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ASX & Media Release
15 February 2018
ASX Symbol
ARL
Ardea Resources Limited
Suite 2 / 45 Ord St West Perth WA 6005
PO Box 1433 West Perth WA 6872
Telephone
+61 8 6244 5136
ardea@ardearesources.com.au
Website
www.ardearesources.com.au
Directors
Katina Law Chair
Matt Painter Managing Director
Ian Buchhorn Technical Executive Director
Wayne Bramwell Non-Executive Director
Issued Capital
Fully Paid Ordinary Shares 83,341,081
Unlisted options exercisable at $0.25 12,310,022
Unlisted Loyalty options exercisable at $0.77 17,845,774
Directors/Employee Performance Rights 4,230,000
ABN 30 614 289 342
Drilling confirms continuity of cobalt and nickel mineralisation
RC drilling at Goongarrie Nickel-Cobalt Project to improve confidence and upgrade resources delivers better than expected results
• Final stages of Pre-Feasibility Study refinement to optimise the
flowsheet for the Goongarrie Nickel Cobalt Project.
• Infill RC drilling confirms continuity of mineralisation in optimised pit
footprint areas:
o Ensures reliability of modelling and mine scheduling.
o Providing samples for variability test work and marketing studies
• Better than expected intercepts are from outside the areas planned
for early stage mining, including:
AGSR0005 32 m at 0.09 % cobalt and 1.06 % nickel from 16 m1
including 14 m at 0.15 % cobalt and 1.46 % nickel from 22 m2
AGSR0009 56 m at 0.07 % cobalt and 1.09 % nickel from 12 m1
including 16 m at 0.11 % cobalt and 1.20 % nickel from 30 m2
AGSR0015 32 m at 0.08 % cobalt and 0.87 % nickel from 32 m1
including 24 m at 0.10 % cobalt and 0.99 % nickel from 36 m2
• Many of these intercepts are from the Elsie South deposit, adjacent
to the proposed plant site.
• RC drilling is ongoing. Further results to be reported once compiled.
• Diamond drilling has commenced:
o Will provide QAQC confidence in RC drilling results,
o Primary source for metallurgical variability test work samples.
o Source for production of marketing samples.
1 Calculated using a 0.50 % nickel cut-off, 2 m minimum intercept, and 4 m maximum internal waste. 2 Calculated using a 0.08 % cobalt cut-off, 2 m minimum intercept, and 4 m maximum internal waste.
2
Work on the Pre-Feasibility Study (PFS) for the Goongarrie Nickel-Cobalt Project is continuing. Refinement
of various models, including financial, resource, and mining models, is reaching its final stages with a view
to optimising efficiencies throughout the mining and production processes. Iterative developments, such
as the incorporation of acid neutralisers from in-pit mineralised carbonates and optimisation of available
ground and process water and process water can further enhance the project and ensure maximum
recovery of cobalt and nickel.
Ardea continues to assess opportunities that could further realise efficiencies in development and mining
at Goongarrie. Several option studies are underway that could have a material positive impact upon the
project. The company is working hard to complete these in the scheduled timeframe.
The aim of the Company is to develop a long-lived, multi-decade mine that will produce nickel sulphate
and cobalt sulphate for the expanding battery industry. A 1 Mtpa project is the base case development
scenario being assessed by Ardea, with scoping at several higher throughput scenarios. Ardea must
demonstrate robust resources and reserves, mining schedules, and high-purity pilot marketing samples of
cobalt sulphate and nickel sulphate for third party evaluation. To this end, drilling continues at Goongarrie.
RC drilling program results
RC drilling commenced at Goongarrie at the end of November 2017. This program is specifically targeting
an increase drill hole density, and therefore resource confidence and classification, in open pit targets
defined by early-stage optimisation studies. These pits will centre on known cobalt and nickel orebodies
which are shown in Figure 1.
New results from this program show significant mineralisation, as expected, at the Goongarrie Nickel-
Cobalt Project. RC drilling has initially focused on the Pamela West and Elsie South deposits (Figure 1).
The results of that drilling comprising the first 43 drill holes are presented in Appendix 1, with highlights
shown below.
Pamela West deposit3
6669840 mN section
AGSR0001 24 m at 0.07 % cobalt and 0.62 % nickel from 8.3 m4
including 4 m at 0.21 % cobalt and 0.85 % nickel from 14.3 m5
AGSR0002 22 m at 0.07 % cobalt and 1.04 % nickel from 8 m4
including 2 m at 0.20 % cobalt and 0.90 % nickel from 10 m5
6669760 mN section
AGSR0005 32 m at 0.09 % cobalt and 1.06 % nickel from 16 m4
including 14 m at 0.15 % cobalt and 1.46 % nickel from 22 m5
3 Drillholes for the Pamela West deposit are listed first by section (north to south), then by hole west to east 4 Calculated using a 0.50 % nickel cut-off, 2 m minimum intercept, and 4 m maximum internal waste. 5 Calculated using a 0.08 % cobalt cut-off, 2 m minimum intercept, and 4 m maximum internal waste.
3
Figure 1 - Deposits of the Goongarrie Nickel-Cobalt Project, from Sylvia Virginia in the north to Scotia Dam in the south, a distance of 16 km. Active mining tenements are outlined in black. Deposits are marked by significant cobalt and nickel mineralisation and are encased within the overall nickel envelope (green, Ni>0.5%). Mining schedules are being finalised, but initial mining is likely to occur at Patricia Anne and Pamela Jean. These and the Elsie Tynan deposits are the current focus of drilling. RC drilling has also commenced further south at the Mavis Irene and Canegrass South deposits at Big Four.
4
Elsie South deposit6
6667760 mN section
AGSR0022 14 m at 0.06 % cobalt and 0.75 % nickel from 28 m7
including 4 m at 0.11 % cobalt and 0.79 % nickel from 38 m8
AGSR0026 26 m at 0.06 % cobalt and 0.99 % nickel from 10 m7
including 8 m at 0.10 % cobalt and 1.28 % nickel from 22 m8
6667680 mN section
AGSR0009 56 m at 0.07 % cobalt and 1.09 % nickel from 12 m7
including 16 m at 0.11 % cobalt and 1.20 % nickel from 30 m8
6667600 mN section
AGSR0015 32 m at 0.08 % cobalt and 0.87 % nickel from 32 m7
including 24 m at 0.10 % cobalt and 0.99 % nickel from 36 m8
Results from the drilling to date show strong continuity between drill holes. This is a hallmark of the
Goongarrie Project in particular and of several ‘goethite´ style (yellow) laterite nickel-cobalt deposits in
general. It contrasts sharply with the more siliceous and nontronitic style (green) laterite deposits which
can exhibit marked variation between holes.
Resource confidence continues to grow with this drilling verifying continuity. This will ensure that mining
schedules are easily and reliably modelled, and that resources provide an accurate estimate of in-ground
metal values and reliable plant feed. As a result, there is high confidence in the various mineralisation
models constructed for the PFS.
At Pamela West, mineralisation commonly starts within 10 m of surface, whereas lacustrine clay cover at
Elsie South means that mineralisation is usually deeper though commonly within 15 m of surface. Grades
at Elsie South are generally lower, but this deposit has the advantage of close proximity to the planned
plant site.
All defined intercepts from the program are listed in Appendix 3.
Scandium results
Scandium levels at Pamela West and Elsie South are typically low, generally around 50 g/t, but with
thicknesses of up to 20 m. Notable intercepts include:
AGSR0016 20 m at 50 g/t scandium and 0.671 % nickel from 10 m9
AGSR0039 4 m at 80 g/t scandium and 0.971 % nickel from 34 m9
Scandium is being assayed systematically throughout all current and future programs with the aim of better
defining the scandium opportunity within the Goongarrie Nickel-Cobalt Project.
6 Drillholes for the Elsie South deposit are listed first by section (north to south), then by hole west to east 7 Calculated using a 0.50 % nickel cut-off, 2 m minimum intercept, and 4 m maximum internal waste. 8 Calculated using a 0.08 % cobalt cut-off, 2 m minimum intercept, and 4 m maximum internal waste. 9 Calculated using a 50 g/t scandium cut-off, 2 m minimum intercept, and 4 m maximum internal waste
5
Figure 2 – Location of new drilling (white dots, abbreviated hole number) at Pamela West and Elsie South (with several holes at the southern end of Elsie Tynan). Dark dots show historic drill collars.
6
Figure 3 – Cross section of nickel, cobalt, and scandium mineralisation at the 6669840mN section across Pamela West (northernmost section of this current program). Nearly all of the mineralisation is located between the base of alluvium and the top of saprock. Various mineralised envelopes mark the upper and lower extent of the threshold grades depicted. Significant intercepts are shown
7
Figure 4 – Cross section of nickel, cobalt, and scandium mineralisation at the 6667680mN section across Elsie South. Nearly all of the mineralisation is located between the base of alluvium and the top of saprock. Various mineralised envelopes mark the upper and lower extent of the threshold grades depicted. Significant intercepts are shown.
8
Ongoing drilling at Goongarrie
Drilling is currently underway at the Patricia Anne deposit (Figure 1) where initial logging of holes indicates
that strong mineralisation has been intercepted near to surface, validating historic RC drilling in the area.
Drilling has also commenced at the Mavis Irene and Canegrass South deposits at Big Four (Figure 1).
Results will be released as they come to hand.
Recent RC drilling at Goongarrie South has infilled between historic drill holes to bring the drill hole density
down from 80mE x 80mN to 40mE x 80mN. The rationale for the drilling is:
• To upgrade resource (and ultimately reserve) definition and classification
• To define and quantify variability between drill holes
• To provide additional material for DFS test work and for producing marketing samples for third
party assessment.
This current phase of drilling (3,700m of drilling in 96 drill holes) will bring all areas marked as a future
open pit mine down to at least a 40mE x 80mN drilling density.
This will lead directly onto a second phase of drilling (199 drill holes for over 7,600m) to bring the drilling
density down to 40mE x 40mN. This is expected to get underway in the coming weeks upon completion
of Phase 1.
Diamond and sonic drilling
Diamond drilling has commenced at Goongarrie. Large diameter PQ triple-tubed diamond drilling is being
undertaken to maximise retrieval of soft, high-grade mineralisation. There are several important aims for
this program:
1. To verify QAQC for existing and forthcoming RC drill holes through twinning.
2. To provide additional sampling of the proposed pits at regular intervals to ensure representivity of
all results.
3. To provide material to produce marketing samples of cobalt sulphate and nickel sulphate for third
party evaluation.
A sonic drill rig, which specialises in retrieval of soft material such as that found in high-grade zones at
Goongarrie, is scheduled to arrive on site in mid-March to complement the diamond drilling. A total of 45
core holes are planned for 2,160m of drilling at various deposits at Goongarrie.
For further information regarding Ardea, please visit www.ardearesources.com.au or contact:
Ardea Resources:
Dr Matt Painter
Managing Director, Ardea Resources Limited
Tel +61 8 6244 5136
9
Compliance Statement (JORC 2012)
A competent person’s statement for the purposes of Listing Rule 5.22 has previously been announced by the Company for:
1. Kalgoorlie Nickel Project on 21 October 2013 and 31 June 2014, October 2016, 2016 Heron Resources Annual Report and 6 January 2017;
2. KNP Cobalt Zone Study on 6 January 2017
The Company confirms that it is not aware of any new information or data that materially affects information included in previous announcements, and all material assumptions and technical parameters underpinning the estimates continue to apply and have not materially changed. All projects will be subject to new work programs following the listing of Ardea, notably drilling, metallurgy and JORC Code 2012 resource estimation as applicable.
The information in this report that relates to KNP Exploration Results is based on information originally compiled by previous and current full time employees of Heron Resources Limited and after February 2017 employees of Ardea Resource Limited. The Exploration Results and data collection processes have been reviewed, verified and re-interpreted by Mr Ian Buchhorn who is a Member of the Australasian Institute of Mining and Metallurgy and currently a director of Ardea Resources Limited. Mr Buchhorn has sufficient experience that is relevant to the style of mineralisation and type of deposit under consideration and to the exploration activities undertaken to qualify as a Competent Person as defined in the 2012 Edition of the ‘Australasian Code for Reporting of Exploration Results, Mineral Resources and Ore Reserves’. Mr Buchhorn consents to the inclusion in this report of the matters based on his information in the form and context that it appears.
The exploration and industry benchmarking summaries are based on information reviewed by Dr Matthew Painter, who is a Member of the Australian Institute of Geoscientists. Dr Painter is a full-time employee and a director of Ardea Resources Limited and has sufficient experience, which is relevant to the style of mineralisation and type of deposit under consideration and to the activity which he is undertaking to qualify as a Competent Person as defined in the 2012 edition of the Australasian Code for Reporting of Exploration Results, Mineral Resources and Ore Reserves’. Dr Painter has reviewed this press release and consents to the inclusion in this report of the information in the form and context in which it appears.
CAUTIONARY NOTE REGARDING FORWARD-LOOKING INFORMATION
This news release contains forward-looking statements and forward-looking information within the meaning of applicable Australian securities laws, which are based on expectations, estimates and projections as of the date of this news release.
This forward-looking information includes, or may be based upon, without limitation, estimates, forecasts and statements as to management’s expectations with respect to, among other things, the timing and ability to complete the Ardea spin-out, the timing and amount of funding required to execute the Company’s exploration, development and business plans, capital and exploration expenditures, the effect on the Company of any changes to existing legislation or policy, government regulation of mining operations, the length of time required to obtain permits, certifications and approvals, the success of exploration, development and mining activities, the geology of the Company’s properties, environmental risks, the availability of labour, the focus of the Company in the future, demand and market outlook for precious metals and the prices thereof, progress in development of mineral properties, the Company’s ability to raise funding privately or on a public market in the future, the Company’s future growth, results of operations, performance, and business prospects and opportunities. Wherever possible, words such as “anticipate”, “believe”, “expect”, “intend”, “may” and similar expressions have been used to identify such forward-looking information. Forward-looking information is based on the opinions and estimates of management at the date the information is given, and on information available to management at such time. Forward-looking information involves significant risks, uncertainties, assumptions and other factors that could cause actual results, performance or achievements to differ materially from the results discussed or implied in the forward-looking information. These factors, including, but not limited to, the ability to complete the Ardea spin-out on the basis of the proposed terms and timing or at all, fluctuations in currency markets, fluctuations in commodity prices, the ability of the Company to access sufficient capital on favourable terms or at all, changes in national and local government legislation, taxation, controls, regulations, political or economic developments in Australia or other countries in which the Company does business or may carry on business in the future, operational or technical difficulties in connection with exploration or development activities, employee relations, the speculative nature of mineral exploration and development, obtaining necessary licenses and permits, diminishing quantities and grades of mineral reserves, contests over title to properties, especially title to undeveloped properties, the inherent risks involved in the exploration and development of mineral properties, the uncertainties involved in interpreting drill results and other geological data, environmental hazards, industrial accidents, unusual or unexpected formations, pressures, cave-ins and flooding, limitations of insurance coverage and the possibility of project cost overruns or unanticipated costs and expenses, and should be considered carefully. Many of these uncertainties and contingencies can affect the Company’s actual results and could cause actual results to differ materially from those expressed or implied in any forward-looking statements made by, or on behalf of, the Company. Prospective investors should not place undue reliance on any forward-looking information.
Although the forward-looking information contained in this news release is based upon what management believes, or believed at the time, to be reasonable assumptions, the Company cannot assure prospective purchasers that actual results will be consistent with such forward-looking information, as there may be other factors that cause results not to be as anticipated, estimated or intended, and neither the Company nor any other person assumes responsibility for the accuracy and completeness of any such forward-looking information. The Company does not undertake, and assumes no obligation, to update or revise any such forward-looking statements or forward-looking information contained herein to reflect new events or circumstances, except as may be required by law.
No stock exchange, regulation services provider, securities commission or other regulatory authority has approved or
disapproved the information contained in this news release.
10
Appendix 1 – Collar location data
New drill holes by Ardea Resources
Drill hole Type Depth
(m) Date
completed Tenement
Grid
Easting (mE)
Northing (mN)
RL (mASL)
Dip (°)
Azimuth (°)
AGSR0001 RC 40.3 24/11/2017 M29/00272 PamelaWest MGA94_51 322820 6669840 375 -90 000
AGSR0002 RC 46.3 26/11/2017 M29/00272 PamelaWest MGA94_51 322740 6669840 375 -90 000
AGSR0003 RC 49.3 26/11/2017 M29/00272 PamelaWest MGA94_51 322660 6669840 375 -90 000
AGSR0004 RC 67 6/12/2017 M29/00272 PamelaWest MGA94_51 322740 6669760 375 -90 000
AGSR0005 RC 62 6/12/2017 M29/00272 PamelaWest MGA94_51 322660 6669760 375 -90 000
AGSR0006 RC 56 6/12/2017 M29/00272 ElsieSouth MGA94_51 323540 6667680 375 -90 000
AGSR0007 RC 59 7/12/2017 M29/00272 ElsieSouth MGA94_51 323460 6667680 375 -90 000
AGSR0008 RC 59 8/12/2017 M29/00272 ElsieSouth MGA94_51 323380 6667680 375 -90 000
AGSR0009 RC 68 9/12/2017 M29/00272 ElsieSouth MGA94_51 323300 6667680 375 -90 000
AGSR0010 RC 68 9/12/2017 M29/00272 ElsieSouth MGA94_51 323220 6667680 375 -90 000
AGSR0011 RC 56 10/12/2017 M29/00272 ElsieSouth MGA94_51 323140 6667680 375 -90 000
AGSR0012 RC 89 11/12/2017 M29/00272 ElsieSouth MGA94_51 323100 6667600 375 -90 000
AGSR0013 RC 74 11/12/2017 M29/00272 ElsieSouth MGA94_51 323140 6667600 375 -90 000
AGSR0014 RC 70 12/12/2017 M29/00272 ElsieSouth MGA94_51 323180 6667600 375 -90 000
AGSR0015 RC 74 12/12/2017 M29/00272 ElsieSouth MGA94_51 323220 6667600 375 -90 000
AGSR0016 RC 41 12/12/2017 M29/00272 ElsieSouth MGA94_51 323300 6667600 375 -90 000
AGSR0017 RC 46 12/12/2017 M29/00272 ElsieSouth MGA94_51 323380 6667600 375 -90 000
AGSR0018 RC 35 13/12/2017 M29/00272 ElsieSouth MGA94_51 323460 6667600 375 -90 000
AGSR0019 RC 35 13/12/2017 M29/00272 ElsieSouth MGA94_51 323460 6667520 375 -90 000
AGSR0020 RC 46 13/12/2017 M29/00272 ElsieSouth MGA94_51 323380 6667520 375 -90 000
AGSR0021 RC 65 13/12/2017 M29/00272 ElsieSouth MGA94_51 323140 6667760 375 -90 000
AGSR0022 RC 47 14/12/2017 M29/00272 ElsieSouth MGA94_51 323220 6667760 375 -90 000
AGSR0023 RC 38 14/12/2017 M29/00272 ElsieSouth MGA94_51 323300 6667760 375 -90 000
AGSR0024 RC 44 14/12/2017 M29/00272 ElsieSouth MGA94_51 323380 6667760 375 -90 000
AGSR0025 RC 41 14/12/2017 M29/00272 ElsieSouth MGA94_51 323460 6667760 375 -90 000
AGSR0026 RC 41 14/12/2017 M29/00272 ElsieSouth MGA94_51 323540 6667760 375 -90 000
AGSR0027 RC 47 15/12/2017 M29/00272 ElsieTynan MGA94_51 322860 6667840 375 -90 000
AGSR0028 RC 47 15/12/2017 M29/00272 ElsieTynan MGA94_51 322900 6667840 375 -90 000
AGSR0029 RC 53 15/12/2017 M29/00272 ElsieTynan MGA94_51 322980 6667840 375 -90 000
AGSR0030 RC 47 15/12/2017 M29/00272 ElsieTynan MGA94_51 323060 6667840 375 -90 000
AGSR0031 RC 44 18/12/2017 M29/00272 ElsieSouth MGA94_51 323220 6667840 375 -90 000
AGSR0032 RC 47 18/12/2017 M29/00272 ElsieSouth MGA94_51 323300 6667840 375 -90 000
AGSR0033 RC 33 18/12/2017 M29/00272 ElsieSouth MGA94_51 323380 6667840 375 -90 000
AGSR0034 RC 48 18/12/2017 M29/00272 ElsieSouth MGA94_51 323460 6667840 375 -90 000
AGSR0035 RC 45 18/12/2017 M29/00272 ElsieSouth MGA94_51 323540 6667840 375 -90 000
AGSR0036 RC 33 19/12/2017 M29/00272 ElsieSouth MGA94_51 323300 6667920 375 -90 000
AGSR0037 RC 39 19/12/2017 M29/00272 ElsieSouth MGA94_51 323380 6667920 375 -90 000
AGSR0038 RC 36 19/12/2017 M29/00272 ElsieSouth MGA94_51 323460 6667920 375 -90 000
AGSR0039 RC 63 19/12/2017 M29/00272 ElsieSouth MGA94_51 323540 6667920 375 -90 000
AGSR0040 RC 36 19/12/2017 M29/00272 ElsieSouth MGA94_51 323500 6668000 375 -90 000
AGSR0041 RC 39 20/12/2017 M29/00272 ElsieSouth MGA94_51 323460 6668000 375 -90 000
AGSR0042 RC 38 20/12/2017 M29/00272 ElsieSouth MGA94_51 323420 6668000 375 -90 000
AGSR0043 RC 30 20/12/2017 M29/00272 ElsieSouth MGA94_51 323380 6668000 375 -90 000
11
Appendix 2 – Assay results from Goongarrie South All assays from the 2017 drilling program at Pamela Jean Deeps, Goongarrie South.
Abbreviations used: Co – cobalt, Ni – nickel, Sc – scandium, Cr – chromium, m – metre, g/t – grams per
tonne, b.d. – below detection.
Hole From (m)
To (m)
Width (m)
Sample number
Co (%)
Ni (%)
Sc (g/t)
Cr (ppm)
AGSR0001 0 2.3 2.3 AR000001 0.001 0.021 10 410
AGSR0001 2.3 4.3 2 AR000002 0.016 0.079 20 1340
AGSR0001 4.3 6.3 2 AR000003 0.007 0.064 40 2130
AGSR0001 6.3 8.3 2 AR000004 0.018 0.155 40 3080
AGSR0001 8.3 10.3 2 AR000005 0.041 0.706 40 3230
AGSR0001 10.3 12.3 2 AR000006 0.024 0.468 40 3560
AGSR0001 12.3 14.3 2 AR000007 0.046 0.757 40 3340
AGSR0001 14.3 16.3 2 AR000009 0.08 0.815 60 3660
AGSR0001 16.3 18.3 2 AR000010 0.338 0.886 40 3150
AGSR0001 18.3 20.3 2 AR000011 0.077 0.754 30 4010
AGSR0001 20.3 22.3 2 AR000012 0.038 0.639 20 2470
AGSR0001 22.3 24.3 2 AR000013 0.027 0.426 10 1850
AGSR0001 24.3 26.3 2 AR000014 0.037 0.502 10 1860
AGSR0001 26.3 28.3 2 AR000015 0.038 0.459 10 1930
AGSR0001 28.3 30.3 2 AR000016 0.028 0.334 10 1450
AGSR0001 30.3 32.3 2 AR000017 0.073 0.645 10 2180
AGSR0001 32.3 34.3 2 AR000019 0.037 0.343 b.d. 865
AGSR0001 34.3 36.3 2 AR000020 0.018 0.319 b.d. 680
AGSR0001 36.3 38.3 2 AR000021 0.011 0.291 b.d. 555
AGSR0001 38.3 40.3 2 AR000022 0.007 0.222 b.d. 610
AGSR0002 0 2 2 AR000023 0.003 0.052 b.d. 490
AGSR0002 2 4 2 AR000024 0.004 0.068 10 660
AGSR0002 4 6 2 AR000025 0.006 0.145 30 1950
AGSR0002 6 8 2 AR000026 0.018 0.38 40 4540
AGSR0002 8 10 2 AR000027 0.041 0.666 20 2120
AGSR0002 10 12 2 AR000029 0.201 0.895 40 8250
AGSR0002 12 14 2 AR000030 0.064 0.925 40 11200
AGSR0002 14 16 2 AR000031 0.049 1.07 50 12200
AGSR0002 16 18 2 AR000032 0.057 1.07 50 12300
AGSR0002 18 20 2 AR000033 0.069 1.5 40 11300
AGSR0002 20 22 2 AR000034 0.056 1.22 30 10600
AGSR0002 22 24 2 AR000035 0.059 1.45 40 19300
AGSR0002 24 26 2 AR000036 0.052 1.26 30 17700
AGSR0002 26 28 2 AR000037 0.045 0.8 20 14600
AGSR0002 28 30 2 AR000039 0.056 0.551 b.d. 11400
AGSR0002 30 32 2 AR000040 0.039 0.339 b.d. 6990
AGSR0002 32 34 2 AR000041 0.015 0.205 b.d. 5170
AGSR0002 34 36 2 AR000042 0.012 0.187 b.d. 3120
AGSR0002 36 38 2 AR000043 0.011 0.171 b.d. 2850
AGSR0002 38 40 2 AR000044 0.011 0.165 b.d. 2290
AGSR0002 40 42 2 AR000045 0.013 0.179 b.d. 4180
AGSR0002 42 44 2 AR000046 0.013 0.198 b.d. 4820
AGSR0002 44 46 2 AR000047 0.016 0.24 b.d. 4260
AGSR0003 0 2.3 2.3 AR000049 0.002 0.029 10 625
AGSR0003 2.3 4.3 2 AR000050 0.004 0.045 40 1640
AGSR0003 4.3 6.3 2 AR000051 0.002 0.029 30 2120
AGSR0003 6.3 8.3 2 AR000052 0.002 0.027 50 3540
AGSR0003 8.3 10.3 2 AR000053 b.d. 0.009 b.d. 1190
AGSR0003 10.3 12.3 2 AR000054 0.002 0.028 b.d. 1850
AGSR0003 12.3 14.3 2 AR000055 0.005 0.135 20 4930
AGSR0003 14.3 16.3 2 AR000056 0.006 0.142 10 4290
AGSR0003 16.3 18.3 2 AR000057 0.011 0.395 20 6140
AGSR0003 18.3 20.3 2 AR000059 0.019 0.794 40 7480
AGSR0003 20.3 22.3 2 AR000060 0.027 1.06 50 8820
AGSR0003 22.3 24.3 2 AR000061 0.018 0.64 20 7640
AGSR0003 24.3 26.3 2 AR000062 0.021 0.696 20 7210
AGSR0003 26.3 28.3 2 AR000063 0.037 1.05 30 10300
AGSR0003 28.3 30.3 2 AR000064 0.039 0.861 10 6980
AGSR0003 30.3 32.3 2 AR000065 0.026 0.457 10 3980
AGSR0003 32.3 34.3 2 AR000066 0.027 0.304 b.d. 2250
AGSR0003 34.3 36.3 2 AR000067 0.015 0.188 b.d. 1510
AGSR0003 36.3 38.3 2 AR000069 0.015 0.18 b.d. 2010
AGSR0003 38.3 40.3 2 AR000070 0.016 0.209 b.d. 3140
AGSR0003 40.3 42.3 2 AR000071 0.019 0.242 b.d. 3540
AGSR0003 42.3 44.3 2 AR000072 0.021 0.267 b.d. 3440
AGSR0003 44.3 46.3 2 AR000073 0.017 0.281 b.d. 6270
AGSR0003 46.3 48.3 2 AR000074 0.016 0.254 10 5520
AGSR0003 48.3 49.3 1 AR000075 0.02 0.389 b.d. 3760
AGSR0004 0 2 2 AR000076 0.003 0.022 b.d. 390
AGSR0004 2 4 2 AR000077 0.014 0.082 10 575
AGSR0004 4 6 2 AR000079 0.005 0.066 50 3170
AGSR0004 6 8 2 AR000080 0.005 0.11 50 4430
AGSR0004 8 10 2 AR000081 0.005 0.229 20 7850
AGSR0004 10 12 2 AR000082 0.005 0.085 10 16000
AGSR0004 12 14 2 AR000083 0.016 0.309 30 7800
AGSR0004 14 16 2 AR000084 0.017 0.418 10 5280
AGSR0004 16 18 2 AR000085 0.016 0.308 b.d. 4910
AGSR0004 18 20 2 AR000086 0.024 0.314 b.d. 6400
Hole From (m)
To (m)
Width (m)
Sample number
Co (%)
Ni (%)
Sc (g/t)
Cr (ppm)
AGSR0004 20 22 2 AR000087 0.015 0.253 b.d. 5300
AGSR0004 22 24 2 AR000089 0.017 0.273 b.d. 6050
AGSR0004 24 26 2 AR000090 0.022 0.295 b.d. 5160
AGSR0004 26 28 2 AR000091 0.012 0.209 b.d. 4160
AGSR0004 28 30 2 AR000092 0.013 0.204 b.d. 4230
AGSR0004 30 32 2 AR000093 0.011 0.187 b.d. 4090
AGSR0004 32 34 2 AR000094 0.009 0.171 b.d. 3480
AGSR0004 34 36 2 AR000095 0.012 0.165 b.d. 3860
AGSR0004 36 38 2 AR000096 0.018 0.199 b.d. 4780
AGSR0004 38 40 2 AR000097 0.012 0.221 b.d. 3950
AGSR0004 40 42 2 AR000099 0.008 0.157 b.d. 3020
AGSR0004 42 44 2 AR000100 0.01 0.23 b.d. 4550
AGSR0004 44 46 2 AR000101 0.009 0.234 b.d. 4510
AGSR0004 46 48 2 AR000102 0.01 0.223 b.d. 4530
AGSR0004 48 50 2 AR000103 0.009 0.188 b.d. 4810
AGSR0004 50 52 2 AR000104 0.011 0.211 b.d. 8160
AGSR0004 52 54 2 AR000105 0.014 0.223 b.d. 3230
AGSR0004 54 56 2 AR000106 0.01 0.187 b.d. 4050
AGSR0004 56 58 2 AR000107 0.012 0.219 b.d. 5410
AGSR0004 58 60 2 AR000108 0.007 0.174 b.d. 4780
AGSR0004 60 62 2 AR000109 0.005 0.136 b.d. 3960
AGSR0004 62 64 2 AR000111 0.005 0.132 b.d. 3410
AGSR0004 64 66 2 AR000112 0.004 0.104 b.d. 3800
AGSR0004 66 67 1 AR000113 0.007 0.189 b.d. 4960
AGSR0005 0 2 2 AR000114 0.001 0.015 b.d. 360
AGSR0005 2 4 2 AR000115 0.002 0.023 20 545
AGSR0005 4 6 2 AR000116 0.003 0.036 20 1500
AGSR0005 6 8 2 AR000117 0.011 0.163 b.d. 4560
AGSR0005 8 10 2 AR000119 0.021 0.251 b.d. 3300
AGSR0005 10 12 2 AR000120 0.023 0.276 20 6370
AGSR0005 12 14 2 AR000121 0.002 0.021 b.d. 1130
AGSR0005 14 16 2 AR000122 0.007 0.06 b.d. 2090
AGSR0005 16 18 2 AR000123 0.045 0.822 40 10800
AGSR0005 18 20 2 AR000124 0.05 0.835 40 10300
AGSR0005 20 22 2 AR000125 0.073 0.974 40 14800
AGSR0005 22 24 2 AR000126 0.082 0.902 40 12900
AGSR0005 24 26 2 AR000127 0.117 1.16 40 13400
AGSR0005 26 28 2 AR000129 0.133 1.34 40 15000
AGSR0005 28 30 2 AR000130 0.154 1.63 40 16300
AGSR0005 30 32 2 AR000131 0.173 1.75 b.d. 18600
AGSR0005 32 34 2 AR000132 0.192 1.71 40 18100
AGSR0005 34 36 2 AR000133 0.169 1.71 40 18900
AGSR0005 36 38 2 AR000134 0.071 1.06 20 20800
AGSR0005 38 40 2 AR000135 0.033 0.638 20 7220
AGSR0005 40 42 2 AR000136 0.031 0.563 20 8970
AGSR0005 42 44 2 AR000137 0.033 0.476 b.d. 12400
AGSR0005 44 46 2 AR000139 0.051 0.834 20 18800
AGSR0005 46 48 2 AR000140 0.038 0.556 10 18300
AGSR0005 48 50 2 AR000141 0.024 0.369 b.d. 7100
AGSR0005 50 52 2 AR000142 0.015 0.221 b.d. 4180
AGSR0005 52 54 2 AR000143 0.013 0.188 b.d. 3840
AGSR0005 54 56 2 AR000144 0.031 0.469 b.d. 3180
AGSR0005 56 58 2 AR000145 0.016 0.453 b.d. 2240
AGSR0005 58 60 2 AR000146 0.013 0.284 b.d. 2970
AGSR0005 60 62 2 AR000147 0.014 0.229 b.d. 3880
AGSR0006 0 1 1 No sample
AGSR0006 1 2 1 AR000148 0.002 0.028 b.d. 490
AGSR0006 2 4 2 AR000150 0.002 0.035 b.d. 965
AGSR0006 4 6 2 AR000151 0.004 0.029 b.d. 625
AGSR0006 6 8 2 AR000152 0.002 0.032 b.d. 940
AGSR0006 8 10 2 AR000153 0.009 0.19 20 3840
AGSR0006 10 12 2 AR000154 0.035 0.679 60 7970
AGSR0006 12 14 2 AR000155 0.048 0.601 40 6250
AGSR0006 14 16 2 AR000156 0.069 0.921 20 4430
AGSR0006 16 18 2 AR000157 0.035 1.09 20 5330
AGSR0006 18 20 2 AR000159 0.041 0.956 20 4450
AGSR0006 20 22 2 AR000160 0.041 1.16 20 6550
AGSR0006 22 24 2 AR000161 0.052 1.17 20 6830
AGSR0006 24 26 2 AR000162 0.039 0.932 20 6950
AGSR0006 26 28 2 AR000163 0.028 0.714 20 5690
AGSR0006 28 30 2 AR000164 0.023 0.481 b.d. 2880
AGSR0006 30 32 2 AR000165 0.032 0.726 20 4750
AGSR0006 32 34 2 AR000166 0.027 0.651 b.d. 4610
AGSR0006 34 36 2 AR000167 0.027 0.664 b.d. 3550
AGSR0006 36 38 2 AR000169 0.024 0.577 20 3340
AGSR0006 38 40 2 AR000170 0.022 0.498 b.d. 2770
AGSR0006 40 42 2 AR000171 0.015 0.286 b.d. 2800
AGSR0006 42 44 2 AR000172 0.011 0.228 b.d. 2370
12
Hole From (m)
To (m)
Width (m)
Sample number
Co (%)
Ni (%)
Sc (g/t)
Cr (ppm)
AGSR0006 44 46 2 AR000173 0.01 0.196 b.d. 1560
AGSR0006 46 48 2 AR000174 0.008 0.199 b.d. 1640
AGSR0006 48 50 2 AR000175 0.012 0.259 b.d. 3230
AGSR0006 50 52 2 AR000176 0.017 0.35 b.d. 5010
AGSR0006 52 54 2 AR000177 0.019 0.399 20 4480
AGSR0006 54 56 2 AR000179 0.013 0.312 b.d. 4250
AGSR0007 0 2 2 AR000180 0.002 0.021 b.d. 380
AGSR0007 2 4 2 AR000181 0.005 0.035 20 450
AGSR0007 4 6 2 AR000182 0.004 0.036 20 745
AGSR0007 6 8 2 AR000183 0.003 0.053 20 3680
AGSR0007 8 10 2 AR000184 0.006 0.124 40 8840
AGSR0007 10 12 2 AR000185 0.023 0.431 40 12500
AGSR0007 12 14 2 AR000186 0.026 0.672 60 12100
AGSR0007 14 16 2 AR000187 0.036 0.606 40 9580
AGSR0007 16 18 2 AR000189 0.025 0.562 40 8110
AGSR0007 18 20 2 AR000190 0.023 0.441 40 8390
AGSR0007 20 22 2 AR000191 0.011 0.324 20 4510
AGSR0007 22 24 2 AR000192 0.014 0.447 20 5480
AGSR0007 24 26 2 AR000193 0.016 0.481 20 5820
AGSR0007 26 28 2 AR000194 0.028 0.437 20 4410
AGSR0007 28 30 2 AR000195 0.046 0.412 b.d. 2640
AGSR0007 30 32 2 AR000196 0.026 0.29 b.d. 1620
AGSR0007 32 34 2 AR000197 0.019 0.273 b.d. 1360
AGSR0007 34 36 2 AR000199 0.017 0.267 b.d. 1330
AGSR0007 36 38 2 AR000200 0.011 0.247 b.d. 1450
AGSR0007 38 40 2 AR000201 0.023 0.298 b.d. 1540
AGSR0007 40 42 2 AR000202 b.d. b.d. b.d. b.d.
AGSR0007 42 44 2 AR000203 b.d. b.d. b.d. b.d.
AGSR0007 44 46 2 AR000204 0.03 0.571 b.d. 3090
AGSR0007 46 48 2 AR000205 0.017 0.358 b.d. 2150
AGSR0007 48 50 2 AR000206 0.012 0.241 b.d. 2380
AGSR0007 50 52 2 AR000207 0.01 0.228 b.d. 2660
AGSR0007 52 54 2 AR000209 0.011 0.236 b.d. 2380
AGSR0007 54 56 2 AR000210 0.012 0.288 b.d. 1750
AGSR0007 56 58 2 AR000211 0.009 0.281 b.d. 710
AGSR0007 58 59 1 AR000212 0.009 0.253 b.d. 1230
AGSR0008 0 2 2 AR000213 0.001 0.015 b.d. 295
AGSR0008 2 4 2 AR000214 0.003 0.029 20 370
AGSR0008 4 6 2 AR000215 b.d. 0.02 20 520
AGSR0008 6 8 2 AR000216 b.d. 0.021 20 1100
AGSR0008 8 10 2 AR000217 0.001 0.041 20 1060
AGSR0008 10 12 2 AR000219 0.007 0.128 b.d. 635
AGSR0008 12 14 2 AR000220 0.009 0.191 b.d. 1050
AGSR0008 14 16 2 AR000221 0.007 0.182 b.d. 395
AGSR0008 16 18 2 AR000222 0.011 0.324 b.d. 705
AGSR0008 18 20 2 AR000223 0.015 0.371 b.d. 1120
AGSR0008 20 22 2 AR000224 0.024 0.492 b.d. 2740
AGSR0008 22 24 2 AR000225 0.031 0.776 20 4280
AGSR0008 24 26 2 AR000226 0.012 0.252 b.d. 1050
AGSR0008 26 28 2 AR000227 0.041 0.639 b.d. 2980
AGSR0008 28 30 2 AR000229 0.04 0.435 b.d. 1120
AGSR0008 30 32 2 AR000230 0.037 0.393 b.d. 1330
AGSR0008 32 34 2 AR000231 0.028 0.361 b.d. 885
AGSR0008 34 36 2 AR000232 0.051 0.657 b.d. 980
AGSR0008 36 38 2 AR000233 0.043 0.624 b.d. 990
AGSR0008 38 40 2 AR000234 0.015 0.303 b.d. 660
AGSR0008 40 42 2 AR000235 0.013 0.296 b.d. 560
AGSR0008 42 44 2 AR000236 0.014 0.318 b.d. 685
AGSR0008 44 46 2 AR000237 0.015 0.299 b.d. 790
AGSR0008 46 48 2 AR000239 0.016 0.305 b.d. 980
AGSR0008 48 50 2 AR000240 0.016 0.307 b.d. 1020
AGSR0008 50 52 2 AR000241 0.016 0.275 b.d. 880
AGSR0008 52 54 2 AR000242 0.016 0.323 b.d. 1550
AGSR0008 54 56 2 AR000243 0.013 0.268 b.d. 1130
AGSR0008 56 58 2 AR000244 0.014 0.208 b.d. 1100
AGSR0008 58 59 1 AR000245 0.018 0.288 b.d. 1020
AGSR0009 0 2 2 AR000246 b.d. 0.013 b.d. 280
AGSR0009 2 4 2 AR000247 0.002 0.026 10 455
AGSR0009 4 6 2 AR000249 0.005 0.219 20 5090
AGSR0009 6 8 2 AR000250 0.009 0.244 30 6480
AGSR0009 8 10 2 AR000251 0.004 0.151 30 6700
AGSR0009 10 12 2 AR000252 0.009 0.408 50 7210
AGSR0009 12 14 2 AR000253 0.029 0.965 70 6150
AGSR0009 14 16 2 AR000254 0.03 1.1 60 6360
AGSR0009 16 18 2 AR000255 0.035 1.24 60 6330
AGSR0009 18 20 2 AR000256 0.047 1.26 40 7470
AGSR0009 20 22 2 AR000257 0.054 1.35 50 16100
AGSR0009 22 24 2 AR000259 0.054 1.25 40 15200
AGSR0009 24 26 2 AR000260 0.057 1.04 40 13400
AGSR0009 26 28 2 AR000261 0.067 1.03 40 13300
AGSR0009 28 30 2 AR000262 0.079 1.22 40 14300
AGSR0009 30 32 2 AR000263 0.088 1.35 40 14900
AGSR0009 32 34 2 AR000264 0.104 1.5 50 14200
AGSR0009 34 36 2 AR000265 0.109 1.2 40 16600
AGSR0009 36 38 2 AR000266 0.137 1.12 40 22100
AGSR0009 38 40 2 AR000267 0.145 0.99 30 37500
AGSR0009 40 42 2 AR000269 0.121 1.06 30 35400
AGSR0009 42 44 2 AR000275 0.095 1.19 40 34300
AGSR0009 44 46 2 AR000270 0.087 1.21 40 41400
AGSR0009 46 48 2 AR000271 0.075 1.22 40 59100
AGSR0009 48 50 2 AR000272 0.054 1 30 32200
AGSR0009 50 52 2 AR000273 0.047 0.896 20 25000
AGSR0009 52 54 2 AR000274 0.04 1.01 20 34900
AGSR0009 54 56 2 AR000276 0.042 1.01 20 49700
Hole From (m)
To (m)
Width (m)
Sample number
Co (%)
Ni (%)
Sc (g/t)
Cr (ppm)
AGSR0009 56 58 2 AR000277 0.048 1.14 20 47200
AGSR0009 58 60 2 AR000279 0.044 1.08 30 45200
AGSR0009 60 62 2 AR000280 0.038 0.95 20 32500
AGSR0009 62 64 2 AR000281 0.037 0.716 10 20200
AGSR0009 64 66 2 AR000282 0.037 0.651 10 20100
AGSR0009 66 68 2 AR000283 0.042 0.622 10 16200
AGSR0010 0 2 2 AR000284 0.002 0.026 b.d. 575
AGSR0010 2 4 2 AR000285 0.003 0.029 10 595
AGSR0010 4 6 2 AR000286 0.001 0.029 10 915
AGSR0010 6 8 2 AR000287 b.d. 0.015 10 1700
AGSR0010 8 10 2 AR000289 0.002 0.028 10 4500
AGSR0010 10 12 2 AR000290 0.001 0.029 10 2540
AGSR0010 12 14 2 AR000291 0.002 0.03 10 1470
AGSR0010 14 16 2 AR000292 b.d. 0.031 10 1520
AGSR0010 16 18 2 AR000293 0.003 0.042 20 1900
AGSR0010 18 20 2 AR000294 0.006 0.066 10 970
AGSR0010 20 22 2 AR000295 0.011 0.093 b.d. 450
AGSR0010 22 24 2 AR000296 0.011 0.062 b.d. 1300
AGSR0010 24 26 2 AR000297 0.027 0.392 30 10200
AGSR0010 26 28 2 AR000298 0.028 0.312 20 11100
AGSR0010 28 30 2 AR000300 0.017 0.705 40 24700
AGSR0010 30 32 2 AR000301 0.024 1.05 60 26600
AGSR0010 32 34 2 AR000302 0.026 1.08 60 24500
AGSR0010 34 36 2 AR000303 0.027 1.09 50 21600
AGSR0010 36 38 2 AR000304 0.024 0.889 40 18200
AGSR0010 38 40 2 AR000305 0.023 1.16 50 21800
AGSR0010 40 42 2 AR000306 0.024 1.42 50 23000
AGSR0010 42 44 2 AR000307 0.027 1.47 50 21100
AGSR0010 44 46 2 AR000309 0.028 0.787 30 8710
AGSR0010 46 48 2 AR000310 0.028 0.668 30 8170
AGSR0010 48 50 2 AR000311 0.038 0.669 20 23600
AGSR0010 50 52 2 AR000312 0.038 0.647 20 18200
AGSR0010 52 54 2 AR000313 0.056 0.897 30 23500
AGSR0010 54 56 2 AR000314 0.072 1.02 30 25400
AGSR0010 56 58 2 AR000315 0.046 0.704 20 8770
AGSR0010 58 60 2 AR000316 0.03 0.605 10 5820
AGSR0010 60 62 2 AR000317 0.025 0.495 10 3450
AGSR0010 62 64 2 AR000319 0.027 0.574 b.d. 2920
AGSR0010 64 66 2 AR000320 0.031 0.529 10 2340
AGSR0010 66 68 2 AR000321 0.02 0.576 10 2660
AGSR0011 0 2 2 AR000322 0.002 0.045 b.d. 555
AGSR0011 2 4 2 AR000323 0.002 0.028 b.d. 485
AGSR0011 4 6 2 AR000324 b.d. 0.023 b.d. 1140
AGSR0011 6 8 2 AR000325 b.d. 0.012 10 2700
AGSR0011 8 10 2 AR000326 b.d. 0.009 10 1070
AGSR0011 10 12 2 AR000327 0.001 0.016 10 550
AGSR0011 12 14 2 AR000329 0.001 0.017 10 660
AGSR0011 14 16 2 AR000330 0.001 0.021 10 800
AGSR0011 16 18 2 AR000331 0.001 0.022 10 870
AGSR0011 18 20 2 AR000332 0.001 0.023 10 885
AGSR0011 20 22 2 AR000333 0.001 0.026 10 850
AGSR0011 22 24 2 AR000334 0.001 0.033 10 895
AGSR0011 24 26 2 AR000335 0.002 0.045 10 850
AGSR0011 26 28 2 AR000336 0.006 0.083 b.d. 675
AGSR0011 28 30 2 AR000337 0.003 0.041 b.d. 270
AGSR0011 30 32 2 AR000339 0.001 0.024 b.d. 165
AGSR0011 32 34 2 AR000340 b.d. 0.011 b.d. 115
AGSR0011 34 36 2 AR000341 b.d. 0.011 b.d. 640
AGSR0011 36 38 2 AR000342 b.d. 0.005 10 680
AGSR0011 38 40 2 AR000343 0.005 0.063 b.d. 3920
AGSR0011 40 42 2 AR000344 0.036 0.54 50 16800
AGSR0011 42 44 2 AR000345 0.076 0.889 50 21900
AGSR0011 44 46 2 AR000346 0.113 0.697 30 15900
AGSR0011 46 48 2 AR000347 0.073 0.756 40 15700
AGSR0011 48 50 2 AR000349 0.009 0.121 b.d. 2680
AGSR0011 50 52 2 AR000350 0.022 0.656 20 12500
AGSR0011 52 54 2 AR000351 0.029 0.799 20 15700
AGSR0011 54 56 2 AR000352 0.021 0.503 10 9190
AGSR0012 0 2 2 AR000353 0.001 0.015 10 325
AGSR0012 2 4 2 AR000354 0.003 0.025 10 450
AGSR0012 4 6 2 AR000355 b.d. 0.017 10 540
AGSR0012 6 8 2 AR000356 b.d. 0.016 10 1050
AGSR0012 8 10 2 AR000357 0.001 0.015 10 2200
AGSR0012 10 12 2 AR000359 0.001 0.02 10 1240
AGSR0012 12 14 2 AR000360 0.002 0.017 10 605
AGSR0012 14 16 2 AR000361 0.001 0.014 20 520
AGSR0012 16 18 2 AR000362 b.d. 0.015 10 520
AGSR0012 18 20 2 AR000363 0.001 0.019 10 810
AGSR0012 20 22 2 AR000364 0.001 0.021 10 835
AGSR0012 22 24 2 AR000365 b.d. 0.02 10 915
AGSR0012 24 26 2 AR000366 0.001 0.023 10 940
AGSR0012 26 28 2 AR000367 0.001 0.029 20 975
AGSR0012 28 30 2 AR000369 0.001 0.045 10 1410
AGSR0012 30 32 2 AR000370 0.003 0.072 10 2120
AGSR0012 32 34 2 AR000371 0.005 0.123 20 1610
AGSR0012 34 36 2 AR000372 0.007 0.114 10 585
AGSR0012 36 38 2 AR000373 0.003 0.063 b.d. 130
AGSR0012 38 40 2 AR000374 0.011 0.222 40 4880
AGSR0012 40 42 2 AR000375 0.013 0.274 40 5550
AGSR0012 42 44 2 AR000376 0.029 0.345 50 7430
AGSR0012 44 46 2 AR000377 0.021 0.213 30 5390
AGSR0012 46 48 2 AR000379 0.03 0.181 30 6030
AGSR0012 48 50 2 AR000380 0.012 0.084 10 2270
AGSR0012 50 52 2 AR000381 0.01 0.077 10 2140
13
Hole From (m)
To (m)
Width (m)
Sample number
Co (%)
Ni (%)
Sc (g/t)
Cr (ppm)
AGSR0012 52 54 2 AR000382 0.004 0.03 10 630
AGSR0012 54 56 2 AR000383 0.005 0.02 10 295
AGSR0012 56 58 2 AR000384 0.009 0.028 b.d. 445
AGSR0012 58 60 2 AR000385 0.01 0.04 10 790
AGSR0012 60 62 2 AR000386 0.012 0.033 10 575
AGSR0012 62 64 2 AR000387 0.005 0.022 b.d. 125
AGSR0012 64 66 2 AR000389 0.014 0.036 b.d. 65
AGSR0012 66 68 2 AR000390 0.003 0.009 b.d. 55
AGSR0012 68 70 2 AR000391 0.001 0.007 b.d. 35
AGSR0012 70 72 2 AR000392 0.003 0.011 b.d. 65
AGSR0012 72 74 2 AR000393 0.002 0.008 b.d. 35
AGSR0012 74 76 2 AR000394 0.002 0.008 b.d. 115
AGSR0012 76 78 2 AR000395 0.004 0.01 10 90
AGSR0012 78 80 2 AR000396 0.003 0.011 b.d. 110
AGSR0012 80 82 2 AR000397 0.003 0.015 b.d. 95
AGSR0012 82 84 2 AR000399 0.003 0.013 b.d. 75
AGSR0012 84 86 2 AR000400 0.005 0.029 10 640
AGSR0012 86 88 2 AR000401 0.006 0.042 b.d. 550
AGSR0012 88 89 1 AR000402 0.003 0.02 b.d. 255
AGSR0013 0 2 2 AR000403 0.001 0.01 b.d. 240
AGSR0013 2 4 2 AR000404 0.003 0.021 10 395
AGSR0013 4 6 2 AR000405 0.001 0.021 10 480
AGSR0013 6 8 2 AR000406 0.002 0.023 10 580
AGSR0013 8 10 2 AR000407 0.001 0.018 10 1200
AGSR0013 10 12 2 AR000409 0.001 0.017 10 1360
AGSR0013 12 14 2 AR000410 0.002 0.019 10 1540
AGSR0013 14 16 2 AR000411 0.001 0.013 10 830
AGSR0013 16 18 2 AR000412 0.001 0.014 10 505
AGSR0013 18 20 2 AR000413 0.012 0.04 10 865
AGSR0013 20 22 2 AR000414 0.007 0.041 10 1040
AGSR0013 22 24 2 AR000415 0.002 0.033 10 1060
AGSR0013 24 26 2 AR000416 0.004 0.035 20 1140
AGSR0013 26 28 2 AR000417 0.002 0.039 20 1300
AGSR0013 28 30 2 AR000419 0.004 0.051 20 1730
AGSR0013 30 32 2 AR000420 0.005 0.102 20 2460
AGSR0013 32 34 2 AR000421 0.014 0.23 b.d. 1070
AGSR0013 34 36 2 AR000422 0.006 0.083 b.d. 585
AGSR0013 36 38 2 AR000423 0.001 0.009 b.d. 155
AGSR0013 38 40 2 AR000424 b.d. 0.004 b.d. 65
AGSR0013 40 42 2 AR000425 0.001 0.005 b.d. 110
AGSR0013 42 44 2 AR000426 b.d. 0.004 b.d. 95
AGSR0013 44 46 2 AR000427 b.d. 0.004 b.d. 125
AGSR0013 46 48 2 AR000429 b.d. 0.004 b.d. 150
AGSR0013 48 50 2 AR000430 0.001 0.01 b.d. 120
AGSR0013 50 52 2 AR000431 b.d. 0.004 10 75
AGSR0013 52 54 2 AR000432 b.d. 0.007 10 145
AGSR0013 54 56 2 AR000433 0.001 0.008 10 115
AGSR0013 56 58 2 AR000434 0.001 0.01 b.d. 150
AGSR0013 58 60 2 AR000435 0.001 0.022 10 290
AGSR0013 60 62 2 AR000436 0.018 0.081 10 205
AGSR0013 62 64 2 AR000437 0.026 0.093 10 185
AGSR0013 64 66 2 AR000439 0.011 0.056 10 155
AGSR0013 66 68 2 AR000440 0.009 0.052 10 145
AGSR0013 68 70 2 AR000441 0.006 0.03 10 90
AGSR0013 70 72 2 AR000442 0.009 0.042 20 130
AGSR0013 72 74 2 AR000443 0.004 0.027 10 145
AGSR0014 0 2 2 AR000444 0.005 0.028 10 280
AGSR0014 2 4 2 AR000445 0.003 0.024 10 330
AGSR0014 4 6 2 AR000446 0.001 0.018 10 430
AGSR0014 6 8 2 AR000447 0.001 0.022 20 560
AGSR0014 8 10 2 AR000449 b.d. 0.014 20 3150
AGSR0014 10 12 2 AR000450 0.001 0.034 30 5070
AGSR0014 12 14 2 AR000451 0.002 0.022 20 835
AGSR0014 14 16 2 AR000452 0.001 0.017 20 490
AGSR0014 16 18 2 AR000453 0.001 0.023 10 650
AGSR0014 18 20 2 AR000454 0.003 0.036 10 950
AGSR0014 20 22 2 AR000455 0.005 0.036 20 1050
AGSR0014 22 24 2 AR000456 0.004 0.037 20 1460
AGSR0014 24 26 2 AR000457 0.001 0.041 20 2430
AGSR0014 26 28 2 AR000459 0.002 0.055 20 3210
AGSR0014 28 30 2 AR000460 0.008 0.156 30 4210
AGSR0014 30 32 2 AR000461 0.023 0.25 10 2160
AGSR0014 32 34 2 AR000462 0.031 0.182 b.d. 1270
AGSR0014 34 36 2 AR000463 0.022 0.171 10 1410
AGSR0014 36 38 2 AR000464 0.031 0.243 10 1800
AGSR0014 38 40 2 AR000465 0.021 0.279 10 2910
AGSR0014 40 42 2 AR000466 0.029 0.281 20 2310
AGSR0014 42 44 2 AR000467 0.038 0.308 30 2460
AGSR0014 44 46 2 AR000469 0.038 0.42 20 4090
AGSR0014 46 48 2 AR000470 0.033 0.445 20 5960
AGSR0014 48 50 2 AR000471 0.025 0.449 10 6780
AGSR0014 50 52 2 AR000472 0.024 0.442 10 7340
AGSR0014 52 54 2 AR000473 0.021 0.413 20 6760
AGSR0014 54 56 2 AR000474 0.019 0.414 10 6690
AGSR0014 56 58 2 AR000475 0.015 0.348 10 5560
AGSR0014 58 60 2 AR000476 0.015 0.345 20 6470
AGSR0014 60 62 2 AR000477 0.013 0.364 10 7030
AGSR0014 62 64 2 AR000479 0.014 0.382 10 6300
AGSR0014 64 66 2 AR000480 0.011 0.237 10 4500
AGSR0014 66 68 2 AR000481 0.01 0.223 10 3670
AGSR0014 68 70 2 AR000482 0.017 0.315 10 4980
AGSR0015 0 2 2 AR000483 0.001 0.012 b.d. 270
AGSR0015 2 4 2 AR000484 0.002 0.022 10 395
AGSR0015 4 6 2 AR000485 0.001 0.019 10 460
Hole From (m)
To (m)
Width (m)
Sample number
Co (%)
Ni (%)
Sc (g/t)
Cr (ppm)
AGSR0015 6 8 2 AR000486 b.d. 0.019 20 530
AGSR0015 8 10 2 AR000487 b.d. 0.016 20 1600
AGSR0015 10 12 2 AR000489 0.005 0.061 30 1570
AGSR0015 12 14 2 AR000490 0.001 0.027 10 780
AGSR0015 14 16 2 AR000491 0.013 0.055 20 1400
AGSR0015 16 18 2 AR000492 0.003 0.045 20 1760
AGSR0015 18 20 2 AR000493 0.001 0.041 30 3810
AGSR0015 20 22 2 AR000494 0.002 0.047 30 5260
AGSR0015 22 24 2 AR000495 0.012 0.156 30 7550
AGSR0015 24 26 2 AR000496 0.016 0.303 50 9970
AGSR0015 26 28 2 AR000497 0.022 0.312 30 11100
AGSR0015 28 30 2 AR000499 0.016 0.329 40 15100
AGSR0015 30 32 2 AR000500 0.016 0.483 60 18100
AGSR0015 32 34 2 AR000501 0.037 0.565 40 12600
AGSR0015 34 36 2 AR000502 0.031 0.329 20 9640
AGSR0015 36 38 2 AR000503 0.094 0.704 50 13500
AGSR0015 38 40 2 AR000504 0.111 0.713 50 12500
AGSR0015 40 42 2 AR000506 0.117 0.867 40 12700
AGSR0015 42 44 2 AR000507 0.097 0.927 50 14700
AGSR0015 44 46 2 AR000508 0.082 1.05 50 19100
AGSR0015 46 48 2 AR000509 0.081 1.12 40 22100
AGSR0015 48 50 2 AR000510 0.078 1.09 50 26200
AGSR0015 50 52 2 AR000511 0.078 0.918 40 18700
AGSR0015 52 54 2 AR000512 0.1 1.05 40 22900
AGSR0015 54 56 2 AR000513 0.115 1.03 30 23400
AGSR0015 56 58 2 AR000514 0.131 1.14 40 24800
AGSR0015 58 60 2 AR000516 0.097 1.22 40 18700
AGSR0015 60 62 2 AR000517 0.046 0.726 20 9260
AGSR0015 62 64 2 AR000518 0.027 0.503 10 6740
AGSR0015 64 66 2 AR000519 0.017 0.367 20 5650
AGSR0015 66 68 2 AR000520 0.011 0.299 10 5220
AGSR0015 68 70 2 AR000521 0.012 0.317 10 4520
AGSR0015 70 72 2 AR000522 0.016 0.43 20 5390
AGSR0015 72 74 2 AR000523 0.016 0.393 10 5410
AGSR0016 0 2 2 AR000524 0.002 0.034 20 580
AGSR0016 2 4 2 AR000526 0.002 0.032 10 515
AGSR0016 4 6 2 AR000527 0.001 0.028 10 700
AGSR0016 6 8 2 AR000528 b.d. 0.053 20 3170
AGSR0016 8 10 2 AR000529 0.001 0.148 30 5130
AGSR0016 10 12 2 AR000530 0.008 0.422 50 7470
AGSR0016 12 14 2 AR000531 0.01 0.454 40 7050
AGSR0016 14 16 2 AR000532 0.01 0.516 50 8550
AGSR0016 16 18 2 AR000533 0.021 0.656 60 10700
AGSR0016 18 20 2 AR000534 0.021 0.666 50 10600
AGSR0016 20 22 2 AR000536 0.018 0.59 50 10800
AGSR0016 22 24 2 AR000537 0.03 0.735 50 9720
AGSR0016 24 26 2 AR000538 0.063 0.834 50 7980
AGSR0016 26 28 2 AR000539 0.064 0.908 50 8270
AGSR0016 28 30 2 AR000540 0.05 0.931 50 9070
AGSR0016 30 32 2 AR000541 0.034 0.88 40 8660
AGSR0016 32 34 2 AR000542 0.026 0.727 30 7050
AGSR0016 34 36 2 AR000543 0.023 0.648 30 5420
AGSR0016 36 38 2 AR000544 0.02 0.596 20 3800
AGSR0016 38 40 2 AR000546 0.008 0.291 10 1500
AGSR0016 40 41 1 AR000547 0.009 0.306 b.d. 1340
AGSR0017 0 2 2 AR000548 b.d. 0.013 10 280
AGSR0017 2 4 2 AR000549 0.002 0.024 b.d. 415
AGSR0017 4 6 2 AR000550 b.d. 0.023 20 640
AGSR0017 6 8 2 AR000551 0.001 0.026 20 1920
AGSR0017 8 10 2 AR000552 0.007 0.105 30 5950
AGSR0017 10 12 2 AR000553 0.014 0.231 40 6450
AGSR0017 12 14 2 AR000554 0.026 0.359 30 7570
AGSR0017 14 16 2 AR000556 0.048 0.573 50 9640
AGSR0017 16 18 2 AR000557 0.037 0.696 50 7640
AGSR0017 18 20 2 AR000558 0.026 0.571 30 5200
AGSR0017 20 22 2 AR000559 0.026 0.634 30 6710
AGSR0017 22 24 2 AR000560 0.032 0.751 40 11500
AGSR0017 24 26 2 AR000561 0.034 0.907 50 24800
AGSR0017 26 28 2 AR000562 0.07 0.843 30 18000
AGSR0017 28 30 2 AR000563 0.142 0.992 30 20600
AGSR0017 30 32 2 AR000564 0.096 0.785 30 18300
AGSR0017 32 34 2 AR000566 0.058 0.589 10 12000
AGSR0017 34 36 2 AR000567 0.052 0.528 10 9510
AGSR0017 36 38 2 AR000568 0.044 0.479 10 6420
AGSR0017 38 40 2 AR000569 0.035 0.467 10 4090
AGSR0017 40 42 2 AR000570 0.022 0.387 b.d. 3240
AGSR0017 42 44 2 AR000571 0.019 0.358 b.d. 3050
AGSR0017 44 46 2 AR000572 0.022 0.372 b.d. 3280
AGSR0018 0 2 2 AR000573 0.001 0.021 b.d. 435
AGSR0018 2 4 2 AR000574 0.003 0.053 10 870
AGSR0018 4 6 2 AR000576 0.003 0.035 10 965
AGSR0018 6 8 2 AR000577 0.003 0.162 10 6460
AGSR0018 8 10 2 AR000578 0.005 0.288 20 15400
AGSR0018 10 12 2 AR000579 0.016 0.34 40 26200
AGSR0018 12 14 2 AR000580 0.017 0.407 30 19700
AGSR0018 14 16 2 AR000581 0.02 0.444 10 8780
AGSR0018 16 18 2 AR000582 0.021 0.459 10 7860
AGSR0018 18 20 2 AR000583 0.024 0.506 20 5020
AGSR0018 20 22 2 AR000584 0.064 0.595 20 8090
AGSR0018 22 24 2 AR000586 0.035 0.393 b.d. 6800
AGSR0018 24 26 2 AR000587 0.017 0.308 b.d. 3310
AGSR0018 26 28 2 AR000588 0.012 0.246 b.d. 2110
AGSR0018 28 30 2 AR000589 0.012 0.299 b.d. 1880
AGSR0018 30 32 2 AR000590 0.008 0.225 b.d. 2160
14
Hole From (m)
To (m)
Width (m)
Sample number
Co (%)
Ni (%)
Sc (g/t)
Cr (ppm)
AGSR0018 32 34 2 AR000591 0.005 0.184 b.d. 1490
AGSR0018 34 35 1 AR000592 0.005 0.186 b.d. 2170
AGSR0019 0 2 2 AR000593 b.d. 0.016 b.d. 365
AGSR0019 2 4 2 AR000594 0.001 0.02 10 420
AGSR0019 4 6 2 AR000596 0.001 0.028 10 720
AGSR0019 6 8 2 AR000597 0.001 0.063 10 2080
AGSR0019 8 10 2 AR000598 0.003 0.107 10 3670
AGSR0019 10 12 2 AR000599 0.008 0.259 10 3260
AGSR0019 12 14 2 AR000600 0.011 0.481 20 4670
AGSR0019 14 16 2 AR000601 0.018 0.402 10 2700
AGSR0019 16 18 2 AR000602 0.022 0.448 10 2820
AGSR0019 18 20 2 AR000603 0.036 0.513 10 4770
AGSR0019 20 22 2 AR000605 0.017 0.232 b.d. 2380
AGSR0019 22 24 2 AR000606 0.02 0.223 b.d. 2220
AGSR0019 24 26 2 AR000607 0.054 0.547 10 7460
AGSR0019 26 28 2 AR000608 0.048 0.524 10 6290
AGSR0019 28 30 2 AR000609 0.032 0.366 b.d. 3720
AGSR0019 30 32 2 AR000610 0.021 0.27 b.d. 3010
AGSR0019 32 34 2 AR000611 0.016 0.249 b.d. 3140
AGSR0019 34 35 1 AR000612 0.014 0.23 b.d. 2590
AGSR0020 0 2 2 AR000613 0.001 0.015 b.d. 320
AGSR0020 2 4 2 AR000614 0.002 0.019 10 390
AGSR0020 4 6 2 AR000616 b.d. 0.015 10 435
AGSR0020 6 8 2 AR000617 0.001 0.025 20 2090
AGSR0020 8 10 2 AR000618 0.001 0.04 20 3740
AGSR0020 10 12 2 AR000619 0.008 0.216 40 9000
AGSR0020 12 14 2 AR000620 0.014 0.277 50 6180
AGSR0020 14 16 2 AR000621 0.042 0.57 50 8480
AGSR0020 16 18 2 AR000622 0.038 0.37 30 4020
AGSR0020 18 20 2 AR000623 0.035 0.448 30 4780
AGSR0020 20 22 2 AR000624 0.011 0.25 10 2170
AGSR0020 22 24 2 AR000626 0.017 0.428 30 3410
AGSR0020 24 26 2 AR000627 0.018 0.477 20 4040
AGSR0020 26 28 2 AR000628 0.015 0.485 20 4090
AGSR0020 28 30 2 AR000629 0.019 0.66 20 5740
AGSR0020 30 32 2 AR000630 0.022 0.903 30 6910
AGSR0020 32 34 2 AR000631 0.014 0.526 20 4730
AGSR0020 34 36 2 AR000632 0.015 0.558 10 4500
AGSR0020 36 38 2 AR000633 0.022 0.585 20 4480
AGSR0020 38 40 2 AR000634 0.031 0.586 10 3550
AGSR0020 40 42 2 AR000636 0.027 0.529 b.d. 2610
AGSR0020 42 44 2 AR000637 0.022 0.435 b.d. 2070
AGSR0020 44 46 2 AR000638 0.01 0.247 b.d. 1060
AGSR0021 0 2 2 AR000639 0.001 0.02 b.d. 350
AGSR0021 2 4 2 AR000640 0.002 0.021 b.d. 385
AGSR0021 4 6 2 AR000641 0.003 0.049 10 950
AGSR0021 6 8 2 AR000642 b.d. 0.013 10 1080
AGSR0021 8 10 2 AR000643 0.001 0.02 10 695
AGSR0021 10 12 2 AR000644 0.001 0.021 10 615
AGSR0021 12 14 2 AR000646 0.001 0.028 10 755
AGSR0021 14 16 2 AR000647 0.001 0.021 10 660
AGSR0021 16 18 2 AR000648 0.001 0.026 20 655
AGSR0021 18 20 2 AR000649 0.005 0.043 10 490
AGSR0021 20 22 2 AR000650 0.001 0.015 b.d. 185
AGSR0021 22 24 2 AR000651 0.001 0.013 b.d. 115
AGSR0021 24 26 2 AR000652 b.d. 0.009 b.d. 40
AGSR0021 26 28 2 AR000653 0.001 0.023 10 610
AGSR0021 28 30 2 AR000654 0.001 0.019 10 855
AGSR0021 30 32 2 AR000656 b.d. 0.003 b.d. 225
AGSR0021 32 34 2 AR000657 0.001 0.024 b.d. 460
AGSR0021 34 36 2 AR000658 0.002 0.039 10 1070
AGSR0021 36 38 2 AR000659 0.001 0.017 b.d. 865
AGSR0021 38 40 2 AR000660 0.001 0.01 b.d. 525
AGSR0021 40 42 2 AR000661 0.001 0.034 10 2690
AGSR0021 42 44 2 AR000662 0.004 0.049 b.d. 1320
AGSR0021 44 46 2 AR000663 0.013 0.17 10 2540
AGSR0021 46 48 2 AR000664 0.019 0.319 10 5020
AGSR0021 48 50 2 AR000666 0.026 0.424 10 8060
AGSR0021 50 52 2 AR000667 0.025 0.42 10 8270
AGSR0021 52 54 2 AR000668 0.015 0.416 10 5810
AGSR0021 54 56 2 AR000669 0.016 0.317 10 5540
AGSR0021 56 58 2 AR000670 0.019 0.4 10 6950
AGSR0021 58 60 2 AR000671 0.02 0.428 10 7480
AGSR0021 60 62 2 AR000672 0.021 0.399 b.d. 3420
AGSR0021 62 64 2 AR000673 0.018 0.354 b.d. 3880
AGSR0021 64 65 1 AR000674 0.016 0.308 b.d. 3770
AGSR0022 0 2 2 AR000676 0.001 0.012 b.d. 265
AGSR0022 2 4 2 AR000677 0.001 0.015 b.d. 340
AGSR0022 4 6 2 AR000678 0.001 0.015 b.d. 775
AGSR0022 6 8 2 AR000679 b.d. 0.013 b.d. 2360
AGSR0022 8 10 2 AR000680 0.003 0.038 b.d. 810
AGSR0022 10 12 2 AR000681 0.012 0.088 10 660
AGSR0022 12 14 2 AR000682 0.013 0.081 b.d. 245
AGSR0022 14 16 2 AR000683 0.002 0.023 b.d. 60
AGSR0022 16 18 2 AR000684 b.d. 0.016 b.d. 40
AGSR0022 18 20 2 AR000686 b.d. 0.017 b.d. 925
AGSR0022 20 22 2 AR000687 b.d. 0.012 b.d. 540
AGSR0022 22 24 2 AR000688 0.013 0.243 20 17000
AGSR0022 24 26 2 AR000689 0.038 0.391 20 20100
AGSR0022 26 28 2 AR000690 0.058 0.41 20 20000
AGSR0022 28 30 2 AR000691 0.058 0.605 30 20300
AGSR0022 30 32 2 AR000692 0.045 1.13 30 19500
AGSR0022 32 34 2 AR000693 0.024 0.53 20 9710
AGSR0022 34 36 2 AR000694 0.032 0.597 20 11700
Hole From (m)
To (m)
Width (m)
Sample number
Co (%)
Ni (%)
Sc (g/t)
Cr (ppm)
AGSR0022 36 38 2 AR000696 0.067 0.832 20 18400
AGSR0022 38 40 2 AR000697 0.091 0.721 10 14700
AGSR0022 40 42 2 AR000698 0.119 0.861 20 17600
AGSR0022 42 44 2 AR000699 0.059 0.445 b.d. 8090
AGSR0022 44 46 2 AR000700 0.038 0.278 b.d. 4010
AGSR0022 46 47 1 AR000701 0.04 0.271 b.d. 3590
AGSR0023 0 2 2 AR000702 0.002 0.026 b.d. 570
AGSR0023 2 4 2 AR000703 0.004 0.067 b.d. 1400
AGSR0023 4 6 2 AR000704 0.013 0.217 10 5880
AGSR0023 6 8 2 AR000706 0.001 0.019 b.d. 4380
AGSR0023 8 10 2 AR000707 0.001 0.027 b.d. 2940
AGSR0023 10 12 2 AR000708 0.004 0.092 b.d. 4540
AGSR0023 12 14 2 AR000709 0.014 0.345 20 5970
AGSR0023 14 16 2 AR000710 0.06 0.871 10 2350
AGSR0023 16 18 2 AR000711 0.041 0.582 10 4860
AGSR0023 18 20 2 AR000712 0.036 0.417 b.d. 3090
AGSR0023 20 22 2 AR000713 0.028 0.239 b.d. 1200
AGSR0023 22 24 2 AR000714 0.022 0.203 b.d. 975
AGSR0023 24 26 2 AR000716 0.013 0.164 b.d. 685
AGSR0023 26 28 2 AR000717 0.011 0.15 b.d. 735
AGSR0023 28 30 2 AR000718 0.014 0.196 b.d. 940
AGSR0023 30 32 2 AR000719 0.012 0.208 b.d. 1250
AGSR0023 32 34 2 AR000720 0.015 0.221 b.d. 885
AGSR0023 34 36 2 AR000721 0.015 0.249 b.d. 540
AGSR0023 36 38 2 AR000722 0.011 0.175 b.d. 630
AGSR0024 0 2 2 AR000723 0.001 0.017 b.d. 280
AGSR0024 2 4 2 AR000724 0.004 0.032 b.d. 380
AGSR0024 4 6 2 AR000726 0.003 0.036 b.d. 855
AGSR0024 6 8 2 AR000727 0.002 0.023 b.d. 895
AGSR0024 8 10 2 AR000728 0.002 0.045 b.d. 755
AGSR0024 10 12 2 AR000729 0.008 0.157 b.d. 275
AGSR0024 12 14 2 AR000730 0.032 0.38 b.d. 210
AGSR0024 14 16 2 AR000731 0.05 0.36 b.d. 115
AGSR0024 16 18 2 AR000732 0.045 0.431 b.d. 125
AGSR0024 18 20 2 AR000733 0.027 0.38 b.d. 95
AGSR0024 20 22 2 AR000734 0.032 0.437 b.d. 95
AGSR0024 22 24 2 AR000736 0.026 0.414 b.d. 90
AGSR0024 24 26 2 AR000737 0.051 0.402 b.d. 80
AGSR0024 26 28 2 AR000738 0.036 0.422 b.d. 85
AGSR0024 28 30 2 AR000739 0.019 0.303 b.d. 75
AGSR0024 30 32 2 AR000740 0.014 0.193 b.d. 90
AGSR0024 32 34 2 AR000741 0.011 0.148 b.d. 60
AGSR0024 34 36 2 AR000742 0.014 0.149 b.d. 110
AGSR0024 36 38 2 AR000743 0.013 0.145 b.d. 95
AGSR0024 38 40 2 AR000744 0.009 0.094 b.d. 145
AGSR0024 40 42 2 AR000746 0.006 0.075 b.d. 75
AGSR0024 42 44 2 AR000747 0.004 0.05 b.d. 75
AGSR0025 0 2 2 AR000748 0.001 0.025 b.d. 350
AGSR0025 2 4 2 AR000749 0.001 0.022 b.d. 550
AGSR0025 4 6 2 AR000750 0.01 0.133 20 9370
AGSR0025 6 8 2 AR000751 0.006 0.141 20 11600
AGSR0025 8 10 2 AR000752 0.004 0.097 40 14500
AGSR0025 10 12 2 AR000753 0.012 0.191 50 14400
AGSR0025 12 14 2 AR000754 0.015 0.382 80 18200
AGSR0025 14 16 2 AR000756 0.026 0.406 60 15700
AGSR0025 16 18 2 AR000757 0.02 0.416 50 16400
AGSR0025 18 20 2 AR000758 0.024 0.458 40 10000
AGSR0025 20 22 2 AR000759 0.027 0.619 40 8890
AGSR0025 22 24 2 AR000760 0.025 0.584 60 15000
AGSR0025 24 26 2 AR000761 0.015 0.569 30 13100
AGSR0025 26 28 2 AR000762 0.025 0.984 40 15400
AGSR0025 28 30 2 AR000763 0.03 0.971 40 12700
AGSR0025 30 32 2 AR000764 0.035 0.997 30 11000
AGSR0025 32 34 2 AR000766 0.042 1.03 20 9520
AGSR0025 34 36 2 AR000767 0.041 1.08 30 10300
AGSR0025 36 38 2 AR000768 0.039 0.915 20 7960
AGSR0025 38 40 2 AR000769 0.031 0.686 b.d. 5460
AGSR0025 40 41 1 AR000770 0.033 0.532 b.d. 4420
AGSR0026 0 2 2 AR000771 0.002 0.025 b.d. 500
AGSR0026 2 4 2 AR000772 0.005 0.038 b.d. 535
AGSR0026 4 6 2 AR000773 0.002 0.039 10 1060
AGSR0026 6 8 2 AR000774 0.002 0.034 10 1570
AGSR0026 8 10 2 AR000776 0.007 0.131 20 3000
AGSR0026 10 12 2 AR000777 0.075 0.606 30 3120
AGSR0026 12 14 2 AR000778 0.027 0.734 b.d. 6500
AGSR0026 14 16 2 AR000779 0.025 0.771 10 6180
AGSR0026 16 18 2 AR000780 0.035 1.05 20 6190
AGSR0026 18 20 2 AR000781 0.032 1.41 10 8820
AGSR0026 20 22 2 AR000782 0.029 1.26 20 11100
AGSR0026 22 24 2 AR000783 0.111 1.77 20 12900
AGSR0026 24 26 2 AR000784 0.088 1.45 20 11500
AGSR0026 26 28 2 AR000786 0.122 0.967 10 11900
AGSR0026 28 30 2 AR000787 0.086 0.944 10 10100
AGSR0026 30 32 2 AR000788 0.063 0.732 10 10200
AGSR0026 32 34 2 AR000789 0.05 0.627 10 7340
AGSR0026 34 36 2 AR000790 0.041 0.56 20 9680
AGSR0026 36 38 2 AR000791 0.015 0.396 10 6400
AGSR0026 38 40 2 AR000792 0.024 0.43 20 6300
AGSR0026 40 41 1 AR000793 0.017 0.35 10 6920
AGSR0027 0 2 2 AR000794 0.003 0.036 b.d. 535
AGSR0027 2 4 2 AR000796 0.005 0.059 10 775
AGSR0027 4 6 2 AR000797 0.007 0.126 10 1720
AGSR0027 6 8 2 AR000798 b.d. 0.01 10 750
AGSR0027 8 10 2 AR000799 0.006 0.115 10 1440
15
Hole From (m)
To (m)
Width (m)
Sample number
Co (%)
Ni (%)
Sc (g/t)
Cr (ppm)
AGSR0027 10 12 2 AR000800 0.005 0.07 b.d. 1020
AGSR0027 12 14 2 AR000801 0.002 0.034 10 660
AGSR0027 14 16 2 AR000802 0.004 0.029 10 730
AGSR0027 16 18 2 AR000803 0.002 0.039 b.d. 1220
AGSR0027 18 20 2 AR000804 0.003 0.047 10 1660
AGSR0027 20 22 2 AR000806 0.002 0.054 10 2120
AGSR0027 22 24 2 AR000807 0.003 0.043 10 3280
AGSR0027 24 26 2 AR000808 0.014 0.178 30 5650
AGSR0027 26 28 2 AR000809 0.015 0.158 30 4620
AGSR0027 28 30 2 AR000810 0.021 0.262 40 7190
AGSR0027 30 32 2 AR000811 0.035 0.393 40 10700
AGSR0027 32 34 2 AR000812 0.038 0.439 40 14500
AGSR0027 34 36 2 AR000813 0.045 0.426 30 12100
AGSR0027 36 38 2 AR000814 0.051 0.459 30 13600
AGSR0027 38 40 2 AR000816 0.082 0.522 40 20100
AGSR0027 40 42 2 AR000817 0.08 0.589 30 17500
AGSR0027 42 44 2 AR000818 0.044 0.328 10 8950
AGSR0027 44 46 2 AR000819 0.045 0.291 b.d. 8430
AGSR0027 46 47 1 AR000820 0.027 0.211 b.d. 6530
AGSR0028 0 2 2 AR000821 0.003 0.033 b.d. 870
AGSR0028 2 4 2 AR000822 0.006 0.039 b.d. 985
AGSR0028 4 6 2 AR000823 0.002 0.028 b.d. 1040
AGSR0028 6 8 2 AR000824 b.d. 0.015 b.d. 960
AGSR0028 8 10 2 AR000826 0.002 0.02 10 815
AGSR0028 10 12 2 AR000827 0.002 0.024 b.d. 755
AGSR0028 12 14 2 AR000828 0.003 0.031 10 915
AGSR0028 14 16 2 AR000829 0.009 0.038 20 880
AGSR0028 16 18 2 AR000830 0.001 0.031 10 1140
AGSR0028 18 20 2 AR000831 0.002 0.034 b.d. 1780
AGSR0028 20 22 2 AR000832 0.001 0.035 10 2470
AGSR0028 22 24 2 AR000833 0.002 0.039 10 4300
AGSR0028 24 26 2 AR000834 0.004 0.081 10 4640
AGSR0028 26 28 2 AR000836 0.013 0.216 30 8020
AGSR0028 28 30 2 AR000837 0.015 0.271 40 7120
AGSR0028 30 32 2 AR000838 0.017 0.239 40 7180
AGSR0028 32 34 2 AR000839 0.026 0.254 30 11400
AGSR0028 34 36 2 AR000840 0.031 0.282 30 13900
AGSR0028 36 38 2 AR000841 0.042 0.386 40 11900
AGSR0028 38 40 2 AR000842 0.045 0.373 30 14700
AGSR0028 40 42 2 AR000843 0.047 0.389 30 15400
AGSR0028 42 44 2 AR000844 0.046 0.405 30 14600
AGSR0028 44 46 2 AR000846 0.052 0.455 30 21500
AGSR0028 46 47 1 AR000847 0.052 0.512 30 20900
AGSR0029 0 2 2 AR000848 0.002 0.025 b.d. 665
AGSR0029 2 4 2 AR000849 0.007 0.063 10 2010
AGSR0029 4 6 2 AR000850 0.007 0.073 b.d. 2350
AGSR0029 6 8 2 AR000851 b.d. 0.014 b.d. 1170
AGSR0029 8 10 2 AR000852 0.003 0.036 10 1750
AGSR0029 10 12 2 AR000853 0.004 0.044 10 2380
AGSR0029 12 14 2 AR000854 0.007 0.073 10 2500
AGSR0029 14 16 2 AR000856 0.004 0.047 b.d. 1970
AGSR0029 16 18 2 AR000857 0.004 0.045 10 2010
AGSR0029 18 20 2 AR000858 0.003 0.06 10 3820
AGSR0029 20 22 2 AR000859 0.02 0.273 10 10900
AGSR0029 22 24 2 AR000860 0.041 0.327 20 8160
AGSR0029 24 26 2 AR000861 0.035 0.4 10 15800
AGSR0029 26 28 2 AR000862 0.056 0.61 40 16400
AGSR0029 28 30 2 AR000863 0.048 0.455 30 26900
AGSR0029 30 32 2 AR000864 0.074 0.676 40 22200
AGSR0029 32 34 2 AR000866 0.079 0.862 30 17300
AGSR0029 34 36 2 AR000867 0.079 0.887 30 15300
AGSR0029 36 38 2 AR000868 0.068 0.758 30 15500
AGSR0029 38 40 2 AR000869 0.059 0.655 20 16700
AGSR0029 40 42 2 AR000870 0.046 0.499 20 12900
AGSR0029 42 44 2 AR000871 0.04 0.447 20 10100
AGSR0029 44 46 2 AR000872 0.037 0.421 20 10700
AGSR0029 46 48 2 AR000873 0.036 0.418 b.d. 12200
AGSR0029 48 50 2 AR000874 0.035 0.413 b.d. 11400
AGSR0029 50 52 2 AR000876 0.02 0.237 b.d. 5470
AGSR0029 52 53 1 AR000877 0.019 0.218 b.d. 5200
AGSR0030 0 2 2 AR000878 0.001 0.012 b.d. 275
AGSR0030 2 4 2 AR000879 0.001 0.019 b.d. 435
AGSR0030 4 6 2 AR000880 0.002 0.022 b.d. 880
AGSR0030 6 8 2 AR000881 0.001 0.009 b.d. 665
AGSR0030 8 10 2 AR000882 0.001 0.015 b.d. 605
AGSR0030 10 12 2 AR000883 b.d. 0.018 b.d. 635
AGSR0030 12 14 2 AR000884 0.004 0.034 b.d. 735
AGSR0030 14 16 2 AR000886 0.004 0.032 b.d. 610
AGSR0030 16 18 2 AR000887 b.d. 0.007 b.d. 115
AGSR0030 18 20 2 AR000888 b.d. 0.004 b.d. 30
AGSR0030 20 22 2 AR000889 b.d. 0.004 b.d. 45
AGSR0030 22 24 2 AR000890 b.d. 0.009 b.d. 705
AGSR0030 24 26 2 AR000891 0.001 0.017 b.d. 645
AGSR0030 26 28 2 AR000892 b.d. 0.017 b.d. 710
AGSR0030 28 30 2 AR000893 0.001 0.027 b.d. 910
AGSR0030 30 32 2 AR000894 b.d. 0.02 b.d. 970
AGSR0030 32 34 2 AR000896 0.001 0.037 b.d. 2330
AGSR0030 34 36 2 AR000897 0.013 0.316 b.d. 9730
AGSR0030 36 38 2 AR000898 0.026 0.515 b.d. 10500
AGSR0030 38 40 2 AR000899 0.05 0.962 20 20900
AGSR0030 40 42 2 AR000900 0.065 0.909 20 19200
AGSR0030 42 44 2 AR000901 0.057 0.836 10 22700
AGSR0030 44 46 2 AR000902 0.031 0.378 b.d. 11600
AGSR0030 46 47 1 AR000903 0.023 0.276 b.d. 8520
Hole From (m)
To (m)
Width (m)
Sample number
Co (%)
Ni (%)
Sc (g/t)
Cr (ppm)
AGSR0031 0 2 2 AR000904 0.001 0.014 b.d. 285
AGSR0031 2 4 2 AR000906 0.002 0.016 10 425
AGSR0031 4 6 2 AR000907 0.001 0.016 10 1320
AGSR0031 6 8 2 AR000908 0.001 0.006 10 590
AGSR0031 8 10 2 AR000909 0.001 0.012 10 350
AGSR0031 10 12 2 AR000910 b.d. 0.008 b.d. 655
AGSR0031 12 14 2 AR000911 0.001 0.007 b.d. 295
AGSR0031 14 16 2 AR000912 0.001 0.019 b.d. 740
AGSR0031 16 18 2 AR000913 0.002 0.016 10 935
AGSR0031 18 20 2 AR000914 0.001 0.02 b.d. 975
AGSR0031 20 22 2 AR000916 0.002 0.05 b.d. 1620
AGSR0031 22 24 2 AR000917 0.005 0.138 b.d. 1750
AGSR0031 24 26 2 AR000918 0.019 0.48 10 5060
AGSR0031 26 28 2 AR000919 0.016 0.448 b.d. 6220
AGSR0031 28 30 2 AR000920 0.013 0.365 10 5180
AGSR0031 30 32 2 AR000921 0.013 0.301 b.d. 5060
AGSR0031 32 34 2 AR000922 0.019 0.263 b.d. 3770
AGSR0031 34 36 2 AR000923 0.009 0.198 b.d. 3140
AGSR0031 36 38 2 AR000924 0.016 0.26 b.d. 3380
AGSR0031 38 40 2 AR000926 0.016 0.283 b.d. 3930
AGSR0031 40 42 2 AR000927 0.019 0.288 b.d. 4080
AGSR0031 42 44 2 AR000928 0.018 0.243 b.d. 4480
AGSR0032 0 2 2 AR000929 0.003 0.036 b.d. 795
AGSR0032 2 4 2 AR000930 0.007 0.184 20 13100
AGSR0032 4 6 2 AR000931 0.007 0.198 20 13200
AGSR0032 6 8 2 AR000932 0.005 0.094 10 4680
AGSR0032 8 10 2 AR000933 0.007 0.236 10 5350
AGSR0032 10 12 2 AR000934 0.012 0.385 20 5980
AGSR0032 12 14 2 AR000936 0.016 0.439 20 7070
AGSR0032 14 16 2 AR000937 0.02 0.693 10 15300
AGSR0032 16 18 2 AR000938 0.021 0.625 10 14100
AGSR0032 18 20 2 AR000939 0.016 0.541 10 10500
AGSR0032 20 22 2 AR000940 0.023 0.544 10 16800
AGSR0032 22 24 2 AR000941 0.021 0.572 20 15200
AGSR0032 24 26 2 AR000942 0.016 0.423 10 13700
AGSR0032 26 28 2 AR000943 0.013 0.355 10 10600
AGSR0032 28 30 2 AR000944 0.039 0.781 10 12000
AGSR0032 30 32 2 AR000946 0.048 0.733 b.d. 15600
AGSR0032 32 34 2 AR000947 0.05 0.704 b.d. 9560
AGSR0032 34 36 2 AR000948 0.02 0.484 10 16200
AGSR0032 36 38 2 AR000949 0.036 0.414 b.d. 7490
AGSR0032 38 40 2 AR000950 0.028 0.322 b.d. 3000
AGSR0032 40 42 2 AR000951 0.029 0.396 b.d. 6940
AGSR0032 42 44 2 AR000952 0.022 0.381 b.d. 6650
AGSR0032 44 46 2 AR000953 0.025 0.51 b.d. 9510
AGSR0032 46 47 1 AR000954 0.021 0.456 b.d. 6790
AGSR0033 0 2 2 AR000956 0.004 0.061 b.d. 1120
AGSR0033 2 4 2 AR000957 0.018 0.374 30 6400
AGSR0033 4 6 2 AR000958 0.022 0.465 40 12500
AGSR0033 6 8 2 AR000959 0.01 0.187 20 5780
AGSR0033 8 10 2 AR000960 0.007 0.133 20 6320
AGSR0033 10 12 2 AR000961 0.014 0.249 20 4120
AGSR0033 12 14 2 AR000962 0.017 0.336 20 2070
AGSR0033 14 16 2 AR000963 0.028 0.445 20 1860
AGSR0033 16 18 2 AR000964 0.018 0.468 20 2550
AGSR0033 18 20 2 AR000966 0.037 0.692 10 3300
AGSR0033 20 22 2 AR000967 0.037 0.597 10 4450
AGSR0033 22 24 2 AR000968 0.032 0.367 10 2380
AGSR0033 24 26 2 AR000969 0.023 0.267 b.d. 885
AGSR0033 26 28 2 AR000970 0.019 0.25 b.d. 835
AGSR0033 28 30 2 AR000971 0.017 0.192 b.d. 625
AGSR0033 30 32 2 AR000972 0.018 0.23 b.d. 910
AGSR0033 32 33 1 AR000973 0.017 0.208 b.d. 675
AGSR0034 0 2 2 AR000974 0.002 0.018 10 385
AGSR0034 2 4 2 AR000976 0.005 0.066 10 2020
AGSR0034 4 6 2 AR000977 0.008 0.131 30 5460
AGSR0034 6 8 2 AR000978 0.003 0.046 20 6080
AGSR0034 8 10 2 AR000979 0.005 0.082 20 9090
AGSR0034 10 12 2 AR000980 0.011 0.203 40 8020
AGSR0034 12 14 2 AR000981 0.011 0.3 40 10100
AGSR0034 14 16 2 AR000982 0.017 0.525 40 6500
AGSR0034 16 18 2 AR000983 0.038 0.932 30 6470
AGSR0034 18 20 2 AR000984 0.028 0.478 b.d. 1920
AGSR0034 20 22 2 AR000986 0.022 0.417 10 2050
AGSR0034 22 24 2 AR000987 0.013 0.156 b.d. 970
AGSR0034 24 26 2 AR000988 0.017 0.283 b.d. 1540
AGSR0034 26 28 2 AR000989 0.016 0.296 10 1360
AGSR0034 28 30 2 AR000990 0.016 0.261 b.d. 985
AGSR0034 30 32 2 AR000991 0.018 0.37 b.d. 1480
AGSR0034 32 34 2 AR000992 0.01 0.237 b.d. 1220
AGSR0034 34 36 2 AR000993 0.017 0.506 b.d. 2330
AGSR0034 36 38 2 AR000994 0.016 0.234 b.d. 990
AGSR0034 38 40 2 AR000996 0.013 0.202 b.d. 995
AGSR0034 40 42 2 AR000997 0.012 0.271 b.d. 1220
AGSR0034 42 44 2 AR000998 0.007 0.219 b.d. 1100
AGSR0034 44 46 2 AR000999 0.007 0.225 b.d. 1010
AGSR0034 46 48 2 AR001000 0.007 0.215 b.d. 1210
AGSR0035 0 2 2 AR001001 0.002 0.02 b.d. 320
AGSR0035 2 4 2 AR001003 0.002 0.032 10 640
AGSR0035 4 6 2 AR001004 0.001 0.017 10 1060
AGSR0035 6 8 2 AR001005 0.002 0.018 10 950
AGSR0035 8 10 2 AR001006 0.011 0.111 30 2850
AGSR0035 10 12 2 AR001007 0.017 0.153 40 6550
AGSR0035 12 14 2 AR001008 0.022 0.302 50 9940
16
Hole From (m)
To (m)
Width (m)
Sample number
Co (%)
Ni (%)
Sc (g/t)
Cr (ppm)
AGSR0035 14 16 2 AR001009 0.018 0.35 80 13800
AGSR0035 16 18 2 AR001010 0.026 0.376 50 10300
AGSR0035 18 20 2 AR001011 0.041 0.602 30 9940
AGSR0035 20 22 2 AR001013 0.048 1 20 13800
AGSR0035 22 24 2 AR001014 0.069 1.92 40 17000
AGSR0035 24 26 2 AR001015 0.094 1.52 30 14800
AGSR0035 26 28 2 AR001016 0.037 0.878 20 12200
AGSR0035 28 30 2 AR001017 0.031 0.652 b.d. 11300
AGSR0035 30 32 2 AR001018 0.038 0.829 20 12000
AGSR0035 32 34 2 AR001019 0.033 0.822 20 9710
AGSR0035 34 36 2 AR001020 0.021 0.513 20 8120
AGSR0035 36 38 2 AR001021 0.022 0.425 20 7410
AGSR0035 38 40 2 AR001023 0.023 0.394 10 6990
AGSR0035 40 42 2 AR001024 0.023 0.342 10 5810
AGSR0035 42 44 2 AR001025 0.014 0.274 10 4330
AGSR0035 44 45 1 AR001026 0.014 0.264 b.d. 3340
AGSR0036 0 2 2 AR001027 0.017 0.312 10 4980
AGSR0036 2 4 2 AR001028 0.005 0.092 b.d. 1770
AGSR0036 4 6 2 AR001029 0.001 0.006 10 1100
AGSR0036 6 8 2 AR001030 0.001 0.01 b.d. 940
AGSR0036 8 10 2 AR001031 0.004 0.052 b.d. 1500
AGSR0036 10 12 2 AR001033 0.004 0.066 b.d. 1560
AGSR0036 12 14 2 AR001034 0.001 0.014 10 830
AGSR0036 14 16 2 AR001035 0.005 0.14 b.d. 3490
AGSR0036 16 18 2 AR001036 0.04 0.716 b.d. 5040
AGSR0036 18 20 2 AR001037 0.028 0.564 10 8550
AGSR0036 20 22 2 AR001038 0.028 0.371 b.d. 5900
AGSR0036 22 24 2 AR001039 0.025 0.287 b.d. 4430
AGSR0036 24 26 2 AR001040 0.019 0.224 b.d. 3230
AGSR0036 26 28 2 AR001041 0.027 0.261 b.d. 3920
AGSR0036 28 30 2 AR001043 0.027 0.241 b.d. 3110
AGSR0036 30 32 2 AR001044 0.025 0.389 b.d. 5620
AGSR0036 32 33 1 AR001045 0.022 0.284 b.d. 5000
AGSR0037 0 2 2 AR001046 0.002 0.021 b.d. 455
AGSR0037 2 4 2 AR001047 0.002 0.048 b.d. 2090
AGSR0037 4 6 2 AR001048 0.006 0.192 20 11000
AGSR0037 6 8 2 AR001049 0.004 0.148 10 8990
AGSR0037 8 10 2 AR001050 0.002 0.025 10 860
AGSR0037 10 12 2 AR001051 0.001 0.016 10 165
AGSR0037 12 14 2 AR001053 0.001 0.039 b.d. 315
AGSR0037 14 16 2 AR001054 0.021 0.411 10 260
AGSR0037 16 18 2 AR001055 0.038 0.465 10 150
AGSR0037 18 20 2 AR001056 0.024 0.494 10 90
AGSR0037 20 22 2 AR001057 0.015 0.43 10 40
AGSR0037 22 24 2 AR001058 0.017 0.626 10 110
AGSR0037 24 26 2 AR001059 0.018 0.504 10 40
AGSR0037 26 28 2 AR001060 0.014 0.325 10 100
AGSR0037 28 30 2 AR001061 0.015 0.222 b.d. 85
AGSR0037 30 32 2 AR001063 0.016 0.253 10 140
AGSR0037 32 34 2 AR001064 0.016 0.149 10 90
AGSR0037 34 36 2 AR001065 0.018 0.232 b.d. 185
AGSR0037 36 38 2 AR001066 0.042 0.492 20 5860
AGSR0037 38 39 1 AR001067 0.02 0.343 10 6890
AGSR0038 0 2 2 AR001068 0.004 0.046 b.d. 540
AGSR0038 2 4 2 AR001069 0.003 0.044 10 810
AGSR0038 4 6 2 AR001070 0.001 0.018 10 695
AGSR0038 6 8 2 AR001071 b.d. 0.007 10 380
AGSR0038 8 10 2 AR001073 b.d. 0.006 b.d. 250
AGSR0038 10 12 2 AR001074 b.d. 0.016 b.d. 480
AGSR0038 12 14 2 AR001075 0.044 0.254 30 8430
AGSR0038 14 16 2 AR001076 0.046 0.662 50 16100
AGSR0038 16 18 2 AR001077 0.026 0.904 70 12500
AGSR0038 18 20 2 AR001078 0.037 0.98 50 9640
AGSR0038 20 22 2 AR001079 0.051 1.23 50 9520
AGSR0038 22 24 2 AR001080 0.039 0.81 20 6030
AGSR0038 24 26 2 AR001081 0.03 0.645 10 4300
AGSR0038 26 28 2 AR001083 0.023 0.446 10 2780
AGSR0038 28 30 2 AR001084 0.026 0.42 10 2490
AGSR0038 30 32 2 AR001085 0.028 0.304 b.d. 1190
AGSR0038 32 34 2 AR001086 0.014 0.243 b.d. 1170
AGSR0038 34 36 2 AR001087 0.014 0.272 b.d. 1490
AGSR0039 0 2 2 AR001088 0.003 0.031 b.d. 415
AGSR0039 2 4 2 AR001089 0.003 0.036 10 615
AGSR0039 4 6 2 AR001090 0.001 0.012 10 710
AGSR0039 6 8 2 AR001091 0.003 0.03 10 710
AGSR0039 8 10 2 AR001093 0.004 0.046 b.d. 790
AGSR0039 10 12 2 AR001094 0.004 0.041 10 535
AGSR0039 12 14 2 AR001095 0.006 0.041 b.d. 295
AGSR0039 14 16 2 AR001096 0.005 0.052 b.d. 585
AGSR0039 16 18 2 AR001097 0.004 0.056 b.d. 345
AGSR0039 18 20 2 AR001098 0.002 0.023 b.d. 145
AGSR0039 20 22 2 AR001099 b.d. 0.011 b.d. 120
AGSR0039 22 24 2 AR001100 0.001 0.01 b.d. 175
AGSR0039 24 26 2 AR001101 0.003 0.038 b.d. 245
AGSR0039 26 28 2 AR001103 0.002 0.026 b.d. 610
AGSR0039 28 30 2 AR001104 0.003 0.016 b.d. 815
AGSR0039 30 32 2 AR001105 0.012 0.238 30 13500
AGSR0039 32 34 2 AR001106 0.012 0.411 40 15700
AGSR0039 34 36 2 AR001107 0.014 0.682 100 21300
AGSR0039 36 38 2 AR001108 0.052 1.26 60 12300
AGSR0039 38 40 2 AR001109 0.059 0.978 40 13400
AGSR0039 40 42 2 AR001110 0.043 0.695 30 9560
AGSR0039 42 44 2 AR001111 0.058 0.79 30 8520
AGSR0039 44 46 2 AR001113 0.028 0.692 20 6680
Hole From (m)
To (m)
Width (m)
Sample number
Co (%)
Ni (%)
Sc (g/t)
Cr (ppm)
AGSR0039 46 48 2 AR001114 0.025 0.679 20 7040
AGSR0039 48 50 2 AR001115 0.025 0.618 20 6640
AGSR0039 50 52 2 AR001116 0.034 0.463 10 4330
AGSR0039 52 54 2 AR001117 0.042 0.467 10 4300
AGSR0039 54 56 2 AR001118 0.021 0.344 10 3700
AGSR0039 56 58 2 AR001119 0.017 0.256 b.d. 2120
AGSR0039 58 60 2 AR001120 0.018 0.299 b.d. 2890
AGSR0039 60 62 2 AR001121 0.016 0.259 b.d. 2690
AGSR0039 62 63 1 AR001123 0.016 0.263 b.d. 2230
AGSR0040 0 2 2 AR001124 0.003 0.057 b.d. 895
AGSR0040 2 4 2 AR001125 0.002 0.02 10 440
AGSR0040 4 6 2 AR001126 0.001 0.021 10 660
AGSR0040 6 8 2 AR001127 b.d. 0.014 10 280
AGSR0040 8 10 2 AR001128 b.d. 0.012 b.d. 310
AGSR0040 10 12 2 AR001129 b.d. 0.006 10 650
AGSR0040 12 14 2 AR001130 b.d. 0.005 10 220
AGSR0040 14 16 2 AR001131 b.d. 0.006 b.d. 315
AGSR0040 16 18 2 AR001133 0.004 0.01 b.d. 200
AGSR0040 18 20 2 AR001134 0.004 0.012 b.d. 325
AGSR0040 20 22 2 AR001135 0.006 0.024 b.d. 580
AGSR0040 22 24 2 AR001136 0.017 0.119 b.d. 2900
AGSR0040 24 26 2 AR001137 0.019 0.217 10 3300
AGSR0040 26 28 2 AR001138 0.014 0.274 10 4500
AGSR0040 28 30 2 AR001139 0.009 0.158 b.d. 1350
AGSR0040 30 32 2 AR001140 0.009 0.147 b.d. 1500
AGSR0040 32 34 2 AR001141 0.01 0.172 b.d. 1860
AGSR0040 34 36 2 AR001143 0.008 0.152 b.d. 2510
AGSR0041 0 2 2 AR001144 0.002 0.036 b.d. 615
AGSR0041 2 4 2 AR001145 0.001 0.025 10 575
AGSR0041 4 6 2 AR001146 0.001 0.018 10 670
AGSR0041 6 8 2 AR001147 b.d. 0.005 b.d. 575
AGSR0041 8 10 2 AR001148 b.d. 0.011 10 270
AGSR0041 10 12 2 AR001149 0.001 0.01 b.d. 300
AGSR0041 12 14 2 AR001150 0.008 0.032 b.d. 1180
AGSR0041 14 16 2 AR001151 0.02 0.118 10 2010
AGSR0041 16 18 2 AR001153 0.023 0.268 10 3230
AGSR0041 18 20 2 AR001154 0.038 0.586 30 4780
AGSR0041 20 22 2 AR001155 0.051 0.99 30 6340
AGSR0041 22 24 2 AR001156 0.051 1.11 20 6600
AGSR0041 24 26 2 AR001157 0.048 1.03 30 6980
AGSR0041 26 28 2 AR001158 0.025 0.703 20 2490
AGSR0041 28 30 2 AR001159 0.035 0.778 10 4250
AGSR0041 30 32 2 AR001160 0.009 0.275 b.d. 1090
AGSR0041 32 34 2 AR001161 0.01 0.302 10 1560
AGSR0041 34 36 2 AR001163 0.01 0.268 10 1120
AGSR0041 36 38 2 AR001164 0.007 0.16 b.d. 825
AGSR0041 38 39 1 AR001165 0.005 0.099 10 420
AGSR0042 0 2 2 AR001166 0.002 0.017 b.d. 315
AGSR0042 2 4 2 AR001167 0.002 0.033 10 755
AGSR0042 4 6 2 AR001168 0.001 0.01 10 490
AGSR0042 6 8 2 AR001169 0.001 0.009 10 520
AGSR0042 8 10 2 AR001170 0.002 0.026 b.d. 1440
AGSR0042 10 12 2 AR001171 0.02 0.092 b.d. 950
AGSR0042 12 14 2 AR001173 0.024 0.467 10 2560
AGSR0042 14 16 2 AR001174 0.014 0.25 b.d. 980
AGSR0042 16 18 2 AR001175 0.008 0.209 b.d. 890
AGSR0042 18 20 2 AR001176 0.008 0.147 10 630
AGSR0042 20 22 2 AR001177 0.01 0.2 10 830
AGSR0042 22 24 2 AR001178 0.013 0.264 10 1150
AGSR0042 24 26 2 AR001179 0.042 0.689 10 3890
AGSR0042 26 28 2 AR001180 0.021 0.269 10 1440
AGSR0042 28 30 2 AR001181 0.019 0.293 10 2190
AGSR0042 30 32 2 AR001183 0.019 0.28 10 2000
AGSR0042 32 34 2 AR001184 0.017 0.245 b.d. 1340
AGSR0042 34 36 2 AR001185 0.017 0.298 b.d. 1960
AGSR0042 36 38 2 AR001186 0.016 0.218 b.d. 620
AGSR0043 0 2 2 AR001187 0.006 0.048 10 445
AGSR0043 2 4 2 AR001188 0.002 0.018 10 580
AGSR0043 4 6 2 AR001189 0.002 0.015 10 570
AGSR0043 6 8 2 AR001190 0.001 0.005 10 290
AGSR0043 8 10 2 AR001191 0.003 0.032 b.d. 745
AGSR0043 10 12 2 AR001193 0.003 0.042 b.d. 790
AGSR0043 12 14 2 AR001194 0.022 0.091 b.d. 1630
AGSR0043 14 16 2 AR001195 0.021 0.118 b.d. 1300
AGSR0043 16 18 2 AR001196 0.029 0.214 b.d. 750
AGSR0043 18 20 2 AR001197 0.019 0.19 b.d. 470
AGSR0043 20 22 2 AR001198 0.014 0.176 b.d. 510
AGSR0043 22 24 2 AR001199 0.018 0.201 b.d. 660
AGSR0043 24 26 2 AR001200 0.022 0.232 b.d. 560
AGSR0043 26 28 2 AR001201 0.02 0.29 b.d. 1290
AGSR0043 28 30 2 AR001203 0.016 0.316 b.d. 1990
17
Appendix 3 – Collated intercepts, Goongarrie South
Parameters used to define nickel, cobalt, and scandium intercepts at Goongarrie South
Parameter Nickel Cobalt Scandium
Minimum cut-off 0.50 % Ni 0.10 % Co 50 g/t Sc
Minimum intercept thickness 2 m 2 m 2 m
Maximum internal waste thickness 4 m 4 m 4 m
Nickel, cobalt, and scandium intercepts from new drilling at Goongarrie South
All newly defined cobalt intercepts at Goongarrie South (calculated both from new data and historic data) were calculated using the following parameters:
• Intercepts based on nickel distributions were first calculated using 0.50 % nickel minimum cut-off, 2 m minimum intercept, and 4 m internal waste. Such parameters define broad intercepts that may be cobalt bearing or cobalt poor. Intercepts are considered of interest where cobalt values exceed 0.08%.
• Intercepts based on cobalt distributions are then calculated using a 0.10 % cobalt minimum cut-off, 2 m minimum intercept, and 4 m internal waste. All significant cobalt intercepts are hosted within the broader nickel-based intercepts and tend to define higher-grade, shorter intercepts.
• Where core loss was an issue, and where the thickness of core loss was less than the internal waste thickness, grades in zones of core loss were taken as the weighted average of the intervals immediately above and below the core loss interval in question. This provides grade distributions downhole that are consistent with mineralised zones, where cobalt and nickel grades are observed to change gradually rather than randomly downhole. By defining zones of core loss as being of a value between the interval above and the interval below, a similarly smooth transition in grades downhole is achieved. This method of estimated grade in zones of core loss is therefore considered the most suitable means of defining grade in such zones at Goongarrie South.
• Where an interval of core loss, through calculation, marked the beginning or end of a mineralised interval, this core loss interval was not included in that mineralisation interval.
Scandium intercepts were defined by using a 50g/t scandium minimum cut-off, a 2 m minimum intercept, and a 4 m internal waste. Scandium intercept distributions do not show a consistent relationship to cobalt and nickel mineralisation and are usually in the shallow subsurface.
Pamela West deposit10
6669840 mN section
AGSR0003 2 m at 50 g/t scandium from 6.3 m11
and 12 m at 0.027 % cobalt and 0.85 % nickel from 18.3 m12
including 2 m at 50 g/t scandium and 1.06 % nickel from 20.3 m11
AGSR0002 22 m at 0.068 % cobalt and 1.037 % nickel from 8 m12
including 2 m at 0.201 % cobalt and 0.895 % nickel from 10 m13
and 4 m at 50 g/t scandium, 0.053 % cobalt, and 1.07 % nickel from 14 m11
AGSR0001 24 m at 0.071 % cobalt and 0.616 % nickel from 8.3 m12
including 4 m at 0.209 % cobalt and 0.85 % nickel from 14.3 m13
6669760 mN section
AGSR0005 32 m at 0.09 % cobalt and 1.06 % nickel from 16 m12
including 14 m at 0.146 % cobalt and 1.457 % nickel from 22 m13
AGSR0004 4 m at 50 g/t scandium from 4 m11
10 Drillholes for the Pamela West deposit are listed first by section (north to south), then by hole west to east 11 Scandium-defined intercept (see top p.17) 12 Nickel-defined intercept (see top p.17) 13 Cobalt-defined intercept (see top p.17)
18
Elsie South deposit14
6668000 mN section
AGSR0042 2 m at 0.042 % cobalt and 0.689 % nickel from 24 m12
AGSR0041 12 m at 0.041 % cobalt and 0.866 % nickel from 18 m12
6667920 mN section
AGSR0036 4 m at 0.034 % cobalt and 0.64 % nickel from 16 m12
AGSR0037 4 m at 0.017 % cobalt and 0.565 % nickel from 22 m12
AGSR0038 12 m at 0.038 % cobalt and 0.872 % nickel from 14 m12
including 8 m at 55 g/t scandium and 0.944 % nickel from 14 m11
AGSR0039 16 m at 0.038 % cobalt and 0.799 % nickel from 34 m12
including 4 m at 80 g/t scandium and 0.971 % nickel from 34 m11
6667840 mN section
AGSR0027 4 m at 0.081 % cobalt and 0.556 % nickel from 38 m12
including 4 m at 0.081 % cobalt and 0.556 % nickel from 38 m13
AGSR0029 14 m at 0.066 % cobalt and 0.7 % nickel from 26 m12
AGSR0030 8 m at 0.049 % cobalt and 0.805 % nickel from 36 m12
AGSR0032 20 m at 0.027 % cobalt and 0.597 % nickel from 14 m12
and 2 m at 0.025 % cobalt and 0.51 % nickel from 44 m12
AGSR0033 4 m at 0.037 % cobalt and 0.644 % nickel from 18 m12
AGSR0034 4 m at 0.027 % cobalt and 0.728 % nickel from 14 m12
and 2 m at 0.017 % cobalt and 0.506 % nickel from 34 m12
AGSR0035 6 m at 60 g/t scandium from 12 m11
and 18 m at 0.046 % cobalt and 0.971 % nickel from 18 m12
including 2 m at 0.094 % cobalt and 1.52 % nickel from 24 m13
6667760 mN section
AGSR0022 14 m at 0.062 % cobalt and 0.754 % nickel from 28 m12
including 4 m at 0.105 % cobalt and 0.791 % nickel from 38 m13
AGSR0023 4 m at 0.05 % cobalt and 0.726 % nickel from 14 m12
AGSR0025 14 m at 54 g/t scandium from 10 m11
21 m at 0.031 % cobalt and 0.829 % nickel from 20 m12
AGSR0026 26 m at 0.06 % cobalt and 0.991 % nickel from 10 m12
including 8 m at 0.102 % cobalt and 1.283 % nickel from 22 m13
14 Drillholes for the Elsie South deposit are listed first by section (north to south), then by hole west to east
19
6667680 mN section
AGSR0011 16 m at 0.047 % cobalt and 0.62 % nickel from 40 m12
including 4 m at 50 g/t scandium, 0.056 % cobalt, and 0.714 % nickel from 40 m11
and 2 m at 0.113 % cobalt and 0.697 % nickel from 44 m13
AGSR0010 40 m at 0.032 % cobalt and 0.852 % nickel from 28 m12
including 14 m at 51 g/t scandium, 0.025 % cobalt, and 1.166 % nickel from 30 m11
AGSR0009 12 m at 55 g/t scandium, 0.034 % cobalt, and 1.054 % nickel from 10 m11
and 56 m at 0.066 % cobalt and 1.085 % nickel from 12 m12
including 16 m at 0.111 % cobalt and 1.202 % nickel from 30 m13
and 2 m at 50 g/t scandium, 0.104 % cobalt, and 1.50 % nickel from 32 m11
AGSR0008 6 m at 0.028 % cobalt and 0.556 % nickel from 22 m12
and 4 m at 0.047 % cobalt and 0.641 % nickel from 34 m12
AGSR0007 6 m at 0.029 % cobalt and 0.613 % nickel from 12 m12
including 2 m at 60 g/t scandium, 0.026 % cobalt, and 0.672 % nickel from 12 m11
and 2 m at 0.03 % cobalt and 0.571 % nickel from 44 m12
AGSR0006 28 m at 0.037 % cobalt and 0.809 % nickel from 10 m12
including 2 m at 60 g/t scandium, 0.035 % cobalt, and 0.679 % nickel from 10 m11
6667600 mN section
AGSR0012 2 m at 50 g/t scandium from 42 m11
AGSR0015 32 m at 0.083 % cobalt and 0.872 % nickel from 32 m12
including 24 m at 0.098 % cobalt and 0.986 % nickel from 36 m13
AGSR0016 20 m at 50 g/t scandium, 0.029 % cobalt, and 0.671 % nickel from 10 m11
and 24 m at 0.032 % cobalt and 0.724 % nickel from 14 m12
AGSR0017 22 m at 0.056 % cobalt and 0.715 % nickel from 14 m12
including 4 m at 50 g/t scandium, 0.043 % cobalt, and 0.634 % nickel from 14 m11
and 2 m at 50 g/t scandium, 0.034 % cobalt, and 0.907 % nickel from 24 m11
and 4 m at 0.119 % cobalt and 0.889 % nickel from 28 m13
AGSR0018 4 m at 0.044 % cobalt and 0.551 % nickel from 18 m12
6667520 mN section
AGSR0020 4 m at 50 g/t scandium from 12 m11
and 2 m at 0.042 % cobalt and 0.57 % nickel from 14 m12
and 14 m at 0.021 % cobalt and 0.621 % nickel from 28 m12
AGSR0019 10 m at 0.035 % cobalt and 0.408 % nickel from 18 m12
20
Appendix 4 – JORC Code, 2012 Edition, Table 1 report
Section 1 Sampling Techniques and Data
(Criteria in this section applies to all succeeding sections)
Criteria JORC Code explanation Commentary
Sampling techniques
Note: Due to the
similarity of the deposit
styles, procedures and
estimations used this
table represents the
combined methods for
all Ardea Resources
(ARL) Cobalt and
Nickel Laterite
Resources. Where data
not collected by ARL
has been used in the
resource calculations,
variances in techniques
are noted.
• Nature and quality of sampling (e.g. cut channels, random chips, or specific specialised industry standard measurement tools appropriate to the minerals under investigation, such as down hole gamma sondes, or handheld XRF instruments, etc). These examples should not be taken as limiting the broad meaning of sampling.
• Include reference to measures taken to ensure sample representivity and the appropriate calibration of any measurement tools or systems used.
• Aspects of the determination of mineralisation that are Material to the Public Report.
• In cases where ‘industry standard’ work has been done this would be relatively simple (e.g. ‘reverse circulation drilling was used to obtain 1 m samples from which 3 kg was pulverised to produce a 30 g charge for fire assay’). In other cases, more explanation may be required, such as where there is coarse gold that has inherent sampling problems. Unusual commodities or mineralisation types (e.g. submarine nodules) may warrant disclosure of detailed information.
• All holes were sampled “in-principle” on a 2 metre down hole interval basis, with exceptions being made due to visual geological/mineralogical breaks, and end of hole final-lengths. All sampling lengths were recorded in ARL’s standard core-sampling record spreadsheets. Sample condition, sample recovery and sample size were recorded for all drill-core samples collected by ARL.
• The drill spacing was designed to augment historic drilling, bringing drill densities down from 80mE x 80mN to 40mE x 80mN. The drilling will also contribute to provide material for the purpose of metallurgical sampling and production of production of pilot marketing samples of cobalt sulphate and nickel sulphate.
• Industry standard practice was used in the processing of samples for assay, with 2m intervals of RC chips collected in green plastic bags. As the drilling was within a 2012 JORC-compliant Indicated Ni-Co resource, prior knowledge of the resource peculiarities contributes and assists significantly to current interpretation of mineralisation.
• Assay of samples utilised standard laboratory techniques with standard ICP-AES undertaken on 50 gram samples for Au, Pt and Pd, and lithium borate fused-bead XRF analysis used for the remaining multi-element suite. Further details of lab processing techniques are found in Quality of assay data and laboratory tests below.
Drilling techniques • Drill type (e.g. core, reverse circulation, open-hole hammer, rotary air blast, auger, Bangka, sonic, etc) and details (e.g. core diameter, triple or standard tube, depth of diamond tails, face-sampling bit or other type, whether core is oriented and if so, by what method, etc).
• In this most recent program, Ardea drilled the Goongarrie South deposit with 43 diamond drill holes on a varying MGA94 z51 northing grid-spacing of 80m at several localities (see Figure 2). Holes were vertical (-90 degree dip), designed to optimally intersect the sub-horizontal mineralisation. RC drilling was performed with a face sampling hammer (bit diameter between 4½ and 5 ¼ inches) and samples were collected by either a cone (majority) or riffle splitter using 2 metre composites. Sample condition, sample recovery and sample size were recorded for all drill samples collected by ARL.
Drill sample recovery • Method of recording and assessing core and chip sample recoveries and results assessed.
• Measures taken to maximise sample recovery and ensure representative nature of the samples.
• Whether a relationship exists between sample recovery and grade and whether sample bias may have occurred due to preferential loss/gain of fine/coarse material.
• RC chip sample recovery was recorded by visual estimation of the reject sample, expressed as a percentage recovery. Overall estimated recovery was approximately 80%, which is considered to be acceptable for nickel-cobalt laterite deposits. RC Chip sample condition recorded using a three code system, D=Dry, M=Moist, W=Wet. A small proportion of samples were moist or wet (11.5%), with the majority of these being associated with soft goethite clays, where water injection has been used to improve drill recovery.
• Measures taken to ensure maximum RC sample recoveries included maintaining a clean cyclone and drilling equipment, using water injection at times of reduced air circulation, as well as regular communication with the drillers and slowing drill advance rates when variable to poor ground conditions are encountered.
Logging • Whether core and chip samples have been geologically and geotechnically logged to a level of detail to support appropriate Mineral Resource estimation, mining studies and metallurgical studies.
• Whether logging is qualitative or quantitative in nature. Core (or costean, channel, etc) photography.
• The total length and percentage of the relevant intersections logged.
• Drilling was undertaken for metallurgical purposes, and twinning comparison with previous historic RC holes. The level of logging detail utilised supports this type of review and was as follows: Visual geological logging was completed for all drilling both at the time of drilling (using standard Ardea laterite logging codes), and later over relevant met-sample intervals with a metallurgical-logging perspective. Geochemistry from historic data was used together with logging data to validate logged geological horizons. Nickel laterite profiles contain geochemically very distinct horizons and represent a sound validation tool against visual logging. The major part of the logging system was developed by Heron Resources Limited specifically for the KNP and was designed to facilitate future geo-metallurgical studies. It has been customised by Ardea Resources Limited as considered appropriate for recent developments. Planned drill hole target lengths were adjusted by the geologist during drilling. The geologist also oversaw all sampling and drilling practices. A mixture of ARL employees and contract geologists supervised all drilling. Quarter core of all drilling has been retained for reference.
• Visual geological logging was completed for all RC drilling on 1 metre intervals. The logging system was developed by Heron Resources Limited specifically for the KNP and was designed to facilitate future geo-metallurgical studies. Logging was performed at the time of drilling, and planned drill hole target lengths adjusted by the geologist during drilling. The geologist also oversaw all sampling and drilling practices. A mixture of ARL employees and contract geologists supervised all drilling.
21
Criteria JORC Code explanation Commentary
A small selection of representative chips were also collected for every 1 metre interval and stored in chip-trays for future reference. Only drilling contractors with previous nickel laterite experience and suitable rigs were used.
• The geological legend used by ARL is a qualitative legend designed to capture the key physical and metallurgical features of the nickel-cobalt laterite mineralisation. Logging captured the colour, regolith unit and mineralisation style, often accompanied by the logging of protolith, estimated percentage of free silica, texture, grain size and alteration. Logging correlated well with the geochemical algorithm developed by Heron Resources Limited for the Yerilla Nickel Project for material type prediction from multi-element assay data.
•
Sub-sampling
techniques and sample
preparation
• If core, whether cut or sawn and whether quarter, half or all core taken.
• If non-core, whether riffled, tube sampled, rotary split, etc and whether sampled wet or dry.
• For all sample types, the nature, quality and appropriateness of the sample preparation technique.
• Quality control procedures adopted for all sub-sampling stages to maximise representivity of samples.
• Measures taken to ensure that the sampling is representative of the in situ material collected, including for instance results for field duplicate/second-half sampling.
• Whether sample sizes are appropriate to the grain size of the material being sampled.
• 2 metre (and rarely 1 metre) composite samples were recovered using a 15:1 rig mounted cone splitter or trailer mounted riffle splitter during drilling into a calico sample bag. Sample target weight was between 2 and 3kg. In the case of wet clay samples, grab samples taken from sample return pile, initially into a calico sample bag. Wet samples stored separately from other samples in plastic bags and riffle split once dry.
• QAQC was employed. A standard, blank or duplicate sample was inserted into the sample stream 10 metres on a rotating basis. Standards were either quantified industry standards, or standards made from homogenised bulk samples of the mineralisation being drilled (in the case of the Yerilla project). Every 30th sample a duplicate sample was taken using the same sample sub sample technique as the original sub sample. Sample sizes are appropriate for the nature of mineralisation.
Quality of assay data
and laboratory tests
• The nature, quality and appropriateness of the assaying and laboratory procedures used and whether the technique is considered partial or total.
• For geophysical tools, spectrometers, handheld XRF instruments, etc, the parameters used in determining the analysis including instrument make and model, reading times, calibrations factors applied and their derivation, etc.
• Nature of quality control procedures adopted (e.g. standards, blanks, duplicates, external laboratory checks) and whether acceptable levels of accuracy (i.e. lack of bias) and precision have been established.
• All Ardea samples were submitted to Kalgoorlie ALS laboratories and transported to ALS Perth, where they were pulverised. Analysis at ALS Perth was by ICP utilising a 50g charge (lab method PGM-ICP24) for PGM suite elements (Au, Pt, Pd). Additional analysis was undertaken by sending subsamples to ALS Brisbane where analysis by silicate fusion / XRF analysis (lab method ME-XRF12n) for multiple grade attributes for laterite ores (Al2O3, As, BaO, CaO, Cl, Co, Cr2O3, Cu, Fe2O3, Ga, K2O, MgO, MnO, Na2O, Ni, P2O5, Pb, Sc, SiO2, SO3, SrO, TiO2, V2O5, Zn, ZrO2). Fusion / XRF analysis is an industry standard method used to analyse nickel laterite ores and ALS is a reputable commercial laboratory with extensive experience in assaying nickel laterite samples from numerous Western Australian nickel laterite deposits.
• ALS routinely inserts analytical blanks, standards and duplicates into the client sample batches for laboratory QAQC performance monitoring.
• Ardea also inserted QAQC samples into the sample stream at a 1 in 10 frequency, alternating between blanks (industrial sands) and standard reference materials. Additionally, a review was conducted for geochemical consistency between historically expected data, recent data, and geochemical values that would be expected in a nickel laterite profile.
• All of the QAQC data has been statistically assessed. There were rare but explainable inconsistencies in the returning results from standards submitted, and it has been determined that levels of accuracy and precision relating to the samples are acceptable.
Verification of sampling
and assaying
• The verification of significant intersections by either independent or alternative company personnel.
• The use of twinned holes.
• Documentation of primary data, data entry procedures, data verification, data storage (physical and electronic) protocols.
• Discuss any adjustment to assay data.
• All Ardea samples were submitted to Kalgoorlie ALS laboratories and transported to ALS Perth, where they were pulverised. Analysis at ALS Perth was by ICP utilising a 50g charge (lab method PGM-ICP24) for PGM suite elements (Au, Pt, Pd). Additional analysis was undertaken by sending subsamples to ALS Brisbane where analysis by silicate fusion / XRF analysis (lab method ME-XRF12n) for multiple grade attributes for laterite ores (Al2O3, As, BaO, CaO, Cl, Co, Cr2O3, Cu, Fe2O3, Ga, K2O, MgO, MnO, Na2O, Ni, P2O5, Pb, Sc, SiO2, SO3, SrO, TiO2, V2O5, Zn, ZrO2). Fusion / XRF analysis is an industry standard method used to analyse nickel laterite ores and ALS is a reputable commercial laboratory with extensive experience in assaying nickel laterite samples from numerous Western Australian nickel laterite deposits.
• ALS routinely inserts analytical blanks, standards and duplicates into the client sample batches for laboratory QAQC performance monitoring.
• Ardea also inserted QAQC samples into the sample stream at a 1 in 20 frequency, alternating between duplicates splits, blanks (industrial sands) and standard reference materials.
• Additionally, a review was conducted for geochemical consistency between historically expected data, recent data, and geochemical values that would be expected in a nickel laterite profile.
• All of the QAQC data has been statistically assessed. There were some inconsistencies in the returning results from standards submitted, relating to the XRF analysis suite. This has been thoroughly investigated with the conclusion that either some standards were not correctly identified and recorded on submission, or time/external influence has had an impact on some of the quality of the values
22
Criteria JORC Code explanation Commentary
standards, as figures reported for the relevant errant standards were significantly different to the normal recognisable standard values. Ardea has undertaken its own further in-house review of QAQC results of the ALS routine standards, 100% of which returned within acceptable QAQC limits. This fact combined with the fact that the data is demonstrably consistent and repeated for expected Ni/Co values within the lateritic ore profiles of both reported areas and is also consistent with nearby abundant historic drilling data, has meant that the results are considered to be acceptable and suitable for reporting.
Location of data points • Accuracy and quality of surveys used to locate drill holes (collar and down-hole surveys), trenches, mine workings and other locations used in Mineral Resource estimation.
• Specification of the grid system used.
• Quality and adequacy of topographic control.
• All drill holes are to be surveyed using an RTK DGPS system with either a 3 or 7 digit accuracy. The coordinates are stored in the exploration database referenced to the MGA Zone 51 Datum GDA94.
• All holes drilled as part of the Goongarrie South program were vertical. No holes were down-hole surveyed except at EOH. The sub-horizontal orientation of the mineralisation, combined with the soft nature of host material resulted in minimal deviation of vertical diamond drill holes.
• The grid system for all models is GDA94. Where historic data or mine grid data has been used it has been transformed into GDA94 from its original source grid via the appropriate transformation. Both original and transformed data is stored in the digital database.
• A DGPS pickup up of drill collar locations is considered sufficiently accurate for reporting of resources, but is not suitable for mine planning and reserves.
Data spacing and
distribution
• Data spacing for reporting of Exploration Results.
• Whether the data spacing and distribution is sufficient to establish the degree of geological and grade continuity appropriate for the Mineral Resource and Ore Reserve estimation procedure(s) and classifications applied.
• Whether sample compositing has been applied.
• The drill spacing was designed to augment historic drilling, bringing drill densities down from 80mE x 80mN to 40mE x 80mN. The program to date is part of a broader program. All proposed drilling has been completed at Elsie South only. Drilling continues at all other deposits.
• Given the homogeneity of this style of orebody, the spacing is, for bulk-scale metallurgical work and probable mining techniques, considered sufficient.
• Sample compositing has not been applied to the newly collected data.
Orientation of data in
relation to geological
structure
• Whether the orientation of sampling achieves unbiased sampling of possible structures and the extent to which this is known, considering the deposit type.
• If the relationship between the drilling orientation and the orientation of key mineralised structures is considered to have introduced a sampling bias, this should be assessed and reported if material.
• All drill holes in this program were vertical and give a true width of the regolith layers and mineralisation within the modelled resource.
• On a local scale, there is some geological variability in the northern most drill line (6669600mN) due to a probable shear structure. However, this local variability is not considered to be significant for the project overall, but will have local effects on mining and scheduling later in the project life. As the detailed shape of the orebody has already been well defined by an abundance of nearby resource drill holes (including the northern section) it is no bias is expected to be introduced from data pertaining to these drill holes with reference to mineralised structures.
Sample security • The measures taken to ensure sample security.
• All samples were collected and accounted for by ARL employees/consultants during drilling. All samples were bagged into calico plastic bags and closed with cable ties. Samples were transported to Kalgoorlie from logging site by ARL employees/ consultants and submitted directly to ALS Kalgoorlie.
• The appropriate manifest of sample numbers and a sample submission form containing laboratory instructions were submitted to the laboratory. Any discrepancies between sample submissions and samples received were routinely followed up and accounted for.
Audits or reviews • The results of any audits or reviews of sampling techniques and data.
• ARL has periodically conducted internal reviews of sampling techniques relating to resultant exploration datasets, and larger scale reviews capturing the data from multiple drilling programmes within the KNP.
• Internal reviews of the exploration data included the following:
• Unsurveyed drill hole collars (less than 1% of collars).
• Drill Holes with overlapping intervals (0%).
• Drill Holes with no logging data (less than 2% of holes).
• Sample logging intervals beyond end of hole depths (0%).
• Samples with no assay data (from 0 to <5% for any given project, usually
• related to issues with sample recovery from difficult ground conditions,
• mechanical issues with drill rig, damage to sample in transport or sample preparation).
• Assay grade ranges.
• Collar coordinate ranges
• Valid hole orientation data.
• The ALS Laboratory was visited by ARL staff in 2016, and the laboratory processes and procedures were reviewed at this time and determined to be robust.
23
Section 2 - Reporting of Exploration Results
(Criteria listed in the preceding section also apply to this section.)
Criteria JORC Code explanation Commentary
Mineral tenement and
land tenure status
• Type, reference name/number, location and ownership including agreements or material issues with third parties such as joint ventures, partnerships, overriding royalties, native title interests, historical sites, wilderness or national park and environmental settings.
• The security of the tenure held at the time of reporting along with any known impediments to obtaining a licence to operate in the area.
• The tenement on which the Goongarrie South drilling was undertaken is M29/272.
• The tenement and land tenure status for the KNP prospect areas containing continuous cobalt rich laterite mineralisation is summarised in Table 3 following and in the Ardea Prospectus, section 9 “Solicitor’s Report on Tenements”.
Exploration done by
other parties
• Acknowledgment and appraisal of exploration by other parties.
• The Goongarrie South deposit was initially discovered by Heron Resources Ltd and subsequently drilled by Vale Inco Limited in a Joint Venture. Much historic assessment of the Black Range Project was undertaken by Heron Resources Limited.
Geology • Deposit type, geological setting and style of mineralisation.
• The KNP nickel-cobalt laterite mineralisation developed during the weathering and near surface enrichment of Archaean-aged olivine-cumulate ultramafic units. The mineralisation is usually within 60 metres of surface and can be further subdivided on mineralogical and metallurgical characteristics into upper iron-rich material and lower magnesium-rich material based on the ratios of iron to magnesium. The deposits are analogous to many weathered ultramafic-hosted nickel-cobalt deposits both within Australia and world-wide.
• Cobalt-rich mineralisation is typically best developed in iron-rich material in regions of deep weathering in close proximity to major shear zones or transfer shear structures and to a lesser extent as thin zones along the interface of ferruginous and saprolite boundaries at shallower depths proximal to shear structures.
• The Cobalt Zone is associated with a distinctive geo-metallurgical type defined as “Clay Upper Pyrolusitic”. Mineralogy is goethite, gibbsite and pyrolusite (strictly “asbolite” or “cobaltian wad”). The Cobalt Zones typically occur as sub-horizontal bodies at a palaeo-water table within the KNP (late stage supergene enrichment). This material is particularly well developed at Goongarrie South.
Drill hole Information • A summary of all information material to the understanding of the exploration results including a tabulation of the following information for all Material drill holes:
• easting and northing of the drill hole collar
• elevation or RL (Reduced Level – elevation
above sea level in metres) of the drill hole collar
• dip and azimuth of the hole
• down hole length and interception depth
• hole length.
• All holes drilled in this most recent program are listed in “Appendix 1 – Collar location data”.
Drill hole Information • If the exclusion of this information is justified on the basis that the information is not Material and this exclusion does not detract from the understanding of the report, the Competent Person should clearly explain why this is the case.
• All assay data relating to the metals of interest at Goongarrie South, namely cobalt, nickel, scandium, and chromium, are listed in “Appendix 2 – Assay results”. Other elements were assayed but have not been reported here. They are of use and of interest from a scientific and metallurgical perspective, but are not considered material and their exclusion does not detract from the understanding of this report.
Data aggregation
methods
• In reporting Exploration Results, weighting averaging techniques, maximum and/or minimum grade truncations (e.g. cutting of high grades) and cut-off grades are usually Material and should be stated.
• Where aggregate intercepts incorporate short lengths of high grade results and longer lengths of low grade results, the procedure used for such aggregation should be stated and some typical examples of such aggregations should be shown in detail.
• The assumptions used for any reporting of metal equivalent values should be clearly stated.
• Most drill hole samples have been collected over 2m down hole intervals.
• All newly defined cobalt and nickel intercepts at Goongarrie South were calculated using the following parameters:
• Intercepts based on nickel distributions were first calculated using 0.50 % nickel minimum cut-off, 2 m minimum intercept, and 4 m internal waste. Such parameters define broad intercepts that may be cobalt bearing or cobalt poor. Intercepts are considered of interest where cobalt values exceed 0.08%.
• Intercepts based on cobalt distributions are then calculated using a 0.10 % cobalt minimum cut-off, 2 m minimum intercept, and 4 m internal waste. All significant cobalt intercepts are hosted within the broader nickel-based intercepts and tend to define higher-grade, shorter intercepts.
• Where core loss was an issue, and where the thickness of core loss was less than the internal waste thickness, grades in zones of core loss were taken as the weighted average of the intervals immediately above and below the core loss interval in question. This provides grade distributions downhole that are consistent with mineralised zones, where cobalt and nickel grades are observed to change gradually rather than randomly downhole. By defining zones of core loss as being of a value between the interval above and the interval below, a similarly smooth transition in grades downhole is achieved. This method of estimated grade in zones of core loss is therefore considered the most suitable means of defining grade in such zones at Goongarrie South.
• Where an interval of core loss, through calculation, marked the beginning or end of a mineralised interval, this core loss interval was not included in that mineralisation
24
Criteria JORC Code explanation Commentary
interval.
• Scandium intercepts were defined by using a 50g/t scandium minimum cut-off, a 2 m minimum intercept, and a 4 m internal waste. Scandium intercept distributions do not show a consistent relationship to cobalt and nickel mineralisation and are usually in the shallow subsurface.
• Assay compositing techniques were not used in this assessment.
• No metal equivalent calculations have been used in this assessment.
Relationship between
mineralisation widths
and intercept lengths
• These relationships are particularly important in the reporting of Exploration Results.
• If the geometry of the mineralisation with respect to the drill hole angle is known, its nature should be reported.
• If it is not known and only the down hole lengths are reported, there should be a clear statement to this effect (e.g. ‘down hole length, true width not known’).
• The nickel-cobalt laterite mineralisation at Goongarrie South has a strong global sub-horizontal orientation.
• All drill holes are vertical.
• All drill holes intersect the mineralisation at approximately 90°to its orientation
Diagrams • Appropriate maps and sections (with scales) and tabulations of intercepts should be included for any significant discovery being reported These should include, but not be limited to a plan view of drill hole collar locations and appropriate sectional views.
• Maps and sections of the cobalt and nickel mineralisation are shown within the report. Every drill hole on every section drilled is shown.
Balanced reporting • Where comprehensive reporting of all Exploration Results is not practicable, representative reporting of both low and high grades and/or widths should be practiced to avoid misleading reporting of Exploration Results.
• Not applicable to this report. All results are report either in the text or in the associated appendices. Examples of high-grade mineralisation are labelled as such.
Other substantive
exploration data
• Other exploration data, if meaningful and material, should be reported including (but not limited to): geological observations; geophysical survey results; geochemical survey results; bulk samples size and method of treatment; metallurgical test results; bulk density, groundwater, geotechnical and rock characteristics; potential deleterious or contaminating substances.
• No other data are, at this stage, known to be either beneficial or deleterious to recovery of the metals reported. Uncertainties surrounding the possibility of recovery of the metals of interest are noted prominently in the report.
Further work • The nature and scale of planned further work (e.g. tests for lateral extensions or depth extensions or large-scale step-out drilling).
• Diagrams clearly highlighting the areas of possible extensions, including the main geological interpretations and future drilling areas, provided this information is not commercially sensitive.
• Further drilling is likely to be undertaken at Goongarrie South but has not yet been defined. Further drilling could include infill drilling as well as extension of lines to the north and south as appropriate.
• Metallurgical assessment of all metals of interest at Goongarrie South will be undertaken during the Pre-Feasibility Study (PFS) which has commenced on the KNP Cobalt Zone.
Recommended