREXEL JF 1997 The petroleum geology of South Australia Vol 3
Officer Basin South Australia Department of Mines and Energy Resources Report Book
9719
MUHLING P C and BRAKEL A T 1985 Geology of the Bangemall Group mdash the evolution
of an intracratonic Proterozoic basin Western Australia Geological Survey Bulletin 128
219p
MYERS J S 1990 Precambrian tectonic evolution of part of Gondwana southwestern Australia
Geology v18 p 537ndash540
NELSON D R 1997 Compilation of SHRIMP UndashPb zircon data Western Australia Geological
Survey Record 19972 196p
PAYTON C E 1977 Seismic stratigraphy mdash applications to hydrocarbon exploration
American Association of Petroleum Geologists Memoir 26 516p
PERINCEK D 1996a The age of NeoproterozoicndashPalaeozoic sediments within the Officer Basin
of the Centralian Super-basin can be constrained by major sequence-bounding unconformities
APPEA Journal v 36 pt 1 p 350ndash368
PERINCEK D 1996b The stratigraphic and structural development of the Officer Basin
Western Australia a review Western Australia Geological Survey Annual Review 1995ndash
1996 p 135ndash148
PERINCEK D 1998 A compilation and review of data pertaining to the hydrocarbon
prospectivity of the Officer Basin Western Australia Geological Survey Record 19976
POSAMENTIER H W JERSEY M T and VAIL P R 1988 Eustatic controls on clastic
deposition 1 mdash Conceptual framework in Sea-level changes an integrated approach edited by
C K WILGUS B S HASTINGS C G St C KENDALL H W POSAMENTIER
38
C A ROSS and J C VAN WAGONER Society of Economic Paleontologists and
Mineralogists Special Publication no 42
STEVENS M K and ADAMIDES N G in prep GSWA Trainor 1 well completion report
Savory Sub-basin Officer Basin Western Australia with notes on petroleum and mineral
potential Western Australia Geological Survey Record 199612
STEVENS M K and GREY K 1997 Skates Hills Formation and Tarcunyah Group Officer
Basin mdash carbonate cycles stratigraphic position and hydrocarbon prospectivity Western
Australia Geological Survey Annual Review for 1996ndash97 p 55ndash60
SUMMONS RE and POWELL C McA 1991 Petroleum source rocks of the Amadeus Basin
in Geological and geophysical studies in the Amadeus Basin central Australia edited by R J
KORSCH and JM KENNARD Australia BMR Geology and Geophysics Bulletin 236
TRAVERSE A 1988 Palaeopalynology Boston Unwin Hyman 600p
VAIL P R MITCHUM R M Jr TODD R G WIDMIER J M THOMPSON S III
SANGREE J B BUBB J N and HATLELID W G 1977 Seismic stratigraphy and
global changes of sea level in Seismic stratigraphy mdash applications to hydrocarbon
exploration edited by C E PAYTON American Association of Petroleum Geologists
Memoir 26 516p
WALTER M R and GORTER J 1994 The Neoproterozoic Centralian Superbasin in Western
Australia the Savory and Officer Basins in The sedimentary basins of Western Australia
edited by P G PURCELL and R R PURCELL Petroleum Exploration Society of Australia
Symposium Perth WA 1994 Proceedings p851ndash864
WALTER M R GREY K WILLIAMS I R and CALVER C R 1994 Stratigraphy of the
Neoproterozoic to early Palaeozoic Savory Basin and correlation with the Amadeus and
Officer Basins Australian Journal of Earth Sciences v 41 p 533ndash546
WALTER M R VEEVERS J J CALVER C R and GREY K 1995 Neoproterozoic
stratigraphy of the Centralian Superbasin Australia Precambrian Research v 73 p 173ndash195
WILLIAMS I R 1992 Geology of the Savory Basin Western Australia Western Australia
Geological Survey Bulletin 141 115p
39
WILLIAMS I R 1995a Bullen WA (2nd Edition) Western Australia Geological Survey
1250 000 Geological Series Explanatory Notes 23p
WILLIAMS I R 1995b Trainor WA (2nd Edition) Western Australia Geological Survey
1250 000 Geological Series Explanatory Notes 31p
WILLIAMS I R and TYLER I M 1991 Robertson WA (2nd edition) Western Australia
Geological Survey 1250 000 Geological Series Explanatory Notes 36p
40
41
Appendix 1
Bibliography
Reports which are relevant to this investigation but which are not specifically cited are listed
below
BAILLIE P W POWELL C McA LI Z X and RYALL A M 1994 The tectonic
framework of Western Australiarsquos Neoproterozoic to recent sedimentary basins in The
sedimentary basins of Western Australia edited by P G PURCELL and R R PURCELL
Petroleum Exploration Society of Australia Symposium Perth WA 1994 Proceedings p
45ndash62
BRADSHAW M T BRADSHAW J MURRAY A P NEEDHAM D J SPENCER L
SUMMONS R E WILMOT J and WINN S 1994 Petroleum systems in West Australian
basins in The sedimentary basins of Western Australia edited by P G PURCELL and R R
PURCELL Petroleum Exploration Society of Australia Symposium Perth WA 1994
Proceedings p 93ndash118
CLARKE G L 1991 Proterozoic tectonic reworking in the Rudall Complex Western Australia
Australian Journal of Earth Science v38 p 31ndash44
COCKBAIN A E and HOCKING R M 1990 Phanerozoic in Geology and mineral resources
of Western Australia Western Australia Geological Survey Memoir 3 p 750ndash755
ETHERIDGE M and WALL V 1994 Tectonic and structural evolution of the Australian
Proterozoic 12th Australian Geological Convention Geological Society of Australia
Abstracts no 37 p 102ndash103
GOODE A D T 1981 Proterozoic geology of Western Australia in Precambrian of the
Southern Hemisphere Developments in Precambrian geology 2 edited by I R HUNTER
Amsterdam Elsevier p 105ndash203
GREY K and JACKSON M J 1983 A re-assessment of stromatolite evidence for the
correlation of the Late Proterozoic Neale and Ilma Beds Officer Basin Western Australia
Australia BMR Journal of Australian Geology and Geophysics v 8 p 359
42
HICKMAN A H WILLIAMS I R and BAGAS L 1994 Proterozoic geology and
mineralization of the TelferndashRudall region Paterson Orogen Geological Society of Australia
(WA Division) Excursion Guidebook no 5 56p
HOCKING R M MORY A J and WILLIAMS I R 1994 An atlas of Neoproterozoic and
Phanerozoic basins of Western Australia in The sedimentary basins of Western Australia
edited by P G PURCELL and R R PURCELL Petroleum Exploration Society of Australia
Symposium Perth WA 1994 Proceedings p 21ndash 44
JACKSON P R 1966 Geology and review of exploration Officer Basin Western Australia
Hunt Oil Company Western Australia Geological Survey S-series S26 (unpublished)
JACKSON M J 1971 Notes on a geological reconnaissance of the Officer Basin Western
Australia Australia BMR Geology and Geophysics Record 19715 30p
JACKSON M J and van de GRAAFF W J E 1981 Geology of the Officer Basin Western
Australia Australia BMR Geology and Geophysics Bulletin 206 102 p
LOWRY D C JACKSON M J van de GRAAFF W J E and KENNEWELL P J 1971
Preliminary result of geological mapping in the Officer Basin Western Australia Western
Australia Geological Survey Annual Report for 1971 p 50ndash56
MYERS J S 1990 Precambrian in Geology and mineral resources of Western Australia
Western Australia Geological Survey Memoir 3 p 737ndash750
MYERS J S SHAW R D and TYLER I M 1994 Proterozoic tectonic evolution of
Australia 12th Australian Geological Convention Geological Society of Australia Abstracts
no 37 p 312
NEDIN C and JENKINS R J F 1991 Re-evaluation of unconformities separating the
lsquoEdiacaranrsquo and Cambrian systems South Australia Palaios v 6 p 102ndash108
PHILLIPS B J JAMES A W and PHILIP G M 1985 The geology and hydrocarbon
potential of the north-western Officer Basin APEA Journal 25 (1) p 52ndash61
POWELL C McA LI Z X McELHINNY M W MEERT J G and PARK J K 1993
Paleomagnetic constraints on timing of the Neoproterozoic breakup of Rodinia and Cambrian
formation of Gondwana Geology v 21 p 889ndash892
43
POWELL C McA PREISS W V GATEHOUSE C G KRAPEZ B and LI Z X 1994
South Australian record of a Rodinian epicontinental basin and its mid-Neoproterozoic
breakup to form the Palaeo-Pacific Ocean Tectonophysics v 237 no 3ndash4 p 113ndash140
PREISS W V 1976 Proterozoic stromatolites from the Nabberu and Officer Basins Western
Australia and their biostratigraphic significance South Australia Geological Survey Report
of Investigations no 47 p 1ndash51
TOWNSON W G 1985 The subsurface geology of the western Officer Basin mdash results of
Shellrsquos 1980ndash1984 petroleum exploration campaign APEA Journal v 25 (1) p 34ndash51
WATTS K J 1982 The geology of the Townsend Quartzite Upper Proterozoic shallow water
deposit of the Northern Officer Basin Western Australia Perth University of Western
Australia BSc honours thesis (unpublished)
WELLS A T and KENNEWELL P J 1974 Evaporite exploration in the Officer Basin
Western Australia at the Madley Diapirs Australia BMR Record 1974194 (unpublished)
WILLIAMS I R and MYERS J S 1990 Paterson Orogen in Geology and mineral resources
of Western Australia Western Australia Geological Survey Memoir 3 p 274ndash286
WILLIAMS I R 1990 Savory Basin in Geology and mineral resources of Western Australia
Western Australia Geological Survey Memoir 3 p 329ndash334
WILLIAMS I R 1994 The Neoproterozoic Savory Basin Western Australia in The
sedimentary basins of Western Australia edited by P G PURCELL and R R PURCELL
Petroleum Exploration Society of Australia Symposium Perth WA 1994 Proceedings p
841ndash850
WILSON R B 1967 Woolnough Hills and Madley diapiric structures Gibson Desert WA
APEA Journal v 7 p 94ndash102
44
Appendix 2
Meteorological data (from Bureau of Meteorology Perth 1994)
Table 21 Wiluna rainfall (mm)
Year Jan Feb Mar Apr May Jun Jul Aug Sept Oct Nov Dec
1975 0 45 446 309 306 59 276 4 34 886 638 164 1976 16 154 12 138 53 16 34 62 12 238 0 2 1977 44 0 66 74 68 95 24 363 1 58 12 727 1978 234 522 94 16 0 96 367 24 16 353 185 45 1979 19 173 122 88 91 4 0 246 58 0 169 114 1980 148 764 68 1081 259 626 629 06 56 02 174 0 1981 123 476 192 32 196 118 44 74 14 0 28 312 1982 374 705 206 244 1079 92 02 143 368 526 368 118 1983 1 112 928 248 0 212 56 32 5 1 42 496 1984 149 7 342 84 836 0 348 132 224 04 16 172 1985 596 483 0 166 556 0 514 56 0 0 4 0 1986 0 154 35 0 0 1085 23 01 239 137 0 04 1987 1204 119 19 89 17 575 154 126 07 1 0 398 1988 46 202 164 13 388 0 202 104 0 0 224 1309 1989 207 234 26 703 278 536 57 0 01 0 144 02 1990 1035 23 281 46 126 53 94 218 44 9 42 0 1991 48 0 41 45 0 472 297 12 0 1 0 7 1992 112 96 1025 1227 323 65 04 174 0 132 48 4 1993 0 697 0 202 445 0 12 306 18 05 14 33 Mean 25 35 22 27 27 25 18 12 6 13 13 21
JAN FEB MAR APR MAY JUN JUL AUG SEP OCT NOV DEC0
10
20
30
40
Mea
n R
ain
fall
(mm
)
Month
Mean monthly rainfall in Wiluna
MKS41 140498
45
Table 22 Wiluna minimum temperature (degC)
Year Jan Feb Mar Apr May Jun Jul Aug Sept Oct Nov Dec
1975 ndash 23 203 15 94 63 71 62 103 124 169 205 1976 242 229 194 15 10 63 59 73 95 143 16 228 1977 243 25 197 148 96 95 56 86 102 ndash 188 23 1978 241 232 203 18 102 64 76 8 9 152 19 205 1979 255 226 216 167 83 6 59 79 97 145 198 223 1980 255 226 231 155 134 83 68 75 121 108 193 223 1981 245 216 19 182 119 6 54 78 138 159 163 218 1982 232 224 177 16 ndash ndash 37 111 112 164 209 225 1983 235 24 197 147 112 88 39 88 121 162 189 219 1984 241 243 191 156 ndash 72 66 7 95 161 182 211 1985 244 231 ndash 159 98 65 71 73 117 147 205 ndash 1986 ndash 229 226 155 93 96 43 49 10 122 ndash 219 1987 ndash 217 183 175 85 77 68 68 112 ndash ndash 221 1988 238 214 209 178 111 ndash ndash 86 104 157 171 195 1989 ndash 237 199 165 107 67 44 61 107 131 187 ndash 1990 232 ndash 211 155 118 62 57 87 102 149 195 22 1991 26 256 217 168 122 101 78 ndash 113 18 168 219 1992 227 227 214 169 102 98 59 69 ndash 125 159 196 1993 241 218 196 171 103 ndash 49 68 88 128 192 211 Mean 24 23 20 16 10 8 6 8 11 14 18 21
NOTE Dashes indicate data unavailable
JAN FEB MAR APR MAY JUN JUL AUG SEP OCT NOV DEC0
10
20
30
40
Month
MKS43 140498
50
Mean monthly minimum temperatures at Wiluna
Mea
n T
emp
erat
ure
(degC
)
46
Table 23 Wiluna maximum temperature (degC)
Year Jan Feb Mar Apr May Jun Jul Aug Sept Oct Nov Dec
1975 ndash 349 326 281 247 201 197 212 256 248 31 344 1976 374 369 346 297 248 206 208 225 265 287 313 388 1977 397 392 352 296 234 212 222 244 ndash 308 337 383 1978 378 345 346 316 242 195 176 205 231 295 334 356 1979 403 36 364 295 ndash ndash ndash 193 242 318 359 373 1980 392 342 377 275 24 176 179 233 292 288 349 391 1981 385 346 337 342 242 178 201 224 30 326 326 369 1982 372 359 315 307 ndash ndash 196 253 252 305 353 379 1983 381 389 327 272 263 222 187 248 287 321 336 366 1984 378 393 322 299 226 215 178 214 234 ndash 336 364 1985 40 366 ndash 294 224 216 205 212 284 307 355 ndash 1986 ndash 383 372 307 ndash 193 166 196 261 277 ndash 382 1987 ndash 339 328 305 21 202 214 218 275 ndash ndash 374 1988 388 365 353 301 23 ndash ndash 228 283 334 31 33 1989 ndash 375 339 285 238 179 181 219 275 298 336 ndash 1990 368 ndash 36 309 268 19 188 205 274 309 373 393 1991 414 416 363 315 268 206 21 ndash 279 338 332 368 1992 363 383 336 263 213 178 213 197 ndash 285 313 359 1993 396 357 344 301 221 ndash 197 215 253 294 347 362 Mean 39 37 34 30 24 20 20 22 27 30 34 37 NOTE Dashes indicate data unavailable
JAN FEB MAR APR MAY JUN JUL AUG SEP OCT NOV DEC0
10
20
30
40
Month
MKS42 140498
50
Mean monthly maximum temperatures at Wiluna
Mea
n T
emp
erat
ure
(degC
)
47
Appendix 3
Table 31 Summary of palynological results
Drillhole Depth (m) F no(a) GSWA no Lithology Formation Assemblage TAI(b)
BWB 1 74ndash75 F49668 135741 dark-grey siltstone basalt Jilyilli gt5 BWB 1 98ndash100 F49669 135742 dark-grey siltstone basalt Jilyilli gt5 BWB 1 121ndash122 F49670 135743 dark-grey siltstone basalt Jilyilli gt5 TWB 1 86ndash87 F49671 135631 dark-grey siltstone McFadden 3+ TWB 1 104ndash105 F49672 135632 dark-grey siltstone Cornelia 3+ TWB 1 121ndash122 F49673 135633 dark-grey siltstone Cornelia 4 TWB 2 14ndash15 F49674 135634 dark-grey siltstone Skates Hills 3+ TWB 6 49ndash50 F49675 135675 dark-grey siltstone Cornelia 1 3+ TWB 9 49ndash51 F49676 135704 dark-grey siltstone Brassey Range 1 3+ Trainor 1 37497- F49733 138939 black mudstone with Cornelia 5 37509 light-grey siltstone Trainor 1 3809 F49734 138940 dark-grey and black Cornelia 4- laminated mudstone Trainor 1 4170 F49735 138941 black unlaminated mudstone Cornelia 4- Trainor 1 4950 F49851 139501 dark-grey indurated siltstone Cornelia 5 Trainor 1 6032 F49852 139502 dark- and light-grey Cornelia 5 indurated siltstone Trainor 1 6434 F49853 139503 greenish indurated finely Cornelia 5 laminated siltstone LDDH 1 270 F49678 138934 dark-grey siltstone interbeds Waters 1 3+ in enterolithic evaporite Tarcunyah Gp LDDH 1 277 F49679 138935 dark-grey siltstone in cavity Waters 1 3+ in enterolithic evaporite Tarcunyah Gp
NOTES (a) GSWA Fossil Catalogue number (b) TAI = Thermal Alteration Index of Traverse (1988 plate 1)
48
Appendix 4
Savory Sub-basin quantitative magnetic and gravity interpretation (extracted from Cowan 1995)
Summary
A program of quantitative aeromagnetic interpretation has been completed on BMRAGSO data from the Savory Sub-
basin Western Australia Quantitative aeromagnetic interpretation utilized the 3D Euler deconvolution method
supported by wavenumber filtering and image processing The results have provided useful information on structural
trends and depth to magnetic sources in a structurally complex area Depth to magnetic source analysis has provided
information on intra-sedimentary magnetic sources as well as basement rocks
The results of the interpretation support previously identified depocentres However the presence of magnetic
sources at several levels makes it very difficult to produce a reliable magnetic basement depth contour map It is
considered more productive to work with the 3D Euler colour circle plots and images rather than trying to contour the
results It would be necessary to carry out a full-scale interpretation of the BMRAGSO profile data to improve on the
3D Euler results The regional gravity was found to be useful in interpreting the regional setting of the area although
the very wide data spacing limits quantitative use of the data The gravity data show quite a complex picture with
limited consistent correlation between gravity features and basin structures This suggests that gravity anomalies
reflect changes in density of the basement rocks rather than basement topography especially in the northern part of the
basin
It is recommended that the GSWA investigate access to company confidential high-resolution aeromagnetic data
prior to planning further aeromagnetic surveys Private companies have flown large parts of the northern half of the
area as part of their diamond exploration program Additional gravity coverage of the area may be more cost effective
than magnetic surveys as the gravity data provides more information on changes within the sedimentary section
Introduction
The main use of aeromagnetic data in petroleum exploration has been the determination of magnetic basement
topography although there has been increasing interest in analysis of intra-sedimentary magnetic anomalies
intrabasement and suprabasement magnetic anomalies These anomalies are used to determine depth to magnetic
basement rocks and hence determine the thickness of the sedimentary sequence Unfortunately interpretation of the
intrabasement and suprabasement magnetic anomalies is non-unique in terms of position and size of causative sources
because of the inherent ambiguity of potential-field methods However this ambiguity can be reduced by placing
49
constraints on source geometry and magnetization and by using geological and other geophysical data to constrain
the solution
Before 1970 most depth-determination techniques involved graphical determination of slopes of selected
magnetic anomalies and application of various empirical factors to convert the slopes into depth estimates Geological
Society of America Memoir 47 Interpretation of Aeromagnetic Maps by Vacquier et al (1951) was a landmark for
this type of interpretation
Automated interpretation procedures have played an increasingly important role in depth interpretation and a
wide range of techniques have been developed Many of these techniques are designed for application to located data
profiles and assume a two-dimensional geometry However there has been renewed interest in techniques applicable
to gridded data
Two distinct types of method can be recognized In the first case often described as discrete methods individual
isolated magnetic anomalies are interpreted and the results used to produce a map of basement relief In the second
case often described as continuous methods areas of data containing a number of anomalies are interpreted
statistically to produce direct output of basement depths
The discrete methods usually involve a semiautomatic initial phase which generates a large number of possible
depth solutions and an interactive second phase to screen and select acceptable solutions The advantage of this
approach is that the interpreter can select features that are relatively free from interference from adjacent anomalies
and consider all aspects of a particular magnetic anomaly The disadvantage is that interpretation can be very time
consuming as a wide range of depths are usually possible depending on the initial model chosen and a significant
amount of effort is needed to select the correct model In the case of the Savory Sub-basin dataset we encountered
problems in separating basement related effects from the effects of shallower intrasedimentary magnetic sources
Because of these problems we have concentrated on displaying the Euler results accompanied by separation filter
images of the data to show the shallower effects and deeper effects rather than trying to refine a 3D Euler
deconvolution depth-to-crystalline-basement contour
The continuous methods are very direct provided that the rather restrictive assumption can be made that all
anomalies are due to lateral magnetization changes due to basement topography This means that shallow effects and
large intrabasement anomalies must be removed from the data This involves judgement and skill as it is necessary to
distinguish between the lower amplitude suprabasement anomalies due to basement topography and the larger
intrabasement anomalies reflecting magnetization changes within the basement These methods were not considered
suitable for the Savory Sub-basin magnetic dataset but were used to invert the gravity data
50
Limitations of magnetic and gravity interpretation
Interpretation of the area is limited by a shortage of information on the nature and physical properties of the deeper
sedimentary sequence and the underlying basement rocks However using techniques such as cross-correlation of
gravity and pseudo-gravity data it is possible to try to differentiate between anomalies relating to basement and those
related to the sedimentary sequence
Gravity anomalies reflect changes within the sedimentary sequence as well as basement condition These
changes in density of sedimentary rocks produce gravity anomalies without a corresponding magnetic anomaly hence
the complementary nature of gravity and magnetic surveys The main use of magnetics is to determine depth to
magnetic basement and any intra-sedimentary volcanic rocks or intrusives whereas gravity provides much more
general information on the sedimentary sequence
Unfortunately interpretation of gravity anomalies is complicated since they can be due to a number of geological
features including
bull major basement faults
bull basement highs
bull igneous intrusions within the basement
bull sedimentary basins which may or may not be isostatically compensated
bull intra-sedimentary volcanics and associated plutonic centres
Two major problems affect the interpretation of both magnetic and gravity data
1 The inherent ambiguity of potential-field data There is no unique solution to any measured gravity or magnetic
anomaly and theoretically there will be an infinite number of source geometry and magnetizationdensity
combinations which will fit the observed data This means that any a priori information which helps to select a
suitable model is very useful
2 Measured anomalies are the summation of effects from different depths For example an observed gravity profile
may contain contributions from shallow sources (density variations within the sedimentary basin) intermediate
depth sources (density variations due to large igneous intrusions within the basement) and deep sources (crustal
thinning producing a mantle anomaly) Separation of these component responses is the regionalresidual problem
which we solve using spectral analysis and differential upward continuation-based separation filtering
Regional setting and interpretation overview
The area studied includes parts of BALFOUR DOWNS (SF51-9) RUDALL (SF51-10) ROBERTSON (SF51-13) GUNANYA
(SF51-14) COLLIER (SG50-4) BULLEN (SG51-1) TRAINOR (SG51-2) MADLEY (SG51-3) NABBERU (SG50-5)
STANLEY (SG51-6) and HERBERT (SG51-7) 1250 000 sheets Broadly the area lies between latitudes 22deg00rsquondash25deg30rsquoS
and longitudes 119deg30rsquondash123deg30rsquoE
51
Regional gravity
The AGSO regional gravity data (at nominal 11 km spacing) was gridded at a 4 km mesh spacing using a minimum-
curvature algorithm Bouguer gravity values in the area are negative reflecting mass deficiency at depth and range
from -84 mgals to -25 mgals
A Bouguer gravity colour image is shown as Figure 41 A residual grid was produced by removing a fifth-order
orthogonal polynomial from the Bouguer data but did not add to the interpretation
120deg 121deg 122deg 123deg
23deg
24deg
25deg
-25
-84
50 km
MKS46 180598
mgal
Figure 41 Regional Bouguer gravity (BMRAGSO data) gridded at 4 km
52
The data show a complex pattern of positive and negative anomalies with no clearly defined trends Correlations
with aeromagnetic data and known basin structures are poor A vague north-northwest linear trend appears to coincide
with the Marloo Fault (Figure 42) A prominent negative anomaly appears to coincide with the Blake Fold and Fault
Belt depocentre and continues as a narrower negative anomaly to the east until it widens out again near the edge of the
basin Elsewhere the gravity data show little correlation with known basin structures and it is likely that especially in
the north of the area gravity anomalies are due to density changes in the basement rather than changes in basement
topography
Production of wavelength-filtered residual gravity plots and vertical gradient plots showed very patchy aliased
data reflecting poor sampling in much of the area
Regional magnetics
The AGSO regional aeromagnetic data were gridded at a 400 m mesh spacing using a minimum-curvature algorithm
(Figure 43) Most of the data has a line spacing of 1600 m with small areas of 1 km spacing The quality of the data is
acceptable for regional interpretation but is not adequate for detailed analysis The accuracy of the flight path is rather
variable reflecting the vintage of the data and the noise envelope of the data is poor by modern standards Problems
were also encountered in joining different map sheets
The magnetic anomaly pattern over the south and west part of the area shows a strong high frequency signature
reflecting the presence of widespread basic sills and dykes Some of the major north-northeasterly trending dykes can
be traced over considerable distances
Discontinuous high-frequency anomalies extend as a northwest-trending zone through the centre of the area and
this zone includes a conspicuous circular magnetic anomaly which is probably a ring complex
The northern and eastern parts of the area are characterized by long-wavelength deep-seated basement magnetic
anomalies with 120deg and 150deg trends dominant The Marloo and Perentie Faults (Figure 42) appear as distinct linear
zones and offsets A prominent easterly trending negative anomaly in the northwest of the area appears to swing round
to the southeast and may separate different basement blocks One possible interpretation is that this very deep seated
anomaly separates areas of Archaean and Proterozoic basement
Regional geology
The regional geology is described in Williams (1992) The GSWA provided a digitized version of Plate 2 from this
Bulletin the structural interpretation map to use as an overlay (Figure 42)
53
Pp
Pp
PSd
PSd
PSd
PSd
PSd
PSo
PSt
PSt
PSf
PSf
PSf
PSb
PSb
PSb
PSsPSs
PSs
PSb
PSm
PSp
PSc
PSc
PSw
PSw
PSw
PSg
PSr
PSj
PSg
PM
Pk
PY
PY
PSd
L
L
L
L
L
L
L
LL
L
L
L
LL
L
LL
L L
LL
L L
L
L
L
L
L
L
L
LL
L
L
BLAKEDEPOCENTRE
MA
RLO
O
FAU
LT
PERENTIEFAULT
50 km
MKS39120598
120deg 121deg 122deg 123deg
25deg
24deg
23deg
Approximate boundaryof aeromagnetic interpretation
PML
PSgL
PSjL
PML
PSpL
PML
PML
PSfL
PSfL
PSpL
LPc
LPcLPcPSrL
LPA
Durba Sandstone
Woora Woora Formation
McFadden Formation
Tchukardine Formation
Boondawari Formation
Skates Hills Formation
Mundadjini Formation
Coondra Formation
Spearhole Formation
Watch Point Formation
Jilyili Formation
Brassey Range Formation
Glass Spring Formation
Paterson Formation
Yeneena Group
Karara Formation
Cornelia Formation
Kahrban Subgroup
Bangemall Group
Fault
Formation boundary
PSdL
PSoL
PSfL
PStL
PSbL
PSsL
PSmL
PScL
PSpL
PSwL
PSjL
PSrL
PSgL
Pp
PYL
PkL
LPc
LPA
PML
Savory Group Other Units
PYL
Figure 42 Regional geology and structure map (after Williams 1992)
54
120deg 121deg 122deg 123deg
23deg
24deg
25deg
5820
3750
MKS47 180598
nT
50 km
Figure 43 Regional aeromagnetic data total magnetic intensity (BMRAGSO data) gridded at 400 m
Analysis
3D analysis
3D Euler deconvolution was used as the primary depth-determination method The advantage of this approach is that
consistent solutions can be obtained over the entire area with minimal assumptions about source geometries Euler
deconvolution of gridded data is used for positional information and estimation of depth to top of source Euler
55
deconvolution yields a large number of depth solutions which have to be screened to reject spurious solutions Results
are plotted as circles in eight depth ranges with radius proportional to depth and colour coded
The 400 m total magnetic intensity grid was used for the analysis Horizontal gradients in x and y and the vertical
gradient were calculated 3D Euler deconvolution was tested on the 400 m gridded data using windows of 9 times 9 and
11 times 11 and 16 times 16 data points and structural indices 05 (fault) and 10 (sill or dyke) It was concluded that the
16 times 16 window produced the best results overall and final plots were produced for the 16 times 16 window and structural
index 05 (Fig 44) Results were very good over the northern and central parts of the area showing magnetic sources
Figure 44 Depth to magnetic source 3D Euler deconvolution 16 times 16 window of 400 m gridded data structural index 05
56
at several different levels Unfortunately in the extreme south of the area shallow intrasedimentary magnetic sources
(sills and dykes) dominated the inversion and the results contained few basement solutions
In order to reduce these problems the 400 m gridded data were filtered using a separation filter based on
interpretation of the log-energy spectrum The 3D Euler method was run on the filtered data in order to generate more
basement-depth solutions Results for the deep-separation filter data were gridded and presented as a colour image in
Cowan (1995) Attempts to grid the Euler output were unsatisfactory and it is considered safer to interpret the 3D
Euler depth plots The 3D Euler depth results from the separation-filter run should be analysed with care as perfect
separation of the basement can never be achieved and there will always be some contamination from sources at
different levels
The results of original total magnetic intensity 3D Euler depth estimation for structural index 05 using a 16 point
window have been plotted at 1500 000 scale (not included in this publication but available in Cowan (1995) from the
GSWA Library as S10331) and as reduced A4 colour circle plots (Figure 44)
The results of deep-basement 3D Euler depth estimation for structural index 05 using a 16 point window have
been plotted as a colour image at 1500 000 scale and as an A4 image (not included in this publication)
2D analysis
Two equispaced profiles were interpolated with a 50 m station interval from the AGSO-located data profiles for the
BULLEN 1250 000 sheet The interpolated profiles were analysed using 2D Euler deconvolution and Werner
deconvolution Results are included in Cowan (1995) and show the use of these methods for more detailed analysis
Filtered data
In order to reconcile 3D Euler results from shallow basement and intrasedimentary magnetic sources we produced
several separation-filtered maps and images We found the shallow-layer double-separation filter (Figure 45) to be
very effective for shallow sources and the deep-layer standard-separation filter (Figure 46) for the basement layer
Gravity and magnetic data correlation
Both lsquoreduced to the polersquo (RTP) magnetics (Figure 47) and pseudo-gravity data (Figure 48) were produced as part of
the reconciliation of gravity and magnetic signatures In both cases the filtering operations assumed magnetization by
induction in the present Earths field The RTP data are fairly similar to the total magnetic intensity The pseudo-
57
gravity data are dominated by a northwest-trending strong positive anomaly and there is little correlation with the
Bouguer gravity data
The poor magneticgravity correlation is confirmed by cross-correlation of the RTP magnetics and the gravity
gradient The correlation plot in Figure 49 shows little coherent response with numerous zones of positive and
negative correlation
Figure 45 Regional aeromagnetic data shallow layer separation filter (BMRAGSO data) gridded at 400 m
Results
In the north and east of the area on the Wells Foreland Sub-basin trend (refer to Figure 1 main text) we see a range
of quite deep 3D Euler depths and several trend directions with north-northwesterly dominant There are relatively few
shallow intrasedimentary solutions in this zone
The second area of deep 3D Euler solutions lies over the Blake depocentre (Figure 43) with several trend
directions
Elsewhere the 3D Euler results are dominated by shallow intrasedimentary depth solutions reflecting mainly the
dolerite sills dykes and the ring complex However where we do see basement-related solutions in the south and
west of the area they appear to be shallower than those noted for the Wells Foreland Sub-basin and the Blake
depocentre
58
Figure 46 Regional aeromagnetic data deep-layer separation filter (BMRAGSO data) gridded at 400 m
Figure 48 Regional aeromagnetic data pseudo-gravity transform (BMRAGSO data) gridded at 400 m
Figure 47 Regional aeromagnetic data reduced-to-pole (BMRAGSO data) gridded at 400 m
Figure 49 Regional aeromagnetic and gravity data gravitymagnetic correlation using RTP magnetics and gravity gradient (BMRAGSO data) gridded at 4 km
59
This subdivision of the area into two zones of deep solutions is consistent with interpreted depocentres
However the interference between sources at different levels and the complexity of the magnetic response of the
basement rocks precludes more refined interpretation at this stage
The area of deep 3D Euler solutions over the Blake depocentre correlates with the pronounced negative gravity
anomaly discussed in the gravity interpretation section Using a density contrast of -015 gcc the negative gravity
anomaly could indicate up to 6ndash8 km of low-density sedimentary rocks depending on assumptions about the regional
field
The area of deep 3D Euler solutions over the Wells Foreland Sub-basin has a complex gravity expression and no
clear basin structure emerges from inversion of these data As noted previously it is likely that observed gravity
anomalies reflect contrasts in basement density rather than basement topography
Separation filtering applied to the magnetic data helps to enhance the intrasedimentary magnetic signature and to
give a better impression of the basement magnetic signature even though separation of the basement response is not
perfect
Conclusions
Quantitative aeromagnetic interpretation using 3D Euler deconvolution supported by wavenumber filtering and image
processing has been successful in providing structural trend and depth information for the Savory Sub-basin
Quantitative magnetic interpretation has revealed two zones of relatively deep magnetic basement beneath the
Wells Foreland Sub-basin and the Blake depocentre
This analysis of the magnetic data supports interpreted depocentres but the complexity of the basement magnetic
signature and interference from sources at different depths precludes further refinement to a map of basement
topography
Regional gravity proved to be very useful in understanding the regional setting of the area and in providing
support for aspects of the interpretation The gravity data support the interpretation of the Blake depocentre
suggesting up to 6ndash8 km of low-density sedimentary rocks
The deep structure of the Savory Sub-basin area is obviously complex with different areas underlain by
Archaean and Proterozoic basement and with the Capricorn suture occurring in the centre of the area
60
Recommendations
The quantitative magnetic interpretation needs to be reconciled with geological models available for the area
In particular the zones tentatively identified as areas with thick sedimentary rocks the Wells Foreland Sub-
basin and the Blake depocentre need to be investigated
Cross sections should be prepared across the basin for joint magneticgravity modelling especially for the Blake
depocentre It is important to be able to explain the strong negative gravity anomaly in this area
In view of the effects of basement density contrasts on the gravity field for the northern part of the area we think
that additional gravity interpretation and acquisition of new gravity data may not be justified as they will not
contribute significantly to understanding basin evolution and structure
It is recommended that GSWA try to get access to company confidential high-resolution aeromagnetic data
rather than flying new surveys The GSWA might offer to fund flying of new infill areas as a bargaining point
References
The original text of this report by Cowan (1995) and 1500 000 scale maps are filed in the GSWA Library under
S10331
COWAN D 1995 Savory Basin quantitative magnetic interpretation Western Australia Geological Survey S-series
S10331 (unpublished)
VACQUIER V STEENLAND N C HENDERSON R G and ZIETZ I 1951 Interpretation of aeromagnetic
maps The Geological Society of America Memoir 47 151p
WILLIAMS I R 1992 Geology of the Savory Basin Western Australia Western Australia Geological Survey
Bulletin 141 115p
61
Appendix 5
Geochemistry
MKS38 250398
Saturate FractionC12+ GLC
1217
Pr18
Ph
22
31CSR WELL-13 315m Cuttings
Figure 51 Canning Stock Route Well 13 gas chromatograph of extract of auger drill sample
12
17
18
22
31
Pr Ph
LDDH 1 6623m CoreSaturate FractionC12+ GLC
MKS35 240398
Figure 52 Gas chromatograph of extract from core sample at 6623 m LDDH1
62
Table 51 Canning Stock Route Well 13 auger drill samples
GSWA sample Drill depth (m)(a) Comments
135601 150 At watertable 135602 203 (all samples consist 135603 310 of sand mud and water) 135604 315 At total depth
NOTE (a) Datum for drill depth is the top of sediment fill in the well which is 155 m below ground level (ie the total depth of 315 m is 47 m below ground level)
Table 52 Canning Stock Route Well 13 gas chromatography data for 315 m depth sediment sample
Parameter Value
Weight of rock extracted (grams) 945 Total extract (ppm) 519 n-Alkane distribution n-C12 07 n-C13 23 n-C14 26 n-C15 22 n-C16 19 n-C17 14 i-C19 23 n-C18 14 i-C20 08 n-C19 11 n-C20 16 n-C21 25 n-C22 29 n-C23 70 n-C24 42 n-C25 95 n-C26 43 n-C27 83 n-C28 38 n-C29 87 n-C30 31 n-C31 273 Alkane compositional data Pristane phytane ratio 279 Pristane n-C17 ratio 161 Phytane n-C18 ratio 059 CPI (1)(a) 284 CPI (2) 209 (C21 + C22) (C28 + C29) 043
NOTE (a) CPI= Carbon preference index
63
Table 53 LDDH1 extract liquid chromatography data for 6623 m concentration
Rock extracted Total extract (grams) (ppm)
702 313
NOTE ppm= parts per million
Table 54 LDDH1 saturate gas chromatography data of core for 6623 m alkane composition
Pristane Pristane Phytane (a) CPI (1) CPI (2) (C21+C22) Phytane n-C17 n-C18 (C28+C29)
103 026 024 103 102 325
NOTE (a)CPI = carbon preference index
Table 55 LDDH1 saturate gas chromatography data of core for 6623 m n-alkane distributions
Parameter Value
n-C12 17 n-C13 38 n-C14 55 n-C15 60 n-C16 65 n-C17 74 i-C19 19 n-C18 78 i-C20 19 n-C19 80 n-C20 79 n-C21 71 n-C22 64 n-C23 57 n-C25 43 n-C24 38 n-C27 31 n-C28 23 n-C29 19 n-C30 12 n-C31 10
64
Appendix 6
Table 61 Summary of data from Trainor waterbores (TWB) and Bullen waterbores (BWB)
Well AMG Elevation TD Status(b) Completion details Water Salinity Water level Flow rate Depth to consolidated AGD84 GL (m) (m) struck mgl(c) (m) (LHr) lithology aquifer(e) Z51(a) Interval (m) (100 mm PVC) (m) (mgl)(d)
TWB 1 473660E 453 122 comp 0ndash75 plain 63 7 300 24 2 880 12 m 7287404N 75ndash93 slotted (9 260) McFadden Fm 93ndash99 plain TWB 2 472 977E 475 23 abd nil 15 m 7285877N Skates Hills Fm dry TWB 3 473259E 475 50 abd nil 7 m 7285849N Skates Hills Fm dry TWB 4 463225 E 445 50 comp 0ndash22 plain 35 7 200 55 3 600 0 m 7286143N 22ndash34 slotted (8 140) Tertiary sand and gravel 23ndash60 plain TWB 5 463095E 445 31 comp 0ndash19 plain 13 26 000 655 3 600 Tertiary sand and gravel 7277721N 19ndash25 slotted (36 700) 25ndash31 plain TWB 6 457013E 455 50 comp 0ndash42 plain 38 920 119 600 0 m 7274352N 42ndash48 slotted (1 030) Cornelia Fm ss TWB 7 453739E 475 26 susp 0ndash2 plain 11 9 300 48 4 500 0 m 7263891N (10 500) Tertiary sand TWB 8 433893E 535 60 susp 0ndash2 plain 47 8 500 gt46 1 200 0 m 7245991N (10 900) Tertiary sand and Brassey Range Fm ss TWB 9 437219E 505 51 comp 0ndash47 plain 45 1 000 58 600 1 m 7235905N 47ndash51 slotted (990) Brassey Range Fm ss TWB 10 434927E 495 32 susp 0ndash2 plain 235 450 120 0 m 7225875N (500) Dolerite
65
BWB 1 287337E 580 122 abd Nil 1 m 7245861N Jilyili Fm dry BWB 2 288346E 545 50 comp 0ndash26 plain 15 630 3 29 000 0 m 7240423N 26ndash38 slotted (730) Tertiary sand and gravel 38ndash50 plain BWB 3 305637E 545 50 abd 19 8 800 43 7 200 0 m 7240423N (10 550) Tertiary ss BWB 4 320167E 515 445 comp 0ndash20 plain 9 980 445 24 000 0 m 7248097N 20ndash32 slotted (1 190) Tertiary ss 32ndash44 plain BWB 5 353393E 545 20 susp 0ndash2 plain 45 (970) 1 m 7238934N Basalt
NOTES (a) GPS accuracy ~ 150 m (b) Comp = completed abd = abandoned susp = suspended (c) Salinity from conductivity (d) Analysis total dissolved solids (e) Fm = Formation ss = sandstone
34
1 Thick accumulations of sedimentary rocks are present (up to 8 km thickness inferred) which
may contain source reservoir and sealing strata
2 Minor oil shows occur in Mundadjini 1 and Boondawari 1 and bitumen is present in mineral
exploration drillhole LDDH1 suggesting that hydrocarbons have migrated within the
Neoproterozoic sequence of the Savory Sub-basin Oil and bitumen are present in mineral
exploration drillhole OD23 in the Bangemall Basin immediately to the south of the Savory
Sub-basin and it is possible that source rocks from the Bangemall Basin could charge traps in
the overlying Savory Sub-basin
3 The age of sedimentary rocks in the sub-basin is still poorly constrained but some of the
Neoproterozoic sedimentary rocks located on GUNANYA and TRAINOR are within the
hydrocarbon-generation window It is possible that a significant thickness of Phanerozoic
sedimentary rocks may also be present
4 Friable sandstones with visible porosity outcrop extensively suggesting numerous potential
reservoirs
5 Significant but not intense faulting and folding has been mapped implying large structural
traps may be present
6 Evaporitic sedimentary rocks occur in several formations and may provide good source rocks
and excellent seals
35
References
APAK S N and CARLSEN G M 1997 A compilation and review of data pertaining to the
hydrocarbon prospectivity of the Canning Basin Western Australia Geological Survey
Record 199610 103p
BAGAS L GREY K and WILLIAMS I R 1995 Reappraisal of the Paterson Orogen and
Savory Basin Western Australia Geological Survey Annual Review 1994ndash95 p 55ndash63
BUSBRIDGE M 1994 Lake Disappointment Exploration Licence 451064 Third Annual
Report Lake Disappointment Diamond Drill Hole LDDH1 Normandy Exploration Limited
Western Australia Geological Survey M-series Item 7567 A41358 (unpublished)
CARLSEN G M and SHEVCHENKO S I 1997 Petroleum exploration in Proterozoic basins
using potential fields data and stratigraphic coring Australian Society of Exploration
Geophysicists 12th Geophysical Conference Handbook Sydney 1997 Preview no 66 p 83
(abstract only)
COWAN D 1995 Savory Basin quantitative magnetic interpretation Western Australia
Geological Survey S-series S10331 (unpublished)
DAISHSAT PTY LTD 1995 Operational and processing report Savory Basin gravity survey
Western Australia Geological Survey S-series S10332 (unpublished)
GARD E and GARD R 1990 Canning Stock Route a travellerrsquos guide for a journey through
history Perth Western Australia Western Desert Guides 448p
GEOLOGICAL SURVEY OF WESTERN AUSTRALIA 1996a Savory Basin first vertical
derivative of Bouguer gravity image 1250 000 Western Australia Geological Survey
GEOLOGICAL SURVEY OF WESTERN AUSTRALIA 1996b Savory Basin Bouguer gravity
image 1250 000 Western Australia Geological Survey
GHORI K A R in prep Petroleum source rock potential and thermal history Officer Basin
Western Australia Western Australia Geological Survey Record
36
GREY K 1995a Savory Basin drillhole BWB 1 (Bullen waterbore) palynology and thermal
maturation GSWA Palaeontology Report no 199512 (unpublished)
GREY K 1995b Savory Basin drillholes TWB 1 2 6 9 (Trainor waterbores) palynology and
thermal maturation GSWA Palaeontology Report no 199520 (unpublished)
GREY K 1995c Palynology of Normandy-Poseidon Lake Disappointment-1 corehole
Tarcunyah Group Paterson Orogen GSWA Palaeontology Report no 199521 (unpublished)
GREY K 1995d Savory Basin drillhole Trainor 1 (Trainor diamond drilling) palynology and
thermal maturity GSWA Palaeontology Report no 199524 (unpublished)
GREY K 1995e Savory Basin drillhole Trainor 1 (Trainor diamond drilling) Additional
Preparation of two samples GSWA Palaeontology Report no 199528 (unpublished)
GREY K 1995f Neoproterozoic stromatolites from the Skates Hills Formation Savory Basin
Western Australia and a review of the distribution of Acaciella australica Australian Journal
of Earth Sciences v 42 p 123ndash132
GREY K 1996a Savory Basin drillhole Trainor 1 (Trainor diamond drilling) Additional
samples palynology and thermal maturation GSWA Palaeontology Report no 199615
(unpublished)
GREY K 1996b Preliminary stromatolite correlations for the Neoproterozoic of the Officer
Basin and a review of Australia-wide correlations GSWA Palaeontology Report no 199615
(unpublished)
GREY K and COTTER K L 1996 Palynology in the search for Proterozoic hydrocarbons
Western Australia Geological Survey Annual Review for 1995ndash96 p 70ndash80
GREY K and STEVENS M K 1997 Neoproterozoic palynomorphs of the Savory Sub-basin
Western Australia and their relevance to petroleum exploration Western Australia
Geological Survey Annual Review for 1996ndash97 p 49ndash54
HUBBARD R J PAPE J and ROBERTS D G 1985 Depositional sequence mapping as a
technique to establish tectonic and stratigraphic framework and evaluate hydrocarbon
potential on a passive continental margin in Seismic stratigraphy II an integrated approach
37
edited by O R BERG and D G WOOLVERTON American Association of Petroleum
Geologists Memoir 39 p 79ndash91
LIBBY WG 1995 A petrological report on six samples of bore cuttings from the Savory Basin
Western Australia Western Australia Geological Survey S-series S31307 (unpublished)
MORTON JGG and DREXEL JF 1997 The petroleum geology of South Australia Vol 3
Officer Basin South Australia Department of Mines and Energy Resources Report Book
9719
MUHLING P C and BRAKEL A T 1985 Geology of the Bangemall Group mdash the evolution
of an intracratonic Proterozoic basin Western Australia Geological Survey Bulletin 128
219p
MYERS J S 1990 Precambrian tectonic evolution of part of Gondwana southwestern Australia
Geology v18 p 537ndash540
NELSON D R 1997 Compilation of SHRIMP UndashPb zircon data Western Australia Geological
Survey Record 19972 196p
PAYTON C E 1977 Seismic stratigraphy mdash applications to hydrocarbon exploration
American Association of Petroleum Geologists Memoir 26 516p
PERINCEK D 1996a The age of NeoproterozoicndashPalaeozoic sediments within the Officer Basin
of the Centralian Super-basin can be constrained by major sequence-bounding unconformities
APPEA Journal v 36 pt 1 p 350ndash368
PERINCEK D 1996b The stratigraphic and structural development of the Officer Basin
Western Australia a review Western Australia Geological Survey Annual Review 1995ndash
1996 p 135ndash148
PERINCEK D 1998 A compilation and review of data pertaining to the hydrocarbon
prospectivity of the Officer Basin Western Australia Geological Survey Record 19976
POSAMENTIER H W JERSEY M T and VAIL P R 1988 Eustatic controls on clastic
deposition 1 mdash Conceptual framework in Sea-level changes an integrated approach edited by
C K WILGUS B S HASTINGS C G St C KENDALL H W POSAMENTIER
38
C A ROSS and J C VAN WAGONER Society of Economic Paleontologists and
Mineralogists Special Publication no 42
STEVENS M K and ADAMIDES N G in prep GSWA Trainor 1 well completion report
Savory Sub-basin Officer Basin Western Australia with notes on petroleum and mineral
potential Western Australia Geological Survey Record 199612
STEVENS M K and GREY K 1997 Skates Hills Formation and Tarcunyah Group Officer
Basin mdash carbonate cycles stratigraphic position and hydrocarbon prospectivity Western
Australia Geological Survey Annual Review for 1996ndash97 p 55ndash60
SUMMONS RE and POWELL C McA 1991 Petroleum source rocks of the Amadeus Basin
in Geological and geophysical studies in the Amadeus Basin central Australia edited by R J
KORSCH and JM KENNARD Australia BMR Geology and Geophysics Bulletin 236
TRAVERSE A 1988 Palaeopalynology Boston Unwin Hyman 600p
VAIL P R MITCHUM R M Jr TODD R G WIDMIER J M THOMPSON S III
SANGREE J B BUBB J N and HATLELID W G 1977 Seismic stratigraphy and
global changes of sea level in Seismic stratigraphy mdash applications to hydrocarbon
exploration edited by C E PAYTON American Association of Petroleum Geologists
Memoir 26 516p
WALTER M R and GORTER J 1994 The Neoproterozoic Centralian Superbasin in Western
Australia the Savory and Officer Basins in The sedimentary basins of Western Australia
edited by P G PURCELL and R R PURCELL Petroleum Exploration Society of Australia
Symposium Perth WA 1994 Proceedings p851ndash864
WALTER M R GREY K WILLIAMS I R and CALVER C R 1994 Stratigraphy of the
Neoproterozoic to early Palaeozoic Savory Basin and correlation with the Amadeus and
Officer Basins Australian Journal of Earth Sciences v 41 p 533ndash546
WALTER M R VEEVERS J J CALVER C R and GREY K 1995 Neoproterozoic
stratigraphy of the Centralian Superbasin Australia Precambrian Research v 73 p 173ndash195
WILLIAMS I R 1992 Geology of the Savory Basin Western Australia Western Australia
Geological Survey Bulletin 141 115p
39
WILLIAMS I R 1995a Bullen WA (2nd Edition) Western Australia Geological Survey
1250 000 Geological Series Explanatory Notes 23p
WILLIAMS I R 1995b Trainor WA (2nd Edition) Western Australia Geological Survey
1250 000 Geological Series Explanatory Notes 31p
WILLIAMS I R and TYLER I M 1991 Robertson WA (2nd edition) Western Australia
Geological Survey 1250 000 Geological Series Explanatory Notes 36p
40
41
Appendix 1
Bibliography
Reports which are relevant to this investigation but which are not specifically cited are listed
below
BAILLIE P W POWELL C McA LI Z X and RYALL A M 1994 The tectonic
framework of Western Australiarsquos Neoproterozoic to recent sedimentary basins in The
sedimentary basins of Western Australia edited by P G PURCELL and R R PURCELL
Petroleum Exploration Society of Australia Symposium Perth WA 1994 Proceedings p
45ndash62
BRADSHAW M T BRADSHAW J MURRAY A P NEEDHAM D J SPENCER L
SUMMONS R E WILMOT J and WINN S 1994 Petroleum systems in West Australian
basins in The sedimentary basins of Western Australia edited by P G PURCELL and R R
PURCELL Petroleum Exploration Society of Australia Symposium Perth WA 1994
Proceedings p 93ndash118
CLARKE G L 1991 Proterozoic tectonic reworking in the Rudall Complex Western Australia
Australian Journal of Earth Science v38 p 31ndash44
COCKBAIN A E and HOCKING R M 1990 Phanerozoic in Geology and mineral resources
of Western Australia Western Australia Geological Survey Memoir 3 p 750ndash755
ETHERIDGE M and WALL V 1994 Tectonic and structural evolution of the Australian
Proterozoic 12th Australian Geological Convention Geological Society of Australia
Abstracts no 37 p 102ndash103
GOODE A D T 1981 Proterozoic geology of Western Australia in Precambrian of the
Southern Hemisphere Developments in Precambrian geology 2 edited by I R HUNTER
Amsterdam Elsevier p 105ndash203
GREY K and JACKSON M J 1983 A re-assessment of stromatolite evidence for the
correlation of the Late Proterozoic Neale and Ilma Beds Officer Basin Western Australia
Australia BMR Journal of Australian Geology and Geophysics v 8 p 359
42
HICKMAN A H WILLIAMS I R and BAGAS L 1994 Proterozoic geology and
mineralization of the TelferndashRudall region Paterson Orogen Geological Society of Australia
(WA Division) Excursion Guidebook no 5 56p
HOCKING R M MORY A J and WILLIAMS I R 1994 An atlas of Neoproterozoic and
Phanerozoic basins of Western Australia in The sedimentary basins of Western Australia
edited by P G PURCELL and R R PURCELL Petroleum Exploration Society of Australia
Symposium Perth WA 1994 Proceedings p 21ndash 44
JACKSON P R 1966 Geology and review of exploration Officer Basin Western Australia
Hunt Oil Company Western Australia Geological Survey S-series S26 (unpublished)
JACKSON M J 1971 Notes on a geological reconnaissance of the Officer Basin Western
Australia Australia BMR Geology and Geophysics Record 19715 30p
JACKSON M J and van de GRAAFF W J E 1981 Geology of the Officer Basin Western
Australia Australia BMR Geology and Geophysics Bulletin 206 102 p
LOWRY D C JACKSON M J van de GRAAFF W J E and KENNEWELL P J 1971
Preliminary result of geological mapping in the Officer Basin Western Australia Western
Australia Geological Survey Annual Report for 1971 p 50ndash56
MYERS J S 1990 Precambrian in Geology and mineral resources of Western Australia
Western Australia Geological Survey Memoir 3 p 737ndash750
MYERS J S SHAW R D and TYLER I M 1994 Proterozoic tectonic evolution of
Australia 12th Australian Geological Convention Geological Society of Australia Abstracts
no 37 p 312
NEDIN C and JENKINS R J F 1991 Re-evaluation of unconformities separating the
lsquoEdiacaranrsquo and Cambrian systems South Australia Palaios v 6 p 102ndash108
PHILLIPS B J JAMES A W and PHILIP G M 1985 The geology and hydrocarbon
potential of the north-western Officer Basin APEA Journal 25 (1) p 52ndash61
POWELL C McA LI Z X McELHINNY M W MEERT J G and PARK J K 1993
Paleomagnetic constraints on timing of the Neoproterozoic breakup of Rodinia and Cambrian
formation of Gondwana Geology v 21 p 889ndash892
43
POWELL C McA PREISS W V GATEHOUSE C G KRAPEZ B and LI Z X 1994
South Australian record of a Rodinian epicontinental basin and its mid-Neoproterozoic
breakup to form the Palaeo-Pacific Ocean Tectonophysics v 237 no 3ndash4 p 113ndash140
PREISS W V 1976 Proterozoic stromatolites from the Nabberu and Officer Basins Western
Australia and their biostratigraphic significance South Australia Geological Survey Report
of Investigations no 47 p 1ndash51
TOWNSON W G 1985 The subsurface geology of the western Officer Basin mdash results of
Shellrsquos 1980ndash1984 petroleum exploration campaign APEA Journal v 25 (1) p 34ndash51
WATTS K J 1982 The geology of the Townsend Quartzite Upper Proterozoic shallow water
deposit of the Northern Officer Basin Western Australia Perth University of Western
Australia BSc honours thesis (unpublished)
WELLS A T and KENNEWELL P J 1974 Evaporite exploration in the Officer Basin
Western Australia at the Madley Diapirs Australia BMR Record 1974194 (unpublished)
WILLIAMS I R and MYERS J S 1990 Paterson Orogen in Geology and mineral resources
of Western Australia Western Australia Geological Survey Memoir 3 p 274ndash286
WILLIAMS I R 1990 Savory Basin in Geology and mineral resources of Western Australia
Western Australia Geological Survey Memoir 3 p 329ndash334
WILLIAMS I R 1994 The Neoproterozoic Savory Basin Western Australia in The
sedimentary basins of Western Australia edited by P G PURCELL and R R PURCELL
Petroleum Exploration Society of Australia Symposium Perth WA 1994 Proceedings p
841ndash850
WILSON R B 1967 Woolnough Hills and Madley diapiric structures Gibson Desert WA
APEA Journal v 7 p 94ndash102
44
Appendix 2
Meteorological data (from Bureau of Meteorology Perth 1994)
Table 21 Wiluna rainfall (mm)
Year Jan Feb Mar Apr May Jun Jul Aug Sept Oct Nov Dec
1975 0 45 446 309 306 59 276 4 34 886 638 164 1976 16 154 12 138 53 16 34 62 12 238 0 2 1977 44 0 66 74 68 95 24 363 1 58 12 727 1978 234 522 94 16 0 96 367 24 16 353 185 45 1979 19 173 122 88 91 4 0 246 58 0 169 114 1980 148 764 68 1081 259 626 629 06 56 02 174 0 1981 123 476 192 32 196 118 44 74 14 0 28 312 1982 374 705 206 244 1079 92 02 143 368 526 368 118 1983 1 112 928 248 0 212 56 32 5 1 42 496 1984 149 7 342 84 836 0 348 132 224 04 16 172 1985 596 483 0 166 556 0 514 56 0 0 4 0 1986 0 154 35 0 0 1085 23 01 239 137 0 04 1987 1204 119 19 89 17 575 154 126 07 1 0 398 1988 46 202 164 13 388 0 202 104 0 0 224 1309 1989 207 234 26 703 278 536 57 0 01 0 144 02 1990 1035 23 281 46 126 53 94 218 44 9 42 0 1991 48 0 41 45 0 472 297 12 0 1 0 7 1992 112 96 1025 1227 323 65 04 174 0 132 48 4 1993 0 697 0 202 445 0 12 306 18 05 14 33 Mean 25 35 22 27 27 25 18 12 6 13 13 21
JAN FEB MAR APR MAY JUN JUL AUG SEP OCT NOV DEC0
10
20
30
40
Mea
n R
ain
fall
(mm
)
Month
Mean monthly rainfall in Wiluna
MKS41 140498
45
Table 22 Wiluna minimum temperature (degC)
Year Jan Feb Mar Apr May Jun Jul Aug Sept Oct Nov Dec
1975 ndash 23 203 15 94 63 71 62 103 124 169 205 1976 242 229 194 15 10 63 59 73 95 143 16 228 1977 243 25 197 148 96 95 56 86 102 ndash 188 23 1978 241 232 203 18 102 64 76 8 9 152 19 205 1979 255 226 216 167 83 6 59 79 97 145 198 223 1980 255 226 231 155 134 83 68 75 121 108 193 223 1981 245 216 19 182 119 6 54 78 138 159 163 218 1982 232 224 177 16 ndash ndash 37 111 112 164 209 225 1983 235 24 197 147 112 88 39 88 121 162 189 219 1984 241 243 191 156 ndash 72 66 7 95 161 182 211 1985 244 231 ndash 159 98 65 71 73 117 147 205 ndash 1986 ndash 229 226 155 93 96 43 49 10 122 ndash 219 1987 ndash 217 183 175 85 77 68 68 112 ndash ndash 221 1988 238 214 209 178 111 ndash ndash 86 104 157 171 195 1989 ndash 237 199 165 107 67 44 61 107 131 187 ndash 1990 232 ndash 211 155 118 62 57 87 102 149 195 22 1991 26 256 217 168 122 101 78 ndash 113 18 168 219 1992 227 227 214 169 102 98 59 69 ndash 125 159 196 1993 241 218 196 171 103 ndash 49 68 88 128 192 211 Mean 24 23 20 16 10 8 6 8 11 14 18 21
NOTE Dashes indicate data unavailable
JAN FEB MAR APR MAY JUN JUL AUG SEP OCT NOV DEC0
10
20
30
40
Month
MKS43 140498
50
Mean monthly minimum temperatures at Wiluna
Mea
n T
emp
erat
ure
(degC
)
46
Table 23 Wiluna maximum temperature (degC)
Year Jan Feb Mar Apr May Jun Jul Aug Sept Oct Nov Dec
1975 ndash 349 326 281 247 201 197 212 256 248 31 344 1976 374 369 346 297 248 206 208 225 265 287 313 388 1977 397 392 352 296 234 212 222 244 ndash 308 337 383 1978 378 345 346 316 242 195 176 205 231 295 334 356 1979 403 36 364 295 ndash ndash ndash 193 242 318 359 373 1980 392 342 377 275 24 176 179 233 292 288 349 391 1981 385 346 337 342 242 178 201 224 30 326 326 369 1982 372 359 315 307 ndash ndash 196 253 252 305 353 379 1983 381 389 327 272 263 222 187 248 287 321 336 366 1984 378 393 322 299 226 215 178 214 234 ndash 336 364 1985 40 366 ndash 294 224 216 205 212 284 307 355 ndash 1986 ndash 383 372 307 ndash 193 166 196 261 277 ndash 382 1987 ndash 339 328 305 21 202 214 218 275 ndash ndash 374 1988 388 365 353 301 23 ndash ndash 228 283 334 31 33 1989 ndash 375 339 285 238 179 181 219 275 298 336 ndash 1990 368 ndash 36 309 268 19 188 205 274 309 373 393 1991 414 416 363 315 268 206 21 ndash 279 338 332 368 1992 363 383 336 263 213 178 213 197 ndash 285 313 359 1993 396 357 344 301 221 ndash 197 215 253 294 347 362 Mean 39 37 34 30 24 20 20 22 27 30 34 37 NOTE Dashes indicate data unavailable
JAN FEB MAR APR MAY JUN JUL AUG SEP OCT NOV DEC0
10
20
30
40
Month
MKS42 140498
50
Mean monthly maximum temperatures at Wiluna
Mea
n T
emp
erat
ure
(degC
)
47
Appendix 3
Table 31 Summary of palynological results
Drillhole Depth (m) F no(a) GSWA no Lithology Formation Assemblage TAI(b)
BWB 1 74ndash75 F49668 135741 dark-grey siltstone basalt Jilyilli gt5 BWB 1 98ndash100 F49669 135742 dark-grey siltstone basalt Jilyilli gt5 BWB 1 121ndash122 F49670 135743 dark-grey siltstone basalt Jilyilli gt5 TWB 1 86ndash87 F49671 135631 dark-grey siltstone McFadden 3+ TWB 1 104ndash105 F49672 135632 dark-grey siltstone Cornelia 3+ TWB 1 121ndash122 F49673 135633 dark-grey siltstone Cornelia 4 TWB 2 14ndash15 F49674 135634 dark-grey siltstone Skates Hills 3+ TWB 6 49ndash50 F49675 135675 dark-grey siltstone Cornelia 1 3+ TWB 9 49ndash51 F49676 135704 dark-grey siltstone Brassey Range 1 3+ Trainor 1 37497- F49733 138939 black mudstone with Cornelia 5 37509 light-grey siltstone Trainor 1 3809 F49734 138940 dark-grey and black Cornelia 4- laminated mudstone Trainor 1 4170 F49735 138941 black unlaminated mudstone Cornelia 4- Trainor 1 4950 F49851 139501 dark-grey indurated siltstone Cornelia 5 Trainor 1 6032 F49852 139502 dark- and light-grey Cornelia 5 indurated siltstone Trainor 1 6434 F49853 139503 greenish indurated finely Cornelia 5 laminated siltstone LDDH 1 270 F49678 138934 dark-grey siltstone interbeds Waters 1 3+ in enterolithic evaporite Tarcunyah Gp LDDH 1 277 F49679 138935 dark-grey siltstone in cavity Waters 1 3+ in enterolithic evaporite Tarcunyah Gp
NOTES (a) GSWA Fossil Catalogue number (b) TAI = Thermal Alteration Index of Traverse (1988 plate 1)
48
Appendix 4
Savory Sub-basin quantitative magnetic and gravity interpretation (extracted from Cowan 1995)
Summary
A program of quantitative aeromagnetic interpretation has been completed on BMRAGSO data from the Savory Sub-
basin Western Australia Quantitative aeromagnetic interpretation utilized the 3D Euler deconvolution method
supported by wavenumber filtering and image processing The results have provided useful information on structural
trends and depth to magnetic sources in a structurally complex area Depth to magnetic source analysis has provided
information on intra-sedimentary magnetic sources as well as basement rocks
The results of the interpretation support previously identified depocentres However the presence of magnetic
sources at several levels makes it very difficult to produce a reliable magnetic basement depth contour map It is
considered more productive to work with the 3D Euler colour circle plots and images rather than trying to contour the
results It would be necessary to carry out a full-scale interpretation of the BMRAGSO profile data to improve on the
3D Euler results The regional gravity was found to be useful in interpreting the regional setting of the area although
the very wide data spacing limits quantitative use of the data The gravity data show quite a complex picture with
limited consistent correlation between gravity features and basin structures This suggests that gravity anomalies
reflect changes in density of the basement rocks rather than basement topography especially in the northern part of the
basin
It is recommended that the GSWA investigate access to company confidential high-resolution aeromagnetic data
prior to planning further aeromagnetic surveys Private companies have flown large parts of the northern half of the
area as part of their diamond exploration program Additional gravity coverage of the area may be more cost effective
than magnetic surveys as the gravity data provides more information on changes within the sedimentary section
Introduction
The main use of aeromagnetic data in petroleum exploration has been the determination of magnetic basement
topography although there has been increasing interest in analysis of intra-sedimentary magnetic anomalies
intrabasement and suprabasement magnetic anomalies These anomalies are used to determine depth to magnetic
basement rocks and hence determine the thickness of the sedimentary sequence Unfortunately interpretation of the
intrabasement and suprabasement magnetic anomalies is non-unique in terms of position and size of causative sources
because of the inherent ambiguity of potential-field methods However this ambiguity can be reduced by placing
49
constraints on source geometry and magnetization and by using geological and other geophysical data to constrain
the solution
Before 1970 most depth-determination techniques involved graphical determination of slopes of selected
magnetic anomalies and application of various empirical factors to convert the slopes into depth estimates Geological
Society of America Memoir 47 Interpretation of Aeromagnetic Maps by Vacquier et al (1951) was a landmark for
this type of interpretation
Automated interpretation procedures have played an increasingly important role in depth interpretation and a
wide range of techniques have been developed Many of these techniques are designed for application to located data
profiles and assume a two-dimensional geometry However there has been renewed interest in techniques applicable
to gridded data
Two distinct types of method can be recognized In the first case often described as discrete methods individual
isolated magnetic anomalies are interpreted and the results used to produce a map of basement relief In the second
case often described as continuous methods areas of data containing a number of anomalies are interpreted
statistically to produce direct output of basement depths
The discrete methods usually involve a semiautomatic initial phase which generates a large number of possible
depth solutions and an interactive second phase to screen and select acceptable solutions The advantage of this
approach is that the interpreter can select features that are relatively free from interference from adjacent anomalies
and consider all aspects of a particular magnetic anomaly The disadvantage is that interpretation can be very time
consuming as a wide range of depths are usually possible depending on the initial model chosen and a significant
amount of effort is needed to select the correct model In the case of the Savory Sub-basin dataset we encountered
problems in separating basement related effects from the effects of shallower intrasedimentary magnetic sources
Because of these problems we have concentrated on displaying the Euler results accompanied by separation filter
images of the data to show the shallower effects and deeper effects rather than trying to refine a 3D Euler
deconvolution depth-to-crystalline-basement contour
The continuous methods are very direct provided that the rather restrictive assumption can be made that all
anomalies are due to lateral magnetization changes due to basement topography This means that shallow effects and
large intrabasement anomalies must be removed from the data This involves judgement and skill as it is necessary to
distinguish between the lower amplitude suprabasement anomalies due to basement topography and the larger
intrabasement anomalies reflecting magnetization changes within the basement These methods were not considered
suitable for the Savory Sub-basin magnetic dataset but were used to invert the gravity data
50
Limitations of magnetic and gravity interpretation
Interpretation of the area is limited by a shortage of information on the nature and physical properties of the deeper
sedimentary sequence and the underlying basement rocks However using techniques such as cross-correlation of
gravity and pseudo-gravity data it is possible to try to differentiate between anomalies relating to basement and those
related to the sedimentary sequence
Gravity anomalies reflect changes within the sedimentary sequence as well as basement condition These
changes in density of sedimentary rocks produce gravity anomalies without a corresponding magnetic anomaly hence
the complementary nature of gravity and magnetic surveys The main use of magnetics is to determine depth to
magnetic basement and any intra-sedimentary volcanic rocks or intrusives whereas gravity provides much more
general information on the sedimentary sequence
Unfortunately interpretation of gravity anomalies is complicated since they can be due to a number of geological
features including
bull major basement faults
bull basement highs
bull igneous intrusions within the basement
bull sedimentary basins which may or may not be isostatically compensated
bull intra-sedimentary volcanics and associated plutonic centres
Two major problems affect the interpretation of both magnetic and gravity data
1 The inherent ambiguity of potential-field data There is no unique solution to any measured gravity or magnetic
anomaly and theoretically there will be an infinite number of source geometry and magnetizationdensity
combinations which will fit the observed data This means that any a priori information which helps to select a
suitable model is very useful
2 Measured anomalies are the summation of effects from different depths For example an observed gravity profile
may contain contributions from shallow sources (density variations within the sedimentary basin) intermediate
depth sources (density variations due to large igneous intrusions within the basement) and deep sources (crustal
thinning producing a mantle anomaly) Separation of these component responses is the regionalresidual problem
which we solve using spectral analysis and differential upward continuation-based separation filtering
Regional setting and interpretation overview
The area studied includes parts of BALFOUR DOWNS (SF51-9) RUDALL (SF51-10) ROBERTSON (SF51-13) GUNANYA
(SF51-14) COLLIER (SG50-4) BULLEN (SG51-1) TRAINOR (SG51-2) MADLEY (SG51-3) NABBERU (SG50-5)
STANLEY (SG51-6) and HERBERT (SG51-7) 1250 000 sheets Broadly the area lies between latitudes 22deg00rsquondash25deg30rsquoS
and longitudes 119deg30rsquondash123deg30rsquoE
51
Regional gravity
The AGSO regional gravity data (at nominal 11 km spacing) was gridded at a 4 km mesh spacing using a minimum-
curvature algorithm Bouguer gravity values in the area are negative reflecting mass deficiency at depth and range
from -84 mgals to -25 mgals
A Bouguer gravity colour image is shown as Figure 41 A residual grid was produced by removing a fifth-order
orthogonal polynomial from the Bouguer data but did not add to the interpretation
120deg 121deg 122deg 123deg
23deg
24deg
25deg
-25
-84
50 km
MKS46 180598
mgal
Figure 41 Regional Bouguer gravity (BMRAGSO data) gridded at 4 km
52
The data show a complex pattern of positive and negative anomalies with no clearly defined trends Correlations
with aeromagnetic data and known basin structures are poor A vague north-northwest linear trend appears to coincide
with the Marloo Fault (Figure 42) A prominent negative anomaly appears to coincide with the Blake Fold and Fault
Belt depocentre and continues as a narrower negative anomaly to the east until it widens out again near the edge of the
basin Elsewhere the gravity data show little correlation with known basin structures and it is likely that especially in
the north of the area gravity anomalies are due to density changes in the basement rather than changes in basement
topography
Production of wavelength-filtered residual gravity plots and vertical gradient plots showed very patchy aliased
data reflecting poor sampling in much of the area
Regional magnetics
The AGSO regional aeromagnetic data were gridded at a 400 m mesh spacing using a minimum-curvature algorithm
(Figure 43) Most of the data has a line spacing of 1600 m with small areas of 1 km spacing The quality of the data is
acceptable for regional interpretation but is not adequate for detailed analysis The accuracy of the flight path is rather
variable reflecting the vintage of the data and the noise envelope of the data is poor by modern standards Problems
were also encountered in joining different map sheets
The magnetic anomaly pattern over the south and west part of the area shows a strong high frequency signature
reflecting the presence of widespread basic sills and dykes Some of the major north-northeasterly trending dykes can
be traced over considerable distances
Discontinuous high-frequency anomalies extend as a northwest-trending zone through the centre of the area and
this zone includes a conspicuous circular magnetic anomaly which is probably a ring complex
The northern and eastern parts of the area are characterized by long-wavelength deep-seated basement magnetic
anomalies with 120deg and 150deg trends dominant The Marloo and Perentie Faults (Figure 42) appear as distinct linear
zones and offsets A prominent easterly trending negative anomaly in the northwest of the area appears to swing round
to the southeast and may separate different basement blocks One possible interpretation is that this very deep seated
anomaly separates areas of Archaean and Proterozoic basement
Regional geology
The regional geology is described in Williams (1992) The GSWA provided a digitized version of Plate 2 from this
Bulletin the structural interpretation map to use as an overlay (Figure 42)
53
Pp
Pp
PSd
PSd
PSd
PSd
PSd
PSo
PSt
PSt
PSf
PSf
PSf
PSb
PSb
PSb
PSsPSs
PSs
PSb
PSm
PSp
PSc
PSc
PSw
PSw
PSw
PSg
PSr
PSj
PSg
PM
Pk
PY
PY
PSd
L
L
L
L
L
L
L
LL
L
L
L
LL
L
LL
L L
LL
L L
L
L
L
L
L
L
L
LL
L
L
BLAKEDEPOCENTRE
MA
RLO
O
FAU
LT
PERENTIEFAULT
50 km
MKS39120598
120deg 121deg 122deg 123deg
25deg
24deg
23deg
Approximate boundaryof aeromagnetic interpretation
PML
PSgL
PSjL
PML
PSpL
PML
PML
PSfL
PSfL
PSpL
LPc
LPcLPcPSrL
LPA
Durba Sandstone
Woora Woora Formation
McFadden Formation
Tchukardine Formation
Boondawari Formation
Skates Hills Formation
Mundadjini Formation
Coondra Formation
Spearhole Formation
Watch Point Formation
Jilyili Formation
Brassey Range Formation
Glass Spring Formation
Paterson Formation
Yeneena Group
Karara Formation
Cornelia Formation
Kahrban Subgroup
Bangemall Group
Fault
Formation boundary
PSdL
PSoL
PSfL
PStL
PSbL
PSsL
PSmL
PScL
PSpL
PSwL
PSjL
PSrL
PSgL
Pp
PYL
PkL
LPc
LPA
PML
Savory Group Other Units
PYL
Figure 42 Regional geology and structure map (after Williams 1992)
54
120deg 121deg 122deg 123deg
23deg
24deg
25deg
5820
3750
MKS47 180598
nT
50 km
Figure 43 Regional aeromagnetic data total magnetic intensity (BMRAGSO data) gridded at 400 m
Analysis
3D analysis
3D Euler deconvolution was used as the primary depth-determination method The advantage of this approach is that
consistent solutions can be obtained over the entire area with minimal assumptions about source geometries Euler
deconvolution of gridded data is used for positional information and estimation of depth to top of source Euler
55
deconvolution yields a large number of depth solutions which have to be screened to reject spurious solutions Results
are plotted as circles in eight depth ranges with radius proportional to depth and colour coded
The 400 m total magnetic intensity grid was used for the analysis Horizontal gradients in x and y and the vertical
gradient were calculated 3D Euler deconvolution was tested on the 400 m gridded data using windows of 9 times 9 and
11 times 11 and 16 times 16 data points and structural indices 05 (fault) and 10 (sill or dyke) It was concluded that the
16 times 16 window produced the best results overall and final plots were produced for the 16 times 16 window and structural
index 05 (Fig 44) Results were very good over the northern and central parts of the area showing magnetic sources
Figure 44 Depth to magnetic source 3D Euler deconvolution 16 times 16 window of 400 m gridded data structural index 05
56
at several different levels Unfortunately in the extreme south of the area shallow intrasedimentary magnetic sources
(sills and dykes) dominated the inversion and the results contained few basement solutions
In order to reduce these problems the 400 m gridded data were filtered using a separation filter based on
interpretation of the log-energy spectrum The 3D Euler method was run on the filtered data in order to generate more
basement-depth solutions Results for the deep-separation filter data were gridded and presented as a colour image in
Cowan (1995) Attempts to grid the Euler output were unsatisfactory and it is considered safer to interpret the 3D
Euler depth plots The 3D Euler depth results from the separation-filter run should be analysed with care as perfect
separation of the basement can never be achieved and there will always be some contamination from sources at
different levels
The results of original total magnetic intensity 3D Euler depth estimation for structural index 05 using a 16 point
window have been plotted at 1500 000 scale (not included in this publication but available in Cowan (1995) from the
GSWA Library as S10331) and as reduced A4 colour circle plots (Figure 44)
The results of deep-basement 3D Euler depth estimation for structural index 05 using a 16 point window have
been plotted as a colour image at 1500 000 scale and as an A4 image (not included in this publication)
2D analysis
Two equispaced profiles were interpolated with a 50 m station interval from the AGSO-located data profiles for the
BULLEN 1250 000 sheet The interpolated profiles were analysed using 2D Euler deconvolution and Werner
deconvolution Results are included in Cowan (1995) and show the use of these methods for more detailed analysis
Filtered data
In order to reconcile 3D Euler results from shallow basement and intrasedimentary magnetic sources we produced
several separation-filtered maps and images We found the shallow-layer double-separation filter (Figure 45) to be
very effective for shallow sources and the deep-layer standard-separation filter (Figure 46) for the basement layer
Gravity and magnetic data correlation
Both lsquoreduced to the polersquo (RTP) magnetics (Figure 47) and pseudo-gravity data (Figure 48) were produced as part of
the reconciliation of gravity and magnetic signatures In both cases the filtering operations assumed magnetization by
induction in the present Earths field The RTP data are fairly similar to the total magnetic intensity The pseudo-
57
gravity data are dominated by a northwest-trending strong positive anomaly and there is little correlation with the
Bouguer gravity data
The poor magneticgravity correlation is confirmed by cross-correlation of the RTP magnetics and the gravity
gradient The correlation plot in Figure 49 shows little coherent response with numerous zones of positive and
negative correlation
Figure 45 Regional aeromagnetic data shallow layer separation filter (BMRAGSO data) gridded at 400 m
Results
In the north and east of the area on the Wells Foreland Sub-basin trend (refer to Figure 1 main text) we see a range
of quite deep 3D Euler depths and several trend directions with north-northwesterly dominant There are relatively few
shallow intrasedimentary solutions in this zone
The second area of deep 3D Euler solutions lies over the Blake depocentre (Figure 43) with several trend
directions
Elsewhere the 3D Euler results are dominated by shallow intrasedimentary depth solutions reflecting mainly the
dolerite sills dykes and the ring complex However where we do see basement-related solutions in the south and
west of the area they appear to be shallower than those noted for the Wells Foreland Sub-basin and the Blake
depocentre
58
Figure 46 Regional aeromagnetic data deep-layer separation filter (BMRAGSO data) gridded at 400 m
Figure 48 Regional aeromagnetic data pseudo-gravity transform (BMRAGSO data) gridded at 400 m
Figure 47 Regional aeromagnetic data reduced-to-pole (BMRAGSO data) gridded at 400 m
Figure 49 Regional aeromagnetic and gravity data gravitymagnetic correlation using RTP magnetics and gravity gradient (BMRAGSO data) gridded at 4 km
59
This subdivision of the area into two zones of deep solutions is consistent with interpreted depocentres
However the interference between sources at different levels and the complexity of the magnetic response of the
basement rocks precludes more refined interpretation at this stage
The area of deep 3D Euler solutions over the Blake depocentre correlates with the pronounced negative gravity
anomaly discussed in the gravity interpretation section Using a density contrast of -015 gcc the negative gravity
anomaly could indicate up to 6ndash8 km of low-density sedimentary rocks depending on assumptions about the regional
field
The area of deep 3D Euler solutions over the Wells Foreland Sub-basin has a complex gravity expression and no
clear basin structure emerges from inversion of these data As noted previously it is likely that observed gravity
anomalies reflect contrasts in basement density rather than basement topography
Separation filtering applied to the magnetic data helps to enhance the intrasedimentary magnetic signature and to
give a better impression of the basement magnetic signature even though separation of the basement response is not
perfect
Conclusions
Quantitative aeromagnetic interpretation using 3D Euler deconvolution supported by wavenumber filtering and image
processing has been successful in providing structural trend and depth information for the Savory Sub-basin
Quantitative magnetic interpretation has revealed two zones of relatively deep magnetic basement beneath the
Wells Foreland Sub-basin and the Blake depocentre
This analysis of the magnetic data supports interpreted depocentres but the complexity of the basement magnetic
signature and interference from sources at different depths precludes further refinement to a map of basement
topography
Regional gravity proved to be very useful in understanding the regional setting of the area and in providing
support for aspects of the interpretation The gravity data support the interpretation of the Blake depocentre
suggesting up to 6ndash8 km of low-density sedimentary rocks
The deep structure of the Savory Sub-basin area is obviously complex with different areas underlain by
Archaean and Proterozoic basement and with the Capricorn suture occurring in the centre of the area
60
Recommendations
The quantitative magnetic interpretation needs to be reconciled with geological models available for the area
In particular the zones tentatively identified as areas with thick sedimentary rocks the Wells Foreland Sub-
basin and the Blake depocentre need to be investigated
Cross sections should be prepared across the basin for joint magneticgravity modelling especially for the Blake
depocentre It is important to be able to explain the strong negative gravity anomaly in this area
In view of the effects of basement density contrasts on the gravity field for the northern part of the area we think
that additional gravity interpretation and acquisition of new gravity data may not be justified as they will not
contribute significantly to understanding basin evolution and structure
It is recommended that GSWA try to get access to company confidential high-resolution aeromagnetic data
rather than flying new surveys The GSWA might offer to fund flying of new infill areas as a bargaining point
References
The original text of this report by Cowan (1995) and 1500 000 scale maps are filed in the GSWA Library under
S10331
COWAN D 1995 Savory Basin quantitative magnetic interpretation Western Australia Geological Survey S-series
S10331 (unpublished)
VACQUIER V STEENLAND N C HENDERSON R G and ZIETZ I 1951 Interpretation of aeromagnetic
maps The Geological Society of America Memoir 47 151p
WILLIAMS I R 1992 Geology of the Savory Basin Western Australia Western Australia Geological Survey
Bulletin 141 115p
61
Appendix 5
Geochemistry
MKS38 250398
Saturate FractionC12+ GLC
1217
Pr18
Ph
22
31CSR WELL-13 315m Cuttings
Figure 51 Canning Stock Route Well 13 gas chromatograph of extract of auger drill sample
12
17
18
22
31
Pr Ph
LDDH 1 6623m CoreSaturate FractionC12+ GLC
MKS35 240398
Figure 52 Gas chromatograph of extract from core sample at 6623 m LDDH1
62
Table 51 Canning Stock Route Well 13 auger drill samples
GSWA sample Drill depth (m)(a) Comments
135601 150 At watertable 135602 203 (all samples consist 135603 310 of sand mud and water) 135604 315 At total depth
NOTE (a) Datum for drill depth is the top of sediment fill in the well which is 155 m below ground level (ie the total depth of 315 m is 47 m below ground level)
Table 52 Canning Stock Route Well 13 gas chromatography data for 315 m depth sediment sample
Parameter Value
Weight of rock extracted (grams) 945 Total extract (ppm) 519 n-Alkane distribution n-C12 07 n-C13 23 n-C14 26 n-C15 22 n-C16 19 n-C17 14 i-C19 23 n-C18 14 i-C20 08 n-C19 11 n-C20 16 n-C21 25 n-C22 29 n-C23 70 n-C24 42 n-C25 95 n-C26 43 n-C27 83 n-C28 38 n-C29 87 n-C30 31 n-C31 273 Alkane compositional data Pristane phytane ratio 279 Pristane n-C17 ratio 161 Phytane n-C18 ratio 059 CPI (1)(a) 284 CPI (2) 209 (C21 + C22) (C28 + C29) 043
NOTE (a) CPI= Carbon preference index
63
Table 53 LDDH1 extract liquid chromatography data for 6623 m concentration
Rock extracted Total extract (grams) (ppm)
702 313
NOTE ppm= parts per million
Table 54 LDDH1 saturate gas chromatography data of core for 6623 m alkane composition
Pristane Pristane Phytane (a) CPI (1) CPI (2) (C21+C22) Phytane n-C17 n-C18 (C28+C29)
103 026 024 103 102 325
NOTE (a)CPI = carbon preference index
Table 55 LDDH1 saturate gas chromatography data of core for 6623 m n-alkane distributions
Parameter Value
n-C12 17 n-C13 38 n-C14 55 n-C15 60 n-C16 65 n-C17 74 i-C19 19 n-C18 78 i-C20 19 n-C19 80 n-C20 79 n-C21 71 n-C22 64 n-C23 57 n-C25 43 n-C24 38 n-C27 31 n-C28 23 n-C29 19 n-C30 12 n-C31 10
64
Appendix 6
Table 61 Summary of data from Trainor waterbores (TWB) and Bullen waterbores (BWB)
Well AMG Elevation TD Status(b) Completion details Water Salinity Water level Flow rate Depth to consolidated AGD84 GL (m) (m) struck mgl(c) (m) (LHr) lithology aquifer(e) Z51(a) Interval (m) (100 mm PVC) (m) (mgl)(d)
TWB 1 473660E 453 122 comp 0ndash75 plain 63 7 300 24 2 880 12 m 7287404N 75ndash93 slotted (9 260) McFadden Fm 93ndash99 plain TWB 2 472 977E 475 23 abd nil 15 m 7285877N Skates Hills Fm dry TWB 3 473259E 475 50 abd nil 7 m 7285849N Skates Hills Fm dry TWB 4 463225 E 445 50 comp 0ndash22 plain 35 7 200 55 3 600 0 m 7286143N 22ndash34 slotted (8 140) Tertiary sand and gravel 23ndash60 plain TWB 5 463095E 445 31 comp 0ndash19 plain 13 26 000 655 3 600 Tertiary sand and gravel 7277721N 19ndash25 slotted (36 700) 25ndash31 plain TWB 6 457013E 455 50 comp 0ndash42 plain 38 920 119 600 0 m 7274352N 42ndash48 slotted (1 030) Cornelia Fm ss TWB 7 453739E 475 26 susp 0ndash2 plain 11 9 300 48 4 500 0 m 7263891N (10 500) Tertiary sand TWB 8 433893E 535 60 susp 0ndash2 plain 47 8 500 gt46 1 200 0 m 7245991N (10 900) Tertiary sand and Brassey Range Fm ss TWB 9 437219E 505 51 comp 0ndash47 plain 45 1 000 58 600 1 m 7235905N 47ndash51 slotted (990) Brassey Range Fm ss TWB 10 434927E 495 32 susp 0ndash2 plain 235 450 120 0 m 7225875N (500) Dolerite
65
BWB 1 287337E 580 122 abd Nil 1 m 7245861N Jilyili Fm dry BWB 2 288346E 545 50 comp 0ndash26 plain 15 630 3 29 000 0 m 7240423N 26ndash38 slotted (730) Tertiary sand and gravel 38ndash50 plain BWB 3 305637E 545 50 abd 19 8 800 43 7 200 0 m 7240423N (10 550) Tertiary ss BWB 4 320167E 515 445 comp 0ndash20 plain 9 980 445 24 000 0 m 7248097N 20ndash32 slotted (1 190) Tertiary ss 32ndash44 plain BWB 5 353393E 545 20 susp 0ndash2 plain 45 (970) 1 m 7238934N Basalt
NOTES (a) GPS accuracy ~ 150 m (b) Comp = completed abd = abandoned susp = suspended (c) Salinity from conductivity (d) Analysis total dissolved solids (e) Fm = Formation ss = sandstone
35
References
APAK S N and CARLSEN G M 1997 A compilation and review of data pertaining to the
hydrocarbon prospectivity of the Canning Basin Western Australia Geological Survey
Record 199610 103p
BAGAS L GREY K and WILLIAMS I R 1995 Reappraisal of the Paterson Orogen and
Savory Basin Western Australia Geological Survey Annual Review 1994ndash95 p 55ndash63
BUSBRIDGE M 1994 Lake Disappointment Exploration Licence 451064 Third Annual
Report Lake Disappointment Diamond Drill Hole LDDH1 Normandy Exploration Limited
Western Australia Geological Survey M-series Item 7567 A41358 (unpublished)
CARLSEN G M and SHEVCHENKO S I 1997 Petroleum exploration in Proterozoic basins
using potential fields data and stratigraphic coring Australian Society of Exploration
Geophysicists 12th Geophysical Conference Handbook Sydney 1997 Preview no 66 p 83
(abstract only)
COWAN D 1995 Savory Basin quantitative magnetic interpretation Western Australia
Geological Survey S-series S10331 (unpublished)
DAISHSAT PTY LTD 1995 Operational and processing report Savory Basin gravity survey
Western Australia Geological Survey S-series S10332 (unpublished)
GARD E and GARD R 1990 Canning Stock Route a travellerrsquos guide for a journey through
history Perth Western Australia Western Desert Guides 448p
GEOLOGICAL SURVEY OF WESTERN AUSTRALIA 1996a Savory Basin first vertical
derivative of Bouguer gravity image 1250 000 Western Australia Geological Survey
GEOLOGICAL SURVEY OF WESTERN AUSTRALIA 1996b Savory Basin Bouguer gravity
image 1250 000 Western Australia Geological Survey
GHORI K A R in prep Petroleum source rock potential and thermal history Officer Basin
Western Australia Western Australia Geological Survey Record
36
GREY K 1995a Savory Basin drillhole BWB 1 (Bullen waterbore) palynology and thermal
maturation GSWA Palaeontology Report no 199512 (unpublished)
GREY K 1995b Savory Basin drillholes TWB 1 2 6 9 (Trainor waterbores) palynology and
thermal maturation GSWA Palaeontology Report no 199520 (unpublished)
GREY K 1995c Palynology of Normandy-Poseidon Lake Disappointment-1 corehole
Tarcunyah Group Paterson Orogen GSWA Palaeontology Report no 199521 (unpublished)
GREY K 1995d Savory Basin drillhole Trainor 1 (Trainor diamond drilling) palynology and
thermal maturity GSWA Palaeontology Report no 199524 (unpublished)
GREY K 1995e Savory Basin drillhole Trainor 1 (Trainor diamond drilling) Additional
Preparation of two samples GSWA Palaeontology Report no 199528 (unpublished)
GREY K 1995f Neoproterozoic stromatolites from the Skates Hills Formation Savory Basin
Western Australia and a review of the distribution of Acaciella australica Australian Journal
of Earth Sciences v 42 p 123ndash132
GREY K 1996a Savory Basin drillhole Trainor 1 (Trainor diamond drilling) Additional
samples palynology and thermal maturation GSWA Palaeontology Report no 199615
(unpublished)
GREY K 1996b Preliminary stromatolite correlations for the Neoproterozoic of the Officer
Basin and a review of Australia-wide correlations GSWA Palaeontology Report no 199615
(unpublished)
GREY K and COTTER K L 1996 Palynology in the search for Proterozoic hydrocarbons
Western Australia Geological Survey Annual Review for 1995ndash96 p 70ndash80
GREY K and STEVENS M K 1997 Neoproterozoic palynomorphs of the Savory Sub-basin
Western Australia and their relevance to petroleum exploration Western Australia
Geological Survey Annual Review for 1996ndash97 p 49ndash54
HUBBARD R J PAPE J and ROBERTS D G 1985 Depositional sequence mapping as a
technique to establish tectonic and stratigraphic framework and evaluate hydrocarbon
potential on a passive continental margin in Seismic stratigraphy II an integrated approach
37
edited by O R BERG and D G WOOLVERTON American Association of Petroleum
Geologists Memoir 39 p 79ndash91
LIBBY WG 1995 A petrological report on six samples of bore cuttings from the Savory Basin
Western Australia Western Australia Geological Survey S-series S31307 (unpublished)
MORTON JGG and DREXEL JF 1997 The petroleum geology of South Australia Vol 3
Officer Basin South Australia Department of Mines and Energy Resources Report Book
9719
MUHLING P C and BRAKEL A T 1985 Geology of the Bangemall Group mdash the evolution
of an intracratonic Proterozoic basin Western Australia Geological Survey Bulletin 128
219p
MYERS J S 1990 Precambrian tectonic evolution of part of Gondwana southwestern Australia
Geology v18 p 537ndash540
NELSON D R 1997 Compilation of SHRIMP UndashPb zircon data Western Australia Geological
Survey Record 19972 196p
PAYTON C E 1977 Seismic stratigraphy mdash applications to hydrocarbon exploration
American Association of Petroleum Geologists Memoir 26 516p
PERINCEK D 1996a The age of NeoproterozoicndashPalaeozoic sediments within the Officer Basin
of the Centralian Super-basin can be constrained by major sequence-bounding unconformities
APPEA Journal v 36 pt 1 p 350ndash368
PERINCEK D 1996b The stratigraphic and structural development of the Officer Basin
Western Australia a review Western Australia Geological Survey Annual Review 1995ndash
1996 p 135ndash148
PERINCEK D 1998 A compilation and review of data pertaining to the hydrocarbon
prospectivity of the Officer Basin Western Australia Geological Survey Record 19976
POSAMENTIER H W JERSEY M T and VAIL P R 1988 Eustatic controls on clastic
deposition 1 mdash Conceptual framework in Sea-level changes an integrated approach edited by
C K WILGUS B S HASTINGS C G St C KENDALL H W POSAMENTIER
38
C A ROSS and J C VAN WAGONER Society of Economic Paleontologists and
Mineralogists Special Publication no 42
STEVENS M K and ADAMIDES N G in prep GSWA Trainor 1 well completion report
Savory Sub-basin Officer Basin Western Australia with notes on petroleum and mineral
potential Western Australia Geological Survey Record 199612
STEVENS M K and GREY K 1997 Skates Hills Formation and Tarcunyah Group Officer
Basin mdash carbonate cycles stratigraphic position and hydrocarbon prospectivity Western
Australia Geological Survey Annual Review for 1996ndash97 p 55ndash60
SUMMONS RE and POWELL C McA 1991 Petroleum source rocks of the Amadeus Basin
in Geological and geophysical studies in the Amadeus Basin central Australia edited by R J
KORSCH and JM KENNARD Australia BMR Geology and Geophysics Bulletin 236
TRAVERSE A 1988 Palaeopalynology Boston Unwin Hyman 600p
VAIL P R MITCHUM R M Jr TODD R G WIDMIER J M THOMPSON S III
SANGREE J B BUBB J N and HATLELID W G 1977 Seismic stratigraphy and
global changes of sea level in Seismic stratigraphy mdash applications to hydrocarbon
exploration edited by C E PAYTON American Association of Petroleum Geologists
Memoir 26 516p
WALTER M R and GORTER J 1994 The Neoproterozoic Centralian Superbasin in Western
Australia the Savory and Officer Basins in The sedimentary basins of Western Australia
edited by P G PURCELL and R R PURCELL Petroleum Exploration Society of Australia
Symposium Perth WA 1994 Proceedings p851ndash864
WALTER M R GREY K WILLIAMS I R and CALVER C R 1994 Stratigraphy of the
Neoproterozoic to early Palaeozoic Savory Basin and correlation with the Amadeus and
Officer Basins Australian Journal of Earth Sciences v 41 p 533ndash546
WALTER M R VEEVERS J J CALVER C R and GREY K 1995 Neoproterozoic
stratigraphy of the Centralian Superbasin Australia Precambrian Research v 73 p 173ndash195
WILLIAMS I R 1992 Geology of the Savory Basin Western Australia Western Australia
Geological Survey Bulletin 141 115p
39
WILLIAMS I R 1995a Bullen WA (2nd Edition) Western Australia Geological Survey
1250 000 Geological Series Explanatory Notes 23p
WILLIAMS I R 1995b Trainor WA (2nd Edition) Western Australia Geological Survey
1250 000 Geological Series Explanatory Notes 31p
WILLIAMS I R and TYLER I M 1991 Robertson WA (2nd edition) Western Australia
Geological Survey 1250 000 Geological Series Explanatory Notes 36p
40
41
Appendix 1
Bibliography
Reports which are relevant to this investigation but which are not specifically cited are listed
below
BAILLIE P W POWELL C McA LI Z X and RYALL A M 1994 The tectonic
framework of Western Australiarsquos Neoproterozoic to recent sedimentary basins in The
sedimentary basins of Western Australia edited by P G PURCELL and R R PURCELL
Petroleum Exploration Society of Australia Symposium Perth WA 1994 Proceedings p
45ndash62
BRADSHAW M T BRADSHAW J MURRAY A P NEEDHAM D J SPENCER L
SUMMONS R E WILMOT J and WINN S 1994 Petroleum systems in West Australian
basins in The sedimentary basins of Western Australia edited by P G PURCELL and R R
PURCELL Petroleum Exploration Society of Australia Symposium Perth WA 1994
Proceedings p 93ndash118
CLARKE G L 1991 Proterozoic tectonic reworking in the Rudall Complex Western Australia
Australian Journal of Earth Science v38 p 31ndash44
COCKBAIN A E and HOCKING R M 1990 Phanerozoic in Geology and mineral resources
of Western Australia Western Australia Geological Survey Memoir 3 p 750ndash755
ETHERIDGE M and WALL V 1994 Tectonic and structural evolution of the Australian
Proterozoic 12th Australian Geological Convention Geological Society of Australia
Abstracts no 37 p 102ndash103
GOODE A D T 1981 Proterozoic geology of Western Australia in Precambrian of the
Southern Hemisphere Developments in Precambrian geology 2 edited by I R HUNTER
Amsterdam Elsevier p 105ndash203
GREY K and JACKSON M J 1983 A re-assessment of stromatolite evidence for the
correlation of the Late Proterozoic Neale and Ilma Beds Officer Basin Western Australia
Australia BMR Journal of Australian Geology and Geophysics v 8 p 359
42
HICKMAN A H WILLIAMS I R and BAGAS L 1994 Proterozoic geology and
mineralization of the TelferndashRudall region Paterson Orogen Geological Society of Australia
(WA Division) Excursion Guidebook no 5 56p
HOCKING R M MORY A J and WILLIAMS I R 1994 An atlas of Neoproterozoic and
Phanerozoic basins of Western Australia in The sedimentary basins of Western Australia
edited by P G PURCELL and R R PURCELL Petroleum Exploration Society of Australia
Symposium Perth WA 1994 Proceedings p 21ndash 44
JACKSON P R 1966 Geology and review of exploration Officer Basin Western Australia
Hunt Oil Company Western Australia Geological Survey S-series S26 (unpublished)
JACKSON M J 1971 Notes on a geological reconnaissance of the Officer Basin Western
Australia Australia BMR Geology and Geophysics Record 19715 30p
JACKSON M J and van de GRAAFF W J E 1981 Geology of the Officer Basin Western
Australia Australia BMR Geology and Geophysics Bulletin 206 102 p
LOWRY D C JACKSON M J van de GRAAFF W J E and KENNEWELL P J 1971
Preliminary result of geological mapping in the Officer Basin Western Australia Western
Australia Geological Survey Annual Report for 1971 p 50ndash56
MYERS J S 1990 Precambrian in Geology and mineral resources of Western Australia
Western Australia Geological Survey Memoir 3 p 737ndash750
MYERS J S SHAW R D and TYLER I M 1994 Proterozoic tectonic evolution of
Australia 12th Australian Geological Convention Geological Society of Australia Abstracts
no 37 p 312
NEDIN C and JENKINS R J F 1991 Re-evaluation of unconformities separating the
lsquoEdiacaranrsquo and Cambrian systems South Australia Palaios v 6 p 102ndash108
PHILLIPS B J JAMES A W and PHILIP G M 1985 The geology and hydrocarbon
potential of the north-western Officer Basin APEA Journal 25 (1) p 52ndash61
POWELL C McA LI Z X McELHINNY M W MEERT J G and PARK J K 1993
Paleomagnetic constraints on timing of the Neoproterozoic breakup of Rodinia and Cambrian
formation of Gondwana Geology v 21 p 889ndash892
43
POWELL C McA PREISS W V GATEHOUSE C G KRAPEZ B and LI Z X 1994
South Australian record of a Rodinian epicontinental basin and its mid-Neoproterozoic
breakup to form the Palaeo-Pacific Ocean Tectonophysics v 237 no 3ndash4 p 113ndash140
PREISS W V 1976 Proterozoic stromatolites from the Nabberu and Officer Basins Western
Australia and their biostratigraphic significance South Australia Geological Survey Report
of Investigations no 47 p 1ndash51
TOWNSON W G 1985 The subsurface geology of the western Officer Basin mdash results of
Shellrsquos 1980ndash1984 petroleum exploration campaign APEA Journal v 25 (1) p 34ndash51
WATTS K J 1982 The geology of the Townsend Quartzite Upper Proterozoic shallow water
deposit of the Northern Officer Basin Western Australia Perth University of Western
Australia BSc honours thesis (unpublished)
WELLS A T and KENNEWELL P J 1974 Evaporite exploration in the Officer Basin
Western Australia at the Madley Diapirs Australia BMR Record 1974194 (unpublished)
WILLIAMS I R and MYERS J S 1990 Paterson Orogen in Geology and mineral resources
of Western Australia Western Australia Geological Survey Memoir 3 p 274ndash286
WILLIAMS I R 1990 Savory Basin in Geology and mineral resources of Western Australia
Western Australia Geological Survey Memoir 3 p 329ndash334
WILLIAMS I R 1994 The Neoproterozoic Savory Basin Western Australia in The
sedimentary basins of Western Australia edited by P G PURCELL and R R PURCELL
Petroleum Exploration Society of Australia Symposium Perth WA 1994 Proceedings p
841ndash850
WILSON R B 1967 Woolnough Hills and Madley diapiric structures Gibson Desert WA
APEA Journal v 7 p 94ndash102
44
Appendix 2
Meteorological data (from Bureau of Meteorology Perth 1994)
Table 21 Wiluna rainfall (mm)
Year Jan Feb Mar Apr May Jun Jul Aug Sept Oct Nov Dec
1975 0 45 446 309 306 59 276 4 34 886 638 164 1976 16 154 12 138 53 16 34 62 12 238 0 2 1977 44 0 66 74 68 95 24 363 1 58 12 727 1978 234 522 94 16 0 96 367 24 16 353 185 45 1979 19 173 122 88 91 4 0 246 58 0 169 114 1980 148 764 68 1081 259 626 629 06 56 02 174 0 1981 123 476 192 32 196 118 44 74 14 0 28 312 1982 374 705 206 244 1079 92 02 143 368 526 368 118 1983 1 112 928 248 0 212 56 32 5 1 42 496 1984 149 7 342 84 836 0 348 132 224 04 16 172 1985 596 483 0 166 556 0 514 56 0 0 4 0 1986 0 154 35 0 0 1085 23 01 239 137 0 04 1987 1204 119 19 89 17 575 154 126 07 1 0 398 1988 46 202 164 13 388 0 202 104 0 0 224 1309 1989 207 234 26 703 278 536 57 0 01 0 144 02 1990 1035 23 281 46 126 53 94 218 44 9 42 0 1991 48 0 41 45 0 472 297 12 0 1 0 7 1992 112 96 1025 1227 323 65 04 174 0 132 48 4 1993 0 697 0 202 445 0 12 306 18 05 14 33 Mean 25 35 22 27 27 25 18 12 6 13 13 21
JAN FEB MAR APR MAY JUN JUL AUG SEP OCT NOV DEC0
10
20
30
40
Mea
n R
ain
fall
(mm
)
Month
Mean monthly rainfall in Wiluna
MKS41 140498
45
Table 22 Wiluna minimum temperature (degC)
Year Jan Feb Mar Apr May Jun Jul Aug Sept Oct Nov Dec
1975 ndash 23 203 15 94 63 71 62 103 124 169 205 1976 242 229 194 15 10 63 59 73 95 143 16 228 1977 243 25 197 148 96 95 56 86 102 ndash 188 23 1978 241 232 203 18 102 64 76 8 9 152 19 205 1979 255 226 216 167 83 6 59 79 97 145 198 223 1980 255 226 231 155 134 83 68 75 121 108 193 223 1981 245 216 19 182 119 6 54 78 138 159 163 218 1982 232 224 177 16 ndash ndash 37 111 112 164 209 225 1983 235 24 197 147 112 88 39 88 121 162 189 219 1984 241 243 191 156 ndash 72 66 7 95 161 182 211 1985 244 231 ndash 159 98 65 71 73 117 147 205 ndash 1986 ndash 229 226 155 93 96 43 49 10 122 ndash 219 1987 ndash 217 183 175 85 77 68 68 112 ndash ndash 221 1988 238 214 209 178 111 ndash ndash 86 104 157 171 195 1989 ndash 237 199 165 107 67 44 61 107 131 187 ndash 1990 232 ndash 211 155 118 62 57 87 102 149 195 22 1991 26 256 217 168 122 101 78 ndash 113 18 168 219 1992 227 227 214 169 102 98 59 69 ndash 125 159 196 1993 241 218 196 171 103 ndash 49 68 88 128 192 211 Mean 24 23 20 16 10 8 6 8 11 14 18 21
NOTE Dashes indicate data unavailable
JAN FEB MAR APR MAY JUN JUL AUG SEP OCT NOV DEC0
10
20
30
40
Month
MKS43 140498
50
Mean monthly minimum temperatures at Wiluna
Mea
n T
emp
erat
ure
(degC
)
46
Table 23 Wiluna maximum temperature (degC)
Year Jan Feb Mar Apr May Jun Jul Aug Sept Oct Nov Dec
1975 ndash 349 326 281 247 201 197 212 256 248 31 344 1976 374 369 346 297 248 206 208 225 265 287 313 388 1977 397 392 352 296 234 212 222 244 ndash 308 337 383 1978 378 345 346 316 242 195 176 205 231 295 334 356 1979 403 36 364 295 ndash ndash ndash 193 242 318 359 373 1980 392 342 377 275 24 176 179 233 292 288 349 391 1981 385 346 337 342 242 178 201 224 30 326 326 369 1982 372 359 315 307 ndash ndash 196 253 252 305 353 379 1983 381 389 327 272 263 222 187 248 287 321 336 366 1984 378 393 322 299 226 215 178 214 234 ndash 336 364 1985 40 366 ndash 294 224 216 205 212 284 307 355 ndash 1986 ndash 383 372 307 ndash 193 166 196 261 277 ndash 382 1987 ndash 339 328 305 21 202 214 218 275 ndash ndash 374 1988 388 365 353 301 23 ndash ndash 228 283 334 31 33 1989 ndash 375 339 285 238 179 181 219 275 298 336 ndash 1990 368 ndash 36 309 268 19 188 205 274 309 373 393 1991 414 416 363 315 268 206 21 ndash 279 338 332 368 1992 363 383 336 263 213 178 213 197 ndash 285 313 359 1993 396 357 344 301 221 ndash 197 215 253 294 347 362 Mean 39 37 34 30 24 20 20 22 27 30 34 37 NOTE Dashes indicate data unavailable
JAN FEB MAR APR MAY JUN JUL AUG SEP OCT NOV DEC0
10
20
30
40
Month
MKS42 140498
50
Mean monthly maximum temperatures at Wiluna
Mea
n T
emp
erat
ure
(degC
)
47
Appendix 3
Table 31 Summary of palynological results
Drillhole Depth (m) F no(a) GSWA no Lithology Formation Assemblage TAI(b)
BWB 1 74ndash75 F49668 135741 dark-grey siltstone basalt Jilyilli gt5 BWB 1 98ndash100 F49669 135742 dark-grey siltstone basalt Jilyilli gt5 BWB 1 121ndash122 F49670 135743 dark-grey siltstone basalt Jilyilli gt5 TWB 1 86ndash87 F49671 135631 dark-grey siltstone McFadden 3+ TWB 1 104ndash105 F49672 135632 dark-grey siltstone Cornelia 3+ TWB 1 121ndash122 F49673 135633 dark-grey siltstone Cornelia 4 TWB 2 14ndash15 F49674 135634 dark-grey siltstone Skates Hills 3+ TWB 6 49ndash50 F49675 135675 dark-grey siltstone Cornelia 1 3+ TWB 9 49ndash51 F49676 135704 dark-grey siltstone Brassey Range 1 3+ Trainor 1 37497- F49733 138939 black mudstone with Cornelia 5 37509 light-grey siltstone Trainor 1 3809 F49734 138940 dark-grey and black Cornelia 4- laminated mudstone Trainor 1 4170 F49735 138941 black unlaminated mudstone Cornelia 4- Trainor 1 4950 F49851 139501 dark-grey indurated siltstone Cornelia 5 Trainor 1 6032 F49852 139502 dark- and light-grey Cornelia 5 indurated siltstone Trainor 1 6434 F49853 139503 greenish indurated finely Cornelia 5 laminated siltstone LDDH 1 270 F49678 138934 dark-grey siltstone interbeds Waters 1 3+ in enterolithic evaporite Tarcunyah Gp LDDH 1 277 F49679 138935 dark-grey siltstone in cavity Waters 1 3+ in enterolithic evaporite Tarcunyah Gp
NOTES (a) GSWA Fossil Catalogue number (b) TAI = Thermal Alteration Index of Traverse (1988 plate 1)
48
Appendix 4
Savory Sub-basin quantitative magnetic and gravity interpretation (extracted from Cowan 1995)
Summary
A program of quantitative aeromagnetic interpretation has been completed on BMRAGSO data from the Savory Sub-
basin Western Australia Quantitative aeromagnetic interpretation utilized the 3D Euler deconvolution method
supported by wavenumber filtering and image processing The results have provided useful information on structural
trends and depth to magnetic sources in a structurally complex area Depth to magnetic source analysis has provided
information on intra-sedimentary magnetic sources as well as basement rocks
The results of the interpretation support previously identified depocentres However the presence of magnetic
sources at several levels makes it very difficult to produce a reliable magnetic basement depth contour map It is
considered more productive to work with the 3D Euler colour circle plots and images rather than trying to contour the
results It would be necessary to carry out a full-scale interpretation of the BMRAGSO profile data to improve on the
3D Euler results The regional gravity was found to be useful in interpreting the regional setting of the area although
the very wide data spacing limits quantitative use of the data The gravity data show quite a complex picture with
limited consistent correlation between gravity features and basin structures This suggests that gravity anomalies
reflect changes in density of the basement rocks rather than basement topography especially in the northern part of the
basin
It is recommended that the GSWA investigate access to company confidential high-resolution aeromagnetic data
prior to planning further aeromagnetic surveys Private companies have flown large parts of the northern half of the
area as part of their diamond exploration program Additional gravity coverage of the area may be more cost effective
than magnetic surveys as the gravity data provides more information on changes within the sedimentary section
Introduction
The main use of aeromagnetic data in petroleum exploration has been the determination of magnetic basement
topography although there has been increasing interest in analysis of intra-sedimentary magnetic anomalies
intrabasement and suprabasement magnetic anomalies These anomalies are used to determine depth to magnetic
basement rocks and hence determine the thickness of the sedimentary sequence Unfortunately interpretation of the
intrabasement and suprabasement magnetic anomalies is non-unique in terms of position and size of causative sources
because of the inherent ambiguity of potential-field methods However this ambiguity can be reduced by placing
49
constraints on source geometry and magnetization and by using geological and other geophysical data to constrain
the solution
Before 1970 most depth-determination techniques involved graphical determination of slopes of selected
magnetic anomalies and application of various empirical factors to convert the slopes into depth estimates Geological
Society of America Memoir 47 Interpretation of Aeromagnetic Maps by Vacquier et al (1951) was a landmark for
this type of interpretation
Automated interpretation procedures have played an increasingly important role in depth interpretation and a
wide range of techniques have been developed Many of these techniques are designed for application to located data
profiles and assume a two-dimensional geometry However there has been renewed interest in techniques applicable
to gridded data
Two distinct types of method can be recognized In the first case often described as discrete methods individual
isolated magnetic anomalies are interpreted and the results used to produce a map of basement relief In the second
case often described as continuous methods areas of data containing a number of anomalies are interpreted
statistically to produce direct output of basement depths
The discrete methods usually involve a semiautomatic initial phase which generates a large number of possible
depth solutions and an interactive second phase to screen and select acceptable solutions The advantage of this
approach is that the interpreter can select features that are relatively free from interference from adjacent anomalies
and consider all aspects of a particular magnetic anomaly The disadvantage is that interpretation can be very time
consuming as a wide range of depths are usually possible depending on the initial model chosen and a significant
amount of effort is needed to select the correct model In the case of the Savory Sub-basin dataset we encountered
problems in separating basement related effects from the effects of shallower intrasedimentary magnetic sources
Because of these problems we have concentrated on displaying the Euler results accompanied by separation filter
images of the data to show the shallower effects and deeper effects rather than trying to refine a 3D Euler
deconvolution depth-to-crystalline-basement contour
The continuous methods are very direct provided that the rather restrictive assumption can be made that all
anomalies are due to lateral magnetization changes due to basement topography This means that shallow effects and
large intrabasement anomalies must be removed from the data This involves judgement and skill as it is necessary to
distinguish between the lower amplitude suprabasement anomalies due to basement topography and the larger
intrabasement anomalies reflecting magnetization changes within the basement These methods were not considered
suitable for the Savory Sub-basin magnetic dataset but were used to invert the gravity data
50
Limitations of magnetic and gravity interpretation
Interpretation of the area is limited by a shortage of information on the nature and physical properties of the deeper
sedimentary sequence and the underlying basement rocks However using techniques such as cross-correlation of
gravity and pseudo-gravity data it is possible to try to differentiate between anomalies relating to basement and those
related to the sedimentary sequence
Gravity anomalies reflect changes within the sedimentary sequence as well as basement condition These
changes in density of sedimentary rocks produce gravity anomalies without a corresponding magnetic anomaly hence
the complementary nature of gravity and magnetic surveys The main use of magnetics is to determine depth to
magnetic basement and any intra-sedimentary volcanic rocks or intrusives whereas gravity provides much more
general information on the sedimentary sequence
Unfortunately interpretation of gravity anomalies is complicated since they can be due to a number of geological
features including
bull major basement faults
bull basement highs
bull igneous intrusions within the basement
bull sedimentary basins which may or may not be isostatically compensated
bull intra-sedimentary volcanics and associated plutonic centres
Two major problems affect the interpretation of both magnetic and gravity data
1 The inherent ambiguity of potential-field data There is no unique solution to any measured gravity or magnetic
anomaly and theoretically there will be an infinite number of source geometry and magnetizationdensity
combinations which will fit the observed data This means that any a priori information which helps to select a
suitable model is very useful
2 Measured anomalies are the summation of effects from different depths For example an observed gravity profile
may contain contributions from shallow sources (density variations within the sedimentary basin) intermediate
depth sources (density variations due to large igneous intrusions within the basement) and deep sources (crustal
thinning producing a mantle anomaly) Separation of these component responses is the regionalresidual problem
which we solve using spectral analysis and differential upward continuation-based separation filtering
Regional setting and interpretation overview
The area studied includes parts of BALFOUR DOWNS (SF51-9) RUDALL (SF51-10) ROBERTSON (SF51-13) GUNANYA
(SF51-14) COLLIER (SG50-4) BULLEN (SG51-1) TRAINOR (SG51-2) MADLEY (SG51-3) NABBERU (SG50-5)
STANLEY (SG51-6) and HERBERT (SG51-7) 1250 000 sheets Broadly the area lies between latitudes 22deg00rsquondash25deg30rsquoS
and longitudes 119deg30rsquondash123deg30rsquoE
51
Regional gravity
The AGSO regional gravity data (at nominal 11 km spacing) was gridded at a 4 km mesh spacing using a minimum-
curvature algorithm Bouguer gravity values in the area are negative reflecting mass deficiency at depth and range
from -84 mgals to -25 mgals
A Bouguer gravity colour image is shown as Figure 41 A residual grid was produced by removing a fifth-order
orthogonal polynomial from the Bouguer data but did not add to the interpretation
120deg 121deg 122deg 123deg
23deg
24deg
25deg
-25
-84
50 km
MKS46 180598
mgal
Figure 41 Regional Bouguer gravity (BMRAGSO data) gridded at 4 km
52
The data show a complex pattern of positive and negative anomalies with no clearly defined trends Correlations
with aeromagnetic data and known basin structures are poor A vague north-northwest linear trend appears to coincide
with the Marloo Fault (Figure 42) A prominent negative anomaly appears to coincide with the Blake Fold and Fault
Belt depocentre and continues as a narrower negative anomaly to the east until it widens out again near the edge of the
basin Elsewhere the gravity data show little correlation with known basin structures and it is likely that especially in
the north of the area gravity anomalies are due to density changes in the basement rather than changes in basement
topography
Production of wavelength-filtered residual gravity plots and vertical gradient plots showed very patchy aliased
data reflecting poor sampling in much of the area
Regional magnetics
The AGSO regional aeromagnetic data were gridded at a 400 m mesh spacing using a minimum-curvature algorithm
(Figure 43) Most of the data has a line spacing of 1600 m with small areas of 1 km spacing The quality of the data is
acceptable for regional interpretation but is not adequate for detailed analysis The accuracy of the flight path is rather
variable reflecting the vintage of the data and the noise envelope of the data is poor by modern standards Problems
were also encountered in joining different map sheets
The magnetic anomaly pattern over the south and west part of the area shows a strong high frequency signature
reflecting the presence of widespread basic sills and dykes Some of the major north-northeasterly trending dykes can
be traced over considerable distances
Discontinuous high-frequency anomalies extend as a northwest-trending zone through the centre of the area and
this zone includes a conspicuous circular magnetic anomaly which is probably a ring complex
The northern and eastern parts of the area are characterized by long-wavelength deep-seated basement magnetic
anomalies with 120deg and 150deg trends dominant The Marloo and Perentie Faults (Figure 42) appear as distinct linear
zones and offsets A prominent easterly trending negative anomaly in the northwest of the area appears to swing round
to the southeast and may separate different basement blocks One possible interpretation is that this very deep seated
anomaly separates areas of Archaean and Proterozoic basement
Regional geology
The regional geology is described in Williams (1992) The GSWA provided a digitized version of Plate 2 from this
Bulletin the structural interpretation map to use as an overlay (Figure 42)
53
Pp
Pp
PSd
PSd
PSd
PSd
PSd
PSo
PSt
PSt
PSf
PSf
PSf
PSb
PSb
PSb
PSsPSs
PSs
PSb
PSm
PSp
PSc
PSc
PSw
PSw
PSw
PSg
PSr
PSj
PSg
PM
Pk
PY
PY
PSd
L
L
L
L
L
L
L
LL
L
L
L
LL
L
LL
L L
LL
L L
L
L
L
L
L
L
L
LL
L
L
BLAKEDEPOCENTRE
MA
RLO
O
FAU
LT
PERENTIEFAULT
50 km
MKS39120598
120deg 121deg 122deg 123deg
25deg
24deg
23deg
Approximate boundaryof aeromagnetic interpretation
PML
PSgL
PSjL
PML
PSpL
PML
PML
PSfL
PSfL
PSpL
LPc
LPcLPcPSrL
LPA
Durba Sandstone
Woora Woora Formation
McFadden Formation
Tchukardine Formation
Boondawari Formation
Skates Hills Formation
Mundadjini Formation
Coondra Formation
Spearhole Formation
Watch Point Formation
Jilyili Formation
Brassey Range Formation
Glass Spring Formation
Paterson Formation
Yeneena Group
Karara Formation
Cornelia Formation
Kahrban Subgroup
Bangemall Group
Fault
Formation boundary
PSdL
PSoL
PSfL
PStL
PSbL
PSsL
PSmL
PScL
PSpL
PSwL
PSjL
PSrL
PSgL
Pp
PYL
PkL
LPc
LPA
PML
Savory Group Other Units
PYL
Figure 42 Regional geology and structure map (after Williams 1992)
54
120deg 121deg 122deg 123deg
23deg
24deg
25deg
5820
3750
MKS47 180598
nT
50 km
Figure 43 Regional aeromagnetic data total magnetic intensity (BMRAGSO data) gridded at 400 m
Analysis
3D analysis
3D Euler deconvolution was used as the primary depth-determination method The advantage of this approach is that
consistent solutions can be obtained over the entire area with minimal assumptions about source geometries Euler
deconvolution of gridded data is used for positional information and estimation of depth to top of source Euler
55
deconvolution yields a large number of depth solutions which have to be screened to reject spurious solutions Results
are plotted as circles in eight depth ranges with radius proportional to depth and colour coded
The 400 m total magnetic intensity grid was used for the analysis Horizontal gradients in x and y and the vertical
gradient were calculated 3D Euler deconvolution was tested on the 400 m gridded data using windows of 9 times 9 and
11 times 11 and 16 times 16 data points and structural indices 05 (fault) and 10 (sill or dyke) It was concluded that the
16 times 16 window produced the best results overall and final plots were produced for the 16 times 16 window and structural
index 05 (Fig 44) Results were very good over the northern and central parts of the area showing magnetic sources
Figure 44 Depth to magnetic source 3D Euler deconvolution 16 times 16 window of 400 m gridded data structural index 05
56
at several different levels Unfortunately in the extreme south of the area shallow intrasedimentary magnetic sources
(sills and dykes) dominated the inversion and the results contained few basement solutions
In order to reduce these problems the 400 m gridded data were filtered using a separation filter based on
interpretation of the log-energy spectrum The 3D Euler method was run on the filtered data in order to generate more
basement-depth solutions Results for the deep-separation filter data were gridded and presented as a colour image in
Cowan (1995) Attempts to grid the Euler output were unsatisfactory and it is considered safer to interpret the 3D
Euler depth plots The 3D Euler depth results from the separation-filter run should be analysed with care as perfect
separation of the basement can never be achieved and there will always be some contamination from sources at
different levels
The results of original total magnetic intensity 3D Euler depth estimation for structural index 05 using a 16 point
window have been plotted at 1500 000 scale (not included in this publication but available in Cowan (1995) from the
GSWA Library as S10331) and as reduced A4 colour circle plots (Figure 44)
The results of deep-basement 3D Euler depth estimation for structural index 05 using a 16 point window have
been plotted as a colour image at 1500 000 scale and as an A4 image (not included in this publication)
2D analysis
Two equispaced profiles were interpolated with a 50 m station interval from the AGSO-located data profiles for the
BULLEN 1250 000 sheet The interpolated profiles were analysed using 2D Euler deconvolution and Werner
deconvolution Results are included in Cowan (1995) and show the use of these methods for more detailed analysis
Filtered data
In order to reconcile 3D Euler results from shallow basement and intrasedimentary magnetic sources we produced
several separation-filtered maps and images We found the shallow-layer double-separation filter (Figure 45) to be
very effective for shallow sources and the deep-layer standard-separation filter (Figure 46) for the basement layer
Gravity and magnetic data correlation
Both lsquoreduced to the polersquo (RTP) magnetics (Figure 47) and pseudo-gravity data (Figure 48) were produced as part of
the reconciliation of gravity and magnetic signatures In both cases the filtering operations assumed magnetization by
induction in the present Earths field The RTP data are fairly similar to the total magnetic intensity The pseudo-
57
gravity data are dominated by a northwest-trending strong positive anomaly and there is little correlation with the
Bouguer gravity data
The poor magneticgravity correlation is confirmed by cross-correlation of the RTP magnetics and the gravity
gradient The correlation plot in Figure 49 shows little coherent response with numerous zones of positive and
negative correlation
Figure 45 Regional aeromagnetic data shallow layer separation filter (BMRAGSO data) gridded at 400 m
Results
In the north and east of the area on the Wells Foreland Sub-basin trend (refer to Figure 1 main text) we see a range
of quite deep 3D Euler depths and several trend directions with north-northwesterly dominant There are relatively few
shallow intrasedimentary solutions in this zone
The second area of deep 3D Euler solutions lies over the Blake depocentre (Figure 43) with several trend
directions
Elsewhere the 3D Euler results are dominated by shallow intrasedimentary depth solutions reflecting mainly the
dolerite sills dykes and the ring complex However where we do see basement-related solutions in the south and
west of the area they appear to be shallower than those noted for the Wells Foreland Sub-basin and the Blake
depocentre
58
Figure 46 Regional aeromagnetic data deep-layer separation filter (BMRAGSO data) gridded at 400 m
Figure 48 Regional aeromagnetic data pseudo-gravity transform (BMRAGSO data) gridded at 400 m
Figure 47 Regional aeromagnetic data reduced-to-pole (BMRAGSO data) gridded at 400 m
Figure 49 Regional aeromagnetic and gravity data gravitymagnetic correlation using RTP magnetics and gravity gradient (BMRAGSO data) gridded at 4 km
59
This subdivision of the area into two zones of deep solutions is consistent with interpreted depocentres
However the interference between sources at different levels and the complexity of the magnetic response of the
basement rocks precludes more refined interpretation at this stage
The area of deep 3D Euler solutions over the Blake depocentre correlates with the pronounced negative gravity
anomaly discussed in the gravity interpretation section Using a density contrast of -015 gcc the negative gravity
anomaly could indicate up to 6ndash8 km of low-density sedimentary rocks depending on assumptions about the regional
field
The area of deep 3D Euler solutions over the Wells Foreland Sub-basin has a complex gravity expression and no
clear basin structure emerges from inversion of these data As noted previously it is likely that observed gravity
anomalies reflect contrasts in basement density rather than basement topography
Separation filtering applied to the magnetic data helps to enhance the intrasedimentary magnetic signature and to
give a better impression of the basement magnetic signature even though separation of the basement response is not
perfect
Conclusions
Quantitative aeromagnetic interpretation using 3D Euler deconvolution supported by wavenumber filtering and image
processing has been successful in providing structural trend and depth information for the Savory Sub-basin
Quantitative magnetic interpretation has revealed two zones of relatively deep magnetic basement beneath the
Wells Foreland Sub-basin and the Blake depocentre
This analysis of the magnetic data supports interpreted depocentres but the complexity of the basement magnetic
signature and interference from sources at different depths precludes further refinement to a map of basement
topography
Regional gravity proved to be very useful in understanding the regional setting of the area and in providing
support for aspects of the interpretation The gravity data support the interpretation of the Blake depocentre
suggesting up to 6ndash8 km of low-density sedimentary rocks
The deep structure of the Savory Sub-basin area is obviously complex with different areas underlain by
Archaean and Proterozoic basement and with the Capricorn suture occurring in the centre of the area
60
Recommendations
The quantitative magnetic interpretation needs to be reconciled with geological models available for the area
In particular the zones tentatively identified as areas with thick sedimentary rocks the Wells Foreland Sub-
basin and the Blake depocentre need to be investigated
Cross sections should be prepared across the basin for joint magneticgravity modelling especially for the Blake
depocentre It is important to be able to explain the strong negative gravity anomaly in this area
In view of the effects of basement density contrasts on the gravity field for the northern part of the area we think
that additional gravity interpretation and acquisition of new gravity data may not be justified as they will not
contribute significantly to understanding basin evolution and structure
It is recommended that GSWA try to get access to company confidential high-resolution aeromagnetic data
rather than flying new surveys The GSWA might offer to fund flying of new infill areas as a bargaining point
References
The original text of this report by Cowan (1995) and 1500 000 scale maps are filed in the GSWA Library under
S10331
COWAN D 1995 Savory Basin quantitative magnetic interpretation Western Australia Geological Survey S-series
S10331 (unpublished)
VACQUIER V STEENLAND N C HENDERSON R G and ZIETZ I 1951 Interpretation of aeromagnetic
maps The Geological Society of America Memoir 47 151p
WILLIAMS I R 1992 Geology of the Savory Basin Western Australia Western Australia Geological Survey
Bulletin 141 115p
61
Appendix 5
Geochemistry
MKS38 250398
Saturate FractionC12+ GLC
1217
Pr18
Ph
22
31CSR WELL-13 315m Cuttings
Figure 51 Canning Stock Route Well 13 gas chromatograph of extract of auger drill sample
12
17
18
22
31
Pr Ph
LDDH 1 6623m CoreSaturate FractionC12+ GLC
MKS35 240398
Figure 52 Gas chromatograph of extract from core sample at 6623 m LDDH1
62
Table 51 Canning Stock Route Well 13 auger drill samples
GSWA sample Drill depth (m)(a) Comments
135601 150 At watertable 135602 203 (all samples consist 135603 310 of sand mud and water) 135604 315 At total depth
NOTE (a) Datum for drill depth is the top of sediment fill in the well which is 155 m below ground level (ie the total depth of 315 m is 47 m below ground level)
Table 52 Canning Stock Route Well 13 gas chromatography data for 315 m depth sediment sample
Parameter Value
Weight of rock extracted (grams) 945 Total extract (ppm) 519 n-Alkane distribution n-C12 07 n-C13 23 n-C14 26 n-C15 22 n-C16 19 n-C17 14 i-C19 23 n-C18 14 i-C20 08 n-C19 11 n-C20 16 n-C21 25 n-C22 29 n-C23 70 n-C24 42 n-C25 95 n-C26 43 n-C27 83 n-C28 38 n-C29 87 n-C30 31 n-C31 273 Alkane compositional data Pristane phytane ratio 279 Pristane n-C17 ratio 161 Phytane n-C18 ratio 059 CPI (1)(a) 284 CPI (2) 209 (C21 + C22) (C28 + C29) 043
NOTE (a) CPI= Carbon preference index
63
Table 53 LDDH1 extract liquid chromatography data for 6623 m concentration
Rock extracted Total extract (grams) (ppm)
702 313
NOTE ppm= parts per million
Table 54 LDDH1 saturate gas chromatography data of core for 6623 m alkane composition
Pristane Pristane Phytane (a) CPI (1) CPI (2) (C21+C22) Phytane n-C17 n-C18 (C28+C29)
103 026 024 103 102 325
NOTE (a)CPI = carbon preference index
Table 55 LDDH1 saturate gas chromatography data of core for 6623 m n-alkane distributions
Parameter Value
n-C12 17 n-C13 38 n-C14 55 n-C15 60 n-C16 65 n-C17 74 i-C19 19 n-C18 78 i-C20 19 n-C19 80 n-C20 79 n-C21 71 n-C22 64 n-C23 57 n-C25 43 n-C24 38 n-C27 31 n-C28 23 n-C29 19 n-C30 12 n-C31 10
64
Appendix 6
Table 61 Summary of data from Trainor waterbores (TWB) and Bullen waterbores (BWB)
Well AMG Elevation TD Status(b) Completion details Water Salinity Water level Flow rate Depth to consolidated AGD84 GL (m) (m) struck mgl(c) (m) (LHr) lithology aquifer(e) Z51(a) Interval (m) (100 mm PVC) (m) (mgl)(d)
TWB 1 473660E 453 122 comp 0ndash75 plain 63 7 300 24 2 880 12 m 7287404N 75ndash93 slotted (9 260) McFadden Fm 93ndash99 plain TWB 2 472 977E 475 23 abd nil 15 m 7285877N Skates Hills Fm dry TWB 3 473259E 475 50 abd nil 7 m 7285849N Skates Hills Fm dry TWB 4 463225 E 445 50 comp 0ndash22 plain 35 7 200 55 3 600 0 m 7286143N 22ndash34 slotted (8 140) Tertiary sand and gravel 23ndash60 plain TWB 5 463095E 445 31 comp 0ndash19 plain 13 26 000 655 3 600 Tertiary sand and gravel 7277721N 19ndash25 slotted (36 700) 25ndash31 plain TWB 6 457013E 455 50 comp 0ndash42 plain 38 920 119 600 0 m 7274352N 42ndash48 slotted (1 030) Cornelia Fm ss TWB 7 453739E 475 26 susp 0ndash2 plain 11 9 300 48 4 500 0 m 7263891N (10 500) Tertiary sand TWB 8 433893E 535 60 susp 0ndash2 plain 47 8 500 gt46 1 200 0 m 7245991N (10 900) Tertiary sand and Brassey Range Fm ss TWB 9 437219E 505 51 comp 0ndash47 plain 45 1 000 58 600 1 m 7235905N 47ndash51 slotted (990) Brassey Range Fm ss TWB 10 434927E 495 32 susp 0ndash2 plain 235 450 120 0 m 7225875N (500) Dolerite
65
BWB 1 287337E 580 122 abd Nil 1 m 7245861N Jilyili Fm dry BWB 2 288346E 545 50 comp 0ndash26 plain 15 630 3 29 000 0 m 7240423N 26ndash38 slotted (730) Tertiary sand and gravel 38ndash50 plain BWB 3 305637E 545 50 abd 19 8 800 43 7 200 0 m 7240423N (10 550) Tertiary ss BWB 4 320167E 515 445 comp 0ndash20 plain 9 980 445 24 000 0 m 7248097N 20ndash32 slotted (1 190) Tertiary ss 32ndash44 plain BWB 5 353393E 545 20 susp 0ndash2 plain 45 (970) 1 m 7238934N Basalt
NOTES (a) GPS accuracy ~ 150 m (b) Comp = completed abd = abandoned susp = suspended (c) Salinity from conductivity (d) Analysis total dissolved solids (e) Fm = Formation ss = sandstone
36
GREY K 1995a Savory Basin drillhole BWB 1 (Bullen waterbore) palynology and thermal
maturation GSWA Palaeontology Report no 199512 (unpublished)
GREY K 1995b Savory Basin drillholes TWB 1 2 6 9 (Trainor waterbores) palynology and
thermal maturation GSWA Palaeontology Report no 199520 (unpublished)
GREY K 1995c Palynology of Normandy-Poseidon Lake Disappointment-1 corehole
Tarcunyah Group Paterson Orogen GSWA Palaeontology Report no 199521 (unpublished)
GREY K 1995d Savory Basin drillhole Trainor 1 (Trainor diamond drilling) palynology and
thermal maturity GSWA Palaeontology Report no 199524 (unpublished)
GREY K 1995e Savory Basin drillhole Trainor 1 (Trainor diamond drilling) Additional
Preparation of two samples GSWA Palaeontology Report no 199528 (unpublished)
GREY K 1995f Neoproterozoic stromatolites from the Skates Hills Formation Savory Basin
Western Australia and a review of the distribution of Acaciella australica Australian Journal
of Earth Sciences v 42 p 123ndash132
GREY K 1996a Savory Basin drillhole Trainor 1 (Trainor diamond drilling) Additional
samples palynology and thermal maturation GSWA Palaeontology Report no 199615
(unpublished)
GREY K 1996b Preliminary stromatolite correlations for the Neoproterozoic of the Officer
Basin and a review of Australia-wide correlations GSWA Palaeontology Report no 199615
(unpublished)
GREY K and COTTER K L 1996 Palynology in the search for Proterozoic hydrocarbons
Western Australia Geological Survey Annual Review for 1995ndash96 p 70ndash80
GREY K and STEVENS M K 1997 Neoproterozoic palynomorphs of the Savory Sub-basin
Western Australia and their relevance to petroleum exploration Western Australia
Geological Survey Annual Review for 1996ndash97 p 49ndash54
HUBBARD R J PAPE J and ROBERTS D G 1985 Depositional sequence mapping as a
technique to establish tectonic and stratigraphic framework and evaluate hydrocarbon
potential on a passive continental margin in Seismic stratigraphy II an integrated approach
37
edited by O R BERG and D G WOOLVERTON American Association of Petroleum
Geologists Memoir 39 p 79ndash91
LIBBY WG 1995 A petrological report on six samples of bore cuttings from the Savory Basin
Western Australia Western Australia Geological Survey S-series S31307 (unpublished)
MORTON JGG and DREXEL JF 1997 The petroleum geology of South Australia Vol 3
Officer Basin South Australia Department of Mines and Energy Resources Report Book
9719
MUHLING P C and BRAKEL A T 1985 Geology of the Bangemall Group mdash the evolution
of an intracratonic Proterozoic basin Western Australia Geological Survey Bulletin 128
219p
MYERS J S 1990 Precambrian tectonic evolution of part of Gondwana southwestern Australia
Geology v18 p 537ndash540
NELSON D R 1997 Compilation of SHRIMP UndashPb zircon data Western Australia Geological
Survey Record 19972 196p
PAYTON C E 1977 Seismic stratigraphy mdash applications to hydrocarbon exploration
American Association of Petroleum Geologists Memoir 26 516p
PERINCEK D 1996a The age of NeoproterozoicndashPalaeozoic sediments within the Officer Basin
of the Centralian Super-basin can be constrained by major sequence-bounding unconformities
APPEA Journal v 36 pt 1 p 350ndash368
PERINCEK D 1996b The stratigraphic and structural development of the Officer Basin
Western Australia a review Western Australia Geological Survey Annual Review 1995ndash
1996 p 135ndash148
PERINCEK D 1998 A compilation and review of data pertaining to the hydrocarbon
prospectivity of the Officer Basin Western Australia Geological Survey Record 19976
POSAMENTIER H W JERSEY M T and VAIL P R 1988 Eustatic controls on clastic
deposition 1 mdash Conceptual framework in Sea-level changes an integrated approach edited by
C K WILGUS B S HASTINGS C G St C KENDALL H W POSAMENTIER
38
C A ROSS and J C VAN WAGONER Society of Economic Paleontologists and
Mineralogists Special Publication no 42
STEVENS M K and ADAMIDES N G in prep GSWA Trainor 1 well completion report
Savory Sub-basin Officer Basin Western Australia with notes on petroleum and mineral
potential Western Australia Geological Survey Record 199612
STEVENS M K and GREY K 1997 Skates Hills Formation and Tarcunyah Group Officer
Basin mdash carbonate cycles stratigraphic position and hydrocarbon prospectivity Western
Australia Geological Survey Annual Review for 1996ndash97 p 55ndash60
SUMMONS RE and POWELL C McA 1991 Petroleum source rocks of the Amadeus Basin
in Geological and geophysical studies in the Amadeus Basin central Australia edited by R J
KORSCH and JM KENNARD Australia BMR Geology and Geophysics Bulletin 236
TRAVERSE A 1988 Palaeopalynology Boston Unwin Hyman 600p
VAIL P R MITCHUM R M Jr TODD R G WIDMIER J M THOMPSON S III
SANGREE J B BUBB J N and HATLELID W G 1977 Seismic stratigraphy and
global changes of sea level in Seismic stratigraphy mdash applications to hydrocarbon
exploration edited by C E PAYTON American Association of Petroleum Geologists
Memoir 26 516p
WALTER M R and GORTER J 1994 The Neoproterozoic Centralian Superbasin in Western
Australia the Savory and Officer Basins in The sedimentary basins of Western Australia
edited by P G PURCELL and R R PURCELL Petroleum Exploration Society of Australia
Symposium Perth WA 1994 Proceedings p851ndash864
WALTER M R GREY K WILLIAMS I R and CALVER C R 1994 Stratigraphy of the
Neoproterozoic to early Palaeozoic Savory Basin and correlation with the Amadeus and
Officer Basins Australian Journal of Earth Sciences v 41 p 533ndash546
WALTER M R VEEVERS J J CALVER C R and GREY K 1995 Neoproterozoic
stratigraphy of the Centralian Superbasin Australia Precambrian Research v 73 p 173ndash195
WILLIAMS I R 1992 Geology of the Savory Basin Western Australia Western Australia
Geological Survey Bulletin 141 115p
39
WILLIAMS I R 1995a Bullen WA (2nd Edition) Western Australia Geological Survey
1250 000 Geological Series Explanatory Notes 23p
WILLIAMS I R 1995b Trainor WA (2nd Edition) Western Australia Geological Survey
1250 000 Geological Series Explanatory Notes 31p
WILLIAMS I R and TYLER I M 1991 Robertson WA (2nd edition) Western Australia
Geological Survey 1250 000 Geological Series Explanatory Notes 36p
40
41
Appendix 1
Bibliography
Reports which are relevant to this investigation but which are not specifically cited are listed
below
BAILLIE P W POWELL C McA LI Z X and RYALL A M 1994 The tectonic
framework of Western Australiarsquos Neoproterozoic to recent sedimentary basins in The
sedimentary basins of Western Australia edited by P G PURCELL and R R PURCELL
Petroleum Exploration Society of Australia Symposium Perth WA 1994 Proceedings p
45ndash62
BRADSHAW M T BRADSHAW J MURRAY A P NEEDHAM D J SPENCER L
SUMMONS R E WILMOT J and WINN S 1994 Petroleum systems in West Australian
basins in The sedimentary basins of Western Australia edited by P G PURCELL and R R
PURCELL Petroleum Exploration Society of Australia Symposium Perth WA 1994
Proceedings p 93ndash118
CLARKE G L 1991 Proterozoic tectonic reworking in the Rudall Complex Western Australia
Australian Journal of Earth Science v38 p 31ndash44
COCKBAIN A E and HOCKING R M 1990 Phanerozoic in Geology and mineral resources
of Western Australia Western Australia Geological Survey Memoir 3 p 750ndash755
ETHERIDGE M and WALL V 1994 Tectonic and structural evolution of the Australian
Proterozoic 12th Australian Geological Convention Geological Society of Australia
Abstracts no 37 p 102ndash103
GOODE A D T 1981 Proterozoic geology of Western Australia in Precambrian of the
Southern Hemisphere Developments in Precambrian geology 2 edited by I R HUNTER
Amsterdam Elsevier p 105ndash203
GREY K and JACKSON M J 1983 A re-assessment of stromatolite evidence for the
correlation of the Late Proterozoic Neale and Ilma Beds Officer Basin Western Australia
Australia BMR Journal of Australian Geology and Geophysics v 8 p 359
42
HICKMAN A H WILLIAMS I R and BAGAS L 1994 Proterozoic geology and
mineralization of the TelferndashRudall region Paterson Orogen Geological Society of Australia
(WA Division) Excursion Guidebook no 5 56p
HOCKING R M MORY A J and WILLIAMS I R 1994 An atlas of Neoproterozoic and
Phanerozoic basins of Western Australia in The sedimentary basins of Western Australia
edited by P G PURCELL and R R PURCELL Petroleum Exploration Society of Australia
Symposium Perth WA 1994 Proceedings p 21ndash 44
JACKSON P R 1966 Geology and review of exploration Officer Basin Western Australia
Hunt Oil Company Western Australia Geological Survey S-series S26 (unpublished)
JACKSON M J 1971 Notes on a geological reconnaissance of the Officer Basin Western
Australia Australia BMR Geology and Geophysics Record 19715 30p
JACKSON M J and van de GRAAFF W J E 1981 Geology of the Officer Basin Western
Australia Australia BMR Geology and Geophysics Bulletin 206 102 p
LOWRY D C JACKSON M J van de GRAAFF W J E and KENNEWELL P J 1971
Preliminary result of geological mapping in the Officer Basin Western Australia Western
Australia Geological Survey Annual Report for 1971 p 50ndash56
MYERS J S 1990 Precambrian in Geology and mineral resources of Western Australia
Western Australia Geological Survey Memoir 3 p 737ndash750
MYERS J S SHAW R D and TYLER I M 1994 Proterozoic tectonic evolution of
Australia 12th Australian Geological Convention Geological Society of Australia Abstracts
no 37 p 312
NEDIN C and JENKINS R J F 1991 Re-evaluation of unconformities separating the
lsquoEdiacaranrsquo and Cambrian systems South Australia Palaios v 6 p 102ndash108
PHILLIPS B J JAMES A W and PHILIP G M 1985 The geology and hydrocarbon
potential of the north-western Officer Basin APEA Journal 25 (1) p 52ndash61
POWELL C McA LI Z X McELHINNY M W MEERT J G and PARK J K 1993
Paleomagnetic constraints on timing of the Neoproterozoic breakup of Rodinia and Cambrian
formation of Gondwana Geology v 21 p 889ndash892
43
POWELL C McA PREISS W V GATEHOUSE C G KRAPEZ B and LI Z X 1994
South Australian record of a Rodinian epicontinental basin and its mid-Neoproterozoic
breakup to form the Palaeo-Pacific Ocean Tectonophysics v 237 no 3ndash4 p 113ndash140
PREISS W V 1976 Proterozoic stromatolites from the Nabberu and Officer Basins Western
Australia and their biostratigraphic significance South Australia Geological Survey Report
of Investigations no 47 p 1ndash51
TOWNSON W G 1985 The subsurface geology of the western Officer Basin mdash results of
Shellrsquos 1980ndash1984 petroleum exploration campaign APEA Journal v 25 (1) p 34ndash51
WATTS K J 1982 The geology of the Townsend Quartzite Upper Proterozoic shallow water
deposit of the Northern Officer Basin Western Australia Perth University of Western
Australia BSc honours thesis (unpublished)
WELLS A T and KENNEWELL P J 1974 Evaporite exploration in the Officer Basin
Western Australia at the Madley Diapirs Australia BMR Record 1974194 (unpublished)
WILLIAMS I R and MYERS J S 1990 Paterson Orogen in Geology and mineral resources
of Western Australia Western Australia Geological Survey Memoir 3 p 274ndash286
WILLIAMS I R 1990 Savory Basin in Geology and mineral resources of Western Australia
Western Australia Geological Survey Memoir 3 p 329ndash334
WILLIAMS I R 1994 The Neoproterozoic Savory Basin Western Australia in The
sedimentary basins of Western Australia edited by P G PURCELL and R R PURCELL
Petroleum Exploration Society of Australia Symposium Perth WA 1994 Proceedings p
841ndash850
WILSON R B 1967 Woolnough Hills and Madley diapiric structures Gibson Desert WA
APEA Journal v 7 p 94ndash102
44
Appendix 2
Meteorological data (from Bureau of Meteorology Perth 1994)
Table 21 Wiluna rainfall (mm)
Year Jan Feb Mar Apr May Jun Jul Aug Sept Oct Nov Dec
1975 0 45 446 309 306 59 276 4 34 886 638 164 1976 16 154 12 138 53 16 34 62 12 238 0 2 1977 44 0 66 74 68 95 24 363 1 58 12 727 1978 234 522 94 16 0 96 367 24 16 353 185 45 1979 19 173 122 88 91 4 0 246 58 0 169 114 1980 148 764 68 1081 259 626 629 06 56 02 174 0 1981 123 476 192 32 196 118 44 74 14 0 28 312 1982 374 705 206 244 1079 92 02 143 368 526 368 118 1983 1 112 928 248 0 212 56 32 5 1 42 496 1984 149 7 342 84 836 0 348 132 224 04 16 172 1985 596 483 0 166 556 0 514 56 0 0 4 0 1986 0 154 35 0 0 1085 23 01 239 137 0 04 1987 1204 119 19 89 17 575 154 126 07 1 0 398 1988 46 202 164 13 388 0 202 104 0 0 224 1309 1989 207 234 26 703 278 536 57 0 01 0 144 02 1990 1035 23 281 46 126 53 94 218 44 9 42 0 1991 48 0 41 45 0 472 297 12 0 1 0 7 1992 112 96 1025 1227 323 65 04 174 0 132 48 4 1993 0 697 0 202 445 0 12 306 18 05 14 33 Mean 25 35 22 27 27 25 18 12 6 13 13 21
JAN FEB MAR APR MAY JUN JUL AUG SEP OCT NOV DEC0
10
20
30
40
Mea
n R
ain
fall
(mm
)
Month
Mean monthly rainfall in Wiluna
MKS41 140498
45
Table 22 Wiluna minimum temperature (degC)
Year Jan Feb Mar Apr May Jun Jul Aug Sept Oct Nov Dec
1975 ndash 23 203 15 94 63 71 62 103 124 169 205 1976 242 229 194 15 10 63 59 73 95 143 16 228 1977 243 25 197 148 96 95 56 86 102 ndash 188 23 1978 241 232 203 18 102 64 76 8 9 152 19 205 1979 255 226 216 167 83 6 59 79 97 145 198 223 1980 255 226 231 155 134 83 68 75 121 108 193 223 1981 245 216 19 182 119 6 54 78 138 159 163 218 1982 232 224 177 16 ndash ndash 37 111 112 164 209 225 1983 235 24 197 147 112 88 39 88 121 162 189 219 1984 241 243 191 156 ndash 72 66 7 95 161 182 211 1985 244 231 ndash 159 98 65 71 73 117 147 205 ndash 1986 ndash 229 226 155 93 96 43 49 10 122 ndash 219 1987 ndash 217 183 175 85 77 68 68 112 ndash ndash 221 1988 238 214 209 178 111 ndash ndash 86 104 157 171 195 1989 ndash 237 199 165 107 67 44 61 107 131 187 ndash 1990 232 ndash 211 155 118 62 57 87 102 149 195 22 1991 26 256 217 168 122 101 78 ndash 113 18 168 219 1992 227 227 214 169 102 98 59 69 ndash 125 159 196 1993 241 218 196 171 103 ndash 49 68 88 128 192 211 Mean 24 23 20 16 10 8 6 8 11 14 18 21
NOTE Dashes indicate data unavailable
JAN FEB MAR APR MAY JUN JUL AUG SEP OCT NOV DEC0
10
20
30
40
Month
MKS43 140498
50
Mean monthly minimum temperatures at Wiluna
Mea
n T
emp
erat
ure
(degC
)
46
Table 23 Wiluna maximum temperature (degC)
Year Jan Feb Mar Apr May Jun Jul Aug Sept Oct Nov Dec
1975 ndash 349 326 281 247 201 197 212 256 248 31 344 1976 374 369 346 297 248 206 208 225 265 287 313 388 1977 397 392 352 296 234 212 222 244 ndash 308 337 383 1978 378 345 346 316 242 195 176 205 231 295 334 356 1979 403 36 364 295 ndash ndash ndash 193 242 318 359 373 1980 392 342 377 275 24 176 179 233 292 288 349 391 1981 385 346 337 342 242 178 201 224 30 326 326 369 1982 372 359 315 307 ndash ndash 196 253 252 305 353 379 1983 381 389 327 272 263 222 187 248 287 321 336 366 1984 378 393 322 299 226 215 178 214 234 ndash 336 364 1985 40 366 ndash 294 224 216 205 212 284 307 355 ndash 1986 ndash 383 372 307 ndash 193 166 196 261 277 ndash 382 1987 ndash 339 328 305 21 202 214 218 275 ndash ndash 374 1988 388 365 353 301 23 ndash ndash 228 283 334 31 33 1989 ndash 375 339 285 238 179 181 219 275 298 336 ndash 1990 368 ndash 36 309 268 19 188 205 274 309 373 393 1991 414 416 363 315 268 206 21 ndash 279 338 332 368 1992 363 383 336 263 213 178 213 197 ndash 285 313 359 1993 396 357 344 301 221 ndash 197 215 253 294 347 362 Mean 39 37 34 30 24 20 20 22 27 30 34 37 NOTE Dashes indicate data unavailable
JAN FEB MAR APR MAY JUN JUL AUG SEP OCT NOV DEC0
10
20
30
40
Month
MKS42 140498
50
Mean monthly maximum temperatures at Wiluna
Mea
n T
emp
erat
ure
(degC
)
47
Appendix 3
Table 31 Summary of palynological results
Drillhole Depth (m) F no(a) GSWA no Lithology Formation Assemblage TAI(b)
BWB 1 74ndash75 F49668 135741 dark-grey siltstone basalt Jilyilli gt5 BWB 1 98ndash100 F49669 135742 dark-grey siltstone basalt Jilyilli gt5 BWB 1 121ndash122 F49670 135743 dark-grey siltstone basalt Jilyilli gt5 TWB 1 86ndash87 F49671 135631 dark-grey siltstone McFadden 3+ TWB 1 104ndash105 F49672 135632 dark-grey siltstone Cornelia 3+ TWB 1 121ndash122 F49673 135633 dark-grey siltstone Cornelia 4 TWB 2 14ndash15 F49674 135634 dark-grey siltstone Skates Hills 3+ TWB 6 49ndash50 F49675 135675 dark-grey siltstone Cornelia 1 3+ TWB 9 49ndash51 F49676 135704 dark-grey siltstone Brassey Range 1 3+ Trainor 1 37497- F49733 138939 black mudstone with Cornelia 5 37509 light-grey siltstone Trainor 1 3809 F49734 138940 dark-grey and black Cornelia 4- laminated mudstone Trainor 1 4170 F49735 138941 black unlaminated mudstone Cornelia 4- Trainor 1 4950 F49851 139501 dark-grey indurated siltstone Cornelia 5 Trainor 1 6032 F49852 139502 dark- and light-grey Cornelia 5 indurated siltstone Trainor 1 6434 F49853 139503 greenish indurated finely Cornelia 5 laminated siltstone LDDH 1 270 F49678 138934 dark-grey siltstone interbeds Waters 1 3+ in enterolithic evaporite Tarcunyah Gp LDDH 1 277 F49679 138935 dark-grey siltstone in cavity Waters 1 3+ in enterolithic evaporite Tarcunyah Gp
NOTES (a) GSWA Fossil Catalogue number (b) TAI = Thermal Alteration Index of Traverse (1988 plate 1)
48
Appendix 4
Savory Sub-basin quantitative magnetic and gravity interpretation (extracted from Cowan 1995)
Summary
A program of quantitative aeromagnetic interpretation has been completed on BMRAGSO data from the Savory Sub-
basin Western Australia Quantitative aeromagnetic interpretation utilized the 3D Euler deconvolution method
supported by wavenumber filtering and image processing The results have provided useful information on structural
trends and depth to magnetic sources in a structurally complex area Depth to magnetic source analysis has provided
information on intra-sedimentary magnetic sources as well as basement rocks
The results of the interpretation support previously identified depocentres However the presence of magnetic
sources at several levels makes it very difficult to produce a reliable magnetic basement depth contour map It is
considered more productive to work with the 3D Euler colour circle plots and images rather than trying to contour the
results It would be necessary to carry out a full-scale interpretation of the BMRAGSO profile data to improve on the
3D Euler results The regional gravity was found to be useful in interpreting the regional setting of the area although
the very wide data spacing limits quantitative use of the data The gravity data show quite a complex picture with
limited consistent correlation between gravity features and basin structures This suggests that gravity anomalies
reflect changes in density of the basement rocks rather than basement topography especially in the northern part of the
basin
It is recommended that the GSWA investigate access to company confidential high-resolution aeromagnetic data
prior to planning further aeromagnetic surveys Private companies have flown large parts of the northern half of the
area as part of their diamond exploration program Additional gravity coverage of the area may be more cost effective
than magnetic surveys as the gravity data provides more information on changes within the sedimentary section
Introduction
The main use of aeromagnetic data in petroleum exploration has been the determination of magnetic basement
topography although there has been increasing interest in analysis of intra-sedimentary magnetic anomalies
intrabasement and suprabasement magnetic anomalies These anomalies are used to determine depth to magnetic
basement rocks and hence determine the thickness of the sedimentary sequence Unfortunately interpretation of the
intrabasement and suprabasement magnetic anomalies is non-unique in terms of position and size of causative sources
because of the inherent ambiguity of potential-field methods However this ambiguity can be reduced by placing
49
constraints on source geometry and magnetization and by using geological and other geophysical data to constrain
the solution
Before 1970 most depth-determination techniques involved graphical determination of slopes of selected
magnetic anomalies and application of various empirical factors to convert the slopes into depth estimates Geological
Society of America Memoir 47 Interpretation of Aeromagnetic Maps by Vacquier et al (1951) was a landmark for
this type of interpretation
Automated interpretation procedures have played an increasingly important role in depth interpretation and a
wide range of techniques have been developed Many of these techniques are designed for application to located data
profiles and assume a two-dimensional geometry However there has been renewed interest in techniques applicable
to gridded data
Two distinct types of method can be recognized In the first case often described as discrete methods individual
isolated magnetic anomalies are interpreted and the results used to produce a map of basement relief In the second
case often described as continuous methods areas of data containing a number of anomalies are interpreted
statistically to produce direct output of basement depths
The discrete methods usually involve a semiautomatic initial phase which generates a large number of possible
depth solutions and an interactive second phase to screen and select acceptable solutions The advantage of this
approach is that the interpreter can select features that are relatively free from interference from adjacent anomalies
and consider all aspects of a particular magnetic anomaly The disadvantage is that interpretation can be very time
consuming as a wide range of depths are usually possible depending on the initial model chosen and a significant
amount of effort is needed to select the correct model In the case of the Savory Sub-basin dataset we encountered
problems in separating basement related effects from the effects of shallower intrasedimentary magnetic sources
Because of these problems we have concentrated on displaying the Euler results accompanied by separation filter
images of the data to show the shallower effects and deeper effects rather than trying to refine a 3D Euler
deconvolution depth-to-crystalline-basement contour
The continuous methods are very direct provided that the rather restrictive assumption can be made that all
anomalies are due to lateral magnetization changes due to basement topography This means that shallow effects and
large intrabasement anomalies must be removed from the data This involves judgement and skill as it is necessary to
distinguish between the lower amplitude suprabasement anomalies due to basement topography and the larger
intrabasement anomalies reflecting magnetization changes within the basement These methods were not considered
suitable for the Savory Sub-basin magnetic dataset but were used to invert the gravity data
50
Limitations of magnetic and gravity interpretation
Interpretation of the area is limited by a shortage of information on the nature and physical properties of the deeper
sedimentary sequence and the underlying basement rocks However using techniques such as cross-correlation of
gravity and pseudo-gravity data it is possible to try to differentiate between anomalies relating to basement and those
related to the sedimentary sequence
Gravity anomalies reflect changes within the sedimentary sequence as well as basement condition These
changes in density of sedimentary rocks produce gravity anomalies without a corresponding magnetic anomaly hence
the complementary nature of gravity and magnetic surveys The main use of magnetics is to determine depth to
magnetic basement and any intra-sedimentary volcanic rocks or intrusives whereas gravity provides much more
general information on the sedimentary sequence
Unfortunately interpretation of gravity anomalies is complicated since they can be due to a number of geological
features including
bull major basement faults
bull basement highs
bull igneous intrusions within the basement
bull sedimentary basins which may or may not be isostatically compensated
bull intra-sedimentary volcanics and associated plutonic centres
Two major problems affect the interpretation of both magnetic and gravity data
1 The inherent ambiguity of potential-field data There is no unique solution to any measured gravity or magnetic
anomaly and theoretically there will be an infinite number of source geometry and magnetizationdensity
combinations which will fit the observed data This means that any a priori information which helps to select a
suitable model is very useful
2 Measured anomalies are the summation of effects from different depths For example an observed gravity profile
may contain contributions from shallow sources (density variations within the sedimentary basin) intermediate
depth sources (density variations due to large igneous intrusions within the basement) and deep sources (crustal
thinning producing a mantle anomaly) Separation of these component responses is the regionalresidual problem
which we solve using spectral analysis and differential upward continuation-based separation filtering
Regional setting and interpretation overview
The area studied includes parts of BALFOUR DOWNS (SF51-9) RUDALL (SF51-10) ROBERTSON (SF51-13) GUNANYA
(SF51-14) COLLIER (SG50-4) BULLEN (SG51-1) TRAINOR (SG51-2) MADLEY (SG51-3) NABBERU (SG50-5)
STANLEY (SG51-6) and HERBERT (SG51-7) 1250 000 sheets Broadly the area lies between latitudes 22deg00rsquondash25deg30rsquoS
and longitudes 119deg30rsquondash123deg30rsquoE
51
Regional gravity
The AGSO regional gravity data (at nominal 11 km spacing) was gridded at a 4 km mesh spacing using a minimum-
curvature algorithm Bouguer gravity values in the area are negative reflecting mass deficiency at depth and range
from -84 mgals to -25 mgals
A Bouguer gravity colour image is shown as Figure 41 A residual grid was produced by removing a fifth-order
orthogonal polynomial from the Bouguer data but did not add to the interpretation
120deg 121deg 122deg 123deg
23deg
24deg
25deg
-25
-84
50 km
MKS46 180598
mgal
Figure 41 Regional Bouguer gravity (BMRAGSO data) gridded at 4 km
52
The data show a complex pattern of positive and negative anomalies with no clearly defined trends Correlations
with aeromagnetic data and known basin structures are poor A vague north-northwest linear trend appears to coincide
with the Marloo Fault (Figure 42) A prominent negative anomaly appears to coincide with the Blake Fold and Fault
Belt depocentre and continues as a narrower negative anomaly to the east until it widens out again near the edge of the
basin Elsewhere the gravity data show little correlation with known basin structures and it is likely that especially in
the north of the area gravity anomalies are due to density changes in the basement rather than changes in basement
topography
Production of wavelength-filtered residual gravity plots and vertical gradient plots showed very patchy aliased
data reflecting poor sampling in much of the area
Regional magnetics
The AGSO regional aeromagnetic data were gridded at a 400 m mesh spacing using a minimum-curvature algorithm
(Figure 43) Most of the data has a line spacing of 1600 m with small areas of 1 km spacing The quality of the data is
acceptable for regional interpretation but is not adequate for detailed analysis The accuracy of the flight path is rather
variable reflecting the vintage of the data and the noise envelope of the data is poor by modern standards Problems
were also encountered in joining different map sheets
The magnetic anomaly pattern over the south and west part of the area shows a strong high frequency signature
reflecting the presence of widespread basic sills and dykes Some of the major north-northeasterly trending dykes can
be traced over considerable distances
Discontinuous high-frequency anomalies extend as a northwest-trending zone through the centre of the area and
this zone includes a conspicuous circular magnetic anomaly which is probably a ring complex
The northern and eastern parts of the area are characterized by long-wavelength deep-seated basement magnetic
anomalies with 120deg and 150deg trends dominant The Marloo and Perentie Faults (Figure 42) appear as distinct linear
zones and offsets A prominent easterly trending negative anomaly in the northwest of the area appears to swing round
to the southeast and may separate different basement blocks One possible interpretation is that this very deep seated
anomaly separates areas of Archaean and Proterozoic basement
Regional geology
The regional geology is described in Williams (1992) The GSWA provided a digitized version of Plate 2 from this
Bulletin the structural interpretation map to use as an overlay (Figure 42)
53
Pp
Pp
PSd
PSd
PSd
PSd
PSd
PSo
PSt
PSt
PSf
PSf
PSf
PSb
PSb
PSb
PSsPSs
PSs
PSb
PSm
PSp
PSc
PSc
PSw
PSw
PSw
PSg
PSr
PSj
PSg
PM
Pk
PY
PY
PSd
L
L
L
L
L
L
L
LL
L
L
L
LL
L
LL
L L
LL
L L
L
L
L
L
L
L
L
LL
L
L
BLAKEDEPOCENTRE
MA
RLO
O
FAU
LT
PERENTIEFAULT
50 km
MKS39120598
120deg 121deg 122deg 123deg
25deg
24deg
23deg
Approximate boundaryof aeromagnetic interpretation
PML
PSgL
PSjL
PML
PSpL
PML
PML
PSfL
PSfL
PSpL
LPc
LPcLPcPSrL
LPA
Durba Sandstone
Woora Woora Formation
McFadden Formation
Tchukardine Formation
Boondawari Formation
Skates Hills Formation
Mundadjini Formation
Coondra Formation
Spearhole Formation
Watch Point Formation
Jilyili Formation
Brassey Range Formation
Glass Spring Formation
Paterson Formation
Yeneena Group
Karara Formation
Cornelia Formation
Kahrban Subgroup
Bangemall Group
Fault
Formation boundary
PSdL
PSoL
PSfL
PStL
PSbL
PSsL
PSmL
PScL
PSpL
PSwL
PSjL
PSrL
PSgL
Pp
PYL
PkL
LPc
LPA
PML
Savory Group Other Units
PYL
Figure 42 Regional geology and structure map (after Williams 1992)
54
120deg 121deg 122deg 123deg
23deg
24deg
25deg
5820
3750
MKS47 180598
nT
50 km
Figure 43 Regional aeromagnetic data total magnetic intensity (BMRAGSO data) gridded at 400 m
Analysis
3D analysis
3D Euler deconvolution was used as the primary depth-determination method The advantage of this approach is that
consistent solutions can be obtained over the entire area with minimal assumptions about source geometries Euler
deconvolution of gridded data is used for positional information and estimation of depth to top of source Euler
55
deconvolution yields a large number of depth solutions which have to be screened to reject spurious solutions Results
are plotted as circles in eight depth ranges with radius proportional to depth and colour coded
The 400 m total magnetic intensity grid was used for the analysis Horizontal gradients in x and y and the vertical
gradient were calculated 3D Euler deconvolution was tested on the 400 m gridded data using windows of 9 times 9 and
11 times 11 and 16 times 16 data points and structural indices 05 (fault) and 10 (sill or dyke) It was concluded that the
16 times 16 window produced the best results overall and final plots were produced for the 16 times 16 window and structural
index 05 (Fig 44) Results were very good over the northern and central parts of the area showing magnetic sources
Figure 44 Depth to magnetic source 3D Euler deconvolution 16 times 16 window of 400 m gridded data structural index 05
56
at several different levels Unfortunately in the extreme south of the area shallow intrasedimentary magnetic sources
(sills and dykes) dominated the inversion and the results contained few basement solutions
In order to reduce these problems the 400 m gridded data were filtered using a separation filter based on
interpretation of the log-energy spectrum The 3D Euler method was run on the filtered data in order to generate more
basement-depth solutions Results for the deep-separation filter data were gridded and presented as a colour image in
Cowan (1995) Attempts to grid the Euler output were unsatisfactory and it is considered safer to interpret the 3D
Euler depth plots The 3D Euler depth results from the separation-filter run should be analysed with care as perfect
separation of the basement can never be achieved and there will always be some contamination from sources at
different levels
The results of original total magnetic intensity 3D Euler depth estimation for structural index 05 using a 16 point
window have been plotted at 1500 000 scale (not included in this publication but available in Cowan (1995) from the
GSWA Library as S10331) and as reduced A4 colour circle plots (Figure 44)
The results of deep-basement 3D Euler depth estimation for structural index 05 using a 16 point window have
been plotted as a colour image at 1500 000 scale and as an A4 image (not included in this publication)
2D analysis
Two equispaced profiles were interpolated with a 50 m station interval from the AGSO-located data profiles for the
BULLEN 1250 000 sheet The interpolated profiles were analysed using 2D Euler deconvolution and Werner
deconvolution Results are included in Cowan (1995) and show the use of these methods for more detailed analysis
Filtered data
In order to reconcile 3D Euler results from shallow basement and intrasedimentary magnetic sources we produced
several separation-filtered maps and images We found the shallow-layer double-separation filter (Figure 45) to be
very effective for shallow sources and the deep-layer standard-separation filter (Figure 46) for the basement layer
Gravity and magnetic data correlation
Both lsquoreduced to the polersquo (RTP) magnetics (Figure 47) and pseudo-gravity data (Figure 48) were produced as part of
the reconciliation of gravity and magnetic signatures In both cases the filtering operations assumed magnetization by
induction in the present Earths field The RTP data are fairly similar to the total magnetic intensity The pseudo-
57
gravity data are dominated by a northwest-trending strong positive anomaly and there is little correlation with the
Bouguer gravity data
The poor magneticgravity correlation is confirmed by cross-correlation of the RTP magnetics and the gravity
gradient The correlation plot in Figure 49 shows little coherent response with numerous zones of positive and
negative correlation
Figure 45 Regional aeromagnetic data shallow layer separation filter (BMRAGSO data) gridded at 400 m
Results
In the north and east of the area on the Wells Foreland Sub-basin trend (refer to Figure 1 main text) we see a range
of quite deep 3D Euler depths and several trend directions with north-northwesterly dominant There are relatively few
shallow intrasedimentary solutions in this zone
The second area of deep 3D Euler solutions lies over the Blake depocentre (Figure 43) with several trend
directions
Elsewhere the 3D Euler results are dominated by shallow intrasedimentary depth solutions reflecting mainly the
dolerite sills dykes and the ring complex However where we do see basement-related solutions in the south and
west of the area they appear to be shallower than those noted for the Wells Foreland Sub-basin and the Blake
depocentre
58
Figure 46 Regional aeromagnetic data deep-layer separation filter (BMRAGSO data) gridded at 400 m
Figure 48 Regional aeromagnetic data pseudo-gravity transform (BMRAGSO data) gridded at 400 m
Figure 47 Regional aeromagnetic data reduced-to-pole (BMRAGSO data) gridded at 400 m
Figure 49 Regional aeromagnetic and gravity data gravitymagnetic correlation using RTP magnetics and gravity gradient (BMRAGSO data) gridded at 4 km
59
This subdivision of the area into two zones of deep solutions is consistent with interpreted depocentres
However the interference between sources at different levels and the complexity of the magnetic response of the
basement rocks precludes more refined interpretation at this stage
The area of deep 3D Euler solutions over the Blake depocentre correlates with the pronounced negative gravity
anomaly discussed in the gravity interpretation section Using a density contrast of -015 gcc the negative gravity
anomaly could indicate up to 6ndash8 km of low-density sedimentary rocks depending on assumptions about the regional
field
The area of deep 3D Euler solutions over the Wells Foreland Sub-basin has a complex gravity expression and no
clear basin structure emerges from inversion of these data As noted previously it is likely that observed gravity
anomalies reflect contrasts in basement density rather than basement topography
Separation filtering applied to the magnetic data helps to enhance the intrasedimentary magnetic signature and to
give a better impression of the basement magnetic signature even though separation of the basement response is not
perfect
Conclusions
Quantitative aeromagnetic interpretation using 3D Euler deconvolution supported by wavenumber filtering and image
processing has been successful in providing structural trend and depth information for the Savory Sub-basin
Quantitative magnetic interpretation has revealed two zones of relatively deep magnetic basement beneath the
Wells Foreland Sub-basin and the Blake depocentre
This analysis of the magnetic data supports interpreted depocentres but the complexity of the basement magnetic
signature and interference from sources at different depths precludes further refinement to a map of basement
topography
Regional gravity proved to be very useful in understanding the regional setting of the area and in providing
support for aspects of the interpretation The gravity data support the interpretation of the Blake depocentre
suggesting up to 6ndash8 km of low-density sedimentary rocks
The deep structure of the Savory Sub-basin area is obviously complex with different areas underlain by
Archaean and Proterozoic basement and with the Capricorn suture occurring in the centre of the area
60
Recommendations
The quantitative magnetic interpretation needs to be reconciled with geological models available for the area
In particular the zones tentatively identified as areas with thick sedimentary rocks the Wells Foreland Sub-
basin and the Blake depocentre need to be investigated
Cross sections should be prepared across the basin for joint magneticgravity modelling especially for the Blake
depocentre It is important to be able to explain the strong negative gravity anomaly in this area
In view of the effects of basement density contrasts on the gravity field for the northern part of the area we think
that additional gravity interpretation and acquisition of new gravity data may not be justified as they will not
contribute significantly to understanding basin evolution and structure
It is recommended that GSWA try to get access to company confidential high-resolution aeromagnetic data
rather than flying new surveys The GSWA might offer to fund flying of new infill areas as a bargaining point
References
The original text of this report by Cowan (1995) and 1500 000 scale maps are filed in the GSWA Library under
S10331
COWAN D 1995 Savory Basin quantitative magnetic interpretation Western Australia Geological Survey S-series
S10331 (unpublished)
VACQUIER V STEENLAND N C HENDERSON R G and ZIETZ I 1951 Interpretation of aeromagnetic
maps The Geological Society of America Memoir 47 151p
WILLIAMS I R 1992 Geology of the Savory Basin Western Australia Western Australia Geological Survey
Bulletin 141 115p
61
Appendix 5
Geochemistry
MKS38 250398
Saturate FractionC12+ GLC
1217
Pr18
Ph
22
31CSR WELL-13 315m Cuttings
Figure 51 Canning Stock Route Well 13 gas chromatograph of extract of auger drill sample
12
17
18
22
31
Pr Ph
LDDH 1 6623m CoreSaturate FractionC12+ GLC
MKS35 240398
Figure 52 Gas chromatograph of extract from core sample at 6623 m LDDH1
62
Table 51 Canning Stock Route Well 13 auger drill samples
GSWA sample Drill depth (m)(a) Comments
135601 150 At watertable 135602 203 (all samples consist 135603 310 of sand mud and water) 135604 315 At total depth
NOTE (a) Datum for drill depth is the top of sediment fill in the well which is 155 m below ground level (ie the total depth of 315 m is 47 m below ground level)
Table 52 Canning Stock Route Well 13 gas chromatography data for 315 m depth sediment sample
Parameter Value
Weight of rock extracted (grams) 945 Total extract (ppm) 519 n-Alkane distribution n-C12 07 n-C13 23 n-C14 26 n-C15 22 n-C16 19 n-C17 14 i-C19 23 n-C18 14 i-C20 08 n-C19 11 n-C20 16 n-C21 25 n-C22 29 n-C23 70 n-C24 42 n-C25 95 n-C26 43 n-C27 83 n-C28 38 n-C29 87 n-C30 31 n-C31 273 Alkane compositional data Pristane phytane ratio 279 Pristane n-C17 ratio 161 Phytane n-C18 ratio 059 CPI (1)(a) 284 CPI (2) 209 (C21 + C22) (C28 + C29) 043
NOTE (a) CPI= Carbon preference index
63
Table 53 LDDH1 extract liquid chromatography data for 6623 m concentration
Rock extracted Total extract (grams) (ppm)
702 313
NOTE ppm= parts per million
Table 54 LDDH1 saturate gas chromatography data of core for 6623 m alkane composition
Pristane Pristane Phytane (a) CPI (1) CPI (2) (C21+C22) Phytane n-C17 n-C18 (C28+C29)
103 026 024 103 102 325
NOTE (a)CPI = carbon preference index
Table 55 LDDH1 saturate gas chromatography data of core for 6623 m n-alkane distributions
Parameter Value
n-C12 17 n-C13 38 n-C14 55 n-C15 60 n-C16 65 n-C17 74 i-C19 19 n-C18 78 i-C20 19 n-C19 80 n-C20 79 n-C21 71 n-C22 64 n-C23 57 n-C25 43 n-C24 38 n-C27 31 n-C28 23 n-C29 19 n-C30 12 n-C31 10
64
Appendix 6
Table 61 Summary of data from Trainor waterbores (TWB) and Bullen waterbores (BWB)
Well AMG Elevation TD Status(b) Completion details Water Salinity Water level Flow rate Depth to consolidated AGD84 GL (m) (m) struck mgl(c) (m) (LHr) lithology aquifer(e) Z51(a) Interval (m) (100 mm PVC) (m) (mgl)(d)
TWB 1 473660E 453 122 comp 0ndash75 plain 63 7 300 24 2 880 12 m 7287404N 75ndash93 slotted (9 260) McFadden Fm 93ndash99 plain TWB 2 472 977E 475 23 abd nil 15 m 7285877N Skates Hills Fm dry TWB 3 473259E 475 50 abd nil 7 m 7285849N Skates Hills Fm dry TWB 4 463225 E 445 50 comp 0ndash22 plain 35 7 200 55 3 600 0 m 7286143N 22ndash34 slotted (8 140) Tertiary sand and gravel 23ndash60 plain TWB 5 463095E 445 31 comp 0ndash19 plain 13 26 000 655 3 600 Tertiary sand and gravel 7277721N 19ndash25 slotted (36 700) 25ndash31 plain TWB 6 457013E 455 50 comp 0ndash42 plain 38 920 119 600 0 m 7274352N 42ndash48 slotted (1 030) Cornelia Fm ss TWB 7 453739E 475 26 susp 0ndash2 plain 11 9 300 48 4 500 0 m 7263891N (10 500) Tertiary sand TWB 8 433893E 535 60 susp 0ndash2 plain 47 8 500 gt46 1 200 0 m 7245991N (10 900) Tertiary sand and Brassey Range Fm ss TWB 9 437219E 505 51 comp 0ndash47 plain 45 1 000 58 600 1 m 7235905N 47ndash51 slotted (990) Brassey Range Fm ss TWB 10 434927E 495 32 susp 0ndash2 plain 235 450 120 0 m 7225875N (500) Dolerite
65
BWB 1 287337E 580 122 abd Nil 1 m 7245861N Jilyili Fm dry BWB 2 288346E 545 50 comp 0ndash26 plain 15 630 3 29 000 0 m 7240423N 26ndash38 slotted (730) Tertiary sand and gravel 38ndash50 plain BWB 3 305637E 545 50 abd 19 8 800 43 7 200 0 m 7240423N (10 550) Tertiary ss BWB 4 320167E 515 445 comp 0ndash20 plain 9 980 445 24 000 0 m 7248097N 20ndash32 slotted (1 190) Tertiary ss 32ndash44 plain BWB 5 353393E 545 20 susp 0ndash2 plain 45 (970) 1 m 7238934N Basalt
NOTES (a) GPS accuracy ~ 150 m (b) Comp = completed abd = abandoned susp = suspended (c) Salinity from conductivity (d) Analysis total dissolved solids (e) Fm = Formation ss = sandstone
37
edited by O R BERG and D G WOOLVERTON American Association of Petroleum
Geologists Memoir 39 p 79ndash91
LIBBY WG 1995 A petrological report on six samples of bore cuttings from the Savory Basin
Western Australia Western Australia Geological Survey S-series S31307 (unpublished)
MORTON JGG and DREXEL JF 1997 The petroleum geology of South Australia Vol 3
Officer Basin South Australia Department of Mines and Energy Resources Report Book
9719
MUHLING P C and BRAKEL A T 1985 Geology of the Bangemall Group mdash the evolution
of an intracratonic Proterozoic basin Western Australia Geological Survey Bulletin 128
219p
MYERS J S 1990 Precambrian tectonic evolution of part of Gondwana southwestern Australia
Geology v18 p 537ndash540
NELSON D R 1997 Compilation of SHRIMP UndashPb zircon data Western Australia Geological
Survey Record 19972 196p
PAYTON C E 1977 Seismic stratigraphy mdash applications to hydrocarbon exploration
American Association of Petroleum Geologists Memoir 26 516p
PERINCEK D 1996a The age of NeoproterozoicndashPalaeozoic sediments within the Officer Basin
of the Centralian Super-basin can be constrained by major sequence-bounding unconformities
APPEA Journal v 36 pt 1 p 350ndash368
PERINCEK D 1996b The stratigraphic and structural development of the Officer Basin
Western Australia a review Western Australia Geological Survey Annual Review 1995ndash
1996 p 135ndash148
PERINCEK D 1998 A compilation and review of data pertaining to the hydrocarbon
prospectivity of the Officer Basin Western Australia Geological Survey Record 19976
POSAMENTIER H W JERSEY M T and VAIL P R 1988 Eustatic controls on clastic
deposition 1 mdash Conceptual framework in Sea-level changes an integrated approach edited by
C K WILGUS B S HASTINGS C G St C KENDALL H W POSAMENTIER
38
C A ROSS and J C VAN WAGONER Society of Economic Paleontologists and
Mineralogists Special Publication no 42
STEVENS M K and ADAMIDES N G in prep GSWA Trainor 1 well completion report
Savory Sub-basin Officer Basin Western Australia with notes on petroleum and mineral
potential Western Australia Geological Survey Record 199612
STEVENS M K and GREY K 1997 Skates Hills Formation and Tarcunyah Group Officer
Basin mdash carbonate cycles stratigraphic position and hydrocarbon prospectivity Western
Australia Geological Survey Annual Review for 1996ndash97 p 55ndash60
SUMMONS RE and POWELL C McA 1991 Petroleum source rocks of the Amadeus Basin
in Geological and geophysical studies in the Amadeus Basin central Australia edited by R J
KORSCH and JM KENNARD Australia BMR Geology and Geophysics Bulletin 236
TRAVERSE A 1988 Palaeopalynology Boston Unwin Hyman 600p
VAIL P R MITCHUM R M Jr TODD R G WIDMIER J M THOMPSON S III
SANGREE J B BUBB J N and HATLELID W G 1977 Seismic stratigraphy and
global changes of sea level in Seismic stratigraphy mdash applications to hydrocarbon
exploration edited by C E PAYTON American Association of Petroleum Geologists
Memoir 26 516p
WALTER M R and GORTER J 1994 The Neoproterozoic Centralian Superbasin in Western
Australia the Savory and Officer Basins in The sedimentary basins of Western Australia
edited by P G PURCELL and R R PURCELL Petroleum Exploration Society of Australia
Symposium Perth WA 1994 Proceedings p851ndash864
WALTER M R GREY K WILLIAMS I R and CALVER C R 1994 Stratigraphy of the
Neoproterozoic to early Palaeozoic Savory Basin and correlation with the Amadeus and
Officer Basins Australian Journal of Earth Sciences v 41 p 533ndash546
WALTER M R VEEVERS J J CALVER C R and GREY K 1995 Neoproterozoic
stratigraphy of the Centralian Superbasin Australia Precambrian Research v 73 p 173ndash195
WILLIAMS I R 1992 Geology of the Savory Basin Western Australia Western Australia
Geological Survey Bulletin 141 115p
39
WILLIAMS I R 1995a Bullen WA (2nd Edition) Western Australia Geological Survey
1250 000 Geological Series Explanatory Notes 23p
WILLIAMS I R 1995b Trainor WA (2nd Edition) Western Australia Geological Survey
1250 000 Geological Series Explanatory Notes 31p
WILLIAMS I R and TYLER I M 1991 Robertson WA (2nd edition) Western Australia
Geological Survey 1250 000 Geological Series Explanatory Notes 36p
40
41
Appendix 1
Bibliography
Reports which are relevant to this investigation but which are not specifically cited are listed
below
BAILLIE P W POWELL C McA LI Z X and RYALL A M 1994 The tectonic
framework of Western Australiarsquos Neoproterozoic to recent sedimentary basins in The
sedimentary basins of Western Australia edited by P G PURCELL and R R PURCELL
Petroleum Exploration Society of Australia Symposium Perth WA 1994 Proceedings p
45ndash62
BRADSHAW M T BRADSHAW J MURRAY A P NEEDHAM D J SPENCER L
SUMMONS R E WILMOT J and WINN S 1994 Petroleum systems in West Australian
basins in The sedimentary basins of Western Australia edited by P G PURCELL and R R
PURCELL Petroleum Exploration Society of Australia Symposium Perth WA 1994
Proceedings p 93ndash118
CLARKE G L 1991 Proterozoic tectonic reworking in the Rudall Complex Western Australia
Australian Journal of Earth Science v38 p 31ndash44
COCKBAIN A E and HOCKING R M 1990 Phanerozoic in Geology and mineral resources
of Western Australia Western Australia Geological Survey Memoir 3 p 750ndash755
ETHERIDGE M and WALL V 1994 Tectonic and structural evolution of the Australian
Proterozoic 12th Australian Geological Convention Geological Society of Australia
Abstracts no 37 p 102ndash103
GOODE A D T 1981 Proterozoic geology of Western Australia in Precambrian of the
Southern Hemisphere Developments in Precambrian geology 2 edited by I R HUNTER
Amsterdam Elsevier p 105ndash203
GREY K and JACKSON M J 1983 A re-assessment of stromatolite evidence for the
correlation of the Late Proterozoic Neale and Ilma Beds Officer Basin Western Australia
Australia BMR Journal of Australian Geology and Geophysics v 8 p 359
42
HICKMAN A H WILLIAMS I R and BAGAS L 1994 Proterozoic geology and
mineralization of the TelferndashRudall region Paterson Orogen Geological Society of Australia
(WA Division) Excursion Guidebook no 5 56p
HOCKING R M MORY A J and WILLIAMS I R 1994 An atlas of Neoproterozoic and
Phanerozoic basins of Western Australia in The sedimentary basins of Western Australia
edited by P G PURCELL and R R PURCELL Petroleum Exploration Society of Australia
Symposium Perth WA 1994 Proceedings p 21ndash 44
JACKSON P R 1966 Geology and review of exploration Officer Basin Western Australia
Hunt Oil Company Western Australia Geological Survey S-series S26 (unpublished)
JACKSON M J 1971 Notes on a geological reconnaissance of the Officer Basin Western
Australia Australia BMR Geology and Geophysics Record 19715 30p
JACKSON M J and van de GRAAFF W J E 1981 Geology of the Officer Basin Western
Australia Australia BMR Geology and Geophysics Bulletin 206 102 p
LOWRY D C JACKSON M J van de GRAAFF W J E and KENNEWELL P J 1971
Preliminary result of geological mapping in the Officer Basin Western Australia Western
Australia Geological Survey Annual Report for 1971 p 50ndash56
MYERS J S 1990 Precambrian in Geology and mineral resources of Western Australia
Western Australia Geological Survey Memoir 3 p 737ndash750
MYERS J S SHAW R D and TYLER I M 1994 Proterozoic tectonic evolution of
Australia 12th Australian Geological Convention Geological Society of Australia Abstracts
no 37 p 312
NEDIN C and JENKINS R J F 1991 Re-evaluation of unconformities separating the
lsquoEdiacaranrsquo and Cambrian systems South Australia Palaios v 6 p 102ndash108
PHILLIPS B J JAMES A W and PHILIP G M 1985 The geology and hydrocarbon
potential of the north-western Officer Basin APEA Journal 25 (1) p 52ndash61
POWELL C McA LI Z X McELHINNY M W MEERT J G and PARK J K 1993
Paleomagnetic constraints on timing of the Neoproterozoic breakup of Rodinia and Cambrian
formation of Gondwana Geology v 21 p 889ndash892
43
POWELL C McA PREISS W V GATEHOUSE C G KRAPEZ B and LI Z X 1994
South Australian record of a Rodinian epicontinental basin and its mid-Neoproterozoic
breakup to form the Palaeo-Pacific Ocean Tectonophysics v 237 no 3ndash4 p 113ndash140
PREISS W V 1976 Proterozoic stromatolites from the Nabberu and Officer Basins Western
Australia and their biostratigraphic significance South Australia Geological Survey Report
of Investigations no 47 p 1ndash51
TOWNSON W G 1985 The subsurface geology of the western Officer Basin mdash results of
Shellrsquos 1980ndash1984 petroleum exploration campaign APEA Journal v 25 (1) p 34ndash51
WATTS K J 1982 The geology of the Townsend Quartzite Upper Proterozoic shallow water
deposit of the Northern Officer Basin Western Australia Perth University of Western
Australia BSc honours thesis (unpublished)
WELLS A T and KENNEWELL P J 1974 Evaporite exploration in the Officer Basin
Western Australia at the Madley Diapirs Australia BMR Record 1974194 (unpublished)
WILLIAMS I R and MYERS J S 1990 Paterson Orogen in Geology and mineral resources
of Western Australia Western Australia Geological Survey Memoir 3 p 274ndash286
WILLIAMS I R 1990 Savory Basin in Geology and mineral resources of Western Australia
Western Australia Geological Survey Memoir 3 p 329ndash334
WILLIAMS I R 1994 The Neoproterozoic Savory Basin Western Australia in The
sedimentary basins of Western Australia edited by P G PURCELL and R R PURCELL
Petroleum Exploration Society of Australia Symposium Perth WA 1994 Proceedings p
841ndash850
WILSON R B 1967 Woolnough Hills and Madley diapiric structures Gibson Desert WA
APEA Journal v 7 p 94ndash102
44
Appendix 2
Meteorological data (from Bureau of Meteorology Perth 1994)
Table 21 Wiluna rainfall (mm)
Year Jan Feb Mar Apr May Jun Jul Aug Sept Oct Nov Dec
1975 0 45 446 309 306 59 276 4 34 886 638 164 1976 16 154 12 138 53 16 34 62 12 238 0 2 1977 44 0 66 74 68 95 24 363 1 58 12 727 1978 234 522 94 16 0 96 367 24 16 353 185 45 1979 19 173 122 88 91 4 0 246 58 0 169 114 1980 148 764 68 1081 259 626 629 06 56 02 174 0 1981 123 476 192 32 196 118 44 74 14 0 28 312 1982 374 705 206 244 1079 92 02 143 368 526 368 118 1983 1 112 928 248 0 212 56 32 5 1 42 496 1984 149 7 342 84 836 0 348 132 224 04 16 172 1985 596 483 0 166 556 0 514 56 0 0 4 0 1986 0 154 35 0 0 1085 23 01 239 137 0 04 1987 1204 119 19 89 17 575 154 126 07 1 0 398 1988 46 202 164 13 388 0 202 104 0 0 224 1309 1989 207 234 26 703 278 536 57 0 01 0 144 02 1990 1035 23 281 46 126 53 94 218 44 9 42 0 1991 48 0 41 45 0 472 297 12 0 1 0 7 1992 112 96 1025 1227 323 65 04 174 0 132 48 4 1993 0 697 0 202 445 0 12 306 18 05 14 33 Mean 25 35 22 27 27 25 18 12 6 13 13 21
JAN FEB MAR APR MAY JUN JUL AUG SEP OCT NOV DEC0
10
20
30
40
Mea
n R
ain
fall
(mm
)
Month
Mean monthly rainfall in Wiluna
MKS41 140498
45
Table 22 Wiluna minimum temperature (degC)
Year Jan Feb Mar Apr May Jun Jul Aug Sept Oct Nov Dec
1975 ndash 23 203 15 94 63 71 62 103 124 169 205 1976 242 229 194 15 10 63 59 73 95 143 16 228 1977 243 25 197 148 96 95 56 86 102 ndash 188 23 1978 241 232 203 18 102 64 76 8 9 152 19 205 1979 255 226 216 167 83 6 59 79 97 145 198 223 1980 255 226 231 155 134 83 68 75 121 108 193 223 1981 245 216 19 182 119 6 54 78 138 159 163 218 1982 232 224 177 16 ndash ndash 37 111 112 164 209 225 1983 235 24 197 147 112 88 39 88 121 162 189 219 1984 241 243 191 156 ndash 72 66 7 95 161 182 211 1985 244 231 ndash 159 98 65 71 73 117 147 205 ndash 1986 ndash 229 226 155 93 96 43 49 10 122 ndash 219 1987 ndash 217 183 175 85 77 68 68 112 ndash ndash 221 1988 238 214 209 178 111 ndash ndash 86 104 157 171 195 1989 ndash 237 199 165 107 67 44 61 107 131 187 ndash 1990 232 ndash 211 155 118 62 57 87 102 149 195 22 1991 26 256 217 168 122 101 78 ndash 113 18 168 219 1992 227 227 214 169 102 98 59 69 ndash 125 159 196 1993 241 218 196 171 103 ndash 49 68 88 128 192 211 Mean 24 23 20 16 10 8 6 8 11 14 18 21
NOTE Dashes indicate data unavailable
JAN FEB MAR APR MAY JUN JUL AUG SEP OCT NOV DEC0
10
20
30
40
Month
MKS43 140498
50
Mean monthly minimum temperatures at Wiluna
Mea
n T
emp
erat
ure
(degC
)
46
Table 23 Wiluna maximum temperature (degC)
Year Jan Feb Mar Apr May Jun Jul Aug Sept Oct Nov Dec
1975 ndash 349 326 281 247 201 197 212 256 248 31 344 1976 374 369 346 297 248 206 208 225 265 287 313 388 1977 397 392 352 296 234 212 222 244 ndash 308 337 383 1978 378 345 346 316 242 195 176 205 231 295 334 356 1979 403 36 364 295 ndash ndash ndash 193 242 318 359 373 1980 392 342 377 275 24 176 179 233 292 288 349 391 1981 385 346 337 342 242 178 201 224 30 326 326 369 1982 372 359 315 307 ndash ndash 196 253 252 305 353 379 1983 381 389 327 272 263 222 187 248 287 321 336 366 1984 378 393 322 299 226 215 178 214 234 ndash 336 364 1985 40 366 ndash 294 224 216 205 212 284 307 355 ndash 1986 ndash 383 372 307 ndash 193 166 196 261 277 ndash 382 1987 ndash 339 328 305 21 202 214 218 275 ndash ndash 374 1988 388 365 353 301 23 ndash ndash 228 283 334 31 33 1989 ndash 375 339 285 238 179 181 219 275 298 336 ndash 1990 368 ndash 36 309 268 19 188 205 274 309 373 393 1991 414 416 363 315 268 206 21 ndash 279 338 332 368 1992 363 383 336 263 213 178 213 197 ndash 285 313 359 1993 396 357 344 301 221 ndash 197 215 253 294 347 362 Mean 39 37 34 30 24 20 20 22 27 30 34 37 NOTE Dashes indicate data unavailable
JAN FEB MAR APR MAY JUN JUL AUG SEP OCT NOV DEC0
10
20
30
40
Month
MKS42 140498
50
Mean monthly maximum temperatures at Wiluna
Mea
n T
emp
erat
ure
(degC
)
47
Appendix 3
Table 31 Summary of palynological results
Drillhole Depth (m) F no(a) GSWA no Lithology Formation Assemblage TAI(b)
BWB 1 74ndash75 F49668 135741 dark-grey siltstone basalt Jilyilli gt5 BWB 1 98ndash100 F49669 135742 dark-grey siltstone basalt Jilyilli gt5 BWB 1 121ndash122 F49670 135743 dark-grey siltstone basalt Jilyilli gt5 TWB 1 86ndash87 F49671 135631 dark-grey siltstone McFadden 3+ TWB 1 104ndash105 F49672 135632 dark-grey siltstone Cornelia 3+ TWB 1 121ndash122 F49673 135633 dark-grey siltstone Cornelia 4 TWB 2 14ndash15 F49674 135634 dark-grey siltstone Skates Hills 3+ TWB 6 49ndash50 F49675 135675 dark-grey siltstone Cornelia 1 3+ TWB 9 49ndash51 F49676 135704 dark-grey siltstone Brassey Range 1 3+ Trainor 1 37497- F49733 138939 black mudstone with Cornelia 5 37509 light-grey siltstone Trainor 1 3809 F49734 138940 dark-grey and black Cornelia 4- laminated mudstone Trainor 1 4170 F49735 138941 black unlaminated mudstone Cornelia 4- Trainor 1 4950 F49851 139501 dark-grey indurated siltstone Cornelia 5 Trainor 1 6032 F49852 139502 dark- and light-grey Cornelia 5 indurated siltstone Trainor 1 6434 F49853 139503 greenish indurated finely Cornelia 5 laminated siltstone LDDH 1 270 F49678 138934 dark-grey siltstone interbeds Waters 1 3+ in enterolithic evaporite Tarcunyah Gp LDDH 1 277 F49679 138935 dark-grey siltstone in cavity Waters 1 3+ in enterolithic evaporite Tarcunyah Gp
NOTES (a) GSWA Fossil Catalogue number (b) TAI = Thermal Alteration Index of Traverse (1988 plate 1)
48
Appendix 4
Savory Sub-basin quantitative magnetic and gravity interpretation (extracted from Cowan 1995)
Summary
A program of quantitative aeromagnetic interpretation has been completed on BMRAGSO data from the Savory Sub-
basin Western Australia Quantitative aeromagnetic interpretation utilized the 3D Euler deconvolution method
supported by wavenumber filtering and image processing The results have provided useful information on structural
trends and depth to magnetic sources in a structurally complex area Depth to magnetic source analysis has provided
information on intra-sedimentary magnetic sources as well as basement rocks
The results of the interpretation support previously identified depocentres However the presence of magnetic
sources at several levels makes it very difficult to produce a reliable magnetic basement depth contour map It is
considered more productive to work with the 3D Euler colour circle plots and images rather than trying to contour the
results It would be necessary to carry out a full-scale interpretation of the BMRAGSO profile data to improve on the
3D Euler results The regional gravity was found to be useful in interpreting the regional setting of the area although
the very wide data spacing limits quantitative use of the data The gravity data show quite a complex picture with
limited consistent correlation between gravity features and basin structures This suggests that gravity anomalies
reflect changes in density of the basement rocks rather than basement topography especially in the northern part of the
basin
It is recommended that the GSWA investigate access to company confidential high-resolution aeromagnetic data
prior to planning further aeromagnetic surveys Private companies have flown large parts of the northern half of the
area as part of their diamond exploration program Additional gravity coverage of the area may be more cost effective
than magnetic surveys as the gravity data provides more information on changes within the sedimentary section
Introduction
The main use of aeromagnetic data in petroleum exploration has been the determination of magnetic basement
topography although there has been increasing interest in analysis of intra-sedimentary magnetic anomalies
intrabasement and suprabasement magnetic anomalies These anomalies are used to determine depth to magnetic
basement rocks and hence determine the thickness of the sedimentary sequence Unfortunately interpretation of the
intrabasement and suprabasement magnetic anomalies is non-unique in terms of position and size of causative sources
because of the inherent ambiguity of potential-field methods However this ambiguity can be reduced by placing
49
constraints on source geometry and magnetization and by using geological and other geophysical data to constrain
the solution
Before 1970 most depth-determination techniques involved graphical determination of slopes of selected
magnetic anomalies and application of various empirical factors to convert the slopes into depth estimates Geological
Society of America Memoir 47 Interpretation of Aeromagnetic Maps by Vacquier et al (1951) was a landmark for
this type of interpretation
Automated interpretation procedures have played an increasingly important role in depth interpretation and a
wide range of techniques have been developed Many of these techniques are designed for application to located data
profiles and assume a two-dimensional geometry However there has been renewed interest in techniques applicable
to gridded data
Two distinct types of method can be recognized In the first case often described as discrete methods individual
isolated magnetic anomalies are interpreted and the results used to produce a map of basement relief In the second
case often described as continuous methods areas of data containing a number of anomalies are interpreted
statistically to produce direct output of basement depths
The discrete methods usually involve a semiautomatic initial phase which generates a large number of possible
depth solutions and an interactive second phase to screen and select acceptable solutions The advantage of this
approach is that the interpreter can select features that are relatively free from interference from adjacent anomalies
and consider all aspects of a particular magnetic anomaly The disadvantage is that interpretation can be very time
consuming as a wide range of depths are usually possible depending on the initial model chosen and a significant
amount of effort is needed to select the correct model In the case of the Savory Sub-basin dataset we encountered
problems in separating basement related effects from the effects of shallower intrasedimentary magnetic sources
Because of these problems we have concentrated on displaying the Euler results accompanied by separation filter
images of the data to show the shallower effects and deeper effects rather than trying to refine a 3D Euler
deconvolution depth-to-crystalline-basement contour
The continuous methods are very direct provided that the rather restrictive assumption can be made that all
anomalies are due to lateral magnetization changes due to basement topography This means that shallow effects and
large intrabasement anomalies must be removed from the data This involves judgement and skill as it is necessary to
distinguish between the lower amplitude suprabasement anomalies due to basement topography and the larger
intrabasement anomalies reflecting magnetization changes within the basement These methods were not considered
suitable for the Savory Sub-basin magnetic dataset but were used to invert the gravity data
50
Limitations of magnetic and gravity interpretation
Interpretation of the area is limited by a shortage of information on the nature and physical properties of the deeper
sedimentary sequence and the underlying basement rocks However using techniques such as cross-correlation of
gravity and pseudo-gravity data it is possible to try to differentiate between anomalies relating to basement and those
related to the sedimentary sequence
Gravity anomalies reflect changes within the sedimentary sequence as well as basement condition These
changes in density of sedimentary rocks produce gravity anomalies without a corresponding magnetic anomaly hence
the complementary nature of gravity and magnetic surveys The main use of magnetics is to determine depth to
magnetic basement and any intra-sedimentary volcanic rocks or intrusives whereas gravity provides much more
general information on the sedimentary sequence
Unfortunately interpretation of gravity anomalies is complicated since they can be due to a number of geological
features including
bull major basement faults
bull basement highs
bull igneous intrusions within the basement
bull sedimentary basins which may or may not be isostatically compensated
bull intra-sedimentary volcanics and associated plutonic centres
Two major problems affect the interpretation of both magnetic and gravity data
1 The inherent ambiguity of potential-field data There is no unique solution to any measured gravity or magnetic
anomaly and theoretically there will be an infinite number of source geometry and magnetizationdensity
combinations which will fit the observed data This means that any a priori information which helps to select a
suitable model is very useful
2 Measured anomalies are the summation of effects from different depths For example an observed gravity profile
may contain contributions from shallow sources (density variations within the sedimentary basin) intermediate
depth sources (density variations due to large igneous intrusions within the basement) and deep sources (crustal
thinning producing a mantle anomaly) Separation of these component responses is the regionalresidual problem
which we solve using spectral analysis and differential upward continuation-based separation filtering
Regional setting and interpretation overview
The area studied includes parts of BALFOUR DOWNS (SF51-9) RUDALL (SF51-10) ROBERTSON (SF51-13) GUNANYA
(SF51-14) COLLIER (SG50-4) BULLEN (SG51-1) TRAINOR (SG51-2) MADLEY (SG51-3) NABBERU (SG50-5)
STANLEY (SG51-6) and HERBERT (SG51-7) 1250 000 sheets Broadly the area lies between latitudes 22deg00rsquondash25deg30rsquoS
and longitudes 119deg30rsquondash123deg30rsquoE
51
Regional gravity
The AGSO regional gravity data (at nominal 11 km spacing) was gridded at a 4 km mesh spacing using a minimum-
curvature algorithm Bouguer gravity values in the area are negative reflecting mass deficiency at depth and range
from -84 mgals to -25 mgals
A Bouguer gravity colour image is shown as Figure 41 A residual grid was produced by removing a fifth-order
orthogonal polynomial from the Bouguer data but did not add to the interpretation
120deg 121deg 122deg 123deg
23deg
24deg
25deg
-25
-84
50 km
MKS46 180598
mgal
Figure 41 Regional Bouguer gravity (BMRAGSO data) gridded at 4 km
52
The data show a complex pattern of positive and negative anomalies with no clearly defined trends Correlations
with aeromagnetic data and known basin structures are poor A vague north-northwest linear trend appears to coincide
with the Marloo Fault (Figure 42) A prominent negative anomaly appears to coincide with the Blake Fold and Fault
Belt depocentre and continues as a narrower negative anomaly to the east until it widens out again near the edge of the
basin Elsewhere the gravity data show little correlation with known basin structures and it is likely that especially in
the north of the area gravity anomalies are due to density changes in the basement rather than changes in basement
topography
Production of wavelength-filtered residual gravity plots and vertical gradient plots showed very patchy aliased
data reflecting poor sampling in much of the area
Regional magnetics
The AGSO regional aeromagnetic data were gridded at a 400 m mesh spacing using a minimum-curvature algorithm
(Figure 43) Most of the data has a line spacing of 1600 m with small areas of 1 km spacing The quality of the data is
acceptable for regional interpretation but is not adequate for detailed analysis The accuracy of the flight path is rather
variable reflecting the vintage of the data and the noise envelope of the data is poor by modern standards Problems
were also encountered in joining different map sheets
The magnetic anomaly pattern over the south and west part of the area shows a strong high frequency signature
reflecting the presence of widespread basic sills and dykes Some of the major north-northeasterly trending dykes can
be traced over considerable distances
Discontinuous high-frequency anomalies extend as a northwest-trending zone through the centre of the area and
this zone includes a conspicuous circular magnetic anomaly which is probably a ring complex
The northern and eastern parts of the area are characterized by long-wavelength deep-seated basement magnetic
anomalies with 120deg and 150deg trends dominant The Marloo and Perentie Faults (Figure 42) appear as distinct linear
zones and offsets A prominent easterly trending negative anomaly in the northwest of the area appears to swing round
to the southeast and may separate different basement blocks One possible interpretation is that this very deep seated
anomaly separates areas of Archaean and Proterozoic basement
Regional geology
The regional geology is described in Williams (1992) The GSWA provided a digitized version of Plate 2 from this
Bulletin the structural interpretation map to use as an overlay (Figure 42)
53
Pp
Pp
PSd
PSd
PSd
PSd
PSd
PSo
PSt
PSt
PSf
PSf
PSf
PSb
PSb
PSb
PSsPSs
PSs
PSb
PSm
PSp
PSc
PSc
PSw
PSw
PSw
PSg
PSr
PSj
PSg
PM
Pk
PY
PY
PSd
L
L
L
L
L
L
L
LL
L
L
L
LL
L
LL
L L
LL
L L
L
L
L
L
L
L
L
LL
L
L
BLAKEDEPOCENTRE
MA
RLO
O
FAU
LT
PERENTIEFAULT
50 km
MKS39120598
120deg 121deg 122deg 123deg
25deg
24deg
23deg
Approximate boundaryof aeromagnetic interpretation
PML
PSgL
PSjL
PML
PSpL
PML
PML
PSfL
PSfL
PSpL
LPc
LPcLPcPSrL
LPA
Durba Sandstone
Woora Woora Formation
McFadden Formation
Tchukardine Formation
Boondawari Formation
Skates Hills Formation
Mundadjini Formation
Coondra Formation
Spearhole Formation
Watch Point Formation
Jilyili Formation
Brassey Range Formation
Glass Spring Formation
Paterson Formation
Yeneena Group
Karara Formation
Cornelia Formation
Kahrban Subgroup
Bangemall Group
Fault
Formation boundary
PSdL
PSoL
PSfL
PStL
PSbL
PSsL
PSmL
PScL
PSpL
PSwL
PSjL
PSrL
PSgL
Pp
PYL
PkL
LPc
LPA
PML
Savory Group Other Units
PYL
Figure 42 Regional geology and structure map (after Williams 1992)
54
120deg 121deg 122deg 123deg
23deg
24deg
25deg
5820
3750
MKS47 180598
nT
50 km
Figure 43 Regional aeromagnetic data total magnetic intensity (BMRAGSO data) gridded at 400 m
Analysis
3D analysis
3D Euler deconvolution was used as the primary depth-determination method The advantage of this approach is that
consistent solutions can be obtained over the entire area with minimal assumptions about source geometries Euler
deconvolution of gridded data is used for positional information and estimation of depth to top of source Euler
55
deconvolution yields a large number of depth solutions which have to be screened to reject spurious solutions Results
are plotted as circles in eight depth ranges with radius proportional to depth and colour coded
The 400 m total magnetic intensity grid was used for the analysis Horizontal gradients in x and y and the vertical
gradient were calculated 3D Euler deconvolution was tested on the 400 m gridded data using windows of 9 times 9 and
11 times 11 and 16 times 16 data points and structural indices 05 (fault) and 10 (sill or dyke) It was concluded that the
16 times 16 window produced the best results overall and final plots were produced for the 16 times 16 window and structural
index 05 (Fig 44) Results were very good over the northern and central parts of the area showing magnetic sources
Figure 44 Depth to magnetic source 3D Euler deconvolution 16 times 16 window of 400 m gridded data structural index 05
56
at several different levels Unfortunately in the extreme south of the area shallow intrasedimentary magnetic sources
(sills and dykes) dominated the inversion and the results contained few basement solutions
In order to reduce these problems the 400 m gridded data were filtered using a separation filter based on
interpretation of the log-energy spectrum The 3D Euler method was run on the filtered data in order to generate more
basement-depth solutions Results for the deep-separation filter data were gridded and presented as a colour image in
Cowan (1995) Attempts to grid the Euler output were unsatisfactory and it is considered safer to interpret the 3D
Euler depth plots The 3D Euler depth results from the separation-filter run should be analysed with care as perfect
separation of the basement can never be achieved and there will always be some contamination from sources at
different levels
The results of original total magnetic intensity 3D Euler depth estimation for structural index 05 using a 16 point
window have been plotted at 1500 000 scale (not included in this publication but available in Cowan (1995) from the
GSWA Library as S10331) and as reduced A4 colour circle plots (Figure 44)
The results of deep-basement 3D Euler depth estimation for structural index 05 using a 16 point window have
been plotted as a colour image at 1500 000 scale and as an A4 image (not included in this publication)
2D analysis
Two equispaced profiles were interpolated with a 50 m station interval from the AGSO-located data profiles for the
BULLEN 1250 000 sheet The interpolated profiles were analysed using 2D Euler deconvolution and Werner
deconvolution Results are included in Cowan (1995) and show the use of these methods for more detailed analysis
Filtered data
In order to reconcile 3D Euler results from shallow basement and intrasedimentary magnetic sources we produced
several separation-filtered maps and images We found the shallow-layer double-separation filter (Figure 45) to be
very effective for shallow sources and the deep-layer standard-separation filter (Figure 46) for the basement layer
Gravity and magnetic data correlation
Both lsquoreduced to the polersquo (RTP) magnetics (Figure 47) and pseudo-gravity data (Figure 48) were produced as part of
the reconciliation of gravity and magnetic signatures In both cases the filtering operations assumed magnetization by
induction in the present Earths field The RTP data are fairly similar to the total magnetic intensity The pseudo-
57
gravity data are dominated by a northwest-trending strong positive anomaly and there is little correlation with the
Bouguer gravity data
The poor magneticgravity correlation is confirmed by cross-correlation of the RTP magnetics and the gravity
gradient The correlation plot in Figure 49 shows little coherent response with numerous zones of positive and
negative correlation
Figure 45 Regional aeromagnetic data shallow layer separation filter (BMRAGSO data) gridded at 400 m
Results
In the north and east of the area on the Wells Foreland Sub-basin trend (refer to Figure 1 main text) we see a range
of quite deep 3D Euler depths and several trend directions with north-northwesterly dominant There are relatively few
shallow intrasedimentary solutions in this zone
The second area of deep 3D Euler solutions lies over the Blake depocentre (Figure 43) with several trend
directions
Elsewhere the 3D Euler results are dominated by shallow intrasedimentary depth solutions reflecting mainly the
dolerite sills dykes and the ring complex However where we do see basement-related solutions in the south and
west of the area they appear to be shallower than those noted for the Wells Foreland Sub-basin and the Blake
depocentre
58
Figure 46 Regional aeromagnetic data deep-layer separation filter (BMRAGSO data) gridded at 400 m
Figure 48 Regional aeromagnetic data pseudo-gravity transform (BMRAGSO data) gridded at 400 m
Figure 47 Regional aeromagnetic data reduced-to-pole (BMRAGSO data) gridded at 400 m
Figure 49 Regional aeromagnetic and gravity data gravitymagnetic correlation using RTP magnetics and gravity gradient (BMRAGSO data) gridded at 4 km
59
This subdivision of the area into two zones of deep solutions is consistent with interpreted depocentres
However the interference between sources at different levels and the complexity of the magnetic response of the
basement rocks precludes more refined interpretation at this stage
The area of deep 3D Euler solutions over the Blake depocentre correlates with the pronounced negative gravity
anomaly discussed in the gravity interpretation section Using a density contrast of -015 gcc the negative gravity
anomaly could indicate up to 6ndash8 km of low-density sedimentary rocks depending on assumptions about the regional
field
The area of deep 3D Euler solutions over the Wells Foreland Sub-basin has a complex gravity expression and no
clear basin structure emerges from inversion of these data As noted previously it is likely that observed gravity
anomalies reflect contrasts in basement density rather than basement topography
Separation filtering applied to the magnetic data helps to enhance the intrasedimentary magnetic signature and to
give a better impression of the basement magnetic signature even though separation of the basement response is not
perfect
Conclusions
Quantitative aeromagnetic interpretation using 3D Euler deconvolution supported by wavenumber filtering and image
processing has been successful in providing structural trend and depth information for the Savory Sub-basin
Quantitative magnetic interpretation has revealed two zones of relatively deep magnetic basement beneath the
Wells Foreland Sub-basin and the Blake depocentre
This analysis of the magnetic data supports interpreted depocentres but the complexity of the basement magnetic
signature and interference from sources at different depths precludes further refinement to a map of basement
topography
Regional gravity proved to be very useful in understanding the regional setting of the area and in providing
support for aspects of the interpretation The gravity data support the interpretation of the Blake depocentre
suggesting up to 6ndash8 km of low-density sedimentary rocks
The deep structure of the Savory Sub-basin area is obviously complex with different areas underlain by
Archaean and Proterozoic basement and with the Capricorn suture occurring in the centre of the area
60
Recommendations
The quantitative magnetic interpretation needs to be reconciled with geological models available for the area
In particular the zones tentatively identified as areas with thick sedimentary rocks the Wells Foreland Sub-
basin and the Blake depocentre need to be investigated
Cross sections should be prepared across the basin for joint magneticgravity modelling especially for the Blake
depocentre It is important to be able to explain the strong negative gravity anomaly in this area
In view of the effects of basement density contrasts on the gravity field for the northern part of the area we think
that additional gravity interpretation and acquisition of new gravity data may not be justified as they will not
contribute significantly to understanding basin evolution and structure
It is recommended that GSWA try to get access to company confidential high-resolution aeromagnetic data
rather than flying new surveys The GSWA might offer to fund flying of new infill areas as a bargaining point
References
The original text of this report by Cowan (1995) and 1500 000 scale maps are filed in the GSWA Library under
S10331
COWAN D 1995 Savory Basin quantitative magnetic interpretation Western Australia Geological Survey S-series
S10331 (unpublished)
VACQUIER V STEENLAND N C HENDERSON R G and ZIETZ I 1951 Interpretation of aeromagnetic
maps The Geological Society of America Memoir 47 151p
WILLIAMS I R 1992 Geology of the Savory Basin Western Australia Western Australia Geological Survey
Bulletin 141 115p
61
Appendix 5
Geochemistry
MKS38 250398
Saturate FractionC12+ GLC
1217
Pr18
Ph
22
31CSR WELL-13 315m Cuttings
Figure 51 Canning Stock Route Well 13 gas chromatograph of extract of auger drill sample
12
17
18
22
31
Pr Ph
LDDH 1 6623m CoreSaturate FractionC12+ GLC
MKS35 240398
Figure 52 Gas chromatograph of extract from core sample at 6623 m LDDH1
62
Table 51 Canning Stock Route Well 13 auger drill samples
GSWA sample Drill depth (m)(a) Comments
135601 150 At watertable 135602 203 (all samples consist 135603 310 of sand mud and water) 135604 315 At total depth
NOTE (a) Datum for drill depth is the top of sediment fill in the well which is 155 m below ground level (ie the total depth of 315 m is 47 m below ground level)
Table 52 Canning Stock Route Well 13 gas chromatography data for 315 m depth sediment sample
Parameter Value
Weight of rock extracted (grams) 945 Total extract (ppm) 519 n-Alkane distribution n-C12 07 n-C13 23 n-C14 26 n-C15 22 n-C16 19 n-C17 14 i-C19 23 n-C18 14 i-C20 08 n-C19 11 n-C20 16 n-C21 25 n-C22 29 n-C23 70 n-C24 42 n-C25 95 n-C26 43 n-C27 83 n-C28 38 n-C29 87 n-C30 31 n-C31 273 Alkane compositional data Pristane phytane ratio 279 Pristane n-C17 ratio 161 Phytane n-C18 ratio 059 CPI (1)(a) 284 CPI (2) 209 (C21 + C22) (C28 + C29) 043
NOTE (a) CPI= Carbon preference index
63
Table 53 LDDH1 extract liquid chromatography data for 6623 m concentration
Rock extracted Total extract (grams) (ppm)
702 313
NOTE ppm= parts per million
Table 54 LDDH1 saturate gas chromatography data of core for 6623 m alkane composition
Pristane Pristane Phytane (a) CPI (1) CPI (2) (C21+C22) Phytane n-C17 n-C18 (C28+C29)
103 026 024 103 102 325
NOTE (a)CPI = carbon preference index
Table 55 LDDH1 saturate gas chromatography data of core for 6623 m n-alkane distributions
Parameter Value
n-C12 17 n-C13 38 n-C14 55 n-C15 60 n-C16 65 n-C17 74 i-C19 19 n-C18 78 i-C20 19 n-C19 80 n-C20 79 n-C21 71 n-C22 64 n-C23 57 n-C25 43 n-C24 38 n-C27 31 n-C28 23 n-C29 19 n-C30 12 n-C31 10
64
Appendix 6
Table 61 Summary of data from Trainor waterbores (TWB) and Bullen waterbores (BWB)
Well AMG Elevation TD Status(b) Completion details Water Salinity Water level Flow rate Depth to consolidated AGD84 GL (m) (m) struck mgl(c) (m) (LHr) lithology aquifer(e) Z51(a) Interval (m) (100 mm PVC) (m) (mgl)(d)
TWB 1 473660E 453 122 comp 0ndash75 plain 63 7 300 24 2 880 12 m 7287404N 75ndash93 slotted (9 260) McFadden Fm 93ndash99 plain TWB 2 472 977E 475 23 abd nil 15 m 7285877N Skates Hills Fm dry TWB 3 473259E 475 50 abd nil 7 m 7285849N Skates Hills Fm dry TWB 4 463225 E 445 50 comp 0ndash22 plain 35 7 200 55 3 600 0 m 7286143N 22ndash34 slotted (8 140) Tertiary sand and gravel 23ndash60 plain TWB 5 463095E 445 31 comp 0ndash19 plain 13 26 000 655 3 600 Tertiary sand and gravel 7277721N 19ndash25 slotted (36 700) 25ndash31 plain TWB 6 457013E 455 50 comp 0ndash42 plain 38 920 119 600 0 m 7274352N 42ndash48 slotted (1 030) Cornelia Fm ss TWB 7 453739E 475 26 susp 0ndash2 plain 11 9 300 48 4 500 0 m 7263891N (10 500) Tertiary sand TWB 8 433893E 535 60 susp 0ndash2 plain 47 8 500 gt46 1 200 0 m 7245991N (10 900) Tertiary sand and Brassey Range Fm ss TWB 9 437219E 505 51 comp 0ndash47 plain 45 1 000 58 600 1 m 7235905N 47ndash51 slotted (990) Brassey Range Fm ss TWB 10 434927E 495 32 susp 0ndash2 plain 235 450 120 0 m 7225875N (500) Dolerite
65
BWB 1 287337E 580 122 abd Nil 1 m 7245861N Jilyili Fm dry BWB 2 288346E 545 50 comp 0ndash26 plain 15 630 3 29 000 0 m 7240423N 26ndash38 slotted (730) Tertiary sand and gravel 38ndash50 plain BWB 3 305637E 545 50 abd 19 8 800 43 7 200 0 m 7240423N (10 550) Tertiary ss BWB 4 320167E 515 445 comp 0ndash20 plain 9 980 445 24 000 0 m 7248097N 20ndash32 slotted (1 190) Tertiary ss 32ndash44 plain BWB 5 353393E 545 20 susp 0ndash2 plain 45 (970) 1 m 7238934N Basalt
NOTES (a) GPS accuracy ~ 150 m (b) Comp = completed abd = abandoned susp = suspended (c) Salinity from conductivity (d) Analysis total dissolved solids (e) Fm = Formation ss = sandstone
38
C A ROSS and J C VAN WAGONER Society of Economic Paleontologists and
Mineralogists Special Publication no 42
STEVENS M K and ADAMIDES N G in prep GSWA Trainor 1 well completion report
Savory Sub-basin Officer Basin Western Australia with notes on petroleum and mineral
potential Western Australia Geological Survey Record 199612
STEVENS M K and GREY K 1997 Skates Hills Formation and Tarcunyah Group Officer
Basin mdash carbonate cycles stratigraphic position and hydrocarbon prospectivity Western
Australia Geological Survey Annual Review for 1996ndash97 p 55ndash60
SUMMONS RE and POWELL C McA 1991 Petroleum source rocks of the Amadeus Basin
in Geological and geophysical studies in the Amadeus Basin central Australia edited by R J
KORSCH and JM KENNARD Australia BMR Geology and Geophysics Bulletin 236
TRAVERSE A 1988 Palaeopalynology Boston Unwin Hyman 600p
VAIL P R MITCHUM R M Jr TODD R G WIDMIER J M THOMPSON S III
SANGREE J B BUBB J N and HATLELID W G 1977 Seismic stratigraphy and
global changes of sea level in Seismic stratigraphy mdash applications to hydrocarbon
exploration edited by C E PAYTON American Association of Petroleum Geologists
Memoir 26 516p
WALTER M R and GORTER J 1994 The Neoproterozoic Centralian Superbasin in Western
Australia the Savory and Officer Basins in The sedimentary basins of Western Australia
edited by P G PURCELL and R R PURCELL Petroleum Exploration Society of Australia
Symposium Perth WA 1994 Proceedings p851ndash864
WALTER M R GREY K WILLIAMS I R and CALVER C R 1994 Stratigraphy of the
Neoproterozoic to early Palaeozoic Savory Basin and correlation with the Amadeus and
Officer Basins Australian Journal of Earth Sciences v 41 p 533ndash546
WALTER M R VEEVERS J J CALVER C R and GREY K 1995 Neoproterozoic
stratigraphy of the Centralian Superbasin Australia Precambrian Research v 73 p 173ndash195
WILLIAMS I R 1992 Geology of the Savory Basin Western Australia Western Australia
Geological Survey Bulletin 141 115p
39
WILLIAMS I R 1995a Bullen WA (2nd Edition) Western Australia Geological Survey
1250 000 Geological Series Explanatory Notes 23p
WILLIAMS I R 1995b Trainor WA (2nd Edition) Western Australia Geological Survey
1250 000 Geological Series Explanatory Notes 31p
WILLIAMS I R and TYLER I M 1991 Robertson WA (2nd edition) Western Australia
Geological Survey 1250 000 Geological Series Explanatory Notes 36p
40
41
Appendix 1
Bibliography
Reports which are relevant to this investigation but which are not specifically cited are listed
below
BAILLIE P W POWELL C McA LI Z X and RYALL A M 1994 The tectonic
framework of Western Australiarsquos Neoproterozoic to recent sedimentary basins in The
sedimentary basins of Western Australia edited by P G PURCELL and R R PURCELL
Petroleum Exploration Society of Australia Symposium Perth WA 1994 Proceedings p
45ndash62
BRADSHAW M T BRADSHAW J MURRAY A P NEEDHAM D J SPENCER L
SUMMONS R E WILMOT J and WINN S 1994 Petroleum systems in West Australian
basins in The sedimentary basins of Western Australia edited by P G PURCELL and R R
PURCELL Petroleum Exploration Society of Australia Symposium Perth WA 1994
Proceedings p 93ndash118
CLARKE G L 1991 Proterozoic tectonic reworking in the Rudall Complex Western Australia
Australian Journal of Earth Science v38 p 31ndash44
COCKBAIN A E and HOCKING R M 1990 Phanerozoic in Geology and mineral resources
of Western Australia Western Australia Geological Survey Memoir 3 p 750ndash755
ETHERIDGE M and WALL V 1994 Tectonic and structural evolution of the Australian
Proterozoic 12th Australian Geological Convention Geological Society of Australia
Abstracts no 37 p 102ndash103
GOODE A D T 1981 Proterozoic geology of Western Australia in Precambrian of the
Southern Hemisphere Developments in Precambrian geology 2 edited by I R HUNTER
Amsterdam Elsevier p 105ndash203
GREY K and JACKSON M J 1983 A re-assessment of stromatolite evidence for the
correlation of the Late Proterozoic Neale and Ilma Beds Officer Basin Western Australia
Australia BMR Journal of Australian Geology and Geophysics v 8 p 359
42
HICKMAN A H WILLIAMS I R and BAGAS L 1994 Proterozoic geology and
mineralization of the TelferndashRudall region Paterson Orogen Geological Society of Australia
(WA Division) Excursion Guidebook no 5 56p
HOCKING R M MORY A J and WILLIAMS I R 1994 An atlas of Neoproterozoic and
Phanerozoic basins of Western Australia in The sedimentary basins of Western Australia
edited by P G PURCELL and R R PURCELL Petroleum Exploration Society of Australia
Symposium Perth WA 1994 Proceedings p 21ndash 44
JACKSON P R 1966 Geology and review of exploration Officer Basin Western Australia
Hunt Oil Company Western Australia Geological Survey S-series S26 (unpublished)
JACKSON M J 1971 Notes on a geological reconnaissance of the Officer Basin Western
Australia Australia BMR Geology and Geophysics Record 19715 30p
JACKSON M J and van de GRAAFF W J E 1981 Geology of the Officer Basin Western
Australia Australia BMR Geology and Geophysics Bulletin 206 102 p
LOWRY D C JACKSON M J van de GRAAFF W J E and KENNEWELL P J 1971
Preliminary result of geological mapping in the Officer Basin Western Australia Western
Australia Geological Survey Annual Report for 1971 p 50ndash56
MYERS J S 1990 Precambrian in Geology and mineral resources of Western Australia
Western Australia Geological Survey Memoir 3 p 737ndash750
MYERS J S SHAW R D and TYLER I M 1994 Proterozoic tectonic evolution of
Australia 12th Australian Geological Convention Geological Society of Australia Abstracts
no 37 p 312
NEDIN C and JENKINS R J F 1991 Re-evaluation of unconformities separating the
lsquoEdiacaranrsquo and Cambrian systems South Australia Palaios v 6 p 102ndash108
PHILLIPS B J JAMES A W and PHILIP G M 1985 The geology and hydrocarbon
potential of the north-western Officer Basin APEA Journal 25 (1) p 52ndash61
POWELL C McA LI Z X McELHINNY M W MEERT J G and PARK J K 1993
Paleomagnetic constraints on timing of the Neoproterozoic breakup of Rodinia and Cambrian
formation of Gondwana Geology v 21 p 889ndash892
43
POWELL C McA PREISS W V GATEHOUSE C G KRAPEZ B and LI Z X 1994
South Australian record of a Rodinian epicontinental basin and its mid-Neoproterozoic
breakup to form the Palaeo-Pacific Ocean Tectonophysics v 237 no 3ndash4 p 113ndash140
PREISS W V 1976 Proterozoic stromatolites from the Nabberu and Officer Basins Western
Australia and their biostratigraphic significance South Australia Geological Survey Report
of Investigations no 47 p 1ndash51
TOWNSON W G 1985 The subsurface geology of the western Officer Basin mdash results of
Shellrsquos 1980ndash1984 petroleum exploration campaign APEA Journal v 25 (1) p 34ndash51
WATTS K J 1982 The geology of the Townsend Quartzite Upper Proterozoic shallow water
deposit of the Northern Officer Basin Western Australia Perth University of Western
Australia BSc honours thesis (unpublished)
WELLS A T and KENNEWELL P J 1974 Evaporite exploration in the Officer Basin
Western Australia at the Madley Diapirs Australia BMR Record 1974194 (unpublished)
WILLIAMS I R and MYERS J S 1990 Paterson Orogen in Geology and mineral resources
of Western Australia Western Australia Geological Survey Memoir 3 p 274ndash286
WILLIAMS I R 1990 Savory Basin in Geology and mineral resources of Western Australia
Western Australia Geological Survey Memoir 3 p 329ndash334
WILLIAMS I R 1994 The Neoproterozoic Savory Basin Western Australia in The
sedimentary basins of Western Australia edited by P G PURCELL and R R PURCELL
Petroleum Exploration Society of Australia Symposium Perth WA 1994 Proceedings p
841ndash850
WILSON R B 1967 Woolnough Hills and Madley diapiric structures Gibson Desert WA
APEA Journal v 7 p 94ndash102
44
Appendix 2
Meteorological data (from Bureau of Meteorology Perth 1994)
Table 21 Wiluna rainfall (mm)
Year Jan Feb Mar Apr May Jun Jul Aug Sept Oct Nov Dec
1975 0 45 446 309 306 59 276 4 34 886 638 164 1976 16 154 12 138 53 16 34 62 12 238 0 2 1977 44 0 66 74 68 95 24 363 1 58 12 727 1978 234 522 94 16 0 96 367 24 16 353 185 45 1979 19 173 122 88 91 4 0 246 58 0 169 114 1980 148 764 68 1081 259 626 629 06 56 02 174 0 1981 123 476 192 32 196 118 44 74 14 0 28 312 1982 374 705 206 244 1079 92 02 143 368 526 368 118 1983 1 112 928 248 0 212 56 32 5 1 42 496 1984 149 7 342 84 836 0 348 132 224 04 16 172 1985 596 483 0 166 556 0 514 56 0 0 4 0 1986 0 154 35 0 0 1085 23 01 239 137 0 04 1987 1204 119 19 89 17 575 154 126 07 1 0 398 1988 46 202 164 13 388 0 202 104 0 0 224 1309 1989 207 234 26 703 278 536 57 0 01 0 144 02 1990 1035 23 281 46 126 53 94 218 44 9 42 0 1991 48 0 41 45 0 472 297 12 0 1 0 7 1992 112 96 1025 1227 323 65 04 174 0 132 48 4 1993 0 697 0 202 445 0 12 306 18 05 14 33 Mean 25 35 22 27 27 25 18 12 6 13 13 21
JAN FEB MAR APR MAY JUN JUL AUG SEP OCT NOV DEC0
10
20
30
40
Mea
n R
ain
fall
(mm
)
Month
Mean monthly rainfall in Wiluna
MKS41 140498
45
Table 22 Wiluna minimum temperature (degC)
Year Jan Feb Mar Apr May Jun Jul Aug Sept Oct Nov Dec
1975 ndash 23 203 15 94 63 71 62 103 124 169 205 1976 242 229 194 15 10 63 59 73 95 143 16 228 1977 243 25 197 148 96 95 56 86 102 ndash 188 23 1978 241 232 203 18 102 64 76 8 9 152 19 205 1979 255 226 216 167 83 6 59 79 97 145 198 223 1980 255 226 231 155 134 83 68 75 121 108 193 223 1981 245 216 19 182 119 6 54 78 138 159 163 218 1982 232 224 177 16 ndash ndash 37 111 112 164 209 225 1983 235 24 197 147 112 88 39 88 121 162 189 219 1984 241 243 191 156 ndash 72 66 7 95 161 182 211 1985 244 231 ndash 159 98 65 71 73 117 147 205 ndash 1986 ndash 229 226 155 93 96 43 49 10 122 ndash 219 1987 ndash 217 183 175 85 77 68 68 112 ndash ndash 221 1988 238 214 209 178 111 ndash ndash 86 104 157 171 195 1989 ndash 237 199 165 107 67 44 61 107 131 187 ndash 1990 232 ndash 211 155 118 62 57 87 102 149 195 22 1991 26 256 217 168 122 101 78 ndash 113 18 168 219 1992 227 227 214 169 102 98 59 69 ndash 125 159 196 1993 241 218 196 171 103 ndash 49 68 88 128 192 211 Mean 24 23 20 16 10 8 6 8 11 14 18 21
NOTE Dashes indicate data unavailable
JAN FEB MAR APR MAY JUN JUL AUG SEP OCT NOV DEC0
10
20
30
40
Month
MKS43 140498
50
Mean monthly minimum temperatures at Wiluna
Mea
n T
emp
erat
ure
(degC
)
46
Table 23 Wiluna maximum temperature (degC)
Year Jan Feb Mar Apr May Jun Jul Aug Sept Oct Nov Dec
1975 ndash 349 326 281 247 201 197 212 256 248 31 344 1976 374 369 346 297 248 206 208 225 265 287 313 388 1977 397 392 352 296 234 212 222 244 ndash 308 337 383 1978 378 345 346 316 242 195 176 205 231 295 334 356 1979 403 36 364 295 ndash ndash ndash 193 242 318 359 373 1980 392 342 377 275 24 176 179 233 292 288 349 391 1981 385 346 337 342 242 178 201 224 30 326 326 369 1982 372 359 315 307 ndash ndash 196 253 252 305 353 379 1983 381 389 327 272 263 222 187 248 287 321 336 366 1984 378 393 322 299 226 215 178 214 234 ndash 336 364 1985 40 366 ndash 294 224 216 205 212 284 307 355 ndash 1986 ndash 383 372 307 ndash 193 166 196 261 277 ndash 382 1987 ndash 339 328 305 21 202 214 218 275 ndash ndash 374 1988 388 365 353 301 23 ndash ndash 228 283 334 31 33 1989 ndash 375 339 285 238 179 181 219 275 298 336 ndash 1990 368 ndash 36 309 268 19 188 205 274 309 373 393 1991 414 416 363 315 268 206 21 ndash 279 338 332 368 1992 363 383 336 263 213 178 213 197 ndash 285 313 359 1993 396 357 344 301 221 ndash 197 215 253 294 347 362 Mean 39 37 34 30 24 20 20 22 27 30 34 37 NOTE Dashes indicate data unavailable
JAN FEB MAR APR MAY JUN JUL AUG SEP OCT NOV DEC0
10
20
30
40
Month
MKS42 140498
50
Mean monthly maximum temperatures at Wiluna
Mea
n T
emp
erat
ure
(degC
)
47
Appendix 3
Table 31 Summary of palynological results
Drillhole Depth (m) F no(a) GSWA no Lithology Formation Assemblage TAI(b)
BWB 1 74ndash75 F49668 135741 dark-grey siltstone basalt Jilyilli gt5 BWB 1 98ndash100 F49669 135742 dark-grey siltstone basalt Jilyilli gt5 BWB 1 121ndash122 F49670 135743 dark-grey siltstone basalt Jilyilli gt5 TWB 1 86ndash87 F49671 135631 dark-grey siltstone McFadden 3+ TWB 1 104ndash105 F49672 135632 dark-grey siltstone Cornelia 3+ TWB 1 121ndash122 F49673 135633 dark-grey siltstone Cornelia 4 TWB 2 14ndash15 F49674 135634 dark-grey siltstone Skates Hills 3+ TWB 6 49ndash50 F49675 135675 dark-grey siltstone Cornelia 1 3+ TWB 9 49ndash51 F49676 135704 dark-grey siltstone Brassey Range 1 3+ Trainor 1 37497- F49733 138939 black mudstone with Cornelia 5 37509 light-grey siltstone Trainor 1 3809 F49734 138940 dark-grey and black Cornelia 4- laminated mudstone Trainor 1 4170 F49735 138941 black unlaminated mudstone Cornelia 4- Trainor 1 4950 F49851 139501 dark-grey indurated siltstone Cornelia 5 Trainor 1 6032 F49852 139502 dark- and light-grey Cornelia 5 indurated siltstone Trainor 1 6434 F49853 139503 greenish indurated finely Cornelia 5 laminated siltstone LDDH 1 270 F49678 138934 dark-grey siltstone interbeds Waters 1 3+ in enterolithic evaporite Tarcunyah Gp LDDH 1 277 F49679 138935 dark-grey siltstone in cavity Waters 1 3+ in enterolithic evaporite Tarcunyah Gp
NOTES (a) GSWA Fossil Catalogue number (b) TAI = Thermal Alteration Index of Traverse (1988 plate 1)
48
Appendix 4
Savory Sub-basin quantitative magnetic and gravity interpretation (extracted from Cowan 1995)
Summary
A program of quantitative aeromagnetic interpretation has been completed on BMRAGSO data from the Savory Sub-
basin Western Australia Quantitative aeromagnetic interpretation utilized the 3D Euler deconvolution method
supported by wavenumber filtering and image processing The results have provided useful information on structural
trends and depth to magnetic sources in a structurally complex area Depth to magnetic source analysis has provided
information on intra-sedimentary magnetic sources as well as basement rocks
The results of the interpretation support previously identified depocentres However the presence of magnetic
sources at several levels makes it very difficult to produce a reliable magnetic basement depth contour map It is
considered more productive to work with the 3D Euler colour circle plots and images rather than trying to contour the
results It would be necessary to carry out a full-scale interpretation of the BMRAGSO profile data to improve on the
3D Euler results The regional gravity was found to be useful in interpreting the regional setting of the area although
the very wide data spacing limits quantitative use of the data The gravity data show quite a complex picture with
limited consistent correlation between gravity features and basin structures This suggests that gravity anomalies
reflect changes in density of the basement rocks rather than basement topography especially in the northern part of the
basin
It is recommended that the GSWA investigate access to company confidential high-resolution aeromagnetic data
prior to planning further aeromagnetic surveys Private companies have flown large parts of the northern half of the
area as part of their diamond exploration program Additional gravity coverage of the area may be more cost effective
than magnetic surveys as the gravity data provides more information on changes within the sedimentary section
Introduction
The main use of aeromagnetic data in petroleum exploration has been the determination of magnetic basement
topography although there has been increasing interest in analysis of intra-sedimentary magnetic anomalies
intrabasement and suprabasement magnetic anomalies These anomalies are used to determine depth to magnetic
basement rocks and hence determine the thickness of the sedimentary sequence Unfortunately interpretation of the
intrabasement and suprabasement magnetic anomalies is non-unique in terms of position and size of causative sources
because of the inherent ambiguity of potential-field methods However this ambiguity can be reduced by placing
49
constraints on source geometry and magnetization and by using geological and other geophysical data to constrain
the solution
Before 1970 most depth-determination techniques involved graphical determination of slopes of selected
magnetic anomalies and application of various empirical factors to convert the slopes into depth estimates Geological
Society of America Memoir 47 Interpretation of Aeromagnetic Maps by Vacquier et al (1951) was a landmark for
this type of interpretation
Automated interpretation procedures have played an increasingly important role in depth interpretation and a
wide range of techniques have been developed Many of these techniques are designed for application to located data
profiles and assume a two-dimensional geometry However there has been renewed interest in techniques applicable
to gridded data
Two distinct types of method can be recognized In the first case often described as discrete methods individual
isolated magnetic anomalies are interpreted and the results used to produce a map of basement relief In the second
case often described as continuous methods areas of data containing a number of anomalies are interpreted
statistically to produce direct output of basement depths
The discrete methods usually involve a semiautomatic initial phase which generates a large number of possible
depth solutions and an interactive second phase to screen and select acceptable solutions The advantage of this
approach is that the interpreter can select features that are relatively free from interference from adjacent anomalies
and consider all aspects of a particular magnetic anomaly The disadvantage is that interpretation can be very time
consuming as a wide range of depths are usually possible depending on the initial model chosen and a significant
amount of effort is needed to select the correct model In the case of the Savory Sub-basin dataset we encountered
problems in separating basement related effects from the effects of shallower intrasedimentary magnetic sources
Because of these problems we have concentrated on displaying the Euler results accompanied by separation filter
images of the data to show the shallower effects and deeper effects rather than trying to refine a 3D Euler
deconvolution depth-to-crystalline-basement contour
The continuous methods are very direct provided that the rather restrictive assumption can be made that all
anomalies are due to lateral magnetization changes due to basement topography This means that shallow effects and
large intrabasement anomalies must be removed from the data This involves judgement and skill as it is necessary to
distinguish between the lower amplitude suprabasement anomalies due to basement topography and the larger
intrabasement anomalies reflecting magnetization changes within the basement These methods were not considered
suitable for the Savory Sub-basin magnetic dataset but were used to invert the gravity data
50
Limitations of magnetic and gravity interpretation
Interpretation of the area is limited by a shortage of information on the nature and physical properties of the deeper
sedimentary sequence and the underlying basement rocks However using techniques such as cross-correlation of
gravity and pseudo-gravity data it is possible to try to differentiate between anomalies relating to basement and those
related to the sedimentary sequence
Gravity anomalies reflect changes within the sedimentary sequence as well as basement condition These
changes in density of sedimentary rocks produce gravity anomalies without a corresponding magnetic anomaly hence
the complementary nature of gravity and magnetic surveys The main use of magnetics is to determine depth to
magnetic basement and any intra-sedimentary volcanic rocks or intrusives whereas gravity provides much more
general information on the sedimentary sequence
Unfortunately interpretation of gravity anomalies is complicated since they can be due to a number of geological
features including
bull major basement faults
bull basement highs
bull igneous intrusions within the basement
bull sedimentary basins which may or may not be isostatically compensated
bull intra-sedimentary volcanics and associated plutonic centres
Two major problems affect the interpretation of both magnetic and gravity data
1 The inherent ambiguity of potential-field data There is no unique solution to any measured gravity or magnetic
anomaly and theoretically there will be an infinite number of source geometry and magnetizationdensity
combinations which will fit the observed data This means that any a priori information which helps to select a
suitable model is very useful
2 Measured anomalies are the summation of effects from different depths For example an observed gravity profile
may contain contributions from shallow sources (density variations within the sedimentary basin) intermediate
depth sources (density variations due to large igneous intrusions within the basement) and deep sources (crustal
thinning producing a mantle anomaly) Separation of these component responses is the regionalresidual problem
which we solve using spectral analysis and differential upward continuation-based separation filtering
Regional setting and interpretation overview
The area studied includes parts of BALFOUR DOWNS (SF51-9) RUDALL (SF51-10) ROBERTSON (SF51-13) GUNANYA
(SF51-14) COLLIER (SG50-4) BULLEN (SG51-1) TRAINOR (SG51-2) MADLEY (SG51-3) NABBERU (SG50-5)
STANLEY (SG51-6) and HERBERT (SG51-7) 1250 000 sheets Broadly the area lies between latitudes 22deg00rsquondash25deg30rsquoS
and longitudes 119deg30rsquondash123deg30rsquoE
51
Regional gravity
The AGSO regional gravity data (at nominal 11 km spacing) was gridded at a 4 km mesh spacing using a minimum-
curvature algorithm Bouguer gravity values in the area are negative reflecting mass deficiency at depth and range
from -84 mgals to -25 mgals
A Bouguer gravity colour image is shown as Figure 41 A residual grid was produced by removing a fifth-order
orthogonal polynomial from the Bouguer data but did not add to the interpretation
120deg 121deg 122deg 123deg
23deg
24deg
25deg
-25
-84
50 km
MKS46 180598
mgal
Figure 41 Regional Bouguer gravity (BMRAGSO data) gridded at 4 km
52
The data show a complex pattern of positive and negative anomalies with no clearly defined trends Correlations
with aeromagnetic data and known basin structures are poor A vague north-northwest linear trend appears to coincide
with the Marloo Fault (Figure 42) A prominent negative anomaly appears to coincide with the Blake Fold and Fault
Belt depocentre and continues as a narrower negative anomaly to the east until it widens out again near the edge of the
basin Elsewhere the gravity data show little correlation with known basin structures and it is likely that especially in
the north of the area gravity anomalies are due to density changes in the basement rather than changes in basement
topography
Production of wavelength-filtered residual gravity plots and vertical gradient plots showed very patchy aliased
data reflecting poor sampling in much of the area
Regional magnetics
The AGSO regional aeromagnetic data were gridded at a 400 m mesh spacing using a minimum-curvature algorithm
(Figure 43) Most of the data has a line spacing of 1600 m with small areas of 1 km spacing The quality of the data is
acceptable for regional interpretation but is not adequate for detailed analysis The accuracy of the flight path is rather
variable reflecting the vintage of the data and the noise envelope of the data is poor by modern standards Problems
were also encountered in joining different map sheets
The magnetic anomaly pattern over the south and west part of the area shows a strong high frequency signature
reflecting the presence of widespread basic sills and dykes Some of the major north-northeasterly trending dykes can
be traced over considerable distances
Discontinuous high-frequency anomalies extend as a northwest-trending zone through the centre of the area and
this zone includes a conspicuous circular magnetic anomaly which is probably a ring complex
The northern and eastern parts of the area are characterized by long-wavelength deep-seated basement magnetic
anomalies with 120deg and 150deg trends dominant The Marloo and Perentie Faults (Figure 42) appear as distinct linear
zones and offsets A prominent easterly trending negative anomaly in the northwest of the area appears to swing round
to the southeast and may separate different basement blocks One possible interpretation is that this very deep seated
anomaly separates areas of Archaean and Proterozoic basement
Regional geology
The regional geology is described in Williams (1992) The GSWA provided a digitized version of Plate 2 from this
Bulletin the structural interpretation map to use as an overlay (Figure 42)
53
Pp
Pp
PSd
PSd
PSd
PSd
PSd
PSo
PSt
PSt
PSf
PSf
PSf
PSb
PSb
PSb
PSsPSs
PSs
PSb
PSm
PSp
PSc
PSc
PSw
PSw
PSw
PSg
PSr
PSj
PSg
PM
Pk
PY
PY
PSd
L
L
L
L
L
L
L
LL
L
L
L
LL
L
LL
L L
LL
L L
L
L
L
L
L
L
L
LL
L
L
BLAKEDEPOCENTRE
MA
RLO
O
FAU
LT
PERENTIEFAULT
50 km
MKS39120598
120deg 121deg 122deg 123deg
25deg
24deg
23deg
Approximate boundaryof aeromagnetic interpretation
PML
PSgL
PSjL
PML
PSpL
PML
PML
PSfL
PSfL
PSpL
LPc
LPcLPcPSrL
LPA
Durba Sandstone
Woora Woora Formation
McFadden Formation
Tchukardine Formation
Boondawari Formation
Skates Hills Formation
Mundadjini Formation
Coondra Formation
Spearhole Formation
Watch Point Formation
Jilyili Formation
Brassey Range Formation
Glass Spring Formation
Paterson Formation
Yeneena Group
Karara Formation
Cornelia Formation
Kahrban Subgroup
Bangemall Group
Fault
Formation boundary
PSdL
PSoL
PSfL
PStL
PSbL
PSsL
PSmL
PScL
PSpL
PSwL
PSjL
PSrL
PSgL
Pp
PYL
PkL
LPc
LPA
PML
Savory Group Other Units
PYL
Figure 42 Regional geology and structure map (after Williams 1992)
54
120deg 121deg 122deg 123deg
23deg
24deg
25deg
5820
3750
MKS47 180598
nT
50 km
Figure 43 Regional aeromagnetic data total magnetic intensity (BMRAGSO data) gridded at 400 m
Analysis
3D analysis
3D Euler deconvolution was used as the primary depth-determination method The advantage of this approach is that
consistent solutions can be obtained over the entire area with minimal assumptions about source geometries Euler
deconvolution of gridded data is used for positional information and estimation of depth to top of source Euler
55
deconvolution yields a large number of depth solutions which have to be screened to reject spurious solutions Results
are plotted as circles in eight depth ranges with radius proportional to depth and colour coded
The 400 m total magnetic intensity grid was used for the analysis Horizontal gradients in x and y and the vertical
gradient were calculated 3D Euler deconvolution was tested on the 400 m gridded data using windows of 9 times 9 and
11 times 11 and 16 times 16 data points and structural indices 05 (fault) and 10 (sill or dyke) It was concluded that the
16 times 16 window produced the best results overall and final plots were produced for the 16 times 16 window and structural
index 05 (Fig 44) Results were very good over the northern and central parts of the area showing magnetic sources
Figure 44 Depth to magnetic source 3D Euler deconvolution 16 times 16 window of 400 m gridded data structural index 05
56
at several different levels Unfortunately in the extreme south of the area shallow intrasedimentary magnetic sources
(sills and dykes) dominated the inversion and the results contained few basement solutions
In order to reduce these problems the 400 m gridded data were filtered using a separation filter based on
interpretation of the log-energy spectrum The 3D Euler method was run on the filtered data in order to generate more
basement-depth solutions Results for the deep-separation filter data were gridded and presented as a colour image in
Cowan (1995) Attempts to grid the Euler output were unsatisfactory and it is considered safer to interpret the 3D
Euler depth plots The 3D Euler depth results from the separation-filter run should be analysed with care as perfect
separation of the basement can never be achieved and there will always be some contamination from sources at
different levels
The results of original total magnetic intensity 3D Euler depth estimation for structural index 05 using a 16 point
window have been plotted at 1500 000 scale (not included in this publication but available in Cowan (1995) from the
GSWA Library as S10331) and as reduced A4 colour circle plots (Figure 44)
The results of deep-basement 3D Euler depth estimation for structural index 05 using a 16 point window have
been plotted as a colour image at 1500 000 scale and as an A4 image (not included in this publication)
2D analysis
Two equispaced profiles were interpolated with a 50 m station interval from the AGSO-located data profiles for the
BULLEN 1250 000 sheet The interpolated profiles were analysed using 2D Euler deconvolution and Werner
deconvolution Results are included in Cowan (1995) and show the use of these methods for more detailed analysis
Filtered data
In order to reconcile 3D Euler results from shallow basement and intrasedimentary magnetic sources we produced
several separation-filtered maps and images We found the shallow-layer double-separation filter (Figure 45) to be
very effective for shallow sources and the deep-layer standard-separation filter (Figure 46) for the basement layer
Gravity and magnetic data correlation
Both lsquoreduced to the polersquo (RTP) magnetics (Figure 47) and pseudo-gravity data (Figure 48) were produced as part of
the reconciliation of gravity and magnetic signatures In both cases the filtering operations assumed magnetization by
induction in the present Earths field The RTP data are fairly similar to the total magnetic intensity The pseudo-
57
gravity data are dominated by a northwest-trending strong positive anomaly and there is little correlation with the
Bouguer gravity data
The poor magneticgravity correlation is confirmed by cross-correlation of the RTP magnetics and the gravity
gradient The correlation plot in Figure 49 shows little coherent response with numerous zones of positive and
negative correlation
Figure 45 Regional aeromagnetic data shallow layer separation filter (BMRAGSO data) gridded at 400 m
Results
In the north and east of the area on the Wells Foreland Sub-basin trend (refer to Figure 1 main text) we see a range
of quite deep 3D Euler depths and several trend directions with north-northwesterly dominant There are relatively few
shallow intrasedimentary solutions in this zone
The second area of deep 3D Euler solutions lies over the Blake depocentre (Figure 43) with several trend
directions
Elsewhere the 3D Euler results are dominated by shallow intrasedimentary depth solutions reflecting mainly the
dolerite sills dykes and the ring complex However where we do see basement-related solutions in the south and
west of the area they appear to be shallower than those noted for the Wells Foreland Sub-basin and the Blake
depocentre
58
Figure 46 Regional aeromagnetic data deep-layer separation filter (BMRAGSO data) gridded at 400 m
Figure 48 Regional aeromagnetic data pseudo-gravity transform (BMRAGSO data) gridded at 400 m
Figure 47 Regional aeromagnetic data reduced-to-pole (BMRAGSO data) gridded at 400 m
Figure 49 Regional aeromagnetic and gravity data gravitymagnetic correlation using RTP magnetics and gravity gradient (BMRAGSO data) gridded at 4 km
59
This subdivision of the area into two zones of deep solutions is consistent with interpreted depocentres
However the interference between sources at different levels and the complexity of the magnetic response of the
basement rocks precludes more refined interpretation at this stage
The area of deep 3D Euler solutions over the Blake depocentre correlates with the pronounced negative gravity
anomaly discussed in the gravity interpretation section Using a density contrast of -015 gcc the negative gravity
anomaly could indicate up to 6ndash8 km of low-density sedimentary rocks depending on assumptions about the regional
field
The area of deep 3D Euler solutions over the Wells Foreland Sub-basin has a complex gravity expression and no
clear basin structure emerges from inversion of these data As noted previously it is likely that observed gravity
anomalies reflect contrasts in basement density rather than basement topography
Separation filtering applied to the magnetic data helps to enhance the intrasedimentary magnetic signature and to
give a better impression of the basement magnetic signature even though separation of the basement response is not
perfect
Conclusions
Quantitative aeromagnetic interpretation using 3D Euler deconvolution supported by wavenumber filtering and image
processing has been successful in providing structural trend and depth information for the Savory Sub-basin
Quantitative magnetic interpretation has revealed two zones of relatively deep magnetic basement beneath the
Wells Foreland Sub-basin and the Blake depocentre
This analysis of the magnetic data supports interpreted depocentres but the complexity of the basement magnetic
signature and interference from sources at different depths precludes further refinement to a map of basement
topography
Regional gravity proved to be very useful in understanding the regional setting of the area and in providing
support for aspects of the interpretation The gravity data support the interpretation of the Blake depocentre
suggesting up to 6ndash8 km of low-density sedimentary rocks
The deep structure of the Savory Sub-basin area is obviously complex with different areas underlain by
Archaean and Proterozoic basement and with the Capricorn suture occurring in the centre of the area
60
Recommendations
The quantitative magnetic interpretation needs to be reconciled with geological models available for the area
In particular the zones tentatively identified as areas with thick sedimentary rocks the Wells Foreland Sub-
basin and the Blake depocentre need to be investigated
Cross sections should be prepared across the basin for joint magneticgravity modelling especially for the Blake
depocentre It is important to be able to explain the strong negative gravity anomaly in this area
In view of the effects of basement density contrasts on the gravity field for the northern part of the area we think
that additional gravity interpretation and acquisition of new gravity data may not be justified as they will not
contribute significantly to understanding basin evolution and structure
It is recommended that GSWA try to get access to company confidential high-resolution aeromagnetic data
rather than flying new surveys The GSWA might offer to fund flying of new infill areas as a bargaining point
References
The original text of this report by Cowan (1995) and 1500 000 scale maps are filed in the GSWA Library under
S10331
COWAN D 1995 Savory Basin quantitative magnetic interpretation Western Australia Geological Survey S-series
S10331 (unpublished)
VACQUIER V STEENLAND N C HENDERSON R G and ZIETZ I 1951 Interpretation of aeromagnetic
maps The Geological Society of America Memoir 47 151p
WILLIAMS I R 1992 Geology of the Savory Basin Western Australia Western Australia Geological Survey
Bulletin 141 115p
61
Appendix 5
Geochemistry
MKS38 250398
Saturate FractionC12+ GLC
1217
Pr18
Ph
22
31CSR WELL-13 315m Cuttings
Figure 51 Canning Stock Route Well 13 gas chromatograph of extract of auger drill sample
12
17
18
22
31
Pr Ph
LDDH 1 6623m CoreSaturate FractionC12+ GLC
MKS35 240398
Figure 52 Gas chromatograph of extract from core sample at 6623 m LDDH1
62
Table 51 Canning Stock Route Well 13 auger drill samples
GSWA sample Drill depth (m)(a) Comments
135601 150 At watertable 135602 203 (all samples consist 135603 310 of sand mud and water) 135604 315 At total depth
NOTE (a) Datum for drill depth is the top of sediment fill in the well which is 155 m below ground level (ie the total depth of 315 m is 47 m below ground level)
Table 52 Canning Stock Route Well 13 gas chromatography data for 315 m depth sediment sample
Parameter Value
Weight of rock extracted (grams) 945 Total extract (ppm) 519 n-Alkane distribution n-C12 07 n-C13 23 n-C14 26 n-C15 22 n-C16 19 n-C17 14 i-C19 23 n-C18 14 i-C20 08 n-C19 11 n-C20 16 n-C21 25 n-C22 29 n-C23 70 n-C24 42 n-C25 95 n-C26 43 n-C27 83 n-C28 38 n-C29 87 n-C30 31 n-C31 273 Alkane compositional data Pristane phytane ratio 279 Pristane n-C17 ratio 161 Phytane n-C18 ratio 059 CPI (1)(a) 284 CPI (2) 209 (C21 + C22) (C28 + C29) 043
NOTE (a) CPI= Carbon preference index
63
Table 53 LDDH1 extract liquid chromatography data for 6623 m concentration
Rock extracted Total extract (grams) (ppm)
702 313
NOTE ppm= parts per million
Table 54 LDDH1 saturate gas chromatography data of core for 6623 m alkane composition
Pristane Pristane Phytane (a) CPI (1) CPI (2) (C21+C22) Phytane n-C17 n-C18 (C28+C29)
103 026 024 103 102 325
NOTE (a)CPI = carbon preference index
Table 55 LDDH1 saturate gas chromatography data of core for 6623 m n-alkane distributions
Parameter Value
n-C12 17 n-C13 38 n-C14 55 n-C15 60 n-C16 65 n-C17 74 i-C19 19 n-C18 78 i-C20 19 n-C19 80 n-C20 79 n-C21 71 n-C22 64 n-C23 57 n-C25 43 n-C24 38 n-C27 31 n-C28 23 n-C29 19 n-C30 12 n-C31 10
64
Appendix 6
Table 61 Summary of data from Trainor waterbores (TWB) and Bullen waterbores (BWB)
Well AMG Elevation TD Status(b) Completion details Water Salinity Water level Flow rate Depth to consolidated AGD84 GL (m) (m) struck mgl(c) (m) (LHr) lithology aquifer(e) Z51(a) Interval (m) (100 mm PVC) (m) (mgl)(d)
TWB 1 473660E 453 122 comp 0ndash75 plain 63 7 300 24 2 880 12 m 7287404N 75ndash93 slotted (9 260) McFadden Fm 93ndash99 plain TWB 2 472 977E 475 23 abd nil 15 m 7285877N Skates Hills Fm dry TWB 3 473259E 475 50 abd nil 7 m 7285849N Skates Hills Fm dry TWB 4 463225 E 445 50 comp 0ndash22 plain 35 7 200 55 3 600 0 m 7286143N 22ndash34 slotted (8 140) Tertiary sand and gravel 23ndash60 plain TWB 5 463095E 445 31 comp 0ndash19 plain 13 26 000 655 3 600 Tertiary sand and gravel 7277721N 19ndash25 slotted (36 700) 25ndash31 plain TWB 6 457013E 455 50 comp 0ndash42 plain 38 920 119 600 0 m 7274352N 42ndash48 slotted (1 030) Cornelia Fm ss TWB 7 453739E 475 26 susp 0ndash2 plain 11 9 300 48 4 500 0 m 7263891N (10 500) Tertiary sand TWB 8 433893E 535 60 susp 0ndash2 plain 47 8 500 gt46 1 200 0 m 7245991N (10 900) Tertiary sand and Brassey Range Fm ss TWB 9 437219E 505 51 comp 0ndash47 plain 45 1 000 58 600 1 m 7235905N 47ndash51 slotted (990) Brassey Range Fm ss TWB 10 434927E 495 32 susp 0ndash2 plain 235 450 120 0 m 7225875N (500) Dolerite
65
BWB 1 287337E 580 122 abd Nil 1 m 7245861N Jilyili Fm dry BWB 2 288346E 545 50 comp 0ndash26 plain 15 630 3 29 000 0 m 7240423N 26ndash38 slotted (730) Tertiary sand and gravel 38ndash50 plain BWB 3 305637E 545 50 abd 19 8 800 43 7 200 0 m 7240423N (10 550) Tertiary ss BWB 4 320167E 515 445 comp 0ndash20 plain 9 980 445 24 000 0 m 7248097N 20ndash32 slotted (1 190) Tertiary ss 32ndash44 plain BWB 5 353393E 545 20 susp 0ndash2 plain 45 (970) 1 m 7238934N Basalt
NOTES (a) GPS accuracy ~ 150 m (b) Comp = completed abd = abandoned susp = suspended (c) Salinity from conductivity (d) Analysis total dissolved solids (e) Fm = Formation ss = sandstone
39
WILLIAMS I R 1995a Bullen WA (2nd Edition) Western Australia Geological Survey
1250 000 Geological Series Explanatory Notes 23p
WILLIAMS I R 1995b Trainor WA (2nd Edition) Western Australia Geological Survey
1250 000 Geological Series Explanatory Notes 31p
WILLIAMS I R and TYLER I M 1991 Robertson WA (2nd edition) Western Australia
Geological Survey 1250 000 Geological Series Explanatory Notes 36p
40
41
Appendix 1
Bibliography
Reports which are relevant to this investigation but which are not specifically cited are listed
below
BAILLIE P W POWELL C McA LI Z X and RYALL A M 1994 The tectonic
framework of Western Australiarsquos Neoproterozoic to recent sedimentary basins in The
sedimentary basins of Western Australia edited by P G PURCELL and R R PURCELL
Petroleum Exploration Society of Australia Symposium Perth WA 1994 Proceedings p
45ndash62
BRADSHAW M T BRADSHAW J MURRAY A P NEEDHAM D J SPENCER L
SUMMONS R E WILMOT J and WINN S 1994 Petroleum systems in West Australian
basins in The sedimentary basins of Western Australia edited by P G PURCELL and R R
PURCELL Petroleum Exploration Society of Australia Symposium Perth WA 1994
Proceedings p 93ndash118
CLARKE G L 1991 Proterozoic tectonic reworking in the Rudall Complex Western Australia
Australian Journal of Earth Science v38 p 31ndash44
COCKBAIN A E and HOCKING R M 1990 Phanerozoic in Geology and mineral resources
of Western Australia Western Australia Geological Survey Memoir 3 p 750ndash755
ETHERIDGE M and WALL V 1994 Tectonic and structural evolution of the Australian
Proterozoic 12th Australian Geological Convention Geological Society of Australia
Abstracts no 37 p 102ndash103
GOODE A D T 1981 Proterozoic geology of Western Australia in Precambrian of the
Southern Hemisphere Developments in Precambrian geology 2 edited by I R HUNTER
Amsterdam Elsevier p 105ndash203
GREY K and JACKSON M J 1983 A re-assessment of stromatolite evidence for the
correlation of the Late Proterozoic Neale and Ilma Beds Officer Basin Western Australia
Australia BMR Journal of Australian Geology and Geophysics v 8 p 359
42
HICKMAN A H WILLIAMS I R and BAGAS L 1994 Proterozoic geology and
mineralization of the TelferndashRudall region Paterson Orogen Geological Society of Australia
(WA Division) Excursion Guidebook no 5 56p
HOCKING R M MORY A J and WILLIAMS I R 1994 An atlas of Neoproterozoic and
Phanerozoic basins of Western Australia in The sedimentary basins of Western Australia
edited by P G PURCELL and R R PURCELL Petroleum Exploration Society of Australia
Symposium Perth WA 1994 Proceedings p 21ndash 44
JACKSON P R 1966 Geology and review of exploration Officer Basin Western Australia
Hunt Oil Company Western Australia Geological Survey S-series S26 (unpublished)
JACKSON M J 1971 Notes on a geological reconnaissance of the Officer Basin Western
Australia Australia BMR Geology and Geophysics Record 19715 30p
JACKSON M J and van de GRAAFF W J E 1981 Geology of the Officer Basin Western
Australia Australia BMR Geology and Geophysics Bulletin 206 102 p
LOWRY D C JACKSON M J van de GRAAFF W J E and KENNEWELL P J 1971
Preliminary result of geological mapping in the Officer Basin Western Australia Western
Australia Geological Survey Annual Report for 1971 p 50ndash56
MYERS J S 1990 Precambrian in Geology and mineral resources of Western Australia
Western Australia Geological Survey Memoir 3 p 737ndash750
MYERS J S SHAW R D and TYLER I M 1994 Proterozoic tectonic evolution of
Australia 12th Australian Geological Convention Geological Society of Australia Abstracts
no 37 p 312
NEDIN C and JENKINS R J F 1991 Re-evaluation of unconformities separating the
lsquoEdiacaranrsquo and Cambrian systems South Australia Palaios v 6 p 102ndash108
PHILLIPS B J JAMES A W and PHILIP G M 1985 The geology and hydrocarbon
potential of the north-western Officer Basin APEA Journal 25 (1) p 52ndash61
POWELL C McA LI Z X McELHINNY M W MEERT J G and PARK J K 1993
Paleomagnetic constraints on timing of the Neoproterozoic breakup of Rodinia and Cambrian
formation of Gondwana Geology v 21 p 889ndash892
43
POWELL C McA PREISS W V GATEHOUSE C G KRAPEZ B and LI Z X 1994
South Australian record of a Rodinian epicontinental basin and its mid-Neoproterozoic
breakup to form the Palaeo-Pacific Ocean Tectonophysics v 237 no 3ndash4 p 113ndash140
PREISS W V 1976 Proterozoic stromatolites from the Nabberu and Officer Basins Western
Australia and their biostratigraphic significance South Australia Geological Survey Report
of Investigations no 47 p 1ndash51
TOWNSON W G 1985 The subsurface geology of the western Officer Basin mdash results of
Shellrsquos 1980ndash1984 petroleum exploration campaign APEA Journal v 25 (1) p 34ndash51
WATTS K J 1982 The geology of the Townsend Quartzite Upper Proterozoic shallow water
deposit of the Northern Officer Basin Western Australia Perth University of Western
Australia BSc honours thesis (unpublished)
WELLS A T and KENNEWELL P J 1974 Evaporite exploration in the Officer Basin
Western Australia at the Madley Diapirs Australia BMR Record 1974194 (unpublished)
WILLIAMS I R and MYERS J S 1990 Paterson Orogen in Geology and mineral resources
of Western Australia Western Australia Geological Survey Memoir 3 p 274ndash286
WILLIAMS I R 1990 Savory Basin in Geology and mineral resources of Western Australia
Western Australia Geological Survey Memoir 3 p 329ndash334
WILLIAMS I R 1994 The Neoproterozoic Savory Basin Western Australia in The
sedimentary basins of Western Australia edited by P G PURCELL and R R PURCELL
Petroleum Exploration Society of Australia Symposium Perth WA 1994 Proceedings p
841ndash850
WILSON R B 1967 Woolnough Hills and Madley diapiric structures Gibson Desert WA
APEA Journal v 7 p 94ndash102
44
Appendix 2
Meteorological data (from Bureau of Meteorology Perth 1994)
Table 21 Wiluna rainfall (mm)
Year Jan Feb Mar Apr May Jun Jul Aug Sept Oct Nov Dec
1975 0 45 446 309 306 59 276 4 34 886 638 164 1976 16 154 12 138 53 16 34 62 12 238 0 2 1977 44 0 66 74 68 95 24 363 1 58 12 727 1978 234 522 94 16 0 96 367 24 16 353 185 45 1979 19 173 122 88 91 4 0 246 58 0 169 114 1980 148 764 68 1081 259 626 629 06 56 02 174 0 1981 123 476 192 32 196 118 44 74 14 0 28 312 1982 374 705 206 244 1079 92 02 143 368 526 368 118 1983 1 112 928 248 0 212 56 32 5 1 42 496 1984 149 7 342 84 836 0 348 132 224 04 16 172 1985 596 483 0 166 556 0 514 56 0 0 4 0 1986 0 154 35 0 0 1085 23 01 239 137 0 04 1987 1204 119 19 89 17 575 154 126 07 1 0 398 1988 46 202 164 13 388 0 202 104 0 0 224 1309 1989 207 234 26 703 278 536 57 0 01 0 144 02 1990 1035 23 281 46 126 53 94 218 44 9 42 0 1991 48 0 41 45 0 472 297 12 0 1 0 7 1992 112 96 1025 1227 323 65 04 174 0 132 48 4 1993 0 697 0 202 445 0 12 306 18 05 14 33 Mean 25 35 22 27 27 25 18 12 6 13 13 21
JAN FEB MAR APR MAY JUN JUL AUG SEP OCT NOV DEC0
10
20
30
40
Mea
n R
ain
fall
(mm
)
Month
Mean monthly rainfall in Wiluna
MKS41 140498
45
Table 22 Wiluna minimum temperature (degC)
Year Jan Feb Mar Apr May Jun Jul Aug Sept Oct Nov Dec
1975 ndash 23 203 15 94 63 71 62 103 124 169 205 1976 242 229 194 15 10 63 59 73 95 143 16 228 1977 243 25 197 148 96 95 56 86 102 ndash 188 23 1978 241 232 203 18 102 64 76 8 9 152 19 205 1979 255 226 216 167 83 6 59 79 97 145 198 223 1980 255 226 231 155 134 83 68 75 121 108 193 223 1981 245 216 19 182 119 6 54 78 138 159 163 218 1982 232 224 177 16 ndash ndash 37 111 112 164 209 225 1983 235 24 197 147 112 88 39 88 121 162 189 219 1984 241 243 191 156 ndash 72 66 7 95 161 182 211 1985 244 231 ndash 159 98 65 71 73 117 147 205 ndash 1986 ndash 229 226 155 93 96 43 49 10 122 ndash 219 1987 ndash 217 183 175 85 77 68 68 112 ndash ndash 221 1988 238 214 209 178 111 ndash ndash 86 104 157 171 195 1989 ndash 237 199 165 107 67 44 61 107 131 187 ndash 1990 232 ndash 211 155 118 62 57 87 102 149 195 22 1991 26 256 217 168 122 101 78 ndash 113 18 168 219 1992 227 227 214 169 102 98 59 69 ndash 125 159 196 1993 241 218 196 171 103 ndash 49 68 88 128 192 211 Mean 24 23 20 16 10 8 6 8 11 14 18 21
NOTE Dashes indicate data unavailable
JAN FEB MAR APR MAY JUN JUL AUG SEP OCT NOV DEC0
10
20
30
40
Month
MKS43 140498
50
Mean monthly minimum temperatures at Wiluna
Mea
n T
emp
erat
ure
(degC
)
46
Table 23 Wiluna maximum temperature (degC)
Year Jan Feb Mar Apr May Jun Jul Aug Sept Oct Nov Dec
1975 ndash 349 326 281 247 201 197 212 256 248 31 344 1976 374 369 346 297 248 206 208 225 265 287 313 388 1977 397 392 352 296 234 212 222 244 ndash 308 337 383 1978 378 345 346 316 242 195 176 205 231 295 334 356 1979 403 36 364 295 ndash ndash ndash 193 242 318 359 373 1980 392 342 377 275 24 176 179 233 292 288 349 391 1981 385 346 337 342 242 178 201 224 30 326 326 369 1982 372 359 315 307 ndash ndash 196 253 252 305 353 379 1983 381 389 327 272 263 222 187 248 287 321 336 366 1984 378 393 322 299 226 215 178 214 234 ndash 336 364 1985 40 366 ndash 294 224 216 205 212 284 307 355 ndash 1986 ndash 383 372 307 ndash 193 166 196 261 277 ndash 382 1987 ndash 339 328 305 21 202 214 218 275 ndash ndash 374 1988 388 365 353 301 23 ndash ndash 228 283 334 31 33 1989 ndash 375 339 285 238 179 181 219 275 298 336 ndash 1990 368 ndash 36 309 268 19 188 205 274 309 373 393 1991 414 416 363 315 268 206 21 ndash 279 338 332 368 1992 363 383 336 263 213 178 213 197 ndash 285 313 359 1993 396 357 344 301 221 ndash 197 215 253 294 347 362 Mean 39 37 34 30 24 20 20 22 27 30 34 37 NOTE Dashes indicate data unavailable
JAN FEB MAR APR MAY JUN JUL AUG SEP OCT NOV DEC0
10
20
30
40
Month
MKS42 140498
50
Mean monthly maximum temperatures at Wiluna
Mea
n T
emp
erat
ure
(degC
)
47
Appendix 3
Table 31 Summary of palynological results
Drillhole Depth (m) F no(a) GSWA no Lithology Formation Assemblage TAI(b)
BWB 1 74ndash75 F49668 135741 dark-grey siltstone basalt Jilyilli gt5 BWB 1 98ndash100 F49669 135742 dark-grey siltstone basalt Jilyilli gt5 BWB 1 121ndash122 F49670 135743 dark-grey siltstone basalt Jilyilli gt5 TWB 1 86ndash87 F49671 135631 dark-grey siltstone McFadden 3+ TWB 1 104ndash105 F49672 135632 dark-grey siltstone Cornelia 3+ TWB 1 121ndash122 F49673 135633 dark-grey siltstone Cornelia 4 TWB 2 14ndash15 F49674 135634 dark-grey siltstone Skates Hills 3+ TWB 6 49ndash50 F49675 135675 dark-grey siltstone Cornelia 1 3+ TWB 9 49ndash51 F49676 135704 dark-grey siltstone Brassey Range 1 3+ Trainor 1 37497- F49733 138939 black mudstone with Cornelia 5 37509 light-grey siltstone Trainor 1 3809 F49734 138940 dark-grey and black Cornelia 4- laminated mudstone Trainor 1 4170 F49735 138941 black unlaminated mudstone Cornelia 4- Trainor 1 4950 F49851 139501 dark-grey indurated siltstone Cornelia 5 Trainor 1 6032 F49852 139502 dark- and light-grey Cornelia 5 indurated siltstone Trainor 1 6434 F49853 139503 greenish indurated finely Cornelia 5 laminated siltstone LDDH 1 270 F49678 138934 dark-grey siltstone interbeds Waters 1 3+ in enterolithic evaporite Tarcunyah Gp LDDH 1 277 F49679 138935 dark-grey siltstone in cavity Waters 1 3+ in enterolithic evaporite Tarcunyah Gp
NOTES (a) GSWA Fossil Catalogue number (b) TAI = Thermal Alteration Index of Traverse (1988 plate 1)
48
Appendix 4
Savory Sub-basin quantitative magnetic and gravity interpretation (extracted from Cowan 1995)
Summary
A program of quantitative aeromagnetic interpretation has been completed on BMRAGSO data from the Savory Sub-
basin Western Australia Quantitative aeromagnetic interpretation utilized the 3D Euler deconvolution method
supported by wavenumber filtering and image processing The results have provided useful information on structural
trends and depth to magnetic sources in a structurally complex area Depth to magnetic source analysis has provided
information on intra-sedimentary magnetic sources as well as basement rocks
The results of the interpretation support previously identified depocentres However the presence of magnetic
sources at several levels makes it very difficult to produce a reliable magnetic basement depth contour map It is
considered more productive to work with the 3D Euler colour circle plots and images rather than trying to contour the
results It would be necessary to carry out a full-scale interpretation of the BMRAGSO profile data to improve on the
3D Euler results The regional gravity was found to be useful in interpreting the regional setting of the area although
the very wide data spacing limits quantitative use of the data The gravity data show quite a complex picture with
limited consistent correlation between gravity features and basin structures This suggests that gravity anomalies
reflect changes in density of the basement rocks rather than basement topography especially in the northern part of the
basin
It is recommended that the GSWA investigate access to company confidential high-resolution aeromagnetic data
prior to planning further aeromagnetic surveys Private companies have flown large parts of the northern half of the
area as part of their diamond exploration program Additional gravity coverage of the area may be more cost effective
than magnetic surveys as the gravity data provides more information on changes within the sedimentary section
Introduction
The main use of aeromagnetic data in petroleum exploration has been the determination of magnetic basement
topography although there has been increasing interest in analysis of intra-sedimentary magnetic anomalies
intrabasement and suprabasement magnetic anomalies These anomalies are used to determine depth to magnetic
basement rocks and hence determine the thickness of the sedimentary sequence Unfortunately interpretation of the
intrabasement and suprabasement magnetic anomalies is non-unique in terms of position and size of causative sources
because of the inherent ambiguity of potential-field methods However this ambiguity can be reduced by placing
49
constraints on source geometry and magnetization and by using geological and other geophysical data to constrain
the solution
Before 1970 most depth-determination techniques involved graphical determination of slopes of selected
magnetic anomalies and application of various empirical factors to convert the slopes into depth estimates Geological
Society of America Memoir 47 Interpretation of Aeromagnetic Maps by Vacquier et al (1951) was a landmark for
this type of interpretation
Automated interpretation procedures have played an increasingly important role in depth interpretation and a
wide range of techniques have been developed Many of these techniques are designed for application to located data
profiles and assume a two-dimensional geometry However there has been renewed interest in techniques applicable
to gridded data
Two distinct types of method can be recognized In the first case often described as discrete methods individual
isolated magnetic anomalies are interpreted and the results used to produce a map of basement relief In the second
case often described as continuous methods areas of data containing a number of anomalies are interpreted
statistically to produce direct output of basement depths
The discrete methods usually involve a semiautomatic initial phase which generates a large number of possible
depth solutions and an interactive second phase to screen and select acceptable solutions The advantage of this
approach is that the interpreter can select features that are relatively free from interference from adjacent anomalies
and consider all aspects of a particular magnetic anomaly The disadvantage is that interpretation can be very time
consuming as a wide range of depths are usually possible depending on the initial model chosen and a significant
amount of effort is needed to select the correct model In the case of the Savory Sub-basin dataset we encountered
problems in separating basement related effects from the effects of shallower intrasedimentary magnetic sources
Because of these problems we have concentrated on displaying the Euler results accompanied by separation filter
images of the data to show the shallower effects and deeper effects rather than trying to refine a 3D Euler
deconvolution depth-to-crystalline-basement contour
The continuous methods are very direct provided that the rather restrictive assumption can be made that all
anomalies are due to lateral magnetization changes due to basement topography This means that shallow effects and
large intrabasement anomalies must be removed from the data This involves judgement and skill as it is necessary to
distinguish between the lower amplitude suprabasement anomalies due to basement topography and the larger
intrabasement anomalies reflecting magnetization changes within the basement These methods were not considered
suitable for the Savory Sub-basin magnetic dataset but were used to invert the gravity data
50
Limitations of magnetic and gravity interpretation
Interpretation of the area is limited by a shortage of information on the nature and physical properties of the deeper
sedimentary sequence and the underlying basement rocks However using techniques such as cross-correlation of
gravity and pseudo-gravity data it is possible to try to differentiate between anomalies relating to basement and those
related to the sedimentary sequence
Gravity anomalies reflect changes within the sedimentary sequence as well as basement condition These
changes in density of sedimentary rocks produce gravity anomalies without a corresponding magnetic anomaly hence
the complementary nature of gravity and magnetic surveys The main use of magnetics is to determine depth to
magnetic basement and any intra-sedimentary volcanic rocks or intrusives whereas gravity provides much more
general information on the sedimentary sequence
Unfortunately interpretation of gravity anomalies is complicated since they can be due to a number of geological
features including
bull major basement faults
bull basement highs
bull igneous intrusions within the basement
bull sedimentary basins which may or may not be isostatically compensated
bull intra-sedimentary volcanics and associated plutonic centres
Two major problems affect the interpretation of both magnetic and gravity data
1 The inherent ambiguity of potential-field data There is no unique solution to any measured gravity or magnetic
anomaly and theoretically there will be an infinite number of source geometry and magnetizationdensity
combinations which will fit the observed data This means that any a priori information which helps to select a
suitable model is very useful
2 Measured anomalies are the summation of effects from different depths For example an observed gravity profile
may contain contributions from shallow sources (density variations within the sedimentary basin) intermediate
depth sources (density variations due to large igneous intrusions within the basement) and deep sources (crustal
thinning producing a mantle anomaly) Separation of these component responses is the regionalresidual problem
which we solve using spectral analysis and differential upward continuation-based separation filtering
Regional setting and interpretation overview
The area studied includes parts of BALFOUR DOWNS (SF51-9) RUDALL (SF51-10) ROBERTSON (SF51-13) GUNANYA
(SF51-14) COLLIER (SG50-4) BULLEN (SG51-1) TRAINOR (SG51-2) MADLEY (SG51-3) NABBERU (SG50-5)
STANLEY (SG51-6) and HERBERT (SG51-7) 1250 000 sheets Broadly the area lies between latitudes 22deg00rsquondash25deg30rsquoS
and longitudes 119deg30rsquondash123deg30rsquoE
51
Regional gravity
The AGSO regional gravity data (at nominal 11 km spacing) was gridded at a 4 km mesh spacing using a minimum-
curvature algorithm Bouguer gravity values in the area are negative reflecting mass deficiency at depth and range
from -84 mgals to -25 mgals
A Bouguer gravity colour image is shown as Figure 41 A residual grid was produced by removing a fifth-order
orthogonal polynomial from the Bouguer data but did not add to the interpretation
120deg 121deg 122deg 123deg
23deg
24deg
25deg
-25
-84
50 km
MKS46 180598
mgal
Figure 41 Regional Bouguer gravity (BMRAGSO data) gridded at 4 km
52
The data show a complex pattern of positive and negative anomalies with no clearly defined trends Correlations
with aeromagnetic data and known basin structures are poor A vague north-northwest linear trend appears to coincide
with the Marloo Fault (Figure 42) A prominent negative anomaly appears to coincide with the Blake Fold and Fault
Belt depocentre and continues as a narrower negative anomaly to the east until it widens out again near the edge of the
basin Elsewhere the gravity data show little correlation with known basin structures and it is likely that especially in
the north of the area gravity anomalies are due to density changes in the basement rather than changes in basement
topography
Production of wavelength-filtered residual gravity plots and vertical gradient plots showed very patchy aliased
data reflecting poor sampling in much of the area
Regional magnetics
The AGSO regional aeromagnetic data were gridded at a 400 m mesh spacing using a minimum-curvature algorithm
(Figure 43) Most of the data has a line spacing of 1600 m with small areas of 1 km spacing The quality of the data is
acceptable for regional interpretation but is not adequate for detailed analysis The accuracy of the flight path is rather
variable reflecting the vintage of the data and the noise envelope of the data is poor by modern standards Problems
were also encountered in joining different map sheets
The magnetic anomaly pattern over the south and west part of the area shows a strong high frequency signature
reflecting the presence of widespread basic sills and dykes Some of the major north-northeasterly trending dykes can
be traced over considerable distances
Discontinuous high-frequency anomalies extend as a northwest-trending zone through the centre of the area and
this zone includes a conspicuous circular magnetic anomaly which is probably a ring complex
The northern and eastern parts of the area are characterized by long-wavelength deep-seated basement magnetic
anomalies with 120deg and 150deg trends dominant The Marloo and Perentie Faults (Figure 42) appear as distinct linear
zones and offsets A prominent easterly trending negative anomaly in the northwest of the area appears to swing round
to the southeast and may separate different basement blocks One possible interpretation is that this very deep seated
anomaly separates areas of Archaean and Proterozoic basement
Regional geology
The regional geology is described in Williams (1992) The GSWA provided a digitized version of Plate 2 from this
Bulletin the structural interpretation map to use as an overlay (Figure 42)
53
Pp
Pp
PSd
PSd
PSd
PSd
PSd
PSo
PSt
PSt
PSf
PSf
PSf
PSb
PSb
PSb
PSsPSs
PSs
PSb
PSm
PSp
PSc
PSc
PSw
PSw
PSw
PSg
PSr
PSj
PSg
PM
Pk
PY
PY
PSd
L
L
L
L
L
L
L
LL
L
L
L
LL
L
LL
L L
LL
L L
L
L
L
L
L
L
L
LL
L
L
BLAKEDEPOCENTRE
MA
RLO
O
FAU
LT
PERENTIEFAULT
50 km
MKS39120598
120deg 121deg 122deg 123deg
25deg
24deg
23deg
Approximate boundaryof aeromagnetic interpretation
PML
PSgL
PSjL
PML
PSpL
PML
PML
PSfL
PSfL
PSpL
LPc
LPcLPcPSrL
LPA
Durba Sandstone
Woora Woora Formation
McFadden Formation
Tchukardine Formation
Boondawari Formation
Skates Hills Formation
Mundadjini Formation
Coondra Formation
Spearhole Formation
Watch Point Formation
Jilyili Formation
Brassey Range Formation
Glass Spring Formation
Paterson Formation
Yeneena Group
Karara Formation
Cornelia Formation
Kahrban Subgroup
Bangemall Group
Fault
Formation boundary
PSdL
PSoL
PSfL
PStL
PSbL
PSsL
PSmL
PScL
PSpL
PSwL
PSjL
PSrL
PSgL
Pp
PYL
PkL
LPc
LPA
PML
Savory Group Other Units
PYL
Figure 42 Regional geology and structure map (after Williams 1992)
54
120deg 121deg 122deg 123deg
23deg
24deg
25deg
5820
3750
MKS47 180598
nT
50 km
Figure 43 Regional aeromagnetic data total magnetic intensity (BMRAGSO data) gridded at 400 m
Analysis
3D analysis
3D Euler deconvolution was used as the primary depth-determination method The advantage of this approach is that
consistent solutions can be obtained over the entire area with minimal assumptions about source geometries Euler
deconvolution of gridded data is used for positional information and estimation of depth to top of source Euler
55
deconvolution yields a large number of depth solutions which have to be screened to reject spurious solutions Results
are plotted as circles in eight depth ranges with radius proportional to depth and colour coded
The 400 m total magnetic intensity grid was used for the analysis Horizontal gradients in x and y and the vertical
gradient were calculated 3D Euler deconvolution was tested on the 400 m gridded data using windows of 9 times 9 and
11 times 11 and 16 times 16 data points and structural indices 05 (fault) and 10 (sill or dyke) It was concluded that the
16 times 16 window produced the best results overall and final plots were produced for the 16 times 16 window and structural
index 05 (Fig 44) Results were very good over the northern and central parts of the area showing magnetic sources
Figure 44 Depth to magnetic source 3D Euler deconvolution 16 times 16 window of 400 m gridded data structural index 05
56
at several different levels Unfortunately in the extreme south of the area shallow intrasedimentary magnetic sources
(sills and dykes) dominated the inversion and the results contained few basement solutions
In order to reduce these problems the 400 m gridded data were filtered using a separation filter based on
interpretation of the log-energy spectrum The 3D Euler method was run on the filtered data in order to generate more
basement-depth solutions Results for the deep-separation filter data were gridded and presented as a colour image in
Cowan (1995) Attempts to grid the Euler output were unsatisfactory and it is considered safer to interpret the 3D
Euler depth plots The 3D Euler depth results from the separation-filter run should be analysed with care as perfect
separation of the basement can never be achieved and there will always be some contamination from sources at
different levels
The results of original total magnetic intensity 3D Euler depth estimation for structural index 05 using a 16 point
window have been plotted at 1500 000 scale (not included in this publication but available in Cowan (1995) from the
GSWA Library as S10331) and as reduced A4 colour circle plots (Figure 44)
The results of deep-basement 3D Euler depth estimation for structural index 05 using a 16 point window have
been plotted as a colour image at 1500 000 scale and as an A4 image (not included in this publication)
2D analysis
Two equispaced profiles were interpolated with a 50 m station interval from the AGSO-located data profiles for the
BULLEN 1250 000 sheet The interpolated profiles were analysed using 2D Euler deconvolution and Werner
deconvolution Results are included in Cowan (1995) and show the use of these methods for more detailed analysis
Filtered data
In order to reconcile 3D Euler results from shallow basement and intrasedimentary magnetic sources we produced
several separation-filtered maps and images We found the shallow-layer double-separation filter (Figure 45) to be
very effective for shallow sources and the deep-layer standard-separation filter (Figure 46) for the basement layer
Gravity and magnetic data correlation
Both lsquoreduced to the polersquo (RTP) magnetics (Figure 47) and pseudo-gravity data (Figure 48) were produced as part of
the reconciliation of gravity and magnetic signatures In both cases the filtering operations assumed magnetization by
induction in the present Earths field The RTP data are fairly similar to the total magnetic intensity The pseudo-
57
gravity data are dominated by a northwest-trending strong positive anomaly and there is little correlation with the
Bouguer gravity data
The poor magneticgravity correlation is confirmed by cross-correlation of the RTP magnetics and the gravity
gradient The correlation plot in Figure 49 shows little coherent response with numerous zones of positive and
negative correlation
Figure 45 Regional aeromagnetic data shallow layer separation filter (BMRAGSO data) gridded at 400 m
Results
In the north and east of the area on the Wells Foreland Sub-basin trend (refer to Figure 1 main text) we see a range
of quite deep 3D Euler depths and several trend directions with north-northwesterly dominant There are relatively few
shallow intrasedimentary solutions in this zone
The second area of deep 3D Euler solutions lies over the Blake depocentre (Figure 43) with several trend
directions
Elsewhere the 3D Euler results are dominated by shallow intrasedimentary depth solutions reflecting mainly the
dolerite sills dykes and the ring complex However where we do see basement-related solutions in the south and
west of the area they appear to be shallower than those noted for the Wells Foreland Sub-basin and the Blake
depocentre
58
Figure 46 Regional aeromagnetic data deep-layer separation filter (BMRAGSO data) gridded at 400 m
Figure 48 Regional aeromagnetic data pseudo-gravity transform (BMRAGSO data) gridded at 400 m
Figure 47 Regional aeromagnetic data reduced-to-pole (BMRAGSO data) gridded at 400 m
Figure 49 Regional aeromagnetic and gravity data gravitymagnetic correlation using RTP magnetics and gravity gradient (BMRAGSO data) gridded at 4 km
59
This subdivision of the area into two zones of deep solutions is consistent with interpreted depocentres
However the interference between sources at different levels and the complexity of the magnetic response of the
basement rocks precludes more refined interpretation at this stage
The area of deep 3D Euler solutions over the Blake depocentre correlates with the pronounced negative gravity
anomaly discussed in the gravity interpretation section Using a density contrast of -015 gcc the negative gravity
anomaly could indicate up to 6ndash8 km of low-density sedimentary rocks depending on assumptions about the regional
field
The area of deep 3D Euler solutions over the Wells Foreland Sub-basin has a complex gravity expression and no
clear basin structure emerges from inversion of these data As noted previously it is likely that observed gravity
anomalies reflect contrasts in basement density rather than basement topography
Separation filtering applied to the magnetic data helps to enhance the intrasedimentary magnetic signature and to
give a better impression of the basement magnetic signature even though separation of the basement response is not
perfect
Conclusions
Quantitative aeromagnetic interpretation using 3D Euler deconvolution supported by wavenumber filtering and image
processing has been successful in providing structural trend and depth information for the Savory Sub-basin
Quantitative magnetic interpretation has revealed two zones of relatively deep magnetic basement beneath the
Wells Foreland Sub-basin and the Blake depocentre
This analysis of the magnetic data supports interpreted depocentres but the complexity of the basement magnetic
signature and interference from sources at different depths precludes further refinement to a map of basement
topography
Regional gravity proved to be very useful in understanding the regional setting of the area and in providing
support for aspects of the interpretation The gravity data support the interpretation of the Blake depocentre
suggesting up to 6ndash8 km of low-density sedimentary rocks
The deep structure of the Savory Sub-basin area is obviously complex with different areas underlain by
Archaean and Proterozoic basement and with the Capricorn suture occurring in the centre of the area
60
Recommendations
The quantitative magnetic interpretation needs to be reconciled with geological models available for the area
In particular the zones tentatively identified as areas with thick sedimentary rocks the Wells Foreland Sub-
basin and the Blake depocentre need to be investigated
Cross sections should be prepared across the basin for joint magneticgravity modelling especially for the Blake
depocentre It is important to be able to explain the strong negative gravity anomaly in this area
In view of the effects of basement density contrasts on the gravity field for the northern part of the area we think
that additional gravity interpretation and acquisition of new gravity data may not be justified as they will not
contribute significantly to understanding basin evolution and structure
It is recommended that GSWA try to get access to company confidential high-resolution aeromagnetic data
rather than flying new surveys The GSWA might offer to fund flying of new infill areas as a bargaining point
References
The original text of this report by Cowan (1995) and 1500 000 scale maps are filed in the GSWA Library under
S10331
COWAN D 1995 Savory Basin quantitative magnetic interpretation Western Australia Geological Survey S-series
S10331 (unpublished)
VACQUIER V STEENLAND N C HENDERSON R G and ZIETZ I 1951 Interpretation of aeromagnetic
maps The Geological Society of America Memoir 47 151p
WILLIAMS I R 1992 Geology of the Savory Basin Western Australia Western Australia Geological Survey
Bulletin 141 115p
61
Appendix 5
Geochemistry
MKS38 250398
Saturate FractionC12+ GLC
1217
Pr18
Ph
22
31CSR WELL-13 315m Cuttings
Figure 51 Canning Stock Route Well 13 gas chromatograph of extract of auger drill sample
12
17
18
22
31
Pr Ph
LDDH 1 6623m CoreSaturate FractionC12+ GLC
MKS35 240398
Figure 52 Gas chromatograph of extract from core sample at 6623 m LDDH1
62
Table 51 Canning Stock Route Well 13 auger drill samples
GSWA sample Drill depth (m)(a) Comments
135601 150 At watertable 135602 203 (all samples consist 135603 310 of sand mud and water) 135604 315 At total depth
NOTE (a) Datum for drill depth is the top of sediment fill in the well which is 155 m below ground level (ie the total depth of 315 m is 47 m below ground level)
Table 52 Canning Stock Route Well 13 gas chromatography data for 315 m depth sediment sample
Parameter Value
Weight of rock extracted (grams) 945 Total extract (ppm) 519 n-Alkane distribution n-C12 07 n-C13 23 n-C14 26 n-C15 22 n-C16 19 n-C17 14 i-C19 23 n-C18 14 i-C20 08 n-C19 11 n-C20 16 n-C21 25 n-C22 29 n-C23 70 n-C24 42 n-C25 95 n-C26 43 n-C27 83 n-C28 38 n-C29 87 n-C30 31 n-C31 273 Alkane compositional data Pristane phytane ratio 279 Pristane n-C17 ratio 161 Phytane n-C18 ratio 059 CPI (1)(a) 284 CPI (2) 209 (C21 + C22) (C28 + C29) 043
NOTE (a) CPI= Carbon preference index
63
Table 53 LDDH1 extract liquid chromatography data for 6623 m concentration
Rock extracted Total extract (grams) (ppm)
702 313
NOTE ppm= parts per million
Table 54 LDDH1 saturate gas chromatography data of core for 6623 m alkane composition
Pristane Pristane Phytane (a) CPI (1) CPI (2) (C21+C22) Phytane n-C17 n-C18 (C28+C29)
103 026 024 103 102 325
NOTE (a)CPI = carbon preference index
Table 55 LDDH1 saturate gas chromatography data of core for 6623 m n-alkane distributions
Parameter Value
n-C12 17 n-C13 38 n-C14 55 n-C15 60 n-C16 65 n-C17 74 i-C19 19 n-C18 78 i-C20 19 n-C19 80 n-C20 79 n-C21 71 n-C22 64 n-C23 57 n-C25 43 n-C24 38 n-C27 31 n-C28 23 n-C29 19 n-C30 12 n-C31 10
64
Appendix 6
Table 61 Summary of data from Trainor waterbores (TWB) and Bullen waterbores (BWB)
Well AMG Elevation TD Status(b) Completion details Water Salinity Water level Flow rate Depth to consolidated AGD84 GL (m) (m) struck mgl(c) (m) (LHr) lithology aquifer(e) Z51(a) Interval (m) (100 mm PVC) (m) (mgl)(d)
TWB 1 473660E 453 122 comp 0ndash75 plain 63 7 300 24 2 880 12 m 7287404N 75ndash93 slotted (9 260) McFadden Fm 93ndash99 plain TWB 2 472 977E 475 23 abd nil 15 m 7285877N Skates Hills Fm dry TWB 3 473259E 475 50 abd nil 7 m 7285849N Skates Hills Fm dry TWB 4 463225 E 445 50 comp 0ndash22 plain 35 7 200 55 3 600 0 m 7286143N 22ndash34 slotted (8 140) Tertiary sand and gravel 23ndash60 plain TWB 5 463095E 445 31 comp 0ndash19 plain 13 26 000 655 3 600 Tertiary sand and gravel 7277721N 19ndash25 slotted (36 700) 25ndash31 plain TWB 6 457013E 455 50 comp 0ndash42 plain 38 920 119 600 0 m 7274352N 42ndash48 slotted (1 030) Cornelia Fm ss TWB 7 453739E 475 26 susp 0ndash2 plain 11 9 300 48 4 500 0 m 7263891N (10 500) Tertiary sand TWB 8 433893E 535 60 susp 0ndash2 plain 47 8 500 gt46 1 200 0 m 7245991N (10 900) Tertiary sand and Brassey Range Fm ss TWB 9 437219E 505 51 comp 0ndash47 plain 45 1 000 58 600 1 m 7235905N 47ndash51 slotted (990) Brassey Range Fm ss TWB 10 434927E 495 32 susp 0ndash2 plain 235 450 120 0 m 7225875N (500) Dolerite
65
BWB 1 287337E 580 122 abd Nil 1 m 7245861N Jilyili Fm dry BWB 2 288346E 545 50 comp 0ndash26 plain 15 630 3 29 000 0 m 7240423N 26ndash38 slotted (730) Tertiary sand and gravel 38ndash50 plain BWB 3 305637E 545 50 abd 19 8 800 43 7 200 0 m 7240423N (10 550) Tertiary ss BWB 4 320167E 515 445 comp 0ndash20 plain 9 980 445 24 000 0 m 7248097N 20ndash32 slotted (1 190) Tertiary ss 32ndash44 plain BWB 5 353393E 545 20 susp 0ndash2 plain 45 (970) 1 m 7238934N Basalt
NOTES (a) GPS accuracy ~ 150 m (b) Comp = completed abd = abandoned susp = suspended (c) Salinity from conductivity (d) Analysis total dissolved solids (e) Fm = Formation ss = sandstone
40
41
Appendix 1
Bibliography
Reports which are relevant to this investigation but which are not specifically cited are listed
below
BAILLIE P W POWELL C McA LI Z X and RYALL A M 1994 The tectonic
framework of Western Australiarsquos Neoproterozoic to recent sedimentary basins in The
sedimentary basins of Western Australia edited by P G PURCELL and R R PURCELL
Petroleum Exploration Society of Australia Symposium Perth WA 1994 Proceedings p
45ndash62
BRADSHAW M T BRADSHAW J MURRAY A P NEEDHAM D J SPENCER L
SUMMONS R E WILMOT J and WINN S 1994 Petroleum systems in West Australian
basins in The sedimentary basins of Western Australia edited by P G PURCELL and R R
PURCELL Petroleum Exploration Society of Australia Symposium Perth WA 1994
Proceedings p 93ndash118
CLARKE G L 1991 Proterozoic tectonic reworking in the Rudall Complex Western Australia
Australian Journal of Earth Science v38 p 31ndash44
COCKBAIN A E and HOCKING R M 1990 Phanerozoic in Geology and mineral resources
of Western Australia Western Australia Geological Survey Memoir 3 p 750ndash755
ETHERIDGE M and WALL V 1994 Tectonic and structural evolution of the Australian
Proterozoic 12th Australian Geological Convention Geological Society of Australia
Abstracts no 37 p 102ndash103
GOODE A D T 1981 Proterozoic geology of Western Australia in Precambrian of the
Southern Hemisphere Developments in Precambrian geology 2 edited by I R HUNTER
Amsterdam Elsevier p 105ndash203
GREY K and JACKSON M J 1983 A re-assessment of stromatolite evidence for the
correlation of the Late Proterozoic Neale and Ilma Beds Officer Basin Western Australia
Australia BMR Journal of Australian Geology and Geophysics v 8 p 359
42
HICKMAN A H WILLIAMS I R and BAGAS L 1994 Proterozoic geology and
mineralization of the TelferndashRudall region Paterson Orogen Geological Society of Australia
(WA Division) Excursion Guidebook no 5 56p
HOCKING R M MORY A J and WILLIAMS I R 1994 An atlas of Neoproterozoic and
Phanerozoic basins of Western Australia in The sedimentary basins of Western Australia
edited by P G PURCELL and R R PURCELL Petroleum Exploration Society of Australia
Symposium Perth WA 1994 Proceedings p 21ndash 44
JACKSON P R 1966 Geology and review of exploration Officer Basin Western Australia
Hunt Oil Company Western Australia Geological Survey S-series S26 (unpublished)
JACKSON M J 1971 Notes on a geological reconnaissance of the Officer Basin Western
Australia Australia BMR Geology and Geophysics Record 19715 30p
JACKSON M J and van de GRAAFF W J E 1981 Geology of the Officer Basin Western
Australia Australia BMR Geology and Geophysics Bulletin 206 102 p
LOWRY D C JACKSON M J van de GRAAFF W J E and KENNEWELL P J 1971
Preliminary result of geological mapping in the Officer Basin Western Australia Western
Australia Geological Survey Annual Report for 1971 p 50ndash56
MYERS J S 1990 Precambrian in Geology and mineral resources of Western Australia
Western Australia Geological Survey Memoir 3 p 737ndash750
MYERS J S SHAW R D and TYLER I M 1994 Proterozoic tectonic evolution of
Australia 12th Australian Geological Convention Geological Society of Australia Abstracts
no 37 p 312
NEDIN C and JENKINS R J F 1991 Re-evaluation of unconformities separating the
lsquoEdiacaranrsquo and Cambrian systems South Australia Palaios v 6 p 102ndash108
PHILLIPS B J JAMES A W and PHILIP G M 1985 The geology and hydrocarbon
potential of the north-western Officer Basin APEA Journal 25 (1) p 52ndash61
POWELL C McA LI Z X McELHINNY M W MEERT J G and PARK J K 1993
Paleomagnetic constraints on timing of the Neoproterozoic breakup of Rodinia and Cambrian
formation of Gondwana Geology v 21 p 889ndash892
43
POWELL C McA PREISS W V GATEHOUSE C G KRAPEZ B and LI Z X 1994
South Australian record of a Rodinian epicontinental basin and its mid-Neoproterozoic
breakup to form the Palaeo-Pacific Ocean Tectonophysics v 237 no 3ndash4 p 113ndash140
PREISS W V 1976 Proterozoic stromatolites from the Nabberu and Officer Basins Western
Australia and their biostratigraphic significance South Australia Geological Survey Report
of Investigations no 47 p 1ndash51
TOWNSON W G 1985 The subsurface geology of the western Officer Basin mdash results of
Shellrsquos 1980ndash1984 petroleum exploration campaign APEA Journal v 25 (1) p 34ndash51
WATTS K J 1982 The geology of the Townsend Quartzite Upper Proterozoic shallow water
deposit of the Northern Officer Basin Western Australia Perth University of Western
Australia BSc honours thesis (unpublished)
WELLS A T and KENNEWELL P J 1974 Evaporite exploration in the Officer Basin
Western Australia at the Madley Diapirs Australia BMR Record 1974194 (unpublished)
WILLIAMS I R and MYERS J S 1990 Paterson Orogen in Geology and mineral resources
of Western Australia Western Australia Geological Survey Memoir 3 p 274ndash286
WILLIAMS I R 1990 Savory Basin in Geology and mineral resources of Western Australia
Western Australia Geological Survey Memoir 3 p 329ndash334
WILLIAMS I R 1994 The Neoproterozoic Savory Basin Western Australia in The
sedimentary basins of Western Australia edited by P G PURCELL and R R PURCELL
Petroleum Exploration Society of Australia Symposium Perth WA 1994 Proceedings p
841ndash850
WILSON R B 1967 Woolnough Hills and Madley diapiric structures Gibson Desert WA
APEA Journal v 7 p 94ndash102
44
Appendix 2
Meteorological data (from Bureau of Meteorology Perth 1994)
Table 21 Wiluna rainfall (mm)
Year Jan Feb Mar Apr May Jun Jul Aug Sept Oct Nov Dec
1975 0 45 446 309 306 59 276 4 34 886 638 164 1976 16 154 12 138 53 16 34 62 12 238 0 2 1977 44 0 66 74 68 95 24 363 1 58 12 727 1978 234 522 94 16 0 96 367 24 16 353 185 45 1979 19 173 122 88 91 4 0 246 58 0 169 114 1980 148 764 68 1081 259 626 629 06 56 02 174 0 1981 123 476 192 32 196 118 44 74 14 0 28 312 1982 374 705 206 244 1079 92 02 143 368 526 368 118 1983 1 112 928 248 0 212 56 32 5 1 42 496 1984 149 7 342 84 836 0 348 132 224 04 16 172 1985 596 483 0 166 556 0 514 56 0 0 4 0 1986 0 154 35 0 0 1085 23 01 239 137 0 04 1987 1204 119 19 89 17 575 154 126 07 1 0 398 1988 46 202 164 13 388 0 202 104 0 0 224 1309 1989 207 234 26 703 278 536 57 0 01 0 144 02 1990 1035 23 281 46 126 53 94 218 44 9 42 0 1991 48 0 41 45 0 472 297 12 0 1 0 7 1992 112 96 1025 1227 323 65 04 174 0 132 48 4 1993 0 697 0 202 445 0 12 306 18 05 14 33 Mean 25 35 22 27 27 25 18 12 6 13 13 21
JAN FEB MAR APR MAY JUN JUL AUG SEP OCT NOV DEC0
10
20
30
40
Mea
n R
ain
fall
(mm
)
Month
Mean monthly rainfall in Wiluna
MKS41 140498
45
Table 22 Wiluna minimum temperature (degC)
Year Jan Feb Mar Apr May Jun Jul Aug Sept Oct Nov Dec
1975 ndash 23 203 15 94 63 71 62 103 124 169 205 1976 242 229 194 15 10 63 59 73 95 143 16 228 1977 243 25 197 148 96 95 56 86 102 ndash 188 23 1978 241 232 203 18 102 64 76 8 9 152 19 205 1979 255 226 216 167 83 6 59 79 97 145 198 223 1980 255 226 231 155 134 83 68 75 121 108 193 223 1981 245 216 19 182 119 6 54 78 138 159 163 218 1982 232 224 177 16 ndash ndash 37 111 112 164 209 225 1983 235 24 197 147 112 88 39 88 121 162 189 219 1984 241 243 191 156 ndash 72 66 7 95 161 182 211 1985 244 231 ndash 159 98 65 71 73 117 147 205 ndash 1986 ndash 229 226 155 93 96 43 49 10 122 ndash 219 1987 ndash 217 183 175 85 77 68 68 112 ndash ndash 221 1988 238 214 209 178 111 ndash ndash 86 104 157 171 195 1989 ndash 237 199 165 107 67 44 61 107 131 187 ndash 1990 232 ndash 211 155 118 62 57 87 102 149 195 22 1991 26 256 217 168 122 101 78 ndash 113 18 168 219 1992 227 227 214 169 102 98 59 69 ndash 125 159 196 1993 241 218 196 171 103 ndash 49 68 88 128 192 211 Mean 24 23 20 16 10 8 6 8 11 14 18 21
NOTE Dashes indicate data unavailable
JAN FEB MAR APR MAY JUN JUL AUG SEP OCT NOV DEC0
10
20
30
40
Month
MKS43 140498
50
Mean monthly minimum temperatures at Wiluna
Mea
n T
emp
erat
ure
(degC
)
46
Table 23 Wiluna maximum temperature (degC)
Year Jan Feb Mar Apr May Jun Jul Aug Sept Oct Nov Dec
1975 ndash 349 326 281 247 201 197 212 256 248 31 344 1976 374 369 346 297 248 206 208 225 265 287 313 388 1977 397 392 352 296 234 212 222 244 ndash 308 337 383 1978 378 345 346 316 242 195 176 205 231 295 334 356 1979 403 36 364 295 ndash ndash ndash 193 242 318 359 373 1980 392 342 377 275 24 176 179 233 292 288 349 391 1981 385 346 337 342 242 178 201 224 30 326 326 369 1982 372 359 315 307 ndash ndash 196 253 252 305 353 379 1983 381 389 327 272 263 222 187 248 287 321 336 366 1984 378 393 322 299 226 215 178 214 234 ndash 336 364 1985 40 366 ndash 294 224 216 205 212 284 307 355 ndash 1986 ndash 383 372 307 ndash 193 166 196 261 277 ndash 382 1987 ndash 339 328 305 21 202 214 218 275 ndash ndash 374 1988 388 365 353 301 23 ndash ndash 228 283 334 31 33 1989 ndash 375 339 285 238 179 181 219 275 298 336 ndash 1990 368 ndash 36 309 268 19 188 205 274 309 373 393 1991 414 416 363 315 268 206 21 ndash 279 338 332 368 1992 363 383 336 263 213 178 213 197 ndash 285 313 359 1993 396 357 344 301 221 ndash 197 215 253 294 347 362 Mean 39 37 34 30 24 20 20 22 27 30 34 37 NOTE Dashes indicate data unavailable
JAN FEB MAR APR MAY JUN JUL AUG SEP OCT NOV DEC0
10
20
30
40
Month
MKS42 140498
50
Mean monthly maximum temperatures at Wiluna
Mea
n T
emp
erat
ure
(degC
)
47
Appendix 3
Table 31 Summary of palynological results
Drillhole Depth (m) F no(a) GSWA no Lithology Formation Assemblage TAI(b)
BWB 1 74ndash75 F49668 135741 dark-grey siltstone basalt Jilyilli gt5 BWB 1 98ndash100 F49669 135742 dark-grey siltstone basalt Jilyilli gt5 BWB 1 121ndash122 F49670 135743 dark-grey siltstone basalt Jilyilli gt5 TWB 1 86ndash87 F49671 135631 dark-grey siltstone McFadden 3+ TWB 1 104ndash105 F49672 135632 dark-grey siltstone Cornelia 3+ TWB 1 121ndash122 F49673 135633 dark-grey siltstone Cornelia 4 TWB 2 14ndash15 F49674 135634 dark-grey siltstone Skates Hills 3+ TWB 6 49ndash50 F49675 135675 dark-grey siltstone Cornelia 1 3+ TWB 9 49ndash51 F49676 135704 dark-grey siltstone Brassey Range 1 3+ Trainor 1 37497- F49733 138939 black mudstone with Cornelia 5 37509 light-grey siltstone Trainor 1 3809 F49734 138940 dark-grey and black Cornelia 4- laminated mudstone Trainor 1 4170 F49735 138941 black unlaminated mudstone Cornelia 4- Trainor 1 4950 F49851 139501 dark-grey indurated siltstone Cornelia 5 Trainor 1 6032 F49852 139502 dark- and light-grey Cornelia 5 indurated siltstone Trainor 1 6434 F49853 139503 greenish indurated finely Cornelia 5 laminated siltstone LDDH 1 270 F49678 138934 dark-grey siltstone interbeds Waters 1 3+ in enterolithic evaporite Tarcunyah Gp LDDH 1 277 F49679 138935 dark-grey siltstone in cavity Waters 1 3+ in enterolithic evaporite Tarcunyah Gp
NOTES (a) GSWA Fossil Catalogue number (b) TAI = Thermal Alteration Index of Traverse (1988 plate 1)
48
Appendix 4
Savory Sub-basin quantitative magnetic and gravity interpretation (extracted from Cowan 1995)
Summary
A program of quantitative aeromagnetic interpretation has been completed on BMRAGSO data from the Savory Sub-
basin Western Australia Quantitative aeromagnetic interpretation utilized the 3D Euler deconvolution method
supported by wavenumber filtering and image processing The results have provided useful information on structural
trends and depth to magnetic sources in a structurally complex area Depth to magnetic source analysis has provided
information on intra-sedimentary magnetic sources as well as basement rocks
The results of the interpretation support previously identified depocentres However the presence of magnetic
sources at several levels makes it very difficult to produce a reliable magnetic basement depth contour map It is
considered more productive to work with the 3D Euler colour circle plots and images rather than trying to contour the
results It would be necessary to carry out a full-scale interpretation of the BMRAGSO profile data to improve on the
3D Euler results The regional gravity was found to be useful in interpreting the regional setting of the area although
the very wide data spacing limits quantitative use of the data The gravity data show quite a complex picture with
limited consistent correlation between gravity features and basin structures This suggests that gravity anomalies
reflect changes in density of the basement rocks rather than basement topography especially in the northern part of the
basin
It is recommended that the GSWA investigate access to company confidential high-resolution aeromagnetic data
prior to planning further aeromagnetic surveys Private companies have flown large parts of the northern half of the
area as part of their diamond exploration program Additional gravity coverage of the area may be more cost effective
than magnetic surveys as the gravity data provides more information on changes within the sedimentary section
Introduction
The main use of aeromagnetic data in petroleum exploration has been the determination of magnetic basement
topography although there has been increasing interest in analysis of intra-sedimentary magnetic anomalies
intrabasement and suprabasement magnetic anomalies These anomalies are used to determine depth to magnetic
basement rocks and hence determine the thickness of the sedimentary sequence Unfortunately interpretation of the
intrabasement and suprabasement magnetic anomalies is non-unique in terms of position and size of causative sources
because of the inherent ambiguity of potential-field methods However this ambiguity can be reduced by placing
49
constraints on source geometry and magnetization and by using geological and other geophysical data to constrain
the solution
Before 1970 most depth-determination techniques involved graphical determination of slopes of selected
magnetic anomalies and application of various empirical factors to convert the slopes into depth estimates Geological
Society of America Memoir 47 Interpretation of Aeromagnetic Maps by Vacquier et al (1951) was a landmark for
this type of interpretation
Automated interpretation procedures have played an increasingly important role in depth interpretation and a
wide range of techniques have been developed Many of these techniques are designed for application to located data
profiles and assume a two-dimensional geometry However there has been renewed interest in techniques applicable
to gridded data
Two distinct types of method can be recognized In the first case often described as discrete methods individual
isolated magnetic anomalies are interpreted and the results used to produce a map of basement relief In the second
case often described as continuous methods areas of data containing a number of anomalies are interpreted
statistically to produce direct output of basement depths
The discrete methods usually involve a semiautomatic initial phase which generates a large number of possible
depth solutions and an interactive second phase to screen and select acceptable solutions The advantage of this
approach is that the interpreter can select features that are relatively free from interference from adjacent anomalies
and consider all aspects of a particular magnetic anomaly The disadvantage is that interpretation can be very time
consuming as a wide range of depths are usually possible depending on the initial model chosen and a significant
amount of effort is needed to select the correct model In the case of the Savory Sub-basin dataset we encountered
problems in separating basement related effects from the effects of shallower intrasedimentary magnetic sources
Because of these problems we have concentrated on displaying the Euler results accompanied by separation filter
images of the data to show the shallower effects and deeper effects rather than trying to refine a 3D Euler
deconvolution depth-to-crystalline-basement contour
The continuous methods are very direct provided that the rather restrictive assumption can be made that all
anomalies are due to lateral magnetization changes due to basement topography This means that shallow effects and
large intrabasement anomalies must be removed from the data This involves judgement and skill as it is necessary to
distinguish between the lower amplitude suprabasement anomalies due to basement topography and the larger
intrabasement anomalies reflecting magnetization changes within the basement These methods were not considered
suitable for the Savory Sub-basin magnetic dataset but were used to invert the gravity data
50
Limitations of magnetic and gravity interpretation
Interpretation of the area is limited by a shortage of information on the nature and physical properties of the deeper
sedimentary sequence and the underlying basement rocks However using techniques such as cross-correlation of
gravity and pseudo-gravity data it is possible to try to differentiate between anomalies relating to basement and those
related to the sedimentary sequence
Gravity anomalies reflect changes within the sedimentary sequence as well as basement condition These
changes in density of sedimentary rocks produce gravity anomalies without a corresponding magnetic anomaly hence
the complementary nature of gravity and magnetic surveys The main use of magnetics is to determine depth to
magnetic basement and any intra-sedimentary volcanic rocks or intrusives whereas gravity provides much more
general information on the sedimentary sequence
Unfortunately interpretation of gravity anomalies is complicated since they can be due to a number of geological
features including
bull major basement faults
bull basement highs
bull igneous intrusions within the basement
bull sedimentary basins which may or may not be isostatically compensated
bull intra-sedimentary volcanics and associated plutonic centres
Two major problems affect the interpretation of both magnetic and gravity data
1 The inherent ambiguity of potential-field data There is no unique solution to any measured gravity or magnetic
anomaly and theoretically there will be an infinite number of source geometry and magnetizationdensity
combinations which will fit the observed data This means that any a priori information which helps to select a
suitable model is very useful
2 Measured anomalies are the summation of effects from different depths For example an observed gravity profile
may contain contributions from shallow sources (density variations within the sedimentary basin) intermediate
depth sources (density variations due to large igneous intrusions within the basement) and deep sources (crustal
thinning producing a mantle anomaly) Separation of these component responses is the regionalresidual problem
which we solve using spectral analysis and differential upward continuation-based separation filtering
Regional setting and interpretation overview
The area studied includes parts of BALFOUR DOWNS (SF51-9) RUDALL (SF51-10) ROBERTSON (SF51-13) GUNANYA
(SF51-14) COLLIER (SG50-4) BULLEN (SG51-1) TRAINOR (SG51-2) MADLEY (SG51-3) NABBERU (SG50-5)
STANLEY (SG51-6) and HERBERT (SG51-7) 1250 000 sheets Broadly the area lies between latitudes 22deg00rsquondash25deg30rsquoS
and longitudes 119deg30rsquondash123deg30rsquoE
51
Regional gravity
The AGSO regional gravity data (at nominal 11 km spacing) was gridded at a 4 km mesh spacing using a minimum-
curvature algorithm Bouguer gravity values in the area are negative reflecting mass deficiency at depth and range
from -84 mgals to -25 mgals
A Bouguer gravity colour image is shown as Figure 41 A residual grid was produced by removing a fifth-order
orthogonal polynomial from the Bouguer data but did not add to the interpretation
120deg 121deg 122deg 123deg
23deg
24deg
25deg
-25
-84
50 km
MKS46 180598
mgal
Figure 41 Regional Bouguer gravity (BMRAGSO data) gridded at 4 km
52
The data show a complex pattern of positive and negative anomalies with no clearly defined trends Correlations
with aeromagnetic data and known basin structures are poor A vague north-northwest linear trend appears to coincide
with the Marloo Fault (Figure 42) A prominent negative anomaly appears to coincide with the Blake Fold and Fault
Belt depocentre and continues as a narrower negative anomaly to the east until it widens out again near the edge of the
basin Elsewhere the gravity data show little correlation with known basin structures and it is likely that especially in
the north of the area gravity anomalies are due to density changes in the basement rather than changes in basement
topography
Production of wavelength-filtered residual gravity plots and vertical gradient plots showed very patchy aliased
data reflecting poor sampling in much of the area
Regional magnetics
The AGSO regional aeromagnetic data were gridded at a 400 m mesh spacing using a minimum-curvature algorithm
(Figure 43) Most of the data has a line spacing of 1600 m with small areas of 1 km spacing The quality of the data is
acceptable for regional interpretation but is not adequate for detailed analysis The accuracy of the flight path is rather
variable reflecting the vintage of the data and the noise envelope of the data is poor by modern standards Problems
were also encountered in joining different map sheets
The magnetic anomaly pattern over the south and west part of the area shows a strong high frequency signature
reflecting the presence of widespread basic sills and dykes Some of the major north-northeasterly trending dykes can
be traced over considerable distances
Discontinuous high-frequency anomalies extend as a northwest-trending zone through the centre of the area and
this zone includes a conspicuous circular magnetic anomaly which is probably a ring complex
The northern and eastern parts of the area are characterized by long-wavelength deep-seated basement magnetic
anomalies with 120deg and 150deg trends dominant The Marloo and Perentie Faults (Figure 42) appear as distinct linear
zones and offsets A prominent easterly trending negative anomaly in the northwest of the area appears to swing round
to the southeast and may separate different basement blocks One possible interpretation is that this very deep seated
anomaly separates areas of Archaean and Proterozoic basement
Regional geology
The regional geology is described in Williams (1992) The GSWA provided a digitized version of Plate 2 from this
Bulletin the structural interpretation map to use as an overlay (Figure 42)
53
Pp
Pp
PSd
PSd
PSd
PSd
PSd
PSo
PSt
PSt
PSf
PSf
PSf
PSb
PSb
PSb
PSsPSs
PSs
PSb
PSm
PSp
PSc
PSc
PSw
PSw
PSw
PSg
PSr
PSj
PSg
PM
Pk
PY
PY
PSd
L
L
L
L
L
L
L
LL
L
L
L
LL
L
LL
L L
LL
L L
L
L
L
L
L
L
L
LL
L
L
BLAKEDEPOCENTRE
MA
RLO
O
FAU
LT
PERENTIEFAULT
50 km
MKS39120598
120deg 121deg 122deg 123deg
25deg
24deg
23deg
Approximate boundaryof aeromagnetic interpretation
PML
PSgL
PSjL
PML
PSpL
PML
PML
PSfL
PSfL
PSpL
LPc
LPcLPcPSrL
LPA
Durba Sandstone
Woora Woora Formation
McFadden Formation
Tchukardine Formation
Boondawari Formation
Skates Hills Formation
Mundadjini Formation
Coondra Formation
Spearhole Formation
Watch Point Formation
Jilyili Formation
Brassey Range Formation
Glass Spring Formation
Paterson Formation
Yeneena Group
Karara Formation
Cornelia Formation
Kahrban Subgroup
Bangemall Group
Fault
Formation boundary
PSdL
PSoL
PSfL
PStL
PSbL
PSsL
PSmL
PScL
PSpL
PSwL
PSjL
PSrL
PSgL
Pp
PYL
PkL
LPc
LPA
PML
Savory Group Other Units
PYL
Figure 42 Regional geology and structure map (after Williams 1992)
54
120deg 121deg 122deg 123deg
23deg
24deg
25deg
5820
3750
MKS47 180598
nT
50 km
Figure 43 Regional aeromagnetic data total magnetic intensity (BMRAGSO data) gridded at 400 m
Analysis
3D analysis
3D Euler deconvolution was used as the primary depth-determination method The advantage of this approach is that
consistent solutions can be obtained over the entire area with minimal assumptions about source geometries Euler
deconvolution of gridded data is used for positional information and estimation of depth to top of source Euler
55
deconvolution yields a large number of depth solutions which have to be screened to reject spurious solutions Results
are plotted as circles in eight depth ranges with radius proportional to depth and colour coded
The 400 m total magnetic intensity grid was used for the analysis Horizontal gradients in x and y and the vertical
gradient were calculated 3D Euler deconvolution was tested on the 400 m gridded data using windows of 9 times 9 and
11 times 11 and 16 times 16 data points and structural indices 05 (fault) and 10 (sill or dyke) It was concluded that the
16 times 16 window produced the best results overall and final plots were produced for the 16 times 16 window and structural
index 05 (Fig 44) Results were very good over the northern and central parts of the area showing magnetic sources
Figure 44 Depth to magnetic source 3D Euler deconvolution 16 times 16 window of 400 m gridded data structural index 05
56
at several different levels Unfortunately in the extreme south of the area shallow intrasedimentary magnetic sources
(sills and dykes) dominated the inversion and the results contained few basement solutions
In order to reduce these problems the 400 m gridded data were filtered using a separation filter based on
interpretation of the log-energy spectrum The 3D Euler method was run on the filtered data in order to generate more
basement-depth solutions Results for the deep-separation filter data were gridded and presented as a colour image in
Cowan (1995) Attempts to grid the Euler output were unsatisfactory and it is considered safer to interpret the 3D
Euler depth plots The 3D Euler depth results from the separation-filter run should be analysed with care as perfect
separation of the basement can never be achieved and there will always be some contamination from sources at
different levels
The results of original total magnetic intensity 3D Euler depth estimation for structural index 05 using a 16 point
window have been plotted at 1500 000 scale (not included in this publication but available in Cowan (1995) from the
GSWA Library as S10331) and as reduced A4 colour circle plots (Figure 44)
The results of deep-basement 3D Euler depth estimation for structural index 05 using a 16 point window have
been plotted as a colour image at 1500 000 scale and as an A4 image (not included in this publication)
2D analysis
Two equispaced profiles were interpolated with a 50 m station interval from the AGSO-located data profiles for the
BULLEN 1250 000 sheet The interpolated profiles were analysed using 2D Euler deconvolution and Werner
deconvolution Results are included in Cowan (1995) and show the use of these methods for more detailed analysis
Filtered data
In order to reconcile 3D Euler results from shallow basement and intrasedimentary magnetic sources we produced
several separation-filtered maps and images We found the shallow-layer double-separation filter (Figure 45) to be
very effective for shallow sources and the deep-layer standard-separation filter (Figure 46) for the basement layer
Gravity and magnetic data correlation
Both lsquoreduced to the polersquo (RTP) magnetics (Figure 47) and pseudo-gravity data (Figure 48) were produced as part of
the reconciliation of gravity and magnetic signatures In both cases the filtering operations assumed magnetization by
induction in the present Earths field The RTP data are fairly similar to the total magnetic intensity The pseudo-
57
gravity data are dominated by a northwest-trending strong positive anomaly and there is little correlation with the
Bouguer gravity data
The poor magneticgravity correlation is confirmed by cross-correlation of the RTP magnetics and the gravity
gradient The correlation plot in Figure 49 shows little coherent response with numerous zones of positive and
negative correlation
Figure 45 Regional aeromagnetic data shallow layer separation filter (BMRAGSO data) gridded at 400 m
Results
In the north and east of the area on the Wells Foreland Sub-basin trend (refer to Figure 1 main text) we see a range
of quite deep 3D Euler depths and several trend directions with north-northwesterly dominant There are relatively few
shallow intrasedimentary solutions in this zone
The second area of deep 3D Euler solutions lies over the Blake depocentre (Figure 43) with several trend
directions
Elsewhere the 3D Euler results are dominated by shallow intrasedimentary depth solutions reflecting mainly the
dolerite sills dykes and the ring complex However where we do see basement-related solutions in the south and
west of the area they appear to be shallower than those noted for the Wells Foreland Sub-basin and the Blake
depocentre
58
Figure 46 Regional aeromagnetic data deep-layer separation filter (BMRAGSO data) gridded at 400 m
Figure 48 Regional aeromagnetic data pseudo-gravity transform (BMRAGSO data) gridded at 400 m
Figure 47 Regional aeromagnetic data reduced-to-pole (BMRAGSO data) gridded at 400 m
Figure 49 Regional aeromagnetic and gravity data gravitymagnetic correlation using RTP magnetics and gravity gradient (BMRAGSO data) gridded at 4 km
59
This subdivision of the area into two zones of deep solutions is consistent with interpreted depocentres
However the interference between sources at different levels and the complexity of the magnetic response of the
basement rocks precludes more refined interpretation at this stage
The area of deep 3D Euler solutions over the Blake depocentre correlates with the pronounced negative gravity
anomaly discussed in the gravity interpretation section Using a density contrast of -015 gcc the negative gravity
anomaly could indicate up to 6ndash8 km of low-density sedimentary rocks depending on assumptions about the regional
field
The area of deep 3D Euler solutions over the Wells Foreland Sub-basin has a complex gravity expression and no
clear basin structure emerges from inversion of these data As noted previously it is likely that observed gravity
anomalies reflect contrasts in basement density rather than basement topography
Separation filtering applied to the magnetic data helps to enhance the intrasedimentary magnetic signature and to
give a better impression of the basement magnetic signature even though separation of the basement response is not
perfect
Conclusions
Quantitative aeromagnetic interpretation using 3D Euler deconvolution supported by wavenumber filtering and image
processing has been successful in providing structural trend and depth information for the Savory Sub-basin
Quantitative magnetic interpretation has revealed two zones of relatively deep magnetic basement beneath the
Wells Foreland Sub-basin and the Blake depocentre
This analysis of the magnetic data supports interpreted depocentres but the complexity of the basement magnetic
signature and interference from sources at different depths precludes further refinement to a map of basement
topography
Regional gravity proved to be very useful in understanding the regional setting of the area and in providing
support for aspects of the interpretation The gravity data support the interpretation of the Blake depocentre
suggesting up to 6ndash8 km of low-density sedimentary rocks
The deep structure of the Savory Sub-basin area is obviously complex with different areas underlain by
Archaean and Proterozoic basement and with the Capricorn suture occurring in the centre of the area
60
Recommendations
The quantitative magnetic interpretation needs to be reconciled with geological models available for the area
In particular the zones tentatively identified as areas with thick sedimentary rocks the Wells Foreland Sub-
basin and the Blake depocentre need to be investigated
Cross sections should be prepared across the basin for joint magneticgravity modelling especially for the Blake
depocentre It is important to be able to explain the strong negative gravity anomaly in this area
In view of the effects of basement density contrasts on the gravity field for the northern part of the area we think
that additional gravity interpretation and acquisition of new gravity data may not be justified as they will not
contribute significantly to understanding basin evolution and structure
It is recommended that GSWA try to get access to company confidential high-resolution aeromagnetic data
rather than flying new surveys The GSWA might offer to fund flying of new infill areas as a bargaining point
References
The original text of this report by Cowan (1995) and 1500 000 scale maps are filed in the GSWA Library under
S10331
COWAN D 1995 Savory Basin quantitative magnetic interpretation Western Australia Geological Survey S-series
S10331 (unpublished)
VACQUIER V STEENLAND N C HENDERSON R G and ZIETZ I 1951 Interpretation of aeromagnetic
maps The Geological Society of America Memoir 47 151p
WILLIAMS I R 1992 Geology of the Savory Basin Western Australia Western Australia Geological Survey
Bulletin 141 115p
61
Appendix 5
Geochemistry
MKS38 250398
Saturate FractionC12+ GLC
1217
Pr18
Ph
22
31CSR WELL-13 315m Cuttings
Figure 51 Canning Stock Route Well 13 gas chromatograph of extract of auger drill sample
12
17
18
22
31
Pr Ph
LDDH 1 6623m CoreSaturate FractionC12+ GLC
MKS35 240398
Figure 52 Gas chromatograph of extract from core sample at 6623 m LDDH1
62
Table 51 Canning Stock Route Well 13 auger drill samples
GSWA sample Drill depth (m)(a) Comments
135601 150 At watertable 135602 203 (all samples consist 135603 310 of sand mud and water) 135604 315 At total depth
NOTE (a) Datum for drill depth is the top of sediment fill in the well which is 155 m below ground level (ie the total depth of 315 m is 47 m below ground level)
Table 52 Canning Stock Route Well 13 gas chromatography data for 315 m depth sediment sample
Parameter Value
Weight of rock extracted (grams) 945 Total extract (ppm) 519 n-Alkane distribution n-C12 07 n-C13 23 n-C14 26 n-C15 22 n-C16 19 n-C17 14 i-C19 23 n-C18 14 i-C20 08 n-C19 11 n-C20 16 n-C21 25 n-C22 29 n-C23 70 n-C24 42 n-C25 95 n-C26 43 n-C27 83 n-C28 38 n-C29 87 n-C30 31 n-C31 273 Alkane compositional data Pristane phytane ratio 279 Pristane n-C17 ratio 161 Phytane n-C18 ratio 059 CPI (1)(a) 284 CPI (2) 209 (C21 + C22) (C28 + C29) 043
NOTE (a) CPI= Carbon preference index
63
Table 53 LDDH1 extract liquid chromatography data for 6623 m concentration
Rock extracted Total extract (grams) (ppm)
702 313
NOTE ppm= parts per million
Table 54 LDDH1 saturate gas chromatography data of core for 6623 m alkane composition
Pristane Pristane Phytane (a) CPI (1) CPI (2) (C21+C22) Phytane n-C17 n-C18 (C28+C29)
103 026 024 103 102 325
NOTE (a)CPI = carbon preference index
Table 55 LDDH1 saturate gas chromatography data of core for 6623 m n-alkane distributions
Parameter Value
n-C12 17 n-C13 38 n-C14 55 n-C15 60 n-C16 65 n-C17 74 i-C19 19 n-C18 78 i-C20 19 n-C19 80 n-C20 79 n-C21 71 n-C22 64 n-C23 57 n-C25 43 n-C24 38 n-C27 31 n-C28 23 n-C29 19 n-C30 12 n-C31 10
64
Appendix 6
Table 61 Summary of data from Trainor waterbores (TWB) and Bullen waterbores (BWB)
Well AMG Elevation TD Status(b) Completion details Water Salinity Water level Flow rate Depth to consolidated AGD84 GL (m) (m) struck mgl(c) (m) (LHr) lithology aquifer(e) Z51(a) Interval (m) (100 mm PVC) (m) (mgl)(d)
TWB 1 473660E 453 122 comp 0ndash75 plain 63 7 300 24 2 880 12 m 7287404N 75ndash93 slotted (9 260) McFadden Fm 93ndash99 plain TWB 2 472 977E 475 23 abd nil 15 m 7285877N Skates Hills Fm dry TWB 3 473259E 475 50 abd nil 7 m 7285849N Skates Hills Fm dry TWB 4 463225 E 445 50 comp 0ndash22 plain 35 7 200 55 3 600 0 m 7286143N 22ndash34 slotted (8 140) Tertiary sand and gravel 23ndash60 plain TWB 5 463095E 445 31 comp 0ndash19 plain 13 26 000 655 3 600 Tertiary sand and gravel 7277721N 19ndash25 slotted (36 700) 25ndash31 plain TWB 6 457013E 455 50 comp 0ndash42 plain 38 920 119 600 0 m 7274352N 42ndash48 slotted (1 030) Cornelia Fm ss TWB 7 453739E 475 26 susp 0ndash2 plain 11 9 300 48 4 500 0 m 7263891N (10 500) Tertiary sand TWB 8 433893E 535 60 susp 0ndash2 plain 47 8 500 gt46 1 200 0 m 7245991N (10 900) Tertiary sand and Brassey Range Fm ss TWB 9 437219E 505 51 comp 0ndash47 plain 45 1 000 58 600 1 m 7235905N 47ndash51 slotted (990) Brassey Range Fm ss TWB 10 434927E 495 32 susp 0ndash2 plain 235 450 120 0 m 7225875N (500) Dolerite
65
BWB 1 287337E 580 122 abd Nil 1 m 7245861N Jilyili Fm dry BWB 2 288346E 545 50 comp 0ndash26 plain 15 630 3 29 000 0 m 7240423N 26ndash38 slotted (730) Tertiary sand and gravel 38ndash50 plain BWB 3 305637E 545 50 abd 19 8 800 43 7 200 0 m 7240423N (10 550) Tertiary ss BWB 4 320167E 515 445 comp 0ndash20 plain 9 980 445 24 000 0 m 7248097N 20ndash32 slotted (1 190) Tertiary ss 32ndash44 plain BWB 5 353393E 545 20 susp 0ndash2 plain 45 (970) 1 m 7238934N Basalt
NOTES (a) GPS accuracy ~ 150 m (b) Comp = completed abd = abandoned susp = suspended (c) Salinity from conductivity (d) Analysis total dissolved solids (e) Fm = Formation ss = sandstone
41
Appendix 1
Bibliography
Reports which are relevant to this investigation but which are not specifically cited are listed
below
BAILLIE P W POWELL C McA LI Z X and RYALL A M 1994 The tectonic
framework of Western Australiarsquos Neoproterozoic to recent sedimentary basins in The
sedimentary basins of Western Australia edited by P G PURCELL and R R PURCELL
Petroleum Exploration Society of Australia Symposium Perth WA 1994 Proceedings p
45ndash62
BRADSHAW M T BRADSHAW J MURRAY A P NEEDHAM D J SPENCER L
SUMMONS R E WILMOT J and WINN S 1994 Petroleum systems in West Australian
basins in The sedimentary basins of Western Australia edited by P G PURCELL and R R
PURCELL Petroleum Exploration Society of Australia Symposium Perth WA 1994
Proceedings p 93ndash118
CLARKE G L 1991 Proterozoic tectonic reworking in the Rudall Complex Western Australia
Australian Journal of Earth Science v38 p 31ndash44
COCKBAIN A E and HOCKING R M 1990 Phanerozoic in Geology and mineral resources
of Western Australia Western Australia Geological Survey Memoir 3 p 750ndash755
ETHERIDGE M and WALL V 1994 Tectonic and structural evolution of the Australian
Proterozoic 12th Australian Geological Convention Geological Society of Australia
Abstracts no 37 p 102ndash103
GOODE A D T 1981 Proterozoic geology of Western Australia in Precambrian of the
Southern Hemisphere Developments in Precambrian geology 2 edited by I R HUNTER
Amsterdam Elsevier p 105ndash203
GREY K and JACKSON M J 1983 A re-assessment of stromatolite evidence for the
correlation of the Late Proterozoic Neale and Ilma Beds Officer Basin Western Australia
Australia BMR Journal of Australian Geology and Geophysics v 8 p 359
42
HICKMAN A H WILLIAMS I R and BAGAS L 1994 Proterozoic geology and
mineralization of the TelferndashRudall region Paterson Orogen Geological Society of Australia
(WA Division) Excursion Guidebook no 5 56p
HOCKING R M MORY A J and WILLIAMS I R 1994 An atlas of Neoproterozoic and
Phanerozoic basins of Western Australia in The sedimentary basins of Western Australia
edited by P G PURCELL and R R PURCELL Petroleum Exploration Society of Australia
Symposium Perth WA 1994 Proceedings p 21ndash 44
JACKSON P R 1966 Geology and review of exploration Officer Basin Western Australia
Hunt Oil Company Western Australia Geological Survey S-series S26 (unpublished)
JACKSON M J 1971 Notes on a geological reconnaissance of the Officer Basin Western
Australia Australia BMR Geology and Geophysics Record 19715 30p
JACKSON M J and van de GRAAFF W J E 1981 Geology of the Officer Basin Western
Australia Australia BMR Geology and Geophysics Bulletin 206 102 p
LOWRY D C JACKSON M J van de GRAAFF W J E and KENNEWELL P J 1971
Preliminary result of geological mapping in the Officer Basin Western Australia Western
Australia Geological Survey Annual Report for 1971 p 50ndash56
MYERS J S 1990 Precambrian in Geology and mineral resources of Western Australia
Western Australia Geological Survey Memoir 3 p 737ndash750
MYERS J S SHAW R D and TYLER I M 1994 Proterozoic tectonic evolution of
Australia 12th Australian Geological Convention Geological Society of Australia Abstracts
no 37 p 312
NEDIN C and JENKINS R J F 1991 Re-evaluation of unconformities separating the
lsquoEdiacaranrsquo and Cambrian systems South Australia Palaios v 6 p 102ndash108
PHILLIPS B J JAMES A W and PHILIP G M 1985 The geology and hydrocarbon
potential of the north-western Officer Basin APEA Journal 25 (1) p 52ndash61
POWELL C McA LI Z X McELHINNY M W MEERT J G and PARK J K 1993
Paleomagnetic constraints on timing of the Neoproterozoic breakup of Rodinia and Cambrian
formation of Gondwana Geology v 21 p 889ndash892
43
POWELL C McA PREISS W V GATEHOUSE C G KRAPEZ B and LI Z X 1994
South Australian record of a Rodinian epicontinental basin and its mid-Neoproterozoic
breakup to form the Palaeo-Pacific Ocean Tectonophysics v 237 no 3ndash4 p 113ndash140
PREISS W V 1976 Proterozoic stromatolites from the Nabberu and Officer Basins Western
Australia and their biostratigraphic significance South Australia Geological Survey Report
of Investigations no 47 p 1ndash51
TOWNSON W G 1985 The subsurface geology of the western Officer Basin mdash results of
Shellrsquos 1980ndash1984 petroleum exploration campaign APEA Journal v 25 (1) p 34ndash51
WATTS K J 1982 The geology of the Townsend Quartzite Upper Proterozoic shallow water
deposit of the Northern Officer Basin Western Australia Perth University of Western
Australia BSc honours thesis (unpublished)
WELLS A T and KENNEWELL P J 1974 Evaporite exploration in the Officer Basin
Western Australia at the Madley Diapirs Australia BMR Record 1974194 (unpublished)
WILLIAMS I R and MYERS J S 1990 Paterson Orogen in Geology and mineral resources
of Western Australia Western Australia Geological Survey Memoir 3 p 274ndash286
WILLIAMS I R 1990 Savory Basin in Geology and mineral resources of Western Australia
Western Australia Geological Survey Memoir 3 p 329ndash334
WILLIAMS I R 1994 The Neoproterozoic Savory Basin Western Australia in The
sedimentary basins of Western Australia edited by P G PURCELL and R R PURCELL
Petroleum Exploration Society of Australia Symposium Perth WA 1994 Proceedings p
841ndash850
WILSON R B 1967 Woolnough Hills and Madley diapiric structures Gibson Desert WA
APEA Journal v 7 p 94ndash102
44
Appendix 2
Meteorological data (from Bureau of Meteorology Perth 1994)
Table 21 Wiluna rainfall (mm)
Year Jan Feb Mar Apr May Jun Jul Aug Sept Oct Nov Dec
1975 0 45 446 309 306 59 276 4 34 886 638 164 1976 16 154 12 138 53 16 34 62 12 238 0 2 1977 44 0 66 74 68 95 24 363 1 58 12 727 1978 234 522 94 16 0 96 367 24 16 353 185 45 1979 19 173 122 88 91 4 0 246 58 0 169 114 1980 148 764 68 1081 259 626 629 06 56 02 174 0 1981 123 476 192 32 196 118 44 74 14 0 28 312 1982 374 705 206 244 1079 92 02 143 368 526 368 118 1983 1 112 928 248 0 212 56 32 5 1 42 496 1984 149 7 342 84 836 0 348 132 224 04 16 172 1985 596 483 0 166 556 0 514 56 0 0 4 0 1986 0 154 35 0 0 1085 23 01 239 137 0 04 1987 1204 119 19 89 17 575 154 126 07 1 0 398 1988 46 202 164 13 388 0 202 104 0 0 224 1309 1989 207 234 26 703 278 536 57 0 01 0 144 02 1990 1035 23 281 46 126 53 94 218 44 9 42 0 1991 48 0 41 45 0 472 297 12 0 1 0 7 1992 112 96 1025 1227 323 65 04 174 0 132 48 4 1993 0 697 0 202 445 0 12 306 18 05 14 33 Mean 25 35 22 27 27 25 18 12 6 13 13 21
JAN FEB MAR APR MAY JUN JUL AUG SEP OCT NOV DEC0
10
20
30
40
Mea
n R
ain
fall
(mm
)
Month
Mean monthly rainfall in Wiluna
MKS41 140498
45
Table 22 Wiluna minimum temperature (degC)
Year Jan Feb Mar Apr May Jun Jul Aug Sept Oct Nov Dec
1975 ndash 23 203 15 94 63 71 62 103 124 169 205 1976 242 229 194 15 10 63 59 73 95 143 16 228 1977 243 25 197 148 96 95 56 86 102 ndash 188 23 1978 241 232 203 18 102 64 76 8 9 152 19 205 1979 255 226 216 167 83 6 59 79 97 145 198 223 1980 255 226 231 155 134 83 68 75 121 108 193 223 1981 245 216 19 182 119 6 54 78 138 159 163 218 1982 232 224 177 16 ndash ndash 37 111 112 164 209 225 1983 235 24 197 147 112 88 39 88 121 162 189 219 1984 241 243 191 156 ndash 72 66 7 95 161 182 211 1985 244 231 ndash 159 98 65 71 73 117 147 205 ndash 1986 ndash 229 226 155 93 96 43 49 10 122 ndash 219 1987 ndash 217 183 175 85 77 68 68 112 ndash ndash 221 1988 238 214 209 178 111 ndash ndash 86 104 157 171 195 1989 ndash 237 199 165 107 67 44 61 107 131 187 ndash 1990 232 ndash 211 155 118 62 57 87 102 149 195 22 1991 26 256 217 168 122 101 78 ndash 113 18 168 219 1992 227 227 214 169 102 98 59 69 ndash 125 159 196 1993 241 218 196 171 103 ndash 49 68 88 128 192 211 Mean 24 23 20 16 10 8 6 8 11 14 18 21
NOTE Dashes indicate data unavailable
JAN FEB MAR APR MAY JUN JUL AUG SEP OCT NOV DEC0
10
20
30
40
Month
MKS43 140498
50
Mean monthly minimum temperatures at Wiluna
Mea
n T
emp
erat
ure
(degC
)
46
Table 23 Wiluna maximum temperature (degC)
Year Jan Feb Mar Apr May Jun Jul Aug Sept Oct Nov Dec
1975 ndash 349 326 281 247 201 197 212 256 248 31 344 1976 374 369 346 297 248 206 208 225 265 287 313 388 1977 397 392 352 296 234 212 222 244 ndash 308 337 383 1978 378 345 346 316 242 195 176 205 231 295 334 356 1979 403 36 364 295 ndash ndash ndash 193 242 318 359 373 1980 392 342 377 275 24 176 179 233 292 288 349 391 1981 385 346 337 342 242 178 201 224 30 326 326 369 1982 372 359 315 307 ndash ndash 196 253 252 305 353 379 1983 381 389 327 272 263 222 187 248 287 321 336 366 1984 378 393 322 299 226 215 178 214 234 ndash 336 364 1985 40 366 ndash 294 224 216 205 212 284 307 355 ndash 1986 ndash 383 372 307 ndash 193 166 196 261 277 ndash 382 1987 ndash 339 328 305 21 202 214 218 275 ndash ndash 374 1988 388 365 353 301 23 ndash ndash 228 283 334 31 33 1989 ndash 375 339 285 238 179 181 219 275 298 336 ndash 1990 368 ndash 36 309 268 19 188 205 274 309 373 393 1991 414 416 363 315 268 206 21 ndash 279 338 332 368 1992 363 383 336 263 213 178 213 197 ndash 285 313 359 1993 396 357 344 301 221 ndash 197 215 253 294 347 362 Mean 39 37 34 30 24 20 20 22 27 30 34 37 NOTE Dashes indicate data unavailable
JAN FEB MAR APR MAY JUN JUL AUG SEP OCT NOV DEC0
10
20
30
40
Month
MKS42 140498
50
Mean monthly maximum temperatures at Wiluna
Mea
n T
emp
erat
ure
(degC
)
47
Appendix 3
Table 31 Summary of palynological results
Drillhole Depth (m) F no(a) GSWA no Lithology Formation Assemblage TAI(b)
BWB 1 74ndash75 F49668 135741 dark-grey siltstone basalt Jilyilli gt5 BWB 1 98ndash100 F49669 135742 dark-grey siltstone basalt Jilyilli gt5 BWB 1 121ndash122 F49670 135743 dark-grey siltstone basalt Jilyilli gt5 TWB 1 86ndash87 F49671 135631 dark-grey siltstone McFadden 3+ TWB 1 104ndash105 F49672 135632 dark-grey siltstone Cornelia 3+ TWB 1 121ndash122 F49673 135633 dark-grey siltstone Cornelia 4 TWB 2 14ndash15 F49674 135634 dark-grey siltstone Skates Hills 3+ TWB 6 49ndash50 F49675 135675 dark-grey siltstone Cornelia 1 3+ TWB 9 49ndash51 F49676 135704 dark-grey siltstone Brassey Range 1 3+ Trainor 1 37497- F49733 138939 black mudstone with Cornelia 5 37509 light-grey siltstone Trainor 1 3809 F49734 138940 dark-grey and black Cornelia 4- laminated mudstone Trainor 1 4170 F49735 138941 black unlaminated mudstone Cornelia 4- Trainor 1 4950 F49851 139501 dark-grey indurated siltstone Cornelia 5 Trainor 1 6032 F49852 139502 dark- and light-grey Cornelia 5 indurated siltstone Trainor 1 6434 F49853 139503 greenish indurated finely Cornelia 5 laminated siltstone LDDH 1 270 F49678 138934 dark-grey siltstone interbeds Waters 1 3+ in enterolithic evaporite Tarcunyah Gp LDDH 1 277 F49679 138935 dark-grey siltstone in cavity Waters 1 3+ in enterolithic evaporite Tarcunyah Gp
NOTES (a) GSWA Fossil Catalogue number (b) TAI = Thermal Alteration Index of Traverse (1988 plate 1)
48
Appendix 4
Savory Sub-basin quantitative magnetic and gravity interpretation (extracted from Cowan 1995)
Summary
A program of quantitative aeromagnetic interpretation has been completed on BMRAGSO data from the Savory Sub-
basin Western Australia Quantitative aeromagnetic interpretation utilized the 3D Euler deconvolution method
supported by wavenumber filtering and image processing The results have provided useful information on structural
trends and depth to magnetic sources in a structurally complex area Depth to magnetic source analysis has provided
information on intra-sedimentary magnetic sources as well as basement rocks
The results of the interpretation support previously identified depocentres However the presence of magnetic
sources at several levels makes it very difficult to produce a reliable magnetic basement depth contour map It is
considered more productive to work with the 3D Euler colour circle plots and images rather than trying to contour the
results It would be necessary to carry out a full-scale interpretation of the BMRAGSO profile data to improve on the
3D Euler results The regional gravity was found to be useful in interpreting the regional setting of the area although
the very wide data spacing limits quantitative use of the data The gravity data show quite a complex picture with
limited consistent correlation between gravity features and basin structures This suggests that gravity anomalies
reflect changes in density of the basement rocks rather than basement topography especially in the northern part of the
basin
It is recommended that the GSWA investigate access to company confidential high-resolution aeromagnetic data
prior to planning further aeromagnetic surveys Private companies have flown large parts of the northern half of the
area as part of their diamond exploration program Additional gravity coverage of the area may be more cost effective
than magnetic surveys as the gravity data provides more information on changes within the sedimentary section
Introduction
The main use of aeromagnetic data in petroleum exploration has been the determination of magnetic basement
topography although there has been increasing interest in analysis of intra-sedimentary magnetic anomalies
intrabasement and suprabasement magnetic anomalies These anomalies are used to determine depth to magnetic
basement rocks and hence determine the thickness of the sedimentary sequence Unfortunately interpretation of the
intrabasement and suprabasement magnetic anomalies is non-unique in terms of position and size of causative sources
because of the inherent ambiguity of potential-field methods However this ambiguity can be reduced by placing
49
constraints on source geometry and magnetization and by using geological and other geophysical data to constrain
the solution
Before 1970 most depth-determination techniques involved graphical determination of slopes of selected
magnetic anomalies and application of various empirical factors to convert the slopes into depth estimates Geological
Society of America Memoir 47 Interpretation of Aeromagnetic Maps by Vacquier et al (1951) was a landmark for
this type of interpretation
Automated interpretation procedures have played an increasingly important role in depth interpretation and a
wide range of techniques have been developed Many of these techniques are designed for application to located data
profiles and assume a two-dimensional geometry However there has been renewed interest in techniques applicable
to gridded data
Two distinct types of method can be recognized In the first case often described as discrete methods individual
isolated magnetic anomalies are interpreted and the results used to produce a map of basement relief In the second
case often described as continuous methods areas of data containing a number of anomalies are interpreted
statistically to produce direct output of basement depths
The discrete methods usually involve a semiautomatic initial phase which generates a large number of possible
depth solutions and an interactive second phase to screen and select acceptable solutions The advantage of this
approach is that the interpreter can select features that are relatively free from interference from adjacent anomalies
and consider all aspects of a particular magnetic anomaly The disadvantage is that interpretation can be very time
consuming as a wide range of depths are usually possible depending on the initial model chosen and a significant
amount of effort is needed to select the correct model In the case of the Savory Sub-basin dataset we encountered
problems in separating basement related effects from the effects of shallower intrasedimentary magnetic sources
Because of these problems we have concentrated on displaying the Euler results accompanied by separation filter
images of the data to show the shallower effects and deeper effects rather than trying to refine a 3D Euler
deconvolution depth-to-crystalline-basement contour
The continuous methods are very direct provided that the rather restrictive assumption can be made that all
anomalies are due to lateral magnetization changes due to basement topography This means that shallow effects and
large intrabasement anomalies must be removed from the data This involves judgement and skill as it is necessary to
distinguish between the lower amplitude suprabasement anomalies due to basement topography and the larger
intrabasement anomalies reflecting magnetization changes within the basement These methods were not considered
suitable for the Savory Sub-basin magnetic dataset but were used to invert the gravity data
50
Limitations of magnetic and gravity interpretation
Interpretation of the area is limited by a shortage of information on the nature and physical properties of the deeper
sedimentary sequence and the underlying basement rocks However using techniques such as cross-correlation of
gravity and pseudo-gravity data it is possible to try to differentiate between anomalies relating to basement and those
related to the sedimentary sequence
Gravity anomalies reflect changes within the sedimentary sequence as well as basement condition These
changes in density of sedimentary rocks produce gravity anomalies without a corresponding magnetic anomaly hence
the complementary nature of gravity and magnetic surveys The main use of magnetics is to determine depth to
magnetic basement and any intra-sedimentary volcanic rocks or intrusives whereas gravity provides much more
general information on the sedimentary sequence
Unfortunately interpretation of gravity anomalies is complicated since they can be due to a number of geological
features including
bull major basement faults
bull basement highs
bull igneous intrusions within the basement
bull sedimentary basins which may or may not be isostatically compensated
bull intra-sedimentary volcanics and associated plutonic centres
Two major problems affect the interpretation of both magnetic and gravity data
1 The inherent ambiguity of potential-field data There is no unique solution to any measured gravity or magnetic
anomaly and theoretically there will be an infinite number of source geometry and magnetizationdensity
combinations which will fit the observed data This means that any a priori information which helps to select a
suitable model is very useful
2 Measured anomalies are the summation of effects from different depths For example an observed gravity profile
may contain contributions from shallow sources (density variations within the sedimentary basin) intermediate
depth sources (density variations due to large igneous intrusions within the basement) and deep sources (crustal
thinning producing a mantle anomaly) Separation of these component responses is the regionalresidual problem
which we solve using spectral analysis and differential upward continuation-based separation filtering
Regional setting and interpretation overview
The area studied includes parts of BALFOUR DOWNS (SF51-9) RUDALL (SF51-10) ROBERTSON (SF51-13) GUNANYA
(SF51-14) COLLIER (SG50-4) BULLEN (SG51-1) TRAINOR (SG51-2) MADLEY (SG51-3) NABBERU (SG50-5)
STANLEY (SG51-6) and HERBERT (SG51-7) 1250 000 sheets Broadly the area lies between latitudes 22deg00rsquondash25deg30rsquoS
and longitudes 119deg30rsquondash123deg30rsquoE
51
Regional gravity
The AGSO regional gravity data (at nominal 11 km spacing) was gridded at a 4 km mesh spacing using a minimum-
curvature algorithm Bouguer gravity values in the area are negative reflecting mass deficiency at depth and range
from -84 mgals to -25 mgals
A Bouguer gravity colour image is shown as Figure 41 A residual grid was produced by removing a fifth-order
orthogonal polynomial from the Bouguer data but did not add to the interpretation
120deg 121deg 122deg 123deg
23deg
24deg
25deg
-25
-84
50 km
MKS46 180598
mgal
Figure 41 Regional Bouguer gravity (BMRAGSO data) gridded at 4 km
52
The data show a complex pattern of positive and negative anomalies with no clearly defined trends Correlations
with aeromagnetic data and known basin structures are poor A vague north-northwest linear trend appears to coincide
with the Marloo Fault (Figure 42) A prominent negative anomaly appears to coincide with the Blake Fold and Fault
Belt depocentre and continues as a narrower negative anomaly to the east until it widens out again near the edge of the
basin Elsewhere the gravity data show little correlation with known basin structures and it is likely that especially in
the north of the area gravity anomalies are due to density changes in the basement rather than changes in basement
topography
Production of wavelength-filtered residual gravity plots and vertical gradient plots showed very patchy aliased
data reflecting poor sampling in much of the area
Regional magnetics
The AGSO regional aeromagnetic data were gridded at a 400 m mesh spacing using a minimum-curvature algorithm
(Figure 43) Most of the data has a line spacing of 1600 m with small areas of 1 km spacing The quality of the data is
acceptable for regional interpretation but is not adequate for detailed analysis The accuracy of the flight path is rather
variable reflecting the vintage of the data and the noise envelope of the data is poor by modern standards Problems
were also encountered in joining different map sheets
The magnetic anomaly pattern over the south and west part of the area shows a strong high frequency signature
reflecting the presence of widespread basic sills and dykes Some of the major north-northeasterly trending dykes can
be traced over considerable distances
Discontinuous high-frequency anomalies extend as a northwest-trending zone through the centre of the area and
this zone includes a conspicuous circular magnetic anomaly which is probably a ring complex
The northern and eastern parts of the area are characterized by long-wavelength deep-seated basement magnetic
anomalies with 120deg and 150deg trends dominant The Marloo and Perentie Faults (Figure 42) appear as distinct linear
zones and offsets A prominent easterly trending negative anomaly in the northwest of the area appears to swing round
to the southeast and may separate different basement blocks One possible interpretation is that this very deep seated
anomaly separates areas of Archaean and Proterozoic basement
Regional geology
The regional geology is described in Williams (1992) The GSWA provided a digitized version of Plate 2 from this
Bulletin the structural interpretation map to use as an overlay (Figure 42)
53
Pp
Pp
PSd
PSd
PSd
PSd
PSd
PSo
PSt
PSt
PSf
PSf
PSf
PSb
PSb
PSb
PSsPSs
PSs
PSb
PSm
PSp
PSc
PSc
PSw
PSw
PSw
PSg
PSr
PSj
PSg
PM
Pk
PY
PY
PSd
L
L
L
L
L
L
L
LL
L
L
L
LL
L
LL
L L
LL
L L
L
L
L
L
L
L
L
LL
L
L
BLAKEDEPOCENTRE
MA
RLO
O
FAU
LT
PERENTIEFAULT
50 km
MKS39120598
120deg 121deg 122deg 123deg
25deg
24deg
23deg
Approximate boundaryof aeromagnetic interpretation
PML
PSgL
PSjL
PML
PSpL
PML
PML
PSfL
PSfL
PSpL
LPc
LPcLPcPSrL
LPA
Durba Sandstone
Woora Woora Formation
McFadden Formation
Tchukardine Formation
Boondawari Formation
Skates Hills Formation
Mundadjini Formation
Coondra Formation
Spearhole Formation
Watch Point Formation
Jilyili Formation
Brassey Range Formation
Glass Spring Formation
Paterson Formation
Yeneena Group
Karara Formation
Cornelia Formation
Kahrban Subgroup
Bangemall Group
Fault
Formation boundary
PSdL
PSoL
PSfL
PStL
PSbL
PSsL
PSmL
PScL
PSpL
PSwL
PSjL
PSrL
PSgL
Pp
PYL
PkL
LPc
LPA
PML
Savory Group Other Units
PYL
Figure 42 Regional geology and structure map (after Williams 1992)
54
120deg 121deg 122deg 123deg
23deg
24deg
25deg
5820
3750
MKS47 180598
nT
50 km
Figure 43 Regional aeromagnetic data total magnetic intensity (BMRAGSO data) gridded at 400 m
Analysis
3D analysis
3D Euler deconvolution was used as the primary depth-determination method The advantage of this approach is that
consistent solutions can be obtained over the entire area with minimal assumptions about source geometries Euler
deconvolution of gridded data is used for positional information and estimation of depth to top of source Euler
55
deconvolution yields a large number of depth solutions which have to be screened to reject spurious solutions Results
are plotted as circles in eight depth ranges with radius proportional to depth and colour coded
The 400 m total magnetic intensity grid was used for the analysis Horizontal gradients in x and y and the vertical
gradient were calculated 3D Euler deconvolution was tested on the 400 m gridded data using windows of 9 times 9 and
11 times 11 and 16 times 16 data points and structural indices 05 (fault) and 10 (sill or dyke) It was concluded that the
16 times 16 window produced the best results overall and final plots were produced for the 16 times 16 window and structural
index 05 (Fig 44) Results were very good over the northern and central parts of the area showing magnetic sources
Figure 44 Depth to magnetic source 3D Euler deconvolution 16 times 16 window of 400 m gridded data structural index 05
56
at several different levels Unfortunately in the extreme south of the area shallow intrasedimentary magnetic sources
(sills and dykes) dominated the inversion and the results contained few basement solutions
In order to reduce these problems the 400 m gridded data were filtered using a separation filter based on
interpretation of the log-energy spectrum The 3D Euler method was run on the filtered data in order to generate more
basement-depth solutions Results for the deep-separation filter data were gridded and presented as a colour image in
Cowan (1995) Attempts to grid the Euler output were unsatisfactory and it is considered safer to interpret the 3D
Euler depth plots The 3D Euler depth results from the separation-filter run should be analysed with care as perfect
separation of the basement can never be achieved and there will always be some contamination from sources at
different levels
The results of original total magnetic intensity 3D Euler depth estimation for structural index 05 using a 16 point
window have been plotted at 1500 000 scale (not included in this publication but available in Cowan (1995) from the
GSWA Library as S10331) and as reduced A4 colour circle plots (Figure 44)
The results of deep-basement 3D Euler depth estimation for structural index 05 using a 16 point window have
been plotted as a colour image at 1500 000 scale and as an A4 image (not included in this publication)
2D analysis
Two equispaced profiles were interpolated with a 50 m station interval from the AGSO-located data profiles for the
BULLEN 1250 000 sheet The interpolated profiles were analysed using 2D Euler deconvolution and Werner
deconvolution Results are included in Cowan (1995) and show the use of these methods for more detailed analysis
Filtered data
In order to reconcile 3D Euler results from shallow basement and intrasedimentary magnetic sources we produced
several separation-filtered maps and images We found the shallow-layer double-separation filter (Figure 45) to be
very effective for shallow sources and the deep-layer standard-separation filter (Figure 46) for the basement layer
Gravity and magnetic data correlation
Both lsquoreduced to the polersquo (RTP) magnetics (Figure 47) and pseudo-gravity data (Figure 48) were produced as part of
the reconciliation of gravity and magnetic signatures In both cases the filtering operations assumed magnetization by
induction in the present Earths field The RTP data are fairly similar to the total magnetic intensity The pseudo-
57
gravity data are dominated by a northwest-trending strong positive anomaly and there is little correlation with the
Bouguer gravity data
The poor magneticgravity correlation is confirmed by cross-correlation of the RTP magnetics and the gravity
gradient The correlation plot in Figure 49 shows little coherent response with numerous zones of positive and
negative correlation
Figure 45 Regional aeromagnetic data shallow layer separation filter (BMRAGSO data) gridded at 400 m
Results
In the north and east of the area on the Wells Foreland Sub-basin trend (refer to Figure 1 main text) we see a range
of quite deep 3D Euler depths and several trend directions with north-northwesterly dominant There are relatively few
shallow intrasedimentary solutions in this zone
The second area of deep 3D Euler solutions lies over the Blake depocentre (Figure 43) with several trend
directions
Elsewhere the 3D Euler results are dominated by shallow intrasedimentary depth solutions reflecting mainly the
dolerite sills dykes and the ring complex However where we do see basement-related solutions in the south and
west of the area they appear to be shallower than those noted for the Wells Foreland Sub-basin and the Blake
depocentre
58
Figure 46 Regional aeromagnetic data deep-layer separation filter (BMRAGSO data) gridded at 400 m
Figure 48 Regional aeromagnetic data pseudo-gravity transform (BMRAGSO data) gridded at 400 m
Figure 47 Regional aeromagnetic data reduced-to-pole (BMRAGSO data) gridded at 400 m
Figure 49 Regional aeromagnetic and gravity data gravitymagnetic correlation using RTP magnetics and gravity gradient (BMRAGSO data) gridded at 4 km
59
This subdivision of the area into two zones of deep solutions is consistent with interpreted depocentres
However the interference between sources at different levels and the complexity of the magnetic response of the
basement rocks precludes more refined interpretation at this stage
The area of deep 3D Euler solutions over the Blake depocentre correlates with the pronounced negative gravity
anomaly discussed in the gravity interpretation section Using a density contrast of -015 gcc the negative gravity
anomaly could indicate up to 6ndash8 km of low-density sedimentary rocks depending on assumptions about the regional
field
The area of deep 3D Euler solutions over the Wells Foreland Sub-basin has a complex gravity expression and no
clear basin structure emerges from inversion of these data As noted previously it is likely that observed gravity
anomalies reflect contrasts in basement density rather than basement topography
Separation filtering applied to the magnetic data helps to enhance the intrasedimentary magnetic signature and to
give a better impression of the basement magnetic signature even though separation of the basement response is not
perfect
Conclusions
Quantitative aeromagnetic interpretation using 3D Euler deconvolution supported by wavenumber filtering and image
processing has been successful in providing structural trend and depth information for the Savory Sub-basin
Quantitative magnetic interpretation has revealed two zones of relatively deep magnetic basement beneath the
Wells Foreland Sub-basin and the Blake depocentre
This analysis of the magnetic data supports interpreted depocentres but the complexity of the basement magnetic
signature and interference from sources at different depths precludes further refinement to a map of basement
topography
Regional gravity proved to be very useful in understanding the regional setting of the area and in providing
support for aspects of the interpretation The gravity data support the interpretation of the Blake depocentre
suggesting up to 6ndash8 km of low-density sedimentary rocks
The deep structure of the Savory Sub-basin area is obviously complex with different areas underlain by
Archaean and Proterozoic basement and with the Capricorn suture occurring in the centre of the area
60
Recommendations
The quantitative magnetic interpretation needs to be reconciled with geological models available for the area
In particular the zones tentatively identified as areas with thick sedimentary rocks the Wells Foreland Sub-
basin and the Blake depocentre need to be investigated
Cross sections should be prepared across the basin for joint magneticgravity modelling especially for the Blake
depocentre It is important to be able to explain the strong negative gravity anomaly in this area
In view of the effects of basement density contrasts on the gravity field for the northern part of the area we think
that additional gravity interpretation and acquisition of new gravity data may not be justified as they will not
contribute significantly to understanding basin evolution and structure
It is recommended that GSWA try to get access to company confidential high-resolution aeromagnetic data
rather than flying new surveys The GSWA might offer to fund flying of new infill areas as a bargaining point
References
The original text of this report by Cowan (1995) and 1500 000 scale maps are filed in the GSWA Library under
S10331
COWAN D 1995 Savory Basin quantitative magnetic interpretation Western Australia Geological Survey S-series
S10331 (unpublished)
VACQUIER V STEENLAND N C HENDERSON R G and ZIETZ I 1951 Interpretation of aeromagnetic
maps The Geological Society of America Memoir 47 151p
WILLIAMS I R 1992 Geology of the Savory Basin Western Australia Western Australia Geological Survey
Bulletin 141 115p
61
Appendix 5
Geochemistry
MKS38 250398
Saturate FractionC12+ GLC
1217
Pr18
Ph
22
31CSR WELL-13 315m Cuttings
Figure 51 Canning Stock Route Well 13 gas chromatograph of extract of auger drill sample
12
17
18
22
31
Pr Ph
LDDH 1 6623m CoreSaturate FractionC12+ GLC
MKS35 240398
Figure 52 Gas chromatograph of extract from core sample at 6623 m LDDH1
62
Table 51 Canning Stock Route Well 13 auger drill samples
GSWA sample Drill depth (m)(a) Comments
135601 150 At watertable 135602 203 (all samples consist 135603 310 of sand mud and water) 135604 315 At total depth
NOTE (a) Datum for drill depth is the top of sediment fill in the well which is 155 m below ground level (ie the total depth of 315 m is 47 m below ground level)
Table 52 Canning Stock Route Well 13 gas chromatography data for 315 m depth sediment sample
Parameter Value
Weight of rock extracted (grams) 945 Total extract (ppm) 519 n-Alkane distribution n-C12 07 n-C13 23 n-C14 26 n-C15 22 n-C16 19 n-C17 14 i-C19 23 n-C18 14 i-C20 08 n-C19 11 n-C20 16 n-C21 25 n-C22 29 n-C23 70 n-C24 42 n-C25 95 n-C26 43 n-C27 83 n-C28 38 n-C29 87 n-C30 31 n-C31 273 Alkane compositional data Pristane phytane ratio 279 Pristane n-C17 ratio 161 Phytane n-C18 ratio 059 CPI (1)(a) 284 CPI (2) 209 (C21 + C22) (C28 + C29) 043
NOTE (a) CPI= Carbon preference index
63
Table 53 LDDH1 extract liquid chromatography data for 6623 m concentration
Rock extracted Total extract (grams) (ppm)
702 313
NOTE ppm= parts per million
Table 54 LDDH1 saturate gas chromatography data of core for 6623 m alkane composition
Pristane Pristane Phytane (a) CPI (1) CPI (2) (C21+C22) Phytane n-C17 n-C18 (C28+C29)
103 026 024 103 102 325
NOTE (a)CPI = carbon preference index
Table 55 LDDH1 saturate gas chromatography data of core for 6623 m n-alkane distributions
Parameter Value
n-C12 17 n-C13 38 n-C14 55 n-C15 60 n-C16 65 n-C17 74 i-C19 19 n-C18 78 i-C20 19 n-C19 80 n-C20 79 n-C21 71 n-C22 64 n-C23 57 n-C25 43 n-C24 38 n-C27 31 n-C28 23 n-C29 19 n-C30 12 n-C31 10
64
Appendix 6
Table 61 Summary of data from Trainor waterbores (TWB) and Bullen waterbores (BWB)
Well AMG Elevation TD Status(b) Completion details Water Salinity Water level Flow rate Depth to consolidated AGD84 GL (m) (m) struck mgl(c) (m) (LHr) lithology aquifer(e) Z51(a) Interval (m) (100 mm PVC) (m) (mgl)(d)
TWB 1 473660E 453 122 comp 0ndash75 plain 63 7 300 24 2 880 12 m 7287404N 75ndash93 slotted (9 260) McFadden Fm 93ndash99 plain TWB 2 472 977E 475 23 abd nil 15 m 7285877N Skates Hills Fm dry TWB 3 473259E 475 50 abd nil 7 m 7285849N Skates Hills Fm dry TWB 4 463225 E 445 50 comp 0ndash22 plain 35 7 200 55 3 600 0 m 7286143N 22ndash34 slotted (8 140) Tertiary sand and gravel 23ndash60 plain TWB 5 463095E 445 31 comp 0ndash19 plain 13 26 000 655 3 600 Tertiary sand and gravel 7277721N 19ndash25 slotted (36 700) 25ndash31 plain TWB 6 457013E 455 50 comp 0ndash42 plain 38 920 119 600 0 m 7274352N 42ndash48 slotted (1 030) Cornelia Fm ss TWB 7 453739E 475 26 susp 0ndash2 plain 11 9 300 48 4 500 0 m 7263891N (10 500) Tertiary sand TWB 8 433893E 535 60 susp 0ndash2 plain 47 8 500 gt46 1 200 0 m 7245991N (10 900) Tertiary sand and Brassey Range Fm ss TWB 9 437219E 505 51 comp 0ndash47 plain 45 1 000 58 600 1 m 7235905N 47ndash51 slotted (990) Brassey Range Fm ss TWB 10 434927E 495 32 susp 0ndash2 plain 235 450 120 0 m 7225875N (500) Dolerite
65
BWB 1 287337E 580 122 abd Nil 1 m 7245861N Jilyili Fm dry BWB 2 288346E 545 50 comp 0ndash26 plain 15 630 3 29 000 0 m 7240423N 26ndash38 slotted (730) Tertiary sand and gravel 38ndash50 plain BWB 3 305637E 545 50 abd 19 8 800 43 7 200 0 m 7240423N (10 550) Tertiary ss BWB 4 320167E 515 445 comp 0ndash20 plain 9 980 445 24 000 0 m 7248097N 20ndash32 slotted (1 190) Tertiary ss 32ndash44 plain BWB 5 353393E 545 20 susp 0ndash2 plain 45 (970) 1 m 7238934N Basalt
NOTES (a) GPS accuracy ~ 150 m (b) Comp = completed abd = abandoned susp = suspended (c) Salinity from conductivity (d) Analysis total dissolved solids (e) Fm = Formation ss = sandstone
42
HICKMAN A H WILLIAMS I R and BAGAS L 1994 Proterozoic geology and
mineralization of the TelferndashRudall region Paterson Orogen Geological Society of Australia
(WA Division) Excursion Guidebook no 5 56p
HOCKING R M MORY A J and WILLIAMS I R 1994 An atlas of Neoproterozoic and
Phanerozoic basins of Western Australia in The sedimentary basins of Western Australia
edited by P G PURCELL and R R PURCELL Petroleum Exploration Society of Australia
Symposium Perth WA 1994 Proceedings p 21ndash 44
JACKSON P R 1966 Geology and review of exploration Officer Basin Western Australia
Hunt Oil Company Western Australia Geological Survey S-series S26 (unpublished)
JACKSON M J 1971 Notes on a geological reconnaissance of the Officer Basin Western
Australia Australia BMR Geology and Geophysics Record 19715 30p
JACKSON M J and van de GRAAFF W J E 1981 Geology of the Officer Basin Western
Australia Australia BMR Geology and Geophysics Bulletin 206 102 p
LOWRY D C JACKSON M J van de GRAAFF W J E and KENNEWELL P J 1971
Preliminary result of geological mapping in the Officer Basin Western Australia Western
Australia Geological Survey Annual Report for 1971 p 50ndash56
MYERS J S 1990 Precambrian in Geology and mineral resources of Western Australia
Western Australia Geological Survey Memoir 3 p 737ndash750
MYERS J S SHAW R D and TYLER I M 1994 Proterozoic tectonic evolution of
Australia 12th Australian Geological Convention Geological Society of Australia Abstracts
no 37 p 312
NEDIN C and JENKINS R J F 1991 Re-evaluation of unconformities separating the
lsquoEdiacaranrsquo and Cambrian systems South Australia Palaios v 6 p 102ndash108
PHILLIPS B J JAMES A W and PHILIP G M 1985 The geology and hydrocarbon
potential of the north-western Officer Basin APEA Journal 25 (1) p 52ndash61
POWELL C McA LI Z X McELHINNY M W MEERT J G and PARK J K 1993
Paleomagnetic constraints on timing of the Neoproterozoic breakup of Rodinia and Cambrian
formation of Gondwana Geology v 21 p 889ndash892
43
POWELL C McA PREISS W V GATEHOUSE C G KRAPEZ B and LI Z X 1994
South Australian record of a Rodinian epicontinental basin and its mid-Neoproterozoic
breakup to form the Palaeo-Pacific Ocean Tectonophysics v 237 no 3ndash4 p 113ndash140
PREISS W V 1976 Proterozoic stromatolites from the Nabberu and Officer Basins Western
Australia and their biostratigraphic significance South Australia Geological Survey Report
of Investigations no 47 p 1ndash51
TOWNSON W G 1985 The subsurface geology of the western Officer Basin mdash results of
Shellrsquos 1980ndash1984 petroleum exploration campaign APEA Journal v 25 (1) p 34ndash51
WATTS K J 1982 The geology of the Townsend Quartzite Upper Proterozoic shallow water
deposit of the Northern Officer Basin Western Australia Perth University of Western
Australia BSc honours thesis (unpublished)
WELLS A T and KENNEWELL P J 1974 Evaporite exploration in the Officer Basin
Western Australia at the Madley Diapirs Australia BMR Record 1974194 (unpublished)
WILLIAMS I R and MYERS J S 1990 Paterson Orogen in Geology and mineral resources
of Western Australia Western Australia Geological Survey Memoir 3 p 274ndash286
WILLIAMS I R 1990 Savory Basin in Geology and mineral resources of Western Australia
Western Australia Geological Survey Memoir 3 p 329ndash334
WILLIAMS I R 1994 The Neoproterozoic Savory Basin Western Australia in The
sedimentary basins of Western Australia edited by P G PURCELL and R R PURCELL
Petroleum Exploration Society of Australia Symposium Perth WA 1994 Proceedings p
841ndash850
WILSON R B 1967 Woolnough Hills and Madley diapiric structures Gibson Desert WA
APEA Journal v 7 p 94ndash102
44
Appendix 2
Meteorological data (from Bureau of Meteorology Perth 1994)
Table 21 Wiluna rainfall (mm)
Year Jan Feb Mar Apr May Jun Jul Aug Sept Oct Nov Dec
1975 0 45 446 309 306 59 276 4 34 886 638 164 1976 16 154 12 138 53 16 34 62 12 238 0 2 1977 44 0 66 74 68 95 24 363 1 58 12 727 1978 234 522 94 16 0 96 367 24 16 353 185 45 1979 19 173 122 88 91 4 0 246 58 0 169 114 1980 148 764 68 1081 259 626 629 06 56 02 174 0 1981 123 476 192 32 196 118 44 74 14 0 28 312 1982 374 705 206 244 1079 92 02 143 368 526 368 118 1983 1 112 928 248 0 212 56 32 5 1 42 496 1984 149 7 342 84 836 0 348 132 224 04 16 172 1985 596 483 0 166 556 0 514 56 0 0 4 0 1986 0 154 35 0 0 1085 23 01 239 137 0 04 1987 1204 119 19 89 17 575 154 126 07 1 0 398 1988 46 202 164 13 388 0 202 104 0 0 224 1309 1989 207 234 26 703 278 536 57 0 01 0 144 02 1990 1035 23 281 46 126 53 94 218 44 9 42 0 1991 48 0 41 45 0 472 297 12 0 1 0 7 1992 112 96 1025 1227 323 65 04 174 0 132 48 4 1993 0 697 0 202 445 0 12 306 18 05 14 33 Mean 25 35 22 27 27 25 18 12 6 13 13 21
JAN FEB MAR APR MAY JUN JUL AUG SEP OCT NOV DEC0
10
20
30
40
Mea
n R
ain
fall
(mm
)
Month
Mean monthly rainfall in Wiluna
MKS41 140498
45
Table 22 Wiluna minimum temperature (degC)
Year Jan Feb Mar Apr May Jun Jul Aug Sept Oct Nov Dec
1975 ndash 23 203 15 94 63 71 62 103 124 169 205 1976 242 229 194 15 10 63 59 73 95 143 16 228 1977 243 25 197 148 96 95 56 86 102 ndash 188 23 1978 241 232 203 18 102 64 76 8 9 152 19 205 1979 255 226 216 167 83 6 59 79 97 145 198 223 1980 255 226 231 155 134 83 68 75 121 108 193 223 1981 245 216 19 182 119 6 54 78 138 159 163 218 1982 232 224 177 16 ndash ndash 37 111 112 164 209 225 1983 235 24 197 147 112 88 39 88 121 162 189 219 1984 241 243 191 156 ndash 72 66 7 95 161 182 211 1985 244 231 ndash 159 98 65 71 73 117 147 205 ndash 1986 ndash 229 226 155 93 96 43 49 10 122 ndash 219 1987 ndash 217 183 175 85 77 68 68 112 ndash ndash 221 1988 238 214 209 178 111 ndash ndash 86 104 157 171 195 1989 ndash 237 199 165 107 67 44 61 107 131 187 ndash 1990 232 ndash 211 155 118 62 57 87 102 149 195 22 1991 26 256 217 168 122 101 78 ndash 113 18 168 219 1992 227 227 214 169 102 98 59 69 ndash 125 159 196 1993 241 218 196 171 103 ndash 49 68 88 128 192 211 Mean 24 23 20 16 10 8 6 8 11 14 18 21
NOTE Dashes indicate data unavailable
JAN FEB MAR APR MAY JUN JUL AUG SEP OCT NOV DEC0
10
20
30
40
Month
MKS43 140498
50
Mean monthly minimum temperatures at Wiluna
Mea
n T
emp
erat
ure
(degC
)
46
Table 23 Wiluna maximum temperature (degC)
Year Jan Feb Mar Apr May Jun Jul Aug Sept Oct Nov Dec
1975 ndash 349 326 281 247 201 197 212 256 248 31 344 1976 374 369 346 297 248 206 208 225 265 287 313 388 1977 397 392 352 296 234 212 222 244 ndash 308 337 383 1978 378 345 346 316 242 195 176 205 231 295 334 356 1979 403 36 364 295 ndash ndash ndash 193 242 318 359 373 1980 392 342 377 275 24 176 179 233 292 288 349 391 1981 385 346 337 342 242 178 201 224 30 326 326 369 1982 372 359 315 307 ndash ndash 196 253 252 305 353 379 1983 381 389 327 272 263 222 187 248 287 321 336 366 1984 378 393 322 299 226 215 178 214 234 ndash 336 364 1985 40 366 ndash 294 224 216 205 212 284 307 355 ndash 1986 ndash 383 372 307 ndash 193 166 196 261 277 ndash 382 1987 ndash 339 328 305 21 202 214 218 275 ndash ndash 374 1988 388 365 353 301 23 ndash ndash 228 283 334 31 33 1989 ndash 375 339 285 238 179 181 219 275 298 336 ndash 1990 368 ndash 36 309 268 19 188 205 274 309 373 393 1991 414 416 363 315 268 206 21 ndash 279 338 332 368 1992 363 383 336 263 213 178 213 197 ndash 285 313 359 1993 396 357 344 301 221 ndash 197 215 253 294 347 362 Mean 39 37 34 30 24 20 20 22 27 30 34 37 NOTE Dashes indicate data unavailable
JAN FEB MAR APR MAY JUN JUL AUG SEP OCT NOV DEC0
10
20
30
40
Month
MKS42 140498
50
Mean monthly maximum temperatures at Wiluna
Mea
n T
emp
erat
ure
(degC
)
47
Appendix 3
Table 31 Summary of palynological results
Drillhole Depth (m) F no(a) GSWA no Lithology Formation Assemblage TAI(b)
BWB 1 74ndash75 F49668 135741 dark-grey siltstone basalt Jilyilli gt5 BWB 1 98ndash100 F49669 135742 dark-grey siltstone basalt Jilyilli gt5 BWB 1 121ndash122 F49670 135743 dark-grey siltstone basalt Jilyilli gt5 TWB 1 86ndash87 F49671 135631 dark-grey siltstone McFadden 3+ TWB 1 104ndash105 F49672 135632 dark-grey siltstone Cornelia 3+ TWB 1 121ndash122 F49673 135633 dark-grey siltstone Cornelia 4 TWB 2 14ndash15 F49674 135634 dark-grey siltstone Skates Hills 3+ TWB 6 49ndash50 F49675 135675 dark-grey siltstone Cornelia 1 3+ TWB 9 49ndash51 F49676 135704 dark-grey siltstone Brassey Range 1 3+ Trainor 1 37497- F49733 138939 black mudstone with Cornelia 5 37509 light-grey siltstone Trainor 1 3809 F49734 138940 dark-grey and black Cornelia 4- laminated mudstone Trainor 1 4170 F49735 138941 black unlaminated mudstone Cornelia 4- Trainor 1 4950 F49851 139501 dark-grey indurated siltstone Cornelia 5 Trainor 1 6032 F49852 139502 dark- and light-grey Cornelia 5 indurated siltstone Trainor 1 6434 F49853 139503 greenish indurated finely Cornelia 5 laminated siltstone LDDH 1 270 F49678 138934 dark-grey siltstone interbeds Waters 1 3+ in enterolithic evaporite Tarcunyah Gp LDDH 1 277 F49679 138935 dark-grey siltstone in cavity Waters 1 3+ in enterolithic evaporite Tarcunyah Gp
NOTES (a) GSWA Fossil Catalogue number (b) TAI = Thermal Alteration Index of Traverse (1988 plate 1)
48
Appendix 4
Savory Sub-basin quantitative magnetic and gravity interpretation (extracted from Cowan 1995)
Summary
A program of quantitative aeromagnetic interpretation has been completed on BMRAGSO data from the Savory Sub-
basin Western Australia Quantitative aeromagnetic interpretation utilized the 3D Euler deconvolution method
supported by wavenumber filtering and image processing The results have provided useful information on structural
trends and depth to magnetic sources in a structurally complex area Depth to magnetic source analysis has provided
information on intra-sedimentary magnetic sources as well as basement rocks
The results of the interpretation support previously identified depocentres However the presence of magnetic
sources at several levels makes it very difficult to produce a reliable magnetic basement depth contour map It is
considered more productive to work with the 3D Euler colour circle plots and images rather than trying to contour the
results It would be necessary to carry out a full-scale interpretation of the BMRAGSO profile data to improve on the
3D Euler results The regional gravity was found to be useful in interpreting the regional setting of the area although
the very wide data spacing limits quantitative use of the data The gravity data show quite a complex picture with
limited consistent correlation between gravity features and basin structures This suggests that gravity anomalies
reflect changes in density of the basement rocks rather than basement topography especially in the northern part of the
basin
It is recommended that the GSWA investigate access to company confidential high-resolution aeromagnetic data
prior to planning further aeromagnetic surveys Private companies have flown large parts of the northern half of the
area as part of their diamond exploration program Additional gravity coverage of the area may be more cost effective
than magnetic surveys as the gravity data provides more information on changes within the sedimentary section
Introduction
The main use of aeromagnetic data in petroleum exploration has been the determination of magnetic basement
topography although there has been increasing interest in analysis of intra-sedimentary magnetic anomalies
intrabasement and suprabasement magnetic anomalies These anomalies are used to determine depth to magnetic
basement rocks and hence determine the thickness of the sedimentary sequence Unfortunately interpretation of the
intrabasement and suprabasement magnetic anomalies is non-unique in terms of position and size of causative sources
because of the inherent ambiguity of potential-field methods However this ambiguity can be reduced by placing
49
constraints on source geometry and magnetization and by using geological and other geophysical data to constrain
the solution
Before 1970 most depth-determination techniques involved graphical determination of slopes of selected
magnetic anomalies and application of various empirical factors to convert the slopes into depth estimates Geological
Society of America Memoir 47 Interpretation of Aeromagnetic Maps by Vacquier et al (1951) was a landmark for
this type of interpretation
Automated interpretation procedures have played an increasingly important role in depth interpretation and a
wide range of techniques have been developed Many of these techniques are designed for application to located data
profiles and assume a two-dimensional geometry However there has been renewed interest in techniques applicable
to gridded data
Two distinct types of method can be recognized In the first case often described as discrete methods individual
isolated magnetic anomalies are interpreted and the results used to produce a map of basement relief In the second
case often described as continuous methods areas of data containing a number of anomalies are interpreted
statistically to produce direct output of basement depths
The discrete methods usually involve a semiautomatic initial phase which generates a large number of possible
depth solutions and an interactive second phase to screen and select acceptable solutions The advantage of this
approach is that the interpreter can select features that are relatively free from interference from adjacent anomalies
and consider all aspects of a particular magnetic anomaly The disadvantage is that interpretation can be very time
consuming as a wide range of depths are usually possible depending on the initial model chosen and a significant
amount of effort is needed to select the correct model In the case of the Savory Sub-basin dataset we encountered
problems in separating basement related effects from the effects of shallower intrasedimentary magnetic sources
Because of these problems we have concentrated on displaying the Euler results accompanied by separation filter
images of the data to show the shallower effects and deeper effects rather than trying to refine a 3D Euler
deconvolution depth-to-crystalline-basement contour
The continuous methods are very direct provided that the rather restrictive assumption can be made that all
anomalies are due to lateral magnetization changes due to basement topography This means that shallow effects and
large intrabasement anomalies must be removed from the data This involves judgement and skill as it is necessary to
distinguish between the lower amplitude suprabasement anomalies due to basement topography and the larger
intrabasement anomalies reflecting magnetization changes within the basement These methods were not considered
suitable for the Savory Sub-basin magnetic dataset but were used to invert the gravity data
50
Limitations of magnetic and gravity interpretation
Interpretation of the area is limited by a shortage of information on the nature and physical properties of the deeper
sedimentary sequence and the underlying basement rocks However using techniques such as cross-correlation of
gravity and pseudo-gravity data it is possible to try to differentiate between anomalies relating to basement and those
related to the sedimentary sequence
Gravity anomalies reflect changes within the sedimentary sequence as well as basement condition These
changes in density of sedimentary rocks produce gravity anomalies without a corresponding magnetic anomaly hence
the complementary nature of gravity and magnetic surveys The main use of magnetics is to determine depth to
magnetic basement and any intra-sedimentary volcanic rocks or intrusives whereas gravity provides much more
general information on the sedimentary sequence
Unfortunately interpretation of gravity anomalies is complicated since they can be due to a number of geological
features including
bull major basement faults
bull basement highs
bull igneous intrusions within the basement
bull sedimentary basins which may or may not be isostatically compensated
bull intra-sedimentary volcanics and associated plutonic centres
Two major problems affect the interpretation of both magnetic and gravity data
1 The inherent ambiguity of potential-field data There is no unique solution to any measured gravity or magnetic
anomaly and theoretically there will be an infinite number of source geometry and magnetizationdensity
combinations which will fit the observed data This means that any a priori information which helps to select a
suitable model is very useful
2 Measured anomalies are the summation of effects from different depths For example an observed gravity profile
may contain contributions from shallow sources (density variations within the sedimentary basin) intermediate
depth sources (density variations due to large igneous intrusions within the basement) and deep sources (crustal
thinning producing a mantle anomaly) Separation of these component responses is the regionalresidual problem
which we solve using spectral analysis and differential upward continuation-based separation filtering
Regional setting and interpretation overview
The area studied includes parts of BALFOUR DOWNS (SF51-9) RUDALL (SF51-10) ROBERTSON (SF51-13) GUNANYA
(SF51-14) COLLIER (SG50-4) BULLEN (SG51-1) TRAINOR (SG51-2) MADLEY (SG51-3) NABBERU (SG50-5)
STANLEY (SG51-6) and HERBERT (SG51-7) 1250 000 sheets Broadly the area lies between latitudes 22deg00rsquondash25deg30rsquoS
and longitudes 119deg30rsquondash123deg30rsquoE
51
Regional gravity
The AGSO regional gravity data (at nominal 11 km spacing) was gridded at a 4 km mesh spacing using a minimum-
curvature algorithm Bouguer gravity values in the area are negative reflecting mass deficiency at depth and range
from -84 mgals to -25 mgals
A Bouguer gravity colour image is shown as Figure 41 A residual grid was produced by removing a fifth-order
orthogonal polynomial from the Bouguer data but did not add to the interpretation
120deg 121deg 122deg 123deg
23deg
24deg
25deg
-25
-84
50 km
MKS46 180598
mgal
Figure 41 Regional Bouguer gravity (BMRAGSO data) gridded at 4 km
52
The data show a complex pattern of positive and negative anomalies with no clearly defined trends Correlations
with aeromagnetic data and known basin structures are poor A vague north-northwest linear trend appears to coincide
with the Marloo Fault (Figure 42) A prominent negative anomaly appears to coincide with the Blake Fold and Fault
Belt depocentre and continues as a narrower negative anomaly to the east until it widens out again near the edge of the
basin Elsewhere the gravity data show little correlation with known basin structures and it is likely that especially in
the north of the area gravity anomalies are due to density changes in the basement rather than changes in basement
topography
Production of wavelength-filtered residual gravity plots and vertical gradient plots showed very patchy aliased
data reflecting poor sampling in much of the area
Regional magnetics
The AGSO regional aeromagnetic data were gridded at a 400 m mesh spacing using a minimum-curvature algorithm
(Figure 43) Most of the data has a line spacing of 1600 m with small areas of 1 km spacing The quality of the data is
acceptable for regional interpretation but is not adequate for detailed analysis The accuracy of the flight path is rather
variable reflecting the vintage of the data and the noise envelope of the data is poor by modern standards Problems
were also encountered in joining different map sheets
The magnetic anomaly pattern over the south and west part of the area shows a strong high frequency signature
reflecting the presence of widespread basic sills and dykes Some of the major north-northeasterly trending dykes can
be traced over considerable distances
Discontinuous high-frequency anomalies extend as a northwest-trending zone through the centre of the area and
this zone includes a conspicuous circular magnetic anomaly which is probably a ring complex
The northern and eastern parts of the area are characterized by long-wavelength deep-seated basement magnetic
anomalies with 120deg and 150deg trends dominant The Marloo and Perentie Faults (Figure 42) appear as distinct linear
zones and offsets A prominent easterly trending negative anomaly in the northwest of the area appears to swing round
to the southeast and may separate different basement blocks One possible interpretation is that this very deep seated
anomaly separates areas of Archaean and Proterozoic basement
Regional geology
The regional geology is described in Williams (1992) The GSWA provided a digitized version of Plate 2 from this
Bulletin the structural interpretation map to use as an overlay (Figure 42)
53
Pp
Pp
PSd
PSd
PSd
PSd
PSd
PSo
PSt
PSt
PSf
PSf
PSf
PSb
PSb
PSb
PSsPSs
PSs
PSb
PSm
PSp
PSc
PSc
PSw
PSw
PSw
PSg
PSr
PSj
PSg
PM
Pk
PY
PY
PSd
L
L
L
L
L
L
L
LL
L
L
L
LL
L
LL
L L
LL
L L
L
L
L
L
L
L
L
LL
L
L
BLAKEDEPOCENTRE
MA
RLO
O
FAU
LT
PERENTIEFAULT
50 km
MKS39120598
120deg 121deg 122deg 123deg
25deg
24deg
23deg
Approximate boundaryof aeromagnetic interpretation
PML
PSgL
PSjL
PML
PSpL
PML
PML
PSfL
PSfL
PSpL
LPc
LPcLPcPSrL
LPA
Durba Sandstone
Woora Woora Formation
McFadden Formation
Tchukardine Formation
Boondawari Formation
Skates Hills Formation
Mundadjini Formation
Coondra Formation
Spearhole Formation
Watch Point Formation
Jilyili Formation
Brassey Range Formation
Glass Spring Formation
Paterson Formation
Yeneena Group
Karara Formation
Cornelia Formation
Kahrban Subgroup
Bangemall Group
Fault
Formation boundary
PSdL
PSoL
PSfL
PStL
PSbL
PSsL
PSmL
PScL
PSpL
PSwL
PSjL
PSrL
PSgL
Pp
PYL
PkL
LPc
LPA
PML
Savory Group Other Units
PYL
Figure 42 Regional geology and structure map (after Williams 1992)
54
120deg 121deg 122deg 123deg
23deg
24deg
25deg
5820
3750
MKS47 180598
nT
50 km
Figure 43 Regional aeromagnetic data total magnetic intensity (BMRAGSO data) gridded at 400 m
Analysis
3D analysis
3D Euler deconvolution was used as the primary depth-determination method The advantage of this approach is that
consistent solutions can be obtained over the entire area with minimal assumptions about source geometries Euler
deconvolution of gridded data is used for positional information and estimation of depth to top of source Euler
55
deconvolution yields a large number of depth solutions which have to be screened to reject spurious solutions Results
are plotted as circles in eight depth ranges with radius proportional to depth and colour coded
The 400 m total magnetic intensity grid was used for the analysis Horizontal gradients in x and y and the vertical
gradient were calculated 3D Euler deconvolution was tested on the 400 m gridded data using windows of 9 times 9 and
11 times 11 and 16 times 16 data points and structural indices 05 (fault) and 10 (sill or dyke) It was concluded that the
16 times 16 window produced the best results overall and final plots were produced for the 16 times 16 window and structural
index 05 (Fig 44) Results were very good over the northern and central parts of the area showing magnetic sources
Figure 44 Depth to magnetic source 3D Euler deconvolution 16 times 16 window of 400 m gridded data structural index 05
56
at several different levels Unfortunately in the extreme south of the area shallow intrasedimentary magnetic sources
(sills and dykes) dominated the inversion and the results contained few basement solutions
In order to reduce these problems the 400 m gridded data were filtered using a separation filter based on
interpretation of the log-energy spectrum The 3D Euler method was run on the filtered data in order to generate more
basement-depth solutions Results for the deep-separation filter data were gridded and presented as a colour image in
Cowan (1995) Attempts to grid the Euler output were unsatisfactory and it is considered safer to interpret the 3D
Euler depth plots The 3D Euler depth results from the separation-filter run should be analysed with care as perfect
separation of the basement can never be achieved and there will always be some contamination from sources at
different levels
The results of original total magnetic intensity 3D Euler depth estimation for structural index 05 using a 16 point
window have been plotted at 1500 000 scale (not included in this publication but available in Cowan (1995) from the
GSWA Library as S10331) and as reduced A4 colour circle plots (Figure 44)
The results of deep-basement 3D Euler depth estimation for structural index 05 using a 16 point window have
been plotted as a colour image at 1500 000 scale and as an A4 image (not included in this publication)
2D analysis
Two equispaced profiles were interpolated with a 50 m station interval from the AGSO-located data profiles for the
BULLEN 1250 000 sheet The interpolated profiles were analysed using 2D Euler deconvolution and Werner
deconvolution Results are included in Cowan (1995) and show the use of these methods for more detailed analysis
Filtered data
In order to reconcile 3D Euler results from shallow basement and intrasedimentary magnetic sources we produced
several separation-filtered maps and images We found the shallow-layer double-separation filter (Figure 45) to be
very effective for shallow sources and the deep-layer standard-separation filter (Figure 46) for the basement layer
Gravity and magnetic data correlation
Both lsquoreduced to the polersquo (RTP) magnetics (Figure 47) and pseudo-gravity data (Figure 48) were produced as part of
the reconciliation of gravity and magnetic signatures In both cases the filtering operations assumed magnetization by
induction in the present Earths field The RTP data are fairly similar to the total magnetic intensity The pseudo-
57
gravity data are dominated by a northwest-trending strong positive anomaly and there is little correlation with the
Bouguer gravity data
The poor magneticgravity correlation is confirmed by cross-correlation of the RTP magnetics and the gravity
gradient The correlation plot in Figure 49 shows little coherent response with numerous zones of positive and
negative correlation
Figure 45 Regional aeromagnetic data shallow layer separation filter (BMRAGSO data) gridded at 400 m
Results
In the north and east of the area on the Wells Foreland Sub-basin trend (refer to Figure 1 main text) we see a range
of quite deep 3D Euler depths and several trend directions with north-northwesterly dominant There are relatively few
shallow intrasedimentary solutions in this zone
The second area of deep 3D Euler solutions lies over the Blake depocentre (Figure 43) with several trend
directions
Elsewhere the 3D Euler results are dominated by shallow intrasedimentary depth solutions reflecting mainly the
dolerite sills dykes and the ring complex However where we do see basement-related solutions in the south and
west of the area they appear to be shallower than those noted for the Wells Foreland Sub-basin and the Blake
depocentre
58
Figure 46 Regional aeromagnetic data deep-layer separation filter (BMRAGSO data) gridded at 400 m
Figure 48 Regional aeromagnetic data pseudo-gravity transform (BMRAGSO data) gridded at 400 m
Figure 47 Regional aeromagnetic data reduced-to-pole (BMRAGSO data) gridded at 400 m
Figure 49 Regional aeromagnetic and gravity data gravitymagnetic correlation using RTP magnetics and gravity gradient (BMRAGSO data) gridded at 4 km
59
This subdivision of the area into two zones of deep solutions is consistent with interpreted depocentres
However the interference between sources at different levels and the complexity of the magnetic response of the
basement rocks precludes more refined interpretation at this stage
The area of deep 3D Euler solutions over the Blake depocentre correlates with the pronounced negative gravity
anomaly discussed in the gravity interpretation section Using a density contrast of -015 gcc the negative gravity
anomaly could indicate up to 6ndash8 km of low-density sedimentary rocks depending on assumptions about the regional
field
The area of deep 3D Euler solutions over the Wells Foreland Sub-basin has a complex gravity expression and no
clear basin structure emerges from inversion of these data As noted previously it is likely that observed gravity
anomalies reflect contrasts in basement density rather than basement topography
Separation filtering applied to the magnetic data helps to enhance the intrasedimentary magnetic signature and to
give a better impression of the basement magnetic signature even though separation of the basement response is not
perfect
Conclusions
Quantitative aeromagnetic interpretation using 3D Euler deconvolution supported by wavenumber filtering and image
processing has been successful in providing structural trend and depth information for the Savory Sub-basin
Quantitative magnetic interpretation has revealed two zones of relatively deep magnetic basement beneath the
Wells Foreland Sub-basin and the Blake depocentre
This analysis of the magnetic data supports interpreted depocentres but the complexity of the basement magnetic
signature and interference from sources at different depths precludes further refinement to a map of basement
topography
Regional gravity proved to be very useful in understanding the regional setting of the area and in providing
support for aspects of the interpretation The gravity data support the interpretation of the Blake depocentre
suggesting up to 6ndash8 km of low-density sedimentary rocks
The deep structure of the Savory Sub-basin area is obviously complex with different areas underlain by
Archaean and Proterozoic basement and with the Capricorn suture occurring in the centre of the area
60
Recommendations
The quantitative magnetic interpretation needs to be reconciled with geological models available for the area
In particular the zones tentatively identified as areas with thick sedimentary rocks the Wells Foreland Sub-
basin and the Blake depocentre need to be investigated
Cross sections should be prepared across the basin for joint magneticgravity modelling especially for the Blake
depocentre It is important to be able to explain the strong negative gravity anomaly in this area
In view of the effects of basement density contrasts on the gravity field for the northern part of the area we think
that additional gravity interpretation and acquisition of new gravity data may not be justified as they will not
contribute significantly to understanding basin evolution and structure
It is recommended that GSWA try to get access to company confidential high-resolution aeromagnetic data
rather than flying new surveys The GSWA might offer to fund flying of new infill areas as a bargaining point
References
The original text of this report by Cowan (1995) and 1500 000 scale maps are filed in the GSWA Library under
S10331
COWAN D 1995 Savory Basin quantitative magnetic interpretation Western Australia Geological Survey S-series
S10331 (unpublished)
VACQUIER V STEENLAND N C HENDERSON R G and ZIETZ I 1951 Interpretation of aeromagnetic
maps The Geological Society of America Memoir 47 151p
WILLIAMS I R 1992 Geology of the Savory Basin Western Australia Western Australia Geological Survey
Bulletin 141 115p
61
Appendix 5
Geochemistry
MKS38 250398
Saturate FractionC12+ GLC
1217
Pr18
Ph
22
31CSR WELL-13 315m Cuttings
Figure 51 Canning Stock Route Well 13 gas chromatograph of extract of auger drill sample
12
17
18
22
31
Pr Ph
LDDH 1 6623m CoreSaturate FractionC12+ GLC
MKS35 240398
Figure 52 Gas chromatograph of extract from core sample at 6623 m LDDH1
62
Table 51 Canning Stock Route Well 13 auger drill samples
GSWA sample Drill depth (m)(a) Comments
135601 150 At watertable 135602 203 (all samples consist 135603 310 of sand mud and water) 135604 315 At total depth
NOTE (a) Datum for drill depth is the top of sediment fill in the well which is 155 m below ground level (ie the total depth of 315 m is 47 m below ground level)
Table 52 Canning Stock Route Well 13 gas chromatography data for 315 m depth sediment sample
Parameter Value
Weight of rock extracted (grams) 945 Total extract (ppm) 519 n-Alkane distribution n-C12 07 n-C13 23 n-C14 26 n-C15 22 n-C16 19 n-C17 14 i-C19 23 n-C18 14 i-C20 08 n-C19 11 n-C20 16 n-C21 25 n-C22 29 n-C23 70 n-C24 42 n-C25 95 n-C26 43 n-C27 83 n-C28 38 n-C29 87 n-C30 31 n-C31 273 Alkane compositional data Pristane phytane ratio 279 Pristane n-C17 ratio 161 Phytane n-C18 ratio 059 CPI (1)(a) 284 CPI (2) 209 (C21 + C22) (C28 + C29) 043
NOTE (a) CPI= Carbon preference index
63
Table 53 LDDH1 extract liquid chromatography data for 6623 m concentration
Rock extracted Total extract (grams) (ppm)
702 313
NOTE ppm= parts per million
Table 54 LDDH1 saturate gas chromatography data of core for 6623 m alkane composition
Pristane Pristane Phytane (a) CPI (1) CPI (2) (C21+C22) Phytane n-C17 n-C18 (C28+C29)
103 026 024 103 102 325
NOTE (a)CPI = carbon preference index
Table 55 LDDH1 saturate gas chromatography data of core for 6623 m n-alkane distributions
Parameter Value
n-C12 17 n-C13 38 n-C14 55 n-C15 60 n-C16 65 n-C17 74 i-C19 19 n-C18 78 i-C20 19 n-C19 80 n-C20 79 n-C21 71 n-C22 64 n-C23 57 n-C25 43 n-C24 38 n-C27 31 n-C28 23 n-C29 19 n-C30 12 n-C31 10
64
Appendix 6
Table 61 Summary of data from Trainor waterbores (TWB) and Bullen waterbores (BWB)
Well AMG Elevation TD Status(b) Completion details Water Salinity Water level Flow rate Depth to consolidated AGD84 GL (m) (m) struck mgl(c) (m) (LHr) lithology aquifer(e) Z51(a) Interval (m) (100 mm PVC) (m) (mgl)(d)
TWB 1 473660E 453 122 comp 0ndash75 plain 63 7 300 24 2 880 12 m 7287404N 75ndash93 slotted (9 260) McFadden Fm 93ndash99 plain TWB 2 472 977E 475 23 abd nil 15 m 7285877N Skates Hills Fm dry TWB 3 473259E 475 50 abd nil 7 m 7285849N Skates Hills Fm dry TWB 4 463225 E 445 50 comp 0ndash22 plain 35 7 200 55 3 600 0 m 7286143N 22ndash34 slotted (8 140) Tertiary sand and gravel 23ndash60 plain TWB 5 463095E 445 31 comp 0ndash19 plain 13 26 000 655 3 600 Tertiary sand and gravel 7277721N 19ndash25 slotted (36 700) 25ndash31 plain TWB 6 457013E 455 50 comp 0ndash42 plain 38 920 119 600 0 m 7274352N 42ndash48 slotted (1 030) Cornelia Fm ss TWB 7 453739E 475 26 susp 0ndash2 plain 11 9 300 48 4 500 0 m 7263891N (10 500) Tertiary sand TWB 8 433893E 535 60 susp 0ndash2 plain 47 8 500 gt46 1 200 0 m 7245991N (10 900) Tertiary sand and Brassey Range Fm ss TWB 9 437219E 505 51 comp 0ndash47 plain 45 1 000 58 600 1 m 7235905N 47ndash51 slotted (990) Brassey Range Fm ss TWB 10 434927E 495 32 susp 0ndash2 plain 235 450 120 0 m 7225875N (500) Dolerite
65
BWB 1 287337E 580 122 abd Nil 1 m 7245861N Jilyili Fm dry BWB 2 288346E 545 50 comp 0ndash26 plain 15 630 3 29 000 0 m 7240423N 26ndash38 slotted (730) Tertiary sand and gravel 38ndash50 plain BWB 3 305637E 545 50 abd 19 8 800 43 7 200 0 m 7240423N (10 550) Tertiary ss BWB 4 320167E 515 445 comp 0ndash20 plain 9 980 445 24 000 0 m 7248097N 20ndash32 slotted (1 190) Tertiary ss 32ndash44 plain BWB 5 353393E 545 20 susp 0ndash2 plain 45 (970) 1 m 7238934N Basalt
NOTES (a) GPS accuracy ~ 150 m (b) Comp = completed abd = abandoned susp = suspended (c) Salinity from conductivity (d) Analysis total dissolved solids (e) Fm = Formation ss = sandstone
43
POWELL C McA PREISS W V GATEHOUSE C G KRAPEZ B and LI Z X 1994
South Australian record of a Rodinian epicontinental basin and its mid-Neoproterozoic
breakup to form the Palaeo-Pacific Ocean Tectonophysics v 237 no 3ndash4 p 113ndash140
PREISS W V 1976 Proterozoic stromatolites from the Nabberu and Officer Basins Western
Australia and their biostratigraphic significance South Australia Geological Survey Report
of Investigations no 47 p 1ndash51
TOWNSON W G 1985 The subsurface geology of the western Officer Basin mdash results of
Shellrsquos 1980ndash1984 petroleum exploration campaign APEA Journal v 25 (1) p 34ndash51
WATTS K J 1982 The geology of the Townsend Quartzite Upper Proterozoic shallow water
deposit of the Northern Officer Basin Western Australia Perth University of Western
Australia BSc honours thesis (unpublished)
WELLS A T and KENNEWELL P J 1974 Evaporite exploration in the Officer Basin
Western Australia at the Madley Diapirs Australia BMR Record 1974194 (unpublished)
WILLIAMS I R and MYERS J S 1990 Paterson Orogen in Geology and mineral resources
of Western Australia Western Australia Geological Survey Memoir 3 p 274ndash286
WILLIAMS I R 1990 Savory Basin in Geology and mineral resources of Western Australia
Western Australia Geological Survey Memoir 3 p 329ndash334
WILLIAMS I R 1994 The Neoproterozoic Savory Basin Western Australia in The
sedimentary basins of Western Australia edited by P G PURCELL and R R PURCELL
Petroleum Exploration Society of Australia Symposium Perth WA 1994 Proceedings p
841ndash850
WILSON R B 1967 Woolnough Hills and Madley diapiric structures Gibson Desert WA
APEA Journal v 7 p 94ndash102
44
Appendix 2
Meteorological data (from Bureau of Meteorology Perth 1994)
Table 21 Wiluna rainfall (mm)
Year Jan Feb Mar Apr May Jun Jul Aug Sept Oct Nov Dec
1975 0 45 446 309 306 59 276 4 34 886 638 164 1976 16 154 12 138 53 16 34 62 12 238 0 2 1977 44 0 66 74 68 95 24 363 1 58 12 727 1978 234 522 94 16 0 96 367 24 16 353 185 45 1979 19 173 122 88 91 4 0 246 58 0 169 114 1980 148 764 68 1081 259 626 629 06 56 02 174 0 1981 123 476 192 32 196 118 44 74 14 0 28 312 1982 374 705 206 244 1079 92 02 143 368 526 368 118 1983 1 112 928 248 0 212 56 32 5 1 42 496 1984 149 7 342 84 836 0 348 132 224 04 16 172 1985 596 483 0 166 556 0 514 56 0 0 4 0 1986 0 154 35 0 0 1085 23 01 239 137 0 04 1987 1204 119 19 89 17 575 154 126 07 1 0 398 1988 46 202 164 13 388 0 202 104 0 0 224 1309 1989 207 234 26 703 278 536 57 0 01 0 144 02 1990 1035 23 281 46 126 53 94 218 44 9 42 0 1991 48 0 41 45 0 472 297 12 0 1 0 7 1992 112 96 1025 1227 323 65 04 174 0 132 48 4 1993 0 697 0 202 445 0 12 306 18 05 14 33 Mean 25 35 22 27 27 25 18 12 6 13 13 21
JAN FEB MAR APR MAY JUN JUL AUG SEP OCT NOV DEC0
10
20
30
40
Mea
n R
ain
fall
(mm
)
Month
Mean monthly rainfall in Wiluna
MKS41 140498
45
Table 22 Wiluna minimum temperature (degC)
Year Jan Feb Mar Apr May Jun Jul Aug Sept Oct Nov Dec
1975 ndash 23 203 15 94 63 71 62 103 124 169 205 1976 242 229 194 15 10 63 59 73 95 143 16 228 1977 243 25 197 148 96 95 56 86 102 ndash 188 23 1978 241 232 203 18 102 64 76 8 9 152 19 205 1979 255 226 216 167 83 6 59 79 97 145 198 223 1980 255 226 231 155 134 83 68 75 121 108 193 223 1981 245 216 19 182 119 6 54 78 138 159 163 218 1982 232 224 177 16 ndash ndash 37 111 112 164 209 225 1983 235 24 197 147 112 88 39 88 121 162 189 219 1984 241 243 191 156 ndash 72 66 7 95 161 182 211 1985 244 231 ndash 159 98 65 71 73 117 147 205 ndash 1986 ndash 229 226 155 93 96 43 49 10 122 ndash 219 1987 ndash 217 183 175 85 77 68 68 112 ndash ndash 221 1988 238 214 209 178 111 ndash ndash 86 104 157 171 195 1989 ndash 237 199 165 107 67 44 61 107 131 187 ndash 1990 232 ndash 211 155 118 62 57 87 102 149 195 22 1991 26 256 217 168 122 101 78 ndash 113 18 168 219 1992 227 227 214 169 102 98 59 69 ndash 125 159 196 1993 241 218 196 171 103 ndash 49 68 88 128 192 211 Mean 24 23 20 16 10 8 6 8 11 14 18 21
NOTE Dashes indicate data unavailable
JAN FEB MAR APR MAY JUN JUL AUG SEP OCT NOV DEC0
10
20
30
40
Month
MKS43 140498
50
Mean monthly minimum temperatures at Wiluna
Mea
n T
emp
erat
ure
(degC
)
46
Table 23 Wiluna maximum temperature (degC)
Year Jan Feb Mar Apr May Jun Jul Aug Sept Oct Nov Dec
1975 ndash 349 326 281 247 201 197 212 256 248 31 344 1976 374 369 346 297 248 206 208 225 265 287 313 388 1977 397 392 352 296 234 212 222 244 ndash 308 337 383 1978 378 345 346 316 242 195 176 205 231 295 334 356 1979 403 36 364 295 ndash ndash ndash 193 242 318 359 373 1980 392 342 377 275 24 176 179 233 292 288 349 391 1981 385 346 337 342 242 178 201 224 30 326 326 369 1982 372 359 315 307 ndash ndash 196 253 252 305 353 379 1983 381 389 327 272 263 222 187 248 287 321 336 366 1984 378 393 322 299 226 215 178 214 234 ndash 336 364 1985 40 366 ndash 294 224 216 205 212 284 307 355 ndash 1986 ndash 383 372 307 ndash 193 166 196 261 277 ndash 382 1987 ndash 339 328 305 21 202 214 218 275 ndash ndash 374 1988 388 365 353 301 23 ndash ndash 228 283 334 31 33 1989 ndash 375 339 285 238 179 181 219 275 298 336 ndash 1990 368 ndash 36 309 268 19 188 205 274 309 373 393 1991 414 416 363 315 268 206 21 ndash 279 338 332 368 1992 363 383 336 263 213 178 213 197 ndash 285 313 359 1993 396 357 344 301 221 ndash 197 215 253 294 347 362 Mean 39 37 34 30 24 20 20 22 27 30 34 37 NOTE Dashes indicate data unavailable
JAN FEB MAR APR MAY JUN JUL AUG SEP OCT NOV DEC0
10
20
30
40
Month
MKS42 140498
50
Mean monthly maximum temperatures at Wiluna
Mea
n T
emp
erat
ure
(degC
)
47
Appendix 3
Table 31 Summary of palynological results
Drillhole Depth (m) F no(a) GSWA no Lithology Formation Assemblage TAI(b)
BWB 1 74ndash75 F49668 135741 dark-grey siltstone basalt Jilyilli gt5 BWB 1 98ndash100 F49669 135742 dark-grey siltstone basalt Jilyilli gt5 BWB 1 121ndash122 F49670 135743 dark-grey siltstone basalt Jilyilli gt5 TWB 1 86ndash87 F49671 135631 dark-grey siltstone McFadden 3+ TWB 1 104ndash105 F49672 135632 dark-grey siltstone Cornelia 3+ TWB 1 121ndash122 F49673 135633 dark-grey siltstone Cornelia 4 TWB 2 14ndash15 F49674 135634 dark-grey siltstone Skates Hills 3+ TWB 6 49ndash50 F49675 135675 dark-grey siltstone Cornelia 1 3+ TWB 9 49ndash51 F49676 135704 dark-grey siltstone Brassey Range 1 3+ Trainor 1 37497- F49733 138939 black mudstone with Cornelia 5 37509 light-grey siltstone Trainor 1 3809 F49734 138940 dark-grey and black Cornelia 4- laminated mudstone Trainor 1 4170 F49735 138941 black unlaminated mudstone Cornelia 4- Trainor 1 4950 F49851 139501 dark-grey indurated siltstone Cornelia 5 Trainor 1 6032 F49852 139502 dark- and light-grey Cornelia 5 indurated siltstone Trainor 1 6434 F49853 139503 greenish indurated finely Cornelia 5 laminated siltstone LDDH 1 270 F49678 138934 dark-grey siltstone interbeds Waters 1 3+ in enterolithic evaporite Tarcunyah Gp LDDH 1 277 F49679 138935 dark-grey siltstone in cavity Waters 1 3+ in enterolithic evaporite Tarcunyah Gp
NOTES (a) GSWA Fossil Catalogue number (b) TAI = Thermal Alteration Index of Traverse (1988 plate 1)
48
Appendix 4
Savory Sub-basin quantitative magnetic and gravity interpretation (extracted from Cowan 1995)
Summary
A program of quantitative aeromagnetic interpretation has been completed on BMRAGSO data from the Savory Sub-
basin Western Australia Quantitative aeromagnetic interpretation utilized the 3D Euler deconvolution method
supported by wavenumber filtering and image processing The results have provided useful information on structural
trends and depth to magnetic sources in a structurally complex area Depth to magnetic source analysis has provided
information on intra-sedimentary magnetic sources as well as basement rocks
The results of the interpretation support previously identified depocentres However the presence of magnetic
sources at several levels makes it very difficult to produce a reliable magnetic basement depth contour map It is
considered more productive to work with the 3D Euler colour circle plots and images rather than trying to contour the
results It would be necessary to carry out a full-scale interpretation of the BMRAGSO profile data to improve on the
3D Euler results The regional gravity was found to be useful in interpreting the regional setting of the area although
the very wide data spacing limits quantitative use of the data The gravity data show quite a complex picture with
limited consistent correlation between gravity features and basin structures This suggests that gravity anomalies
reflect changes in density of the basement rocks rather than basement topography especially in the northern part of the
basin
It is recommended that the GSWA investigate access to company confidential high-resolution aeromagnetic data
prior to planning further aeromagnetic surveys Private companies have flown large parts of the northern half of the
area as part of their diamond exploration program Additional gravity coverage of the area may be more cost effective
than magnetic surveys as the gravity data provides more information on changes within the sedimentary section
Introduction
The main use of aeromagnetic data in petroleum exploration has been the determination of magnetic basement
topography although there has been increasing interest in analysis of intra-sedimentary magnetic anomalies
intrabasement and suprabasement magnetic anomalies These anomalies are used to determine depth to magnetic
basement rocks and hence determine the thickness of the sedimentary sequence Unfortunately interpretation of the
intrabasement and suprabasement magnetic anomalies is non-unique in terms of position and size of causative sources
because of the inherent ambiguity of potential-field methods However this ambiguity can be reduced by placing
49
constraints on source geometry and magnetization and by using geological and other geophysical data to constrain
the solution
Before 1970 most depth-determination techniques involved graphical determination of slopes of selected
magnetic anomalies and application of various empirical factors to convert the slopes into depth estimates Geological
Society of America Memoir 47 Interpretation of Aeromagnetic Maps by Vacquier et al (1951) was a landmark for
this type of interpretation
Automated interpretation procedures have played an increasingly important role in depth interpretation and a
wide range of techniques have been developed Many of these techniques are designed for application to located data
profiles and assume a two-dimensional geometry However there has been renewed interest in techniques applicable
to gridded data
Two distinct types of method can be recognized In the first case often described as discrete methods individual
isolated magnetic anomalies are interpreted and the results used to produce a map of basement relief In the second
case often described as continuous methods areas of data containing a number of anomalies are interpreted
statistically to produce direct output of basement depths
The discrete methods usually involve a semiautomatic initial phase which generates a large number of possible
depth solutions and an interactive second phase to screen and select acceptable solutions The advantage of this
approach is that the interpreter can select features that are relatively free from interference from adjacent anomalies
and consider all aspects of a particular magnetic anomaly The disadvantage is that interpretation can be very time
consuming as a wide range of depths are usually possible depending on the initial model chosen and a significant
amount of effort is needed to select the correct model In the case of the Savory Sub-basin dataset we encountered
problems in separating basement related effects from the effects of shallower intrasedimentary magnetic sources
Because of these problems we have concentrated on displaying the Euler results accompanied by separation filter
images of the data to show the shallower effects and deeper effects rather than trying to refine a 3D Euler
deconvolution depth-to-crystalline-basement contour
The continuous methods are very direct provided that the rather restrictive assumption can be made that all
anomalies are due to lateral magnetization changes due to basement topography This means that shallow effects and
large intrabasement anomalies must be removed from the data This involves judgement and skill as it is necessary to
distinguish between the lower amplitude suprabasement anomalies due to basement topography and the larger
intrabasement anomalies reflecting magnetization changes within the basement These methods were not considered
suitable for the Savory Sub-basin magnetic dataset but were used to invert the gravity data
50
Limitations of magnetic and gravity interpretation
Interpretation of the area is limited by a shortage of information on the nature and physical properties of the deeper
sedimentary sequence and the underlying basement rocks However using techniques such as cross-correlation of
gravity and pseudo-gravity data it is possible to try to differentiate between anomalies relating to basement and those
related to the sedimentary sequence
Gravity anomalies reflect changes within the sedimentary sequence as well as basement condition These
changes in density of sedimentary rocks produce gravity anomalies without a corresponding magnetic anomaly hence
the complementary nature of gravity and magnetic surveys The main use of magnetics is to determine depth to
magnetic basement and any intra-sedimentary volcanic rocks or intrusives whereas gravity provides much more
general information on the sedimentary sequence
Unfortunately interpretation of gravity anomalies is complicated since they can be due to a number of geological
features including
bull major basement faults
bull basement highs
bull igneous intrusions within the basement
bull sedimentary basins which may or may not be isostatically compensated
bull intra-sedimentary volcanics and associated plutonic centres
Two major problems affect the interpretation of both magnetic and gravity data
1 The inherent ambiguity of potential-field data There is no unique solution to any measured gravity or magnetic
anomaly and theoretically there will be an infinite number of source geometry and magnetizationdensity
combinations which will fit the observed data This means that any a priori information which helps to select a
suitable model is very useful
2 Measured anomalies are the summation of effects from different depths For example an observed gravity profile
may contain contributions from shallow sources (density variations within the sedimentary basin) intermediate
depth sources (density variations due to large igneous intrusions within the basement) and deep sources (crustal
thinning producing a mantle anomaly) Separation of these component responses is the regionalresidual problem
which we solve using spectral analysis and differential upward continuation-based separation filtering
Regional setting and interpretation overview
The area studied includes parts of BALFOUR DOWNS (SF51-9) RUDALL (SF51-10) ROBERTSON (SF51-13) GUNANYA
(SF51-14) COLLIER (SG50-4) BULLEN (SG51-1) TRAINOR (SG51-2) MADLEY (SG51-3) NABBERU (SG50-5)
STANLEY (SG51-6) and HERBERT (SG51-7) 1250 000 sheets Broadly the area lies between latitudes 22deg00rsquondash25deg30rsquoS
and longitudes 119deg30rsquondash123deg30rsquoE
51
Regional gravity
The AGSO regional gravity data (at nominal 11 km spacing) was gridded at a 4 km mesh spacing using a minimum-
curvature algorithm Bouguer gravity values in the area are negative reflecting mass deficiency at depth and range
from -84 mgals to -25 mgals
A Bouguer gravity colour image is shown as Figure 41 A residual grid was produced by removing a fifth-order
orthogonal polynomial from the Bouguer data but did not add to the interpretation
120deg 121deg 122deg 123deg
23deg
24deg
25deg
-25
-84
50 km
MKS46 180598
mgal
Figure 41 Regional Bouguer gravity (BMRAGSO data) gridded at 4 km
52
The data show a complex pattern of positive and negative anomalies with no clearly defined trends Correlations
with aeromagnetic data and known basin structures are poor A vague north-northwest linear trend appears to coincide
with the Marloo Fault (Figure 42) A prominent negative anomaly appears to coincide with the Blake Fold and Fault
Belt depocentre and continues as a narrower negative anomaly to the east until it widens out again near the edge of the
basin Elsewhere the gravity data show little correlation with known basin structures and it is likely that especially in
the north of the area gravity anomalies are due to density changes in the basement rather than changes in basement
topography
Production of wavelength-filtered residual gravity plots and vertical gradient plots showed very patchy aliased
data reflecting poor sampling in much of the area
Regional magnetics
The AGSO regional aeromagnetic data were gridded at a 400 m mesh spacing using a minimum-curvature algorithm
(Figure 43) Most of the data has a line spacing of 1600 m with small areas of 1 km spacing The quality of the data is
acceptable for regional interpretation but is not adequate for detailed analysis The accuracy of the flight path is rather
variable reflecting the vintage of the data and the noise envelope of the data is poor by modern standards Problems
were also encountered in joining different map sheets
The magnetic anomaly pattern over the south and west part of the area shows a strong high frequency signature
reflecting the presence of widespread basic sills and dykes Some of the major north-northeasterly trending dykes can
be traced over considerable distances
Discontinuous high-frequency anomalies extend as a northwest-trending zone through the centre of the area and
this zone includes a conspicuous circular magnetic anomaly which is probably a ring complex
The northern and eastern parts of the area are characterized by long-wavelength deep-seated basement magnetic
anomalies with 120deg and 150deg trends dominant The Marloo and Perentie Faults (Figure 42) appear as distinct linear
zones and offsets A prominent easterly trending negative anomaly in the northwest of the area appears to swing round
to the southeast and may separate different basement blocks One possible interpretation is that this very deep seated
anomaly separates areas of Archaean and Proterozoic basement
Regional geology
The regional geology is described in Williams (1992) The GSWA provided a digitized version of Plate 2 from this
Bulletin the structural interpretation map to use as an overlay (Figure 42)
53
Pp
Pp
PSd
PSd
PSd
PSd
PSd
PSo
PSt
PSt
PSf
PSf
PSf
PSb
PSb
PSb
PSsPSs
PSs
PSb
PSm
PSp
PSc
PSc
PSw
PSw
PSw
PSg
PSr
PSj
PSg
PM
Pk
PY
PY
PSd
L
L
L
L
L
L
L
LL
L
L
L
LL
L
LL
L L
LL
L L
L
L
L
L
L
L
L
LL
L
L
BLAKEDEPOCENTRE
MA
RLO
O
FAU
LT
PERENTIEFAULT
50 km
MKS39120598
120deg 121deg 122deg 123deg
25deg
24deg
23deg
Approximate boundaryof aeromagnetic interpretation
PML
PSgL
PSjL
PML
PSpL
PML
PML
PSfL
PSfL
PSpL
LPc
LPcLPcPSrL
LPA
Durba Sandstone
Woora Woora Formation
McFadden Formation
Tchukardine Formation
Boondawari Formation
Skates Hills Formation
Mundadjini Formation
Coondra Formation
Spearhole Formation
Watch Point Formation
Jilyili Formation
Brassey Range Formation
Glass Spring Formation
Paterson Formation
Yeneena Group
Karara Formation
Cornelia Formation
Kahrban Subgroup
Bangemall Group
Fault
Formation boundary
PSdL
PSoL
PSfL
PStL
PSbL
PSsL
PSmL
PScL
PSpL
PSwL
PSjL
PSrL
PSgL
Pp
PYL
PkL
LPc
LPA
PML
Savory Group Other Units
PYL
Figure 42 Regional geology and structure map (after Williams 1992)
54
120deg 121deg 122deg 123deg
23deg
24deg
25deg
5820
3750
MKS47 180598
nT
50 km
Figure 43 Regional aeromagnetic data total magnetic intensity (BMRAGSO data) gridded at 400 m
Analysis
3D analysis
3D Euler deconvolution was used as the primary depth-determination method The advantage of this approach is that
consistent solutions can be obtained over the entire area with minimal assumptions about source geometries Euler
deconvolution of gridded data is used for positional information and estimation of depth to top of source Euler
55
deconvolution yields a large number of depth solutions which have to be screened to reject spurious solutions Results
are plotted as circles in eight depth ranges with radius proportional to depth and colour coded
The 400 m total magnetic intensity grid was used for the analysis Horizontal gradients in x and y and the vertical
gradient were calculated 3D Euler deconvolution was tested on the 400 m gridded data using windows of 9 times 9 and
11 times 11 and 16 times 16 data points and structural indices 05 (fault) and 10 (sill or dyke) It was concluded that the
16 times 16 window produced the best results overall and final plots were produced for the 16 times 16 window and structural
index 05 (Fig 44) Results were very good over the northern and central parts of the area showing magnetic sources
Figure 44 Depth to magnetic source 3D Euler deconvolution 16 times 16 window of 400 m gridded data structural index 05
56
at several different levels Unfortunately in the extreme south of the area shallow intrasedimentary magnetic sources
(sills and dykes) dominated the inversion and the results contained few basement solutions
In order to reduce these problems the 400 m gridded data were filtered using a separation filter based on
interpretation of the log-energy spectrum The 3D Euler method was run on the filtered data in order to generate more
basement-depth solutions Results for the deep-separation filter data were gridded and presented as a colour image in
Cowan (1995) Attempts to grid the Euler output were unsatisfactory and it is considered safer to interpret the 3D
Euler depth plots The 3D Euler depth results from the separation-filter run should be analysed with care as perfect
separation of the basement can never be achieved and there will always be some contamination from sources at
different levels
The results of original total magnetic intensity 3D Euler depth estimation for structural index 05 using a 16 point
window have been plotted at 1500 000 scale (not included in this publication but available in Cowan (1995) from the
GSWA Library as S10331) and as reduced A4 colour circle plots (Figure 44)
The results of deep-basement 3D Euler depth estimation for structural index 05 using a 16 point window have
been plotted as a colour image at 1500 000 scale and as an A4 image (not included in this publication)
2D analysis
Two equispaced profiles were interpolated with a 50 m station interval from the AGSO-located data profiles for the
BULLEN 1250 000 sheet The interpolated profiles were analysed using 2D Euler deconvolution and Werner
deconvolution Results are included in Cowan (1995) and show the use of these methods for more detailed analysis
Filtered data
In order to reconcile 3D Euler results from shallow basement and intrasedimentary magnetic sources we produced
several separation-filtered maps and images We found the shallow-layer double-separation filter (Figure 45) to be
very effective for shallow sources and the deep-layer standard-separation filter (Figure 46) for the basement layer
Gravity and magnetic data correlation
Both lsquoreduced to the polersquo (RTP) magnetics (Figure 47) and pseudo-gravity data (Figure 48) were produced as part of
the reconciliation of gravity and magnetic signatures In both cases the filtering operations assumed magnetization by
induction in the present Earths field The RTP data are fairly similar to the total magnetic intensity The pseudo-
57
gravity data are dominated by a northwest-trending strong positive anomaly and there is little correlation with the
Bouguer gravity data
The poor magneticgravity correlation is confirmed by cross-correlation of the RTP magnetics and the gravity
gradient The correlation plot in Figure 49 shows little coherent response with numerous zones of positive and
negative correlation
Figure 45 Regional aeromagnetic data shallow layer separation filter (BMRAGSO data) gridded at 400 m
Results
In the north and east of the area on the Wells Foreland Sub-basin trend (refer to Figure 1 main text) we see a range
of quite deep 3D Euler depths and several trend directions with north-northwesterly dominant There are relatively few
shallow intrasedimentary solutions in this zone
The second area of deep 3D Euler solutions lies over the Blake depocentre (Figure 43) with several trend
directions
Elsewhere the 3D Euler results are dominated by shallow intrasedimentary depth solutions reflecting mainly the
dolerite sills dykes and the ring complex However where we do see basement-related solutions in the south and
west of the area they appear to be shallower than those noted for the Wells Foreland Sub-basin and the Blake
depocentre
58
Figure 46 Regional aeromagnetic data deep-layer separation filter (BMRAGSO data) gridded at 400 m
Figure 48 Regional aeromagnetic data pseudo-gravity transform (BMRAGSO data) gridded at 400 m
Figure 47 Regional aeromagnetic data reduced-to-pole (BMRAGSO data) gridded at 400 m
Figure 49 Regional aeromagnetic and gravity data gravitymagnetic correlation using RTP magnetics and gravity gradient (BMRAGSO data) gridded at 4 km
59
This subdivision of the area into two zones of deep solutions is consistent with interpreted depocentres
However the interference between sources at different levels and the complexity of the magnetic response of the
basement rocks precludes more refined interpretation at this stage
The area of deep 3D Euler solutions over the Blake depocentre correlates with the pronounced negative gravity
anomaly discussed in the gravity interpretation section Using a density contrast of -015 gcc the negative gravity
anomaly could indicate up to 6ndash8 km of low-density sedimentary rocks depending on assumptions about the regional
field
The area of deep 3D Euler solutions over the Wells Foreland Sub-basin has a complex gravity expression and no
clear basin structure emerges from inversion of these data As noted previously it is likely that observed gravity
anomalies reflect contrasts in basement density rather than basement topography
Separation filtering applied to the magnetic data helps to enhance the intrasedimentary magnetic signature and to
give a better impression of the basement magnetic signature even though separation of the basement response is not
perfect
Conclusions
Quantitative aeromagnetic interpretation using 3D Euler deconvolution supported by wavenumber filtering and image
processing has been successful in providing structural trend and depth information for the Savory Sub-basin
Quantitative magnetic interpretation has revealed two zones of relatively deep magnetic basement beneath the
Wells Foreland Sub-basin and the Blake depocentre
This analysis of the magnetic data supports interpreted depocentres but the complexity of the basement magnetic
signature and interference from sources at different depths precludes further refinement to a map of basement
topography
Regional gravity proved to be very useful in understanding the regional setting of the area and in providing
support for aspects of the interpretation The gravity data support the interpretation of the Blake depocentre
suggesting up to 6ndash8 km of low-density sedimentary rocks
The deep structure of the Savory Sub-basin area is obviously complex with different areas underlain by
Archaean and Proterozoic basement and with the Capricorn suture occurring in the centre of the area
60
Recommendations
The quantitative magnetic interpretation needs to be reconciled with geological models available for the area
In particular the zones tentatively identified as areas with thick sedimentary rocks the Wells Foreland Sub-
basin and the Blake depocentre need to be investigated
Cross sections should be prepared across the basin for joint magneticgravity modelling especially for the Blake
depocentre It is important to be able to explain the strong negative gravity anomaly in this area
In view of the effects of basement density contrasts on the gravity field for the northern part of the area we think
that additional gravity interpretation and acquisition of new gravity data may not be justified as they will not
contribute significantly to understanding basin evolution and structure
It is recommended that GSWA try to get access to company confidential high-resolution aeromagnetic data
rather than flying new surveys The GSWA might offer to fund flying of new infill areas as a bargaining point
References
The original text of this report by Cowan (1995) and 1500 000 scale maps are filed in the GSWA Library under
S10331
COWAN D 1995 Savory Basin quantitative magnetic interpretation Western Australia Geological Survey S-series
S10331 (unpublished)
VACQUIER V STEENLAND N C HENDERSON R G and ZIETZ I 1951 Interpretation of aeromagnetic
maps The Geological Society of America Memoir 47 151p
WILLIAMS I R 1992 Geology of the Savory Basin Western Australia Western Australia Geological Survey
Bulletin 141 115p
61
Appendix 5
Geochemistry
MKS38 250398
Saturate FractionC12+ GLC
1217
Pr18
Ph
22
31CSR WELL-13 315m Cuttings
Figure 51 Canning Stock Route Well 13 gas chromatograph of extract of auger drill sample
12
17
18
22
31
Pr Ph
LDDH 1 6623m CoreSaturate FractionC12+ GLC
MKS35 240398
Figure 52 Gas chromatograph of extract from core sample at 6623 m LDDH1
62
Table 51 Canning Stock Route Well 13 auger drill samples
GSWA sample Drill depth (m)(a) Comments
135601 150 At watertable 135602 203 (all samples consist 135603 310 of sand mud and water) 135604 315 At total depth
NOTE (a) Datum for drill depth is the top of sediment fill in the well which is 155 m below ground level (ie the total depth of 315 m is 47 m below ground level)
Table 52 Canning Stock Route Well 13 gas chromatography data for 315 m depth sediment sample
Parameter Value
Weight of rock extracted (grams) 945 Total extract (ppm) 519 n-Alkane distribution n-C12 07 n-C13 23 n-C14 26 n-C15 22 n-C16 19 n-C17 14 i-C19 23 n-C18 14 i-C20 08 n-C19 11 n-C20 16 n-C21 25 n-C22 29 n-C23 70 n-C24 42 n-C25 95 n-C26 43 n-C27 83 n-C28 38 n-C29 87 n-C30 31 n-C31 273 Alkane compositional data Pristane phytane ratio 279 Pristane n-C17 ratio 161 Phytane n-C18 ratio 059 CPI (1)(a) 284 CPI (2) 209 (C21 + C22) (C28 + C29) 043
NOTE (a) CPI= Carbon preference index
63
Table 53 LDDH1 extract liquid chromatography data for 6623 m concentration
Rock extracted Total extract (grams) (ppm)
702 313
NOTE ppm= parts per million
Table 54 LDDH1 saturate gas chromatography data of core for 6623 m alkane composition
Pristane Pristane Phytane (a) CPI (1) CPI (2) (C21+C22) Phytane n-C17 n-C18 (C28+C29)
103 026 024 103 102 325
NOTE (a)CPI = carbon preference index
Table 55 LDDH1 saturate gas chromatography data of core for 6623 m n-alkane distributions
Parameter Value
n-C12 17 n-C13 38 n-C14 55 n-C15 60 n-C16 65 n-C17 74 i-C19 19 n-C18 78 i-C20 19 n-C19 80 n-C20 79 n-C21 71 n-C22 64 n-C23 57 n-C25 43 n-C24 38 n-C27 31 n-C28 23 n-C29 19 n-C30 12 n-C31 10
64
Appendix 6
Table 61 Summary of data from Trainor waterbores (TWB) and Bullen waterbores (BWB)
Well AMG Elevation TD Status(b) Completion details Water Salinity Water level Flow rate Depth to consolidated AGD84 GL (m) (m) struck mgl(c) (m) (LHr) lithology aquifer(e) Z51(a) Interval (m) (100 mm PVC) (m) (mgl)(d)
TWB 1 473660E 453 122 comp 0ndash75 plain 63 7 300 24 2 880 12 m 7287404N 75ndash93 slotted (9 260) McFadden Fm 93ndash99 plain TWB 2 472 977E 475 23 abd nil 15 m 7285877N Skates Hills Fm dry TWB 3 473259E 475 50 abd nil 7 m 7285849N Skates Hills Fm dry TWB 4 463225 E 445 50 comp 0ndash22 plain 35 7 200 55 3 600 0 m 7286143N 22ndash34 slotted (8 140) Tertiary sand and gravel 23ndash60 plain TWB 5 463095E 445 31 comp 0ndash19 plain 13 26 000 655 3 600 Tertiary sand and gravel 7277721N 19ndash25 slotted (36 700) 25ndash31 plain TWB 6 457013E 455 50 comp 0ndash42 plain 38 920 119 600 0 m 7274352N 42ndash48 slotted (1 030) Cornelia Fm ss TWB 7 453739E 475 26 susp 0ndash2 plain 11 9 300 48 4 500 0 m 7263891N (10 500) Tertiary sand TWB 8 433893E 535 60 susp 0ndash2 plain 47 8 500 gt46 1 200 0 m 7245991N (10 900) Tertiary sand and Brassey Range Fm ss TWB 9 437219E 505 51 comp 0ndash47 plain 45 1 000 58 600 1 m 7235905N 47ndash51 slotted (990) Brassey Range Fm ss TWB 10 434927E 495 32 susp 0ndash2 plain 235 450 120 0 m 7225875N (500) Dolerite
65
BWB 1 287337E 580 122 abd Nil 1 m 7245861N Jilyili Fm dry BWB 2 288346E 545 50 comp 0ndash26 plain 15 630 3 29 000 0 m 7240423N 26ndash38 slotted (730) Tertiary sand and gravel 38ndash50 plain BWB 3 305637E 545 50 abd 19 8 800 43 7 200 0 m 7240423N (10 550) Tertiary ss BWB 4 320167E 515 445 comp 0ndash20 plain 9 980 445 24 000 0 m 7248097N 20ndash32 slotted (1 190) Tertiary ss 32ndash44 plain BWB 5 353393E 545 20 susp 0ndash2 plain 45 (970) 1 m 7238934N Basalt
NOTES (a) GPS accuracy ~ 150 m (b) Comp = completed abd = abandoned susp = suspended (c) Salinity from conductivity (d) Analysis total dissolved solids (e) Fm = Formation ss = sandstone
44
Appendix 2
Meteorological data (from Bureau of Meteorology Perth 1994)
Table 21 Wiluna rainfall (mm)
Year Jan Feb Mar Apr May Jun Jul Aug Sept Oct Nov Dec
1975 0 45 446 309 306 59 276 4 34 886 638 164 1976 16 154 12 138 53 16 34 62 12 238 0 2 1977 44 0 66 74 68 95 24 363 1 58 12 727 1978 234 522 94 16 0 96 367 24 16 353 185 45 1979 19 173 122 88 91 4 0 246 58 0 169 114 1980 148 764 68 1081 259 626 629 06 56 02 174 0 1981 123 476 192 32 196 118 44 74 14 0 28 312 1982 374 705 206 244 1079 92 02 143 368 526 368 118 1983 1 112 928 248 0 212 56 32 5 1 42 496 1984 149 7 342 84 836 0 348 132 224 04 16 172 1985 596 483 0 166 556 0 514 56 0 0 4 0 1986 0 154 35 0 0 1085 23 01 239 137 0 04 1987 1204 119 19 89 17 575 154 126 07 1 0 398 1988 46 202 164 13 388 0 202 104 0 0 224 1309 1989 207 234 26 703 278 536 57 0 01 0 144 02 1990 1035 23 281 46 126 53 94 218 44 9 42 0 1991 48 0 41 45 0 472 297 12 0 1 0 7 1992 112 96 1025 1227 323 65 04 174 0 132 48 4 1993 0 697 0 202 445 0 12 306 18 05 14 33 Mean 25 35 22 27 27 25 18 12 6 13 13 21
JAN FEB MAR APR MAY JUN JUL AUG SEP OCT NOV DEC0
10
20
30
40
Mea
n R
ain
fall
(mm
)
Month
Mean monthly rainfall in Wiluna
MKS41 140498
45
Table 22 Wiluna minimum temperature (degC)
Year Jan Feb Mar Apr May Jun Jul Aug Sept Oct Nov Dec
1975 ndash 23 203 15 94 63 71 62 103 124 169 205 1976 242 229 194 15 10 63 59 73 95 143 16 228 1977 243 25 197 148 96 95 56 86 102 ndash 188 23 1978 241 232 203 18 102 64 76 8 9 152 19 205 1979 255 226 216 167 83 6 59 79 97 145 198 223 1980 255 226 231 155 134 83 68 75 121 108 193 223 1981 245 216 19 182 119 6 54 78 138 159 163 218 1982 232 224 177 16 ndash ndash 37 111 112 164 209 225 1983 235 24 197 147 112 88 39 88 121 162 189 219 1984 241 243 191 156 ndash 72 66 7 95 161 182 211 1985 244 231 ndash 159 98 65 71 73 117 147 205 ndash 1986 ndash 229 226 155 93 96 43 49 10 122 ndash 219 1987 ndash 217 183 175 85 77 68 68 112 ndash ndash 221 1988 238 214 209 178 111 ndash ndash 86 104 157 171 195 1989 ndash 237 199 165 107 67 44 61 107 131 187 ndash 1990 232 ndash 211 155 118 62 57 87 102 149 195 22 1991 26 256 217 168 122 101 78 ndash 113 18 168 219 1992 227 227 214 169 102 98 59 69 ndash 125 159 196 1993 241 218 196 171 103 ndash 49 68 88 128 192 211 Mean 24 23 20 16 10 8 6 8 11 14 18 21
NOTE Dashes indicate data unavailable
JAN FEB MAR APR MAY JUN JUL AUG SEP OCT NOV DEC0
10
20
30
40
Month
MKS43 140498
50
Mean monthly minimum temperatures at Wiluna
Mea
n T
emp
erat
ure
(degC
)
46
Table 23 Wiluna maximum temperature (degC)
Year Jan Feb Mar Apr May Jun Jul Aug Sept Oct Nov Dec
1975 ndash 349 326 281 247 201 197 212 256 248 31 344 1976 374 369 346 297 248 206 208 225 265 287 313 388 1977 397 392 352 296 234 212 222 244 ndash 308 337 383 1978 378 345 346 316 242 195 176 205 231 295 334 356 1979 403 36 364 295 ndash ndash ndash 193 242 318 359 373 1980 392 342 377 275 24 176 179 233 292 288 349 391 1981 385 346 337 342 242 178 201 224 30 326 326 369 1982 372 359 315 307 ndash ndash 196 253 252 305 353 379 1983 381 389 327 272 263 222 187 248 287 321 336 366 1984 378 393 322 299 226 215 178 214 234 ndash 336 364 1985 40 366 ndash 294 224 216 205 212 284 307 355 ndash 1986 ndash 383 372 307 ndash 193 166 196 261 277 ndash 382 1987 ndash 339 328 305 21 202 214 218 275 ndash ndash 374 1988 388 365 353 301 23 ndash ndash 228 283 334 31 33 1989 ndash 375 339 285 238 179 181 219 275 298 336 ndash 1990 368 ndash 36 309 268 19 188 205 274 309 373 393 1991 414 416 363 315 268 206 21 ndash 279 338 332 368 1992 363 383 336 263 213 178 213 197 ndash 285 313 359 1993 396 357 344 301 221 ndash 197 215 253 294 347 362 Mean 39 37 34 30 24 20 20 22 27 30 34 37 NOTE Dashes indicate data unavailable
JAN FEB MAR APR MAY JUN JUL AUG SEP OCT NOV DEC0
10
20
30
40
Month
MKS42 140498
50
Mean monthly maximum temperatures at Wiluna
Mea
n T
emp
erat
ure
(degC
)
47
Appendix 3
Table 31 Summary of palynological results
Drillhole Depth (m) F no(a) GSWA no Lithology Formation Assemblage TAI(b)
BWB 1 74ndash75 F49668 135741 dark-grey siltstone basalt Jilyilli gt5 BWB 1 98ndash100 F49669 135742 dark-grey siltstone basalt Jilyilli gt5 BWB 1 121ndash122 F49670 135743 dark-grey siltstone basalt Jilyilli gt5 TWB 1 86ndash87 F49671 135631 dark-grey siltstone McFadden 3+ TWB 1 104ndash105 F49672 135632 dark-grey siltstone Cornelia 3+ TWB 1 121ndash122 F49673 135633 dark-grey siltstone Cornelia 4 TWB 2 14ndash15 F49674 135634 dark-grey siltstone Skates Hills 3+ TWB 6 49ndash50 F49675 135675 dark-grey siltstone Cornelia 1 3+ TWB 9 49ndash51 F49676 135704 dark-grey siltstone Brassey Range 1 3+ Trainor 1 37497- F49733 138939 black mudstone with Cornelia 5 37509 light-grey siltstone Trainor 1 3809 F49734 138940 dark-grey and black Cornelia 4- laminated mudstone Trainor 1 4170 F49735 138941 black unlaminated mudstone Cornelia 4- Trainor 1 4950 F49851 139501 dark-grey indurated siltstone Cornelia 5 Trainor 1 6032 F49852 139502 dark- and light-grey Cornelia 5 indurated siltstone Trainor 1 6434 F49853 139503 greenish indurated finely Cornelia 5 laminated siltstone LDDH 1 270 F49678 138934 dark-grey siltstone interbeds Waters 1 3+ in enterolithic evaporite Tarcunyah Gp LDDH 1 277 F49679 138935 dark-grey siltstone in cavity Waters 1 3+ in enterolithic evaporite Tarcunyah Gp
NOTES (a) GSWA Fossil Catalogue number (b) TAI = Thermal Alteration Index of Traverse (1988 plate 1)
48
Appendix 4
Savory Sub-basin quantitative magnetic and gravity interpretation (extracted from Cowan 1995)
Summary
A program of quantitative aeromagnetic interpretation has been completed on BMRAGSO data from the Savory Sub-
basin Western Australia Quantitative aeromagnetic interpretation utilized the 3D Euler deconvolution method
supported by wavenumber filtering and image processing The results have provided useful information on structural
trends and depth to magnetic sources in a structurally complex area Depth to magnetic source analysis has provided
information on intra-sedimentary magnetic sources as well as basement rocks
The results of the interpretation support previously identified depocentres However the presence of magnetic
sources at several levels makes it very difficult to produce a reliable magnetic basement depth contour map It is
considered more productive to work with the 3D Euler colour circle plots and images rather than trying to contour the
results It would be necessary to carry out a full-scale interpretation of the BMRAGSO profile data to improve on the
3D Euler results The regional gravity was found to be useful in interpreting the regional setting of the area although
the very wide data spacing limits quantitative use of the data The gravity data show quite a complex picture with
limited consistent correlation between gravity features and basin structures This suggests that gravity anomalies
reflect changes in density of the basement rocks rather than basement topography especially in the northern part of the
basin
It is recommended that the GSWA investigate access to company confidential high-resolution aeromagnetic data
prior to planning further aeromagnetic surveys Private companies have flown large parts of the northern half of the
area as part of their diamond exploration program Additional gravity coverage of the area may be more cost effective
than magnetic surveys as the gravity data provides more information on changes within the sedimentary section
Introduction
The main use of aeromagnetic data in petroleum exploration has been the determination of magnetic basement
topography although there has been increasing interest in analysis of intra-sedimentary magnetic anomalies
intrabasement and suprabasement magnetic anomalies These anomalies are used to determine depth to magnetic
basement rocks and hence determine the thickness of the sedimentary sequence Unfortunately interpretation of the
intrabasement and suprabasement magnetic anomalies is non-unique in terms of position and size of causative sources
because of the inherent ambiguity of potential-field methods However this ambiguity can be reduced by placing
49
constraints on source geometry and magnetization and by using geological and other geophysical data to constrain
the solution
Before 1970 most depth-determination techniques involved graphical determination of slopes of selected
magnetic anomalies and application of various empirical factors to convert the slopes into depth estimates Geological
Society of America Memoir 47 Interpretation of Aeromagnetic Maps by Vacquier et al (1951) was a landmark for
this type of interpretation
Automated interpretation procedures have played an increasingly important role in depth interpretation and a
wide range of techniques have been developed Many of these techniques are designed for application to located data
profiles and assume a two-dimensional geometry However there has been renewed interest in techniques applicable
to gridded data
Two distinct types of method can be recognized In the first case often described as discrete methods individual
isolated magnetic anomalies are interpreted and the results used to produce a map of basement relief In the second
case often described as continuous methods areas of data containing a number of anomalies are interpreted
statistically to produce direct output of basement depths
The discrete methods usually involve a semiautomatic initial phase which generates a large number of possible
depth solutions and an interactive second phase to screen and select acceptable solutions The advantage of this
approach is that the interpreter can select features that are relatively free from interference from adjacent anomalies
and consider all aspects of a particular magnetic anomaly The disadvantage is that interpretation can be very time
consuming as a wide range of depths are usually possible depending on the initial model chosen and a significant
amount of effort is needed to select the correct model In the case of the Savory Sub-basin dataset we encountered
problems in separating basement related effects from the effects of shallower intrasedimentary magnetic sources
Because of these problems we have concentrated on displaying the Euler results accompanied by separation filter
images of the data to show the shallower effects and deeper effects rather than trying to refine a 3D Euler
deconvolution depth-to-crystalline-basement contour
The continuous methods are very direct provided that the rather restrictive assumption can be made that all
anomalies are due to lateral magnetization changes due to basement topography This means that shallow effects and
large intrabasement anomalies must be removed from the data This involves judgement and skill as it is necessary to
distinguish between the lower amplitude suprabasement anomalies due to basement topography and the larger
intrabasement anomalies reflecting magnetization changes within the basement These methods were not considered
suitable for the Savory Sub-basin magnetic dataset but were used to invert the gravity data
50
Limitations of magnetic and gravity interpretation
Interpretation of the area is limited by a shortage of information on the nature and physical properties of the deeper
sedimentary sequence and the underlying basement rocks However using techniques such as cross-correlation of
gravity and pseudo-gravity data it is possible to try to differentiate between anomalies relating to basement and those
related to the sedimentary sequence
Gravity anomalies reflect changes within the sedimentary sequence as well as basement condition These
changes in density of sedimentary rocks produce gravity anomalies without a corresponding magnetic anomaly hence
the complementary nature of gravity and magnetic surveys The main use of magnetics is to determine depth to
magnetic basement and any intra-sedimentary volcanic rocks or intrusives whereas gravity provides much more
general information on the sedimentary sequence
Unfortunately interpretation of gravity anomalies is complicated since they can be due to a number of geological
features including
bull major basement faults
bull basement highs
bull igneous intrusions within the basement
bull sedimentary basins which may or may not be isostatically compensated
bull intra-sedimentary volcanics and associated plutonic centres
Two major problems affect the interpretation of both magnetic and gravity data
1 The inherent ambiguity of potential-field data There is no unique solution to any measured gravity or magnetic
anomaly and theoretically there will be an infinite number of source geometry and magnetizationdensity
combinations which will fit the observed data This means that any a priori information which helps to select a
suitable model is very useful
2 Measured anomalies are the summation of effects from different depths For example an observed gravity profile
may contain contributions from shallow sources (density variations within the sedimentary basin) intermediate
depth sources (density variations due to large igneous intrusions within the basement) and deep sources (crustal
thinning producing a mantle anomaly) Separation of these component responses is the regionalresidual problem
which we solve using spectral analysis and differential upward continuation-based separation filtering
Regional setting and interpretation overview
The area studied includes parts of BALFOUR DOWNS (SF51-9) RUDALL (SF51-10) ROBERTSON (SF51-13) GUNANYA
(SF51-14) COLLIER (SG50-4) BULLEN (SG51-1) TRAINOR (SG51-2) MADLEY (SG51-3) NABBERU (SG50-5)
STANLEY (SG51-6) and HERBERT (SG51-7) 1250 000 sheets Broadly the area lies between latitudes 22deg00rsquondash25deg30rsquoS
and longitudes 119deg30rsquondash123deg30rsquoE
51
Regional gravity
The AGSO regional gravity data (at nominal 11 km spacing) was gridded at a 4 km mesh spacing using a minimum-
curvature algorithm Bouguer gravity values in the area are negative reflecting mass deficiency at depth and range
from -84 mgals to -25 mgals
A Bouguer gravity colour image is shown as Figure 41 A residual grid was produced by removing a fifth-order
orthogonal polynomial from the Bouguer data but did not add to the interpretation
120deg 121deg 122deg 123deg
23deg
24deg
25deg
-25
-84
50 km
MKS46 180598
mgal
Figure 41 Regional Bouguer gravity (BMRAGSO data) gridded at 4 km
52
The data show a complex pattern of positive and negative anomalies with no clearly defined trends Correlations
with aeromagnetic data and known basin structures are poor A vague north-northwest linear trend appears to coincide
with the Marloo Fault (Figure 42) A prominent negative anomaly appears to coincide with the Blake Fold and Fault
Belt depocentre and continues as a narrower negative anomaly to the east until it widens out again near the edge of the
basin Elsewhere the gravity data show little correlation with known basin structures and it is likely that especially in
the north of the area gravity anomalies are due to density changes in the basement rather than changes in basement
topography
Production of wavelength-filtered residual gravity plots and vertical gradient plots showed very patchy aliased
data reflecting poor sampling in much of the area
Regional magnetics
The AGSO regional aeromagnetic data were gridded at a 400 m mesh spacing using a minimum-curvature algorithm
(Figure 43) Most of the data has a line spacing of 1600 m with small areas of 1 km spacing The quality of the data is
acceptable for regional interpretation but is not adequate for detailed analysis The accuracy of the flight path is rather
variable reflecting the vintage of the data and the noise envelope of the data is poor by modern standards Problems
were also encountered in joining different map sheets
The magnetic anomaly pattern over the south and west part of the area shows a strong high frequency signature
reflecting the presence of widespread basic sills and dykes Some of the major north-northeasterly trending dykes can
be traced over considerable distances
Discontinuous high-frequency anomalies extend as a northwest-trending zone through the centre of the area and
this zone includes a conspicuous circular magnetic anomaly which is probably a ring complex
The northern and eastern parts of the area are characterized by long-wavelength deep-seated basement magnetic
anomalies with 120deg and 150deg trends dominant The Marloo and Perentie Faults (Figure 42) appear as distinct linear
zones and offsets A prominent easterly trending negative anomaly in the northwest of the area appears to swing round
to the southeast and may separate different basement blocks One possible interpretation is that this very deep seated
anomaly separates areas of Archaean and Proterozoic basement
Regional geology
The regional geology is described in Williams (1992) The GSWA provided a digitized version of Plate 2 from this
Bulletin the structural interpretation map to use as an overlay (Figure 42)
53
Pp
Pp
PSd
PSd
PSd
PSd
PSd
PSo
PSt
PSt
PSf
PSf
PSf
PSb
PSb
PSb
PSsPSs
PSs
PSb
PSm
PSp
PSc
PSc
PSw
PSw
PSw
PSg
PSr
PSj
PSg
PM
Pk
PY
PY
PSd
L
L
L
L
L
L
L
LL
L
L
L
LL
L
LL
L L
LL
L L
L
L
L
L
L
L
L
LL
L
L
BLAKEDEPOCENTRE
MA
RLO
O
FAU
LT
PERENTIEFAULT
50 km
MKS39120598
120deg 121deg 122deg 123deg
25deg
24deg
23deg
Approximate boundaryof aeromagnetic interpretation
PML
PSgL
PSjL
PML
PSpL
PML
PML
PSfL
PSfL
PSpL
LPc
LPcLPcPSrL
LPA
Durba Sandstone
Woora Woora Formation
McFadden Formation
Tchukardine Formation
Boondawari Formation
Skates Hills Formation
Mundadjini Formation
Coondra Formation
Spearhole Formation
Watch Point Formation
Jilyili Formation
Brassey Range Formation
Glass Spring Formation
Paterson Formation
Yeneena Group
Karara Formation
Cornelia Formation
Kahrban Subgroup
Bangemall Group
Fault
Formation boundary
PSdL
PSoL
PSfL
PStL
PSbL
PSsL
PSmL
PScL
PSpL
PSwL
PSjL
PSrL
PSgL
Pp
PYL
PkL
LPc
LPA
PML
Savory Group Other Units
PYL
Figure 42 Regional geology and structure map (after Williams 1992)
54
120deg 121deg 122deg 123deg
23deg
24deg
25deg
5820
3750
MKS47 180598
nT
50 km
Figure 43 Regional aeromagnetic data total magnetic intensity (BMRAGSO data) gridded at 400 m
Analysis
3D analysis
3D Euler deconvolution was used as the primary depth-determination method The advantage of this approach is that
consistent solutions can be obtained over the entire area with minimal assumptions about source geometries Euler
deconvolution of gridded data is used for positional information and estimation of depth to top of source Euler
55
deconvolution yields a large number of depth solutions which have to be screened to reject spurious solutions Results
are plotted as circles in eight depth ranges with radius proportional to depth and colour coded
The 400 m total magnetic intensity grid was used for the analysis Horizontal gradients in x and y and the vertical
gradient were calculated 3D Euler deconvolution was tested on the 400 m gridded data using windows of 9 times 9 and
11 times 11 and 16 times 16 data points and structural indices 05 (fault) and 10 (sill or dyke) It was concluded that the
16 times 16 window produced the best results overall and final plots were produced for the 16 times 16 window and structural
index 05 (Fig 44) Results were very good over the northern and central parts of the area showing magnetic sources
Figure 44 Depth to magnetic source 3D Euler deconvolution 16 times 16 window of 400 m gridded data structural index 05
56
at several different levels Unfortunately in the extreme south of the area shallow intrasedimentary magnetic sources
(sills and dykes) dominated the inversion and the results contained few basement solutions
In order to reduce these problems the 400 m gridded data were filtered using a separation filter based on
interpretation of the log-energy spectrum The 3D Euler method was run on the filtered data in order to generate more
basement-depth solutions Results for the deep-separation filter data were gridded and presented as a colour image in
Cowan (1995) Attempts to grid the Euler output were unsatisfactory and it is considered safer to interpret the 3D
Euler depth plots The 3D Euler depth results from the separation-filter run should be analysed with care as perfect
separation of the basement can never be achieved and there will always be some contamination from sources at
different levels
The results of original total magnetic intensity 3D Euler depth estimation for structural index 05 using a 16 point
window have been plotted at 1500 000 scale (not included in this publication but available in Cowan (1995) from the
GSWA Library as S10331) and as reduced A4 colour circle plots (Figure 44)
The results of deep-basement 3D Euler depth estimation for structural index 05 using a 16 point window have
been plotted as a colour image at 1500 000 scale and as an A4 image (not included in this publication)
2D analysis
Two equispaced profiles were interpolated with a 50 m station interval from the AGSO-located data profiles for the
BULLEN 1250 000 sheet The interpolated profiles were analysed using 2D Euler deconvolution and Werner
deconvolution Results are included in Cowan (1995) and show the use of these methods for more detailed analysis
Filtered data
In order to reconcile 3D Euler results from shallow basement and intrasedimentary magnetic sources we produced
several separation-filtered maps and images We found the shallow-layer double-separation filter (Figure 45) to be
very effective for shallow sources and the deep-layer standard-separation filter (Figure 46) for the basement layer
Gravity and magnetic data correlation
Both lsquoreduced to the polersquo (RTP) magnetics (Figure 47) and pseudo-gravity data (Figure 48) were produced as part of
the reconciliation of gravity and magnetic signatures In both cases the filtering operations assumed magnetization by
induction in the present Earths field The RTP data are fairly similar to the total magnetic intensity The pseudo-
57
gravity data are dominated by a northwest-trending strong positive anomaly and there is little correlation with the
Bouguer gravity data
The poor magneticgravity correlation is confirmed by cross-correlation of the RTP magnetics and the gravity
gradient The correlation plot in Figure 49 shows little coherent response with numerous zones of positive and
negative correlation
Figure 45 Regional aeromagnetic data shallow layer separation filter (BMRAGSO data) gridded at 400 m
Results
In the north and east of the area on the Wells Foreland Sub-basin trend (refer to Figure 1 main text) we see a range
of quite deep 3D Euler depths and several trend directions with north-northwesterly dominant There are relatively few
shallow intrasedimentary solutions in this zone
The second area of deep 3D Euler solutions lies over the Blake depocentre (Figure 43) with several trend
directions
Elsewhere the 3D Euler results are dominated by shallow intrasedimentary depth solutions reflecting mainly the
dolerite sills dykes and the ring complex However where we do see basement-related solutions in the south and
west of the area they appear to be shallower than those noted for the Wells Foreland Sub-basin and the Blake
depocentre
58
Figure 46 Regional aeromagnetic data deep-layer separation filter (BMRAGSO data) gridded at 400 m
Figure 48 Regional aeromagnetic data pseudo-gravity transform (BMRAGSO data) gridded at 400 m
Figure 47 Regional aeromagnetic data reduced-to-pole (BMRAGSO data) gridded at 400 m
Figure 49 Regional aeromagnetic and gravity data gravitymagnetic correlation using RTP magnetics and gravity gradient (BMRAGSO data) gridded at 4 km
59
This subdivision of the area into two zones of deep solutions is consistent with interpreted depocentres
However the interference between sources at different levels and the complexity of the magnetic response of the
basement rocks precludes more refined interpretation at this stage
The area of deep 3D Euler solutions over the Blake depocentre correlates with the pronounced negative gravity
anomaly discussed in the gravity interpretation section Using a density contrast of -015 gcc the negative gravity
anomaly could indicate up to 6ndash8 km of low-density sedimentary rocks depending on assumptions about the regional
field
The area of deep 3D Euler solutions over the Wells Foreland Sub-basin has a complex gravity expression and no
clear basin structure emerges from inversion of these data As noted previously it is likely that observed gravity
anomalies reflect contrasts in basement density rather than basement topography
Separation filtering applied to the magnetic data helps to enhance the intrasedimentary magnetic signature and to
give a better impression of the basement magnetic signature even though separation of the basement response is not
perfect
Conclusions
Quantitative aeromagnetic interpretation using 3D Euler deconvolution supported by wavenumber filtering and image
processing has been successful in providing structural trend and depth information for the Savory Sub-basin
Quantitative magnetic interpretation has revealed two zones of relatively deep magnetic basement beneath the
Wells Foreland Sub-basin and the Blake depocentre
This analysis of the magnetic data supports interpreted depocentres but the complexity of the basement magnetic
signature and interference from sources at different depths precludes further refinement to a map of basement
topography
Regional gravity proved to be very useful in understanding the regional setting of the area and in providing
support for aspects of the interpretation The gravity data support the interpretation of the Blake depocentre
suggesting up to 6ndash8 km of low-density sedimentary rocks
The deep structure of the Savory Sub-basin area is obviously complex with different areas underlain by
Archaean and Proterozoic basement and with the Capricorn suture occurring in the centre of the area
60
Recommendations
The quantitative magnetic interpretation needs to be reconciled with geological models available for the area
In particular the zones tentatively identified as areas with thick sedimentary rocks the Wells Foreland Sub-
basin and the Blake depocentre need to be investigated
Cross sections should be prepared across the basin for joint magneticgravity modelling especially for the Blake
depocentre It is important to be able to explain the strong negative gravity anomaly in this area
In view of the effects of basement density contrasts on the gravity field for the northern part of the area we think
that additional gravity interpretation and acquisition of new gravity data may not be justified as they will not
contribute significantly to understanding basin evolution and structure
It is recommended that GSWA try to get access to company confidential high-resolution aeromagnetic data
rather than flying new surveys The GSWA might offer to fund flying of new infill areas as a bargaining point
References
The original text of this report by Cowan (1995) and 1500 000 scale maps are filed in the GSWA Library under
S10331
COWAN D 1995 Savory Basin quantitative magnetic interpretation Western Australia Geological Survey S-series
S10331 (unpublished)
VACQUIER V STEENLAND N C HENDERSON R G and ZIETZ I 1951 Interpretation of aeromagnetic
maps The Geological Society of America Memoir 47 151p
WILLIAMS I R 1992 Geology of the Savory Basin Western Australia Western Australia Geological Survey
Bulletin 141 115p
61
Appendix 5
Geochemistry
MKS38 250398
Saturate FractionC12+ GLC
1217
Pr18
Ph
22
31CSR WELL-13 315m Cuttings
Figure 51 Canning Stock Route Well 13 gas chromatograph of extract of auger drill sample
12
17
18
22
31
Pr Ph
LDDH 1 6623m CoreSaturate FractionC12+ GLC
MKS35 240398
Figure 52 Gas chromatograph of extract from core sample at 6623 m LDDH1
62
Table 51 Canning Stock Route Well 13 auger drill samples
GSWA sample Drill depth (m)(a) Comments
135601 150 At watertable 135602 203 (all samples consist 135603 310 of sand mud and water) 135604 315 At total depth
NOTE (a) Datum for drill depth is the top of sediment fill in the well which is 155 m below ground level (ie the total depth of 315 m is 47 m below ground level)
Table 52 Canning Stock Route Well 13 gas chromatography data for 315 m depth sediment sample
Parameter Value
Weight of rock extracted (grams) 945 Total extract (ppm) 519 n-Alkane distribution n-C12 07 n-C13 23 n-C14 26 n-C15 22 n-C16 19 n-C17 14 i-C19 23 n-C18 14 i-C20 08 n-C19 11 n-C20 16 n-C21 25 n-C22 29 n-C23 70 n-C24 42 n-C25 95 n-C26 43 n-C27 83 n-C28 38 n-C29 87 n-C30 31 n-C31 273 Alkane compositional data Pristane phytane ratio 279 Pristane n-C17 ratio 161 Phytane n-C18 ratio 059 CPI (1)(a) 284 CPI (2) 209 (C21 + C22) (C28 + C29) 043
NOTE (a) CPI= Carbon preference index
63
Table 53 LDDH1 extract liquid chromatography data for 6623 m concentration
Rock extracted Total extract (grams) (ppm)
702 313
NOTE ppm= parts per million
Table 54 LDDH1 saturate gas chromatography data of core for 6623 m alkane composition
Pristane Pristane Phytane (a) CPI (1) CPI (2) (C21+C22) Phytane n-C17 n-C18 (C28+C29)
103 026 024 103 102 325
NOTE (a)CPI = carbon preference index
Table 55 LDDH1 saturate gas chromatography data of core for 6623 m n-alkane distributions
Parameter Value
n-C12 17 n-C13 38 n-C14 55 n-C15 60 n-C16 65 n-C17 74 i-C19 19 n-C18 78 i-C20 19 n-C19 80 n-C20 79 n-C21 71 n-C22 64 n-C23 57 n-C25 43 n-C24 38 n-C27 31 n-C28 23 n-C29 19 n-C30 12 n-C31 10
64
Appendix 6
Table 61 Summary of data from Trainor waterbores (TWB) and Bullen waterbores (BWB)
Well AMG Elevation TD Status(b) Completion details Water Salinity Water level Flow rate Depth to consolidated AGD84 GL (m) (m) struck mgl(c) (m) (LHr) lithology aquifer(e) Z51(a) Interval (m) (100 mm PVC) (m) (mgl)(d)
TWB 1 473660E 453 122 comp 0ndash75 plain 63 7 300 24 2 880 12 m 7287404N 75ndash93 slotted (9 260) McFadden Fm 93ndash99 plain TWB 2 472 977E 475 23 abd nil 15 m 7285877N Skates Hills Fm dry TWB 3 473259E 475 50 abd nil 7 m 7285849N Skates Hills Fm dry TWB 4 463225 E 445 50 comp 0ndash22 plain 35 7 200 55 3 600 0 m 7286143N 22ndash34 slotted (8 140) Tertiary sand and gravel 23ndash60 plain TWB 5 463095E 445 31 comp 0ndash19 plain 13 26 000 655 3 600 Tertiary sand and gravel 7277721N 19ndash25 slotted (36 700) 25ndash31 plain TWB 6 457013E 455 50 comp 0ndash42 plain 38 920 119 600 0 m 7274352N 42ndash48 slotted (1 030) Cornelia Fm ss TWB 7 453739E 475 26 susp 0ndash2 plain 11 9 300 48 4 500 0 m 7263891N (10 500) Tertiary sand TWB 8 433893E 535 60 susp 0ndash2 plain 47 8 500 gt46 1 200 0 m 7245991N (10 900) Tertiary sand and Brassey Range Fm ss TWB 9 437219E 505 51 comp 0ndash47 plain 45 1 000 58 600 1 m 7235905N 47ndash51 slotted (990) Brassey Range Fm ss TWB 10 434927E 495 32 susp 0ndash2 plain 235 450 120 0 m 7225875N (500) Dolerite
65
BWB 1 287337E 580 122 abd Nil 1 m 7245861N Jilyili Fm dry BWB 2 288346E 545 50 comp 0ndash26 plain 15 630 3 29 000 0 m 7240423N 26ndash38 slotted (730) Tertiary sand and gravel 38ndash50 plain BWB 3 305637E 545 50 abd 19 8 800 43 7 200 0 m 7240423N (10 550) Tertiary ss BWB 4 320167E 515 445 comp 0ndash20 plain 9 980 445 24 000 0 m 7248097N 20ndash32 slotted (1 190) Tertiary ss 32ndash44 plain BWB 5 353393E 545 20 susp 0ndash2 plain 45 (970) 1 m 7238934N Basalt
NOTES (a) GPS accuracy ~ 150 m (b) Comp = completed abd = abandoned susp = suspended (c) Salinity from conductivity (d) Analysis total dissolved solids (e) Fm = Formation ss = sandstone
45
Table 22 Wiluna minimum temperature (degC)
Year Jan Feb Mar Apr May Jun Jul Aug Sept Oct Nov Dec
1975 ndash 23 203 15 94 63 71 62 103 124 169 205 1976 242 229 194 15 10 63 59 73 95 143 16 228 1977 243 25 197 148 96 95 56 86 102 ndash 188 23 1978 241 232 203 18 102 64 76 8 9 152 19 205 1979 255 226 216 167 83 6 59 79 97 145 198 223 1980 255 226 231 155 134 83 68 75 121 108 193 223 1981 245 216 19 182 119 6 54 78 138 159 163 218 1982 232 224 177 16 ndash ndash 37 111 112 164 209 225 1983 235 24 197 147 112 88 39 88 121 162 189 219 1984 241 243 191 156 ndash 72 66 7 95 161 182 211 1985 244 231 ndash 159 98 65 71 73 117 147 205 ndash 1986 ndash 229 226 155 93 96 43 49 10 122 ndash 219 1987 ndash 217 183 175 85 77 68 68 112 ndash ndash 221 1988 238 214 209 178 111 ndash ndash 86 104 157 171 195 1989 ndash 237 199 165 107 67 44 61 107 131 187 ndash 1990 232 ndash 211 155 118 62 57 87 102 149 195 22 1991 26 256 217 168 122 101 78 ndash 113 18 168 219 1992 227 227 214 169 102 98 59 69 ndash 125 159 196 1993 241 218 196 171 103 ndash 49 68 88 128 192 211 Mean 24 23 20 16 10 8 6 8 11 14 18 21
NOTE Dashes indicate data unavailable
JAN FEB MAR APR MAY JUN JUL AUG SEP OCT NOV DEC0
10
20
30
40
Month
MKS43 140498
50
Mean monthly minimum temperatures at Wiluna
Mea
n T
emp
erat
ure
(degC
)
46
Table 23 Wiluna maximum temperature (degC)
Year Jan Feb Mar Apr May Jun Jul Aug Sept Oct Nov Dec
1975 ndash 349 326 281 247 201 197 212 256 248 31 344 1976 374 369 346 297 248 206 208 225 265 287 313 388 1977 397 392 352 296 234 212 222 244 ndash 308 337 383 1978 378 345 346 316 242 195 176 205 231 295 334 356 1979 403 36 364 295 ndash ndash ndash 193 242 318 359 373 1980 392 342 377 275 24 176 179 233 292 288 349 391 1981 385 346 337 342 242 178 201 224 30 326 326 369 1982 372 359 315 307 ndash ndash 196 253 252 305 353 379 1983 381 389 327 272 263 222 187 248 287 321 336 366 1984 378 393 322 299 226 215 178 214 234 ndash 336 364 1985 40 366 ndash 294 224 216 205 212 284 307 355 ndash 1986 ndash 383 372 307 ndash 193 166 196 261 277 ndash 382 1987 ndash 339 328 305 21 202 214 218 275 ndash ndash 374 1988 388 365 353 301 23 ndash ndash 228 283 334 31 33 1989 ndash 375 339 285 238 179 181 219 275 298 336 ndash 1990 368 ndash 36 309 268 19 188 205 274 309 373 393 1991 414 416 363 315 268 206 21 ndash 279 338 332 368 1992 363 383 336 263 213 178 213 197 ndash 285 313 359 1993 396 357 344 301 221 ndash 197 215 253 294 347 362 Mean 39 37 34 30 24 20 20 22 27 30 34 37 NOTE Dashes indicate data unavailable
JAN FEB MAR APR MAY JUN JUL AUG SEP OCT NOV DEC0
10
20
30
40
Month
MKS42 140498
50
Mean monthly maximum temperatures at Wiluna
Mea
n T
emp
erat
ure
(degC
)
47
Appendix 3
Table 31 Summary of palynological results
Drillhole Depth (m) F no(a) GSWA no Lithology Formation Assemblage TAI(b)
BWB 1 74ndash75 F49668 135741 dark-grey siltstone basalt Jilyilli gt5 BWB 1 98ndash100 F49669 135742 dark-grey siltstone basalt Jilyilli gt5 BWB 1 121ndash122 F49670 135743 dark-grey siltstone basalt Jilyilli gt5 TWB 1 86ndash87 F49671 135631 dark-grey siltstone McFadden 3+ TWB 1 104ndash105 F49672 135632 dark-grey siltstone Cornelia 3+ TWB 1 121ndash122 F49673 135633 dark-grey siltstone Cornelia 4 TWB 2 14ndash15 F49674 135634 dark-grey siltstone Skates Hills 3+ TWB 6 49ndash50 F49675 135675 dark-grey siltstone Cornelia 1 3+ TWB 9 49ndash51 F49676 135704 dark-grey siltstone Brassey Range 1 3+ Trainor 1 37497- F49733 138939 black mudstone with Cornelia 5 37509 light-grey siltstone Trainor 1 3809 F49734 138940 dark-grey and black Cornelia 4- laminated mudstone Trainor 1 4170 F49735 138941 black unlaminated mudstone Cornelia 4- Trainor 1 4950 F49851 139501 dark-grey indurated siltstone Cornelia 5 Trainor 1 6032 F49852 139502 dark- and light-grey Cornelia 5 indurated siltstone Trainor 1 6434 F49853 139503 greenish indurated finely Cornelia 5 laminated siltstone LDDH 1 270 F49678 138934 dark-grey siltstone interbeds Waters 1 3+ in enterolithic evaporite Tarcunyah Gp LDDH 1 277 F49679 138935 dark-grey siltstone in cavity Waters 1 3+ in enterolithic evaporite Tarcunyah Gp
NOTES (a) GSWA Fossil Catalogue number (b) TAI = Thermal Alteration Index of Traverse (1988 plate 1)
48
Appendix 4
Savory Sub-basin quantitative magnetic and gravity interpretation (extracted from Cowan 1995)
Summary
A program of quantitative aeromagnetic interpretation has been completed on BMRAGSO data from the Savory Sub-
basin Western Australia Quantitative aeromagnetic interpretation utilized the 3D Euler deconvolution method
supported by wavenumber filtering and image processing The results have provided useful information on structural
trends and depth to magnetic sources in a structurally complex area Depth to magnetic source analysis has provided
information on intra-sedimentary magnetic sources as well as basement rocks
The results of the interpretation support previously identified depocentres However the presence of magnetic
sources at several levels makes it very difficult to produce a reliable magnetic basement depth contour map It is
considered more productive to work with the 3D Euler colour circle plots and images rather than trying to contour the
results It would be necessary to carry out a full-scale interpretation of the BMRAGSO profile data to improve on the
3D Euler results The regional gravity was found to be useful in interpreting the regional setting of the area although
the very wide data spacing limits quantitative use of the data The gravity data show quite a complex picture with
limited consistent correlation between gravity features and basin structures This suggests that gravity anomalies
reflect changes in density of the basement rocks rather than basement topography especially in the northern part of the
basin
It is recommended that the GSWA investigate access to company confidential high-resolution aeromagnetic data
prior to planning further aeromagnetic surveys Private companies have flown large parts of the northern half of the
area as part of their diamond exploration program Additional gravity coverage of the area may be more cost effective
than magnetic surveys as the gravity data provides more information on changes within the sedimentary section
Introduction
The main use of aeromagnetic data in petroleum exploration has been the determination of magnetic basement
topography although there has been increasing interest in analysis of intra-sedimentary magnetic anomalies
intrabasement and suprabasement magnetic anomalies These anomalies are used to determine depth to magnetic
basement rocks and hence determine the thickness of the sedimentary sequence Unfortunately interpretation of the
intrabasement and suprabasement magnetic anomalies is non-unique in terms of position and size of causative sources
because of the inherent ambiguity of potential-field methods However this ambiguity can be reduced by placing
49
constraints on source geometry and magnetization and by using geological and other geophysical data to constrain
the solution
Before 1970 most depth-determination techniques involved graphical determination of slopes of selected
magnetic anomalies and application of various empirical factors to convert the slopes into depth estimates Geological
Society of America Memoir 47 Interpretation of Aeromagnetic Maps by Vacquier et al (1951) was a landmark for
this type of interpretation
Automated interpretation procedures have played an increasingly important role in depth interpretation and a
wide range of techniques have been developed Many of these techniques are designed for application to located data
profiles and assume a two-dimensional geometry However there has been renewed interest in techniques applicable
to gridded data
Two distinct types of method can be recognized In the first case often described as discrete methods individual
isolated magnetic anomalies are interpreted and the results used to produce a map of basement relief In the second
case often described as continuous methods areas of data containing a number of anomalies are interpreted
statistically to produce direct output of basement depths
The discrete methods usually involve a semiautomatic initial phase which generates a large number of possible
depth solutions and an interactive second phase to screen and select acceptable solutions The advantage of this
approach is that the interpreter can select features that are relatively free from interference from adjacent anomalies
and consider all aspects of a particular magnetic anomaly The disadvantage is that interpretation can be very time
consuming as a wide range of depths are usually possible depending on the initial model chosen and a significant
amount of effort is needed to select the correct model In the case of the Savory Sub-basin dataset we encountered
problems in separating basement related effects from the effects of shallower intrasedimentary magnetic sources
Because of these problems we have concentrated on displaying the Euler results accompanied by separation filter
images of the data to show the shallower effects and deeper effects rather than trying to refine a 3D Euler
deconvolution depth-to-crystalline-basement contour
The continuous methods are very direct provided that the rather restrictive assumption can be made that all
anomalies are due to lateral magnetization changes due to basement topography This means that shallow effects and
large intrabasement anomalies must be removed from the data This involves judgement and skill as it is necessary to
distinguish between the lower amplitude suprabasement anomalies due to basement topography and the larger
intrabasement anomalies reflecting magnetization changes within the basement These methods were not considered
suitable for the Savory Sub-basin magnetic dataset but were used to invert the gravity data
50
Limitations of magnetic and gravity interpretation
Interpretation of the area is limited by a shortage of information on the nature and physical properties of the deeper
sedimentary sequence and the underlying basement rocks However using techniques such as cross-correlation of
gravity and pseudo-gravity data it is possible to try to differentiate between anomalies relating to basement and those
related to the sedimentary sequence
Gravity anomalies reflect changes within the sedimentary sequence as well as basement condition These
changes in density of sedimentary rocks produce gravity anomalies without a corresponding magnetic anomaly hence
the complementary nature of gravity and magnetic surveys The main use of magnetics is to determine depth to
magnetic basement and any intra-sedimentary volcanic rocks or intrusives whereas gravity provides much more
general information on the sedimentary sequence
Unfortunately interpretation of gravity anomalies is complicated since they can be due to a number of geological
features including
bull major basement faults
bull basement highs
bull igneous intrusions within the basement
bull sedimentary basins which may or may not be isostatically compensated
bull intra-sedimentary volcanics and associated plutonic centres
Two major problems affect the interpretation of both magnetic and gravity data
1 The inherent ambiguity of potential-field data There is no unique solution to any measured gravity or magnetic
anomaly and theoretically there will be an infinite number of source geometry and magnetizationdensity
combinations which will fit the observed data This means that any a priori information which helps to select a
suitable model is very useful
2 Measured anomalies are the summation of effects from different depths For example an observed gravity profile
may contain contributions from shallow sources (density variations within the sedimentary basin) intermediate
depth sources (density variations due to large igneous intrusions within the basement) and deep sources (crustal
thinning producing a mantle anomaly) Separation of these component responses is the regionalresidual problem
which we solve using spectral analysis and differential upward continuation-based separation filtering
Regional setting and interpretation overview
The area studied includes parts of BALFOUR DOWNS (SF51-9) RUDALL (SF51-10) ROBERTSON (SF51-13) GUNANYA
(SF51-14) COLLIER (SG50-4) BULLEN (SG51-1) TRAINOR (SG51-2) MADLEY (SG51-3) NABBERU (SG50-5)
STANLEY (SG51-6) and HERBERT (SG51-7) 1250 000 sheets Broadly the area lies between latitudes 22deg00rsquondash25deg30rsquoS
and longitudes 119deg30rsquondash123deg30rsquoE
51
Regional gravity
The AGSO regional gravity data (at nominal 11 km spacing) was gridded at a 4 km mesh spacing using a minimum-
curvature algorithm Bouguer gravity values in the area are negative reflecting mass deficiency at depth and range
from -84 mgals to -25 mgals
A Bouguer gravity colour image is shown as Figure 41 A residual grid was produced by removing a fifth-order
orthogonal polynomial from the Bouguer data but did not add to the interpretation
120deg 121deg 122deg 123deg
23deg
24deg
25deg
-25
-84
50 km
MKS46 180598
mgal
Figure 41 Regional Bouguer gravity (BMRAGSO data) gridded at 4 km
52
The data show a complex pattern of positive and negative anomalies with no clearly defined trends Correlations
with aeromagnetic data and known basin structures are poor A vague north-northwest linear trend appears to coincide
with the Marloo Fault (Figure 42) A prominent negative anomaly appears to coincide with the Blake Fold and Fault
Belt depocentre and continues as a narrower negative anomaly to the east until it widens out again near the edge of the
basin Elsewhere the gravity data show little correlation with known basin structures and it is likely that especially in
the north of the area gravity anomalies are due to density changes in the basement rather than changes in basement
topography
Production of wavelength-filtered residual gravity plots and vertical gradient plots showed very patchy aliased
data reflecting poor sampling in much of the area
Regional magnetics
The AGSO regional aeromagnetic data were gridded at a 400 m mesh spacing using a minimum-curvature algorithm
(Figure 43) Most of the data has a line spacing of 1600 m with small areas of 1 km spacing The quality of the data is
acceptable for regional interpretation but is not adequate for detailed analysis The accuracy of the flight path is rather
variable reflecting the vintage of the data and the noise envelope of the data is poor by modern standards Problems
were also encountered in joining different map sheets
The magnetic anomaly pattern over the south and west part of the area shows a strong high frequency signature
reflecting the presence of widespread basic sills and dykes Some of the major north-northeasterly trending dykes can
be traced over considerable distances
Discontinuous high-frequency anomalies extend as a northwest-trending zone through the centre of the area and
this zone includes a conspicuous circular magnetic anomaly which is probably a ring complex
The northern and eastern parts of the area are characterized by long-wavelength deep-seated basement magnetic
anomalies with 120deg and 150deg trends dominant The Marloo and Perentie Faults (Figure 42) appear as distinct linear
zones and offsets A prominent easterly trending negative anomaly in the northwest of the area appears to swing round
to the southeast and may separate different basement blocks One possible interpretation is that this very deep seated
anomaly separates areas of Archaean and Proterozoic basement
Regional geology
The regional geology is described in Williams (1992) The GSWA provided a digitized version of Plate 2 from this
Bulletin the structural interpretation map to use as an overlay (Figure 42)
53
Pp
Pp
PSd
PSd
PSd
PSd
PSd
PSo
PSt
PSt
PSf
PSf
PSf
PSb
PSb
PSb
PSsPSs
PSs
PSb
PSm
PSp
PSc
PSc
PSw
PSw
PSw
PSg
PSr
PSj
PSg
PM
Pk
PY
PY
PSd
L
L
L
L
L
L
L
LL
L
L
L
LL
L
LL
L L
LL
L L
L
L
L
L
L
L
L
LL
L
L
BLAKEDEPOCENTRE
MA
RLO
O
FAU
LT
PERENTIEFAULT
50 km
MKS39120598
120deg 121deg 122deg 123deg
25deg
24deg
23deg
Approximate boundaryof aeromagnetic interpretation
PML
PSgL
PSjL
PML
PSpL
PML
PML
PSfL
PSfL
PSpL
LPc
LPcLPcPSrL
LPA
Durba Sandstone
Woora Woora Formation
McFadden Formation
Tchukardine Formation
Boondawari Formation
Skates Hills Formation
Mundadjini Formation
Coondra Formation
Spearhole Formation
Watch Point Formation
Jilyili Formation
Brassey Range Formation
Glass Spring Formation
Paterson Formation
Yeneena Group
Karara Formation
Cornelia Formation
Kahrban Subgroup
Bangemall Group
Fault
Formation boundary
PSdL
PSoL
PSfL
PStL
PSbL
PSsL
PSmL
PScL
PSpL
PSwL
PSjL
PSrL
PSgL
Pp
PYL
PkL
LPc
LPA
PML
Savory Group Other Units
PYL
Figure 42 Regional geology and structure map (after Williams 1992)
54
120deg 121deg 122deg 123deg
23deg
24deg
25deg
5820
3750
MKS47 180598
nT
50 km
Figure 43 Regional aeromagnetic data total magnetic intensity (BMRAGSO data) gridded at 400 m
Analysis
3D analysis
3D Euler deconvolution was used as the primary depth-determination method The advantage of this approach is that
consistent solutions can be obtained over the entire area with minimal assumptions about source geometries Euler
deconvolution of gridded data is used for positional information and estimation of depth to top of source Euler
55
deconvolution yields a large number of depth solutions which have to be screened to reject spurious solutions Results
are plotted as circles in eight depth ranges with radius proportional to depth and colour coded
The 400 m total magnetic intensity grid was used for the analysis Horizontal gradients in x and y and the vertical
gradient were calculated 3D Euler deconvolution was tested on the 400 m gridded data using windows of 9 times 9 and
11 times 11 and 16 times 16 data points and structural indices 05 (fault) and 10 (sill or dyke) It was concluded that the
16 times 16 window produced the best results overall and final plots were produced for the 16 times 16 window and structural
index 05 (Fig 44) Results were very good over the northern and central parts of the area showing magnetic sources
Figure 44 Depth to magnetic source 3D Euler deconvolution 16 times 16 window of 400 m gridded data structural index 05
56
at several different levels Unfortunately in the extreme south of the area shallow intrasedimentary magnetic sources
(sills and dykes) dominated the inversion and the results contained few basement solutions
In order to reduce these problems the 400 m gridded data were filtered using a separation filter based on
interpretation of the log-energy spectrum The 3D Euler method was run on the filtered data in order to generate more
basement-depth solutions Results for the deep-separation filter data were gridded and presented as a colour image in
Cowan (1995) Attempts to grid the Euler output were unsatisfactory and it is considered safer to interpret the 3D
Euler depth plots The 3D Euler depth results from the separation-filter run should be analysed with care as perfect
separation of the basement can never be achieved and there will always be some contamination from sources at
different levels
The results of original total magnetic intensity 3D Euler depth estimation for structural index 05 using a 16 point
window have been plotted at 1500 000 scale (not included in this publication but available in Cowan (1995) from the
GSWA Library as S10331) and as reduced A4 colour circle plots (Figure 44)
The results of deep-basement 3D Euler depth estimation for structural index 05 using a 16 point window have
been plotted as a colour image at 1500 000 scale and as an A4 image (not included in this publication)
2D analysis
Two equispaced profiles were interpolated with a 50 m station interval from the AGSO-located data profiles for the
BULLEN 1250 000 sheet The interpolated profiles were analysed using 2D Euler deconvolution and Werner
deconvolution Results are included in Cowan (1995) and show the use of these methods for more detailed analysis
Filtered data
In order to reconcile 3D Euler results from shallow basement and intrasedimentary magnetic sources we produced
several separation-filtered maps and images We found the shallow-layer double-separation filter (Figure 45) to be
very effective for shallow sources and the deep-layer standard-separation filter (Figure 46) for the basement layer
Gravity and magnetic data correlation
Both lsquoreduced to the polersquo (RTP) magnetics (Figure 47) and pseudo-gravity data (Figure 48) were produced as part of
the reconciliation of gravity and magnetic signatures In both cases the filtering operations assumed magnetization by
induction in the present Earths field The RTP data are fairly similar to the total magnetic intensity The pseudo-
57
gravity data are dominated by a northwest-trending strong positive anomaly and there is little correlation with the
Bouguer gravity data
The poor magneticgravity correlation is confirmed by cross-correlation of the RTP magnetics and the gravity
gradient The correlation plot in Figure 49 shows little coherent response with numerous zones of positive and
negative correlation
Figure 45 Regional aeromagnetic data shallow layer separation filter (BMRAGSO data) gridded at 400 m
Results
In the north and east of the area on the Wells Foreland Sub-basin trend (refer to Figure 1 main text) we see a range
of quite deep 3D Euler depths and several trend directions with north-northwesterly dominant There are relatively few
shallow intrasedimentary solutions in this zone
The second area of deep 3D Euler solutions lies over the Blake depocentre (Figure 43) with several trend
directions
Elsewhere the 3D Euler results are dominated by shallow intrasedimentary depth solutions reflecting mainly the
dolerite sills dykes and the ring complex However where we do see basement-related solutions in the south and
west of the area they appear to be shallower than those noted for the Wells Foreland Sub-basin and the Blake
depocentre
58
Figure 46 Regional aeromagnetic data deep-layer separation filter (BMRAGSO data) gridded at 400 m
Figure 48 Regional aeromagnetic data pseudo-gravity transform (BMRAGSO data) gridded at 400 m
Figure 47 Regional aeromagnetic data reduced-to-pole (BMRAGSO data) gridded at 400 m
Figure 49 Regional aeromagnetic and gravity data gravitymagnetic correlation using RTP magnetics and gravity gradient (BMRAGSO data) gridded at 4 km
59
This subdivision of the area into two zones of deep solutions is consistent with interpreted depocentres
However the interference between sources at different levels and the complexity of the magnetic response of the
basement rocks precludes more refined interpretation at this stage
The area of deep 3D Euler solutions over the Blake depocentre correlates with the pronounced negative gravity
anomaly discussed in the gravity interpretation section Using a density contrast of -015 gcc the negative gravity
anomaly could indicate up to 6ndash8 km of low-density sedimentary rocks depending on assumptions about the regional
field
The area of deep 3D Euler solutions over the Wells Foreland Sub-basin has a complex gravity expression and no
clear basin structure emerges from inversion of these data As noted previously it is likely that observed gravity
anomalies reflect contrasts in basement density rather than basement topography
Separation filtering applied to the magnetic data helps to enhance the intrasedimentary magnetic signature and to
give a better impression of the basement magnetic signature even though separation of the basement response is not
perfect
Conclusions
Quantitative aeromagnetic interpretation using 3D Euler deconvolution supported by wavenumber filtering and image
processing has been successful in providing structural trend and depth information for the Savory Sub-basin
Quantitative magnetic interpretation has revealed two zones of relatively deep magnetic basement beneath the
Wells Foreland Sub-basin and the Blake depocentre
This analysis of the magnetic data supports interpreted depocentres but the complexity of the basement magnetic
signature and interference from sources at different depths precludes further refinement to a map of basement
topography
Regional gravity proved to be very useful in understanding the regional setting of the area and in providing
support for aspects of the interpretation The gravity data support the interpretation of the Blake depocentre
suggesting up to 6ndash8 km of low-density sedimentary rocks
The deep structure of the Savory Sub-basin area is obviously complex with different areas underlain by
Archaean and Proterozoic basement and with the Capricorn suture occurring in the centre of the area
60
Recommendations
The quantitative magnetic interpretation needs to be reconciled with geological models available for the area
In particular the zones tentatively identified as areas with thick sedimentary rocks the Wells Foreland Sub-
basin and the Blake depocentre need to be investigated
Cross sections should be prepared across the basin for joint magneticgravity modelling especially for the Blake
depocentre It is important to be able to explain the strong negative gravity anomaly in this area
In view of the effects of basement density contrasts on the gravity field for the northern part of the area we think
that additional gravity interpretation and acquisition of new gravity data may not be justified as they will not
contribute significantly to understanding basin evolution and structure
It is recommended that GSWA try to get access to company confidential high-resolution aeromagnetic data
rather than flying new surveys The GSWA might offer to fund flying of new infill areas as a bargaining point
References
The original text of this report by Cowan (1995) and 1500 000 scale maps are filed in the GSWA Library under
S10331
COWAN D 1995 Savory Basin quantitative magnetic interpretation Western Australia Geological Survey S-series
S10331 (unpublished)
VACQUIER V STEENLAND N C HENDERSON R G and ZIETZ I 1951 Interpretation of aeromagnetic
maps The Geological Society of America Memoir 47 151p
WILLIAMS I R 1992 Geology of the Savory Basin Western Australia Western Australia Geological Survey
Bulletin 141 115p
61
Appendix 5
Geochemistry
MKS38 250398
Saturate FractionC12+ GLC
1217
Pr18
Ph
22
31CSR WELL-13 315m Cuttings
Figure 51 Canning Stock Route Well 13 gas chromatograph of extract of auger drill sample
12
17
18
22
31
Pr Ph
LDDH 1 6623m CoreSaturate FractionC12+ GLC
MKS35 240398
Figure 52 Gas chromatograph of extract from core sample at 6623 m LDDH1
62
Table 51 Canning Stock Route Well 13 auger drill samples
GSWA sample Drill depth (m)(a) Comments
135601 150 At watertable 135602 203 (all samples consist 135603 310 of sand mud and water) 135604 315 At total depth
NOTE (a) Datum for drill depth is the top of sediment fill in the well which is 155 m below ground level (ie the total depth of 315 m is 47 m below ground level)
Table 52 Canning Stock Route Well 13 gas chromatography data for 315 m depth sediment sample
Parameter Value
Weight of rock extracted (grams) 945 Total extract (ppm) 519 n-Alkane distribution n-C12 07 n-C13 23 n-C14 26 n-C15 22 n-C16 19 n-C17 14 i-C19 23 n-C18 14 i-C20 08 n-C19 11 n-C20 16 n-C21 25 n-C22 29 n-C23 70 n-C24 42 n-C25 95 n-C26 43 n-C27 83 n-C28 38 n-C29 87 n-C30 31 n-C31 273 Alkane compositional data Pristane phytane ratio 279 Pristane n-C17 ratio 161 Phytane n-C18 ratio 059 CPI (1)(a) 284 CPI (2) 209 (C21 + C22) (C28 + C29) 043
NOTE (a) CPI= Carbon preference index
63
Table 53 LDDH1 extract liquid chromatography data for 6623 m concentration
Rock extracted Total extract (grams) (ppm)
702 313
NOTE ppm= parts per million
Table 54 LDDH1 saturate gas chromatography data of core for 6623 m alkane composition
Pristane Pristane Phytane (a) CPI (1) CPI (2) (C21+C22) Phytane n-C17 n-C18 (C28+C29)
103 026 024 103 102 325
NOTE (a)CPI = carbon preference index
Table 55 LDDH1 saturate gas chromatography data of core for 6623 m n-alkane distributions
Parameter Value
n-C12 17 n-C13 38 n-C14 55 n-C15 60 n-C16 65 n-C17 74 i-C19 19 n-C18 78 i-C20 19 n-C19 80 n-C20 79 n-C21 71 n-C22 64 n-C23 57 n-C25 43 n-C24 38 n-C27 31 n-C28 23 n-C29 19 n-C30 12 n-C31 10
64
Appendix 6
Table 61 Summary of data from Trainor waterbores (TWB) and Bullen waterbores (BWB)
Well AMG Elevation TD Status(b) Completion details Water Salinity Water level Flow rate Depth to consolidated AGD84 GL (m) (m) struck mgl(c) (m) (LHr) lithology aquifer(e) Z51(a) Interval (m) (100 mm PVC) (m) (mgl)(d)
TWB 1 473660E 453 122 comp 0ndash75 plain 63 7 300 24 2 880 12 m 7287404N 75ndash93 slotted (9 260) McFadden Fm 93ndash99 plain TWB 2 472 977E 475 23 abd nil 15 m 7285877N Skates Hills Fm dry TWB 3 473259E 475 50 abd nil 7 m 7285849N Skates Hills Fm dry TWB 4 463225 E 445 50 comp 0ndash22 plain 35 7 200 55 3 600 0 m 7286143N 22ndash34 slotted (8 140) Tertiary sand and gravel 23ndash60 plain TWB 5 463095E 445 31 comp 0ndash19 plain 13 26 000 655 3 600 Tertiary sand and gravel 7277721N 19ndash25 slotted (36 700) 25ndash31 plain TWB 6 457013E 455 50 comp 0ndash42 plain 38 920 119 600 0 m 7274352N 42ndash48 slotted (1 030) Cornelia Fm ss TWB 7 453739E 475 26 susp 0ndash2 plain 11 9 300 48 4 500 0 m 7263891N (10 500) Tertiary sand TWB 8 433893E 535 60 susp 0ndash2 plain 47 8 500 gt46 1 200 0 m 7245991N (10 900) Tertiary sand and Brassey Range Fm ss TWB 9 437219E 505 51 comp 0ndash47 plain 45 1 000 58 600 1 m 7235905N 47ndash51 slotted (990) Brassey Range Fm ss TWB 10 434927E 495 32 susp 0ndash2 plain 235 450 120 0 m 7225875N (500) Dolerite
65
BWB 1 287337E 580 122 abd Nil 1 m 7245861N Jilyili Fm dry BWB 2 288346E 545 50 comp 0ndash26 plain 15 630 3 29 000 0 m 7240423N 26ndash38 slotted (730) Tertiary sand and gravel 38ndash50 plain BWB 3 305637E 545 50 abd 19 8 800 43 7 200 0 m 7240423N (10 550) Tertiary ss BWB 4 320167E 515 445 comp 0ndash20 plain 9 980 445 24 000 0 m 7248097N 20ndash32 slotted (1 190) Tertiary ss 32ndash44 plain BWB 5 353393E 545 20 susp 0ndash2 plain 45 (970) 1 m 7238934N Basalt
NOTES (a) GPS accuracy ~ 150 m (b) Comp = completed abd = abandoned susp = suspended (c) Salinity from conductivity (d) Analysis total dissolved solids (e) Fm = Formation ss = sandstone
46
Table 23 Wiluna maximum temperature (degC)
Year Jan Feb Mar Apr May Jun Jul Aug Sept Oct Nov Dec
1975 ndash 349 326 281 247 201 197 212 256 248 31 344 1976 374 369 346 297 248 206 208 225 265 287 313 388 1977 397 392 352 296 234 212 222 244 ndash 308 337 383 1978 378 345 346 316 242 195 176 205 231 295 334 356 1979 403 36 364 295 ndash ndash ndash 193 242 318 359 373 1980 392 342 377 275 24 176 179 233 292 288 349 391 1981 385 346 337 342 242 178 201 224 30 326 326 369 1982 372 359 315 307 ndash ndash 196 253 252 305 353 379 1983 381 389 327 272 263 222 187 248 287 321 336 366 1984 378 393 322 299 226 215 178 214 234 ndash 336 364 1985 40 366 ndash 294 224 216 205 212 284 307 355 ndash 1986 ndash 383 372 307 ndash 193 166 196 261 277 ndash 382 1987 ndash 339 328 305 21 202 214 218 275 ndash ndash 374 1988 388 365 353 301 23 ndash ndash 228 283 334 31 33 1989 ndash 375 339 285 238 179 181 219 275 298 336 ndash 1990 368 ndash 36 309 268 19 188 205 274 309 373 393 1991 414 416 363 315 268 206 21 ndash 279 338 332 368 1992 363 383 336 263 213 178 213 197 ndash 285 313 359 1993 396 357 344 301 221 ndash 197 215 253 294 347 362 Mean 39 37 34 30 24 20 20 22 27 30 34 37 NOTE Dashes indicate data unavailable
JAN FEB MAR APR MAY JUN JUL AUG SEP OCT NOV DEC0
10
20
30
40
Month
MKS42 140498
50
Mean monthly maximum temperatures at Wiluna
Mea
n T
emp
erat
ure
(degC
)
47
Appendix 3
Table 31 Summary of palynological results
Drillhole Depth (m) F no(a) GSWA no Lithology Formation Assemblage TAI(b)
BWB 1 74ndash75 F49668 135741 dark-grey siltstone basalt Jilyilli gt5 BWB 1 98ndash100 F49669 135742 dark-grey siltstone basalt Jilyilli gt5 BWB 1 121ndash122 F49670 135743 dark-grey siltstone basalt Jilyilli gt5 TWB 1 86ndash87 F49671 135631 dark-grey siltstone McFadden 3+ TWB 1 104ndash105 F49672 135632 dark-grey siltstone Cornelia 3+ TWB 1 121ndash122 F49673 135633 dark-grey siltstone Cornelia 4 TWB 2 14ndash15 F49674 135634 dark-grey siltstone Skates Hills 3+ TWB 6 49ndash50 F49675 135675 dark-grey siltstone Cornelia 1 3+ TWB 9 49ndash51 F49676 135704 dark-grey siltstone Brassey Range 1 3+ Trainor 1 37497- F49733 138939 black mudstone with Cornelia 5 37509 light-grey siltstone Trainor 1 3809 F49734 138940 dark-grey and black Cornelia 4- laminated mudstone Trainor 1 4170 F49735 138941 black unlaminated mudstone Cornelia 4- Trainor 1 4950 F49851 139501 dark-grey indurated siltstone Cornelia 5 Trainor 1 6032 F49852 139502 dark- and light-grey Cornelia 5 indurated siltstone Trainor 1 6434 F49853 139503 greenish indurated finely Cornelia 5 laminated siltstone LDDH 1 270 F49678 138934 dark-grey siltstone interbeds Waters 1 3+ in enterolithic evaporite Tarcunyah Gp LDDH 1 277 F49679 138935 dark-grey siltstone in cavity Waters 1 3+ in enterolithic evaporite Tarcunyah Gp
NOTES (a) GSWA Fossil Catalogue number (b) TAI = Thermal Alteration Index of Traverse (1988 plate 1)
48
Appendix 4
Savory Sub-basin quantitative magnetic and gravity interpretation (extracted from Cowan 1995)
Summary
A program of quantitative aeromagnetic interpretation has been completed on BMRAGSO data from the Savory Sub-
basin Western Australia Quantitative aeromagnetic interpretation utilized the 3D Euler deconvolution method
supported by wavenumber filtering and image processing The results have provided useful information on structural
trends and depth to magnetic sources in a structurally complex area Depth to magnetic source analysis has provided
information on intra-sedimentary magnetic sources as well as basement rocks
The results of the interpretation support previously identified depocentres However the presence of magnetic
sources at several levels makes it very difficult to produce a reliable magnetic basement depth contour map It is
considered more productive to work with the 3D Euler colour circle plots and images rather than trying to contour the
results It would be necessary to carry out a full-scale interpretation of the BMRAGSO profile data to improve on the
3D Euler results The regional gravity was found to be useful in interpreting the regional setting of the area although
the very wide data spacing limits quantitative use of the data The gravity data show quite a complex picture with
limited consistent correlation between gravity features and basin structures This suggests that gravity anomalies
reflect changes in density of the basement rocks rather than basement topography especially in the northern part of the
basin
It is recommended that the GSWA investigate access to company confidential high-resolution aeromagnetic data
prior to planning further aeromagnetic surveys Private companies have flown large parts of the northern half of the
area as part of their diamond exploration program Additional gravity coverage of the area may be more cost effective
than magnetic surveys as the gravity data provides more information on changes within the sedimentary section
Introduction
The main use of aeromagnetic data in petroleum exploration has been the determination of magnetic basement
topography although there has been increasing interest in analysis of intra-sedimentary magnetic anomalies
intrabasement and suprabasement magnetic anomalies These anomalies are used to determine depth to magnetic
basement rocks and hence determine the thickness of the sedimentary sequence Unfortunately interpretation of the
intrabasement and suprabasement magnetic anomalies is non-unique in terms of position and size of causative sources
because of the inherent ambiguity of potential-field methods However this ambiguity can be reduced by placing
49
constraints on source geometry and magnetization and by using geological and other geophysical data to constrain
the solution
Before 1970 most depth-determination techniques involved graphical determination of slopes of selected
magnetic anomalies and application of various empirical factors to convert the slopes into depth estimates Geological
Society of America Memoir 47 Interpretation of Aeromagnetic Maps by Vacquier et al (1951) was a landmark for
this type of interpretation
Automated interpretation procedures have played an increasingly important role in depth interpretation and a
wide range of techniques have been developed Many of these techniques are designed for application to located data
profiles and assume a two-dimensional geometry However there has been renewed interest in techniques applicable
to gridded data
Two distinct types of method can be recognized In the first case often described as discrete methods individual
isolated magnetic anomalies are interpreted and the results used to produce a map of basement relief In the second
case often described as continuous methods areas of data containing a number of anomalies are interpreted
statistically to produce direct output of basement depths
The discrete methods usually involve a semiautomatic initial phase which generates a large number of possible
depth solutions and an interactive second phase to screen and select acceptable solutions The advantage of this
approach is that the interpreter can select features that are relatively free from interference from adjacent anomalies
and consider all aspects of a particular magnetic anomaly The disadvantage is that interpretation can be very time
consuming as a wide range of depths are usually possible depending on the initial model chosen and a significant
amount of effort is needed to select the correct model In the case of the Savory Sub-basin dataset we encountered
problems in separating basement related effects from the effects of shallower intrasedimentary magnetic sources
Because of these problems we have concentrated on displaying the Euler results accompanied by separation filter
images of the data to show the shallower effects and deeper effects rather than trying to refine a 3D Euler
deconvolution depth-to-crystalline-basement contour
The continuous methods are very direct provided that the rather restrictive assumption can be made that all
anomalies are due to lateral magnetization changes due to basement topography This means that shallow effects and
large intrabasement anomalies must be removed from the data This involves judgement and skill as it is necessary to
distinguish between the lower amplitude suprabasement anomalies due to basement topography and the larger
intrabasement anomalies reflecting magnetization changes within the basement These methods were not considered
suitable for the Savory Sub-basin magnetic dataset but were used to invert the gravity data
50
Limitations of magnetic and gravity interpretation
Interpretation of the area is limited by a shortage of information on the nature and physical properties of the deeper
sedimentary sequence and the underlying basement rocks However using techniques such as cross-correlation of
gravity and pseudo-gravity data it is possible to try to differentiate between anomalies relating to basement and those
related to the sedimentary sequence
Gravity anomalies reflect changes within the sedimentary sequence as well as basement condition These
changes in density of sedimentary rocks produce gravity anomalies without a corresponding magnetic anomaly hence
the complementary nature of gravity and magnetic surveys The main use of magnetics is to determine depth to
magnetic basement and any intra-sedimentary volcanic rocks or intrusives whereas gravity provides much more
general information on the sedimentary sequence
Unfortunately interpretation of gravity anomalies is complicated since they can be due to a number of geological
features including
bull major basement faults
bull basement highs
bull igneous intrusions within the basement
bull sedimentary basins which may or may not be isostatically compensated
bull intra-sedimentary volcanics and associated plutonic centres
Two major problems affect the interpretation of both magnetic and gravity data
1 The inherent ambiguity of potential-field data There is no unique solution to any measured gravity or magnetic
anomaly and theoretically there will be an infinite number of source geometry and magnetizationdensity
combinations which will fit the observed data This means that any a priori information which helps to select a
suitable model is very useful
2 Measured anomalies are the summation of effects from different depths For example an observed gravity profile
may contain contributions from shallow sources (density variations within the sedimentary basin) intermediate
depth sources (density variations due to large igneous intrusions within the basement) and deep sources (crustal
thinning producing a mantle anomaly) Separation of these component responses is the regionalresidual problem
which we solve using spectral analysis and differential upward continuation-based separation filtering
Regional setting and interpretation overview
The area studied includes parts of BALFOUR DOWNS (SF51-9) RUDALL (SF51-10) ROBERTSON (SF51-13) GUNANYA
(SF51-14) COLLIER (SG50-4) BULLEN (SG51-1) TRAINOR (SG51-2) MADLEY (SG51-3) NABBERU (SG50-5)
STANLEY (SG51-6) and HERBERT (SG51-7) 1250 000 sheets Broadly the area lies between latitudes 22deg00rsquondash25deg30rsquoS
and longitudes 119deg30rsquondash123deg30rsquoE
51
Regional gravity
The AGSO regional gravity data (at nominal 11 km spacing) was gridded at a 4 km mesh spacing using a minimum-
curvature algorithm Bouguer gravity values in the area are negative reflecting mass deficiency at depth and range
from -84 mgals to -25 mgals
A Bouguer gravity colour image is shown as Figure 41 A residual grid was produced by removing a fifth-order
orthogonal polynomial from the Bouguer data but did not add to the interpretation
120deg 121deg 122deg 123deg
23deg
24deg
25deg
-25
-84
50 km
MKS46 180598
mgal
Figure 41 Regional Bouguer gravity (BMRAGSO data) gridded at 4 km
52
The data show a complex pattern of positive and negative anomalies with no clearly defined trends Correlations
with aeromagnetic data and known basin structures are poor A vague north-northwest linear trend appears to coincide
with the Marloo Fault (Figure 42) A prominent negative anomaly appears to coincide with the Blake Fold and Fault
Belt depocentre and continues as a narrower negative anomaly to the east until it widens out again near the edge of the
basin Elsewhere the gravity data show little correlation with known basin structures and it is likely that especially in
the north of the area gravity anomalies are due to density changes in the basement rather than changes in basement
topography
Production of wavelength-filtered residual gravity plots and vertical gradient plots showed very patchy aliased
data reflecting poor sampling in much of the area
Regional magnetics
The AGSO regional aeromagnetic data were gridded at a 400 m mesh spacing using a minimum-curvature algorithm
(Figure 43) Most of the data has a line spacing of 1600 m with small areas of 1 km spacing The quality of the data is
acceptable for regional interpretation but is not adequate for detailed analysis The accuracy of the flight path is rather
variable reflecting the vintage of the data and the noise envelope of the data is poor by modern standards Problems
were also encountered in joining different map sheets
The magnetic anomaly pattern over the south and west part of the area shows a strong high frequency signature
reflecting the presence of widespread basic sills and dykes Some of the major north-northeasterly trending dykes can
be traced over considerable distances
Discontinuous high-frequency anomalies extend as a northwest-trending zone through the centre of the area and
this zone includes a conspicuous circular magnetic anomaly which is probably a ring complex
The northern and eastern parts of the area are characterized by long-wavelength deep-seated basement magnetic
anomalies with 120deg and 150deg trends dominant The Marloo and Perentie Faults (Figure 42) appear as distinct linear
zones and offsets A prominent easterly trending negative anomaly in the northwest of the area appears to swing round
to the southeast and may separate different basement blocks One possible interpretation is that this very deep seated
anomaly separates areas of Archaean and Proterozoic basement
Regional geology
The regional geology is described in Williams (1992) The GSWA provided a digitized version of Plate 2 from this
Bulletin the structural interpretation map to use as an overlay (Figure 42)
53
Pp
Pp
PSd
PSd
PSd
PSd
PSd
PSo
PSt
PSt
PSf
PSf
PSf
PSb
PSb
PSb
PSsPSs
PSs
PSb
PSm
PSp
PSc
PSc
PSw
PSw
PSw
PSg
PSr
PSj
PSg
PM
Pk
PY
PY
PSd
L
L
L
L
L
L
L
LL
L
L
L
LL
L
LL
L L
LL
L L
L
L
L
L
L
L
L
LL
L
L
BLAKEDEPOCENTRE
MA
RLO
O
FAU
LT
PERENTIEFAULT
50 km
MKS39120598
120deg 121deg 122deg 123deg
25deg
24deg
23deg
Approximate boundaryof aeromagnetic interpretation
PML
PSgL
PSjL
PML
PSpL
PML
PML
PSfL
PSfL
PSpL
LPc
LPcLPcPSrL
LPA
Durba Sandstone
Woora Woora Formation
McFadden Formation
Tchukardine Formation
Boondawari Formation
Skates Hills Formation
Mundadjini Formation
Coondra Formation
Spearhole Formation
Watch Point Formation
Jilyili Formation
Brassey Range Formation
Glass Spring Formation
Paterson Formation
Yeneena Group
Karara Formation
Cornelia Formation
Kahrban Subgroup
Bangemall Group
Fault
Formation boundary
PSdL
PSoL
PSfL
PStL
PSbL
PSsL
PSmL
PScL
PSpL
PSwL
PSjL
PSrL
PSgL
Pp
PYL
PkL
LPc
LPA
PML
Savory Group Other Units
PYL
Figure 42 Regional geology and structure map (after Williams 1992)
54
120deg 121deg 122deg 123deg
23deg
24deg
25deg
5820
3750
MKS47 180598
nT
50 km
Figure 43 Regional aeromagnetic data total magnetic intensity (BMRAGSO data) gridded at 400 m
Analysis
3D analysis
3D Euler deconvolution was used as the primary depth-determination method The advantage of this approach is that
consistent solutions can be obtained over the entire area with minimal assumptions about source geometries Euler
deconvolution of gridded data is used for positional information and estimation of depth to top of source Euler
55
deconvolution yields a large number of depth solutions which have to be screened to reject spurious solutions Results
are plotted as circles in eight depth ranges with radius proportional to depth and colour coded
The 400 m total magnetic intensity grid was used for the analysis Horizontal gradients in x and y and the vertical
gradient were calculated 3D Euler deconvolution was tested on the 400 m gridded data using windows of 9 times 9 and
11 times 11 and 16 times 16 data points and structural indices 05 (fault) and 10 (sill or dyke) It was concluded that the
16 times 16 window produced the best results overall and final plots were produced for the 16 times 16 window and structural
index 05 (Fig 44) Results were very good over the northern and central parts of the area showing magnetic sources
Figure 44 Depth to magnetic source 3D Euler deconvolution 16 times 16 window of 400 m gridded data structural index 05
56
at several different levels Unfortunately in the extreme south of the area shallow intrasedimentary magnetic sources
(sills and dykes) dominated the inversion and the results contained few basement solutions
In order to reduce these problems the 400 m gridded data were filtered using a separation filter based on
interpretation of the log-energy spectrum The 3D Euler method was run on the filtered data in order to generate more
basement-depth solutions Results for the deep-separation filter data were gridded and presented as a colour image in
Cowan (1995) Attempts to grid the Euler output were unsatisfactory and it is considered safer to interpret the 3D
Euler depth plots The 3D Euler depth results from the separation-filter run should be analysed with care as perfect
separation of the basement can never be achieved and there will always be some contamination from sources at
different levels
The results of original total magnetic intensity 3D Euler depth estimation for structural index 05 using a 16 point
window have been plotted at 1500 000 scale (not included in this publication but available in Cowan (1995) from the
GSWA Library as S10331) and as reduced A4 colour circle plots (Figure 44)
The results of deep-basement 3D Euler depth estimation for structural index 05 using a 16 point window have
been plotted as a colour image at 1500 000 scale and as an A4 image (not included in this publication)
2D analysis
Two equispaced profiles were interpolated with a 50 m station interval from the AGSO-located data profiles for the
BULLEN 1250 000 sheet The interpolated profiles were analysed using 2D Euler deconvolution and Werner
deconvolution Results are included in Cowan (1995) and show the use of these methods for more detailed analysis
Filtered data
In order to reconcile 3D Euler results from shallow basement and intrasedimentary magnetic sources we produced
several separation-filtered maps and images We found the shallow-layer double-separation filter (Figure 45) to be
very effective for shallow sources and the deep-layer standard-separation filter (Figure 46) for the basement layer
Gravity and magnetic data correlation
Both lsquoreduced to the polersquo (RTP) magnetics (Figure 47) and pseudo-gravity data (Figure 48) were produced as part of
the reconciliation of gravity and magnetic signatures In both cases the filtering operations assumed magnetization by
induction in the present Earths field The RTP data are fairly similar to the total magnetic intensity The pseudo-
57
gravity data are dominated by a northwest-trending strong positive anomaly and there is little correlation with the
Bouguer gravity data
The poor magneticgravity correlation is confirmed by cross-correlation of the RTP magnetics and the gravity
gradient The correlation plot in Figure 49 shows little coherent response with numerous zones of positive and
negative correlation
Figure 45 Regional aeromagnetic data shallow layer separation filter (BMRAGSO data) gridded at 400 m
Results
In the north and east of the area on the Wells Foreland Sub-basin trend (refer to Figure 1 main text) we see a range
of quite deep 3D Euler depths and several trend directions with north-northwesterly dominant There are relatively few
shallow intrasedimentary solutions in this zone
The second area of deep 3D Euler solutions lies over the Blake depocentre (Figure 43) with several trend
directions
Elsewhere the 3D Euler results are dominated by shallow intrasedimentary depth solutions reflecting mainly the
dolerite sills dykes and the ring complex However where we do see basement-related solutions in the south and
west of the area they appear to be shallower than those noted for the Wells Foreland Sub-basin and the Blake
depocentre
58
Figure 46 Regional aeromagnetic data deep-layer separation filter (BMRAGSO data) gridded at 400 m
Figure 48 Regional aeromagnetic data pseudo-gravity transform (BMRAGSO data) gridded at 400 m
Figure 47 Regional aeromagnetic data reduced-to-pole (BMRAGSO data) gridded at 400 m
Figure 49 Regional aeromagnetic and gravity data gravitymagnetic correlation using RTP magnetics and gravity gradient (BMRAGSO data) gridded at 4 km
59
This subdivision of the area into two zones of deep solutions is consistent with interpreted depocentres
However the interference between sources at different levels and the complexity of the magnetic response of the
basement rocks precludes more refined interpretation at this stage
The area of deep 3D Euler solutions over the Blake depocentre correlates with the pronounced negative gravity
anomaly discussed in the gravity interpretation section Using a density contrast of -015 gcc the negative gravity
anomaly could indicate up to 6ndash8 km of low-density sedimentary rocks depending on assumptions about the regional
field
The area of deep 3D Euler solutions over the Wells Foreland Sub-basin has a complex gravity expression and no
clear basin structure emerges from inversion of these data As noted previously it is likely that observed gravity
anomalies reflect contrasts in basement density rather than basement topography
Separation filtering applied to the magnetic data helps to enhance the intrasedimentary magnetic signature and to
give a better impression of the basement magnetic signature even though separation of the basement response is not
perfect
Conclusions
Quantitative aeromagnetic interpretation using 3D Euler deconvolution supported by wavenumber filtering and image
processing has been successful in providing structural trend and depth information for the Savory Sub-basin
Quantitative magnetic interpretation has revealed two zones of relatively deep magnetic basement beneath the
Wells Foreland Sub-basin and the Blake depocentre
This analysis of the magnetic data supports interpreted depocentres but the complexity of the basement magnetic
signature and interference from sources at different depths precludes further refinement to a map of basement
topography
Regional gravity proved to be very useful in understanding the regional setting of the area and in providing
support for aspects of the interpretation The gravity data support the interpretation of the Blake depocentre
suggesting up to 6ndash8 km of low-density sedimentary rocks
The deep structure of the Savory Sub-basin area is obviously complex with different areas underlain by
Archaean and Proterozoic basement and with the Capricorn suture occurring in the centre of the area
60
Recommendations
The quantitative magnetic interpretation needs to be reconciled with geological models available for the area
In particular the zones tentatively identified as areas with thick sedimentary rocks the Wells Foreland Sub-
basin and the Blake depocentre need to be investigated
Cross sections should be prepared across the basin for joint magneticgravity modelling especially for the Blake
depocentre It is important to be able to explain the strong negative gravity anomaly in this area
In view of the effects of basement density contrasts on the gravity field for the northern part of the area we think
that additional gravity interpretation and acquisition of new gravity data may not be justified as they will not
contribute significantly to understanding basin evolution and structure
It is recommended that GSWA try to get access to company confidential high-resolution aeromagnetic data
rather than flying new surveys The GSWA might offer to fund flying of new infill areas as a bargaining point
References
The original text of this report by Cowan (1995) and 1500 000 scale maps are filed in the GSWA Library under
S10331
COWAN D 1995 Savory Basin quantitative magnetic interpretation Western Australia Geological Survey S-series
S10331 (unpublished)
VACQUIER V STEENLAND N C HENDERSON R G and ZIETZ I 1951 Interpretation of aeromagnetic
maps The Geological Society of America Memoir 47 151p
WILLIAMS I R 1992 Geology of the Savory Basin Western Australia Western Australia Geological Survey
Bulletin 141 115p
61
Appendix 5
Geochemistry
MKS38 250398
Saturate FractionC12+ GLC
1217
Pr18
Ph
22
31CSR WELL-13 315m Cuttings
Figure 51 Canning Stock Route Well 13 gas chromatograph of extract of auger drill sample
12
17
18
22
31
Pr Ph
LDDH 1 6623m CoreSaturate FractionC12+ GLC
MKS35 240398
Figure 52 Gas chromatograph of extract from core sample at 6623 m LDDH1
62
Table 51 Canning Stock Route Well 13 auger drill samples
GSWA sample Drill depth (m)(a) Comments
135601 150 At watertable 135602 203 (all samples consist 135603 310 of sand mud and water) 135604 315 At total depth
NOTE (a) Datum for drill depth is the top of sediment fill in the well which is 155 m below ground level (ie the total depth of 315 m is 47 m below ground level)
Table 52 Canning Stock Route Well 13 gas chromatography data for 315 m depth sediment sample
Parameter Value
Weight of rock extracted (grams) 945 Total extract (ppm) 519 n-Alkane distribution n-C12 07 n-C13 23 n-C14 26 n-C15 22 n-C16 19 n-C17 14 i-C19 23 n-C18 14 i-C20 08 n-C19 11 n-C20 16 n-C21 25 n-C22 29 n-C23 70 n-C24 42 n-C25 95 n-C26 43 n-C27 83 n-C28 38 n-C29 87 n-C30 31 n-C31 273 Alkane compositional data Pristane phytane ratio 279 Pristane n-C17 ratio 161 Phytane n-C18 ratio 059 CPI (1)(a) 284 CPI (2) 209 (C21 + C22) (C28 + C29) 043
NOTE (a) CPI= Carbon preference index
63
Table 53 LDDH1 extract liquid chromatography data for 6623 m concentration
Rock extracted Total extract (grams) (ppm)
702 313
NOTE ppm= parts per million
Table 54 LDDH1 saturate gas chromatography data of core for 6623 m alkane composition
Pristane Pristane Phytane (a) CPI (1) CPI (2) (C21+C22) Phytane n-C17 n-C18 (C28+C29)
103 026 024 103 102 325
NOTE (a)CPI = carbon preference index
Table 55 LDDH1 saturate gas chromatography data of core for 6623 m n-alkane distributions
Parameter Value
n-C12 17 n-C13 38 n-C14 55 n-C15 60 n-C16 65 n-C17 74 i-C19 19 n-C18 78 i-C20 19 n-C19 80 n-C20 79 n-C21 71 n-C22 64 n-C23 57 n-C25 43 n-C24 38 n-C27 31 n-C28 23 n-C29 19 n-C30 12 n-C31 10
64
Appendix 6
Table 61 Summary of data from Trainor waterbores (TWB) and Bullen waterbores (BWB)
Well AMG Elevation TD Status(b) Completion details Water Salinity Water level Flow rate Depth to consolidated AGD84 GL (m) (m) struck mgl(c) (m) (LHr) lithology aquifer(e) Z51(a) Interval (m) (100 mm PVC) (m) (mgl)(d)
TWB 1 473660E 453 122 comp 0ndash75 plain 63 7 300 24 2 880 12 m 7287404N 75ndash93 slotted (9 260) McFadden Fm 93ndash99 plain TWB 2 472 977E 475 23 abd nil 15 m 7285877N Skates Hills Fm dry TWB 3 473259E 475 50 abd nil 7 m 7285849N Skates Hills Fm dry TWB 4 463225 E 445 50 comp 0ndash22 plain 35 7 200 55 3 600 0 m 7286143N 22ndash34 slotted (8 140) Tertiary sand and gravel 23ndash60 plain TWB 5 463095E 445 31 comp 0ndash19 plain 13 26 000 655 3 600 Tertiary sand and gravel 7277721N 19ndash25 slotted (36 700) 25ndash31 plain TWB 6 457013E 455 50 comp 0ndash42 plain 38 920 119 600 0 m 7274352N 42ndash48 slotted (1 030) Cornelia Fm ss TWB 7 453739E 475 26 susp 0ndash2 plain 11 9 300 48 4 500 0 m 7263891N (10 500) Tertiary sand TWB 8 433893E 535 60 susp 0ndash2 plain 47 8 500 gt46 1 200 0 m 7245991N (10 900) Tertiary sand and Brassey Range Fm ss TWB 9 437219E 505 51 comp 0ndash47 plain 45 1 000 58 600 1 m 7235905N 47ndash51 slotted (990) Brassey Range Fm ss TWB 10 434927E 495 32 susp 0ndash2 plain 235 450 120 0 m 7225875N (500) Dolerite
65
BWB 1 287337E 580 122 abd Nil 1 m 7245861N Jilyili Fm dry BWB 2 288346E 545 50 comp 0ndash26 plain 15 630 3 29 000 0 m 7240423N 26ndash38 slotted (730) Tertiary sand and gravel 38ndash50 plain BWB 3 305637E 545 50 abd 19 8 800 43 7 200 0 m 7240423N (10 550) Tertiary ss BWB 4 320167E 515 445 comp 0ndash20 plain 9 980 445 24 000 0 m 7248097N 20ndash32 slotted (1 190) Tertiary ss 32ndash44 plain BWB 5 353393E 545 20 susp 0ndash2 plain 45 (970) 1 m 7238934N Basalt
NOTES (a) GPS accuracy ~ 150 m (b) Comp = completed abd = abandoned susp = suspended (c) Salinity from conductivity (d) Analysis total dissolved solids (e) Fm = Formation ss = sandstone
47
Appendix 3
Table 31 Summary of palynological results
Drillhole Depth (m) F no(a) GSWA no Lithology Formation Assemblage TAI(b)
BWB 1 74ndash75 F49668 135741 dark-grey siltstone basalt Jilyilli gt5 BWB 1 98ndash100 F49669 135742 dark-grey siltstone basalt Jilyilli gt5 BWB 1 121ndash122 F49670 135743 dark-grey siltstone basalt Jilyilli gt5 TWB 1 86ndash87 F49671 135631 dark-grey siltstone McFadden 3+ TWB 1 104ndash105 F49672 135632 dark-grey siltstone Cornelia 3+ TWB 1 121ndash122 F49673 135633 dark-grey siltstone Cornelia 4 TWB 2 14ndash15 F49674 135634 dark-grey siltstone Skates Hills 3+ TWB 6 49ndash50 F49675 135675 dark-grey siltstone Cornelia 1 3+ TWB 9 49ndash51 F49676 135704 dark-grey siltstone Brassey Range 1 3+ Trainor 1 37497- F49733 138939 black mudstone with Cornelia 5 37509 light-grey siltstone Trainor 1 3809 F49734 138940 dark-grey and black Cornelia 4- laminated mudstone Trainor 1 4170 F49735 138941 black unlaminated mudstone Cornelia 4- Trainor 1 4950 F49851 139501 dark-grey indurated siltstone Cornelia 5 Trainor 1 6032 F49852 139502 dark- and light-grey Cornelia 5 indurated siltstone Trainor 1 6434 F49853 139503 greenish indurated finely Cornelia 5 laminated siltstone LDDH 1 270 F49678 138934 dark-grey siltstone interbeds Waters 1 3+ in enterolithic evaporite Tarcunyah Gp LDDH 1 277 F49679 138935 dark-grey siltstone in cavity Waters 1 3+ in enterolithic evaporite Tarcunyah Gp
NOTES (a) GSWA Fossil Catalogue number (b) TAI = Thermal Alteration Index of Traverse (1988 plate 1)
48
Appendix 4
Savory Sub-basin quantitative magnetic and gravity interpretation (extracted from Cowan 1995)
Summary
A program of quantitative aeromagnetic interpretation has been completed on BMRAGSO data from the Savory Sub-
basin Western Australia Quantitative aeromagnetic interpretation utilized the 3D Euler deconvolution method
supported by wavenumber filtering and image processing The results have provided useful information on structural
trends and depth to magnetic sources in a structurally complex area Depth to magnetic source analysis has provided
information on intra-sedimentary magnetic sources as well as basement rocks
The results of the interpretation support previously identified depocentres However the presence of magnetic
sources at several levels makes it very difficult to produce a reliable magnetic basement depth contour map It is
considered more productive to work with the 3D Euler colour circle plots and images rather than trying to contour the
results It would be necessary to carry out a full-scale interpretation of the BMRAGSO profile data to improve on the
3D Euler results The regional gravity was found to be useful in interpreting the regional setting of the area although
the very wide data spacing limits quantitative use of the data The gravity data show quite a complex picture with
limited consistent correlation between gravity features and basin structures This suggests that gravity anomalies
reflect changes in density of the basement rocks rather than basement topography especially in the northern part of the
basin
It is recommended that the GSWA investigate access to company confidential high-resolution aeromagnetic data
prior to planning further aeromagnetic surveys Private companies have flown large parts of the northern half of the
area as part of their diamond exploration program Additional gravity coverage of the area may be more cost effective
than magnetic surveys as the gravity data provides more information on changes within the sedimentary section
Introduction
The main use of aeromagnetic data in petroleum exploration has been the determination of magnetic basement
topography although there has been increasing interest in analysis of intra-sedimentary magnetic anomalies
intrabasement and suprabasement magnetic anomalies These anomalies are used to determine depth to magnetic
basement rocks and hence determine the thickness of the sedimentary sequence Unfortunately interpretation of the
intrabasement and suprabasement magnetic anomalies is non-unique in terms of position and size of causative sources
because of the inherent ambiguity of potential-field methods However this ambiguity can be reduced by placing
49
constraints on source geometry and magnetization and by using geological and other geophysical data to constrain
the solution
Before 1970 most depth-determination techniques involved graphical determination of slopes of selected
magnetic anomalies and application of various empirical factors to convert the slopes into depth estimates Geological
Society of America Memoir 47 Interpretation of Aeromagnetic Maps by Vacquier et al (1951) was a landmark for
this type of interpretation
Automated interpretation procedures have played an increasingly important role in depth interpretation and a
wide range of techniques have been developed Many of these techniques are designed for application to located data
profiles and assume a two-dimensional geometry However there has been renewed interest in techniques applicable
to gridded data
Two distinct types of method can be recognized In the first case often described as discrete methods individual
isolated magnetic anomalies are interpreted and the results used to produce a map of basement relief In the second
case often described as continuous methods areas of data containing a number of anomalies are interpreted
statistically to produce direct output of basement depths
The discrete methods usually involve a semiautomatic initial phase which generates a large number of possible
depth solutions and an interactive second phase to screen and select acceptable solutions The advantage of this
approach is that the interpreter can select features that are relatively free from interference from adjacent anomalies
and consider all aspects of a particular magnetic anomaly The disadvantage is that interpretation can be very time
consuming as a wide range of depths are usually possible depending on the initial model chosen and a significant
amount of effort is needed to select the correct model In the case of the Savory Sub-basin dataset we encountered
problems in separating basement related effects from the effects of shallower intrasedimentary magnetic sources
Because of these problems we have concentrated on displaying the Euler results accompanied by separation filter
images of the data to show the shallower effects and deeper effects rather than trying to refine a 3D Euler
deconvolution depth-to-crystalline-basement contour
The continuous methods are very direct provided that the rather restrictive assumption can be made that all
anomalies are due to lateral magnetization changes due to basement topography This means that shallow effects and
large intrabasement anomalies must be removed from the data This involves judgement and skill as it is necessary to
distinguish between the lower amplitude suprabasement anomalies due to basement topography and the larger
intrabasement anomalies reflecting magnetization changes within the basement These methods were not considered
suitable for the Savory Sub-basin magnetic dataset but were used to invert the gravity data
50
Limitations of magnetic and gravity interpretation
Interpretation of the area is limited by a shortage of information on the nature and physical properties of the deeper
sedimentary sequence and the underlying basement rocks However using techniques such as cross-correlation of
gravity and pseudo-gravity data it is possible to try to differentiate between anomalies relating to basement and those
related to the sedimentary sequence
Gravity anomalies reflect changes within the sedimentary sequence as well as basement condition These
changes in density of sedimentary rocks produce gravity anomalies without a corresponding magnetic anomaly hence
the complementary nature of gravity and magnetic surveys The main use of magnetics is to determine depth to
magnetic basement and any intra-sedimentary volcanic rocks or intrusives whereas gravity provides much more
general information on the sedimentary sequence
Unfortunately interpretation of gravity anomalies is complicated since they can be due to a number of geological
features including
bull major basement faults
bull basement highs
bull igneous intrusions within the basement
bull sedimentary basins which may or may not be isostatically compensated
bull intra-sedimentary volcanics and associated plutonic centres
Two major problems affect the interpretation of both magnetic and gravity data
1 The inherent ambiguity of potential-field data There is no unique solution to any measured gravity or magnetic
anomaly and theoretically there will be an infinite number of source geometry and magnetizationdensity
combinations which will fit the observed data This means that any a priori information which helps to select a
suitable model is very useful
2 Measured anomalies are the summation of effects from different depths For example an observed gravity profile
may contain contributions from shallow sources (density variations within the sedimentary basin) intermediate
depth sources (density variations due to large igneous intrusions within the basement) and deep sources (crustal
thinning producing a mantle anomaly) Separation of these component responses is the regionalresidual problem
which we solve using spectral analysis and differential upward continuation-based separation filtering
Regional setting and interpretation overview
The area studied includes parts of BALFOUR DOWNS (SF51-9) RUDALL (SF51-10) ROBERTSON (SF51-13) GUNANYA
(SF51-14) COLLIER (SG50-4) BULLEN (SG51-1) TRAINOR (SG51-2) MADLEY (SG51-3) NABBERU (SG50-5)
STANLEY (SG51-6) and HERBERT (SG51-7) 1250 000 sheets Broadly the area lies between latitudes 22deg00rsquondash25deg30rsquoS
and longitudes 119deg30rsquondash123deg30rsquoE
51
Regional gravity
The AGSO regional gravity data (at nominal 11 km spacing) was gridded at a 4 km mesh spacing using a minimum-
curvature algorithm Bouguer gravity values in the area are negative reflecting mass deficiency at depth and range
from -84 mgals to -25 mgals
A Bouguer gravity colour image is shown as Figure 41 A residual grid was produced by removing a fifth-order
orthogonal polynomial from the Bouguer data but did not add to the interpretation
120deg 121deg 122deg 123deg
23deg
24deg
25deg
-25
-84
50 km
MKS46 180598
mgal
Figure 41 Regional Bouguer gravity (BMRAGSO data) gridded at 4 km
52
The data show a complex pattern of positive and negative anomalies with no clearly defined trends Correlations
with aeromagnetic data and known basin structures are poor A vague north-northwest linear trend appears to coincide
with the Marloo Fault (Figure 42) A prominent negative anomaly appears to coincide with the Blake Fold and Fault
Belt depocentre and continues as a narrower negative anomaly to the east until it widens out again near the edge of the
basin Elsewhere the gravity data show little correlation with known basin structures and it is likely that especially in
the north of the area gravity anomalies are due to density changes in the basement rather than changes in basement
topography
Production of wavelength-filtered residual gravity plots and vertical gradient plots showed very patchy aliased
data reflecting poor sampling in much of the area
Regional magnetics
The AGSO regional aeromagnetic data were gridded at a 400 m mesh spacing using a minimum-curvature algorithm
(Figure 43) Most of the data has a line spacing of 1600 m with small areas of 1 km spacing The quality of the data is
acceptable for regional interpretation but is not adequate for detailed analysis The accuracy of the flight path is rather
variable reflecting the vintage of the data and the noise envelope of the data is poor by modern standards Problems
were also encountered in joining different map sheets
The magnetic anomaly pattern over the south and west part of the area shows a strong high frequency signature
reflecting the presence of widespread basic sills and dykes Some of the major north-northeasterly trending dykes can
be traced over considerable distances
Discontinuous high-frequency anomalies extend as a northwest-trending zone through the centre of the area and
this zone includes a conspicuous circular magnetic anomaly which is probably a ring complex
The northern and eastern parts of the area are characterized by long-wavelength deep-seated basement magnetic
anomalies with 120deg and 150deg trends dominant The Marloo and Perentie Faults (Figure 42) appear as distinct linear
zones and offsets A prominent easterly trending negative anomaly in the northwest of the area appears to swing round
to the southeast and may separate different basement blocks One possible interpretation is that this very deep seated
anomaly separates areas of Archaean and Proterozoic basement
Regional geology
The regional geology is described in Williams (1992) The GSWA provided a digitized version of Plate 2 from this
Bulletin the structural interpretation map to use as an overlay (Figure 42)
53
Pp
Pp
PSd
PSd
PSd
PSd
PSd
PSo
PSt
PSt
PSf
PSf
PSf
PSb
PSb
PSb
PSsPSs
PSs
PSb
PSm
PSp
PSc
PSc
PSw
PSw
PSw
PSg
PSr
PSj
PSg
PM
Pk
PY
PY
PSd
L
L
L
L
L
L
L
LL
L
L
L
LL
L
LL
L L
LL
L L
L
L
L
L
L
L
L
LL
L
L
BLAKEDEPOCENTRE
MA
RLO
O
FAU
LT
PERENTIEFAULT
50 km
MKS39120598
120deg 121deg 122deg 123deg
25deg
24deg
23deg
Approximate boundaryof aeromagnetic interpretation
PML
PSgL
PSjL
PML
PSpL
PML
PML
PSfL
PSfL
PSpL
LPc
LPcLPcPSrL
LPA
Durba Sandstone
Woora Woora Formation
McFadden Formation
Tchukardine Formation
Boondawari Formation
Skates Hills Formation
Mundadjini Formation
Coondra Formation
Spearhole Formation
Watch Point Formation
Jilyili Formation
Brassey Range Formation
Glass Spring Formation
Paterson Formation
Yeneena Group
Karara Formation
Cornelia Formation
Kahrban Subgroup
Bangemall Group
Fault
Formation boundary
PSdL
PSoL
PSfL
PStL
PSbL
PSsL
PSmL
PScL
PSpL
PSwL
PSjL
PSrL
PSgL
Pp
PYL
PkL
LPc
LPA
PML
Savory Group Other Units
PYL
Figure 42 Regional geology and structure map (after Williams 1992)
54
120deg 121deg 122deg 123deg
23deg
24deg
25deg
5820
3750
MKS47 180598
nT
50 km
Figure 43 Regional aeromagnetic data total magnetic intensity (BMRAGSO data) gridded at 400 m
Analysis
3D analysis
3D Euler deconvolution was used as the primary depth-determination method The advantage of this approach is that
consistent solutions can be obtained over the entire area with minimal assumptions about source geometries Euler
deconvolution of gridded data is used for positional information and estimation of depth to top of source Euler
55
deconvolution yields a large number of depth solutions which have to be screened to reject spurious solutions Results
are plotted as circles in eight depth ranges with radius proportional to depth and colour coded
The 400 m total magnetic intensity grid was used for the analysis Horizontal gradients in x and y and the vertical
gradient were calculated 3D Euler deconvolution was tested on the 400 m gridded data using windows of 9 times 9 and
11 times 11 and 16 times 16 data points and structural indices 05 (fault) and 10 (sill or dyke) It was concluded that the
16 times 16 window produced the best results overall and final plots were produced for the 16 times 16 window and structural
index 05 (Fig 44) Results were very good over the northern and central parts of the area showing magnetic sources
Figure 44 Depth to magnetic source 3D Euler deconvolution 16 times 16 window of 400 m gridded data structural index 05
56
at several different levels Unfortunately in the extreme south of the area shallow intrasedimentary magnetic sources
(sills and dykes) dominated the inversion and the results contained few basement solutions
In order to reduce these problems the 400 m gridded data were filtered using a separation filter based on
interpretation of the log-energy spectrum The 3D Euler method was run on the filtered data in order to generate more
basement-depth solutions Results for the deep-separation filter data were gridded and presented as a colour image in
Cowan (1995) Attempts to grid the Euler output were unsatisfactory and it is considered safer to interpret the 3D
Euler depth plots The 3D Euler depth results from the separation-filter run should be analysed with care as perfect
separation of the basement can never be achieved and there will always be some contamination from sources at
different levels
The results of original total magnetic intensity 3D Euler depth estimation for structural index 05 using a 16 point
window have been plotted at 1500 000 scale (not included in this publication but available in Cowan (1995) from the
GSWA Library as S10331) and as reduced A4 colour circle plots (Figure 44)
The results of deep-basement 3D Euler depth estimation for structural index 05 using a 16 point window have
been plotted as a colour image at 1500 000 scale and as an A4 image (not included in this publication)
2D analysis
Two equispaced profiles were interpolated with a 50 m station interval from the AGSO-located data profiles for the
BULLEN 1250 000 sheet The interpolated profiles were analysed using 2D Euler deconvolution and Werner
deconvolution Results are included in Cowan (1995) and show the use of these methods for more detailed analysis
Filtered data
In order to reconcile 3D Euler results from shallow basement and intrasedimentary magnetic sources we produced
several separation-filtered maps and images We found the shallow-layer double-separation filter (Figure 45) to be
very effective for shallow sources and the deep-layer standard-separation filter (Figure 46) for the basement layer
Gravity and magnetic data correlation
Both lsquoreduced to the polersquo (RTP) magnetics (Figure 47) and pseudo-gravity data (Figure 48) were produced as part of
the reconciliation of gravity and magnetic signatures In both cases the filtering operations assumed magnetization by
induction in the present Earths field The RTP data are fairly similar to the total magnetic intensity The pseudo-
57
gravity data are dominated by a northwest-trending strong positive anomaly and there is little correlation with the
Bouguer gravity data
The poor magneticgravity correlation is confirmed by cross-correlation of the RTP magnetics and the gravity
gradient The correlation plot in Figure 49 shows little coherent response with numerous zones of positive and
negative correlation
Figure 45 Regional aeromagnetic data shallow layer separation filter (BMRAGSO data) gridded at 400 m
Results
In the north and east of the area on the Wells Foreland Sub-basin trend (refer to Figure 1 main text) we see a range
of quite deep 3D Euler depths and several trend directions with north-northwesterly dominant There are relatively few
shallow intrasedimentary solutions in this zone
The second area of deep 3D Euler solutions lies over the Blake depocentre (Figure 43) with several trend
directions
Elsewhere the 3D Euler results are dominated by shallow intrasedimentary depth solutions reflecting mainly the
dolerite sills dykes and the ring complex However where we do see basement-related solutions in the south and
west of the area they appear to be shallower than those noted for the Wells Foreland Sub-basin and the Blake
depocentre
58
Figure 46 Regional aeromagnetic data deep-layer separation filter (BMRAGSO data) gridded at 400 m
Figure 48 Regional aeromagnetic data pseudo-gravity transform (BMRAGSO data) gridded at 400 m
Figure 47 Regional aeromagnetic data reduced-to-pole (BMRAGSO data) gridded at 400 m
Figure 49 Regional aeromagnetic and gravity data gravitymagnetic correlation using RTP magnetics and gravity gradient (BMRAGSO data) gridded at 4 km
59
This subdivision of the area into two zones of deep solutions is consistent with interpreted depocentres
However the interference between sources at different levels and the complexity of the magnetic response of the
basement rocks precludes more refined interpretation at this stage
The area of deep 3D Euler solutions over the Blake depocentre correlates with the pronounced negative gravity
anomaly discussed in the gravity interpretation section Using a density contrast of -015 gcc the negative gravity
anomaly could indicate up to 6ndash8 km of low-density sedimentary rocks depending on assumptions about the regional
field
The area of deep 3D Euler solutions over the Wells Foreland Sub-basin has a complex gravity expression and no
clear basin structure emerges from inversion of these data As noted previously it is likely that observed gravity
anomalies reflect contrasts in basement density rather than basement topography
Separation filtering applied to the magnetic data helps to enhance the intrasedimentary magnetic signature and to
give a better impression of the basement magnetic signature even though separation of the basement response is not
perfect
Conclusions
Quantitative aeromagnetic interpretation using 3D Euler deconvolution supported by wavenumber filtering and image
processing has been successful in providing structural trend and depth information for the Savory Sub-basin
Quantitative magnetic interpretation has revealed two zones of relatively deep magnetic basement beneath the
Wells Foreland Sub-basin and the Blake depocentre
This analysis of the magnetic data supports interpreted depocentres but the complexity of the basement magnetic
signature and interference from sources at different depths precludes further refinement to a map of basement
topography
Regional gravity proved to be very useful in understanding the regional setting of the area and in providing
support for aspects of the interpretation The gravity data support the interpretation of the Blake depocentre
suggesting up to 6ndash8 km of low-density sedimentary rocks
The deep structure of the Savory Sub-basin area is obviously complex with different areas underlain by
Archaean and Proterozoic basement and with the Capricorn suture occurring in the centre of the area
60
Recommendations
The quantitative magnetic interpretation needs to be reconciled with geological models available for the area
In particular the zones tentatively identified as areas with thick sedimentary rocks the Wells Foreland Sub-
basin and the Blake depocentre need to be investigated
Cross sections should be prepared across the basin for joint magneticgravity modelling especially for the Blake
depocentre It is important to be able to explain the strong negative gravity anomaly in this area
In view of the effects of basement density contrasts on the gravity field for the northern part of the area we think
that additional gravity interpretation and acquisition of new gravity data may not be justified as they will not
contribute significantly to understanding basin evolution and structure
It is recommended that GSWA try to get access to company confidential high-resolution aeromagnetic data
rather than flying new surveys The GSWA might offer to fund flying of new infill areas as a bargaining point
References
The original text of this report by Cowan (1995) and 1500 000 scale maps are filed in the GSWA Library under
S10331
COWAN D 1995 Savory Basin quantitative magnetic interpretation Western Australia Geological Survey S-series
S10331 (unpublished)
VACQUIER V STEENLAND N C HENDERSON R G and ZIETZ I 1951 Interpretation of aeromagnetic
maps The Geological Society of America Memoir 47 151p
WILLIAMS I R 1992 Geology of the Savory Basin Western Australia Western Australia Geological Survey
Bulletin 141 115p
61
Appendix 5
Geochemistry
MKS38 250398
Saturate FractionC12+ GLC
1217
Pr18
Ph
22
31CSR WELL-13 315m Cuttings
Figure 51 Canning Stock Route Well 13 gas chromatograph of extract of auger drill sample
12
17
18
22
31
Pr Ph
LDDH 1 6623m CoreSaturate FractionC12+ GLC
MKS35 240398
Figure 52 Gas chromatograph of extract from core sample at 6623 m LDDH1
62
Table 51 Canning Stock Route Well 13 auger drill samples
GSWA sample Drill depth (m)(a) Comments
135601 150 At watertable 135602 203 (all samples consist 135603 310 of sand mud and water) 135604 315 At total depth
NOTE (a) Datum for drill depth is the top of sediment fill in the well which is 155 m below ground level (ie the total depth of 315 m is 47 m below ground level)
Table 52 Canning Stock Route Well 13 gas chromatography data for 315 m depth sediment sample
Parameter Value
Weight of rock extracted (grams) 945 Total extract (ppm) 519 n-Alkane distribution n-C12 07 n-C13 23 n-C14 26 n-C15 22 n-C16 19 n-C17 14 i-C19 23 n-C18 14 i-C20 08 n-C19 11 n-C20 16 n-C21 25 n-C22 29 n-C23 70 n-C24 42 n-C25 95 n-C26 43 n-C27 83 n-C28 38 n-C29 87 n-C30 31 n-C31 273 Alkane compositional data Pristane phytane ratio 279 Pristane n-C17 ratio 161 Phytane n-C18 ratio 059 CPI (1)(a) 284 CPI (2) 209 (C21 + C22) (C28 + C29) 043
NOTE (a) CPI= Carbon preference index
63
Table 53 LDDH1 extract liquid chromatography data for 6623 m concentration
Rock extracted Total extract (grams) (ppm)
702 313
NOTE ppm= parts per million
Table 54 LDDH1 saturate gas chromatography data of core for 6623 m alkane composition
Pristane Pristane Phytane (a) CPI (1) CPI (2) (C21+C22) Phytane n-C17 n-C18 (C28+C29)
103 026 024 103 102 325
NOTE (a)CPI = carbon preference index
Table 55 LDDH1 saturate gas chromatography data of core for 6623 m n-alkane distributions
Parameter Value
n-C12 17 n-C13 38 n-C14 55 n-C15 60 n-C16 65 n-C17 74 i-C19 19 n-C18 78 i-C20 19 n-C19 80 n-C20 79 n-C21 71 n-C22 64 n-C23 57 n-C25 43 n-C24 38 n-C27 31 n-C28 23 n-C29 19 n-C30 12 n-C31 10
64
Appendix 6
Table 61 Summary of data from Trainor waterbores (TWB) and Bullen waterbores (BWB)
Well AMG Elevation TD Status(b) Completion details Water Salinity Water level Flow rate Depth to consolidated AGD84 GL (m) (m) struck mgl(c) (m) (LHr) lithology aquifer(e) Z51(a) Interval (m) (100 mm PVC) (m) (mgl)(d)
TWB 1 473660E 453 122 comp 0ndash75 plain 63 7 300 24 2 880 12 m 7287404N 75ndash93 slotted (9 260) McFadden Fm 93ndash99 plain TWB 2 472 977E 475 23 abd nil 15 m 7285877N Skates Hills Fm dry TWB 3 473259E 475 50 abd nil 7 m 7285849N Skates Hills Fm dry TWB 4 463225 E 445 50 comp 0ndash22 plain 35 7 200 55 3 600 0 m 7286143N 22ndash34 slotted (8 140) Tertiary sand and gravel 23ndash60 plain TWB 5 463095E 445 31 comp 0ndash19 plain 13 26 000 655 3 600 Tertiary sand and gravel 7277721N 19ndash25 slotted (36 700) 25ndash31 plain TWB 6 457013E 455 50 comp 0ndash42 plain 38 920 119 600 0 m 7274352N 42ndash48 slotted (1 030) Cornelia Fm ss TWB 7 453739E 475 26 susp 0ndash2 plain 11 9 300 48 4 500 0 m 7263891N (10 500) Tertiary sand TWB 8 433893E 535 60 susp 0ndash2 plain 47 8 500 gt46 1 200 0 m 7245991N (10 900) Tertiary sand and Brassey Range Fm ss TWB 9 437219E 505 51 comp 0ndash47 plain 45 1 000 58 600 1 m 7235905N 47ndash51 slotted (990) Brassey Range Fm ss TWB 10 434927E 495 32 susp 0ndash2 plain 235 450 120 0 m 7225875N (500) Dolerite
65
BWB 1 287337E 580 122 abd Nil 1 m 7245861N Jilyili Fm dry BWB 2 288346E 545 50 comp 0ndash26 plain 15 630 3 29 000 0 m 7240423N 26ndash38 slotted (730) Tertiary sand and gravel 38ndash50 plain BWB 3 305637E 545 50 abd 19 8 800 43 7 200 0 m 7240423N (10 550) Tertiary ss BWB 4 320167E 515 445 comp 0ndash20 plain 9 980 445 24 000 0 m 7248097N 20ndash32 slotted (1 190) Tertiary ss 32ndash44 plain BWB 5 353393E 545 20 susp 0ndash2 plain 45 (970) 1 m 7238934N Basalt
NOTES (a) GPS accuracy ~ 150 m (b) Comp = completed abd = abandoned susp = suspended (c) Salinity from conductivity (d) Analysis total dissolved solids (e) Fm = Formation ss = sandstone
48
Appendix 4
Savory Sub-basin quantitative magnetic and gravity interpretation (extracted from Cowan 1995)
Summary
A program of quantitative aeromagnetic interpretation has been completed on BMRAGSO data from the Savory Sub-
basin Western Australia Quantitative aeromagnetic interpretation utilized the 3D Euler deconvolution method
supported by wavenumber filtering and image processing The results have provided useful information on structural
trends and depth to magnetic sources in a structurally complex area Depth to magnetic source analysis has provided
information on intra-sedimentary magnetic sources as well as basement rocks
The results of the interpretation support previously identified depocentres However the presence of magnetic
sources at several levels makes it very difficult to produce a reliable magnetic basement depth contour map It is
considered more productive to work with the 3D Euler colour circle plots and images rather than trying to contour the
results It would be necessary to carry out a full-scale interpretation of the BMRAGSO profile data to improve on the
3D Euler results The regional gravity was found to be useful in interpreting the regional setting of the area although
the very wide data spacing limits quantitative use of the data The gravity data show quite a complex picture with
limited consistent correlation between gravity features and basin structures This suggests that gravity anomalies
reflect changes in density of the basement rocks rather than basement topography especially in the northern part of the
basin
It is recommended that the GSWA investigate access to company confidential high-resolution aeromagnetic data
prior to planning further aeromagnetic surveys Private companies have flown large parts of the northern half of the
area as part of their diamond exploration program Additional gravity coverage of the area may be more cost effective
than magnetic surveys as the gravity data provides more information on changes within the sedimentary section
Introduction
The main use of aeromagnetic data in petroleum exploration has been the determination of magnetic basement
topography although there has been increasing interest in analysis of intra-sedimentary magnetic anomalies
intrabasement and suprabasement magnetic anomalies These anomalies are used to determine depth to magnetic
basement rocks and hence determine the thickness of the sedimentary sequence Unfortunately interpretation of the
intrabasement and suprabasement magnetic anomalies is non-unique in terms of position and size of causative sources
because of the inherent ambiguity of potential-field methods However this ambiguity can be reduced by placing
49
constraints on source geometry and magnetization and by using geological and other geophysical data to constrain
the solution
Before 1970 most depth-determination techniques involved graphical determination of slopes of selected
magnetic anomalies and application of various empirical factors to convert the slopes into depth estimates Geological
Society of America Memoir 47 Interpretation of Aeromagnetic Maps by Vacquier et al (1951) was a landmark for
this type of interpretation
Automated interpretation procedures have played an increasingly important role in depth interpretation and a
wide range of techniques have been developed Many of these techniques are designed for application to located data
profiles and assume a two-dimensional geometry However there has been renewed interest in techniques applicable
to gridded data
Two distinct types of method can be recognized In the first case often described as discrete methods individual
isolated magnetic anomalies are interpreted and the results used to produce a map of basement relief In the second
case often described as continuous methods areas of data containing a number of anomalies are interpreted
statistically to produce direct output of basement depths
The discrete methods usually involve a semiautomatic initial phase which generates a large number of possible
depth solutions and an interactive second phase to screen and select acceptable solutions The advantage of this
approach is that the interpreter can select features that are relatively free from interference from adjacent anomalies
and consider all aspects of a particular magnetic anomaly The disadvantage is that interpretation can be very time
consuming as a wide range of depths are usually possible depending on the initial model chosen and a significant
amount of effort is needed to select the correct model In the case of the Savory Sub-basin dataset we encountered
problems in separating basement related effects from the effects of shallower intrasedimentary magnetic sources
Because of these problems we have concentrated on displaying the Euler results accompanied by separation filter
images of the data to show the shallower effects and deeper effects rather than trying to refine a 3D Euler
deconvolution depth-to-crystalline-basement contour
The continuous methods are very direct provided that the rather restrictive assumption can be made that all
anomalies are due to lateral magnetization changes due to basement topography This means that shallow effects and
large intrabasement anomalies must be removed from the data This involves judgement and skill as it is necessary to
distinguish between the lower amplitude suprabasement anomalies due to basement topography and the larger
intrabasement anomalies reflecting magnetization changes within the basement These methods were not considered
suitable for the Savory Sub-basin magnetic dataset but were used to invert the gravity data
50
Limitations of magnetic and gravity interpretation
Interpretation of the area is limited by a shortage of information on the nature and physical properties of the deeper
sedimentary sequence and the underlying basement rocks However using techniques such as cross-correlation of
gravity and pseudo-gravity data it is possible to try to differentiate between anomalies relating to basement and those
related to the sedimentary sequence
Gravity anomalies reflect changes within the sedimentary sequence as well as basement condition These
changes in density of sedimentary rocks produce gravity anomalies without a corresponding magnetic anomaly hence
the complementary nature of gravity and magnetic surveys The main use of magnetics is to determine depth to
magnetic basement and any intra-sedimentary volcanic rocks or intrusives whereas gravity provides much more
general information on the sedimentary sequence
Unfortunately interpretation of gravity anomalies is complicated since they can be due to a number of geological
features including
bull major basement faults
bull basement highs
bull igneous intrusions within the basement
bull sedimentary basins which may or may not be isostatically compensated
bull intra-sedimentary volcanics and associated plutonic centres
Two major problems affect the interpretation of both magnetic and gravity data
1 The inherent ambiguity of potential-field data There is no unique solution to any measured gravity or magnetic
anomaly and theoretically there will be an infinite number of source geometry and magnetizationdensity
combinations which will fit the observed data This means that any a priori information which helps to select a
suitable model is very useful
2 Measured anomalies are the summation of effects from different depths For example an observed gravity profile
may contain contributions from shallow sources (density variations within the sedimentary basin) intermediate
depth sources (density variations due to large igneous intrusions within the basement) and deep sources (crustal
thinning producing a mantle anomaly) Separation of these component responses is the regionalresidual problem
which we solve using spectral analysis and differential upward continuation-based separation filtering
Regional setting and interpretation overview
The area studied includes parts of BALFOUR DOWNS (SF51-9) RUDALL (SF51-10) ROBERTSON (SF51-13) GUNANYA
(SF51-14) COLLIER (SG50-4) BULLEN (SG51-1) TRAINOR (SG51-2) MADLEY (SG51-3) NABBERU (SG50-5)
STANLEY (SG51-6) and HERBERT (SG51-7) 1250 000 sheets Broadly the area lies between latitudes 22deg00rsquondash25deg30rsquoS
and longitudes 119deg30rsquondash123deg30rsquoE
51
Regional gravity
The AGSO regional gravity data (at nominal 11 km spacing) was gridded at a 4 km mesh spacing using a minimum-
curvature algorithm Bouguer gravity values in the area are negative reflecting mass deficiency at depth and range
from -84 mgals to -25 mgals
A Bouguer gravity colour image is shown as Figure 41 A residual grid was produced by removing a fifth-order
orthogonal polynomial from the Bouguer data but did not add to the interpretation
120deg 121deg 122deg 123deg
23deg
24deg
25deg
-25
-84
50 km
MKS46 180598
mgal
Figure 41 Regional Bouguer gravity (BMRAGSO data) gridded at 4 km
52
The data show a complex pattern of positive and negative anomalies with no clearly defined trends Correlations
with aeromagnetic data and known basin structures are poor A vague north-northwest linear trend appears to coincide
with the Marloo Fault (Figure 42) A prominent negative anomaly appears to coincide with the Blake Fold and Fault
Belt depocentre and continues as a narrower negative anomaly to the east until it widens out again near the edge of the
basin Elsewhere the gravity data show little correlation with known basin structures and it is likely that especially in
the north of the area gravity anomalies are due to density changes in the basement rather than changes in basement
topography
Production of wavelength-filtered residual gravity plots and vertical gradient plots showed very patchy aliased
data reflecting poor sampling in much of the area
Regional magnetics
The AGSO regional aeromagnetic data were gridded at a 400 m mesh spacing using a minimum-curvature algorithm
(Figure 43) Most of the data has a line spacing of 1600 m with small areas of 1 km spacing The quality of the data is
acceptable for regional interpretation but is not adequate for detailed analysis The accuracy of the flight path is rather
variable reflecting the vintage of the data and the noise envelope of the data is poor by modern standards Problems
were also encountered in joining different map sheets
The magnetic anomaly pattern over the south and west part of the area shows a strong high frequency signature
reflecting the presence of widespread basic sills and dykes Some of the major north-northeasterly trending dykes can
be traced over considerable distances
Discontinuous high-frequency anomalies extend as a northwest-trending zone through the centre of the area and
this zone includes a conspicuous circular magnetic anomaly which is probably a ring complex
The northern and eastern parts of the area are characterized by long-wavelength deep-seated basement magnetic
anomalies with 120deg and 150deg trends dominant The Marloo and Perentie Faults (Figure 42) appear as distinct linear
zones and offsets A prominent easterly trending negative anomaly in the northwest of the area appears to swing round
to the southeast and may separate different basement blocks One possible interpretation is that this very deep seated
anomaly separates areas of Archaean and Proterozoic basement
Regional geology
The regional geology is described in Williams (1992) The GSWA provided a digitized version of Plate 2 from this
Bulletin the structural interpretation map to use as an overlay (Figure 42)
53
Pp
Pp
PSd
PSd
PSd
PSd
PSd
PSo
PSt
PSt
PSf
PSf
PSf
PSb
PSb
PSb
PSsPSs
PSs
PSb
PSm
PSp
PSc
PSc
PSw
PSw
PSw
PSg
PSr
PSj
PSg
PM
Pk
PY
PY
PSd
L
L
L
L
L
L
L
LL
L
L
L
LL
L
LL
L L
LL
L L
L
L
L
L
L
L
L
LL
L
L
BLAKEDEPOCENTRE
MA
RLO
O
FAU
LT
PERENTIEFAULT
50 km
MKS39120598
120deg 121deg 122deg 123deg
25deg
24deg
23deg
Approximate boundaryof aeromagnetic interpretation
PML
PSgL
PSjL
PML
PSpL
PML
PML
PSfL
PSfL
PSpL
LPc
LPcLPcPSrL
LPA
Durba Sandstone
Woora Woora Formation
McFadden Formation
Tchukardine Formation
Boondawari Formation
Skates Hills Formation
Mundadjini Formation
Coondra Formation
Spearhole Formation
Watch Point Formation
Jilyili Formation
Brassey Range Formation
Glass Spring Formation
Paterson Formation
Yeneena Group
Karara Formation
Cornelia Formation
Kahrban Subgroup
Bangemall Group
Fault
Formation boundary
PSdL
PSoL
PSfL
PStL
PSbL
PSsL
PSmL
PScL
PSpL
PSwL
PSjL
PSrL
PSgL
Pp
PYL
PkL
LPc
LPA
PML
Savory Group Other Units
PYL
Figure 42 Regional geology and structure map (after Williams 1992)
54
120deg 121deg 122deg 123deg
23deg
24deg
25deg
5820
3750
MKS47 180598
nT
50 km
Figure 43 Regional aeromagnetic data total magnetic intensity (BMRAGSO data) gridded at 400 m
Analysis
3D analysis
3D Euler deconvolution was used as the primary depth-determination method The advantage of this approach is that
consistent solutions can be obtained over the entire area with minimal assumptions about source geometries Euler
deconvolution of gridded data is used for positional information and estimation of depth to top of source Euler
55
deconvolution yields a large number of depth solutions which have to be screened to reject spurious solutions Results
are plotted as circles in eight depth ranges with radius proportional to depth and colour coded
The 400 m total magnetic intensity grid was used for the analysis Horizontal gradients in x and y and the vertical
gradient were calculated 3D Euler deconvolution was tested on the 400 m gridded data using windows of 9 times 9 and
11 times 11 and 16 times 16 data points and structural indices 05 (fault) and 10 (sill or dyke) It was concluded that the
16 times 16 window produced the best results overall and final plots were produced for the 16 times 16 window and structural
index 05 (Fig 44) Results were very good over the northern and central parts of the area showing magnetic sources
Figure 44 Depth to magnetic source 3D Euler deconvolution 16 times 16 window of 400 m gridded data structural index 05
56
at several different levels Unfortunately in the extreme south of the area shallow intrasedimentary magnetic sources
(sills and dykes) dominated the inversion and the results contained few basement solutions
In order to reduce these problems the 400 m gridded data were filtered using a separation filter based on
interpretation of the log-energy spectrum The 3D Euler method was run on the filtered data in order to generate more
basement-depth solutions Results for the deep-separation filter data were gridded and presented as a colour image in
Cowan (1995) Attempts to grid the Euler output were unsatisfactory and it is considered safer to interpret the 3D
Euler depth plots The 3D Euler depth results from the separation-filter run should be analysed with care as perfect
separation of the basement can never be achieved and there will always be some contamination from sources at
different levels
The results of original total magnetic intensity 3D Euler depth estimation for structural index 05 using a 16 point
window have been plotted at 1500 000 scale (not included in this publication but available in Cowan (1995) from the
GSWA Library as S10331) and as reduced A4 colour circle plots (Figure 44)
The results of deep-basement 3D Euler depth estimation for structural index 05 using a 16 point window have
been plotted as a colour image at 1500 000 scale and as an A4 image (not included in this publication)
2D analysis
Two equispaced profiles were interpolated with a 50 m station interval from the AGSO-located data profiles for the
BULLEN 1250 000 sheet The interpolated profiles were analysed using 2D Euler deconvolution and Werner
deconvolution Results are included in Cowan (1995) and show the use of these methods for more detailed analysis
Filtered data
In order to reconcile 3D Euler results from shallow basement and intrasedimentary magnetic sources we produced
several separation-filtered maps and images We found the shallow-layer double-separation filter (Figure 45) to be
very effective for shallow sources and the deep-layer standard-separation filter (Figure 46) for the basement layer
Gravity and magnetic data correlation
Both lsquoreduced to the polersquo (RTP) magnetics (Figure 47) and pseudo-gravity data (Figure 48) were produced as part of
the reconciliation of gravity and magnetic signatures In both cases the filtering operations assumed magnetization by
induction in the present Earths field The RTP data are fairly similar to the total magnetic intensity The pseudo-
57
gravity data are dominated by a northwest-trending strong positive anomaly and there is little correlation with the
Bouguer gravity data
The poor magneticgravity correlation is confirmed by cross-correlation of the RTP magnetics and the gravity
gradient The correlation plot in Figure 49 shows little coherent response with numerous zones of positive and
negative correlation
Figure 45 Regional aeromagnetic data shallow layer separation filter (BMRAGSO data) gridded at 400 m
Results
In the north and east of the area on the Wells Foreland Sub-basin trend (refer to Figure 1 main text) we see a range
of quite deep 3D Euler depths and several trend directions with north-northwesterly dominant There are relatively few
shallow intrasedimentary solutions in this zone
The second area of deep 3D Euler solutions lies over the Blake depocentre (Figure 43) with several trend
directions
Elsewhere the 3D Euler results are dominated by shallow intrasedimentary depth solutions reflecting mainly the
dolerite sills dykes and the ring complex However where we do see basement-related solutions in the south and
west of the area they appear to be shallower than those noted for the Wells Foreland Sub-basin and the Blake
depocentre
58
Figure 46 Regional aeromagnetic data deep-layer separation filter (BMRAGSO data) gridded at 400 m
Figure 48 Regional aeromagnetic data pseudo-gravity transform (BMRAGSO data) gridded at 400 m
Figure 47 Regional aeromagnetic data reduced-to-pole (BMRAGSO data) gridded at 400 m
Figure 49 Regional aeromagnetic and gravity data gravitymagnetic correlation using RTP magnetics and gravity gradient (BMRAGSO data) gridded at 4 km
59
This subdivision of the area into two zones of deep solutions is consistent with interpreted depocentres
However the interference between sources at different levels and the complexity of the magnetic response of the
basement rocks precludes more refined interpretation at this stage
The area of deep 3D Euler solutions over the Blake depocentre correlates with the pronounced negative gravity
anomaly discussed in the gravity interpretation section Using a density contrast of -015 gcc the negative gravity
anomaly could indicate up to 6ndash8 km of low-density sedimentary rocks depending on assumptions about the regional
field
The area of deep 3D Euler solutions over the Wells Foreland Sub-basin has a complex gravity expression and no
clear basin structure emerges from inversion of these data As noted previously it is likely that observed gravity
anomalies reflect contrasts in basement density rather than basement topography
Separation filtering applied to the magnetic data helps to enhance the intrasedimentary magnetic signature and to
give a better impression of the basement magnetic signature even though separation of the basement response is not
perfect
Conclusions
Quantitative aeromagnetic interpretation using 3D Euler deconvolution supported by wavenumber filtering and image
processing has been successful in providing structural trend and depth information for the Savory Sub-basin
Quantitative magnetic interpretation has revealed two zones of relatively deep magnetic basement beneath the
Wells Foreland Sub-basin and the Blake depocentre
This analysis of the magnetic data supports interpreted depocentres but the complexity of the basement magnetic
signature and interference from sources at different depths precludes further refinement to a map of basement
topography
Regional gravity proved to be very useful in understanding the regional setting of the area and in providing
support for aspects of the interpretation The gravity data support the interpretation of the Blake depocentre
suggesting up to 6ndash8 km of low-density sedimentary rocks
The deep structure of the Savory Sub-basin area is obviously complex with different areas underlain by
Archaean and Proterozoic basement and with the Capricorn suture occurring in the centre of the area
60
Recommendations
The quantitative magnetic interpretation needs to be reconciled with geological models available for the area
In particular the zones tentatively identified as areas with thick sedimentary rocks the Wells Foreland Sub-
basin and the Blake depocentre need to be investigated
Cross sections should be prepared across the basin for joint magneticgravity modelling especially for the Blake
depocentre It is important to be able to explain the strong negative gravity anomaly in this area
In view of the effects of basement density contrasts on the gravity field for the northern part of the area we think
that additional gravity interpretation and acquisition of new gravity data may not be justified as they will not
contribute significantly to understanding basin evolution and structure
It is recommended that GSWA try to get access to company confidential high-resolution aeromagnetic data
rather than flying new surveys The GSWA might offer to fund flying of new infill areas as a bargaining point
References
The original text of this report by Cowan (1995) and 1500 000 scale maps are filed in the GSWA Library under
S10331
COWAN D 1995 Savory Basin quantitative magnetic interpretation Western Australia Geological Survey S-series
S10331 (unpublished)
VACQUIER V STEENLAND N C HENDERSON R G and ZIETZ I 1951 Interpretation of aeromagnetic
maps The Geological Society of America Memoir 47 151p
WILLIAMS I R 1992 Geology of the Savory Basin Western Australia Western Australia Geological Survey
Bulletin 141 115p
61
Appendix 5
Geochemistry
MKS38 250398
Saturate FractionC12+ GLC
1217
Pr18
Ph
22
31CSR WELL-13 315m Cuttings
Figure 51 Canning Stock Route Well 13 gas chromatograph of extract of auger drill sample
12
17
18
22
31
Pr Ph
LDDH 1 6623m CoreSaturate FractionC12+ GLC
MKS35 240398
Figure 52 Gas chromatograph of extract from core sample at 6623 m LDDH1
62
Table 51 Canning Stock Route Well 13 auger drill samples
GSWA sample Drill depth (m)(a) Comments
135601 150 At watertable 135602 203 (all samples consist 135603 310 of sand mud and water) 135604 315 At total depth
NOTE (a) Datum for drill depth is the top of sediment fill in the well which is 155 m below ground level (ie the total depth of 315 m is 47 m below ground level)
Table 52 Canning Stock Route Well 13 gas chromatography data for 315 m depth sediment sample
Parameter Value
Weight of rock extracted (grams) 945 Total extract (ppm) 519 n-Alkane distribution n-C12 07 n-C13 23 n-C14 26 n-C15 22 n-C16 19 n-C17 14 i-C19 23 n-C18 14 i-C20 08 n-C19 11 n-C20 16 n-C21 25 n-C22 29 n-C23 70 n-C24 42 n-C25 95 n-C26 43 n-C27 83 n-C28 38 n-C29 87 n-C30 31 n-C31 273 Alkane compositional data Pristane phytane ratio 279 Pristane n-C17 ratio 161 Phytane n-C18 ratio 059 CPI (1)(a) 284 CPI (2) 209 (C21 + C22) (C28 + C29) 043
NOTE (a) CPI= Carbon preference index
63
Table 53 LDDH1 extract liquid chromatography data for 6623 m concentration
Rock extracted Total extract (grams) (ppm)
702 313
NOTE ppm= parts per million
Table 54 LDDH1 saturate gas chromatography data of core for 6623 m alkane composition
Pristane Pristane Phytane (a) CPI (1) CPI (2) (C21+C22) Phytane n-C17 n-C18 (C28+C29)
103 026 024 103 102 325
NOTE (a)CPI = carbon preference index
Table 55 LDDH1 saturate gas chromatography data of core for 6623 m n-alkane distributions
Parameter Value
n-C12 17 n-C13 38 n-C14 55 n-C15 60 n-C16 65 n-C17 74 i-C19 19 n-C18 78 i-C20 19 n-C19 80 n-C20 79 n-C21 71 n-C22 64 n-C23 57 n-C25 43 n-C24 38 n-C27 31 n-C28 23 n-C29 19 n-C30 12 n-C31 10
64
Appendix 6
Table 61 Summary of data from Trainor waterbores (TWB) and Bullen waterbores (BWB)
Well AMG Elevation TD Status(b) Completion details Water Salinity Water level Flow rate Depth to consolidated AGD84 GL (m) (m) struck mgl(c) (m) (LHr) lithology aquifer(e) Z51(a) Interval (m) (100 mm PVC) (m) (mgl)(d)
TWB 1 473660E 453 122 comp 0ndash75 plain 63 7 300 24 2 880 12 m 7287404N 75ndash93 slotted (9 260) McFadden Fm 93ndash99 plain TWB 2 472 977E 475 23 abd nil 15 m 7285877N Skates Hills Fm dry TWB 3 473259E 475 50 abd nil 7 m 7285849N Skates Hills Fm dry TWB 4 463225 E 445 50 comp 0ndash22 plain 35 7 200 55 3 600 0 m 7286143N 22ndash34 slotted (8 140) Tertiary sand and gravel 23ndash60 plain TWB 5 463095E 445 31 comp 0ndash19 plain 13 26 000 655 3 600 Tertiary sand and gravel 7277721N 19ndash25 slotted (36 700) 25ndash31 plain TWB 6 457013E 455 50 comp 0ndash42 plain 38 920 119 600 0 m 7274352N 42ndash48 slotted (1 030) Cornelia Fm ss TWB 7 453739E 475 26 susp 0ndash2 plain 11 9 300 48 4 500 0 m 7263891N (10 500) Tertiary sand TWB 8 433893E 535 60 susp 0ndash2 plain 47 8 500 gt46 1 200 0 m 7245991N (10 900) Tertiary sand and Brassey Range Fm ss TWB 9 437219E 505 51 comp 0ndash47 plain 45 1 000 58 600 1 m 7235905N 47ndash51 slotted (990) Brassey Range Fm ss TWB 10 434927E 495 32 susp 0ndash2 plain 235 450 120 0 m 7225875N (500) Dolerite
65
BWB 1 287337E 580 122 abd Nil 1 m 7245861N Jilyili Fm dry BWB 2 288346E 545 50 comp 0ndash26 plain 15 630 3 29 000 0 m 7240423N 26ndash38 slotted (730) Tertiary sand and gravel 38ndash50 plain BWB 3 305637E 545 50 abd 19 8 800 43 7 200 0 m 7240423N (10 550) Tertiary ss BWB 4 320167E 515 445 comp 0ndash20 plain 9 980 445 24 000 0 m 7248097N 20ndash32 slotted (1 190) Tertiary ss 32ndash44 plain BWB 5 353393E 545 20 susp 0ndash2 plain 45 (970) 1 m 7238934N Basalt
NOTES (a) GPS accuracy ~ 150 m (b) Comp = completed abd = abandoned susp = suspended (c) Salinity from conductivity (d) Analysis total dissolved solids (e) Fm = Formation ss = sandstone
49
constraints on source geometry and magnetization and by using geological and other geophysical data to constrain
the solution
Before 1970 most depth-determination techniques involved graphical determination of slopes of selected
magnetic anomalies and application of various empirical factors to convert the slopes into depth estimates Geological
Society of America Memoir 47 Interpretation of Aeromagnetic Maps by Vacquier et al (1951) was a landmark for
this type of interpretation
Automated interpretation procedures have played an increasingly important role in depth interpretation and a
wide range of techniques have been developed Many of these techniques are designed for application to located data
profiles and assume a two-dimensional geometry However there has been renewed interest in techniques applicable
to gridded data
Two distinct types of method can be recognized In the first case often described as discrete methods individual
isolated magnetic anomalies are interpreted and the results used to produce a map of basement relief In the second
case often described as continuous methods areas of data containing a number of anomalies are interpreted
statistically to produce direct output of basement depths
The discrete methods usually involve a semiautomatic initial phase which generates a large number of possible
depth solutions and an interactive second phase to screen and select acceptable solutions The advantage of this
approach is that the interpreter can select features that are relatively free from interference from adjacent anomalies
and consider all aspects of a particular magnetic anomaly The disadvantage is that interpretation can be very time
consuming as a wide range of depths are usually possible depending on the initial model chosen and a significant
amount of effort is needed to select the correct model In the case of the Savory Sub-basin dataset we encountered
problems in separating basement related effects from the effects of shallower intrasedimentary magnetic sources
Because of these problems we have concentrated on displaying the Euler results accompanied by separation filter
images of the data to show the shallower effects and deeper effects rather than trying to refine a 3D Euler
deconvolution depth-to-crystalline-basement contour
The continuous methods are very direct provided that the rather restrictive assumption can be made that all
anomalies are due to lateral magnetization changes due to basement topography This means that shallow effects and
large intrabasement anomalies must be removed from the data This involves judgement and skill as it is necessary to
distinguish between the lower amplitude suprabasement anomalies due to basement topography and the larger
intrabasement anomalies reflecting magnetization changes within the basement These methods were not considered
suitable for the Savory Sub-basin magnetic dataset but were used to invert the gravity data
50
Limitations of magnetic and gravity interpretation
Interpretation of the area is limited by a shortage of information on the nature and physical properties of the deeper
sedimentary sequence and the underlying basement rocks However using techniques such as cross-correlation of
gravity and pseudo-gravity data it is possible to try to differentiate between anomalies relating to basement and those
related to the sedimentary sequence
Gravity anomalies reflect changes within the sedimentary sequence as well as basement condition These
changes in density of sedimentary rocks produce gravity anomalies without a corresponding magnetic anomaly hence
the complementary nature of gravity and magnetic surveys The main use of magnetics is to determine depth to
magnetic basement and any intra-sedimentary volcanic rocks or intrusives whereas gravity provides much more
general information on the sedimentary sequence
Unfortunately interpretation of gravity anomalies is complicated since they can be due to a number of geological
features including
bull major basement faults
bull basement highs
bull igneous intrusions within the basement
bull sedimentary basins which may or may not be isostatically compensated
bull intra-sedimentary volcanics and associated plutonic centres
Two major problems affect the interpretation of both magnetic and gravity data
1 The inherent ambiguity of potential-field data There is no unique solution to any measured gravity or magnetic
anomaly and theoretically there will be an infinite number of source geometry and magnetizationdensity
combinations which will fit the observed data This means that any a priori information which helps to select a
suitable model is very useful
2 Measured anomalies are the summation of effects from different depths For example an observed gravity profile
may contain contributions from shallow sources (density variations within the sedimentary basin) intermediate
depth sources (density variations due to large igneous intrusions within the basement) and deep sources (crustal
thinning producing a mantle anomaly) Separation of these component responses is the regionalresidual problem
which we solve using spectral analysis and differential upward continuation-based separation filtering
Regional setting and interpretation overview
The area studied includes parts of BALFOUR DOWNS (SF51-9) RUDALL (SF51-10) ROBERTSON (SF51-13) GUNANYA
(SF51-14) COLLIER (SG50-4) BULLEN (SG51-1) TRAINOR (SG51-2) MADLEY (SG51-3) NABBERU (SG50-5)
STANLEY (SG51-6) and HERBERT (SG51-7) 1250 000 sheets Broadly the area lies between latitudes 22deg00rsquondash25deg30rsquoS
and longitudes 119deg30rsquondash123deg30rsquoE
51
Regional gravity
The AGSO regional gravity data (at nominal 11 km spacing) was gridded at a 4 km mesh spacing using a minimum-
curvature algorithm Bouguer gravity values in the area are negative reflecting mass deficiency at depth and range
from -84 mgals to -25 mgals
A Bouguer gravity colour image is shown as Figure 41 A residual grid was produced by removing a fifth-order
orthogonal polynomial from the Bouguer data but did not add to the interpretation
120deg 121deg 122deg 123deg
23deg
24deg
25deg
-25
-84
50 km
MKS46 180598
mgal
Figure 41 Regional Bouguer gravity (BMRAGSO data) gridded at 4 km
52
The data show a complex pattern of positive and negative anomalies with no clearly defined trends Correlations
with aeromagnetic data and known basin structures are poor A vague north-northwest linear trend appears to coincide
with the Marloo Fault (Figure 42) A prominent negative anomaly appears to coincide with the Blake Fold and Fault
Belt depocentre and continues as a narrower negative anomaly to the east until it widens out again near the edge of the
basin Elsewhere the gravity data show little correlation with known basin structures and it is likely that especially in
the north of the area gravity anomalies are due to density changes in the basement rather than changes in basement
topography
Production of wavelength-filtered residual gravity plots and vertical gradient plots showed very patchy aliased
data reflecting poor sampling in much of the area
Regional magnetics
The AGSO regional aeromagnetic data were gridded at a 400 m mesh spacing using a minimum-curvature algorithm
(Figure 43) Most of the data has a line spacing of 1600 m with small areas of 1 km spacing The quality of the data is
acceptable for regional interpretation but is not adequate for detailed analysis The accuracy of the flight path is rather
variable reflecting the vintage of the data and the noise envelope of the data is poor by modern standards Problems
were also encountered in joining different map sheets
The magnetic anomaly pattern over the south and west part of the area shows a strong high frequency signature
reflecting the presence of widespread basic sills and dykes Some of the major north-northeasterly trending dykes can
be traced over considerable distances
Discontinuous high-frequency anomalies extend as a northwest-trending zone through the centre of the area and
this zone includes a conspicuous circular magnetic anomaly which is probably a ring complex
The northern and eastern parts of the area are characterized by long-wavelength deep-seated basement magnetic
anomalies with 120deg and 150deg trends dominant The Marloo and Perentie Faults (Figure 42) appear as distinct linear
zones and offsets A prominent easterly trending negative anomaly in the northwest of the area appears to swing round
to the southeast and may separate different basement blocks One possible interpretation is that this very deep seated
anomaly separates areas of Archaean and Proterozoic basement
Regional geology
The regional geology is described in Williams (1992) The GSWA provided a digitized version of Plate 2 from this
Bulletin the structural interpretation map to use as an overlay (Figure 42)
53
Pp
Pp
PSd
PSd
PSd
PSd
PSd
PSo
PSt
PSt
PSf
PSf
PSf
PSb
PSb
PSb
PSsPSs
PSs
PSb
PSm
PSp
PSc
PSc
PSw
PSw
PSw
PSg
PSr
PSj
PSg
PM
Pk
PY
PY
PSd
L
L
L
L
L
L
L
LL
L
L
L
LL
L
LL
L L
LL
L L
L
L
L
L
L
L
L
LL
L
L
BLAKEDEPOCENTRE
MA
RLO
O
FAU
LT
PERENTIEFAULT
50 km
MKS39120598
120deg 121deg 122deg 123deg
25deg
24deg
23deg
Approximate boundaryof aeromagnetic interpretation
PML
PSgL
PSjL
PML
PSpL
PML
PML
PSfL
PSfL
PSpL
LPc
LPcLPcPSrL
LPA
Durba Sandstone
Woora Woora Formation
McFadden Formation
Tchukardine Formation
Boondawari Formation
Skates Hills Formation
Mundadjini Formation
Coondra Formation
Spearhole Formation
Watch Point Formation
Jilyili Formation
Brassey Range Formation
Glass Spring Formation
Paterson Formation
Yeneena Group
Karara Formation
Cornelia Formation
Kahrban Subgroup
Bangemall Group
Fault
Formation boundary
PSdL
PSoL
PSfL
PStL
PSbL
PSsL
PSmL
PScL
PSpL
PSwL
PSjL
PSrL
PSgL
Pp
PYL
PkL
LPc
LPA
PML
Savory Group Other Units
PYL
Figure 42 Regional geology and structure map (after Williams 1992)
54
120deg 121deg 122deg 123deg
23deg
24deg
25deg
5820
3750
MKS47 180598
nT
50 km
Figure 43 Regional aeromagnetic data total magnetic intensity (BMRAGSO data) gridded at 400 m
Analysis
3D analysis
3D Euler deconvolution was used as the primary depth-determination method The advantage of this approach is that
consistent solutions can be obtained over the entire area with minimal assumptions about source geometries Euler
deconvolution of gridded data is used for positional information and estimation of depth to top of source Euler
55
deconvolution yields a large number of depth solutions which have to be screened to reject spurious solutions Results
are plotted as circles in eight depth ranges with radius proportional to depth and colour coded
The 400 m total magnetic intensity grid was used for the analysis Horizontal gradients in x and y and the vertical
gradient were calculated 3D Euler deconvolution was tested on the 400 m gridded data using windows of 9 times 9 and
11 times 11 and 16 times 16 data points and structural indices 05 (fault) and 10 (sill or dyke) It was concluded that the
16 times 16 window produced the best results overall and final plots were produced for the 16 times 16 window and structural
index 05 (Fig 44) Results were very good over the northern and central parts of the area showing magnetic sources
Figure 44 Depth to magnetic source 3D Euler deconvolution 16 times 16 window of 400 m gridded data structural index 05
56
at several different levels Unfortunately in the extreme south of the area shallow intrasedimentary magnetic sources
(sills and dykes) dominated the inversion and the results contained few basement solutions
In order to reduce these problems the 400 m gridded data were filtered using a separation filter based on
interpretation of the log-energy spectrum The 3D Euler method was run on the filtered data in order to generate more
basement-depth solutions Results for the deep-separation filter data were gridded and presented as a colour image in
Cowan (1995) Attempts to grid the Euler output were unsatisfactory and it is considered safer to interpret the 3D
Euler depth plots The 3D Euler depth results from the separation-filter run should be analysed with care as perfect
separation of the basement can never be achieved and there will always be some contamination from sources at
different levels
The results of original total magnetic intensity 3D Euler depth estimation for structural index 05 using a 16 point
window have been plotted at 1500 000 scale (not included in this publication but available in Cowan (1995) from the
GSWA Library as S10331) and as reduced A4 colour circle plots (Figure 44)
The results of deep-basement 3D Euler depth estimation for structural index 05 using a 16 point window have
been plotted as a colour image at 1500 000 scale and as an A4 image (not included in this publication)
2D analysis
Two equispaced profiles were interpolated with a 50 m station interval from the AGSO-located data profiles for the
BULLEN 1250 000 sheet The interpolated profiles were analysed using 2D Euler deconvolution and Werner
deconvolution Results are included in Cowan (1995) and show the use of these methods for more detailed analysis
Filtered data
In order to reconcile 3D Euler results from shallow basement and intrasedimentary magnetic sources we produced
several separation-filtered maps and images We found the shallow-layer double-separation filter (Figure 45) to be
very effective for shallow sources and the deep-layer standard-separation filter (Figure 46) for the basement layer
Gravity and magnetic data correlation
Both lsquoreduced to the polersquo (RTP) magnetics (Figure 47) and pseudo-gravity data (Figure 48) were produced as part of
the reconciliation of gravity and magnetic signatures In both cases the filtering operations assumed magnetization by
induction in the present Earths field The RTP data are fairly similar to the total magnetic intensity The pseudo-
57
gravity data are dominated by a northwest-trending strong positive anomaly and there is little correlation with the
Bouguer gravity data
The poor magneticgravity correlation is confirmed by cross-correlation of the RTP magnetics and the gravity
gradient The correlation plot in Figure 49 shows little coherent response with numerous zones of positive and
negative correlation
Figure 45 Regional aeromagnetic data shallow layer separation filter (BMRAGSO data) gridded at 400 m
Results
In the north and east of the area on the Wells Foreland Sub-basin trend (refer to Figure 1 main text) we see a range
of quite deep 3D Euler depths and several trend directions with north-northwesterly dominant There are relatively few
shallow intrasedimentary solutions in this zone
The second area of deep 3D Euler solutions lies over the Blake depocentre (Figure 43) with several trend
directions
Elsewhere the 3D Euler results are dominated by shallow intrasedimentary depth solutions reflecting mainly the
dolerite sills dykes and the ring complex However where we do see basement-related solutions in the south and
west of the area they appear to be shallower than those noted for the Wells Foreland Sub-basin and the Blake
depocentre
58
Figure 46 Regional aeromagnetic data deep-layer separation filter (BMRAGSO data) gridded at 400 m
Figure 48 Regional aeromagnetic data pseudo-gravity transform (BMRAGSO data) gridded at 400 m
Figure 47 Regional aeromagnetic data reduced-to-pole (BMRAGSO data) gridded at 400 m
Figure 49 Regional aeromagnetic and gravity data gravitymagnetic correlation using RTP magnetics and gravity gradient (BMRAGSO data) gridded at 4 km
59
This subdivision of the area into two zones of deep solutions is consistent with interpreted depocentres
However the interference between sources at different levels and the complexity of the magnetic response of the
basement rocks precludes more refined interpretation at this stage
The area of deep 3D Euler solutions over the Blake depocentre correlates with the pronounced negative gravity
anomaly discussed in the gravity interpretation section Using a density contrast of -015 gcc the negative gravity
anomaly could indicate up to 6ndash8 km of low-density sedimentary rocks depending on assumptions about the regional
field
The area of deep 3D Euler solutions over the Wells Foreland Sub-basin has a complex gravity expression and no
clear basin structure emerges from inversion of these data As noted previously it is likely that observed gravity
anomalies reflect contrasts in basement density rather than basement topography
Separation filtering applied to the magnetic data helps to enhance the intrasedimentary magnetic signature and to
give a better impression of the basement magnetic signature even though separation of the basement response is not
perfect
Conclusions
Quantitative aeromagnetic interpretation using 3D Euler deconvolution supported by wavenumber filtering and image
processing has been successful in providing structural trend and depth information for the Savory Sub-basin
Quantitative magnetic interpretation has revealed two zones of relatively deep magnetic basement beneath the
Wells Foreland Sub-basin and the Blake depocentre
This analysis of the magnetic data supports interpreted depocentres but the complexity of the basement magnetic
signature and interference from sources at different depths precludes further refinement to a map of basement
topography
Regional gravity proved to be very useful in understanding the regional setting of the area and in providing
support for aspects of the interpretation The gravity data support the interpretation of the Blake depocentre
suggesting up to 6ndash8 km of low-density sedimentary rocks
The deep structure of the Savory Sub-basin area is obviously complex with different areas underlain by
Archaean and Proterozoic basement and with the Capricorn suture occurring in the centre of the area
60
Recommendations
The quantitative magnetic interpretation needs to be reconciled with geological models available for the area
In particular the zones tentatively identified as areas with thick sedimentary rocks the Wells Foreland Sub-
basin and the Blake depocentre need to be investigated
Cross sections should be prepared across the basin for joint magneticgravity modelling especially for the Blake
depocentre It is important to be able to explain the strong negative gravity anomaly in this area
In view of the effects of basement density contrasts on the gravity field for the northern part of the area we think
that additional gravity interpretation and acquisition of new gravity data may not be justified as they will not
contribute significantly to understanding basin evolution and structure
It is recommended that GSWA try to get access to company confidential high-resolution aeromagnetic data
rather than flying new surveys The GSWA might offer to fund flying of new infill areas as a bargaining point
References
The original text of this report by Cowan (1995) and 1500 000 scale maps are filed in the GSWA Library under
S10331
COWAN D 1995 Savory Basin quantitative magnetic interpretation Western Australia Geological Survey S-series
S10331 (unpublished)
VACQUIER V STEENLAND N C HENDERSON R G and ZIETZ I 1951 Interpretation of aeromagnetic
maps The Geological Society of America Memoir 47 151p
WILLIAMS I R 1992 Geology of the Savory Basin Western Australia Western Australia Geological Survey
Bulletin 141 115p
61
Appendix 5
Geochemistry
MKS38 250398
Saturate FractionC12+ GLC
1217
Pr18
Ph
22
31CSR WELL-13 315m Cuttings
Figure 51 Canning Stock Route Well 13 gas chromatograph of extract of auger drill sample
12
17
18
22
31
Pr Ph
LDDH 1 6623m CoreSaturate FractionC12+ GLC
MKS35 240398
Figure 52 Gas chromatograph of extract from core sample at 6623 m LDDH1
62
Table 51 Canning Stock Route Well 13 auger drill samples
GSWA sample Drill depth (m)(a) Comments
135601 150 At watertable 135602 203 (all samples consist 135603 310 of sand mud and water) 135604 315 At total depth
NOTE (a) Datum for drill depth is the top of sediment fill in the well which is 155 m below ground level (ie the total depth of 315 m is 47 m below ground level)
Table 52 Canning Stock Route Well 13 gas chromatography data for 315 m depth sediment sample
Parameter Value
Weight of rock extracted (grams) 945 Total extract (ppm) 519 n-Alkane distribution n-C12 07 n-C13 23 n-C14 26 n-C15 22 n-C16 19 n-C17 14 i-C19 23 n-C18 14 i-C20 08 n-C19 11 n-C20 16 n-C21 25 n-C22 29 n-C23 70 n-C24 42 n-C25 95 n-C26 43 n-C27 83 n-C28 38 n-C29 87 n-C30 31 n-C31 273 Alkane compositional data Pristane phytane ratio 279 Pristane n-C17 ratio 161 Phytane n-C18 ratio 059 CPI (1)(a) 284 CPI (2) 209 (C21 + C22) (C28 + C29) 043
NOTE (a) CPI= Carbon preference index
63
Table 53 LDDH1 extract liquid chromatography data for 6623 m concentration
Rock extracted Total extract (grams) (ppm)
702 313
NOTE ppm= parts per million
Table 54 LDDH1 saturate gas chromatography data of core for 6623 m alkane composition
Pristane Pristane Phytane (a) CPI (1) CPI (2) (C21+C22) Phytane n-C17 n-C18 (C28+C29)
103 026 024 103 102 325
NOTE (a)CPI = carbon preference index
Table 55 LDDH1 saturate gas chromatography data of core for 6623 m n-alkane distributions
Parameter Value
n-C12 17 n-C13 38 n-C14 55 n-C15 60 n-C16 65 n-C17 74 i-C19 19 n-C18 78 i-C20 19 n-C19 80 n-C20 79 n-C21 71 n-C22 64 n-C23 57 n-C25 43 n-C24 38 n-C27 31 n-C28 23 n-C29 19 n-C30 12 n-C31 10
64
Appendix 6
Table 61 Summary of data from Trainor waterbores (TWB) and Bullen waterbores (BWB)
Well AMG Elevation TD Status(b) Completion details Water Salinity Water level Flow rate Depth to consolidated AGD84 GL (m) (m) struck mgl(c) (m) (LHr) lithology aquifer(e) Z51(a) Interval (m) (100 mm PVC) (m) (mgl)(d)
TWB 1 473660E 453 122 comp 0ndash75 plain 63 7 300 24 2 880 12 m 7287404N 75ndash93 slotted (9 260) McFadden Fm 93ndash99 plain TWB 2 472 977E 475 23 abd nil 15 m 7285877N Skates Hills Fm dry TWB 3 473259E 475 50 abd nil 7 m 7285849N Skates Hills Fm dry TWB 4 463225 E 445 50 comp 0ndash22 plain 35 7 200 55 3 600 0 m 7286143N 22ndash34 slotted (8 140) Tertiary sand and gravel 23ndash60 plain TWB 5 463095E 445 31 comp 0ndash19 plain 13 26 000 655 3 600 Tertiary sand and gravel 7277721N 19ndash25 slotted (36 700) 25ndash31 plain TWB 6 457013E 455 50 comp 0ndash42 plain 38 920 119 600 0 m 7274352N 42ndash48 slotted (1 030) Cornelia Fm ss TWB 7 453739E 475 26 susp 0ndash2 plain 11 9 300 48 4 500 0 m 7263891N (10 500) Tertiary sand TWB 8 433893E 535 60 susp 0ndash2 plain 47 8 500 gt46 1 200 0 m 7245991N (10 900) Tertiary sand and Brassey Range Fm ss TWB 9 437219E 505 51 comp 0ndash47 plain 45 1 000 58 600 1 m 7235905N 47ndash51 slotted (990) Brassey Range Fm ss TWB 10 434927E 495 32 susp 0ndash2 plain 235 450 120 0 m 7225875N (500) Dolerite
65
BWB 1 287337E 580 122 abd Nil 1 m 7245861N Jilyili Fm dry BWB 2 288346E 545 50 comp 0ndash26 plain 15 630 3 29 000 0 m 7240423N 26ndash38 slotted (730) Tertiary sand and gravel 38ndash50 plain BWB 3 305637E 545 50 abd 19 8 800 43 7 200 0 m 7240423N (10 550) Tertiary ss BWB 4 320167E 515 445 comp 0ndash20 plain 9 980 445 24 000 0 m 7248097N 20ndash32 slotted (1 190) Tertiary ss 32ndash44 plain BWB 5 353393E 545 20 susp 0ndash2 plain 45 (970) 1 m 7238934N Basalt
NOTES (a) GPS accuracy ~ 150 m (b) Comp = completed abd = abandoned susp = suspended (c) Salinity from conductivity (d) Analysis total dissolved solids (e) Fm = Formation ss = sandstone
50
Limitations of magnetic and gravity interpretation
Interpretation of the area is limited by a shortage of information on the nature and physical properties of the deeper
sedimentary sequence and the underlying basement rocks However using techniques such as cross-correlation of
gravity and pseudo-gravity data it is possible to try to differentiate between anomalies relating to basement and those
related to the sedimentary sequence
Gravity anomalies reflect changes within the sedimentary sequence as well as basement condition These
changes in density of sedimentary rocks produce gravity anomalies without a corresponding magnetic anomaly hence
the complementary nature of gravity and magnetic surveys The main use of magnetics is to determine depth to
magnetic basement and any intra-sedimentary volcanic rocks or intrusives whereas gravity provides much more
general information on the sedimentary sequence
Unfortunately interpretation of gravity anomalies is complicated since they can be due to a number of geological
features including
bull major basement faults
bull basement highs
bull igneous intrusions within the basement
bull sedimentary basins which may or may not be isostatically compensated
bull intra-sedimentary volcanics and associated plutonic centres
Two major problems affect the interpretation of both magnetic and gravity data
1 The inherent ambiguity of potential-field data There is no unique solution to any measured gravity or magnetic
anomaly and theoretically there will be an infinite number of source geometry and magnetizationdensity
combinations which will fit the observed data This means that any a priori information which helps to select a
suitable model is very useful
2 Measured anomalies are the summation of effects from different depths For example an observed gravity profile
may contain contributions from shallow sources (density variations within the sedimentary basin) intermediate
depth sources (density variations due to large igneous intrusions within the basement) and deep sources (crustal
thinning producing a mantle anomaly) Separation of these component responses is the regionalresidual problem
which we solve using spectral analysis and differential upward continuation-based separation filtering
Regional setting and interpretation overview
The area studied includes parts of BALFOUR DOWNS (SF51-9) RUDALL (SF51-10) ROBERTSON (SF51-13) GUNANYA
(SF51-14) COLLIER (SG50-4) BULLEN (SG51-1) TRAINOR (SG51-2) MADLEY (SG51-3) NABBERU (SG50-5)
STANLEY (SG51-6) and HERBERT (SG51-7) 1250 000 sheets Broadly the area lies between latitudes 22deg00rsquondash25deg30rsquoS
and longitudes 119deg30rsquondash123deg30rsquoE
51
Regional gravity
The AGSO regional gravity data (at nominal 11 km spacing) was gridded at a 4 km mesh spacing using a minimum-
curvature algorithm Bouguer gravity values in the area are negative reflecting mass deficiency at depth and range
from -84 mgals to -25 mgals
A Bouguer gravity colour image is shown as Figure 41 A residual grid was produced by removing a fifth-order
orthogonal polynomial from the Bouguer data but did not add to the interpretation
120deg 121deg 122deg 123deg
23deg
24deg
25deg
-25
-84
50 km
MKS46 180598
mgal
Figure 41 Regional Bouguer gravity (BMRAGSO data) gridded at 4 km
52
The data show a complex pattern of positive and negative anomalies with no clearly defined trends Correlations
with aeromagnetic data and known basin structures are poor A vague north-northwest linear trend appears to coincide
with the Marloo Fault (Figure 42) A prominent negative anomaly appears to coincide with the Blake Fold and Fault
Belt depocentre and continues as a narrower negative anomaly to the east until it widens out again near the edge of the
basin Elsewhere the gravity data show little correlation with known basin structures and it is likely that especially in
the north of the area gravity anomalies are due to density changes in the basement rather than changes in basement
topography
Production of wavelength-filtered residual gravity plots and vertical gradient plots showed very patchy aliased
data reflecting poor sampling in much of the area
Regional magnetics
The AGSO regional aeromagnetic data were gridded at a 400 m mesh spacing using a minimum-curvature algorithm
(Figure 43) Most of the data has a line spacing of 1600 m with small areas of 1 km spacing The quality of the data is
acceptable for regional interpretation but is not adequate for detailed analysis The accuracy of the flight path is rather
variable reflecting the vintage of the data and the noise envelope of the data is poor by modern standards Problems
were also encountered in joining different map sheets
The magnetic anomaly pattern over the south and west part of the area shows a strong high frequency signature
reflecting the presence of widespread basic sills and dykes Some of the major north-northeasterly trending dykes can
be traced over considerable distances
Discontinuous high-frequency anomalies extend as a northwest-trending zone through the centre of the area and
this zone includes a conspicuous circular magnetic anomaly which is probably a ring complex
The northern and eastern parts of the area are characterized by long-wavelength deep-seated basement magnetic
anomalies with 120deg and 150deg trends dominant The Marloo and Perentie Faults (Figure 42) appear as distinct linear
zones and offsets A prominent easterly trending negative anomaly in the northwest of the area appears to swing round
to the southeast and may separate different basement blocks One possible interpretation is that this very deep seated
anomaly separates areas of Archaean and Proterozoic basement
Regional geology
The regional geology is described in Williams (1992) The GSWA provided a digitized version of Plate 2 from this
Bulletin the structural interpretation map to use as an overlay (Figure 42)
53
Pp
Pp
PSd
PSd
PSd
PSd
PSd
PSo
PSt
PSt
PSf
PSf
PSf
PSb
PSb
PSb
PSsPSs
PSs
PSb
PSm
PSp
PSc
PSc
PSw
PSw
PSw
PSg
PSr
PSj
PSg
PM
Pk
PY
PY
PSd
L
L
L
L
L
L
L
LL
L
L
L
LL
L
LL
L L
LL
L L
L
L
L
L
L
L
L
LL
L
L
BLAKEDEPOCENTRE
MA
RLO
O
FAU
LT
PERENTIEFAULT
50 km
MKS39120598
120deg 121deg 122deg 123deg
25deg
24deg
23deg
Approximate boundaryof aeromagnetic interpretation
PML
PSgL
PSjL
PML
PSpL
PML
PML
PSfL
PSfL
PSpL
LPc
LPcLPcPSrL
LPA
Durba Sandstone
Woora Woora Formation
McFadden Formation
Tchukardine Formation
Boondawari Formation
Skates Hills Formation
Mundadjini Formation
Coondra Formation
Spearhole Formation
Watch Point Formation
Jilyili Formation
Brassey Range Formation
Glass Spring Formation
Paterson Formation
Yeneena Group
Karara Formation
Cornelia Formation
Kahrban Subgroup
Bangemall Group
Fault
Formation boundary
PSdL
PSoL
PSfL
PStL
PSbL
PSsL
PSmL
PScL
PSpL
PSwL
PSjL
PSrL
PSgL
Pp
PYL
PkL
LPc
LPA
PML
Savory Group Other Units
PYL
Figure 42 Regional geology and structure map (after Williams 1992)
54
120deg 121deg 122deg 123deg
23deg
24deg
25deg
5820
3750
MKS47 180598
nT
50 km
Figure 43 Regional aeromagnetic data total magnetic intensity (BMRAGSO data) gridded at 400 m
Analysis
3D analysis
3D Euler deconvolution was used as the primary depth-determination method The advantage of this approach is that
consistent solutions can be obtained over the entire area with minimal assumptions about source geometries Euler
deconvolution of gridded data is used for positional information and estimation of depth to top of source Euler
55
deconvolution yields a large number of depth solutions which have to be screened to reject spurious solutions Results
are plotted as circles in eight depth ranges with radius proportional to depth and colour coded
The 400 m total magnetic intensity grid was used for the analysis Horizontal gradients in x and y and the vertical
gradient were calculated 3D Euler deconvolution was tested on the 400 m gridded data using windows of 9 times 9 and
11 times 11 and 16 times 16 data points and structural indices 05 (fault) and 10 (sill or dyke) It was concluded that the
16 times 16 window produced the best results overall and final plots were produced for the 16 times 16 window and structural
index 05 (Fig 44) Results were very good over the northern and central parts of the area showing magnetic sources
Figure 44 Depth to magnetic source 3D Euler deconvolution 16 times 16 window of 400 m gridded data structural index 05
56
at several different levels Unfortunately in the extreme south of the area shallow intrasedimentary magnetic sources
(sills and dykes) dominated the inversion and the results contained few basement solutions
In order to reduce these problems the 400 m gridded data were filtered using a separation filter based on
interpretation of the log-energy spectrum The 3D Euler method was run on the filtered data in order to generate more
basement-depth solutions Results for the deep-separation filter data were gridded and presented as a colour image in
Cowan (1995) Attempts to grid the Euler output were unsatisfactory and it is considered safer to interpret the 3D
Euler depth plots The 3D Euler depth results from the separation-filter run should be analysed with care as perfect
separation of the basement can never be achieved and there will always be some contamination from sources at
different levels
The results of original total magnetic intensity 3D Euler depth estimation for structural index 05 using a 16 point
window have been plotted at 1500 000 scale (not included in this publication but available in Cowan (1995) from the
GSWA Library as S10331) and as reduced A4 colour circle plots (Figure 44)
The results of deep-basement 3D Euler depth estimation for structural index 05 using a 16 point window have
been plotted as a colour image at 1500 000 scale and as an A4 image (not included in this publication)
2D analysis
Two equispaced profiles were interpolated with a 50 m station interval from the AGSO-located data profiles for the
BULLEN 1250 000 sheet The interpolated profiles were analysed using 2D Euler deconvolution and Werner
deconvolution Results are included in Cowan (1995) and show the use of these methods for more detailed analysis
Filtered data
In order to reconcile 3D Euler results from shallow basement and intrasedimentary magnetic sources we produced
several separation-filtered maps and images We found the shallow-layer double-separation filter (Figure 45) to be
very effective for shallow sources and the deep-layer standard-separation filter (Figure 46) for the basement layer
Gravity and magnetic data correlation
Both lsquoreduced to the polersquo (RTP) magnetics (Figure 47) and pseudo-gravity data (Figure 48) were produced as part of
the reconciliation of gravity and magnetic signatures In both cases the filtering operations assumed magnetization by
induction in the present Earths field The RTP data are fairly similar to the total magnetic intensity The pseudo-
57
gravity data are dominated by a northwest-trending strong positive anomaly and there is little correlation with the
Bouguer gravity data
The poor magneticgravity correlation is confirmed by cross-correlation of the RTP magnetics and the gravity
gradient The correlation plot in Figure 49 shows little coherent response with numerous zones of positive and
negative correlation
Figure 45 Regional aeromagnetic data shallow layer separation filter (BMRAGSO data) gridded at 400 m
Results
In the north and east of the area on the Wells Foreland Sub-basin trend (refer to Figure 1 main text) we see a range
of quite deep 3D Euler depths and several trend directions with north-northwesterly dominant There are relatively few
shallow intrasedimentary solutions in this zone
The second area of deep 3D Euler solutions lies over the Blake depocentre (Figure 43) with several trend
directions
Elsewhere the 3D Euler results are dominated by shallow intrasedimentary depth solutions reflecting mainly the
dolerite sills dykes and the ring complex However where we do see basement-related solutions in the south and
west of the area they appear to be shallower than those noted for the Wells Foreland Sub-basin and the Blake
depocentre
58
Figure 46 Regional aeromagnetic data deep-layer separation filter (BMRAGSO data) gridded at 400 m
Figure 48 Regional aeromagnetic data pseudo-gravity transform (BMRAGSO data) gridded at 400 m
Figure 47 Regional aeromagnetic data reduced-to-pole (BMRAGSO data) gridded at 400 m
Figure 49 Regional aeromagnetic and gravity data gravitymagnetic correlation using RTP magnetics and gravity gradient (BMRAGSO data) gridded at 4 km
59
This subdivision of the area into two zones of deep solutions is consistent with interpreted depocentres
However the interference between sources at different levels and the complexity of the magnetic response of the
basement rocks precludes more refined interpretation at this stage
The area of deep 3D Euler solutions over the Blake depocentre correlates with the pronounced negative gravity
anomaly discussed in the gravity interpretation section Using a density contrast of -015 gcc the negative gravity
anomaly could indicate up to 6ndash8 km of low-density sedimentary rocks depending on assumptions about the regional
field
The area of deep 3D Euler solutions over the Wells Foreland Sub-basin has a complex gravity expression and no
clear basin structure emerges from inversion of these data As noted previously it is likely that observed gravity
anomalies reflect contrasts in basement density rather than basement topography
Separation filtering applied to the magnetic data helps to enhance the intrasedimentary magnetic signature and to
give a better impression of the basement magnetic signature even though separation of the basement response is not
perfect
Conclusions
Quantitative aeromagnetic interpretation using 3D Euler deconvolution supported by wavenumber filtering and image
processing has been successful in providing structural trend and depth information for the Savory Sub-basin
Quantitative magnetic interpretation has revealed two zones of relatively deep magnetic basement beneath the
Wells Foreland Sub-basin and the Blake depocentre
This analysis of the magnetic data supports interpreted depocentres but the complexity of the basement magnetic
signature and interference from sources at different depths precludes further refinement to a map of basement
topography
Regional gravity proved to be very useful in understanding the regional setting of the area and in providing
support for aspects of the interpretation The gravity data support the interpretation of the Blake depocentre
suggesting up to 6ndash8 km of low-density sedimentary rocks
The deep structure of the Savory Sub-basin area is obviously complex with different areas underlain by
Archaean and Proterozoic basement and with the Capricorn suture occurring in the centre of the area
60
Recommendations
The quantitative magnetic interpretation needs to be reconciled with geological models available for the area
In particular the zones tentatively identified as areas with thick sedimentary rocks the Wells Foreland Sub-
basin and the Blake depocentre need to be investigated
Cross sections should be prepared across the basin for joint magneticgravity modelling especially for the Blake
depocentre It is important to be able to explain the strong negative gravity anomaly in this area
In view of the effects of basement density contrasts on the gravity field for the northern part of the area we think
that additional gravity interpretation and acquisition of new gravity data may not be justified as they will not
contribute significantly to understanding basin evolution and structure
It is recommended that GSWA try to get access to company confidential high-resolution aeromagnetic data
rather than flying new surveys The GSWA might offer to fund flying of new infill areas as a bargaining point
References
The original text of this report by Cowan (1995) and 1500 000 scale maps are filed in the GSWA Library under
S10331
COWAN D 1995 Savory Basin quantitative magnetic interpretation Western Australia Geological Survey S-series
S10331 (unpublished)
VACQUIER V STEENLAND N C HENDERSON R G and ZIETZ I 1951 Interpretation of aeromagnetic
maps The Geological Society of America Memoir 47 151p
WILLIAMS I R 1992 Geology of the Savory Basin Western Australia Western Australia Geological Survey
Bulletin 141 115p
61
Appendix 5
Geochemistry
MKS38 250398
Saturate FractionC12+ GLC
1217
Pr18
Ph
22
31CSR WELL-13 315m Cuttings
Figure 51 Canning Stock Route Well 13 gas chromatograph of extract of auger drill sample
12
17
18
22
31
Pr Ph
LDDH 1 6623m CoreSaturate FractionC12+ GLC
MKS35 240398
Figure 52 Gas chromatograph of extract from core sample at 6623 m LDDH1
62
Table 51 Canning Stock Route Well 13 auger drill samples
GSWA sample Drill depth (m)(a) Comments
135601 150 At watertable 135602 203 (all samples consist 135603 310 of sand mud and water) 135604 315 At total depth
NOTE (a) Datum for drill depth is the top of sediment fill in the well which is 155 m below ground level (ie the total depth of 315 m is 47 m below ground level)
Table 52 Canning Stock Route Well 13 gas chromatography data for 315 m depth sediment sample
Parameter Value
Weight of rock extracted (grams) 945 Total extract (ppm) 519 n-Alkane distribution n-C12 07 n-C13 23 n-C14 26 n-C15 22 n-C16 19 n-C17 14 i-C19 23 n-C18 14 i-C20 08 n-C19 11 n-C20 16 n-C21 25 n-C22 29 n-C23 70 n-C24 42 n-C25 95 n-C26 43 n-C27 83 n-C28 38 n-C29 87 n-C30 31 n-C31 273 Alkane compositional data Pristane phytane ratio 279 Pristane n-C17 ratio 161 Phytane n-C18 ratio 059 CPI (1)(a) 284 CPI (2) 209 (C21 + C22) (C28 + C29) 043
NOTE (a) CPI= Carbon preference index
63
Table 53 LDDH1 extract liquid chromatography data for 6623 m concentration
Rock extracted Total extract (grams) (ppm)
702 313
NOTE ppm= parts per million
Table 54 LDDH1 saturate gas chromatography data of core for 6623 m alkane composition
Pristane Pristane Phytane (a) CPI (1) CPI (2) (C21+C22) Phytane n-C17 n-C18 (C28+C29)
103 026 024 103 102 325
NOTE (a)CPI = carbon preference index
Table 55 LDDH1 saturate gas chromatography data of core for 6623 m n-alkane distributions
Parameter Value
n-C12 17 n-C13 38 n-C14 55 n-C15 60 n-C16 65 n-C17 74 i-C19 19 n-C18 78 i-C20 19 n-C19 80 n-C20 79 n-C21 71 n-C22 64 n-C23 57 n-C25 43 n-C24 38 n-C27 31 n-C28 23 n-C29 19 n-C30 12 n-C31 10
64
Appendix 6
Table 61 Summary of data from Trainor waterbores (TWB) and Bullen waterbores (BWB)
Well AMG Elevation TD Status(b) Completion details Water Salinity Water level Flow rate Depth to consolidated AGD84 GL (m) (m) struck mgl(c) (m) (LHr) lithology aquifer(e) Z51(a) Interval (m) (100 mm PVC) (m) (mgl)(d)
TWB 1 473660E 453 122 comp 0ndash75 plain 63 7 300 24 2 880 12 m 7287404N 75ndash93 slotted (9 260) McFadden Fm 93ndash99 plain TWB 2 472 977E 475 23 abd nil 15 m 7285877N Skates Hills Fm dry TWB 3 473259E 475 50 abd nil 7 m 7285849N Skates Hills Fm dry TWB 4 463225 E 445 50 comp 0ndash22 plain 35 7 200 55 3 600 0 m 7286143N 22ndash34 slotted (8 140) Tertiary sand and gravel 23ndash60 plain TWB 5 463095E 445 31 comp 0ndash19 plain 13 26 000 655 3 600 Tertiary sand and gravel 7277721N 19ndash25 slotted (36 700) 25ndash31 plain TWB 6 457013E 455 50 comp 0ndash42 plain 38 920 119 600 0 m 7274352N 42ndash48 slotted (1 030) Cornelia Fm ss TWB 7 453739E 475 26 susp 0ndash2 plain 11 9 300 48 4 500 0 m 7263891N (10 500) Tertiary sand TWB 8 433893E 535 60 susp 0ndash2 plain 47 8 500 gt46 1 200 0 m 7245991N (10 900) Tertiary sand and Brassey Range Fm ss TWB 9 437219E 505 51 comp 0ndash47 plain 45 1 000 58 600 1 m 7235905N 47ndash51 slotted (990) Brassey Range Fm ss TWB 10 434927E 495 32 susp 0ndash2 plain 235 450 120 0 m 7225875N (500) Dolerite
65
BWB 1 287337E 580 122 abd Nil 1 m 7245861N Jilyili Fm dry BWB 2 288346E 545 50 comp 0ndash26 plain 15 630 3 29 000 0 m 7240423N 26ndash38 slotted (730) Tertiary sand and gravel 38ndash50 plain BWB 3 305637E 545 50 abd 19 8 800 43 7 200 0 m 7240423N (10 550) Tertiary ss BWB 4 320167E 515 445 comp 0ndash20 plain 9 980 445 24 000 0 m 7248097N 20ndash32 slotted (1 190) Tertiary ss 32ndash44 plain BWB 5 353393E 545 20 susp 0ndash2 plain 45 (970) 1 m 7238934N Basalt
NOTES (a) GPS accuracy ~ 150 m (b) Comp = completed abd = abandoned susp = suspended (c) Salinity from conductivity (d) Analysis total dissolved solids (e) Fm = Formation ss = sandstone
51
Regional gravity
The AGSO regional gravity data (at nominal 11 km spacing) was gridded at a 4 km mesh spacing using a minimum-
curvature algorithm Bouguer gravity values in the area are negative reflecting mass deficiency at depth and range
from -84 mgals to -25 mgals
A Bouguer gravity colour image is shown as Figure 41 A residual grid was produced by removing a fifth-order
orthogonal polynomial from the Bouguer data but did not add to the interpretation
120deg 121deg 122deg 123deg
23deg
24deg
25deg
-25
-84
50 km
MKS46 180598
mgal
Figure 41 Regional Bouguer gravity (BMRAGSO data) gridded at 4 km
52
The data show a complex pattern of positive and negative anomalies with no clearly defined trends Correlations
with aeromagnetic data and known basin structures are poor A vague north-northwest linear trend appears to coincide
with the Marloo Fault (Figure 42) A prominent negative anomaly appears to coincide with the Blake Fold and Fault
Belt depocentre and continues as a narrower negative anomaly to the east until it widens out again near the edge of the
basin Elsewhere the gravity data show little correlation with known basin structures and it is likely that especially in
the north of the area gravity anomalies are due to density changes in the basement rather than changes in basement
topography
Production of wavelength-filtered residual gravity plots and vertical gradient plots showed very patchy aliased
data reflecting poor sampling in much of the area
Regional magnetics
The AGSO regional aeromagnetic data were gridded at a 400 m mesh spacing using a minimum-curvature algorithm
(Figure 43) Most of the data has a line spacing of 1600 m with small areas of 1 km spacing The quality of the data is
acceptable for regional interpretation but is not adequate for detailed analysis The accuracy of the flight path is rather
variable reflecting the vintage of the data and the noise envelope of the data is poor by modern standards Problems
were also encountered in joining different map sheets
The magnetic anomaly pattern over the south and west part of the area shows a strong high frequency signature
reflecting the presence of widespread basic sills and dykes Some of the major north-northeasterly trending dykes can
be traced over considerable distances
Discontinuous high-frequency anomalies extend as a northwest-trending zone through the centre of the area and
this zone includes a conspicuous circular magnetic anomaly which is probably a ring complex
The northern and eastern parts of the area are characterized by long-wavelength deep-seated basement magnetic
anomalies with 120deg and 150deg trends dominant The Marloo and Perentie Faults (Figure 42) appear as distinct linear
zones and offsets A prominent easterly trending negative anomaly in the northwest of the area appears to swing round
to the southeast and may separate different basement blocks One possible interpretation is that this very deep seated
anomaly separates areas of Archaean and Proterozoic basement
Regional geology
The regional geology is described in Williams (1992) The GSWA provided a digitized version of Plate 2 from this
Bulletin the structural interpretation map to use as an overlay (Figure 42)
53
Pp
Pp
PSd
PSd
PSd
PSd
PSd
PSo
PSt
PSt
PSf
PSf
PSf
PSb
PSb
PSb
PSsPSs
PSs
PSb
PSm
PSp
PSc
PSc
PSw
PSw
PSw
PSg
PSr
PSj
PSg
PM
Pk
PY
PY
PSd
L
L
L
L
L
L
L
LL
L
L
L
LL
L
LL
L L
LL
L L
L
L
L
L
L
L
L
LL
L
L
BLAKEDEPOCENTRE
MA
RLO
O
FAU
LT
PERENTIEFAULT
50 km
MKS39120598
120deg 121deg 122deg 123deg
25deg
24deg
23deg
Approximate boundaryof aeromagnetic interpretation
PML
PSgL
PSjL
PML
PSpL
PML
PML
PSfL
PSfL
PSpL
LPc
LPcLPcPSrL
LPA
Durba Sandstone
Woora Woora Formation
McFadden Formation
Tchukardine Formation
Boondawari Formation
Skates Hills Formation
Mundadjini Formation
Coondra Formation
Spearhole Formation
Watch Point Formation
Jilyili Formation
Brassey Range Formation
Glass Spring Formation
Paterson Formation
Yeneena Group
Karara Formation
Cornelia Formation
Kahrban Subgroup
Bangemall Group
Fault
Formation boundary
PSdL
PSoL
PSfL
PStL
PSbL
PSsL
PSmL
PScL
PSpL
PSwL
PSjL
PSrL
PSgL
Pp
PYL
PkL
LPc
LPA
PML
Savory Group Other Units
PYL
Figure 42 Regional geology and structure map (after Williams 1992)
54
120deg 121deg 122deg 123deg
23deg
24deg
25deg
5820
3750
MKS47 180598
nT
50 km
Figure 43 Regional aeromagnetic data total magnetic intensity (BMRAGSO data) gridded at 400 m
Analysis
3D analysis
3D Euler deconvolution was used as the primary depth-determination method The advantage of this approach is that
consistent solutions can be obtained over the entire area with minimal assumptions about source geometries Euler
deconvolution of gridded data is used for positional information and estimation of depth to top of source Euler
55
deconvolution yields a large number of depth solutions which have to be screened to reject spurious solutions Results
are plotted as circles in eight depth ranges with radius proportional to depth and colour coded
The 400 m total magnetic intensity grid was used for the analysis Horizontal gradients in x and y and the vertical
gradient were calculated 3D Euler deconvolution was tested on the 400 m gridded data using windows of 9 times 9 and
11 times 11 and 16 times 16 data points and structural indices 05 (fault) and 10 (sill or dyke) It was concluded that the
16 times 16 window produced the best results overall and final plots were produced for the 16 times 16 window and structural
index 05 (Fig 44) Results were very good over the northern and central parts of the area showing magnetic sources
Figure 44 Depth to magnetic source 3D Euler deconvolution 16 times 16 window of 400 m gridded data structural index 05
56
at several different levels Unfortunately in the extreme south of the area shallow intrasedimentary magnetic sources
(sills and dykes) dominated the inversion and the results contained few basement solutions
In order to reduce these problems the 400 m gridded data were filtered using a separation filter based on
interpretation of the log-energy spectrum The 3D Euler method was run on the filtered data in order to generate more
basement-depth solutions Results for the deep-separation filter data were gridded and presented as a colour image in
Cowan (1995) Attempts to grid the Euler output were unsatisfactory and it is considered safer to interpret the 3D
Euler depth plots The 3D Euler depth results from the separation-filter run should be analysed with care as perfect
separation of the basement can never be achieved and there will always be some contamination from sources at
different levels
The results of original total magnetic intensity 3D Euler depth estimation for structural index 05 using a 16 point
window have been plotted at 1500 000 scale (not included in this publication but available in Cowan (1995) from the
GSWA Library as S10331) and as reduced A4 colour circle plots (Figure 44)
The results of deep-basement 3D Euler depth estimation for structural index 05 using a 16 point window have
been plotted as a colour image at 1500 000 scale and as an A4 image (not included in this publication)
2D analysis
Two equispaced profiles were interpolated with a 50 m station interval from the AGSO-located data profiles for the
BULLEN 1250 000 sheet The interpolated profiles were analysed using 2D Euler deconvolution and Werner
deconvolution Results are included in Cowan (1995) and show the use of these methods for more detailed analysis
Filtered data
In order to reconcile 3D Euler results from shallow basement and intrasedimentary magnetic sources we produced
several separation-filtered maps and images We found the shallow-layer double-separation filter (Figure 45) to be
very effective for shallow sources and the deep-layer standard-separation filter (Figure 46) for the basement layer
Gravity and magnetic data correlation
Both lsquoreduced to the polersquo (RTP) magnetics (Figure 47) and pseudo-gravity data (Figure 48) were produced as part of
the reconciliation of gravity and magnetic signatures In both cases the filtering operations assumed magnetization by
induction in the present Earths field The RTP data are fairly similar to the total magnetic intensity The pseudo-
57
gravity data are dominated by a northwest-trending strong positive anomaly and there is little correlation with the
Bouguer gravity data
The poor magneticgravity correlation is confirmed by cross-correlation of the RTP magnetics and the gravity
gradient The correlation plot in Figure 49 shows little coherent response with numerous zones of positive and
negative correlation
Figure 45 Regional aeromagnetic data shallow layer separation filter (BMRAGSO data) gridded at 400 m
Results
In the north and east of the area on the Wells Foreland Sub-basin trend (refer to Figure 1 main text) we see a range
of quite deep 3D Euler depths and several trend directions with north-northwesterly dominant There are relatively few
shallow intrasedimentary solutions in this zone
The second area of deep 3D Euler solutions lies over the Blake depocentre (Figure 43) with several trend
directions
Elsewhere the 3D Euler results are dominated by shallow intrasedimentary depth solutions reflecting mainly the
dolerite sills dykes and the ring complex However where we do see basement-related solutions in the south and
west of the area they appear to be shallower than those noted for the Wells Foreland Sub-basin and the Blake
depocentre
58
Figure 46 Regional aeromagnetic data deep-layer separation filter (BMRAGSO data) gridded at 400 m
Figure 48 Regional aeromagnetic data pseudo-gravity transform (BMRAGSO data) gridded at 400 m
Figure 47 Regional aeromagnetic data reduced-to-pole (BMRAGSO data) gridded at 400 m
Figure 49 Regional aeromagnetic and gravity data gravitymagnetic correlation using RTP magnetics and gravity gradient (BMRAGSO data) gridded at 4 km
59
This subdivision of the area into two zones of deep solutions is consistent with interpreted depocentres
However the interference between sources at different levels and the complexity of the magnetic response of the
basement rocks precludes more refined interpretation at this stage
The area of deep 3D Euler solutions over the Blake depocentre correlates with the pronounced negative gravity
anomaly discussed in the gravity interpretation section Using a density contrast of -015 gcc the negative gravity
anomaly could indicate up to 6ndash8 km of low-density sedimentary rocks depending on assumptions about the regional
field
The area of deep 3D Euler solutions over the Wells Foreland Sub-basin has a complex gravity expression and no
clear basin structure emerges from inversion of these data As noted previously it is likely that observed gravity
anomalies reflect contrasts in basement density rather than basement topography
Separation filtering applied to the magnetic data helps to enhance the intrasedimentary magnetic signature and to
give a better impression of the basement magnetic signature even though separation of the basement response is not
perfect
Conclusions
Quantitative aeromagnetic interpretation using 3D Euler deconvolution supported by wavenumber filtering and image
processing has been successful in providing structural trend and depth information for the Savory Sub-basin
Quantitative magnetic interpretation has revealed two zones of relatively deep magnetic basement beneath the
Wells Foreland Sub-basin and the Blake depocentre
This analysis of the magnetic data supports interpreted depocentres but the complexity of the basement magnetic
signature and interference from sources at different depths precludes further refinement to a map of basement
topography
Regional gravity proved to be very useful in understanding the regional setting of the area and in providing
support for aspects of the interpretation The gravity data support the interpretation of the Blake depocentre
suggesting up to 6ndash8 km of low-density sedimentary rocks
The deep structure of the Savory Sub-basin area is obviously complex with different areas underlain by
Archaean and Proterozoic basement and with the Capricorn suture occurring in the centre of the area
60
Recommendations
The quantitative magnetic interpretation needs to be reconciled with geological models available for the area
In particular the zones tentatively identified as areas with thick sedimentary rocks the Wells Foreland Sub-
basin and the Blake depocentre need to be investigated
Cross sections should be prepared across the basin for joint magneticgravity modelling especially for the Blake
depocentre It is important to be able to explain the strong negative gravity anomaly in this area
In view of the effects of basement density contrasts on the gravity field for the northern part of the area we think
that additional gravity interpretation and acquisition of new gravity data may not be justified as they will not
contribute significantly to understanding basin evolution and structure
It is recommended that GSWA try to get access to company confidential high-resolution aeromagnetic data
rather than flying new surveys The GSWA might offer to fund flying of new infill areas as a bargaining point
References
The original text of this report by Cowan (1995) and 1500 000 scale maps are filed in the GSWA Library under
S10331
COWAN D 1995 Savory Basin quantitative magnetic interpretation Western Australia Geological Survey S-series
S10331 (unpublished)
VACQUIER V STEENLAND N C HENDERSON R G and ZIETZ I 1951 Interpretation of aeromagnetic
maps The Geological Society of America Memoir 47 151p
WILLIAMS I R 1992 Geology of the Savory Basin Western Australia Western Australia Geological Survey
Bulletin 141 115p
61
Appendix 5
Geochemistry
MKS38 250398
Saturate FractionC12+ GLC
1217
Pr18
Ph
22
31CSR WELL-13 315m Cuttings
Figure 51 Canning Stock Route Well 13 gas chromatograph of extract of auger drill sample
12
17
18
22
31
Pr Ph
LDDH 1 6623m CoreSaturate FractionC12+ GLC
MKS35 240398
Figure 52 Gas chromatograph of extract from core sample at 6623 m LDDH1
62
Table 51 Canning Stock Route Well 13 auger drill samples
GSWA sample Drill depth (m)(a) Comments
135601 150 At watertable 135602 203 (all samples consist 135603 310 of sand mud and water) 135604 315 At total depth
NOTE (a) Datum for drill depth is the top of sediment fill in the well which is 155 m below ground level (ie the total depth of 315 m is 47 m below ground level)
Table 52 Canning Stock Route Well 13 gas chromatography data for 315 m depth sediment sample
Parameter Value
Weight of rock extracted (grams) 945 Total extract (ppm) 519 n-Alkane distribution n-C12 07 n-C13 23 n-C14 26 n-C15 22 n-C16 19 n-C17 14 i-C19 23 n-C18 14 i-C20 08 n-C19 11 n-C20 16 n-C21 25 n-C22 29 n-C23 70 n-C24 42 n-C25 95 n-C26 43 n-C27 83 n-C28 38 n-C29 87 n-C30 31 n-C31 273 Alkane compositional data Pristane phytane ratio 279 Pristane n-C17 ratio 161 Phytane n-C18 ratio 059 CPI (1)(a) 284 CPI (2) 209 (C21 + C22) (C28 + C29) 043
NOTE (a) CPI= Carbon preference index
63
Table 53 LDDH1 extract liquid chromatography data for 6623 m concentration
Rock extracted Total extract (grams) (ppm)
702 313
NOTE ppm= parts per million
Table 54 LDDH1 saturate gas chromatography data of core for 6623 m alkane composition
Pristane Pristane Phytane (a) CPI (1) CPI (2) (C21+C22) Phytane n-C17 n-C18 (C28+C29)
103 026 024 103 102 325
NOTE (a)CPI = carbon preference index
Table 55 LDDH1 saturate gas chromatography data of core for 6623 m n-alkane distributions
Parameter Value
n-C12 17 n-C13 38 n-C14 55 n-C15 60 n-C16 65 n-C17 74 i-C19 19 n-C18 78 i-C20 19 n-C19 80 n-C20 79 n-C21 71 n-C22 64 n-C23 57 n-C25 43 n-C24 38 n-C27 31 n-C28 23 n-C29 19 n-C30 12 n-C31 10
64
Appendix 6
Table 61 Summary of data from Trainor waterbores (TWB) and Bullen waterbores (BWB)
Well AMG Elevation TD Status(b) Completion details Water Salinity Water level Flow rate Depth to consolidated AGD84 GL (m) (m) struck mgl(c) (m) (LHr) lithology aquifer(e) Z51(a) Interval (m) (100 mm PVC) (m) (mgl)(d)
TWB 1 473660E 453 122 comp 0ndash75 plain 63 7 300 24 2 880 12 m 7287404N 75ndash93 slotted (9 260) McFadden Fm 93ndash99 plain TWB 2 472 977E 475 23 abd nil 15 m 7285877N Skates Hills Fm dry TWB 3 473259E 475 50 abd nil 7 m 7285849N Skates Hills Fm dry TWB 4 463225 E 445 50 comp 0ndash22 plain 35 7 200 55 3 600 0 m 7286143N 22ndash34 slotted (8 140) Tertiary sand and gravel 23ndash60 plain TWB 5 463095E 445 31 comp 0ndash19 plain 13 26 000 655 3 600 Tertiary sand and gravel 7277721N 19ndash25 slotted (36 700) 25ndash31 plain TWB 6 457013E 455 50 comp 0ndash42 plain 38 920 119 600 0 m 7274352N 42ndash48 slotted (1 030) Cornelia Fm ss TWB 7 453739E 475 26 susp 0ndash2 plain 11 9 300 48 4 500 0 m 7263891N (10 500) Tertiary sand TWB 8 433893E 535 60 susp 0ndash2 plain 47 8 500 gt46 1 200 0 m 7245991N (10 900) Tertiary sand and Brassey Range Fm ss TWB 9 437219E 505 51 comp 0ndash47 plain 45 1 000 58 600 1 m 7235905N 47ndash51 slotted (990) Brassey Range Fm ss TWB 10 434927E 495 32 susp 0ndash2 plain 235 450 120 0 m 7225875N (500) Dolerite
65
BWB 1 287337E 580 122 abd Nil 1 m 7245861N Jilyili Fm dry BWB 2 288346E 545 50 comp 0ndash26 plain 15 630 3 29 000 0 m 7240423N 26ndash38 slotted (730) Tertiary sand and gravel 38ndash50 plain BWB 3 305637E 545 50 abd 19 8 800 43 7 200 0 m 7240423N (10 550) Tertiary ss BWB 4 320167E 515 445 comp 0ndash20 plain 9 980 445 24 000 0 m 7248097N 20ndash32 slotted (1 190) Tertiary ss 32ndash44 plain BWB 5 353393E 545 20 susp 0ndash2 plain 45 (970) 1 m 7238934N Basalt
NOTES (a) GPS accuracy ~ 150 m (b) Comp = completed abd = abandoned susp = suspended (c) Salinity from conductivity (d) Analysis total dissolved solids (e) Fm = Formation ss = sandstone
52
The data show a complex pattern of positive and negative anomalies with no clearly defined trends Correlations
with aeromagnetic data and known basin structures are poor A vague north-northwest linear trend appears to coincide
with the Marloo Fault (Figure 42) A prominent negative anomaly appears to coincide with the Blake Fold and Fault
Belt depocentre and continues as a narrower negative anomaly to the east until it widens out again near the edge of the
basin Elsewhere the gravity data show little correlation with known basin structures and it is likely that especially in
the north of the area gravity anomalies are due to density changes in the basement rather than changes in basement
topography
Production of wavelength-filtered residual gravity plots and vertical gradient plots showed very patchy aliased
data reflecting poor sampling in much of the area
Regional magnetics
The AGSO regional aeromagnetic data were gridded at a 400 m mesh spacing using a minimum-curvature algorithm
(Figure 43) Most of the data has a line spacing of 1600 m with small areas of 1 km spacing The quality of the data is
acceptable for regional interpretation but is not adequate for detailed analysis The accuracy of the flight path is rather
variable reflecting the vintage of the data and the noise envelope of the data is poor by modern standards Problems
were also encountered in joining different map sheets
The magnetic anomaly pattern over the south and west part of the area shows a strong high frequency signature
reflecting the presence of widespread basic sills and dykes Some of the major north-northeasterly trending dykes can
be traced over considerable distances
Discontinuous high-frequency anomalies extend as a northwest-trending zone through the centre of the area and
this zone includes a conspicuous circular magnetic anomaly which is probably a ring complex
The northern and eastern parts of the area are characterized by long-wavelength deep-seated basement magnetic
anomalies with 120deg and 150deg trends dominant The Marloo and Perentie Faults (Figure 42) appear as distinct linear
zones and offsets A prominent easterly trending negative anomaly in the northwest of the area appears to swing round
to the southeast and may separate different basement blocks One possible interpretation is that this very deep seated
anomaly separates areas of Archaean and Proterozoic basement
Regional geology
The regional geology is described in Williams (1992) The GSWA provided a digitized version of Plate 2 from this
Bulletin the structural interpretation map to use as an overlay (Figure 42)
53
Pp
Pp
PSd
PSd
PSd
PSd
PSd
PSo
PSt
PSt
PSf
PSf
PSf
PSb
PSb
PSb
PSsPSs
PSs
PSb
PSm
PSp
PSc
PSc
PSw
PSw
PSw
PSg
PSr
PSj
PSg
PM
Pk
PY
PY
PSd
L
L
L
L
L
L
L
LL
L
L
L
LL
L
LL
L L
LL
L L
L
L
L
L
L
L
L
LL
L
L
BLAKEDEPOCENTRE
MA
RLO
O
FAU
LT
PERENTIEFAULT
50 km
MKS39120598
120deg 121deg 122deg 123deg
25deg
24deg
23deg
Approximate boundaryof aeromagnetic interpretation
PML
PSgL
PSjL
PML
PSpL
PML
PML
PSfL
PSfL
PSpL
LPc
LPcLPcPSrL
LPA
Durba Sandstone
Woora Woora Formation
McFadden Formation
Tchukardine Formation
Boondawari Formation
Skates Hills Formation
Mundadjini Formation
Coondra Formation
Spearhole Formation
Watch Point Formation
Jilyili Formation
Brassey Range Formation
Glass Spring Formation
Paterson Formation
Yeneena Group
Karara Formation
Cornelia Formation
Kahrban Subgroup
Bangemall Group
Fault
Formation boundary
PSdL
PSoL
PSfL
PStL
PSbL
PSsL
PSmL
PScL
PSpL
PSwL
PSjL
PSrL
PSgL
Pp
PYL
PkL
LPc
LPA
PML
Savory Group Other Units
PYL
Figure 42 Regional geology and structure map (after Williams 1992)
54
120deg 121deg 122deg 123deg
23deg
24deg
25deg
5820
3750
MKS47 180598
nT
50 km
Figure 43 Regional aeromagnetic data total magnetic intensity (BMRAGSO data) gridded at 400 m
Analysis
3D analysis
3D Euler deconvolution was used as the primary depth-determination method The advantage of this approach is that
consistent solutions can be obtained over the entire area with minimal assumptions about source geometries Euler
deconvolution of gridded data is used for positional information and estimation of depth to top of source Euler
55
deconvolution yields a large number of depth solutions which have to be screened to reject spurious solutions Results
are plotted as circles in eight depth ranges with radius proportional to depth and colour coded
The 400 m total magnetic intensity grid was used for the analysis Horizontal gradients in x and y and the vertical
gradient were calculated 3D Euler deconvolution was tested on the 400 m gridded data using windows of 9 times 9 and
11 times 11 and 16 times 16 data points and structural indices 05 (fault) and 10 (sill or dyke) It was concluded that the
16 times 16 window produced the best results overall and final plots were produced for the 16 times 16 window and structural
index 05 (Fig 44) Results were very good over the northern and central parts of the area showing magnetic sources
Figure 44 Depth to magnetic source 3D Euler deconvolution 16 times 16 window of 400 m gridded data structural index 05
56
at several different levels Unfortunately in the extreme south of the area shallow intrasedimentary magnetic sources
(sills and dykes) dominated the inversion and the results contained few basement solutions
In order to reduce these problems the 400 m gridded data were filtered using a separation filter based on
interpretation of the log-energy spectrum The 3D Euler method was run on the filtered data in order to generate more
basement-depth solutions Results for the deep-separation filter data were gridded and presented as a colour image in
Cowan (1995) Attempts to grid the Euler output were unsatisfactory and it is considered safer to interpret the 3D
Euler depth plots The 3D Euler depth results from the separation-filter run should be analysed with care as perfect
separation of the basement can never be achieved and there will always be some contamination from sources at
different levels
The results of original total magnetic intensity 3D Euler depth estimation for structural index 05 using a 16 point
window have been plotted at 1500 000 scale (not included in this publication but available in Cowan (1995) from the
GSWA Library as S10331) and as reduced A4 colour circle plots (Figure 44)
The results of deep-basement 3D Euler depth estimation for structural index 05 using a 16 point window have
been plotted as a colour image at 1500 000 scale and as an A4 image (not included in this publication)
2D analysis
Two equispaced profiles were interpolated with a 50 m station interval from the AGSO-located data profiles for the
BULLEN 1250 000 sheet The interpolated profiles were analysed using 2D Euler deconvolution and Werner
deconvolution Results are included in Cowan (1995) and show the use of these methods for more detailed analysis
Filtered data
In order to reconcile 3D Euler results from shallow basement and intrasedimentary magnetic sources we produced
several separation-filtered maps and images We found the shallow-layer double-separation filter (Figure 45) to be
very effective for shallow sources and the deep-layer standard-separation filter (Figure 46) for the basement layer
Gravity and magnetic data correlation
Both lsquoreduced to the polersquo (RTP) magnetics (Figure 47) and pseudo-gravity data (Figure 48) were produced as part of
the reconciliation of gravity and magnetic signatures In both cases the filtering operations assumed magnetization by
induction in the present Earths field The RTP data are fairly similar to the total magnetic intensity The pseudo-
57
gravity data are dominated by a northwest-trending strong positive anomaly and there is little correlation with the
Bouguer gravity data
The poor magneticgravity correlation is confirmed by cross-correlation of the RTP magnetics and the gravity
gradient The correlation plot in Figure 49 shows little coherent response with numerous zones of positive and
negative correlation
Figure 45 Regional aeromagnetic data shallow layer separation filter (BMRAGSO data) gridded at 400 m
Results
In the north and east of the area on the Wells Foreland Sub-basin trend (refer to Figure 1 main text) we see a range
of quite deep 3D Euler depths and several trend directions with north-northwesterly dominant There are relatively few
shallow intrasedimentary solutions in this zone
The second area of deep 3D Euler solutions lies over the Blake depocentre (Figure 43) with several trend
directions
Elsewhere the 3D Euler results are dominated by shallow intrasedimentary depth solutions reflecting mainly the
dolerite sills dykes and the ring complex However where we do see basement-related solutions in the south and
west of the area they appear to be shallower than those noted for the Wells Foreland Sub-basin and the Blake
depocentre
58
Figure 46 Regional aeromagnetic data deep-layer separation filter (BMRAGSO data) gridded at 400 m
Figure 48 Regional aeromagnetic data pseudo-gravity transform (BMRAGSO data) gridded at 400 m
Figure 47 Regional aeromagnetic data reduced-to-pole (BMRAGSO data) gridded at 400 m
Figure 49 Regional aeromagnetic and gravity data gravitymagnetic correlation using RTP magnetics and gravity gradient (BMRAGSO data) gridded at 4 km
59
This subdivision of the area into two zones of deep solutions is consistent with interpreted depocentres
However the interference between sources at different levels and the complexity of the magnetic response of the
basement rocks precludes more refined interpretation at this stage
The area of deep 3D Euler solutions over the Blake depocentre correlates with the pronounced negative gravity
anomaly discussed in the gravity interpretation section Using a density contrast of -015 gcc the negative gravity
anomaly could indicate up to 6ndash8 km of low-density sedimentary rocks depending on assumptions about the regional
field
The area of deep 3D Euler solutions over the Wells Foreland Sub-basin has a complex gravity expression and no
clear basin structure emerges from inversion of these data As noted previously it is likely that observed gravity
anomalies reflect contrasts in basement density rather than basement topography
Separation filtering applied to the magnetic data helps to enhance the intrasedimentary magnetic signature and to
give a better impression of the basement magnetic signature even though separation of the basement response is not
perfect
Conclusions
Quantitative aeromagnetic interpretation using 3D Euler deconvolution supported by wavenumber filtering and image
processing has been successful in providing structural trend and depth information for the Savory Sub-basin
Quantitative magnetic interpretation has revealed two zones of relatively deep magnetic basement beneath the
Wells Foreland Sub-basin and the Blake depocentre
This analysis of the magnetic data supports interpreted depocentres but the complexity of the basement magnetic
signature and interference from sources at different depths precludes further refinement to a map of basement
topography
Regional gravity proved to be very useful in understanding the regional setting of the area and in providing
support for aspects of the interpretation The gravity data support the interpretation of the Blake depocentre
suggesting up to 6ndash8 km of low-density sedimentary rocks
The deep structure of the Savory Sub-basin area is obviously complex with different areas underlain by
Archaean and Proterozoic basement and with the Capricorn suture occurring in the centre of the area
60
Recommendations
The quantitative magnetic interpretation needs to be reconciled with geological models available for the area
In particular the zones tentatively identified as areas with thick sedimentary rocks the Wells Foreland Sub-
basin and the Blake depocentre need to be investigated
Cross sections should be prepared across the basin for joint magneticgravity modelling especially for the Blake
depocentre It is important to be able to explain the strong negative gravity anomaly in this area
In view of the effects of basement density contrasts on the gravity field for the northern part of the area we think
that additional gravity interpretation and acquisition of new gravity data may not be justified as they will not
contribute significantly to understanding basin evolution and structure
It is recommended that GSWA try to get access to company confidential high-resolution aeromagnetic data
rather than flying new surveys The GSWA might offer to fund flying of new infill areas as a bargaining point
References
The original text of this report by Cowan (1995) and 1500 000 scale maps are filed in the GSWA Library under
S10331
COWAN D 1995 Savory Basin quantitative magnetic interpretation Western Australia Geological Survey S-series
S10331 (unpublished)
VACQUIER V STEENLAND N C HENDERSON R G and ZIETZ I 1951 Interpretation of aeromagnetic
maps The Geological Society of America Memoir 47 151p
WILLIAMS I R 1992 Geology of the Savory Basin Western Australia Western Australia Geological Survey
Bulletin 141 115p
61
Appendix 5
Geochemistry
MKS38 250398
Saturate FractionC12+ GLC
1217
Pr18
Ph
22
31CSR WELL-13 315m Cuttings
Figure 51 Canning Stock Route Well 13 gas chromatograph of extract of auger drill sample
12
17
18
22
31
Pr Ph
LDDH 1 6623m CoreSaturate FractionC12+ GLC
MKS35 240398
Figure 52 Gas chromatograph of extract from core sample at 6623 m LDDH1
62
Table 51 Canning Stock Route Well 13 auger drill samples
GSWA sample Drill depth (m)(a) Comments
135601 150 At watertable 135602 203 (all samples consist 135603 310 of sand mud and water) 135604 315 At total depth
NOTE (a) Datum for drill depth is the top of sediment fill in the well which is 155 m below ground level (ie the total depth of 315 m is 47 m below ground level)
Table 52 Canning Stock Route Well 13 gas chromatography data for 315 m depth sediment sample
Parameter Value
Weight of rock extracted (grams) 945 Total extract (ppm) 519 n-Alkane distribution n-C12 07 n-C13 23 n-C14 26 n-C15 22 n-C16 19 n-C17 14 i-C19 23 n-C18 14 i-C20 08 n-C19 11 n-C20 16 n-C21 25 n-C22 29 n-C23 70 n-C24 42 n-C25 95 n-C26 43 n-C27 83 n-C28 38 n-C29 87 n-C30 31 n-C31 273 Alkane compositional data Pristane phytane ratio 279 Pristane n-C17 ratio 161 Phytane n-C18 ratio 059 CPI (1)(a) 284 CPI (2) 209 (C21 + C22) (C28 + C29) 043
NOTE (a) CPI= Carbon preference index
63
Table 53 LDDH1 extract liquid chromatography data for 6623 m concentration
Rock extracted Total extract (grams) (ppm)
702 313
NOTE ppm= parts per million
Table 54 LDDH1 saturate gas chromatography data of core for 6623 m alkane composition
Pristane Pristane Phytane (a) CPI (1) CPI (2) (C21+C22) Phytane n-C17 n-C18 (C28+C29)
103 026 024 103 102 325
NOTE (a)CPI = carbon preference index
Table 55 LDDH1 saturate gas chromatography data of core for 6623 m n-alkane distributions
Parameter Value
n-C12 17 n-C13 38 n-C14 55 n-C15 60 n-C16 65 n-C17 74 i-C19 19 n-C18 78 i-C20 19 n-C19 80 n-C20 79 n-C21 71 n-C22 64 n-C23 57 n-C25 43 n-C24 38 n-C27 31 n-C28 23 n-C29 19 n-C30 12 n-C31 10
64
Appendix 6
Table 61 Summary of data from Trainor waterbores (TWB) and Bullen waterbores (BWB)
Well AMG Elevation TD Status(b) Completion details Water Salinity Water level Flow rate Depth to consolidated AGD84 GL (m) (m) struck mgl(c) (m) (LHr) lithology aquifer(e) Z51(a) Interval (m) (100 mm PVC) (m) (mgl)(d)
TWB 1 473660E 453 122 comp 0ndash75 plain 63 7 300 24 2 880 12 m 7287404N 75ndash93 slotted (9 260) McFadden Fm 93ndash99 plain TWB 2 472 977E 475 23 abd nil 15 m 7285877N Skates Hills Fm dry TWB 3 473259E 475 50 abd nil 7 m 7285849N Skates Hills Fm dry TWB 4 463225 E 445 50 comp 0ndash22 plain 35 7 200 55 3 600 0 m 7286143N 22ndash34 slotted (8 140) Tertiary sand and gravel 23ndash60 plain TWB 5 463095E 445 31 comp 0ndash19 plain 13 26 000 655 3 600 Tertiary sand and gravel 7277721N 19ndash25 slotted (36 700) 25ndash31 plain TWB 6 457013E 455 50 comp 0ndash42 plain 38 920 119 600 0 m 7274352N 42ndash48 slotted (1 030) Cornelia Fm ss TWB 7 453739E 475 26 susp 0ndash2 plain 11 9 300 48 4 500 0 m 7263891N (10 500) Tertiary sand TWB 8 433893E 535 60 susp 0ndash2 plain 47 8 500 gt46 1 200 0 m 7245991N (10 900) Tertiary sand and Brassey Range Fm ss TWB 9 437219E 505 51 comp 0ndash47 plain 45 1 000 58 600 1 m 7235905N 47ndash51 slotted (990) Brassey Range Fm ss TWB 10 434927E 495 32 susp 0ndash2 plain 235 450 120 0 m 7225875N (500) Dolerite
65
BWB 1 287337E 580 122 abd Nil 1 m 7245861N Jilyili Fm dry BWB 2 288346E 545 50 comp 0ndash26 plain 15 630 3 29 000 0 m 7240423N 26ndash38 slotted (730) Tertiary sand and gravel 38ndash50 plain BWB 3 305637E 545 50 abd 19 8 800 43 7 200 0 m 7240423N (10 550) Tertiary ss BWB 4 320167E 515 445 comp 0ndash20 plain 9 980 445 24 000 0 m 7248097N 20ndash32 slotted (1 190) Tertiary ss 32ndash44 plain BWB 5 353393E 545 20 susp 0ndash2 plain 45 (970) 1 m 7238934N Basalt
NOTES (a) GPS accuracy ~ 150 m (b) Comp = completed abd = abandoned susp = suspended (c) Salinity from conductivity (d) Analysis total dissolved solids (e) Fm = Formation ss = sandstone
53
Pp
Pp
PSd
PSd
PSd
PSd
PSd
PSo
PSt
PSt
PSf
PSf
PSf
PSb
PSb
PSb
PSsPSs
PSs
PSb
PSm
PSp
PSc
PSc
PSw
PSw
PSw
PSg
PSr
PSj
PSg
PM
Pk
PY
PY
PSd
L
L
L
L
L
L
L
LL
L
L
L
LL
L
LL
L L
LL
L L
L
L
L
L
L
L
L
LL
L
L
BLAKEDEPOCENTRE
MA
RLO
O
FAU
LT
PERENTIEFAULT
50 km
MKS39120598
120deg 121deg 122deg 123deg
25deg
24deg
23deg
Approximate boundaryof aeromagnetic interpretation
PML
PSgL
PSjL
PML
PSpL
PML
PML
PSfL
PSfL
PSpL
LPc
LPcLPcPSrL
LPA
Durba Sandstone
Woora Woora Formation
McFadden Formation
Tchukardine Formation
Boondawari Formation
Skates Hills Formation
Mundadjini Formation
Coondra Formation
Spearhole Formation
Watch Point Formation
Jilyili Formation
Brassey Range Formation
Glass Spring Formation
Paterson Formation
Yeneena Group
Karara Formation
Cornelia Formation
Kahrban Subgroup
Bangemall Group
Fault
Formation boundary
PSdL
PSoL
PSfL
PStL
PSbL
PSsL
PSmL
PScL
PSpL
PSwL
PSjL
PSrL
PSgL
Pp
PYL
PkL
LPc
LPA
PML
Savory Group Other Units
PYL
Figure 42 Regional geology and structure map (after Williams 1992)
54
120deg 121deg 122deg 123deg
23deg
24deg
25deg
5820
3750
MKS47 180598
nT
50 km
Figure 43 Regional aeromagnetic data total magnetic intensity (BMRAGSO data) gridded at 400 m
Analysis
3D analysis
3D Euler deconvolution was used as the primary depth-determination method The advantage of this approach is that
consistent solutions can be obtained over the entire area with minimal assumptions about source geometries Euler
deconvolution of gridded data is used for positional information and estimation of depth to top of source Euler
55
deconvolution yields a large number of depth solutions which have to be screened to reject spurious solutions Results
are plotted as circles in eight depth ranges with radius proportional to depth and colour coded
The 400 m total magnetic intensity grid was used for the analysis Horizontal gradients in x and y and the vertical
gradient were calculated 3D Euler deconvolution was tested on the 400 m gridded data using windows of 9 times 9 and
11 times 11 and 16 times 16 data points and structural indices 05 (fault) and 10 (sill or dyke) It was concluded that the
16 times 16 window produced the best results overall and final plots were produced for the 16 times 16 window and structural
index 05 (Fig 44) Results were very good over the northern and central parts of the area showing magnetic sources
Figure 44 Depth to magnetic source 3D Euler deconvolution 16 times 16 window of 400 m gridded data structural index 05
56
at several different levels Unfortunately in the extreme south of the area shallow intrasedimentary magnetic sources
(sills and dykes) dominated the inversion and the results contained few basement solutions
In order to reduce these problems the 400 m gridded data were filtered using a separation filter based on
interpretation of the log-energy spectrum The 3D Euler method was run on the filtered data in order to generate more
basement-depth solutions Results for the deep-separation filter data were gridded and presented as a colour image in
Cowan (1995) Attempts to grid the Euler output were unsatisfactory and it is considered safer to interpret the 3D
Euler depth plots The 3D Euler depth results from the separation-filter run should be analysed with care as perfect
separation of the basement can never be achieved and there will always be some contamination from sources at
different levels
The results of original total magnetic intensity 3D Euler depth estimation for structural index 05 using a 16 point
window have been plotted at 1500 000 scale (not included in this publication but available in Cowan (1995) from the
GSWA Library as S10331) and as reduced A4 colour circle plots (Figure 44)
The results of deep-basement 3D Euler depth estimation for structural index 05 using a 16 point window have
been plotted as a colour image at 1500 000 scale and as an A4 image (not included in this publication)
2D analysis
Two equispaced profiles were interpolated with a 50 m station interval from the AGSO-located data profiles for the
BULLEN 1250 000 sheet The interpolated profiles were analysed using 2D Euler deconvolution and Werner
deconvolution Results are included in Cowan (1995) and show the use of these methods for more detailed analysis
Filtered data
In order to reconcile 3D Euler results from shallow basement and intrasedimentary magnetic sources we produced
several separation-filtered maps and images We found the shallow-layer double-separation filter (Figure 45) to be
very effective for shallow sources and the deep-layer standard-separation filter (Figure 46) for the basement layer
Gravity and magnetic data correlation
Both lsquoreduced to the polersquo (RTP) magnetics (Figure 47) and pseudo-gravity data (Figure 48) were produced as part of
the reconciliation of gravity and magnetic signatures In both cases the filtering operations assumed magnetization by
induction in the present Earths field The RTP data are fairly similar to the total magnetic intensity The pseudo-
57
gravity data are dominated by a northwest-trending strong positive anomaly and there is little correlation with the
Bouguer gravity data
The poor magneticgravity correlation is confirmed by cross-correlation of the RTP magnetics and the gravity
gradient The correlation plot in Figure 49 shows little coherent response with numerous zones of positive and
negative correlation
Figure 45 Regional aeromagnetic data shallow layer separation filter (BMRAGSO data) gridded at 400 m
Results
In the north and east of the area on the Wells Foreland Sub-basin trend (refer to Figure 1 main text) we see a range
of quite deep 3D Euler depths and several trend directions with north-northwesterly dominant There are relatively few
shallow intrasedimentary solutions in this zone
The second area of deep 3D Euler solutions lies over the Blake depocentre (Figure 43) with several trend
directions
Elsewhere the 3D Euler results are dominated by shallow intrasedimentary depth solutions reflecting mainly the
dolerite sills dykes and the ring complex However where we do see basement-related solutions in the south and
west of the area they appear to be shallower than those noted for the Wells Foreland Sub-basin and the Blake
depocentre
58
Figure 46 Regional aeromagnetic data deep-layer separation filter (BMRAGSO data) gridded at 400 m
Figure 48 Regional aeromagnetic data pseudo-gravity transform (BMRAGSO data) gridded at 400 m
Figure 47 Regional aeromagnetic data reduced-to-pole (BMRAGSO data) gridded at 400 m
Figure 49 Regional aeromagnetic and gravity data gravitymagnetic correlation using RTP magnetics and gravity gradient (BMRAGSO data) gridded at 4 km
59
This subdivision of the area into two zones of deep solutions is consistent with interpreted depocentres
However the interference between sources at different levels and the complexity of the magnetic response of the
basement rocks precludes more refined interpretation at this stage
The area of deep 3D Euler solutions over the Blake depocentre correlates with the pronounced negative gravity
anomaly discussed in the gravity interpretation section Using a density contrast of -015 gcc the negative gravity
anomaly could indicate up to 6ndash8 km of low-density sedimentary rocks depending on assumptions about the regional
field
The area of deep 3D Euler solutions over the Wells Foreland Sub-basin has a complex gravity expression and no
clear basin structure emerges from inversion of these data As noted previously it is likely that observed gravity
anomalies reflect contrasts in basement density rather than basement topography
Separation filtering applied to the magnetic data helps to enhance the intrasedimentary magnetic signature and to
give a better impression of the basement magnetic signature even though separation of the basement response is not
perfect
Conclusions
Quantitative aeromagnetic interpretation using 3D Euler deconvolution supported by wavenumber filtering and image
processing has been successful in providing structural trend and depth information for the Savory Sub-basin
Quantitative magnetic interpretation has revealed two zones of relatively deep magnetic basement beneath the
Wells Foreland Sub-basin and the Blake depocentre
This analysis of the magnetic data supports interpreted depocentres but the complexity of the basement magnetic
signature and interference from sources at different depths precludes further refinement to a map of basement
topography
Regional gravity proved to be very useful in understanding the regional setting of the area and in providing
support for aspects of the interpretation The gravity data support the interpretation of the Blake depocentre
suggesting up to 6ndash8 km of low-density sedimentary rocks
The deep structure of the Savory Sub-basin area is obviously complex with different areas underlain by
Archaean and Proterozoic basement and with the Capricorn suture occurring in the centre of the area
60
Recommendations
The quantitative magnetic interpretation needs to be reconciled with geological models available for the area
In particular the zones tentatively identified as areas with thick sedimentary rocks the Wells Foreland Sub-
basin and the Blake depocentre need to be investigated
Cross sections should be prepared across the basin for joint magneticgravity modelling especially for the Blake
depocentre It is important to be able to explain the strong negative gravity anomaly in this area
In view of the effects of basement density contrasts on the gravity field for the northern part of the area we think
that additional gravity interpretation and acquisition of new gravity data may not be justified as they will not
contribute significantly to understanding basin evolution and structure
It is recommended that GSWA try to get access to company confidential high-resolution aeromagnetic data
rather than flying new surveys The GSWA might offer to fund flying of new infill areas as a bargaining point
References
The original text of this report by Cowan (1995) and 1500 000 scale maps are filed in the GSWA Library under
S10331
COWAN D 1995 Savory Basin quantitative magnetic interpretation Western Australia Geological Survey S-series
S10331 (unpublished)
VACQUIER V STEENLAND N C HENDERSON R G and ZIETZ I 1951 Interpretation of aeromagnetic
maps The Geological Society of America Memoir 47 151p
WILLIAMS I R 1992 Geology of the Savory Basin Western Australia Western Australia Geological Survey
Bulletin 141 115p
61
Appendix 5
Geochemistry
MKS38 250398
Saturate FractionC12+ GLC
1217
Pr18
Ph
22
31CSR WELL-13 315m Cuttings
Figure 51 Canning Stock Route Well 13 gas chromatograph of extract of auger drill sample
12
17
18
22
31
Pr Ph
LDDH 1 6623m CoreSaturate FractionC12+ GLC
MKS35 240398
Figure 52 Gas chromatograph of extract from core sample at 6623 m LDDH1
62
Table 51 Canning Stock Route Well 13 auger drill samples
GSWA sample Drill depth (m)(a) Comments
135601 150 At watertable 135602 203 (all samples consist 135603 310 of sand mud and water) 135604 315 At total depth
NOTE (a) Datum for drill depth is the top of sediment fill in the well which is 155 m below ground level (ie the total depth of 315 m is 47 m below ground level)
Table 52 Canning Stock Route Well 13 gas chromatography data for 315 m depth sediment sample
Parameter Value
Weight of rock extracted (grams) 945 Total extract (ppm) 519 n-Alkane distribution n-C12 07 n-C13 23 n-C14 26 n-C15 22 n-C16 19 n-C17 14 i-C19 23 n-C18 14 i-C20 08 n-C19 11 n-C20 16 n-C21 25 n-C22 29 n-C23 70 n-C24 42 n-C25 95 n-C26 43 n-C27 83 n-C28 38 n-C29 87 n-C30 31 n-C31 273 Alkane compositional data Pristane phytane ratio 279 Pristane n-C17 ratio 161 Phytane n-C18 ratio 059 CPI (1)(a) 284 CPI (2) 209 (C21 + C22) (C28 + C29) 043
NOTE (a) CPI= Carbon preference index
63
Table 53 LDDH1 extract liquid chromatography data for 6623 m concentration
Rock extracted Total extract (grams) (ppm)
702 313
NOTE ppm= parts per million
Table 54 LDDH1 saturate gas chromatography data of core for 6623 m alkane composition
Pristane Pristane Phytane (a) CPI (1) CPI (2) (C21+C22) Phytane n-C17 n-C18 (C28+C29)
103 026 024 103 102 325
NOTE (a)CPI = carbon preference index
Table 55 LDDH1 saturate gas chromatography data of core for 6623 m n-alkane distributions
Parameter Value
n-C12 17 n-C13 38 n-C14 55 n-C15 60 n-C16 65 n-C17 74 i-C19 19 n-C18 78 i-C20 19 n-C19 80 n-C20 79 n-C21 71 n-C22 64 n-C23 57 n-C25 43 n-C24 38 n-C27 31 n-C28 23 n-C29 19 n-C30 12 n-C31 10
64
Appendix 6
Table 61 Summary of data from Trainor waterbores (TWB) and Bullen waterbores (BWB)
Well AMG Elevation TD Status(b) Completion details Water Salinity Water level Flow rate Depth to consolidated AGD84 GL (m) (m) struck mgl(c) (m) (LHr) lithology aquifer(e) Z51(a) Interval (m) (100 mm PVC) (m) (mgl)(d)
TWB 1 473660E 453 122 comp 0ndash75 plain 63 7 300 24 2 880 12 m 7287404N 75ndash93 slotted (9 260) McFadden Fm 93ndash99 plain TWB 2 472 977E 475 23 abd nil 15 m 7285877N Skates Hills Fm dry TWB 3 473259E 475 50 abd nil 7 m 7285849N Skates Hills Fm dry TWB 4 463225 E 445 50 comp 0ndash22 plain 35 7 200 55 3 600 0 m 7286143N 22ndash34 slotted (8 140) Tertiary sand and gravel 23ndash60 plain TWB 5 463095E 445 31 comp 0ndash19 plain 13 26 000 655 3 600 Tertiary sand and gravel 7277721N 19ndash25 slotted (36 700) 25ndash31 plain TWB 6 457013E 455 50 comp 0ndash42 plain 38 920 119 600 0 m 7274352N 42ndash48 slotted (1 030) Cornelia Fm ss TWB 7 453739E 475 26 susp 0ndash2 plain 11 9 300 48 4 500 0 m 7263891N (10 500) Tertiary sand TWB 8 433893E 535 60 susp 0ndash2 plain 47 8 500 gt46 1 200 0 m 7245991N (10 900) Tertiary sand and Brassey Range Fm ss TWB 9 437219E 505 51 comp 0ndash47 plain 45 1 000 58 600 1 m 7235905N 47ndash51 slotted (990) Brassey Range Fm ss TWB 10 434927E 495 32 susp 0ndash2 plain 235 450 120 0 m 7225875N (500) Dolerite
65
BWB 1 287337E 580 122 abd Nil 1 m 7245861N Jilyili Fm dry BWB 2 288346E 545 50 comp 0ndash26 plain 15 630 3 29 000 0 m 7240423N 26ndash38 slotted (730) Tertiary sand and gravel 38ndash50 plain BWB 3 305637E 545 50 abd 19 8 800 43 7 200 0 m 7240423N (10 550) Tertiary ss BWB 4 320167E 515 445 comp 0ndash20 plain 9 980 445 24 000 0 m 7248097N 20ndash32 slotted (1 190) Tertiary ss 32ndash44 plain BWB 5 353393E 545 20 susp 0ndash2 plain 45 (970) 1 m 7238934N Basalt
NOTES (a) GPS accuracy ~ 150 m (b) Comp = completed abd = abandoned susp = suspended (c) Salinity from conductivity (d) Analysis total dissolved solids (e) Fm = Formation ss = sandstone
54
120deg 121deg 122deg 123deg
23deg
24deg
25deg
5820
3750
MKS47 180598
nT
50 km
Figure 43 Regional aeromagnetic data total magnetic intensity (BMRAGSO data) gridded at 400 m
Analysis
3D analysis
3D Euler deconvolution was used as the primary depth-determination method The advantage of this approach is that
consistent solutions can be obtained over the entire area with minimal assumptions about source geometries Euler
deconvolution of gridded data is used for positional information and estimation of depth to top of source Euler
55
deconvolution yields a large number of depth solutions which have to be screened to reject spurious solutions Results
are plotted as circles in eight depth ranges with radius proportional to depth and colour coded
The 400 m total magnetic intensity grid was used for the analysis Horizontal gradients in x and y and the vertical
gradient were calculated 3D Euler deconvolution was tested on the 400 m gridded data using windows of 9 times 9 and
11 times 11 and 16 times 16 data points and structural indices 05 (fault) and 10 (sill or dyke) It was concluded that the
16 times 16 window produced the best results overall and final plots were produced for the 16 times 16 window and structural
index 05 (Fig 44) Results were very good over the northern and central parts of the area showing magnetic sources
Figure 44 Depth to magnetic source 3D Euler deconvolution 16 times 16 window of 400 m gridded data structural index 05
56
at several different levels Unfortunately in the extreme south of the area shallow intrasedimentary magnetic sources
(sills and dykes) dominated the inversion and the results contained few basement solutions
In order to reduce these problems the 400 m gridded data were filtered using a separation filter based on
interpretation of the log-energy spectrum The 3D Euler method was run on the filtered data in order to generate more
basement-depth solutions Results for the deep-separation filter data were gridded and presented as a colour image in
Cowan (1995) Attempts to grid the Euler output were unsatisfactory and it is considered safer to interpret the 3D
Euler depth plots The 3D Euler depth results from the separation-filter run should be analysed with care as perfect
separation of the basement can never be achieved and there will always be some contamination from sources at
different levels
The results of original total magnetic intensity 3D Euler depth estimation for structural index 05 using a 16 point
window have been plotted at 1500 000 scale (not included in this publication but available in Cowan (1995) from the
GSWA Library as S10331) and as reduced A4 colour circle plots (Figure 44)
The results of deep-basement 3D Euler depth estimation for structural index 05 using a 16 point window have
been plotted as a colour image at 1500 000 scale and as an A4 image (not included in this publication)
2D analysis
Two equispaced profiles were interpolated with a 50 m station interval from the AGSO-located data profiles for the
BULLEN 1250 000 sheet The interpolated profiles were analysed using 2D Euler deconvolution and Werner
deconvolution Results are included in Cowan (1995) and show the use of these methods for more detailed analysis
Filtered data
In order to reconcile 3D Euler results from shallow basement and intrasedimentary magnetic sources we produced
several separation-filtered maps and images We found the shallow-layer double-separation filter (Figure 45) to be
very effective for shallow sources and the deep-layer standard-separation filter (Figure 46) for the basement layer
Gravity and magnetic data correlation
Both lsquoreduced to the polersquo (RTP) magnetics (Figure 47) and pseudo-gravity data (Figure 48) were produced as part of
the reconciliation of gravity and magnetic signatures In both cases the filtering operations assumed magnetization by
induction in the present Earths field The RTP data are fairly similar to the total magnetic intensity The pseudo-
57
gravity data are dominated by a northwest-trending strong positive anomaly and there is little correlation with the
Bouguer gravity data
The poor magneticgravity correlation is confirmed by cross-correlation of the RTP magnetics and the gravity
gradient The correlation plot in Figure 49 shows little coherent response with numerous zones of positive and
negative correlation
Figure 45 Regional aeromagnetic data shallow layer separation filter (BMRAGSO data) gridded at 400 m
Results
In the north and east of the area on the Wells Foreland Sub-basin trend (refer to Figure 1 main text) we see a range
of quite deep 3D Euler depths and several trend directions with north-northwesterly dominant There are relatively few
shallow intrasedimentary solutions in this zone
The second area of deep 3D Euler solutions lies over the Blake depocentre (Figure 43) with several trend
directions
Elsewhere the 3D Euler results are dominated by shallow intrasedimentary depth solutions reflecting mainly the
dolerite sills dykes and the ring complex However where we do see basement-related solutions in the south and
west of the area they appear to be shallower than those noted for the Wells Foreland Sub-basin and the Blake
depocentre
58
Figure 46 Regional aeromagnetic data deep-layer separation filter (BMRAGSO data) gridded at 400 m
Figure 48 Regional aeromagnetic data pseudo-gravity transform (BMRAGSO data) gridded at 400 m
Figure 47 Regional aeromagnetic data reduced-to-pole (BMRAGSO data) gridded at 400 m
Figure 49 Regional aeromagnetic and gravity data gravitymagnetic correlation using RTP magnetics and gravity gradient (BMRAGSO data) gridded at 4 km
59
This subdivision of the area into two zones of deep solutions is consistent with interpreted depocentres
However the interference between sources at different levels and the complexity of the magnetic response of the
basement rocks precludes more refined interpretation at this stage
The area of deep 3D Euler solutions over the Blake depocentre correlates with the pronounced negative gravity
anomaly discussed in the gravity interpretation section Using a density contrast of -015 gcc the negative gravity
anomaly could indicate up to 6ndash8 km of low-density sedimentary rocks depending on assumptions about the regional
field
The area of deep 3D Euler solutions over the Wells Foreland Sub-basin has a complex gravity expression and no
clear basin structure emerges from inversion of these data As noted previously it is likely that observed gravity
anomalies reflect contrasts in basement density rather than basement topography
Separation filtering applied to the magnetic data helps to enhance the intrasedimentary magnetic signature and to
give a better impression of the basement magnetic signature even though separation of the basement response is not
perfect
Conclusions
Quantitative aeromagnetic interpretation using 3D Euler deconvolution supported by wavenumber filtering and image
processing has been successful in providing structural trend and depth information for the Savory Sub-basin
Quantitative magnetic interpretation has revealed two zones of relatively deep magnetic basement beneath the
Wells Foreland Sub-basin and the Blake depocentre
This analysis of the magnetic data supports interpreted depocentres but the complexity of the basement magnetic
signature and interference from sources at different depths precludes further refinement to a map of basement
topography
Regional gravity proved to be very useful in understanding the regional setting of the area and in providing
support for aspects of the interpretation The gravity data support the interpretation of the Blake depocentre
suggesting up to 6ndash8 km of low-density sedimentary rocks
The deep structure of the Savory Sub-basin area is obviously complex with different areas underlain by
Archaean and Proterozoic basement and with the Capricorn suture occurring in the centre of the area
60
Recommendations
The quantitative magnetic interpretation needs to be reconciled with geological models available for the area
In particular the zones tentatively identified as areas with thick sedimentary rocks the Wells Foreland Sub-
basin and the Blake depocentre need to be investigated
Cross sections should be prepared across the basin for joint magneticgravity modelling especially for the Blake
depocentre It is important to be able to explain the strong negative gravity anomaly in this area
In view of the effects of basement density contrasts on the gravity field for the northern part of the area we think
that additional gravity interpretation and acquisition of new gravity data may not be justified as they will not
contribute significantly to understanding basin evolution and structure
It is recommended that GSWA try to get access to company confidential high-resolution aeromagnetic data
rather than flying new surveys The GSWA might offer to fund flying of new infill areas as a bargaining point
References
The original text of this report by Cowan (1995) and 1500 000 scale maps are filed in the GSWA Library under
S10331
COWAN D 1995 Savory Basin quantitative magnetic interpretation Western Australia Geological Survey S-series
S10331 (unpublished)
VACQUIER V STEENLAND N C HENDERSON R G and ZIETZ I 1951 Interpretation of aeromagnetic
maps The Geological Society of America Memoir 47 151p
WILLIAMS I R 1992 Geology of the Savory Basin Western Australia Western Australia Geological Survey
Bulletin 141 115p
61
Appendix 5
Geochemistry
MKS38 250398
Saturate FractionC12+ GLC
1217
Pr18
Ph
22
31CSR WELL-13 315m Cuttings
Figure 51 Canning Stock Route Well 13 gas chromatograph of extract of auger drill sample
12
17
18
22
31
Pr Ph
LDDH 1 6623m CoreSaturate FractionC12+ GLC
MKS35 240398
Figure 52 Gas chromatograph of extract from core sample at 6623 m LDDH1
62
Table 51 Canning Stock Route Well 13 auger drill samples
GSWA sample Drill depth (m)(a) Comments
135601 150 At watertable 135602 203 (all samples consist 135603 310 of sand mud and water) 135604 315 At total depth
NOTE (a) Datum for drill depth is the top of sediment fill in the well which is 155 m below ground level (ie the total depth of 315 m is 47 m below ground level)
Table 52 Canning Stock Route Well 13 gas chromatography data for 315 m depth sediment sample
Parameter Value
Weight of rock extracted (grams) 945 Total extract (ppm) 519 n-Alkane distribution n-C12 07 n-C13 23 n-C14 26 n-C15 22 n-C16 19 n-C17 14 i-C19 23 n-C18 14 i-C20 08 n-C19 11 n-C20 16 n-C21 25 n-C22 29 n-C23 70 n-C24 42 n-C25 95 n-C26 43 n-C27 83 n-C28 38 n-C29 87 n-C30 31 n-C31 273 Alkane compositional data Pristane phytane ratio 279 Pristane n-C17 ratio 161 Phytane n-C18 ratio 059 CPI (1)(a) 284 CPI (2) 209 (C21 + C22) (C28 + C29) 043
NOTE (a) CPI= Carbon preference index
63
Table 53 LDDH1 extract liquid chromatography data for 6623 m concentration
Rock extracted Total extract (grams) (ppm)
702 313
NOTE ppm= parts per million
Table 54 LDDH1 saturate gas chromatography data of core for 6623 m alkane composition
Pristane Pristane Phytane (a) CPI (1) CPI (2) (C21+C22) Phytane n-C17 n-C18 (C28+C29)
103 026 024 103 102 325
NOTE (a)CPI = carbon preference index
Table 55 LDDH1 saturate gas chromatography data of core for 6623 m n-alkane distributions
Parameter Value
n-C12 17 n-C13 38 n-C14 55 n-C15 60 n-C16 65 n-C17 74 i-C19 19 n-C18 78 i-C20 19 n-C19 80 n-C20 79 n-C21 71 n-C22 64 n-C23 57 n-C25 43 n-C24 38 n-C27 31 n-C28 23 n-C29 19 n-C30 12 n-C31 10
64
Appendix 6
Table 61 Summary of data from Trainor waterbores (TWB) and Bullen waterbores (BWB)
Well AMG Elevation TD Status(b) Completion details Water Salinity Water level Flow rate Depth to consolidated AGD84 GL (m) (m) struck mgl(c) (m) (LHr) lithology aquifer(e) Z51(a) Interval (m) (100 mm PVC) (m) (mgl)(d)
TWB 1 473660E 453 122 comp 0ndash75 plain 63 7 300 24 2 880 12 m 7287404N 75ndash93 slotted (9 260) McFadden Fm 93ndash99 plain TWB 2 472 977E 475 23 abd nil 15 m 7285877N Skates Hills Fm dry TWB 3 473259E 475 50 abd nil 7 m 7285849N Skates Hills Fm dry TWB 4 463225 E 445 50 comp 0ndash22 plain 35 7 200 55 3 600 0 m 7286143N 22ndash34 slotted (8 140) Tertiary sand and gravel 23ndash60 plain TWB 5 463095E 445 31 comp 0ndash19 plain 13 26 000 655 3 600 Tertiary sand and gravel 7277721N 19ndash25 slotted (36 700) 25ndash31 plain TWB 6 457013E 455 50 comp 0ndash42 plain 38 920 119 600 0 m 7274352N 42ndash48 slotted (1 030) Cornelia Fm ss TWB 7 453739E 475 26 susp 0ndash2 plain 11 9 300 48 4 500 0 m 7263891N (10 500) Tertiary sand TWB 8 433893E 535 60 susp 0ndash2 plain 47 8 500 gt46 1 200 0 m 7245991N (10 900) Tertiary sand and Brassey Range Fm ss TWB 9 437219E 505 51 comp 0ndash47 plain 45 1 000 58 600 1 m 7235905N 47ndash51 slotted (990) Brassey Range Fm ss TWB 10 434927E 495 32 susp 0ndash2 plain 235 450 120 0 m 7225875N (500) Dolerite
65
BWB 1 287337E 580 122 abd Nil 1 m 7245861N Jilyili Fm dry BWB 2 288346E 545 50 comp 0ndash26 plain 15 630 3 29 000 0 m 7240423N 26ndash38 slotted (730) Tertiary sand and gravel 38ndash50 plain BWB 3 305637E 545 50 abd 19 8 800 43 7 200 0 m 7240423N (10 550) Tertiary ss BWB 4 320167E 515 445 comp 0ndash20 plain 9 980 445 24 000 0 m 7248097N 20ndash32 slotted (1 190) Tertiary ss 32ndash44 plain BWB 5 353393E 545 20 susp 0ndash2 plain 45 (970) 1 m 7238934N Basalt
NOTES (a) GPS accuracy ~ 150 m (b) Comp = completed abd = abandoned susp = suspended (c) Salinity from conductivity (d) Analysis total dissolved solids (e) Fm = Formation ss = sandstone
55
deconvolution yields a large number of depth solutions which have to be screened to reject spurious solutions Results
are plotted as circles in eight depth ranges with radius proportional to depth and colour coded
The 400 m total magnetic intensity grid was used for the analysis Horizontal gradients in x and y and the vertical
gradient were calculated 3D Euler deconvolution was tested on the 400 m gridded data using windows of 9 times 9 and
11 times 11 and 16 times 16 data points and structural indices 05 (fault) and 10 (sill or dyke) It was concluded that the
16 times 16 window produced the best results overall and final plots were produced for the 16 times 16 window and structural
index 05 (Fig 44) Results were very good over the northern and central parts of the area showing magnetic sources
Figure 44 Depth to magnetic source 3D Euler deconvolution 16 times 16 window of 400 m gridded data structural index 05
56
at several different levels Unfortunately in the extreme south of the area shallow intrasedimentary magnetic sources
(sills and dykes) dominated the inversion and the results contained few basement solutions
In order to reduce these problems the 400 m gridded data were filtered using a separation filter based on
interpretation of the log-energy spectrum The 3D Euler method was run on the filtered data in order to generate more
basement-depth solutions Results for the deep-separation filter data were gridded and presented as a colour image in
Cowan (1995) Attempts to grid the Euler output were unsatisfactory and it is considered safer to interpret the 3D
Euler depth plots The 3D Euler depth results from the separation-filter run should be analysed with care as perfect
separation of the basement can never be achieved and there will always be some contamination from sources at
different levels
The results of original total magnetic intensity 3D Euler depth estimation for structural index 05 using a 16 point
window have been plotted at 1500 000 scale (not included in this publication but available in Cowan (1995) from the
GSWA Library as S10331) and as reduced A4 colour circle plots (Figure 44)
The results of deep-basement 3D Euler depth estimation for structural index 05 using a 16 point window have
been plotted as a colour image at 1500 000 scale and as an A4 image (not included in this publication)
2D analysis
Two equispaced profiles were interpolated with a 50 m station interval from the AGSO-located data profiles for the
BULLEN 1250 000 sheet The interpolated profiles were analysed using 2D Euler deconvolution and Werner
deconvolution Results are included in Cowan (1995) and show the use of these methods for more detailed analysis
Filtered data
In order to reconcile 3D Euler results from shallow basement and intrasedimentary magnetic sources we produced
several separation-filtered maps and images We found the shallow-layer double-separation filter (Figure 45) to be
very effective for shallow sources and the deep-layer standard-separation filter (Figure 46) for the basement layer
Gravity and magnetic data correlation
Both lsquoreduced to the polersquo (RTP) magnetics (Figure 47) and pseudo-gravity data (Figure 48) were produced as part of
the reconciliation of gravity and magnetic signatures In both cases the filtering operations assumed magnetization by
induction in the present Earths field The RTP data are fairly similar to the total magnetic intensity The pseudo-
57
gravity data are dominated by a northwest-trending strong positive anomaly and there is little correlation with the
Bouguer gravity data
The poor magneticgravity correlation is confirmed by cross-correlation of the RTP magnetics and the gravity
gradient The correlation plot in Figure 49 shows little coherent response with numerous zones of positive and
negative correlation
Figure 45 Regional aeromagnetic data shallow layer separation filter (BMRAGSO data) gridded at 400 m
Results
In the north and east of the area on the Wells Foreland Sub-basin trend (refer to Figure 1 main text) we see a range
of quite deep 3D Euler depths and several trend directions with north-northwesterly dominant There are relatively few
shallow intrasedimentary solutions in this zone
The second area of deep 3D Euler solutions lies over the Blake depocentre (Figure 43) with several trend
directions
Elsewhere the 3D Euler results are dominated by shallow intrasedimentary depth solutions reflecting mainly the
dolerite sills dykes and the ring complex However where we do see basement-related solutions in the south and
west of the area they appear to be shallower than those noted for the Wells Foreland Sub-basin and the Blake
depocentre
58
Figure 46 Regional aeromagnetic data deep-layer separation filter (BMRAGSO data) gridded at 400 m
Figure 48 Regional aeromagnetic data pseudo-gravity transform (BMRAGSO data) gridded at 400 m
Figure 47 Regional aeromagnetic data reduced-to-pole (BMRAGSO data) gridded at 400 m
Figure 49 Regional aeromagnetic and gravity data gravitymagnetic correlation using RTP magnetics and gravity gradient (BMRAGSO data) gridded at 4 km
59
This subdivision of the area into two zones of deep solutions is consistent with interpreted depocentres
However the interference between sources at different levels and the complexity of the magnetic response of the
basement rocks precludes more refined interpretation at this stage
The area of deep 3D Euler solutions over the Blake depocentre correlates with the pronounced negative gravity
anomaly discussed in the gravity interpretation section Using a density contrast of -015 gcc the negative gravity
anomaly could indicate up to 6ndash8 km of low-density sedimentary rocks depending on assumptions about the regional
field
The area of deep 3D Euler solutions over the Wells Foreland Sub-basin has a complex gravity expression and no
clear basin structure emerges from inversion of these data As noted previously it is likely that observed gravity
anomalies reflect contrasts in basement density rather than basement topography
Separation filtering applied to the magnetic data helps to enhance the intrasedimentary magnetic signature and to
give a better impression of the basement magnetic signature even though separation of the basement response is not
perfect
Conclusions
Quantitative aeromagnetic interpretation using 3D Euler deconvolution supported by wavenumber filtering and image
processing has been successful in providing structural trend and depth information for the Savory Sub-basin
Quantitative magnetic interpretation has revealed two zones of relatively deep magnetic basement beneath the
Wells Foreland Sub-basin and the Blake depocentre
This analysis of the magnetic data supports interpreted depocentres but the complexity of the basement magnetic
signature and interference from sources at different depths precludes further refinement to a map of basement
topography
Regional gravity proved to be very useful in understanding the regional setting of the area and in providing
support for aspects of the interpretation The gravity data support the interpretation of the Blake depocentre
suggesting up to 6ndash8 km of low-density sedimentary rocks
The deep structure of the Savory Sub-basin area is obviously complex with different areas underlain by
Archaean and Proterozoic basement and with the Capricorn suture occurring in the centre of the area
60
Recommendations
The quantitative magnetic interpretation needs to be reconciled with geological models available for the area
In particular the zones tentatively identified as areas with thick sedimentary rocks the Wells Foreland Sub-
basin and the Blake depocentre need to be investigated
Cross sections should be prepared across the basin for joint magneticgravity modelling especially for the Blake
depocentre It is important to be able to explain the strong negative gravity anomaly in this area
In view of the effects of basement density contrasts on the gravity field for the northern part of the area we think
that additional gravity interpretation and acquisition of new gravity data may not be justified as they will not
contribute significantly to understanding basin evolution and structure
It is recommended that GSWA try to get access to company confidential high-resolution aeromagnetic data
rather than flying new surveys The GSWA might offer to fund flying of new infill areas as a bargaining point
References
The original text of this report by Cowan (1995) and 1500 000 scale maps are filed in the GSWA Library under
S10331
COWAN D 1995 Savory Basin quantitative magnetic interpretation Western Australia Geological Survey S-series
S10331 (unpublished)
VACQUIER V STEENLAND N C HENDERSON R G and ZIETZ I 1951 Interpretation of aeromagnetic
maps The Geological Society of America Memoir 47 151p
WILLIAMS I R 1992 Geology of the Savory Basin Western Australia Western Australia Geological Survey
Bulletin 141 115p
61
Appendix 5
Geochemistry
MKS38 250398
Saturate FractionC12+ GLC
1217
Pr18
Ph
22
31CSR WELL-13 315m Cuttings
Figure 51 Canning Stock Route Well 13 gas chromatograph of extract of auger drill sample
12
17
18
22
31
Pr Ph
LDDH 1 6623m CoreSaturate FractionC12+ GLC
MKS35 240398
Figure 52 Gas chromatograph of extract from core sample at 6623 m LDDH1
62
Table 51 Canning Stock Route Well 13 auger drill samples
GSWA sample Drill depth (m)(a) Comments
135601 150 At watertable 135602 203 (all samples consist 135603 310 of sand mud and water) 135604 315 At total depth
NOTE (a) Datum for drill depth is the top of sediment fill in the well which is 155 m below ground level (ie the total depth of 315 m is 47 m below ground level)
Table 52 Canning Stock Route Well 13 gas chromatography data for 315 m depth sediment sample
Parameter Value
Weight of rock extracted (grams) 945 Total extract (ppm) 519 n-Alkane distribution n-C12 07 n-C13 23 n-C14 26 n-C15 22 n-C16 19 n-C17 14 i-C19 23 n-C18 14 i-C20 08 n-C19 11 n-C20 16 n-C21 25 n-C22 29 n-C23 70 n-C24 42 n-C25 95 n-C26 43 n-C27 83 n-C28 38 n-C29 87 n-C30 31 n-C31 273 Alkane compositional data Pristane phytane ratio 279 Pristane n-C17 ratio 161 Phytane n-C18 ratio 059 CPI (1)(a) 284 CPI (2) 209 (C21 + C22) (C28 + C29) 043
NOTE (a) CPI= Carbon preference index
63
Table 53 LDDH1 extract liquid chromatography data for 6623 m concentration
Rock extracted Total extract (grams) (ppm)
702 313
NOTE ppm= parts per million
Table 54 LDDH1 saturate gas chromatography data of core for 6623 m alkane composition
Pristane Pristane Phytane (a) CPI (1) CPI (2) (C21+C22) Phytane n-C17 n-C18 (C28+C29)
103 026 024 103 102 325
NOTE (a)CPI = carbon preference index
Table 55 LDDH1 saturate gas chromatography data of core for 6623 m n-alkane distributions
Parameter Value
n-C12 17 n-C13 38 n-C14 55 n-C15 60 n-C16 65 n-C17 74 i-C19 19 n-C18 78 i-C20 19 n-C19 80 n-C20 79 n-C21 71 n-C22 64 n-C23 57 n-C25 43 n-C24 38 n-C27 31 n-C28 23 n-C29 19 n-C30 12 n-C31 10
64
Appendix 6
Table 61 Summary of data from Trainor waterbores (TWB) and Bullen waterbores (BWB)
Well AMG Elevation TD Status(b) Completion details Water Salinity Water level Flow rate Depth to consolidated AGD84 GL (m) (m) struck mgl(c) (m) (LHr) lithology aquifer(e) Z51(a) Interval (m) (100 mm PVC) (m) (mgl)(d)
TWB 1 473660E 453 122 comp 0ndash75 plain 63 7 300 24 2 880 12 m 7287404N 75ndash93 slotted (9 260) McFadden Fm 93ndash99 plain TWB 2 472 977E 475 23 abd nil 15 m 7285877N Skates Hills Fm dry TWB 3 473259E 475 50 abd nil 7 m 7285849N Skates Hills Fm dry TWB 4 463225 E 445 50 comp 0ndash22 plain 35 7 200 55 3 600 0 m 7286143N 22ndash34 slotted (8 140) Tertiary sand and gravel 23ndash60 plain TWB 5 463095E 445 31 comp 0ndash19 plain 13 26 000 655 3 600 Tertiary sand and gravel 7277721N 19ndash25 slotted (36 700) 25ndash31 plain TWB 6 457013E 455 50 comp 0ndash42 plain 38 920 119 600 0 m 7274352N 42ndash48 slotted (1 030) Cornelia Fm ss TWB 7 453739E 475 26 susp 0ndash2 plain 11 9 300 48 4 500 0 m 7263891N (10 500) Tertiary sand TWB 8 433893E 535 60 susp 0ndash2 plain 47 8 500 gt46 1 200 0 m 7245991N (10 900) Tertiary sand and Brassey Range Fm ss TWB 9 437219E 505 51 comp 0ndash47 plain 45 1 000 58 600 1 m 7235905N 47ndash51 slotted (990) Brassey Range Fm ss TWB 10 434927E 495 32 susp 0ndash2 plain 235 450 120 0 m 7225875N (500) Dolerite
65
BWB 1 287337E 580 122 abd Nil 1 m 7245861N Jilyili Fm dry BWB 2 288346E 545 50 comp 0ndash26 plain 15 630 3 29 000 0 m 7240423N 26ndash38 slotted (730) Tertiary sand and gravel 38ndash50 plain BWB 3 305637E 545 50 abd 19 8 800 43 7 200 0 m 7240423N (10 550) Tertiary ss BWB 4 320167E 515 445 comp 0ndash20 plain 9 980 445 24 000 0 m 7248097N 20ndash32 slotted (1 190) Tertiary ss 32ndash44 plain BWB 5 353393E 545 20 susp 0ndash2 plain 45 (970) 1 m 7238934N Basalt
NOTES (a) GPS accuracy ~ 150 m (b) Comp = completed abd = abandoned susp = suspended (c) Salinity from conductivity (d) Analysis total dissolved solids (e) Fm = Formation ss = sandstone
56
at several different levels Unfortunately in the extreme south of the area shallow intrasedimentary magnetic sources
(sills and dykes) dominated the inversion and the results contained few basement solutions
In order to reduce these problems the 400 m gridded data were filtered using a separation filter based on
interpretation of the log-energy spectrum The 3D Euler method was run on the filtered data in order to generate more
basement-depth solutions Results for the deep-separation filter data were gridded and presented as a colour image in
Cowan (1995) Attempts to grid the Euler output were unsatisfactory and it is considered safer to interpret the 3D
Euler depth plots The 3D Euler depth results from the separation-filter run should be analysed with care as perfect
separation of the basement can never be achieved and there will always be some contamination from sources at
different levels
The results of original total magnetic intensity 3D Euler depth estimation for structural index 05 using a 16 point
window have been plotted at 1500 000 scale (not included in this publication but available in Cowan (1995) from the
GSWA Library as S10331) and as reduced A4 colour circle plots (Figure 44)
The results of deep-basement 3D Euler depth estimation for structural index 05 using a 16 point window have
been plotted as a colour image at 1500 000 scale and as an A4 image (not included in this publication)
2D analysis
Two equispaced profiles were interpolated with a 50 m station interval from the AGSO-located data profiles for the
BULLEN 1250 000 sheet The interpolated profiles were analysed using 2D Euler deconvolution and Werner
deconvolution Results are included in Cowan (1995) and show the use of these methods for more detailed analysis
Filtered data
In order to reconcile 3D Euler results from shallow basement and intrasedimentary magnetic sources we produced
several separation-filtered maps and images We found the shallow-layer double-separation filter (Figure 45) to be
very effective for shallow sources and the deep-layer standard-separation filter (Figure 46) for the basement layer
Gravity and magnetic data correlation
Both lsquoreduced to the polersquo (RTP) magnetics (Figure 47) and pseudo-gravity data (Figure 48) were produced as part of
the reconciliation of gravity and magnetic signatures In both cases the filtering operations assumed magnetization by
induction in the present Earths field The RTP data are fairly similar to the total magnetic intensity The pseudo-
57
gravity data are dominated by a northwest-trending strong positive anomaly and there is little correlation with the
Bouguer gravity data
The poor magneticgravity correlation is confirmed by cross-correlation of the RTP magnetics and the gravity
gradient The correlation plot in Figure 49 shows little coherent response with numerous zones of positive and
negative correlation
Figure 45 Regional aeromagnetic data shallow layer separation filter (BMRAGSO data) gridded at 400 m
Results
In the north and east of the area on the Wells Foreland Sub-basin trend (refer to Figure 1 main text) we see a range
of quite deep 3D Euler depths and several trend directions with north-northwesterly dominant There are relatively few
shallow intrasedimentary solutions in this zone
The second area of deep 3D Euler solutions lies over the Blake depocentre (Figure 43) with several trend
directions
Elsewhere the 3D Euler results are dominated by shallow intrasedimentary depth solutions reflecting mainly the
dolerite sills dykes and the ring complex However where we do see basement-related solutions in the south and
west of the area they appear to be shallower than those noted for the Wells Foreland Sub-basin and the Blake
depocentre
58
Figure 46 Regional aeromagnetic data deep-layer separation filter (BMRAGSO data) gridded at 400 m
Figure 48 Regional aeromagnetic data pseudo-gravity transform (BMRAGSO data) gridded at 400 m
Figure 47 Regional aeromagnetic data reduced-to-pole (BMRAGSO data) gridded at 400 m
Figure 49 Regional aeromagnetic and gravity data gravitymagnetic correlation using RTP magnetics and gravity gradient (BMRAGSO data) gridded at 4 km
59
This subdivision of the area into two zones of deep solutions is consistent with interpreted depocentres
However the interference between sources at different levels and the complexity of the magnetic response of the
basement rocks precludes more refined interpretation at this stage
The area of deep 3D Euler solutions over the Blake depocentre correlates with the pronounced negative gravity
anomaly discussed in the gravity interpretation section Using a density contrast of -015 gcc the negative gravity
anomaly could indicate up to 6ndash8 km of low-density sedimentary rocks depending on assumptions about the regional
field
The area of deep 3D Euler solutions over the Wells Foreland Sub-basin has a complex gravity expression and no
clear basin structure emerges from inversion of these data As noted previously it is likely that observed gravity
anomalies reflect contrasts in basement density rather than basement topography
Separation filtering applied to the magnetic data helps to enhance the intrasedimentary magnetic signature and to
give a better impression of the basement magnetic signature even though separation of the basement response is not
perfect
Conclusions
Quantitative aeromagnetic interpretation using 3D Euler deconvolution supported by wavenumber filtering and image
processing has been successful in providing structural trend and depth information for the Savory Sub-basin
Quantitative magnetic interpretation has revealed two zones of relatively deep magnetic basement beneath the
Wells Foreland Sub-basin and the Blake depocentre
This analysis of the magnetic data supports interpreted depocentres but the complexity of the basement magnetic
signature and interference from sources at different depths precludes further refinement to a map of basement
topography
Regional gravity proved to be very useful in understanding the regional setting of the area and in providing
support for aspects of the interpretation The gravity data support the interpretation of the Blake depocentre
suggesting up to 6ndash8 km of low-density sedimentary rocks
The deep structure of the Savory Sub-basin area is obviously complex with different areas underlain by
Archaean and Proterozoic basement and with the Capricorn suture occurring in the centre of the area
60
Recommendations
The quantitative magnetic interpretation needs to be reconciled with geological models available for the area
In particular the zones tentatively identified as areas with thick sedimentary rocks the Wells Foreland Sub-
basin and the Blake depocentre need to be investigated
Cross sections should be prepared across the basin for joint magneticgravity modelling especially for the Blake
depocentre It is important to be able to explain the strong negative gravity anomaly in this area
In view of the effects of basement density contrasts on the gravity field for the northern part of the area we think
that additional gravity interpretation and acquisition of new gravity data may not be justified as they will not
contribute significantly to understanding basin evolution and structure
It is recommended that GSWA try to get access to company confidential high-resolution aeromagnetic data
rather than flying new surveys The GSWA might offer to fund flying of new infill areas as a bargaining point
References
The original text of this report by Cowan (1995) and 1500 000 scale maps are filed in the GSWA Library under
S10331
COWAN D 1995 Savory Basin quantitative magnetic interpretation Western Australia Geological Survey S-series
S10331 (unpublished)
VACQUIER V STEENLAND N C HENDERSON R G and ZIETZ I 1951 Interpretation of aeromagnetic
maps The Geological Society of America Memoir 47 151p
WILLIAMS I R 1992 Geology of the Savory Basin Western Australia Western Australia Geological Survey
Bulletin 141 115p
61
Appendix 5
Geochemistry
MKS38 250398
Saturate FractionC12+ GLC
1217
Pr18
Ph
22
31CSR WELL-13 315m Cuttings
Figure 51 Canning Stock Route Well 13 gas chromatograph of extract of auger drill sample
12
17
18
22
31
Pr Ph
LDDH 1 6623m CoreSaturate FractionC12+ GLC
MKS35 240398
Figure 52 Gas chromatograph of extract from core sample at 6623 m LDDH1
62
Table 51 Canning Stock Route Well 13 auger drill samples
GSWA sample Drill depth (m)(a) Comments
135601 150 At watertable 135602 203 (all samples consist 135603 310 of sand mud and water) 135604 315 At total depth
NOTE (a) Datum for drill depth is the top of sediment fill in the well which is 155 m below ground level (ie the total depth of 315 m is 47 m below ground level)
Table 52 Canning Stock Route Well 13 gas chromatography data for 315 m depth sediment sample
Parameter Value
Weight of rock extracted (grams) 945 Total extract (ppm) 519 n-Alkane distribution n-C12 07 n-C13 23 n-C14 26 n-C15 22 n-C16 19 n-C17 14 i-C19 23 n-C18 14 i-C20 08 n-C19 11 n-C20 16 n-C21 25 n-C22 29 n-C23 70 n-C24 42 n-C25 95 n-C26 43 n-C27 83 n-C28 38 n-C29 87 n-C30 31 n-C31 273 Alkane compositional data Pristane phytane ratio 279 Pristane n-C17 ratio 161 Phytane n-C18 ratio 059 CPI (1)(a) 284 CPI (2) 209 (C21 + C22) (C28 + C29) 043
NOTE (a) CPI= Carbon preference index
63
Table 53 LDDH1 extract liquid chromatography data for 6623 m concentration
Rock extracted Total extract (grams) (ppm)
702 313
NOTE ppm= parts per million
Table 54 LDDH1 saturate gas chromatography data of core for 6623 m alkane composition
Pristane Pristane Phytane (a) CPI (1) CPI (2) (C21+C22) Phytane n-C17 n-C18 (C28+C29)
103 026 024 103 102 325
NOTE (a)CPI = carbon preference index
Table 55 LDDH1 saturate gas chromatography data of core for 6623 m n-alkane distributions
Parameter Value
n-C12 17 n-C13 38 n-C14 55 n-C15 60 n-C16 65 n-C17 74 i-C19 19 n-C18 78 i-C20 19 n-C19 80 n-C20 79 n-C21 71 n-C22 64 n-C23 57 n-C25 43 n-C24 38 n-C27 31 n-C28 23 n-C29 19 n-C30 12 n-C31 10
64
Appendix 6
Table 61 Summary of data from Trainor waterbores (TWB) and Bullen waterbores (BWB)
Well AMG Elevation TD Status(b) Completion details Water Salinity Water level Flow rate Depth to consolidated AGD84 GL (m) (m) struck mgl(c) (m) (LHr) lithology aquifer(e) Z51(a) Interval (m) (100 mm PVC) (m) (mgl)(d)
TWB 1 473660E 453 122 comp 0ndash75 plain 63 7 300 24 2 880 12 m 7287404N 75ndash93 slotted (9 260) McFadden Fm 93ndash99 plain TWB 2 472 977E 475 23 abd nil 15 m 7285877N Skates Hills Fm dry TWB 3 473259E 475 50 abd nil 7 m 7285849N Skates Hills Fm dry TWB 4 463225 E 445 50 comp 0ndash22 plain 35 7 200 55 3 600 0 m 7286143N 22ndash34 slotted (8 140) Tertiary sand and gravel 23ndash60 plain TWB 5 463095E 445 31 comp 0ndash19 plain 13 26 000 655 3 600 Tertiary sand and gravel 7277721N 19ndash25 slotted (36 700) 25ndash31 plain TWB 6 457013E 455 50 comp 0ndash42 plain 38 920 119 600 0 m 7274352N 42ndash48 slotted (1 030) Cornelia Fm ss TWB 7 453739E 475 26 susp 0ndash2 plain 11 9 300 48 4 500 0 m 7263891N (10 500) Tertiary sand TWB 8 433893E 535 60 susp 0ndash2 plain 47 8 500 gt46 1 200 0 m 7245991N (10 900) Tertiary sand and Brassey Range Fm ss TWB 9 437219E 505 51 comp 0ndash47 plain 45 1 000 58 600 1 m 7235905N 47ndash51 slotted (990) Brassey Range Fm ss TWB 10 434927E 495 32 susp 0ndash2 plain 235 450 120 0 m 7225875N (500) Dolerite
65
BWB 1 287337E 580 122 abd Nil 1 m 7245861N Jilyili Fm dry BWB 2 288346E 545 50 comp 0ndash26 plain 15 630 3 29 000 0 m 7240423N 26ndash38 slotted (730) Tertiary sand and gravel 38ndash50 plain BWB 3 305637E 545 50 abd 19 8 800 43 7 200 0 m 7240423N (10 550) Tertiary ss BWB 4 320167E 515 445 comp 0ndash20 plain 9 980 445 24 000 0 m 7248097N 20ndash32 slotted (1 190) Tertiary ss 32ndash44 plain BWB 5 353393E 545 20 susp 0ndash2 plain 45 (970) 1 m 7238934N Basalt
NOTES (a) GPS accuracy ~ 150 m (b) Comp = completed abd = abandoned susp = suspended (c) Salinity from conductivity (d) Analysis total dissolved solids (e) Fm = Formation ss = sandstone
57
gravity data are dominated by a northwest-trending strong positive anomaly and there is little correlation with the
Bouguer gravity data
The poor magneticgravity correlation is confirmed by cross-correlation of the RTP magnetics and the gravity
gradient The correlation plot in Figure 49 shows little coherent response with numerous zones of positive and
negative correlation
Figure 45 Regional aeromagnetic data shallow layer separation filter (BMRAGSO data) gridded at 400 m
Results
In the north and east of the area on the Wells Foreland Sub-basin trend (refer to Figure 1 main text) we see a range
of quite deep 3D Euler depths and several trend directions with north-northwesterly dominant There are relatively few
shallow intrasedimentary solutions in this zone
The second area of deep 3D Euler solutions lies over the Blake depocentre (Figure 43) with several trend
directions
Elsewhere the 3D Euler results are dominated by shallow intrasedimentary depth solutions reflecting mainly the
dolerite sills dykes and the ring complex However where we do see basement-related solutions in the south and
west of the area they appear to be shallower than those noted for the Wells Foreland Sub-basin and the Blake
depocentre
58
Figure 46 Regional aeromagnetic data deep-layer separation filter (BMRAGSO data) gridded at 400 m
Figure 48 Regional aeromagnetic data pseudo-gravity transform (BMRAGSO data) gridded at 400 m
Figure 47 Regional aeromagnetic data reduced-to-pole (BMRAGSO data) gridded at 400 m
Figure 49 Regional aeromagnetic and gravity data gravitymagnetic correlation using RTP magnetics and gravity gradient (BMRAGSO data) gridded at 4 km
59
This subdivision of the area into two zones of deep solutions is consistent with interpreted depocentres
However the interference between sources at different levels and the complexity of the magnetic response of the
basement rocks precludes more refined interpretation at this stage
The area of deep 3D Euler solutions over the Blake depocentre correlates with the pronounced negative gravity
anomaly discussed in the gravity interpretation section Using a density contrast of -015 gcc the negative gravity
anomaly could indicate up to 6ndash8 km of low-density sedimentary rocks depending on assumptions about the regional
field
The area of deep 3D Euler solutions over the Wells Foreland Sub-basin has a complex gravity expression and no
clear basin structure emerges from inversion of these data As noted previously it is likely that observed gravity
anomalies reflect contrasts in basement density rather than basement topography
Separation filtering applied to the magnetic data helps to enhance the intrasedimentary magnetic signature and to
give a better impression of the basement magnetic signature even though separation of the basement response is not
perfect
Conclusions
Quantitative aeromagnetic interpretation using 3D Euler deconvolution supported by wavenumber filtering and image
processing has been successful in providing structural trend and depth information for the Savory Sub-basin
Quantitative magnetic interpretation has revealed two zones of relatively deep magnetic basement beneath the
Wells Foreland Sub-basin and the Blake depocentre
This analysis of the magnetic data supports interpreted depocentres but the complexity of the basement magnetic
signature and interference from sources at different depths precludes further refinement to a map of basement
topography
Regional gravity proved to be very useful in understanding the regional setting of the area and in providing
support for aspects of the interpretation The gravity data support the interpretation of the Blake depocentre
suggesting up to 6ndash8 km of low-density sedimentary rocks
The deep structure of the Savory Sub-basin area is obviously complex with different areas underlain by
Archaean and Proterozoic basement and with the Capricorn suture occurring in the centre of the area
60
Recommendations
The quantitative magnetic interpretation needs to be reconciled with geological models available for the area
In particular the zones tentatively identified as areas with thick sedimentary rocks the Wells Foreland Sub-
basin and the Blake depocentre need to be investigated
Cross sections should be prepared across the basin for joint magneticgravity modelling especially for the Blake
depocentre It is important to be able to explain the strong negative gravity anomaly in this area
In view of the effects of basement density contrasts on the gravity field for the northern part of the area we think
that additional gravity interpretation and acquisition of new gravity data may not be justified as they will not
contribute significantly to understanding basin evolution and structure
It is recommended that GSWA try to get access to company confidential high-resolution aeromagnetic data
rather than flying new surveys The GSWA might offer to fund flying of new infill areas as a bargaining point
References
The original text of this report by Cowan (1995) and 1500 000 scale maps are filed in the GSWA Library under
S10331
COWAN D 1995 Savory Basin quantitative magnetic interpretation Western Australia Geological Survey S-series
S10331 (unpublished)
VACQUIER V STEENLAND N C HENDERSON R G and ZIETZ I 1951 Interpretation of aeromagnetic
maps The Geological Society of America Memoir 47 151p
WILLIAMS I R 1992 Geology of the Savory Basin Western Australia Western Australia Geological Survey
Bulletin 141 115p
61
Appendix 5
Geochemistry
MKS38 250398
Saturate FractionC12+ GLC
1217
Pr18
Ph
22
31CSR WELL-13 315m Cuttings
Figure 51 Canning Stock Route Well 13 gas chromatograph of extract of auger drill sample
12
17
18
22
31
Pr Ph
LDDH 1 6623m CoreSaturate FractionC12+ GLC
MKS35 240398
Figure 52 Gas chromatograph of extract from core sample at 6623 m LDDH1
62
Table 51 Canning Stock Route Well 13 auger drill samples
GSWA sample Drill depth (m)(a) Comments
135601 150 At watertable 135602 203 (all samples consist 135603 310 of sand mud and water) 135604 315 At total depth
NOTE (a) Datum for drill depth is the top of sediment fill in the well which is 155 m below ground level (ie the total depth of 315 m is 47 m below ground level)
Table 52 Canning Stock Route Well 13 gas chromatography data for 315 m depth sediment sample
Parameter Value
Weight of rock extracted (grams) 945 Total extract (ppm) 519 n-Alkane distribution n-C12 07 n-C13 23 n-C14 26 n-C15 22 n-C16 19 n-C17 14 i-C19 23 n-C18 14 i-C20 08 n-C19 11 n-C20 16 n-C21 25 n-C22 29 n-C23 70 n-C24 42 n-C25 95 n-C26 43 n-C27 83 n-C28 38 n-C29 87 n-C30 31 n-C31 273 Alkane compositional data Pristane phytane ratio 279 Pristane n-C17 ratio 161 Phytane n-C18 ratio 059 CPI (1)(a) 284 CPI (2) 209 (C21 + C22) (C28 + C29) 043
NOTE (a) CPI= Carbon preference index
63
Table 53 LDDH1 extract liquid chromatography data for 6623 m concentration
Rock extracted Total extract (grams) (ppm)
702 313
NOTE ppm= parts per million
Table 54 LDDH1 saturate gas chromatography data of core for 6623 m alkane composition
Pristane Pristane Phytane (a) CPI (1) CPI (2) (C21+C22) Phytane n-C17 n-C18 (C28+C29)
103 026 024 103 102 325
NOTE (a)CPI = carbon preference index
Table 55 LDDH1 saturate gas chromatography data of core for 6623 m n-alkane distributions
Parameter Value
n-C12 17 n-C13 38 n-C14 55 n-C15 60 n-C16 65 n-C17 74 i-C19 19 n-C18 78 i-C20 19 n-C19 80 n-C20 79 n-C21 71 n-C22 64 n-C23 57 n-C25 43 n-C24 38 n-C27 31 n-C28 23 n-C29 19 n-C30 12 n-C31 10
64
Appendix 6
Table 61 Summary of data from Trainor waterbores (TWB) and Bullen waterbores (BWB)
Well AMG Elevation TD Status(b) Completion details Water Salinity Water level Flow rate Depth to consolidated AGD84 GL (m) (m) struck mgl(c) (m) (LHr) lithology aquifer(e) Z51(a) Interval (m) (100 mm PVC) (m) (mgl)(d)
TWB 1 473660E 453 122 comp 0ndash75 plain 63 7 300 24 2 880 12 m 7287404N 75ndash93 slotted (9 260) McFadden Fm 93ndash99 plain TWB 2 472 977E 475 23 abd nil 15 m 7285877N Skates Hills Fm dry TWB 3 473259E 475 50 abd nil 7 m 7285849N Skates Hills Fm dry TWB 4 463225 E 445 50 comp 0ndash22 plain 35 7 200 55 3 600 0 m 7286143N 22ndash34 slotted (8 140) Tertiary sand and gravel 23ndash60 plain TWB 5 463095E 445 31 comp 0ndash19 plain 13 26 000 655 3 600 Tertiary sand and gravel 7277721N 19ndash25 slotted (36 700) 25ndash31 plain TWB 6 457013E 455 50 comp 0ndash42 plain 38 920 119 600 0 m 7274352N 42ndash48 slotted (1 030) Cornelia Fm ss TWB 7 453739E 475 26 susp 0ndash2 plain 11 9 300 48 4 500 0 m 7263891N (10 500) Tertiary sand TWB 8 433893E 535 60 susp 0ndash2 plain 47 8 500 gt46 1 200 0 m 7245991N (10 900) Tertiary sand and Brassey Range Fm ss TWB 9 437219E 505 51 comp 0ndash47 plain 45 1 000 58 600 1 m 7235905N 47ndash51 slotted (990) Brassey Range Fm ss TWB 10 434927E 495 32 susp 0ndash2 plain 235 450 120 0 m 7225875N (500) Dolerite
65
BWB 1 287337E 580 122 abd Nil 1 m 7245861N Jilyili Fm dry BWB 2 288346E 545 50 comp 0ndash26 plain 15 630 3 29 000 0 m 7240423N 26ndash38 slotted (730) Tertiary sand and gravel 38ndash50 plain BWB 3 305637E 545 50 abd 19 8 800 43 7 200 0 m 7240423N (10 550) Tertiary ss BWB 4 320167E 515 445 comp 0ndash20 plain 9 980 445 24 000 0 m 7248097N 20ndash32 slotted (1 190) Tertiary ss 32ndash44 plain BWB 5 353393E 545 20 susp 0ndash2 plain 45 (970) 1 m 7238934N Basalt
NOTES (a) GPS accuracy ~ 150 m (b) Comp = completed abd = abandoned susp = suspended (c) Salinity from conductivity (d) Analysis total dissolved solids (e) Fm = Formation ss = sandstone
58
Figure 46 Regional aeromagnetic data deep-layer separation filter (BMRAGSO data) gridded at 400 m
Figure 48 Regional aeromagnetic data pseudo-gravity transform (BMRAGSO data) gridded at 400 m
Figure 47 Regional aeromagnetic data reduced-to-pole (BMRAGSO data) gridded at 400 m
Figure 49 Regional aeromagnetic and gravity data gravitymagnetic correlation using RTP magnetics and gravity gradient (BMRAGSO data) gridded at 4 km
59
This subdivision of the area into two zones of deep solutions is consistent with interpreted depocentres
However the interference between sources at different levels and the complexity of the magnetic response of the
basement rocks precludes more refined interpretation at this stage
The area of deep 3D Euler solutions over the Blake depocentre correlates with the pronounced negative gravity
anomaly discussed in the gravity interpretation section Using a density contrast of -015 gcc the negative gravity
anomaly could indicate up to 6ndash8 km of low-density sedimentary rocks depending on assumptions about the regional
field
The area of deep 3D Euler solutions over the Wells Foreland Sub-basin has a complex gravity expression and no
clear basin structure emerges from inversion of these data As noted previously it is likely that observed gravity
anomalies reflect contrasts in basement density rather than basement topography
Separation filtering applied to the magnetic data helps to enhance the intrasedimentary magnetic signature and to
give a better impression of the basement magnetic signature even though separation of the basement response is not
perfect
Conclusions
Quantitative aeromagnetic interpretation using 3D Euler deconvolution supported by wavenumber filtering and image
processing has been successful in providing structural trend and depth information for the Savory Sub-basin
Quantitative magnetic interpretation has revealed two zones of relatively deep magnetic basement beneath the
Wells Foreland Sub-basin and the Blake depocentre
This analysis of the magnetic data supports interpreted depocentres but the complexity of the basement magnetic
signature and interference from sources at different depths precludes further refinement to a map of basement
topography
Regional gravity proved to be very useful in understanding the regional setting of the area and in providing
support for aspects of the interpretation The gravity data support the interpretation of the Blake depocentre
suggesting up to 6ndash8 km of low-density sedimentary rocks
The deep structure of the Savory Sub-basin area is obviously complex with different areas underlain by
Archaean and Proterozoic basement and with the Capricorn suture occurring in the centre of the area
60
Recommendations
The quantitative magnetic interpretation needs to be reconciled with geological models available for the area
In particular the zones tentatively identified as areas with thick sedimentary rocks the Wells Foreland Sub-
basin and the Blake depocentre need to be investigated
Cross sections should be prepared across the basin for joint magneticgravity modelling especially for the Blake
depocentre It is important to be able to explain the strong negative gravity anomaly in this area
In view of the effects of basement density contrasts on the gravity field for the northern part of the area we think
that additional gravity interpretation and acquisition of new gravity data may not be justified as they will not
contribute significantly to understanding basin evolution and structure
It is recommended that GSWA try to get access to company confidential high-resolution aeromagnetic data
rather than flying new surveys The GSWA might offer to fund flying of new infill areas as a bargaining point
References
The original text of this report by Cowan (1995) and 1500 000 scale maps are filed in the GSWA Library under
S10331
COWAN D 1995 Savory Basin quantitative magnetic interpretation Western Australia Geological Survey S-series
S10331 (unpublished)
VACQUIER V STEENLAND N C HENDERSON R G and ZIETZ I 1951 Interpretation of aeromagnetic
maps The Geological Society of America Memoir 47 151p
WILLIAMS I R 1992 Geology of the Savory Basin Western Australia Western Australia Geological Survey
Bulletin 141 115p
61
Appendix 5
Geochemistry
MKS38 250398
Saturate FractionC12+ GLC
1217
Pr18
Ph
22
31CSR WELL-13 315m Cuttings
Figure 51 Canning Stock Route Well 13 gas chromatograph of extract of auger drill sample
12
17
18
22
31
Pr Ph
LDDH 1 6623m CoreSaturate FractionC12+ GLC
MKS35 240398
Figure 52 Gas chromatograph of extract from core sample at 6623 m LDDH1
62
Table 51 Canning Stock Route Well 13 auger drill samples
GSWA sample Drill depth (m)(a) Comments
135601 150 At watertable 135602 203 (all samples consist 135603 310 of sand mud and water) 135604 315 At total depth
NOTE (a) Datum for drill depth is the top of sediment fill in the well which is 155 m below ground level (ie the total depth of 315 m is 47 m below ground level)
Table 52 Canning Stock Route Well 13 gas chromatography data for 315 m depth sediment sample
Parameter Value
Weight of rock extracted (grams) 945 Total extract (ppm) 519 n-Alkane distribution n-C12 07 n-C13 23 n-C14 26 n-C15 22 n-C16 19 n-C17 14 i-C19 23 n-C18 14 i-C20 08 n-C19 11 n-C20 16 n-C21 25 n-C22 29 n-C23 70 n-C24 42 n-C25 95 n-C26 43 n-C27 83 n-C28 38 n-C29 87 n-C30 31 n-C31 273 Alkane compositional data Pristane phytane ratio 279 Pristane n-C17 ratio 161 Phytane n-C18 ratio 059 CPI (1)(a) 284 CPI (2) 209 (C21 + C22) (C28 + C29) 043
NOTE (a) CPI= Carbon preference index
63
Table 53 LDDH1 extract liquid chromatography data for 6623 m concentration
Rock extracted Total extract (grams) (ppm)
702 313
NOTE ppm= parts per million
Table 54 LDDH1 saturate gas chromatography data of core for 6623 m alkane composition
Pristane Pristane Phytane (a) CPI (1) CPI (2) (C21+C22) Phytane n-C17 n-C18 (C28+C29)
103 026 024 103 102 325
NOTE (a)CPI = carbon preference index
Table 55 LDDH1 saturate gas chromatography data of core for 6623 m n-alkane distributions
Parameter Value
n-C12 17 n-C13 38 n-C14 55 n-C15 60 n-C16 65 n-C17 74 i-C19 19 n-C18 78 i-C20 19 n-C19 80 n-C20 79 n-C21 71 n-C22 64 n-C23 57 n-C25 43 n-C24 38 n-C27 31 n-C28 23 n-C29 19 n-C30 12 n-C31 10
64
Appendix 6
Table 61 Summary of data from Trainor waterbores (TWB) and Bullen waterbores (BWB)
Well AMG Elevation TD Status(b) Completion details Water Salinity Water level Flow rate Depth to consolidated AGD84 GL (m) (m) struck mgl(c) (m) (LHr) lithology aquifer(e) Z51(a) Interval (m) (100 mm PVC) (m) (mgl)(d)
TWB 1 473660E 453 122 comp 0ndash75 plain 63 7 300 24 2 880 12 m 7287404N 75ndash93 slotted (9 260) McFadden Fm 93ndash99 plain TWB 2 472 977E 475 23 abd nil 15 m 7285877N Skates Hills Fm dry TWB 3 473259E 475 50 abd nil 7 m 7285849N Skates Hills Fm dry TWB 4 463225 E 445 50 comp 0ndash22 plain 35 7 200 55 3 600 0 m 7286143N 22ndash34 slotted (8 140) Tertiary sand and gravel 23ndash60 plain TWB 5 463095E 445 31 comp 0ndash19 plain 13 26 000 655 3 600 Tertiary sand and gravel 7277721N 19ndash25 slotted (36 700) 25ndash31 plain TWB 6 457013E 455 50 comp 0ndash42 plain 38 920 119 600 0 m 7274352N 42ndash48 slotted (1 030) Cornelia Fm ss TWB 7 453739E 475 26 susp 0ndash2 plain 11 9 300 48 4 500 0 m 7263891N (10 500) Tertiary sand TWB 8 433893E 535 60 susp 0ndash2 plain 47 8 500 gt46 1 200 0 m 7245991N (10 900) Tertiary sand and Brassey Range Fm ss TWB 9 437219E 505 51 comp 0ndash47 plain 45 1 000 58 600 1 m 7235905N 47ndash51 slotted (990) Brassey Range Fm ss TWB 10 434927E 495 32 susp 0ndash2 plain 235 450 120 0 m 7225875N (500) Dolerite
65
BWB 1 287337E 580 122 abd Nil 1 m 7245861N Jilyili Fm dry BWB 2 288346E 545 50 comp 0ndash26 plain 15 630 3 29 000 0 m 7240423N 26ndash38 slotted (730) Tertiary sand and gravel 38ndash50 plain BWB 3 305637E 545 50 abd 19 8 800 43 7 200 0 m 7240423N (10 550) Tertiary ss BWB 4 320167E 515 445 comp 0ndash20 plain 9 980 445 24 000 0 m 7248097N 20ndash32 slotted (1 190) Tertiary ss 32ndash44 plain BWB 5 353393E 545 20 susp 0ndash2 plain 45 (970) 1 m 7238934N Basalt
NOTES (a) GPS accuracy ~ 150 m (b) Comp = completed abd = abandoned susp = suspended (c) Salinity from conductivity (d) Analysis total dissolved solids (e) Fm = Formation ss = sandstone
59
This subdivision of the area into two zones of deep solutions is consistent with interpreted depocentres
However the interference between sources at different levels and the complexity of the magnetic response of the
basement rocks precludes more refined interpretation at this stage
The area of deep 3D Euler solutions over the Blake depocentre correlates with the pronounced negative gravity
anomaly discussed in the gravity interpretation section Using a density contrast of -015 gcc the negative gravity
anomaly could indicate up to 6ndash8 km of low-density sedimentary rocks depending on assumptions about the regional
field
The area of deep 3D Euler solutions over the Wells Foreland Sub-basin has a complex gravity expression and no
clear basin structure emerges from inversion of these data As noted previously it is likely that observed gravity
anomalies reflect contrasts in basement density rather than basement topography
Separation filtering applied to the magnetic data helps to enhance the intrasedimentary magnetic signature and to
give a better impression of the basement magnetic signature even though separation of the basement response is not
perfect
Conclusions
Quantitative aeromagnetic interpretation using 3D Euler deconvolution supported by wavenumber filtering and image
processing has been successful in providing structural trend and depth information for the Savory Sub-basin
Quantitative magnetic interpretation has revealed two zones of relatively deep magnetic basement beneath the
Wells Foreland Sub-basin and the Blake depocentre
This analysis of the magnetic data supports interpreted depocentres but the complexity of the basement magnetic
signature and interference from sources at different depths precludes further refinement to a map of basement
topography
Regional gravity proved to be very useful in understanding the regional setting of the area and in providing
support for aspects of the interpretation The gravity data support the interpretation of the Blake depocentre
suggesting up to 6ndash8 km of low-density sedimentary rocks
The deep structure of the Savory Sub-basin area is obviously complex with different areas underlain by
Archaean and Proterozoic basement and with the Capricorn suture occurring in the centre of the area
60
Recommendations
The quantitative magnetic interpretation needs to be reconciled with geological models available for the area
In particular the zones tentatively identified as areas with thick sedimentary rocks the Wells Foreland Sub-
basin and the Blake depocentre need to be investigated
Cross sections should be prepared across the basin for joint magneticgravity modelling especially for the Blake
depocentre It is important to be able to explain the strong negative gravity anomaly in this area
In view of the effects of basement density contrasts on the gravity field for the northern part of the area we think
that additional gravity interpretation and acquisition of new gravity data may not be justified as they will not
contribute significantly to understanding basin evolution and structure
It is recommended that GSWA try to get access to company confidential high-resolution aeromagnetic data
rather than flying new surveys The GSWA might offer to fund flying of new infill areas as a bargaining point
References
The original text of this report by Cowan (1995) and 1500 000 scale maps are filed in the GSWA Library under
S10331
COWAN D 1995 Savory Basin quantitative magnetic interpretation Western Australia Geological Survey S-series
S10331 (unpublished)
VACQUIER V STEENLAND N C HENDERSON R G and ZIETZ I 1951 Interpretation of aeromagnetic
maps The Geological Society of America Memoir 47 151p
WILLIAMS I R 1992 Geology of the Savory Basin Western Australia Western Australia Geological Survey
Bulletin 141 115p
61
Appendix 5
Geochemistry
MKS38 250398
Saturate FractionC12+ GLC
1217
Pr18
Ph
22
31CSR WELL-13 315m Cuttings
Figure 51 Canning Stock Route Well 13 gas chromatograph of extract of auger drill sample
12
17
18
22
31
Pr Ph
LDDH 1 6623m CoreSaturate FractionC12+ GLC
MKS35 240398
Figure 52 Gas chromatograph of extract from core sample at 6623 m LDDH1
62
Table 51 Canning Stock Route Well 13 auger drill samples
GSWA sample Drill depth (m)(a) Comments
135601 150 At watertable 135602 203 (all samples consist 135603 310 of sand mud and water) 135604 315 At total depth
NOTE (a) Datum for drill depth is the top of sediment fill in the well which is 155 m below ground level (ie the total depth of 315 m is 47 m below ground level)
Table 52 Canning Stock Route Well 13 gas chromatography data for 315 m depth sediment sample
Parameter Value
Weight of rock extracted (grams) 945 Total extract (ppm) 519 n-Alkane distribution n-C12 07 n-C13 23 n-C14 26 n-C15 22 n-C16 19 n-C17 14 i-C19 23 n-C18 14 i-C20 08 n-C19 11 n-C20 16 n-C21 25 n-C22 29 n-C23 70 n-C24 42 n-C25 95 n-C26 43 n-C27 83 n-C28 38 n-C29 87 n-C30 31 n-C31 273 Alkane compositional data Pristane phytane ratio 279 Pristane n-C17 ratio 161 Phytane n-C18 ratio 059 CPI (1)(a) 284 CPI (2) 209 (C21 + C22) (C28 + C29) 043
NOTE (a) CPI= Carbon preference index
63
Table 53 LDDH1 extract liquid chromatography data for 6623 m concentration
Rock extracted Total extract (grams) (ppm)
702 313
NOTE ppm= parts per million
Table 54 LDDH1 saturate gas chromatography data of core for 6623 m alkane composition
Pristane Pristane Phytane (a) CPI (1) CPI (2) (C21+C22) Phytane n-C17 n-C18 (C28+C29)
103 026 024 103 102 325
NOTE (a)CPI = carbon preference index
Table 55 LDDH1 saturate gas chromatography data of core for 6623 m n-alkane distributions
Parameter Value
n-C12 17 n-C13 38 n-C14 55 n-C15 60 n-C16 65 n-C17 74 i-C19 19 n-C18 78 i-C20 19 n-C19 80 n-C20 79 n-C21 71 n-C22 64 n-C23 57 n-C25 43 n-C24 38 n-C27 31 n-C28 23 n-C29 19 n-C30 12 n-C31 10
64
Appendix 6
Table 61 Summary of data from Trainor waterbores (TWB) and Bullen waterbores (BWB)
Well AMG Elevation TD Status(b) Completion details Water Salinity Water level Flow rate Depth to consolidated AGD84 GL (m) (m) struck mgl(c) (m) (LHr) lithology aquifer(e) Z51(a) Interval (m) (100 mm PVC) (m) (mgl)(d)
TWB 1 473660E 453 122 comp 0ndash75 plain 63 7 300 24 2 880 12 m 7287404N 75ndash93 slotted (9 260) McFadden Fm 93ndash99 plain TWB 2 472 977E 475 23 abd nil 15 m 7285877N Skates Hills Fm dry TWB 3 473259E 475 50 abd nil 7 m 7285849N Skates Hills Fm dry TWB 4 463225 E 445 50 comp 0ndash22 plain 35 7 200 55 3 600 0 m 7286143N 22ndash34 slotted (8 140) Tertiary sand and gravel 23ndash60 plain TWB 5 463095E 445 31 comp 0ndash19 plain 13 26 000 655 3 600 Tertiary sand and gravel 7277721N 19ndash25 slotted (36 700) 25ndash31 plain TWB 6 457013E 455 50 comp 0ndash42 plain 38 920 119 600 0 m 7274352N 42ndash48 slotted (1 030) Cornelia Fm ss TWB 7 453739E 475 26 susp 0ndash2 plain 11 9 300 48 4 500 0 m 7263891N (10 500) Tertiary sand TWB 8 433893E 535 60 susp 0ndash2 plain 47 8 500 gt46 1 200 0 m 7245991N (10 900) Tertiary sand and Brassey Range Fm ss TWB 9 437219E 505 51 comp 0ndash47 plain 45 1 000 58 600 1 m 7235905N 47ndash51 slotted (990) Brassey Range Fm ss TWB 10 434927E 495 32 susp 0ndash2 plain 235 450 120 0 m 7225875N (500) Dolerite
65
BWB 1 287337E 580 122 abd Nil 1 m 7245861N Jilyili Fm dry BWB 2 288346E 545 50 comp 0ndash26 plain 15 630 3 29 000 0 m 7240423N 26ndash38 slotted (730) Tertiary sand and gravel 38ndash50 plain BWB 3 305637E 545 50 abd 19 8 800 43 7 200 0 m 7240423N (10 550) Tertiary ss BWB 4 320167E 515 445 comp 0ndash20 plain 9 980 445 24 000 0 m 7248097N 20ndash32 slotted (1 190) Tertiary ss 32ndash44 plain BWB 5 353393E 545 20 susp 0ndash2 plain 45 (970) 1 m 7238934N Basalt
NOTES (a) GPS accuracy ~ 150 m (b) Comp = completed abd = abandoned susp = suspended (c) Salinity from conductivity (d) Analysis total dissolved solids (e) Fm = Formation ss = sandstone
60
Recommendations
The quantitative magnetic interpretation needs to be reconciled with geological models available for the area
In particular the zones tentatively identified as areas with thick sedimentary rocks the Wells Foreland Sub-
basin and the Blake depocentre need to be investigated
Cross sections should be prepared across the basin for joint magneticgravity modelling especially for the Blake
depocentre It is important to be able to explain the strong negative gravity anomaly in this area
In view of the effects of basement density contrasts on the gravity field for the northern part of the area we think
that additional gravity interpretation and acquisition of new gravity data may not be justified as they will not
contribute significantly to understanding basin evolution and structure
It is recommended that GSWA try to get access to company confidential high-resolution aeromagnetic data
rather than flying new surveys The GSWA might offer to fund flying of new infill areas as a bargaining point
References
The original text of this report by Cowan (1995) and 1500 000 scale maps are filed in the GSWA Library under
S10331
COWAN D 1995 Savory Basin quantitative magnetic interpretation Western Australia Geological Survey S-series
S10331 (unpublished)
VACQUIER V STEENLAND N C HENDERSON R G and ZIETZ I 1951 Interpretation of aeromagnetic
maps The Geological Society of America Memoir 47 151p
WILLIAMS I R 1992 Geology of the Savory Basin Western Australia Western Australia Geological Survey
Bulletin 141 115p
61
Appendix 5
Geochemistry
MKS38 250398
Saturate FractionC12+ GLC
1217
Pr18
Ph
22
31CSR WELL-13 315m Cuttings
Figure 51 Canning Stock Route Well 13 gas chromatograph of extract of auger drill sample
12
17
18
22
31
Pr Ph
LDDH 1 6623m CoreSaturate FractionC12+ GLC
MKS35 240398
Figure 52 Gas chromatograph of extract from core sample at 6623 m LDDH1
62
Table 51 Canning Stock Route Well 13 auger drill samples
GSWA sample Drill depth (m)(a) Comments
135601 150 At watertable 135602 203 (all samples consist 135603 310 of sand mud and water) 135604 315 At total depth
NOTE (a) Datum for drill depth is the top of sediment fill in the well which is 155 m below ground level (ie the total depth of 315 m is 47 m below ground level)
Table 52 Canning Stock Route Well 13 gas chromatography data for 315 m depth sediment sample
Parameter Value
Weight of rock extracted (grams) 945 Total extract (ppm) 519 n-Alkane distribution n-C12 07 n-C13 23 n-C14 26 n-C15 22 n-C16 19 n-C17 14 i-C19 23 n-C18 14 i-C20 08 n-C19 11 n-C20 16 n-C21 25 n-C22 29 n-C23 70 n-C24 42 n-C25 95 n-C26 43 n-C27 83 n-C28 38 n-C29 87 n-C30 31 n-C31 273 Alkane compositional data Pristane phytane ratio 279 Pristane n-C17 ratio 161 Phytane n-C18 ratio 059 CPI (1)(a) 284 CPI (2) 209 (C21 + C22) (C28 + C29) 043
NOTE (a) CPI= Carbon preference index
63
Table 53 LDDH1 extract liquid chromatography data for 6623 m concentration
Rock extracted Total extract (grams) (ppm)
702 313
NOTE ppm= parts per million
Table 54 LDDH1 saturate gas chromatography data of core for 6623 m alkane composition
Pristane Pristane Phytane (a) CPI (1) CPI (2) (C21+C22) Phytane n-C17 n-C18 (C28+C29)
103 026 024 103 102 325
NOTE (a)CPI = carbon preference index
Table 55 LDDH1 saturate gas chromatography data of core for 6623 m n-alkane distributions
Parameter Value
n-C12 17 n-C13 38 n-C14 55 n-C15 60 n-C16 65 n-C17 74 i-C19 19 n-C18 78 i-C20 19 n-C19 80 n-C20 79 n-C21 71 n-C22 64 n-C23 57 n-C25 43 n-C24 38 n-C27 31 n-C28 23 n-C29 19 n-C30 12 n-C31 10
64
Appendix 6
Table 61 Summary of data from Trainor waterbores (TWB) and Bullen waterbores (BWB)
Well AMG Elevation TD Status(b) Completion details Water Salinity Water level Flow rate Depth to consolidated AGD84 GL (m) (m) struck mgl(c) (m) (LHr) lithology aquifer(e) Z51(a) Interval (m) (100 mm PVC) (m) (mgl)(d)
TWB 1 473660E 453 122 comp 0ndash75 plain 63 7 300 24 2 880 12 m 7287404N 75ndash93 slotted (9 260) McFadden Fm 93ndash99 plain TWB 2 472 977E 475 23 abd nil 15 m 7285877N Skates Hills Fm dry TWB 3 473259E 475 50 abd nil 7 m 7285849N Skates Hills Fm dry TWB 4 463225 E 445 50 comp 0ndash22 plain 35 7 200 55 3 600 0 m 7286143N 22ndash34 slotted (8 140) Tertiary sand and gravel 23ndash60 plain TWB 5 463095E 445 31 comp 0ndash19 plain 13 26 000 655 3 600 Tertiary sand and gravel 7277721N 19ndash25 slotted (36 700) 25ndash31 plain TWB 6 457013E 455 50 comp 0ndash42 plain 38 920 119 600 0 m 7274352N 42ndash48 slotted (1 030) Cornelia Fm ss TWB 7 453739E 475 26 susp 0ndash2 plain 11 9 300 48 4 500 0 m 7263891N (10 500) Tertiary sand TWB 8 433893E 535 60 susp 0ndash2 plain 47 8 500 gt46 1 200 0 m 7245991N (10 900) Tertiary sand and Brassey Range Fm ss TWB 9 437219E 505 51 comp 0ndash47 plain 45 1 000 58 600 1 m 7235905N 47ndash51 slotted (990) Brassey Range Fm ss TWB 10 434927E 495 32 susp 0ndash2 plain 235 450 120 0 m 7225875N (500) Dolerite
65
BWB 1 287337E 580 122 abd Nil 1 m 7245861N Jilyili Fm dry BWB 2 288346E 545 50 comp 0ndash26 plain 15 630 3 29 000 0 m 7240423N 26ndash38 slotted (730) Tertiary sand and gravel 38ndash50 plain BWB 3 305637E 545 50 abd 19 8 800 43 7 200 0 m 7240423N (10 550) Tertiary ss BWB 4 320167E 515 445 comp 0ndash20 plain 9 980 445 24 000 0 m 7248097N 20ndash32 slotted (1 190) Tertiary ss 32ndash44 plain BWB 5 353393E 545 20 susp 0ndash2 plain 45 (970) 1 m 7238934N Basalt
NOTES (a) GPS accuracy ~ 150 m (b) Comp = completed abd = abandoned susp = suspended (c) Salinity from conductivity (d) Analysis total dissolved solids (e) Fm = Formation ss = sandstone
61
Appendix 5
Geochemistry
MKS38 250398
Saturate FractionC12+ GLC
1217
Pr18
Ph
22
31CSR WELL-13 315m Cuttings
Figure 51 Canning Stock Route Well 13 gas chromatograph of extract of auger drill sample
12
17
18
22
31
Pr Ph
LDDH 1 6623m CoreSaturate FractionC12+ GLC
MKS35 240398
Figure 52 Gas chromatograph of extract from core sample at 6623 m LDDH1
62
Table 51 Canning Stock Route Well 13 auger drill samples
GSWA sample Drill depth (m)(a) Comments
135601 150 At watertable 135602 203 (all samples consist 135603 310 of sand mud and water) 135604 315 At total depth
NOTE (a) Datum for drill depth is the top of sediment fill in the well which is 155 m below ground level (ie the total depth of 315 m is 47 m below ground level)
Table 52 Canning Stock Route Well 13 gas chromatography data for 315 m depth sediment sample
Parameter Value
Weight of rock extracted (grams) 945 Total extract (ppm) 519 n-Alkane distribution n-C12 07 n-C13 23 n-C14 26 n-C15 22 n-C16 19 n-C17 14 i-C19 23 n-C18 14 i-C20 08 n-C19 11 n-C20 16 n-C21 25 n-C22 29 n-C23 70 n-C24 42 n-C25 95 n-C26 43 n-C27 83 n-C28 38 n-C29 87 n-C30 31 n-C31 273 Alkane compositional data Pristane phytane ratio 279 Pristane n-C17 ratio 161 Phytane n-C18 ratio 059 CPI (1)(a) 284 CPI (2) 209 (C21 + C22) (C28 + C29) 043
NOTE (a) CPI= Carbon preference index
63
Table 53 LDDH1 extract liquid chromatography data for 6623 m concentration
Rock extracted Total extract (grams) (ppm)
702 313
NOTE ppm= parts per million
Table 54 LDDH1 saturate gas chromatography data of core for 6623 m alkane composition
Pristane Pristane Phytane (a) CPI (1) CPI (2) (C21+C22) Phytane n-C17 n-C18 (C28+C29)
103 026 024 103 102 325
NOTE (a)CPI = carbon preference index
Table 55 LDDH1 saturate gas chromatography data of core for 6623 m n-alkane distributions
Parameter Value
n-C12 17 n-C13 38 n-C14 55 n-C15 60 n-C16 65 n-C17 74 i-C19 19 n-C18 78 i-C20 19 n-C19 80 n-C20 79 n-C21 71 n-C22 64 n-C23 57 n-C25 43 n-C24 38 n-C27 31 n-C28 23 n-C29 19 n-C30 12 n-C31 10
64
Appendix 6
Table 61 Summary of data from Trainor waterbores (TWB) and Bullen waterbores (BWB)
Well AMG Elevation TD Status(b) Completion details Water Salinity Water level Flow rate Depth to consolidated AGD84 GL (m) (m) struck mgl(c) (m) (LHr) lithology aquifer(e) Z51(a) Interval (m) (100 mm PVC) (m) (mgl)(d)
TWB 1 473660E 453 122 comp 0ndash75 plain 63 7 300 24 2 880 12 m 7287404N 75ndash93 slotted (9 260) McFadden Fm 93ndash99 plain TWB 2 472 977E 475 23 abd nil 15 m 7285877N Skates Hills Fm dry TWB 3 473259E 475 50 abd nil 7 m 7285849N Skates Hills Fm dry TWB 4 463225 E 445 50 comp 0ndash22 plain 35 7 200 55 3 600 0 m 7286143N 22ndash34 slotted (8 140) Tertiary sand and gravel 23ndash60 plain TWB 5 463095E 445 31 comp 0ndash19 plain 13 26 000 655 3 600 Tertiary sand and gravel 7277721N 19ndash25 slotted (36 700) 25ndash31 plain TWB 6 457013E 455 50 comp 0ndash42 plain 38 920 119 600 0 m 7274352N 42ndash48 slotted (1 030) Cornelia Fm ss TWB 7 453739E 475 26 susp 0ndash2 plain 11 9 300 48 4 500 0 m 7263891N (10 500) Tertiary sand TWB 8 433893E 535 60 susp 0ndash2 plain 47 8 500 gt46 1 200 0 m 7245991N (10 900) Tertiary sand and Brassey Range Fm ss TWB 9 437219E 505 51 comp 0ndash47 plain 45 1 000 58 600 1 m 7235905N 47ndash51 slotted (990) Brassey Range Fm ss TWB 10 434927E 495 32 susp 0ndash2 plain 235 450 120 0 m 7225875N (500) Dolerite
65
BWB 1 287337E 580 122 abd Nil 1 m 7245861N Jilyili Fm dry BWB 2 288346E 545 50 comp 0ndash26 plain 15 630 3 29 000 0 m 7240423N 26ndash38 slotted (730) Tertiary sand and gravel 38ndash50 plain BWB 3 305637E 545 50 abd 19 8 800 43 7 200 0 m 7240423N (10 550) Tertiary ss BWB 4 320167E 515 445 comp 0ndash20 plain 9 980 445 24 000 0 m 7248097N 20ndash32 slotted (1 190) Tertiary ss 32ndash44 plain BWB 5 353393E 545 20 susp 0ndash2 plain 45 (970) 1 m 7238934N Basalt
NOTES (a) GPS accuracy ~ 150 m (b) Comp = completed abd = abandoned susp = suspended (c) Salinity from conductivity (d) Analysis total dissolved solids (e) Fm = Formation ss = sandstone
62
Table 51 Canning Stock Route Well 13 auger drill samples
GSWA sample Drill depth (m)(a) Comments
135601 150 At watertable 135602 203 (all samples consist 135603 310 of sand mud and water) 135604 315 At total depth
NOTE (a) Datum for drill depth is the top of sediment fill in the well which is 155 m below ground level (ie the total depth of 315 m is 47 m below ground level)
Table 52 Canning Stock Route Well 13 gas chromatography data for 315 m depth sediment sample
Parameter Value
Weight of rock extracted (grams) 945 Total extract (ppm) 519 n-Alkane distribution n-C12 07 n-C13 23 n-C14 26 n-C15 22 n-C16 19 n-C17 14 i-C19 23 n-C18 14 i-C20 08 n-C19 11 n-C20 16 n-C21 25 n-C22 29 n-C23 70 n-C24 42 n-C25 95 n-C26 43 n-C27 83 n-C28 38 n-C29 87 n-C30 31 n-C31 273 Alkane compositional data Pristane phytane ratio 279 Pristane n-C17 ratio 161 Phytane n-C18 ratio 059 CPI (1)(a) 284 CPI (2) 209 (C21 + C22) (C28 + C29) 043
NOTE (a) CPI= Carbon preference index
63
Table 53 LDDH1 extract liquid chromatography data for 6623 m concentration
Rock extracted Total extract (grams) (ppm)
702 313
NOTE ppm= parts per million
Table 54 LDDH1 saturate gas chromatography data of core for 6623 m alkane composition
Pristane Pristane Phytane (a) CPI (1) CPI (2) (C21+C22) Phytane n-C17 n-C18 (C28+C29)
103 026 024 103 102 325
NOTE (a)CPI = carbon preference index
Table 55 LDDH1 saturate gas chromatography data of core for 6623 m n-alkane distributions
Parameter Value
n-C12 17 n-C13 38 n-C14 55 n-C15 60 n-C16 65 n-C17 74 i-C19 19 n-C18 78 i-C20 19 n-C19 80 n-C20 79 n-C21 71 n-C22 64 n-C23 57 n-C25 43 n-C24 38 n-C27 31 n-C28 23 n-C29 19 n-C30 12 n-C31 10
64
Appendix 6
Table 61 Summary of data from Trainor waterbores (TWB) and Bullen waterbores (BWB)
Well AMG Elevation TD Status(b) Completion details Water Salinity Water level Flow rate Depth to consolidated AGD84 GL (m) (m) struck mgl(c) (m) (LHr) lithology aquifer(e) Z51(a) Interval (m) (100 mm PVC) (m) (mgl)(d)
TWB 1 473660E 453 122 comp 0ndash75 plain 63 7 300 24 2 880 12 m 7287404N 75ndash93 slotted (9 260) McFadden Fm 93ndash99 plain TWB 2 472 977E 475 23 abd nil 15 m 7285877N Skates Hills Fm dry TWB 3 473259E 475 50 abd nil 7 m 7285849N Skates Hills Fm dry TWB 4 463225 E 445 50 comp 0ndash22 plain 35 7 200 55 3 600 0 m 7286143N 22ndash34 slotted (8 140) Tertiary sand and gravel 23ndash60 plain TWB 5 463095E 445 31 comp 0ndash19 plain 13 26 000 655 3 600 Tertiary sand and gravel 7277721N 19ndash25 slotted (36 700) 25ndash31 plain TWB 6 457013E 455 50 comp 0ndash42 plain 38 920 119 600 0 m 7274352N 42ndash48 slotted (1 030) Cornelia Fm ss TWB 7 453739E 475 26 susp 0ndash2 plain 11 9 300 48 4 500 0 m 7263891N (10 500) Tertiary sand TWB 8 433893E 535 60 susp 0ndash2 plain 47 8 500 gt46 1 200 0 m 7245991N (10 900) Tertiary sand and Brassey Range Fm ss TWB 9 437219E 505 51 comp 0ndash47 plain 45 1 000 58 600 1 m 7235905N 47ndash51 slotted (990) Brassey Range Fm ss TWB 10 434927E 495 32 susp 0ndash2 plain 235 450 120 0 m 7225875N (500) Dolerite
65
BWB 1 287337E 580 122 abd Nil 1 m 7245861N Jilyili Fm dry BWB 2 288346E 545 50 comp 0ndash26 plain 15 630 3 29 000 0 m 7240423N 26ndash38 slotted (730) Tertiary sand and gravel 38ndash50 plain BWB 3 305637E 545 50 abd 19 8 800 43 7 200 0 m 7240423N (10 550) Tertiary ss BWB 4 320167E 515 445 comp 0ndash20 plain 9 980 445 24 000 0 m 7248097N 20ndash32 slotted (1 190) Tertiary ss 32ndash44 plain BWB 5 353393E 545 20 susp 0ndash2 plain 45 (970) 1 m 7238934N Basalt
NOTES (a) GPS accuracy ~ 150 m (b) Comp = completed abd = abandoned susp = suspended (c) Salinity from conductivity (d) Analysis total dissolved solids (e) Fm = Formation ss = sandstone
63
Table 53 LDDH1 extract liquid chromatography data for 6623 m concentration
Rock extracted Total extract (grams) (ppm)
702 313
NOTE ppm= parts per million
Table 54 LDDH1 saturate gas chromatography data of core for 6623 m alkane composition
Pristane Pristane Phytane (a) CPI (1) CPI (2) (C21+C22) Phytane n-C17 n-C18 (C28+C29)
103 026 024 103 102 325
NOTE (a)CPI = carbon preference index
Table 55 LDDH1 saturate gas chromatography data of core for 6623 m n-alkane distributions
Parameter Value
n-C12 17 n-C13 38 n-C14 55 n-C15 60 n-C16 65 n-C17 74 i-C19 19 n-C18 78 i-C20 19 n-C19 80 n-C20 79 n-C21 71 n-C22 64 n-C23 57 n-C25 43 n-C24 38 n-C27 31 n-C28 23 n-C29 19 n-C30 12 n-C31 10
64
Appendix 6
Table 61 Summary of data from Trainor waterbores (TWB) and Bullen waterbores (BWB)
Well AMG Elevation TD Status(b) Completion details Water Salinity Water level Flow rate Depth to consolidated AGD84 GL (m) (m) struck mgl(c) (m) (LHr) lithology aquifer(e) Z51(a) Interval (m) (100 mm PVC) (m) (mgl)(d)
TWB 1 473660E 453 122 comp 0ndash75 plain 63 7 300 24 2 880 12 m 7287404N 75ndash93 slotted (9 260) McFadden Fm 93ndash99 plain TWB 2 472 977E 475 23 abd nil 15 m 7285877N Skates Hills Fm dry TWB 3 473259E 475 50 abd nil 7 m 7285849N Skates Hills Fm dry TWB 4 463225 E 445 50 comp 0ndash22 plain 35 7 200 55 3 600 0 m 7286143N 22ndash34 slotted (8 140) Tertiary sand and gravel 23ndash60 plain TWB 5 463095E 445 31 comp 0ndash19 plain 13 26 000 655 3 600 Tertiary sand and gravel 7277721N 19ndash25 slotted (36 700) 25ndash31 plain TWB 6 457013E 455 50 comp 0ndash42 plain 38 920 119 600 0 m 7274352N 42ndash48 slotted (1 030) Cornelia Fm ss TWB 7 453739E 475 26 susp 0ndash2 plain 11 9 300 48 4 500 0 m 7263891N (10 500) Tertiary sand TWB 8 433893E 535 60 susp 0ndash2 plain 47 8 500 gt46 1 200 0 m 7245991N (10 900) Tertiary sand and Brassey Range Fm ss TWB 9 437219E 505 51 comp 0ndash47 plain 45 1 000 58 600 1 m 7235905N 47ndash51 slotted (990) Brassey Range Fm ss TWB 10 434927E 495 32 susp 0ndash2 plain 235 450 120 0 m 7225875N (500) Dolerite
65
BWB 1 287337E 580 122 abd Nil 1 m 7245861N Jilyili Fm dry BWB 2 288346E 545 50 comp 0ndash26 plain 15 630 3 29 000 0 m 7240423N 26ndash38 slotted (730) Tertiary sand and gravel 38ndash50 plain BWB 3 305637E 545 50 abd 19 8 800 43 7 200 0 m 7240423N (10 550) Tertiary ss BWB 4 320167E 515 445 comp 0ndash20 plain 9 980 445 24 000 0 m 7248097N 20ndash32 slotted (1 190) Tertiary ss 32ndash44 plain BWB 5 353393E 545 20 susp 0ndash2 plain 45 (970) 1 m 7238934N Basalt
NOTES (a) GPS accuracy ~ 150 m (b) Comp = completed abd = abandoned susp = suspended (c) Salinity from conductivity (d) Analysis total dissolved solids (e) Fm = Formation ss = sandstone
64
Appendix 6
Table 61 Summary of data from Trainor waterbores (TWB) and Bullen waterbores (BWB)
Well AMG Elevation TD Status(b) Completion details Water Salinity Water level Flow rate Depth to consolidated AGD84 GL (m) (m) struck mgl(c) (m) (LHr) lithology aquifer(e) Z51(a) Interval (m) (100 mm PVC) (m) (mgl)(d)
TWB 1 473660E 453 122 comp 0ndash75 plain 63 7 300 24 2 880 12 m 7287404N 75ndash93 slotted (9 260) McFadden Fm 93ndash99 plain TWB 2 472 977E 475 23 abd nil 15 m 7285877N Skates Hills Fm dry TWB 3 473259E 475 50 abd nil 7 m 7285849N Skates Hills Fm dry TWB 4 463225 E 445 50 comp 0ndash22 plain 35 7 200 55 3 600 0 m 7286143N 22ndash34 slotted (8 140) Tertiary sand and gravel 23ndash60 plain TWB 5 463095E 445 31 comp 0ndash19 plain 13 26 000 655 3 600 Tertiary sand and gravel 7277721N 19ndash25 slotted (36 700) 25ndash31 plain TWB 6 457013E 455 50 comp 0ndash42 plain 38 920 119 600 0 m 7274352N 42ndash48 slotted (1 030) Cornelia Fm ss TWB 7 453739E 475 26 susp 0ndash2 plain 11 9 300 48 4 500 0 m 7263891N (10 500) Tertiary sand TWB 8 433893E 535 60 susp 0ndash2 plain 47 8 500 gt46 1 200 0 m 7245991N (10 900) Tertiary sand and Brassey Range Fm ss TWB 9 437219E 505 51 comp 0ndash47 plain 45 1 000 58 600 1 m 7235905N 47ndash51 slotted (990) Brassey Range Fm ss TWB 10 434927E 495 32 susp 0ndash2 plain 235 450 120 0 m 7225875N (500) Dolerite
65
BWB 1 287337E 580 122 abd Nil 1 m 7245861N Jilyili Fm dry BWB 2 288346E 545 50 comp 0ndash26 plain 15 630 3 29 000 0 m 7240423N 26ndash38 slotted (730) Tertiary sand and gravel 38ndash50 plain BWB 3 305637E 545 50 abd 19 8 800 43 7 200 0 m 7240423N (10 550) Tertiary ss BWB 4 320167E 515 445 comp 0ndash20 plain 9 980 445 24 000 0 m 7248097N 20ndash32 slotted (1 190) Tertiary ss 32ndash44 plain BWB 5 353393E 545 20 susp 0ndash2 plain 45 (970) 1 m 7238934N Basalt
NOTES (a) GPS accuracy ~ 150 m (b) Comp = completed abd = abandoned susp = suspended (c) Salinity from conductivity (d) Analysis total dissolved solids (e) Fm = Formation ss = sandstone
65
BWB 1 287337E 580 122 abd Nil 1 m 7245861N Jilyili Fm dry BWB 2 288346E 545 50 comp 0ndash26 plain 15 630 3 29 000 0 m 7240423N 26ndash38 slotted (730) Tertiary sand and gravel 38ndash50 plain BWB 3 305637E 545 50 abd 19 8 800 43 7 200 0 m 7240423N (10 550) Tertiary ss BWB 4 320167E 515 445 comp 0ndash20 plain 9 980 445 24 000 0 m 7248097N 20ndash32 slotted (1 190) Tertiary ss 32ndash44 plain BWB 5 353393E 545 20 susp 0ndash2 plain 45 (970) 1 m 7238934N Basalt
NOTES (a) GPS accuracy ~ 150 m (b) Comp = completed abd = abandoned susp = suspended (c) Salinity from conductivity (d) Analysis total dissolved solids (e) Fm = Formation ss = sandstone