Upload
others
View
1
Download
0
Embed Size (px)
Citation preview
Kullinggade 31 · DK-5700 Svendborg · Denmark · Ph(1) +45 4059 1012 · Ph(2) +45 6168 1015
THE FEN CARBONATITE COMPLEX,
ULEFOSS, SOUTH NORWAY
Summary of historic work and data
Compiled and prepared by 21st NORTH, Svendborg 12 May 2011 in commission for REE Minerals, Norway
________________________ ________________________
Anders Lie M.Sc. Geology Claus Østergaard M.Sc. Geology
21st NORTH 21st NORTH
TABLE OF CONTENTS
1 PROJECT HIGHLIGTHS
2 REGIONAL SETTING
3 HISTORIC EXPLORATION AND MINING
3.1 The Fen iron mines 1657-1927
3.2 The Soeve niobium mines 1953-1965
3.3 Geophysical surveying and exploration for Th
and REE
3.4 Junior exploration activities 2000-
4 GEOLOGY
4.1 Introduction
4.2 Rocks of igneous origin
4.3 Metasomatic alteration and associated rocks
5 LICENSE AREA – REE MINERALS
6 RADIOMETRY
7 REE MINERALISATION IN THE FEN COMPLEX
7.1 Introduction
7.2 NGU works in the 1960s and 1970s
7.3 Results
8 EXPLORATION IN RECENT YEARS
9 SLAG DUMP AT SOEVE NIOBIUM MINE
10 REFERENCES
APPENDIX A-C
A Rock samples – NGU 1967-1970
B Drill hole data
C Radiometry and rock sample anomaly maps
Page 2 of 47
1. Project highlights
� 9km2 world famous carbonatite complex sited at excellent position in south Norway
� Previously mined for iron from 1657-1927 [c. 1 Mt) and for niobium from 1953 to 1965
� Limited knowledge on full REE composition – The majority of historic drill and surface rock data were only
assayed for La, Sm, Eu, Yb and Y. A limited number of metallurgical samples and drill hole sections were also
assayed for Ce, Pr, Nd, Gd and Dy.
� The Norwegian geological survey [NGU] conducted a detailed study on the REE potential from 1967-1970
focussed on the north-eastern part of the complex. The following main results and conclusions were
obtained:
o The best grades were observed in hematite-rich carbonatite (rodbergite) and iron (hematite)-ore
o Metallurgical recoveries were low due to very fine grain-size of RE oxides (1µ). The grains size of
RE oxides in calcite- (50-70% >43µ) and ankerite-dolomite carbonatite is significantly larger (70-
90% > 43µ).
o Bulk sampling of iron rich carbonatite (rodbergite) returned 2.8% TREO [8 elements + Y]
o Ankerite-calcite-dolomite carbonatite (rauhaugite) returns 1.51% TREO over 170 meter strike
length [8 elements + Y]
o Drill hole F1 returns 1.03% REO over 251 meters [6 elements + Y]
o Drill hole F2 returns 1.06% REO over 190 meters [8 elements + Y]
o Drill hole F3 returns 1.32% REO over 31 meters [8 elements + Y]
� Grab sampling with up to 4% REE and >50% Fe are reported from the untested Bjoerndalen area by junior
exploration companies
� Carbonatite samples in distal parts of complex return up to 0.44% Y
� Slag dump at the historic Soeve niobium process plant comprises c. 600 tonnes of aluminum-rich waste
material with an average grade of 1.12% REOs [Ce, La, Nd, Pr + Y]
� 50m line spacing heli-borne radiometric survey was completed by NGU in 2006 outlining near-surface
thorium, uranium and potassium anomalies
� The Fen carbonatite complex hosts one of the world´s largest known thorium deposits. Uranium levels are
low
� Excellent infrastructure and gentle terrain mostly comprising farmlands and forest in the license area
Page 3 of 47
2. Regional Setting
The Fen Complex, an early Cambrian intrusive complex of alkaline rocks and carbonatites, is situated in Nome
municipality, Telemark County, 119 kilometers southwest of Oslo in the vicinity of the late Palaeozoic alkaline Oslo
Rift. The intrusion has a roughly circular outcrop of 9 km2 and is placed within Mesoproterozoic Telemark gneisses,
which form part of the Gothian-Sveconorwegian terrane of southern Scandinavia (fig.1).
The eastern parts of the complex are strongly enriched in REEs and the radioactive element thorium-232, and to a
much lesser degree uranium-238. Concentrations of thorium in the eastern part of the complex are so significant that
Norway is considered to host one of the world’s largest thorium deposits (OECD NEA and IAEA 2006).
The location became famous in the geological community in 1921, after Broegger published his classic work on the
intrusion. Broegger believed that carbonate rocks in the Fen Complex were of magmatic origin, and became one of the
first proponents of the existence of carbonate magmas. The, at that time outrageous claim, was first generally
accepted when carbonate lava was observed flowing from the Oldoinyo Lengai, a volcano in Tanzania early in the
1960s. Broegger introduced the term “carbonatite” for carbonate rocks of apparent magmatic origin, and named many
rock types in this suite after localities in the Fen region. Today, the Fen complex is widely recognized as the type
locality for carbonatites
3. Historic exploration and mining
The Fen Complex has an old and interesting exploration history comprising several episodes of mining initiated as
early in the mid-seventeenth century and later substantial work in the 1960s and -70s by the Norwegian Geological
Survey [NGU] outlining the REE potential Most recently the complex has been surveyed for radiogenic elements,
notably thorium.
3.1 The Fen iron mines 1657-1927
Iron ores associated with the carbonatites were worked in the eastern part of the Fen Complex for several hundred
years involving both open pit as well as underground mining. The ore comprised hematite-rich carbonatites, known
as rodbergite, which follows a system of N-S trending veins and dykes.
Mining took place at several localities in and around the central complex with iron grades generally in excess of 50%
Fe. The most extensive workings were in the Gruveåsen area, close to the eastern margin of the intrusion where
operations by the 1920s had reached a level 225 meters below the surface of Lake Norsjø. Today, the existing surface
exposures of both ore and associated carbonatite are deeply weathered and the underground workings of the mines
are not open to the public without permission. Fresh exposures are mostly found along road sections in the vicinity of
the mining areas.
3.2 Soeve niobium mine 1953-1965
The carbonatites of the Fen area are geochemically enriched in niobium. The main niobium-bearing mineral,
pyrochlore was identified already in 1918 in a soevite rock next to Lake Norsjø. The niobium potential was first
investigated in the late 30s by the Norwegian state and later by the Germans during the 2nd WW who did a
considerable research work with the aim of exploiting the resource. After the war, partly driven by American interest,
a state-owned company, Norsk Bergverk A/S, was formed in 1951 in order to produce niobium concentrate and
ferroniob from the pyrochlore-bearing soevites. The average grade was about 0.35-0.4% Nb2O5. After extensive
development work and ore dressing tests, mining started in 1953 as a quarry near Lake Norsjø. Further development
involved construction of a 900 meter tunnel (Tuftestollen) towards the central parts of the soevite area producing
about 100.000 to 150.000 tons of raw ore annually. The mining operations and development work carried out by
Norsk Bergverk A/S have given a good knowledge of the structures in the soevite rocks and of the niobium
mineralisation including the peripheral ore bodies at the Cappelen and Hydro deposits. The niobium mineralisation
seems to be connected with N-S trending, partly brecciated, zones in the carbonatites.
Page 4 of 47
Waste material from the production of ferroniob from the production was dumped as an aluminum-rich slag at a
small hill next to the production plant in Soeve. The slag includes comprises 570 tonnes, which was covered and
sealed by marine clays afterwards. The material is rich in radioactive elements and REEs (>1% REO). Leaching of the
slag has enriched radiation locally and polluted nearby water ways; however, a strategy for handling and storing the
material has not been decided upon by the local Municipality.
3.3 Geophysical surveying and exploration for Th and REE
1940s: Due to the extensive Quaternary clay cover in the Fen area, early geological mapping was supported by a
ground-based geomagnetic survey using a 25 meter grid. Several, at that time, hidden rock units and contacts were
outlined by this method. It was also discovered that the hematite was non-magnetic and only detected when
associated with disseminated magnetite.
1950s-1970s: Prospecting carried out by Norsk Bergverk A/S during niobium mining in the 1950s and -60s showed a
rather strong radioactivity in several parts of the Fen Complex. Furthermore, it was demonstrated that the highest
concentration of REEs generally coincided with high Th contents. However, a planned study of the Th and REE
potential was never carried out due to economic problems in the company.
FSJ [a state-governed research group prospecting for REEs] was formed in 1967 as a national survey program for
REEs in Norway and continued until 1970. C. 200 rock samples were collected along road sections and from historic
mining pits in the Fen complex and historic drill holes were resampled and analysed. In addition, three new diamond
drill holes were completed in what was regarded as the most prospective areas.
The program concluded that substantial deposits of REEs occurred in an area of app. 1km2 next to the historic Fen
mining area. This area generally coincides with the iron-rich rodbergite, but also in the unaltered carbonatites
significant enrichment of REEs was identified.
Part of the sample and drill material was subjected to mineralogical studies and beneficiation test work carried out by
the NGU; however, results were mostly discouraging with low recoveries due to the fine grain size of the ore.
1980s-1990s: Dahlgren (1983) published a map showing gamma-ray exposure rates 1 m above the ground over the
Fen Complex around the nearby town of Ulefoss. Comparison with measurements on core samples showed that
extremely high thorium concentrations, accompanied by elevated uranium concentrations in the carbonatites, were
responsible for the high exposure rates. Between 1993 and 2000, indoor radon measurements were carried out in
about 250 dwellings in Nome municipality by the company Labnet and the Norwegian Radiation Protection Authority.
2000-: Based on the realization that high levels of radon were emitted in houses and constructions of the Fen area, the
NGU conducted an aerial radiometric survey in 2006. Helicopter measurements were carried out using a 256-channel
Exploranium GR820 gamma-ray spectrometer with sodium iodide detector packs. An area of about 20 km2 over the
Fen Complex and nearby town of Ulefoss was surveyed. To ensure a uniform and dense data coverage, the
measurements were performed along parallel lines with a narrow line spacing of 50 m. The average flying altitude
during the measurements was 45 m and an average speed of 70 km h-1 resulted in measurement intervals of app. 20
m.
3.4 Junior exploration activities 2000- Several Norwegian junior companies have claims within the Fen complex, but no systematic exploration has been
carried out for REEs. Unconfirmed data from Thorium Norway´s website report grab samples with up to 4% REE and
50% Fe from the Bjoerndalen area in the southeastern part of the license area.
REE Minerals are presently exploring for REEs in the southern and eastern part of the complex with focus on the
mostly sediment covered extension of known mineralisation at Gruveåsen and Rauhaug. This report forms the initial
part of an exploration campaign taking place in 2011 with 21st NORTH as operator.
Page 5 of 47
4. Geology
4.1 Introduction
The Fen Complex has an irregular, circular-shaped surface structure with a size of app. 9km2, and formed when
alkaline magmas intruded into 1105 Ma Precambrian Telemark gneisses in the Late Neoproterozoic (fig.1). The
complex has an age of c. 583 ± 10 Ma. Today, only the feeder pipe is visible at the surface because the upper 1–2 km of
the former volcanic edifice has been eroded away. However, gravity modeling shows that the Fen Complex extends to
at least 15 km depth. Today, large parts of the Fen Complex are covered by post-glacial allochthonous marine silt and
clay deposits (~60% of the surface area) that can reach a thickness of several tens of meters. There appears to be no
single contact between the edge of the complex, but rather a gradational series of intensely altered rocks whose
primary character is obscured by contact metamorphism, hydrothermal alteration, veining and possible brecciation.
Comprehensive descriptions of surface geology are given by Broegger (1921) and Saether (1957). The geological
mapping has been based on small and infrequent exposures due to the heavy Quaternary cover. Some descriptions of
rocks are likewise based on erratic blocks rather than in situ exposures.
The country rock of the Fen Complex is predominantly a felsic, medium-grained, migmatitic gneiss, comprising quartz,
perthitic microcline, oligoclase, dark-brown biotite and green hornblende, with subordinate opaque’s, apatite, allanite,
titanite and zircon, interpreted as foliated granite and possibly metavolcanic rocks. Towards the margin of the Fen
Complex the gneiss shows a gradual increasing brecciation and a gradual increasing replacement of the original
biotite, hornblende and quartz by aggregates of Na-pyroxenes and Na-amphiboles. Microcline gives way to
mesoperthite and chessboard albite aggregates. Plagioclase shows a gradual increasing saussuritization. Close to the
rocks of the Fen Complex, plagioclase is replaced by clear aggregates of albite. The fenitised zone around the Fen
Complex has a maximum width of 200-300 m, sometimes only a few meters and is best preserved along the western
and southern margins. However, outside this zone there are many occurrences of minerals typical for fenitisation.
The principal types of carbonatite in the Fen Complex are soevite (a calcite carbonatite), rauhaugite (ankeritic or
ferrodolomitic carbonatite) and rodbergite (a hematite-carbonate rock). Steeply dipping iron-ore veins occur mainly
in the hematite-rich rodbergite. REE and thorium concentrations are particularly high within the rodbergite and
ankerite carbonatite (rauhaugite) and associated iron-ore veins.
Basic alkaline silicate rocks of the ijolite and melteigite group (rocks consisting of nepheline and pyroxene) occur in
the south western part of the complex. A minor area in the south central part of the complex consists of vipetoite; a
coarse-grained cumulate rock consisting of amphibole, pyroxene, phlogopite and apatite. Damtjernite, a porphyritic
ultramafic lamprophyre with megacrysts of phlogopite, amphibole, pyroxene and olivine, occurs as minor bodies
scattered within the Fen Complex. Diatremes and dykes of damtjernite, and dykes of carbonatite and phonolite
(‘tinguaites’) penetrate the Proterozoic basement surrounding the Fen Complex, and have been discovered up to 47
km from the complex.
4.2 Rocks of igneous origin
Basic rocks: In the central southwestern parts of the Fen complex several associated igneous basic rocks characterized
by the main minerals nepheline, aegirine and augite and lack of feldspar dominate the map pattern. In parts of the
region they are transformed into biotite-calcite or chlorite-calcite rocks. They include (in order of decreasing
nepheline content):
Urtite: Consisting mainly of nepheline (70-90%) together with pyroxene and biotite.
Ijolite: Consisting of nepheline and aegirine-augite in equal amounts.
Meltgeite: Has aegirine-augite as its main constituent, with up to 30% nepheline.
Vipetoite: Consists of augite, amphibole, biotite and minor calcite. Titanomagnetite, apatite, pyrite, titanite and
occasionally melanite and cancrinite occur as accessories.
Page 6 of 47
Fig.1. Geological sketch map of the Fen Complex, superimposed on part of the 5th NOR edition of the 1:50,000
topographical map-sheet UMT 1713 IV Nordagutu 1964.
Lamphrophyric rocks: Gravity investigations by Ramberg in the 60s and 70s established that the various rocks
outcropping in the Fen Complex form only a thin cap on top of a vertical cylindrical body at least 15 km deep
consisting of igneous material with a density of about 3.10 g cm3. This material was believed by Ramberg to be
damtjernite, a phlogopite-bearing, ultramafic lamprophyre, which also occur as isolated bodies throughout the
complex. The mantle origin of the damkjernite is indicated by the presence of lherzolite nodules. The differentiation
Page 7 of 47
processes producing the damkjernite magma probably occurred at or below the base of the continental crust, which is
now at least 33 to 34 km below the Fen area.
Damtjernite: Is distinguished by phenocrysts of biotite in a fine-grained matrix of pyroxene, amphibole, biotite,
nepheline, feldspar and calcite in varying proportions. Phlogopite occurs as coatings on biotite and accessory minerals
include apatite, ilmenite, chromite, pyrite and titanite. The rock often forms intrusive breccias including fragments of
gneiss, fenite, basic rocks and carbonatites.
Carbonatitic rocks:
Calcite carbonatite (soevite): A carbonate rock of variable composition, consisting mostly of calcite with subordinate
silicates. The grain size varies from fine-grained, almost marble-like texture, to coarse-grained carbonatite. Ankerite
and dolomite occur in variable amounts and in places can become quite dominant, in which case the rock is called
rauhaugite. Mica, magnetite, pyrochlore and apatiite occur as accesory minerals.
Ankerite-dolomite carbonatite (rauhaugite): An iron-magnesium rich carbonate rock dominated by ankerite and
dolomite as rock forming minerals.
Hematite-ankerite carbonatite (rodbergite): Meaning red rock, an iron-rich carbonate rock (with calcite and ankerite in
varying proportions), which is red-coloured from finely dispersed hematite along NW-SE striking fissures. Locally, the
hematite becomes the main consitutent and form iron ore. The rock is generally highly enriched in thorium and REEs.
The texture is mostly fine to very fine-grained with hematite occuring as poikilitic inclusions in calcite and along
grain-boundaries. In thin section the rock appears full of reddish dust particles.
4.3 Metasomatic alteration and associated rocks
Emplacement of the Fen peralkaline-carbonatitic complex 583±10 Ma ago in the older Telemark gneisses caused
mineralogical, chemical and Sr-isotopic changes, i.e., fenitisation, in the country rocks. Fenitisation involved at least
two main phases of brecciation, creating pathways for the fenitising fluids, and at least two main phases of
metasomatic alteration of varying degree. In some places the fenite only constitutes a narrow zone between the
intrusive rocks of the Fen complex and the country gneiss whereas other parts, mostly towards the south and west,
are characterized by several hundred meters wide areas with fenitisation. Weaker signs of fenitisation, mostly as
discrete alkaline veins or sheets, occur several kilometers away from the complex.
Fenite: refers to an alkali syenitic rock formed by metasomatic alteration and is found in peripheral parts of the Fen
intrusion. The main minerals in the rock are alkali feldspar, partly as a characteristic microperthite, aegirine, aegirine-
augite and minor Na-amphibole. Apatite, zircon and pyrite occur as accessory minerals. The rock form through
breakdown and replacement of the original minerals of the gneiss such as biotite, hornblende and feldspar by alkaline
equivalents mentioned above.
Left: Hematite carbonatite (rodbergite) outcrop along new road to water tank at Bjoerndalen. Right: Calcium
carbonatite (soevite) with magnetite phenocrysts at road section next to Soeve.
Page 8 of 47
Examples of altered and fenitised country rock along the marginal part of the Fen complex.
Transitional rocks: Along the boundaries between the fenite and the basic rocks transitional types containing
nepheline, feldspar, pyroxene, biotite and melanite occur. Broegger referred to them as:
Juveite: A nepheline syenite with orthoclase, nepheline, aegirine, biotite and minor calcite
Tveitaiste: A melanocratic rock consisting of alkali feldspar and aegirine-augite (shonkinite)
Kampreite: A melanocratic rock with alkali feldspar and biotite
Malignite: Consisting of alkali feldspar, nepheline and aegirine-augite
Tinguaite: A leucocratic dyke rock
These rocks have their widest development in the southern part of the Fen area, but are also found in the northern
part. They are invariably surrounded, and always separated from the basement rocks, by a zone of fenite. In general,
they have low content of REEs.
5. License area – REE minerals
All parts of the Fen carbonatite complex are presently covered by minerals exploration or exploitation claims (fig.2).
The central western parts of the complex next to the town of Ulefoss are claimed by the Norwegian State (license
dated back to 1987) whereas the eastern central parts including the far majority of the historic iron mining areas is
claimed by Cappelen, the old iron mining family in Ulefoss. Cappelen also have exploitation right within the area
dating back to 1981 but no initiatives to mine either iron or REEs has been taken to date. REE Minerals (previously
known as Thorium Norway) has control of exploration rights covering the eastern and southernmost extension of the
carbonatites extending into the fenitised gneiss along the margin of the intrusive complex. Areas of immediate
interest within the license include the Fensmyra and Bjoerndalen valley, which for most parts are covered by
farmland and forest (fig.3). Outcrops are scarce, mostly observed along road sections and as scattered lenses within
higher levels of the forest. The main consideration of exploration work is to evaluate the extent of carbonatite and
rodbergite towards south and east, which presently is unknown due to the extensive cover of marine sediments.
Suggested exploration includes the use of various geophysical approaches such as magnetic/gravimetric surveys and
MMI soil sampling combined with the existing radiometric data set in order to define the most promising drill targets.
Page 9 of 47
Fig.2. License map of the Ulefoss/Fen area centered on the carbonatite complex. REE Minerals´ has control of claims
covering the eastern and southernmost parts of the complex bordering the historic iron mining locations, which is known
to host significant REE mineralisation.
6. Radiometry
During the period of niobium mining it was realized that some parts of the carbonatite complex were highly
radioactive. In 1955 and 1956 a study of the radioactivity was completed by Norsk Bergverk A/S, which showed that
especially the old iron minings around Gruveåsen in the eastern part of the complex showed very high concentrations
of thorium and REEs. Uranium levels on the other hand are generally low.
A complete radiometric survey was not conducted until 2006 were the NGU launched an airborne survey of the entire
complex to investigate radon radiation. Helicopter measurements were carried out using a 256-channel Exploranium
GR820 gamma-ray spectrometer with sodium iodide detector packs. An area of about 20 km2 over the Fen Complex
and nearby town of Ulefoss was surveyed. To ensure a uniform and dense data coverage, the measurements were
performed along parallel lines with a narrow line spacing of 50 m. The average flying altitude during the
measurements was 45 m and an average speed of 70 km h-1 resulted in measurement intervals of app. 20 m.
Thorium concentrations were shown to vary significantly within the complex, partly reflecting the complex geology of
the region (Figures 4a, b) and the footprint of human activities from historic mining and ore smelting (generating
spoil and slag heaps) as well as road and construction work in the area. In addition, the survey clearly outlined areas
with Quaternary marine cover. Only a few decimeters of fine-grained marine sediments are enough to effectively
shield gamma radiation emitted by underlying thorium- and uranium-bearing rocks. Consistent with this, areas of
fine-grained marine deposits in the Fen area are marked by low concentrations of thorium (< 20 ppm eTh) and
uranium (< 4 ppm eU) on figures 4a, b. Where rocks of the volcanic complex and their weathering products are at or
near the land surface, very high thorium concentrations (up to 1460 ppm eTh at Gruveasen) and significant uranium
concentrations are observed.
Page 10 of 47
Fig.3. Aerial photo of the Fen area overlain by radiometry (uranium) based on 2006 NGU survey. Simplified license
borders are shown as black lines. The area of interest within REE Minerals´ license is outlined by shaded white figure in
the south eastern part of the map.
Page 11 of 47
Fig.4a-b. Concentration of a) thorium and b) uranium isotopes at surface within the Fen complex based on 2006 heli-
borne radiometric survey conducted by the NGU. Areas with >560 ppm Th and 13 ppm U are shown in black. White lines
define area with radiation intensity > 20µR/h from historic ground surveys.
Page 12 of 47
Fig.5. Simplified geological map of the Fen carbonatite and fenitised country rock. Red and yellow lines outlines areas
with high concentration of thorium (>250 ppm) and uranium (>7 ppm) based on radiometric survey by NGU in 2006.
Page 13 of 47
7. REE Mineralisation In the Fen complex
7.1 Introduction
A large number of REE projects have seen the day within the last few years in order to develop reserves to
accommodate the growing and critical demand and to provide especially the western world with other import options
than China who has announced a potential export ban on certain elements. Very few of these projects are situated in
Europe, and the location of the Fen Complex in southern Norway is thus ideal to supply the European market. Despite
the present rush for REEs in most other parts of the world no exploration work to date has been carried out in the Fen
carbonatite complex for REE deposits since the late 60s.
7.2 NGU work in the 1960s and 1970s
The earliest recordings of REEs in the Fen area were contemporary with working on the Soeve Niobium mines in the
late 50s by Norsk Bergverk A/S. Several assays of iron ore and rodbergite from various pits in the mining area
returned between 0.8-2% REE and 0.1-0.3% thorium. However, due to low grades of niobium in the areas of interest
no further work was carried out on the REE potential. The Fen iron ore typically occur as veins, lenses or dyke-like
bodies found within carbonatites or carbonatised gneisses in their immediate surroundings. They are most frequently
associated with hematite (±magnetite)-dolomite-calcic carbonatite (rodbergite) in the eastern part of the complex.
The individual ore lenses range in width from a few centimeters to several meters and may extend for tens of meters
along strike in an irregular en echelon northwest trending pattern. The ores may be classified as either hematite or
magnetite and occur as both massive and disseminated varieties.
In 1967, the state owned FSJ and NGU established an exploration program to outline resources and metallurgical
issues within the areas in the eastern part of the carbonatite complex that had seen iron and niobium mining in the
past. It was known that several rock types were highly radiogenic and Ce-rich REE carrying mineral phases were
known to occur within the carbonatites and iron ore.
The execution of the program was carried out by NGU and involved the following tasks:
� Geochemical analysis and mineralogical investigations on rock and drill core samples
� Radiometric surveys and measurements in parts of the Fen complex
� Beneficiation test work on rock and drill core samples
� A preliminary drill campaign to outline continuity, structural relationships and resources within the most
prospective parts of the complex
7.3 Results
Most samples were assayed for REEs and thorium at IFA in Norway whereas standard geochemical and whole-rock
analysis was done by the NGU.
Most samples were only assayed for a selected number of REEs including La, Sm, Eu, Yb and Y. A limited number of
metallurgical samples (table 1) and drill hole sections were also assayed for Ce, Pr, Nd, Gd and Dy. Historic rock and
drill data is included in Appendix A+B. It should be noted that some assays, especially for Sm vary significantly due to
analytical errors and it is highly recommended to regard the historic data set critically.
Rock and drill core samples:
A few hundred rock samples were collected during the prospecting work, mostly along road sections in the Fen iron
mining area and in the south-lying Gruveåsen. Other areas, which were sampled, include Rauhaug and Vipeto.
Unfortunately, most rock samples are without description, hence the only indication of rock type, texture and
composition is the geological map found in NGU reports from 1967-1970. In general, the samples from the Fen mining
area show high levels of REEs but with some variation. As part of the sampling program, a continuous profile of chip
samples was collected along an 800 meter road section in the northern part of the area next to Norsjø. The profile
corresponds to the highest levels of thorium and comprises 10 meter chip samples from west to east. The highest
Page 14 of 47
levels of REEs occur in the westernmost part of the road section within an area dominated by dolomite-ankerite
carbonatite (rauhaugite) and hematite-stained rodbergite returning 1.51% REO over 170 meters [9 elements + Y].
Rock sampling from areas outside of the Fen Mining area is collected much less extensive and systematic and is
generally confined to the Fen, Rauhaug and Vipeto areas. The best grades occur in rauhaugite and rodbergite with
grades up to 4200 ppm La and more interestingly a few samples with Y values up to 4400 ppm (samples only assayed
for La, Sm, Eu, Yb and Y). The La levels correspond to the higher grade sections of the Fen Mining area whereas high Y
levels are not recorded in other parts of the complex. In general, it is obvious that additional rock sampling is required
in the mores distal parts of the carbonatite complex.
In addition to rock sampling, several historic drill holes were re-sampled and assayed for a number of REEs. An
overview of re-sampled drill hole sections is found in Appendix B. Unfortunately, the exact location and orientation of
some drill holes is unknown. Information on the location and orientation of drill holes is compiled in Appendix B 1-2).
The following list includes a brief overview of re-sampled historic drill holes:
� Historic drill core samples from Tuftefeltet:
o 197 samples from holes T9, T11, T12, T13, T14, T16, T18, T21 and T23 (comprising soevites, rauhaugites
and rodbergite rock)
� Historic drill core samples from Soeve niobium plant/Cappelen field
o 11 samples from holes C11 and C43 (next to Norsjø)
� Historic drill core samples from Bolladalen
o 84 samples from holes B.1, B.2 and Bolla (same location)
� Historic drill core samples from the Tuftestollen adit
o 25 samples from hole Ts7 (drilled for pyrochlore mineralisation)
The samples from Tuftefeltet defines an east-west going profile of drill holes, which show a clear enrichment of REEs
from west towards the Fen mining area in the east. This enrichment is first noticed in DH T16 with maximum values
in DH T21. Especially La demonstrates this trend very clearly with La levels increasing from 100-200 ppm up to 3000
ppm in DH T21. Also Sm and Eu show a threefold increase from west to east. Yttrium levels are relatively constant.
In 1970, the NGU completed three new drill holes based on the mapping and results from samples collected the
previous years. All holes were drilled in the Bolladalen area at Gruveåsen with a total length of 510.35 meters. The
holes are designated F1 to F3 (Appendix B).
� F1: Carbonatite and rodbergite with an avg. grade of 1.03% REO over 251 meters [6 elements + Y]
� F2: Carbonatite w/minor magnetite with an avg. grade of 1.06% REO over 190 meters [8 elements + Y]
� F3: Mostly rodbergite w/minor carbonatite and damtjernite. Limited zones with rich hematite-ore with an
average grade of 1.32% REO over 31 meters [8 elements + Y]
The general sample length was between 3 and 5 meters and all samples were split in half with one part retained in the
core box and the other prepped and sent to analysis. A total of 115 samples were assayed.
Mineralogy and metallurgical testing:
Historic academic geochemical work and mineralogical studies within the Fen complex has shown that REE
abundances increase in the order ijolite-damtjernite<soevite-rauhaugite<rodbergite reflecting the differentiation order
of the magma with highest REE concentration in the latest forming rocks. Based on the collected samples and work
scope, the NGU concluded that the old iron mining area and Gruveåsen had the best potential for finding an economic
REE deposit. Here, large and continuous areas with hematite-rich carbonatite occur with a high average content of
REEs around 1.5% REO. Smaller bodies may return significantly higher grade.
Mineral separation and mineralogical studies concluded that the REE ore mainly consisted of the following minerals
(R = rare earth element, dominated by Ce and La):
� Monazite R PO4
� Bastnaesite R CO3 F
� Synchisite R Ca(CO3)2 F
� Parisite R2 Ca(CO3)3 F2
Page 15 of 47
The NGU subjected a number of samples to metallurgical test work in order to evaluate the mineralogy and a
workable flow sheet to concentrate the REEs. The samples were mostly collected as mini-bulk samples of a few
hundred kilos or reject material from the drill holes. Sample material was analysed and processed by the NGU in
Trondheim, IFA and the Fiskaa Verk.
The iron-ore and fine-grained hematite-carbonatites (rodbergite) contains up to 95% hematite and in general differs
from other known deposits of REEs by the high content of iron. The sample material generally proved difficult to
concentrate through grinding and magnetic separation and roasting with recoveries around 50% (“hematite malm”
sample). REE minerals (dominated by monazite) are very fine-grained with sizes around 1µ and irregular grain
boundaries and required grinding down to >78% at -200 mesh. Flotation studies using 250 kg 1:5 diluted H2SO4 and
accessory NaClO3 as oxidation source per tonnes sample material proved effective but are obviously a more costly
solution. After a few hours in the acid the material was filtered and NaOH added. From this solution a pure
concentrate of thorium and REOs was produced with a recovery of c. 90%. A high concentration of calcium may
inhibit filtration but was not a problem in samples with CaO < 10wt. %.
Mineralogical studies showed that the samples “Vegskæring” and “Bolladalen” (table 1) are more coarse-grained with
good liberation around 100-120 mesh grinding with a grain size of 50-90% > 43µ. Magnetite separation shows that
the individual fractions following were rich in REOs, mostly comprising parisite and synchisite. Preliminary flotation
studies did, however, not produce a satisfying concentrate.
Based on the mineralogical and metallurgical test work the NGU concluded that three types of ore could be identified:
� Very fine-grained hematite ore, representing vein type mineralisation from the Fen mining/Gruveåsen area
(represented by the “hematite malm” ore sample) with a REO content (including 8 RE elements + Y) of
c.2.8%. REE minerals primarily occur as coatings of monazite on hematite often as sub-microscopic
recrystallisation products forming inhomogeneous aggregates or “clouds” of very fine-grained REE minerals
(grain size of 1µ).
� Dolomite-ankerite carbonatite from the road section next to the Fen mining area (represented by the
“vegskjæring” ore sample) with an REO content (including 8 RE elements + Y) of c. 1.5%. RE minerals are
belonging to the bastnaesite group and are significantly more coarse-grained than in the hematite-rich
samples (50-70% >43 µ). Part of the REOs occur intergrown with hematite.
� Gruveåsen ore comprising hematite-rich carbonatite (represented by the “Bolladalen” ore sample) with a
REO content of c. 1.6% (including 8 RE elements + Y). RE minerals are belonging to the bastnaesite group and
are significantly more coarse-grained than in the hematite-rich samples (70-90% >43 µ).
Sample ID Description
1 Hematite ore, Hoved Berghallen - Fens Gruvene.
2 "Vegskjæring""pure" carbonatite/dolomite-ankerite, road cut at Fens gruvene. 200 kg bulk sample comprising 50 kg
samples I, III, IX and X corresponding to sample 121-137 (170 m)
3 "Hematit malm"200 kg Hematite ore from small vein (0,5m) at Fens Gruvene next to sample 150. Road c. 70m V of
"grundstoll" at Fens Gruvene
4 "Bolladalen"4* 50 kg bulk samples comprising V, VI, VII, VIII from Gruveåsen. Hematite-calcite rock w/ minor silicates
"Bolladalen"
5 DH F2 avg over 190 meters
6 DH F3 avg over 31 meters
Table 1. Description, geochemical and mineralogical results from processing of six mini-bulk samples from the Fen area
(continued on next page).
Page 16 of 47
Sample ID Y [ppm] La [ppm] Ce [ppm] Pr [ppm] Nd [ppm] Sm [ppm] Eu [ppm] Gd [ppm] Dy [ppm]
1 145 8500 570 92
2 "Vegskjæring" 182 3045 6475 883 1845 300 71 68 70
3 "Hematit malm" 220 4760 9800 2000 5700 1060 130 61 270
4 "Bolladalen" 240 2150 6940 905 2900 450 86 56 105
5 184 2400 5900 243 57 317
6 355 2400 7700 325 68 435
Sample IDTotal REE
[ppm]
Total REO
[ppm]
Dissolved
HCl/HNO3
silicates [%]
Carbonates
[%]
Hematite
[%]
RE-min.
[%]Apatite [%] Sulphides [%]
1 9307 10889 7 19 63 4 4 2,5
2 "Vegskjæring" 12939 15139 8 85 2,5 1 3,5
3 "Hematit malm" 24001 28081 7,4 14 69 5 2,5
4 "Bolladalen" 13832 16183 3,9 67 26 3 1,5 3,5
5 9101 10648
6 11283 13201
Table 1. Description, geochemical and mineralogical results from processing of six mini-bulk samples from the Fen area.
8. Exploration in recent years
The Fen complex has seen very limited exploration activity for REEs after the NGU terminated their campaign in 1970.
The historic iron mining family, Cappelen, has retained an exploitation license covering the majority of the known
iron-rich rodbergite outcrops and the Norwegian State has large claims in the westernmost parts of the carbonatite
towards the town of Ulefoss. A few Norwegian junior exploration companies including REE Minerals have claims in
the remaining and more distal parts of the complex where outcrops of carbonatite and iron-rich rocks is less common
due to extensive marine cover and agricultural farmland. The radiometric survey from 2006 suggests that the
easternmost parts of these areas may include significant hidden bodies of carbonatites, which can only be targeted by
drilling.
Surface exploration has by all means been very limited only including a few random samples from areas with high
radioactivity in the Bjoerndalen area to the southeast. Grab sampling from these localities has returned up to 4%
TREO (unconfirmed data – Thorium Norway).
9. The slag dump at soeve niobium plant
Norsk Bergverk A/S exploited niobium in soevite during the period 1953-1965, mainly the supplying the American
steel industry after the 2nd WW. The ore graded app. 0.35-0.4% Nb hosted by the minerals pyrochlore ((Na, Ca) Nb2O6
(OH, F)), columbite (FeNb2O6) and fersmite ((Ca, Ce, Na) (Nb, Ta, Ti) (O, OH, F)6. These minerals also contain small
amounts of uranium, thorium, tantalum and REEs.
A considerable amount of industrial slag was deposited next to the mining area and comprises two main types of
material: (1) leftovers from production of niobium concentrate and (2) the metallurgical product ferroniob,
respectively. Production of these materials took place at the Soeve plant and involved standard grinding, washing,
magnetic separation and flotation procedures to separate and concentrate the niobium from the ore.
Page 17 of 47
Waste material from the production of niobium concentrate included light minerals such as calcite, apatite and mica,
as well as accessory non-soluble niobium minerals, which were deposited at Lake Norsjø among others. Apparently
the addition of calcium has had a positive effect on the fish stocks and the deposit does not represent any
environmental hazard.
During the period of ferroniob production, a total amount of c. 600 tonnes of slag was deposited on the slope next to
the processing plant. The slag dump was following covered by marine clays. Part of the niobium material was
however also unintentionally mixed with the soil for construction on the plant and is referred to as “washing soil”. It
has long been known that the slag was radioactive and several studies has thus been undertaken to investigate the
composition and potential health issues the material may cause. Chemically, the material is dominated by aluminum
(53% Al2O3), niobium (9% Nb2O5) and calcium (CaO) with minor amounts of manganese, titanium, barium and
sodium. The concentration of uranium, thorium, REEs, tantalum and zircon makes up several percent of the total
waste.
The Norwegian Geotechnical Institute [NGI] completed a study in 2009 concluding that radiation is primarily
comprising gamma- and radon emission from thorium and uranium, which varies considerably in the area.
Furthermore, the concentration of certain heavy metals such as uranium, thorium and arsenic is also higher than the
accept criteria (fig.6).
It has been suggested that the slag dump is either concealed on site (estimated to cost 12 million NOK) or are removed
and deposited somewhere else (the Gulen plant where low radioactive material from the North Sea is presently stored
is an option). The estimated price for removing the slag material is 190 million NOK. The Norwegian state has
earmarked a large funding for this purpose although no action has been taken to date by the municipality of Nome.
Alternatively the slag is processed and recovered for its precious metals such as REEs and tantalum. However, the
limited size of the slag dump makes it questionable whether such a production would be feasible.
Fig 6. Aerial photo from 1965 covering the Soeve processing plant separated into areas of potential pollution: RED: areas
with high levels of radiation (>5mSv/yr) and some heavy metals. YELLOW: Considerable radiation (>3mSv/yr). GREEN:
Variable radiation with point areas having high levels due to storage of radioactive soil.
Page 18 of 47
Oxide wt% Soeve 1 Soeve 2 Soeve 3 Soeve 4 Avg. Soeve 1-4
Soeve 5 Washing Soil
Nb- konc.
Ferro- niob metal %
FeNb
Si02 5,26 5,09 3,44 4,87 4,67 28,50 3,20 Si 2,66
Ti02 2,92 8,88 6,76 4,52 5,77 1,30 7,50 Ti 0,35
Al203 48,85 52,58 54,92 55,70 53,01 7,80 0,10 Al nd
Fe203 0,07 0,09 1,22 0,10 0,37 29,80 15,90 Fe 41,08
MoO 0,51 0,66 0,48 0,43 0,52 0,30 0,90 Mo 0,47
MgO 5,97 0,56 0,65 0,53 1,93 1,90 0,20 Mg nd
CaO 7,05 7,73 9,62 7,52 7,98 11,70 4,80 Ca 0,09
Na20 4,33 4,40 3,56 5,53 4,46 1,30 0,20 Na 0,77
K20 0,05 0,04 0,05 0,04 0,05 1,60 nd K nd
P205 nd 0,02 nd nd 0,80 0,50 P 0,10
BaO 4,27 3,40 3,09 6,24 4,25 1,50 1,40 Ba 0,03
SrO 0,41 0,27 0,27 0,59 0,39 0,10 0,20 Sr nd
Nb205 12,17 8,51 9,21 5,06 8,74 10,40 60,30 Nb 52,92
Ta205 2,14 0,71 0,71 1,79 1,34 0,20 0,30 Ta 0,70
Zr02 1,30 2,41 1,87 1,62 1,80 0,40 1,50 Zr nd
Th02 1,88 1,56 1,41 1,95 1,70 0,30 1,30 Th 0,10
U308 1,12 0,42 0,44 1,01 0,75 0,05 0,10 U nd
Y203 0,03 0,05 0,04 0,04 0,04 0,01 0,06 Y nd
Ce02 0,49 0,95 0,78 0,66 0,72 nd 0,60 Ce nd
Nd203 0,10 0,21 0,14 0,16 0,15 nd 0,20 Nd nd
La203 0,17 0,16 0,16 0,17 0,17 La nd
Pr6011 0,03 0,04 0,05 0,04 0,04 Pr nd
S03 0,02 0,06 0,04 1,40 0,50 S03 nd
CI nd 0,02 0,05 0,30 nd Cl nd
F 0,68 0,99 1,00 1,14 V 0,14
Sm203 0,02 0,02 Mo 0,07
Sc203 0,01 nd Co 0,05
V205 0,06 nd Sn 0,02
Total 99,14 99,88 99,91 99,80 99,66 99,76 Sum 99,55
Table 2. XRF analysis and average grade of slag material from the Soeve niobium plant. Soeve 1 to 4 represent slag
material and Soeve 5 so-called “washing soil”. FeNb material represents globule separated from the sample Soeve 3. The
average concentration of REOs in the slag material is 1.12wt% (Ce, La, Nd, Pr and Y).
Page 19 of 47
10. references
Andersen, T. 1983: Iron ores in the Fen central complex, Telemark (S. Norway): Petrography, chemical evolution and conditions of equilibrium. Norsk Geologisk Tidsskrift 2-3, 73-82.
Andersen, T. 1984: Secondary processes in carbonatites: petrology of ‘rodberg’ (hematite-calcite-dolomite carbonatite) in the Fen central complex, Telemark (South Norway). Lithos, 17, 227–245. Andersen, T. 1986: Magmatic fluids in the Fen carbonatite complex, S. E. Norway: evidence of mid-crustal fractionation from solid and fluid inclusions in apatite. Contributions to Mineralogy and Petrology 93, 491–503. Andersen, T. 1986: Compositional variation of some rare earth minerals from the Fen complex (Telemark, SE Norway): implications for the mobility of rare earths in a carbonatite system. Mineralogical Magazine 50, 503-509.
Andersen, T. 1987: Mantle and crustal components in a carbonatite complex, and the evolution of carbonatite magma: REE and isotopic evidence from the Fen complex, S. E. Norway. Chemical Geology 65, Isotope Geoscience Section, 147–166.
Andersen, T. 1988: Evolution of peralkaline calcite carbonatite magma in the Fen complex, southeast Norway. Lithos 22, 99-112
Andersen, T. 1989: Carbonatite-related contact metasomatism in the Fen complex, Norway: effects and petrogenetic implications. Mineralogical Magazine 53, 395–414. Andersen, T. & Qvale, H. 1985: The Fen Central Complex. Guide to an excursion 3-4 June 1985. Report no IFE/KR/F-85/074. Barth,T.W.W. & Ramberg, I.B. 1966: The Fen circular complex. In: Tuttle,O. F. & Gittins, J. (eds.) Carbonatites , John
Wiley and Sons, New York, 225–257.
Bergstøl, S. 1960: En petrografisk og mineralogisk undersøkelse av bergartene rundt Fens feltet med hovedvekt på gangbergartene. Unpublished internal report, University of Oslo, 55 pp.
Bergstøl, S. & Svinndal, S. 1960: The carbonatites and per-alkaline rocks of the Fen area. Norges geologiske undersøkelse 208, 99–105. Bjørlykke, H. & Svinndal, S. 1960: The carbonatite and the peralkaline rocks of the Fen area.Mining and exploration work. Norges geologiske undersøkelse 208, 105–110. Brøgger, W. C. 1921: Die Eruptivgesteine des Kristianiagebietes: IV. Das Fengebiet in Telemark, Norwegen. Norske
Vindenskapsakademi i Oslo Skrifter I Mat-Nat Klasse 1920, 9, Kristiania, 408 pp. Bugge, J.A.W. 1973: Thorium i Fensfeltet, Nome, Telemark. NGU report 1162, 28 pp.
Cook, N.J. & Ciobanu, C.L. 2009: Reconnaissance visit to Fen ore field 30th – 31st May 2009. Internal Field report prepared for Thorium Norway, 20 pp.
Dahlgren, S. 1984: Geology of central Telemark area, South Norway. Volume of abstracts of the NATO Advanced Study Institute “The Deep Proterozoic Crust in the North Atlantic Provinces”, Norway 1984.
Dahlgren, S. 1987: The satellitic intrusions in the Fen Carbonatite-Alkaline Rock Province, Telemark, Southeastern Norway. Unpublished. cand. scient. thesis,Univ. of Oslo, 390 pp.
Dahlgren, S. 1994: Late Proterozoic and Carboniferous ultramafic magmatism of carbonatitic affinity in southern Norway. Lithos 31, 141–154.
Dahlgren, S. (1994): Late Proterozoic and Carboniferous ultramafic magmatism of carbonatitic affinity in southern Norway. Lithos, 31, 141–154.
Dahlgren, S. 2005: Miljøgeologisk undersøkelse av lavradioaktivt slagg fra ferroniob produksjonen på Søve 1956–1965. Regiongeologen for Buskerud, Telemark og Vestfold, Rapport nr.1, 47 pp.
Page 20 of 47
Dahlgren, S. 2004: Bergrunnskart, foreløpig utgave 1 : 50 000 Nordagutu 1713 IV, Norges geologiske undesøkelse. Endre, E, Sparrevik,M., Cappelen, P., Baardvik, G. and Holmström, P. 2010: Kartlegging av omfang og kostnader ved eventuell senere opprydding av radioaktivt materiale ved Søve gruver. NGI report 20091927-00-14-R, 157 pp.
Heincke, B.H., Mogaard, J.O., Rønning, J.S. & Smethurst, M.A. 2007: Kartlegging av thorium, uran og kalium fra helicopter ved Ulefoss, Nome Kommune. NGU report 2007.021, 16 pp.
Heincke, B.H., Smethurst, M.A., Bjørlykke, A., Dahlgren S., Rønning, J.S. & Mogaard, J.O. 2008: Airborne gamma-ray spectrometer mapping for relating indoor radon concentrations to geological parameters in the Fen region, southeast Norway. Geology for Society, Geological Survey of Norway Special Publication, 11, pp. 131–143.
Kresten, P. 1988: The chemistry of fenitization: Examples from Fen, Norway. Chemical Geology 68, 329–349. Kresten, P. 1994: Chemistry of fenitization at Fen, Norway and Alnö, Sweden. In: Meyer, H.O. A. & Leonardos,O. H. (eds.) Proceedings of the Fifth International Kimberlite Conference, Araxá, Brazil 1991. Vol. 1. Kimberlites, related rocks
and mantle xenoliths. 252–262.
Kresten, P. & Morogan V. 1986: Fenitization at the Fen complex, southern Norway. Lithos 19, 27–42. Landreth, J.O. 1979: Mineral potential of the Fen Alkaline Complex. Ulefoss. Norway. Bergvesenet Rapport BV 1332, 30 pp. Meert, J. G., Torsvik, T. H., Eide, E. A. & Dahlgren, S. 1998: Tectonic Significance of the Fen Province, S. Norway: Constraints from geochronology and paleomagnetism. Journal of Geology 106, 553–564. Mitchell, R.H. 1980: Pyroxenes of the Fen alkaline complex, Norway. American Mineralogist 65, 45-54.
Mitchell, R. H. & Brunfelt, A.O. 1974: Scandium, cobalt and iron geochemistry of the Fen alkaline complex, southern Norway. Earth and Planetary Science Letters 23, 189–192.
Mitchell, R. H. & Brunfelt, A.O. 1975: Rare earth element chemistry of the Fen alkaline complex, Norway. Contributions to mineralogical petrology 52, 247-259.
Mitchell, R. H. & Crocket, J. H. 1972: Isotopic composition of strontium in rocks of the Fen alkaline complex, South Norway. Journal of Petrology 13, 83–97.
Neumann, H. 1960: Apparent ages of Norwegian minerals and rocks. Norsk Geologisk Tidsskrift 40, 173–191. Ramberg, I. B. 1964: Preliminary results of gravimetric investigations in the Fen area. Norsk Geologisk Tidsskrift 44, 431–434. Ramberg, I. B. 1973: Gravity studies on the Fen Complex, Norway, and their petrological significance. Contributions to Mineralogy and Petrology 38, 115–134. Svinndal, S. 1967: Undersøkelser efter sjeldne jordartselementer (RE) I Fensfeltet, Ulefoss. NGU report 776, 23 pp. Svinndal, S. 1968: Undersøkelser efter sjeldne jordartselementer (RE) I Fensfeltet, Ulefoss. NGU report 820, 42 pp.
Svinndal, S. 1968: Undersøkelser efter sjeldne jordartselementer (RE) I Fensfeltet, Ulefoss. NGU report 820 B, 46 pp. Svinndal, S. 1970: Undersøkelser efter sjeldne jordartselementer (RE) I Fensfeltet, Ulefoss. NGU report 966, 18 pp.
Sæther, E. 1957: The alkaline rock province of the Fen area in southern Norway. Det Kongelige Norske Videnskabers Selskabs Skrifter 1, 150 pp. Verschure, R. H. & Maijer, C. 1984: Pluri-metasomatic resetting of Rb-Sr whole-rock systems around the Fen peralkaline-carbonatitic ring complex, Telemark, south Norway. Terra Cognita 4, 191–192.
Verschure, R. H. 1985: Geochronological framework for the Late-Proterozoic evolution of the Baltic Shield in South Scandinavia. In: Tobi,A.C.& Touret J.L.R. (eds.) The Deep Proterozoic Crust in the North Atlantic Provinces. NATO ASI Serie C, Vol. 158 D. Reidel Publishing Company, Dordrecht, 499–516.
Page 21 of 47
Verschure, R. H. & Maijer, C. 2005: A new Rb-Sr isotopic parameter for metasomatism,Δt, and its application in a study of pluri-fenitized gneisses around the Fen ring complex, South Norway. NGU Bulletin 445, 45-71.
Page 22 of 47
THE FEN CARBONATITE COMPLEX,
ULEFOSS, SOUTH NORWAY
Summary of historic work and data
Compiled and prepared by 21st NORTH, Svendborg 12 May 2011 in commission for REE Minerals, Norway
Appendix a
Rock samples – NGU 1967-1970
Page 23 of 47
Sample ID Year Area CollectorX UTM
[WGS 84 32N]
Y UTM
[WGS 84 32N]Rock type REE Total [ppm] Y [ppm] La [ppm] Sm [ppm] Eu [ppm] Yb [ppm] Gd [ppm]
1 1967 Gruveåsen NGU 517760 6570550 700 42 380 150 18 100 10
2 1967 Gruveåsen NGU 517630 6570649 1236 95 750 150 68 160 13
3 1967 Gruveåsen NGU 517636 6570667 1600 140 1080 170 65 50 95
4 1967 Gruveåsen NGU 517649 6570667 1341 260 610 160 60 160 91
5 1967 Gruveåsen NGU 517690 6570666 546 120 270 50 34 50 22
6 1967 Gruveåsen NGU 517714 6570664 1859 360 880 300 98 130 91
7 1967 Gruveåsen NGU 517742 6570666 1956 180 1240 300 81 50 105
8 1967 Gruveåsen NGU 517770 6570659 1127 110 690 160 34 120 13
9 1967 Gruveåsen NGU 517610 6570720 1758 220 710 550 138 140
10 1967 Gruveåsen NGU 517580 6570720 1347 96 740 270 61 180
11 1967 Gruveåsen NGU 517410 6570580 1940 100 1560 150 54 50 26
12 1967 Gruveåsen NGU 517410 6570580 2341 28 1500 260 33 510 10
13 1967 Gruveåsen NGU 517686 6570600 1098 92 710 140 26 120 10
15 1967 Gruveåsen NGU 517371 6570643 2655 250 1670 400 133 120 82
16 1967 Gruveåsen NGU 517370 6570643 3665 200 2600 600 168 80 17
17 1967 Fensgruvene NGU 517040 6571090 3348 60 2800 330 88 70
18 1967 Fensgruvene NGU 517040 6571095 997 140 710 60 37 50
20 1967 Gruveåsen NGU 517600 6570620 1088 110 620 120 38 200
21 1967 Gruveåsen NGU 517601 6570620 3066 190 2000 570 156 150
22 1967 Gruveåsen NGU 517570 6570940 1250 75 700 260 45 170
23 1967 Gruveåsen NGU 517569 6570940 509 35 260 100 14 100
24 1967 Gruveåsen NGU 517548 6570653 1814 44 1070 160 20 520
25 1967 Gruveåsen NGU 517488 6570719 2650 250 1760 410 60 170
26 1967 Gruveåsen NGU 517376 6570705 4202 95 3860 140 57 50
27 1967 Gruveåsen NGU 517442 6570659 2908 85 2400 290 63 70
28 1967 Gruveåsen NGU 517441 6570659 2274 120 1750 240 64 100
29 1967 Gruveåsen NGU 517493 6570574 1565 170 960 300 65 70
30 1967 Gruveåsen NGU 517429 6570549 3663 95 2810 580 128 50
31 1967 Gruveåsen NGU 517430 6570549 1321 390 500 290 91 50
32 1967 Gruveåsen NGU 517517 6570498 1604 10 1140 310 44 100
33 1967 Gruveåsen NGU 517517 6570499 0
34 1967 Gruveåsen NGU 517580 6570540 3039 50 2430 210 49 300
35 1967 Gruveåsen NGU 517580 6570540 0
36 1967 Fen NGU 517246 6570531 3224 88 2610 310 76 140
100 1968 Gruveåsen NGU 517360 6570680 1975 120 1340 320 65 130
101 1968 Gruveåsen NGU 517360 6570680 2660 150 2060 350 50 50
102 1968 Gruveåsen NGU 517360 6570680 3180 170 2480 380 100 50
103 1968 Rauhaug NGU 516956 6569948 3690 30 3480 110 20 50
104 1968 Rauhaug NGU 516979 6569905 2120 55 1840 140 35 50
105 1968 Rauhaug NGU 516990 6569857 1340 40 1090 130 30 50
Table A1 of A5.
Page 24 of 47
Sample ID Year Area CollectorX UTM
[WGS 84 32N]
Y UTM
[WGS 84 32N]Rock type REE Total [ppm] Y [ppm] La [ppm] Sm [ppm] Eu [ppm] Yb [ppm] Gd [ppm]
106 1968 Rauhaug NGU 517004 6569810 655 120 340 110 35 50
107 1968 Rauhaug NGU 517249 6569850 1630 60 1340 150 30 50
108 1968 Rauhaug NGU 517286 6569621 1030 120 680 150 30 50
109 1968 Rauhaug NGU 517490 6570010 1755 55 1360 240 50 50
110 1968 Rauhaug NGU 517440 6570090 1540 30 1340 90 30 50
111 1968 Fensgruvene NGU 516659 6571336 Damtjernite? 540 90 320 70 10 50
112 1968 Fensgruvene NGU 516678 6571335 carbonatite 360 45 190 65 10 50
113 1968 Fensgruvene NGU 516718 6571287 Damtjernite + rodbergite 1325 60 1080 110 25 50
114 1968 Fensgruvene NGU 516719 6571282 4165 70 3850 160 35 50
115 1968 Fensgruvene NGU 516723 6571274 2745 40 2500 130 25 50
116 1968 Fensgruvene NGU 516742 6571257 1815 45 1640 60 20 50
117 1968 Fensgruvene NGU 516761 6571235 5780 40 5500 160 30 50
118 1968 Fensgruvene NGU 516765 6571229 3685 35 3440 130 30 50
119 1968 Fensgruvene NGU 516813 6571149 9160 60 8600 340 110 50
120 1968 Fensgruvene NGU 516899 6571117 Damtjernite? 3160 120 2680 260 50 50
121 1968 Fensgruvene NGU 517000 6571090 Damtjernite? 3160 110 2720 220 60 50
122 1968 Fensgruvene NGU 517009 6571080 Damtjernite? 4505 90 3940 350 75 50
123 1968 Fensgruvene NGU 517020 6571072 hematite ore zones 9470 120 8600 540 160 50
124 1968 Fensgruvene NGU 517031 6571060 hematite ore zones 5760 120 5000 480 110 50
125 1968 Fensgruvene NGU 517040 6571050 hematite ore zones 3735 90 3160 360 75 50
126 1968 Fensgruvene NGU 517044 6571046 hematite ore zones 5420 120 4840 320 90 50
127 1968 Fensgruvene NGU 517055 6571038 hematite ore zones 4080 130 3600 240 60 50
128 1968 Fensgruvene NGU 517064 6571031 hematite ore zones 4130 400 3260 340 80 50
129 1968 Fensgruvene NGU 517075 6571025 hematite ore zones 4030 150 3460 300 70 50
130 1968 Fensgruvene NGU 517083 6571016 hematite ore zones 3490 180 2920 280 60 50
131 1968 Fensgruvene NGU 517088 6571009 hematite ore zones 3395 170 2850 270 55 50
132 1968 Fensgruvene NGU 517091 6571006 hematite ore zones 4030 160 3480 280 60 50
133 1968 Fensgruvene NGU 517094 6571003 hematite ore zones 4085 160 3530 270 75 50
134 1968 Fensgruvene NGU 517099 6570996 hematite ore zones 3080 230 2450 280 70 50
135 1968 Fensgruvene NGU 517107 6570989 hematite ore zones 3875 200 3280 280 65 50
136 1968 Fensgruvene NGU 517110 6570985 hematite ore zones 4055 130 3560 250 65 50
137 1968 Fensgruvene NGU 517110 6570982 hematite ore zones 4580 240 3860 350 80 50
138 1968 Fensgruvene NGU 517155 6570949 hematite ore zones 2450 160 1950 200 55 50 35
139 1968 Fensgruvene NGU 517165 6570940 hematite ore zones 2146 130 1720 180 40 50 26
140 1968 Fensgruvene NGU 517174 6570934 hematite ore zones 1186 110 900 90 10 50 26
141 1968 Fensgruvene NGU 517188 6570923 hematite ore zones 2003 110 1620 150 30 50 43
142 1968 Fensgruvene NGU 517200 6570917 hematite ore zones 1706 100 1400 100 30 50 26
143 1968 Fensgruvene NGU 517217 6570908 hematite ore zones 3503 140 2940 200 95 50 78
144 1968 Fensgruvene NGU 517227 6570903 hematite ore zones 1321 220 800 150 45 50 56
145 1968 Fensgruvene NGU 517238 6570900 hematite ore zones 4209 140 3580 290 80 50 69
Table A2 of A5.
Page 25 of 47
Sample ID Year Area CollectorX UTM
[WGS 84 32N]
Y UTM
[WGS 84 32N]Rock type REE Total [ppm] Y [ppm] La [ppm] Sm [ppm] Eu [ppm] Yb [ppm] Gd [ppm]
146 1968 Fensgruvene NGU 517247 6570897 hematite ore zones 1589 140 1100 200 60 50 39
147 1968 Fensgruvene NGU 517260 6570895 hematite ore zones 1960 260 1300 200 50 50 100
148 1968 Fensgruvene NGU 517294 6570901 hematite ore zones 3543 200 2820 300 65 50 108
149 1968 Fensgruvene NGU 517306 6570904 hematite ore zones 2832 180 2230 240 50 50 82
150 1968 Fensgruvene NGU 517317 6570905 hematite ore zones 3977 360 2900 440 110 50 117
151 1968 Fensgruvene NGU 517327 6570906 hematite ore zones 2093 210 1540 200 50 50 43
152 1968 Fensgruvene NGU 517338 6570907 hematite ore zones 1376 140 1000 120 35 50 31
153 1968 Fensgruvene NGU 517348 6570910 hematite ore zones 2286 180 1720 260 45 50 31
154 1968 Fensgruvene NGU 517366 6570911 hematite ore zones 1748 180 1240 190 45 50 43
155 1968 Fensgruvene NGU 517382 6570911 hematite ore zones 3377 220 2640 340 75 50 52
156 1968 Fensgruvene NGU 517393 6570914 hematite ore zones 2885 300 2070 310 90 50 65
157 1968 Fensgruvene NGU 517406 6570915 hematite ore zones 1829 260 1150 230 65 50 74
158 1968 Fensgruvene NGU 517418 6570916 hematite ore zones 3777 280 2870 360 100 50 117
159 1968 Fensgruvene NGU 517430 6570923 hematite ore zones 1592 230 1060 140 60 50 52
160 1968 Fensgruvene NGU 517501 6570954 hematite ore zones 665 140 390 65 20 50
161 1968 Fensgruvene NGU 517507 6570959 Increasing fenitisation 845 120 510 140 25 50
162 1968 Fensgruvene NGU 517512 6570962 Increasing fenitisation 655 95 450 45 15 50
163 1968 Fensgruvene NGU 517517 6570968 Increasing fenitisation 1410 50 1160 140 10 50
164 1968 Fensgruvene NGU 517524 6570974 Increasing fenitisation 980 80 780 60 10 50
165 1968 Fensgruvene NGU 517528 6570979 Increasing fenitisation 480 100 260 50 20 50
166 1968 Fensgruvene NGU 517535 6570984 Increasing fenitisation 950 180 590 100 30 50
167 1968 Fensgruvene NGU 517542 6570989 Increasing fenitisation 2015 220 1390 280 60 65
168 1968 Fensgruvene NGU 517547 6570995 Increasing fenitisation 1200 250 720 140 40 50
169 1968 Fensgruvene NGU 517554 6570997 Increasing fenitisation 2580 240 1900 330 60 50
170 1968 Fensgruvene NGU 517561 6570999 Increasing fenitisation 1070 130 800 65 25 50
171 1968 Fensgruvene NGU 517562 6571003 Increasing fenitisation 845 150 500 120 25 50
172 1968 Fensgruvene NGU 517577 6571008 Increasing fenitisation 470 110 250 40 20 50
173 1968 Fensgruvene NGU 517585 6571012 Increasing fenitisation 475 140 240 30 15 50
174 1968 Fensgruvene NGU 517595 6571015 Increasing fenitisation 330 120 120 30 10 50
175 1968 Fensgruvene NGU 517606 6571019 Fenite w/ minor carbonatite and rodbergite 585 140 300 85 10 50
176 1968 Fensgruvene NGU 517619 6571023 Fenite w/ minor carbonatite and rodbergite 480 80 280 60 10 50
177 1968 Fensgruvene NGU 517633 6571027 Fenite w/ minor carbonatite and rodbergite 550 120 320 50 10 50
178 1968 Fensgruvene NGU 517644 6571029 Fenite w/ minor carbonatite and rodbergite 385 110 170 45 10 50
179 1968 Fensgruvene NGU 517658 6571029 Fenite w/ minor carbonatite and rodbergite 400 110 190 40 10 50
180 1968 Fensgruvene NGU 517669 6571032 Fenite w/ minor carbonatite and rodbergite 455 120 250 25 10 50
181 1968 Fensgruvene NGU 517686 6571027 Fenite w/ minor carbonatite and rodbergite 430 120 220 30 10 50
182 1968 NGU 2590 90 2240 170 40 50
183 1968 Rauhaug NGU 517129 6569964 540 90 320 60 20 50
184 1968 Rauhaug NGU 517106 6570041 1755 50 1540 100 15 50
185 1968 Rauhaug NGU 517066 6570068 965 65 770 65 15 50
Table A3 of A5.
Page 26 of 47
Sample ID Year Area CollectorX UTM
[WGS 84 32N]
Y UTM
[WGS 84 32N]Rock type REE Total [ppm] Y [ppm] La [ppm] Sm [ppm] Eu [ppm] Yb [ppm] Gd [ppm]
186 1968 Rauhaug NGU 516886 6569806 645 120 390 55 30 50
187 1968 Søve Gruver NGU 516421 6571225 595 80 390 60 15 50
188 1968 Søve Gruver NGU 516430 6571130 4970 25 4780 90 25 50
189 1968 Søve Gruver NGU 516460 6570980 2570 25 2340 120 35 50
190 1968 Søve Gruver NGU 516460 6570930 1870 35 1620 130 35 50
191 1968 Søve Gruver NGU 516420 6570810 1335 45 1150 65 25 50
192 1968 Fen NGU 517332 6570436 975 80 740 80 25 50
193 1968 Fen NGU 517150 6570540 1715 70 1460 110 25 50
194 1968 Fen NGU 1880 220 1350 200 60 50
14a 1967 Gruveåsen NGU 1204 70 720 170 54 180 10
14b 1967 Gruveåsen NGU 1149 220 660 140 39 90
1 1967 Melteig NGU 515640 6569006 282 120 60 20 12 70
2 1967 Melteig NGU 515627 6569008 372 72 220 20 10 50
2b 1967 Melteig NGU 432 78 270 10 14 60
3 1967 Melteig NGU 515641 6569022 581 190 170 50 21 150
4 1967 Melteig NGU 515632 6568986 369 64 220 20 15 50
5 1967 Melteig NGU 515633 6568986 350 30 230 20 10 60
6 1967 Melteig NGU 515620 6568974 384 84 230 10 10 50
7 1967 Melteig NGU 515632 6568951 212 52 20 20 10 110
8 1967 Melteig NGU 515627 6568927 244 44 120 20 10 50
9 1967 Melteig NGU 515620 6568861 256 56 130 10 10 50
1 1967 Rauhaug NGU 517113 6569588 764 220 220 90 50 50 134
1x 1967 Rauhaug NGU 740 180 400 65 45 50
2 1967 Rauhaug NGU 517091 6569605 1005 210 580 70 47 50 48
3 1967 Rauhaug NGU 517071 6569621 992 170 620 80 42 50 30
4 1967 Rauhaug NGU 517056 6569643 487 120 220 40 35 50 22
5a 1967 Rauhaug NGU 457 120 220 30 37 50
5b 1967 Rauhaug NGU 826 150 500 80 46 50
6a 1967 Rauhaug NGU 517260 6569939 813 110 460 90 25 50 78
6b 1967 Rauhaug NGU 517264 6569930 832 180 400 90 51 50 61
7 1967 Rauhaug NGU 517252 6569941 0
8 1967 Rauhaug NGU 517235 6569938 1733 54 1270 250 66 50 43
9 1967 Rauhaug NGU 517160 6570064 1307 100 900 120 42 50 95
10 1967 Rauhaug NGU 517035 6569798 4889 44 4200 440 145 50 10
10a 1967 Rauhaug NGU 6228 66 5500 460 152 50
10b 1967 Rauhaug NGU 6365 62 5660 430 163 50
11 1967 Rauhaug NGU 517046 6569788 726 120 410 100 46 50
12 1967 Rauhaug NGU 517101 6569765 1158 75 850 85 46 50 52
12b 1967 Rauhaug NGU 1553 78 1240 140 45 50
Table A4 of A5.
Page 27 of 47
Sample ID Year Area CollectorX UTM
[WGS 84 32N]
Y UTM
[WGS 84 32N]Rock type REE Total [ppm] Y [ppm] La [ppm] Sm [ppm] Eu [ppm] Yb [ppm] Gd [ppm]
13 1967 Rauhaug NGU 517065 6569771 carbonatite 6833 4410 1880 230 103 50 160
14 1967 Rauhaug NGU 517083 6569774 carbonatite 4275 2320 1670 150 50 50 35
15 1967 Rauhaug NGU 517068 6569726 hematite ore 3619 78 2950 400 78 70 43
16 1967 Rauhaug NGU 517112 6569752 rodbergite 1039 120 740 85 39 7 48
1 1967 Søve NGU 516090 6570990 tuftestollen/underground 1589 86 1400 30 23 50
2 1967 Søve NGU 516090 6570990 tuftestollen/underground 504 66 360 10 18 50
1a 1967 Vipeto NGU 516680 6569460 333 100 160 10 13 50
1b 1967 Vipeto NGU carbonatite 344 80 180 10 24 50
2 1967 Vipeto NGU 516680 6569462 310 80 160 10 10 50
3 1967 Vipeto NGU 516670 6569600 carbonatite 314 50 180 10 24 50
3a 1967 Vipeto NGU light carbonatite 270 82 80 40 18 50
3b 1967 Vipeto NGU dark carbonatite 135 20 50 15 50
4 1967 Vipeto NGU 516828 6569461 467 76 280 40 21 50
4x 1967 Vipeto NGU 198 34 80 20 14 50
4b 1967 Vipeto NGU Vipetoite 497 82 300 50 15 50
5 1967 Vipeto NGU 516825 6569485 Vipetoite 283 56 150 10 17 50
6 1967 Vipeto NGU 516833 6569495 299 55 160 20 14 50
7 1967 Vipeto NGU 516838 6569515 164 24 60 20 10 50
8 1967 Vipeto NGU 516837 6569533 0
9 1967 Vipeto NGU 516838 6569550 270 40 120 50 10 50
10 1967 Vipeto NGU 516836 6569576 190 40 70 20 10 50
10b 1967 Vipeto NGU 389 60 220 40 19 50
11 1967 Vipeto NGU 516831 6569590 140 46 20 10 14 50
12 1967 Vipeto NGU 516832 6569591 259 55 100 40 14 50
12a 1967 Vipeto NGU 254 44 100 50 10 50
12b 1967 Vipeto NGU 392 84 170 60 28 50
13 1967 Vipeto NGU 516831 6569590 260 48 120 20 22 50
13b 1967 Vipeto NGU 182 12 100 10 10 50
14 1967 Vipeto NGU 516828 6569614 199 35 90 10 14 50
15 1967 Vipeto NGU 516570 6569620 405 85 250 10 10 50
16 1967 Vipeto NGU 516580 6569670 carbonatite 449 85 280 10 24 50
17 1967 Vipeto NGU 516600 6569660 carbonatite 862 80 650 50 32 50
18 1967 Vipeto NGU 517000 6569430 carbonatite 334 60 200 10 14 50
Table A5 of A5.
Page 28 of 47
THE FEN CARBONATITE COMPLEX,
ULEFOSS, SOUTH NORWAY
Summary of historic work and data
Compiled and prepared by 21st NORTH, Svendborg 12 May 2011 in commission for REE Minerals, Norway
Appendix B
Drill hole data
Re-assays of historic drill holes
B.1, B.2, Bolla, C11, C43, T9, T11, T12, T13, T14, T16, T18, T21, T23 and Ts7
NGU drill holes
F1, F2 and F3
Page 29 of 47
Fig. B1. Aerial photo of The Soeve – Gruveåsen area with location and orientation of historic drill holes referred to in appendix B.
Page 30 of 47
DH_ID AZI DipCollar X UTM
WGS 84 32N
Collar Y WGS
84 32NLength [m]
Core
diameter
[mm]
Year drilled
T 9 270 5 515990 6570450 130,00 na historic
T 11 90 35 516000 6570450 150,00 na historic
T12 270 40 516600 6570450 120,00 na historic
T13 270 25 516600 6570450 145,00 na historic
T14 90 40 516690 6570450 157,50 na historic
T 18 270 25 516350 6570550 150,00 na historic
T 16 90 43 516360 6570550 120,00 na historic
T 21 270 15 516660 6570550 120,00 na historic
T 23 90 20 516670 6570550 155,00 na historic
F1 210 11 517070 6571030 251,10 46 1970
F2 205 10 517170 6570930 195,45 46 1970
F3 80 15 517330 6570730 63,80 46 1970
B1 240 0 517360 6570630 97,00 22 1956
B2 240 25 517360 6570630 88,70 22 1956
C11 unknown unknown 516471 6571513 120,00 unknown historic
C43 0 90 516592 6571540 120,00 unknown historic
Ts7 25 unknown 516190 6570560 unknown unknown historic
Bolla 240 unknown 517360 6570630 unknown unknown 1956
Table B1 of B12. Collar position and orientation of analysed drill holes referred to in the text and appendix B. Some information is missing for certain holes. Length of hole for some
holes are estimated based on graphical logs and is not exact.
Page 31 of 47
DH ID Sample ID Year From [m] To [m]Density
[g/cm3]Th [ppm] Y [ppm] La [ppm] Ce [ppm] Sm [ppm] Eu [ppm] Gd [ppm] Yb [ppm] Rock type
B1 1 1956 (re-assay) 0,00 4,55 1100 220 2200 7000 300 53 350 Rodbergite
B1 2 1956 (re-assay) 4,55 9,75 1300 310 2200 6500 350 61 410 Rodbergite
B1 3 1956 (re-assay) 9,75 15,55 1500 339 2500 7500 380 51 460 Rodbergite
B1 4 1956 (re-assay) 15,55 20,50 1100 190 2200 6400 260 56 330 Rodbergite
B1 5 1956 (re-assay) 20,50 24,70 1100 210 2200 6400 240 49 310 Rodbergite
B1 6 1956 (re-assay) 24,70 30,25 1500 230 2400 6700 310 62 370 Rodbergite and carbonatite
B1 7 1956 (re-assay) 30,25 36,05 1500 240 2500 7500 370 58 440 Rodbergite
B1 1956 (re-assay) 36,05 37,45 Diabase
B1 8 1956 (re-assay) 37,45 41,40 1200 290 2400 7400 430 67 430 Rodbergite and carbonatite
B1 9 1956 (re-assay) 41,40 45,50 1200 270 2000 5600 300 47 250 Carbonatite
B1 10 1956 (re-assay) 45,50 51,80 1100 210 3100 7600 280 40 350 Carbonatite
B1 11 1956 (re-assay) 51,80 55,60 630 180 750 2100 160 55 110 Carbonatite
B1 12 1956 (re-assay) 55,60 60,60 1200 250 2500 6400 280 53 290 Carbonatite
B1 13 1956 (re-assay) 60,60 65,25 1100 379 3000 8100 370 63 460 Rodbergite and carbonatite
B1 14 1956 (re-assay) 65,25 70,05 1000 350 2900 8000 260 52 380 Rodbergite
B1 15 1956 (re-assay) 70,05 75,55 830 230 2500 6800 250 51 290 Rodbergite and carbonatite
B1 16 1956 (re-assay) 75,55 81,00 1100 270 1500 4600 240 43 220 Carbonatite, minor rodbergite
B1 1956 (re-assay) 81,00 82,00 Diabase
B1 17 1956 (re-assay) 82,00 87,75 1000 250 1300 4600 240 47 220 Carbonatite
B1 18 1956 (re-assay) 87,75 92,75 790 170 2200 8000 220 41 340 Carbonatite
B1 19 1956 (re-assay) 92,75 97,00 660 170 2200 7400 170 36 310 Carbonatite
B2 1 1956 (re-assay) 0,00 4,85 880 200 1900 6000 350 60 310 Rodbergite
B2 2 1956 (re-assay) 4,85 9,65 1300 320 2900 8300 370 90 470 Rodbergite
B2 3 1956 (re-assay) 9,65 15,35 1400 300 2700 8000 360 74 470 Rodbergite
B2 4 1956 (re-assay) 15,35 19,70 1400 260 2400 6900 310 64 390 Rodbergite, minor carbonatite
B2 5 1956 (re-assay) 19,70 25,00 1100 230 2200 6800 290 62 380 Rodbergite, breccia structure
B2 6 1956 (re-assay) 25,00 29,80 1000 180 1900 5900 340 36 340 Rodbergite, varoable composition
B2 7 1956 (re-assay) 29,80 35,00 1300 220 3600 10000 380 100 480
Rodbergite interleaved w/ carbonatite. Local massive
hem ore.
B2 8 1956 (re-assay) 35,00 38,20 1200 250 3700 11000 470 83 580
Rodbergite, minor carbonatite and some massive hem
ore.
B2 1956 (re-assay) 38,20 40,00 Diabase
B2 9 1956 (re-assay) 40,00 45,20 1000 220 2600 8000 320 59 470 Rodbergite
B2 10 1956 (re-assay) 45,20 51,30 920 270 3100 8600 300 54 470 Rodbergite
B2 11 1956 (re-assay) 51,30 56,55 1100 310 2300 6500 230 54 350 Rodbergite, light
B2 12 1956 (re-assay) 56,55 62,50 860 180 1500 4800 200 45 290 Rodbergite, impure
B2 13 1956 (re-assay) 62,50 68,50 500 140 1100 3900 130 31 210 Rodbergite
B2 14 1956 (re-assay) 68,50 73,80 6800 170 1500 4200 120 32 230 Rodbergite
B2 15 1956 (re-assay) 73,80 78,30 8900 210 2500 7500 250 43 410 Rodbergite
B2 16 1956 (re-assay) 78,30 84,00 8900 210 2700 8300 280 51 440 Rodbergite
B2 17 1956 (re-assay) 84,00 88,70 1200 250 3700 9000 380 63 560
Table B2 of B12.
Page 32 of 47
DH ID Sample ID Year From [m] To [m]Density
[g/cm3]Th [ppm] Y [ppm] La [ppm] Ce [ppm] Sm [ppm] Eu [ppm] Gd [ppm] Yb [ppm] Rock type
Bolla 1 1956 3,3 2100 100 3340 360 66
Bolla 2 1956 3,0 1300 180 2380 290 62
Bolla 3 1956 2,7 1400 150 2880 280 59
Bolla 4 1956 2,8 1900 260 4520 550 110
Bolla 5 1956 3,3 1600 120 2780 310 68
Bolla 6 1956 4,4 800 84 2660 380 54
Bolla 7 1956 2,7 2200 220 1920 300 61
Bolla 8 1956 2,7 900 130 2020 330 75
Bolla 9 1956 3,0 900 210 4000 520 90
Bolla 10 1956 4,4 4500 78 6600 740 130
Bolla 11 1956 2,5 0 32 280 80 10
Bolla 12 1956 3,5 3300 210 9760 880 150
Bolla 13 1956 3,0 1400 180 3840 330 106
Bolla 14 1956 2,7 500 140 400 140 38
Bolla 15 1956 3,1 2100 100 3360 260 61
Bolla 16 1956 3,0 1000 260 2880 270 62
Bolla 17 1956 3,2 1500 120 2300 360 71
Bolla 18 1956 4,4 1100 32 2560 320 40
Bolla 19 1956 3,2 1500 100 2420 320 45
Bolla 20 1956 2,8 1300 340 2760 500 75
Bolla 21 1956 3 1200 290 900 310 77
Bolla 22 1956 2,7 2300 140 1800 260 53
Bolla 23 1956 3,2 1700 130 2760 370 55
Bolla 24 1956 3 1000 110 3260 340 54
Bolla 25 1956 2,9 400 120 420 55 27
Bolla 26 1956 3 1100 58 900 130 37
Bolla 27 1956 2,9 2000 200 3040 330 90
Bolla 28 1956 4,1 2500 120 9400 990 190
Bolla 29 1956 3,7 700 160 1120 210 41
Bolla 30 1956 3 1200 320 1980 380 87
Bolla 31 1956 2,9 3600 210 4900 270 140
Bolla 32 1956 2,9 1500 570 2000 630 55
Bolla 33 1956 2,8 1500 320 1600 240 60
Bolla 34 1956 2,9 400 92 3620 68 27
Bolla 35 1956 2,8 600 84 460 120 10
Bolla 36 1956 2,9 900 190 940 170 52
Bolla 37 1956 2,9 1100 150 3480 240 65
Bolla 38 1956 3 3800 370 4160 490 120
Bolla 39 1956 3,4 800 130 1960 520 75
Bolla 40 1956 2,9 200 36 460 60 10
Bolla 41 1956 3 800 150 2520 170 48
Bolla 42 1956 3 1100 170 1640 140 45
Table B3 of B12.
Page 33 of 47
Page 34 of 47
DH ID Sample ID Year From [m] To [m]Density
[g/cm3]Th [ppm] Y [ppm] La [ppm] Ce [ppm] Sm [ppm] Eu [ppm] Gd [ppm] Yb [ppm] Rock type
Bolla 43 1956 2,8 1100 200 2560 210 64
Bolla 44 1956 3 1300 210 1420 280 61
Bolla 45 1956 3,1 1400 380 5420 550 150
Bolla 46 1956 3 4200 550 3960 360 110
Bolla 47 1956 2,9 1900 200 3700 430 75
Bolla 48 1956 2,6 1400 440 1260 250 82
C 11 1 1968 (re-sampled) 45 230 35 10 50
C 11 2 1968 (re-sampled) 45 100 20 10 50
C 43 8 1968 (re-sampled) 110 170 55 20 50 Soev ite
C 43 15 1968 (re-sampled) 75 230 45 15 50 Soev ite
C 43 16 1968 (re-sampled) 75 290 65 15 50 Soev ite
C 43 17 1968 (re-sampled) 80 320 65 15 50 Soev ite
C 43 18 1968 (re-sampled) 55 300 65 15 50 Soev ite
C 43 19 1968 (re-sampled) 60 240 35 10 50 Fenite
C 43 20 1968 (re-sampled) 60 320 70 15 50 Soev ite
C 43 21 1968 (re-sampled) 90 360 65 15 50 Soev ite and Hollaite
C 43 22 1968 (re-sampled) 80 300 45 15 50 Soev ite
F1 1970 0,00 1,25 Casing
F1 1 1970 1,25 3,20 900 220 1900 4600 270 51 240 Carbonatite w/ dark brieccia structures
F1 2 1970 3,20 6,80 800 370 1000 2600 170 34 200 Rodbergite
F1 3 1970 6,80 11,40 500 220 700 1800 150 19 110 Damtjernite some hem, mag, ilm?
F1 4 1970 11,40 12,70 600 220 800 2100 110 29 140 Rodbergite
F1 1970 12,70 16,00 1000 Damtjernite
F1 5 1970 16,00 18,00 270 1100 2800 170 37 170 Rodbergite, partly eroded. Brecciated
F1 6 1970 18,00 21,20 1000 330 1600 4600 310 70 360 Rodbergite
F1 7 1970 21,20 25,20 1300 220 2200 6300 270 63 340 Carb, impure. Minor hem first 0,5 m. Brecciated
F1 8 1970 25,20 30,30 800 240 2000 5800 230 57 340 Carb, minor section w/ red spots.
F1 9 1970 30,30 35,20 800 220 1500 4100 190 40 200 Carb, partly impure. Brecciastructure
F1 10 1970 35,20 39,20 1000 250 2100 5400 280 55 290 Carb, breccia structure
F1 11 1970 39,20 42,90 900 230 1900 5000 300 54 270 Carb, partially strongly brecciated
F1 12 1970 42,90 47,90 700 240 1600 4500 220 48 250 Carb w/ brecciastructure. Spotted red last 0,5 m
F1 13 1970 47,90 48,10 1100 250 2100 5400 290 51 320 Rodbergite
F1 1970 48,10 54,80 Carb w/ brecciastructure
F1 14 1970 54,80 57,00 900 240 1900 4400 240 64 260 Rodbergite
F1 15 1970 57,00 60,55 700 130 1100 3100 180 35 160 Carbonatite
F1 16 1970 60,55 65,60 1600 250 7800 10000 320 61 440 Carbonatite
F1 17 1970 65,60 70,00 1100 190 6900 12500 210 37 500 Carbonatite
F1 18 1970 70,00 75,40 1100 320 2000 5400 400 66 350 Carbonatite
F1 19 1970 75,40 80,20 900 210 1700 4600 250 51 240 Carbonatite
F1 20 1970 80,20 85,00 600 160 1000 2400 140 26 140 Carbonatite
F1 21 1970 85,00 89,90 400 150 400 1200 110 21 70 Carbonatite
F1 22 1970 89,90 94,80 800 210 1300 3900 150 36 200 Carbonatite
Table B4 of B12.
Page 35 of 47
DH ID Sample ID Year From [m] To [m]Density
[g/cm3]Th [ppm] Y [ppm] La [ppm] Ce [ppm] Sm [ppm] Eu [ppm] Gd [ppm] Yb [ppm] Rock type
F1 23 1970 94,80 99,10 600 200 1500 4300 180 37 230 Carbonatite
F1 24 1970 99,10 103,20 700 240 1700 5200 210 44 280 Carbonatite
F1 25 1970 103,20 109,90 1300 350 1200 4100 290 74 280 Rodbergite
F1 26 1970 109,90 114,00 900 230 1500 5000 250 51 310 Rodbergite
F1 27 1970 114,00 119,40 800 150 1600 5800 200 44 330 Rodbergite
F1 28 1970 119,40 125,00 1000 130 2600 8900 270 56 440 Rodbergite
F1 29 1970 125,00 130,10 800 210 2200 7000 270 60 370 Rodbergite
F1 30 1970 130,10 135,50 900 260 2600 7200 270 65 370 Rodbergite
F1 31 1970 135,50 140,80 700 300 2300 6500 300 80 400 Rodbergite
F1 32 1970 140,80 145,80 600 300 2300 6400 320 89 380 Rodbergite
F1 33 1970 145,80 149,90 900 400 3200 7700 340 46 360 Rodbergite
F1 34 1970 149,90 154,30 900 250 2600 7200 250 52 370 Carbonatite, minor sulphides and hematite red colouring.
F1 35 1970 154,30 157,40 700 300 2600 7800 210 49 390 Rodbergite, rotten
F1 36 1970 157,40 162,70 900 270 3200 7800 210 48 350 Rodbergite, grey weak hematite impregnation
F1 37 1970 162,70 167,50 700 230 3100 7200 190 43 340 Rodbergite, some massive hematite
F1 38 1970 167,50 170,60 600 240 2400 5200 130 27 230 Carbonatite, light grey
F1 39 1970 170,60 174,40 400 270 1500 4400 150 41 200 Rodbergite, partly w/ massive hematite
F1 40 1970 174,40 177,60 400 150 2500 7000 220 42 350 Rodbergite, partly w/ massive hematite
F1 41 1970 177,60 182,10 600 230 2700 7000 200 45 360 Carbonatite, red spots of hematite
F1 42 1970 182,10 187,80 800 220 2900 7200 180 43 320 Carbonatite
F1 43 1970 187,80 192,30 800 170 2300 5600 160 32 270 Carbonatite
F1 44 1970 192,30 196,50 900 340 2000 5200 180 44 260 Carbonatite, impure, some rodbergite
F1 45 1970 196,50 201,00 400 170 1200 3100 130 29 140 Carbonatite
F1 46 1970 201,00 206,65 300 300 1100 3000 140 31 130 Carbonatite
F1 47 1970 206,65 212,00 600 410 2000 4700 170 39 220 Carbonatite
F1 48 1970 212,00 216,60 400 210 1500 4600 210 45 320 Rodbergite, weak hematite impregnation
F1 49 1970 216,60 217,60 500 180 1700 4100 140 32 230 Carbonatite
F1 50 1970 217,60 219,20 400 140 2600 7200 200 49 440 Rodbergite
F1 51 1970 219,20 223,10 900 300 2700 7000 210 62 390 Carbonatite, grading out of rodbergite
F1 52 1970 223,10 228,70 500 230 2000 5200 160 37 280 Carbonatite
F1 53 1970 228,70 234,30 600 240 2400 6000 170 44 300 Carbonatite
F1 54 1970 234,30 239,00 900 260 1900 4900 220 59 270 Carbonatite, minor red colouring due to hematite
F1 55 1970 239,00 244,00 600 160 1500 3900 130 27 230 Carbonatite
F1 56 1970 244,00 251,10 600 150 1700 4400 130 28 170 Carbonatite
F2 1 1970 0,00 2,40 1300 240 2900 7300 290 70 410 Carbonatite, rotten. Minor hematite.
F2 2 1970 2,40 5,90 900 160 2000 5000 220 54 290 Carbonatite, rotten. Minor hematite.
F2 3 1970 5,90 9,30 900 180 2400 5900 230 51 330 Carbonatite
F2 4 1970 9,30 11,40 500 180 800 2100 150 29 150 Carbonatite
F2 5 1970 11,40 13,70 1100 220 2400 7000 330 73 450 Carbonatite, magnetite from 11,5-11,85
F2 6 1970 13,70 18,80 1000 190 2100 5100 240 52 280 Carbonatite, cloudy magnetite
F2 7 1970 18,80 23,80 1000 240 3500 8200 300 70 420 Carbonatite, partly rotten w/ mag and sulphides
F2 8 1970 23,80 28,20 1300 310 2300 5900 280 60 340 Carbonatite, partly rotten w/ mag and sulphides
Table B5 of B12.
Page 36 of 47
DH ID Sample ID Year From [m] To [m]Density
[g/cm3]Th [ppm] Y [ppm] La [ppm] Ce [ppm] Sm [ppm] Eu [ppm] Gd [ppm] Yb [ppm] Rock type
F2 9 1970 28,20 33,60 1400 270 2700 7000 330 77 400 Carbonatite, partly rotten w/ mag and sulphides
F2 10 1970 33,60 38,00 1000 200 3000 7100 220 60 330 Carbonatite, partly rotten w/ mag and sulphides
F2 11 1970 38,00 42,60 900 170 2400 5800 170 43 280 Carbonatite, minor mag
F2 12 1970 42,60 47,10 1200 190 2000 5300 320 70 320 Carbonatite
F2 13 1970 47,10 51,70 1000 170 2100 5100 230 50 290 Carbonatite, minor mag
F2 14 1970 51,70 56,70 800 180 2200 5200 200 55 270 Carbonatite, minor mag
F2 15 1970 56,70 60,70 900 160 3600 8300 230 66 370 Carbonatite, minor mag.
F2 16 1970 60,70 65,80 800 180 2700 6600 250 54 350 Carbonatite, minor mag, sulphides and fluorite
F2 17 1970 65,80 70,00 900 170 2600 6500 210 52 320 Carbonatite, minor mag+sulphides in rosettes
F2 18 1970 70,00 74,30 900 160 2400 6000 240 54 290 Carbonatite, partly rotten w/ mag and sulphides
F2 19 1970 74,30 80,30 900 200 2600 6200 220 46 290 Carbonatite
F2 20 1970 80,30 85,30 1200 320 4300 10000 280 77 500 Carbonatite, minor mag and sulphides
F2 21 1970 85,30 89,50 1100 240 2400 5900 240 66 310 Carbonatite
F2 22 1970 89,50 92,50 800 190 2700 7200 320 62 410 Carbonatite, some sections rich in mag
F2 23 1970 92,50 98,20 800 170 2100 5400 220 45 280 Carbonatite
F2 24 1970 98,20 100,00 500 90 1600 4500 280 48 270 Carbonatite, rich in mag as clouds
F2 25 1970 100,00 105,85 900 140 1800 4700 220 54 250 Carbonatite, rich in mag
F2 26 1970 105,85 110,25 1000 170 2100 5200 240 53 280 Carbonatite
F2 27 1970 110,25 115,65 900 100 2800 6800 230 57 310 Carbonatite
F2 28 1970 115,65 120,65 900 130 2800 6800 270 50 310 Carbonatite
F2 29 1970 120,65 126,05 1100 190 2900 7600 270 73 370 Carbonatite, minor red hem spots, mag and sulphides.
F2 30 1970 126,05 131,15 1100 190 4200 10000 290 72 450 Carbonatite
F2 31 1970 131,15 136,65 900 150 2000 4900 200 50 240 Carbonatite, partly impure and brecciated
F2 32 1970 136,65 140,05 1000 250 2000 5000 220 61 280 Carbonatite, partly impure and brecciated
F2 33 1970 140,05 145,55 1300 210 2200 5400 220 62 290 Carbonatite, partly impure and brecciated
F2 34 1970 145,55 148,20 800 170 800 2200 120 29 180
Carbonatite, partly hematite spotted. Possible diabase as
well ?
F2 35 1970 148,20 152,15 900 180 1300 3600 190 44 230 Carbonatite
F2 36 1970 152,15 157,25 900 150 1800 4500 170 45 260 Carbonatite
F2 37 1970 157,25 162,25 900 260 1900 4900 260 61 300 Carbonatite, breccia structure
F2 38 1970 162,25 167,95 800 180 1800 4600 240 55 250 Carbonatite, breccia structure
F2 39 1970 167,95 173,35 900 170 2600 6600 290 65 340 Carbonatite, impure. Weak breccia structure
F2 40 1970 173,35 178,75 1000 200 2100 5600 210 46 330 Carbonatite, impure. Weak breccia structure
F2 41 1970 178,75 183,25 1200 240 2600 6600 270 59 370 Carbonatite, impure. Weak breccia structure
F2 42 1970 183,25 186,60 1000 180 1900 5100 180 41 290 Carbonatite, impure. Weak breccia structure
F2 43 1970 186,60 188,15 400 110 800 2000 70 12 110 Carbonatite, coarse secondary fracturing
F2 44 1970 188,15 192,75 600 280 1000 2600 150 40 180 Mix of carbonatite, damtjernite and basic rocks ?
F2 45 1970 192,75 195,45 600 230 1300 3700 180 37 230 Mix of carbonatite, damtjernite and basic rocks ?
F3 1 1970 0,00 5,00 1700 230 1900 6700 340 68 370 Rodbergite, broken. 2m core loss.
F3 2 1970 5,00 8,80 1100 150 1500 5100 410 56 360 Rodbergite, dark carbonate bands. Partly rotten.
F3 3 1970 8,80 12,50 1500 310 3800 12000 340 79 630 Rodbergite, weak brecciastructure
F3 4 1970 12,50 16,90 1100 460 1900 6000 250 58 380 Rodbergite, brecciastructure. Partly rotten.
F3 5 1970 16,90 21,30 1000 340 2000 6400 270 65 360 Rodbergite, brecciated
Table B6 of B12.
Page 37 of 47
DH ID Sample ID Year From [m] To [m]Density
[g/cm3]Th [ppm] Y [ppm] La [ppm] Ce [ppm] Sm [ppm] Eu [ppm] Gd [ppm] Yb [ppm] Rock type
F3 6 1970 21,30 24,10 1300 460 2500 8100 270 73 450 Rodbergite, weathered
F3 7 1970 24,10 26,60 1200 240 4300 13400 450 71 690 Rodbergite, dark, brecciated and rotten
F3 8 1970 26,60 31,00 1900 620 2100 6900 280 80 490 Rodbergite, light. Breccia structure. Somwhat rotten.
F3 9 1970 31,00 36,10 830 230 930 2600 180 35 180 Carbonatite, impure. Some rodbergite, breccia structure.
F3 10 1970 36,10 41,00 630 150 750 1900 100 27 120 Robergite, carbonate veins, breccia structure
F3 11 1970 41,00 47,00 1100 260 2900 7200 210 25 340 Robergite, carbonate veins, breccia structure
F3 12 1970 47,00 53,70 550 130 1100 3100 160 26 180 Carbonatite, strongly fractured w/ cav ities
F3 13 1970 53,70 58,10 1300 120 1200 3700 300 43 250 Robergite, iron rich
F3 14 1970 58,10 63,80 700 110 950 3100 240 33 230 Robergite, iron rich
T 11 1 60 130 10 22 90 Soev ite
T 11 3 30 70 10 10 60 Soev ite
T 11 6 44 170 10 19 50 Soev ite
T 11 9 40 150 10 17 50 Soev ite
T 11 12 40 130 10 20 50 Soev ite
T 11 15 38 220 10 20 50 Soev ite
T 11 18 60 390 10 25 50 Soev ite and hollaite
T 11 21 30 120 10 14 50 Soev ite
T 11 24 30 120 10 15 50 Soev ite
T 11 27 64 130 10 19 50 Soev ite
T 11 30 40 130 10 18 50 Soev ite
T 11 33 70 290 40 24 50 Hollaite
T 11 36 70 160 35 19 50 Hollaite
T 11 39 60 150 20 21 50 Hollaite
T 11 42 50 280 50 27 50 Hollaite
T 11 45 60 130 40 21 50 Hollaite
T 11 48 30 150 15 21 50 Hollaite
T 11 51 70 430 65 27 50 Hollaite
T 11 54 45 240 25 18 50 Hollaite
T 11 57 30 150 20 18 50 Hollaite
T 11 60 45 130 20 21 50 Hollaite
T 11 63 15 140 30 14 50 Hollaite
T 11 66 45 150 90 42 50 Hollaite
T 11 69 20 140 30 10 50 Hollaite
T 11 72 25 130 20 10 50 Soev ite
T 11 75 45 380 65 27 50 Soev ite and hollaite
T 11 79 50 110 25 22 50 Hollaite
T 11 82 22 70 20 16 50 Hollaite
T 11 85 40 240 10 19 50 Hollaite
T 12 1 1968 (re-sampled) 70 360 40 20 50 Soev ite
T 12 4 1968 (re-sampled) 60 310 75 20 50 Rodbergite
T 12 7 1968 (re-sampled) 90 420 130 40 75 Soev ite
T 12 10 1968 (re-sampled) 55 370 60 20 50 Soev ite
Table B7 of B12.
Page 38 of 47
DH ID Sample ID Year From [m] To [m]Density
[g/cm3]Th [ppm] Y [ppm] La [ppm] Ce [ppm] Sm [ppm] Eu [ppm] Gd [ppm] Yb [ppm] Rock type
T 12 13 1968 (re-sampled) 70 840 35 20 50 Soev ite
T 12 18 1968 (re-sampled) 100 2240 75 25 50 Soev ite
T 12 20 1968 (re-sampled) 120 490 90 30 50 Soev ite
T 12 24 1968 (re-sampled) 110 350 50 15 50 Soev ite
T 12 27 1968 (re-sampled) 110 700 55 15 50 Soev ite
T 12 31 1968 (re-sampled) 90 240 35 15 50 Soev ite
T 12 32 1968 (re-sampled) 75 360 70 20 50 Soev ite
T 12 33 1968 (re-sampled) 80 530 70 20 50 Soev ite
T 12 34 1968 (re-sampled) 80 330 35 20 50 Soev ite
T 12 35 1968 (re-sampled) 55 250 50 15 50 Soev ite
T 12 36 1968 (re-sampled) 150 350 70 20 50 Soev ite
T 12 37 1968 (re-sampled) 60 230 30 15 50 Soev ite
T 12 38 1968 (re-sampled) 75 240 40 15 50 Soev ite
T 12 39 1968 (re-sampled) 90 770 80 25 50 Soev ite
T 12 40 1968 (re-sampled) 85 450 65 35 50 Soev ite
T 12 41 1968 (re-sampled) 40 1440 60 15 50 Hollaite
T 12 42 1968 (re-sampled) 40 410 85 20 50 Soev ite
T 12 43 1968 (re-sampled) 70 530 120 35 50 Breccia in carbonatite
T 12 44 1968 (re-sampled) 75 580 85 35 50 Breccia in carbonatite
T 12 45 1968 (re-sampled) 30 580 90 25 50 Soev ite
T 13 2 1968 (re-sampled) 90 700 120 40 50 Rodbergite
T 13 5 1968 (re-sampled) 45 160 30 10 50 Soev ite
T 13 8 1968 (re-sampled) 40 170 30 10 50 Soev ite
T 13 10 1968 (re-sampled) 60 320 65 20 50 Soev ite
T 13 14 1968 (re-sampled) 75 560 70 20 50 Soev ite
T 13 17 1968 (re-sampled) 70 520 35 15 50 Soev ite
T 13 21 1968 (re-sampled) 75 380 60 20 50 Soev ite
T 13 23 1968 (re-sampled) 75 480 45 15 50 Soev ite
T 13 26 1968 (re-sampled) 80 500 80 20 50 Soev ite
T 13 30 1968 (re-sampled) 85 360 65 25 50 Soev ite and Hollaite
T 13 31 1968 (re-sampled) 50 400 45 20 50 Soev ite
T 13 32 1968 (re-sampled) 40 260 55 15 50 Soev ite
T 13 33 1968 (re-sampled) 55 280 80 15 50 Soev ite
T 13 34 1968 (re-sampled) 70 310 50 20 50 Soev ite
T 13 35 1968 (re-sampled) 75 240 50 20 50 Soev ite and Hollaite
T 13 36 1968 (re-sampled) 90 380 50 20 50 Soev ite and Hollaite
T 13 37 1968 (re-sampled) 60 260 40 15 50 Soev ite
T 13 38 1968 (re-sampled) 70 300 65 20 50 Soev ite
T 13 39 1968 (re-sampled) 60 320 75 20 50 Soev ite
T 13 40 1968 (re-sampled) 45 1350 85 20 50 Soev ite
T 13 42 1968 (re-sampled) 65 630 65 20 50 Soev ite
T 13 45 1968 (re-sampled) 80 1370 210 40 50 Soev ite
T 13 48 1968 (re-sampled) 50 700 85 15 50 Soev ite
Table B8 of B12.
Page 39 of 47
DH ID Sample ID Year From [m] To [m]Density
[g/cm3]Th [ppm] Y [ppm] La [ppm] Ce [ppm] Sm [ppm] Eu [ppm] Gd [ppm] Yb [ppm] Rock type
T 14 1 1968 (re-sampled) 210 380 60 25 50 Soevite
T 14 3 1968 (re-sampled) 95 3000 85 50 50 Soevite
T 14 5 1968 (re-sampled) 50 860 85 50 50 Hollaite
T 14 7 1968 (re-sampled) 70 1340 55 35 50 Soevite
T 14 10 1968 (re-sampled) 120 920 100 45 50 Soevite
T 14 13 1968 (re-sampled) 85 500 70 30 50 Soevite
T 14 14 1968 (re-sampled) 60 700 75 30 50 Soevite
T 14 15 1968 (re-sampled) 65 680 90 30 50 Soevite
T 14 16 1968 (re-sampled) 80 900 80 35 50 Soevite
T 14 17 1968 (re-sampled) 60 490 60 30 50 Soevite
T 14 20 1968 (re-sampled) 110 570 110 35 50 Soevite
T 14 23 1968 (re-sampled) 85 750 85 40 50 Soevite
T 14 26 1968 (re-sampled) 60 520 100 35 50 Soevite
T 14 29 1968 (re-sampled) 80 590 120 40 50 Soevite
T 14 33 1968 (re-sampled) 70 1160 90 40 50 Soevite
T 14 34 1968 (re-sampled) 90 330 85 40 50 Rodbergite
T 14 35 1968 (re-sampled) 35 280 45 25 50 Soevite
T 14 38 1968 (re-sampled) 80 2360 130 40 50 Soevite
T 14 41 1968 (re-sampled) 65 840 90 30 50 Soevite
T 14 44 1968 (re-sampled) 70 750 90 30 50 Soevite
T 14 47 1968 (re-sampled) 55 540 85 30 50 Soevite
T 14 48 1968 (re-sampled) 100 680 85 30 50 Soevite
T 14 49 1968 (re-sampled) 70 1020 75 30 50 Soevite
T 14 52 1968 (re-sampled) 75 1060 110 35 50 Soevite
T 14 53 1968 (re-sampled) 70 600 70 30 50 Rodbergite
T 14 54 1968 (re-sampled) 50 420 70 20 50 Soevite
T 14 59 1968 (re-sampled) 55 470 70 50 50 Soevite
T 14 61 1968 (re-sampled) 70 470 80 20 50 Soevite
T 16 6 42 880 50 24 50 Soevite
T 16 10 15 7720 150 73 50 Soevite
T 16 13 34 860 50 29 50 Soevite
T 16 16 38 540 10 25 50 Soevite
T 16 19 42 1780 110 52 50 Soevite
T 16 22 10 1740 100 43 50 Soevite
T 16 25 20 1640 130 52 50 Soevite
T 16 28 18 2180 50 30 50 Soevite
T 16 31 10 1660 60 28 50 Soevite
T 16 34 10 1200 10 24 50 Breccia in soev ite
T 16 37 35 460 30 30 50 Soevite
T 16 40 45 1010 30 38 50 Soevite
T 16 43 28 940 60 19 50 Soevite
T 16 46 36 260 10 18 50 Soevite
Table B9 of B12.
Page 40 of 47
DH ID Sample ID Year From [m] To [m]Density
[g/cm3]Th [ppm] Y [ppm] La [ppm] Ce [ppm] Sm [ppm] Eu [ppm] Gd [ppm] Yb [ppm] Rock type
T 16 49 48 250 40 31 50 Soev ite
T 16 52 38 330 45 35 50 Hollaite
T 16 55 38 160 40 34 50 Soev ite
T 16 58 30 1660 160 69 50 Soev ite
T 16 61 72 580 30 33 50 Soev ite
T 16 64 72 680 10 32 50 Soev ite
T 16 67 56 500 20 30 50 Soev ite
T 16 70 180 400 40 33 80 Hollaite
T 18 1 42 210 10 18 50 Soev ite
T 18 3 52 380 10 23 50 Soev ite and hollaite
T 18 6 36 310 10 17 50 Soev ite
T 18 9 40 230 10 24 50 Soev ite
T 18 12 54 240 10 25 50 Soev ite
T 18 15 64 340 10 20 50 Soev ite
T 18 18 56 250 10 17 50 Soev ite
T 18 21 40 210 10 18 50 Soev ite
T 18 24 21 100 10 10 50 Soev ite
T 18 27 20 140 10 15 50 Soev ite
T 18 30 44 280 10 23 50 Hollaite
T 18 34 120 240 20 35 70 Soev ite
T 18 36 56 220 35 32 50 Soev ite
T 18 40 58 160 10 20 50 Soev ite
T 18 45 40 270 10 23 50 Soev ite
T 18 48 40 150 10 18 50 Soev ite
T 18 51 47 190 10 18 50 Soev ite
T 18 54 40 180 10 18 50 Soev ite
T 18 57 35 130 10 18 50 Soev ite
T 18 60 60 170 10 14 50 Hollaite
T 18 63 65 200 40 22 50 Hollaite
T 21 1 10 4300 40 37 50 Soev ite
T 21 3 16 7400 100 55 50 Soev ite
T 21 6 34 6080 140 57 50 Soev ite
T 21 9 10 7360 80 40 50 Soev ite
T 21 12 10 6800 70 36 50 Soev ite
T 21 15 10 4880 90 32 50 Rodbergite
T 21 18 10 2300 80 23 50 Rodbergite
T 21 21 10 2400 130 31 50 Rodbergite
T 21 24 10 4680 60 40 50 Soev ite
T 21 27 10 3140 50 24 50 Soev ite
T 21 30 46 5600 30 42 50 Soev ite
T 21 33 16 1600 30 22 50 Soev ite
T 21 36 70 460 10 27 50 Soev ite
Table B10 of B12.
Page 41 of 47
DH ID Sample ID Year From [m] To [m]Density
[g/cm3]Th [ppm] Y [ppm] La [ppm] Ce [ppm] Sm [ppm] Eu [ppm] Gd [ppm] Yb [ppm] Rock type
T 21 39 28 1060 30 24 50 Soevite
T 21 42 44 4440 110 62 50 Soevite
T 21 45 10 1800 90 37 50 Rodbergite
T 21 48 15 1380 50 33 50 Rodbergite
T 23 1 70 360 60 33 50 Soevite
T 23 3 36 270 50 26 50 Soevite
T 23 6 44 240 20 25 50 Soevite
T 23 9 36 540 20 35 50 Soevite
T 23 12 58 3520 30 49 50 Soevite
T 23 15 40 3630 90 38 50 Rodbergite
T 23 18 62 940 110 46 50 Rodbergite
T 23 21 22 570 70 40 50 Rodbergite
T 23 26 15 700 160 52 50 Rodbergite
T 23 29 22 450 90 43 50 Rodbergite
T 23 32 15 490 150 49 50 Rodbergite
T 23 35 35 540 120 41 50 Soevite
T 23 39 18 790 100 52 50 Soevite
T 23 42 10 850 65 38 50 Soevite
T 23 45 25 940 55 33 50 Soevite
T 23 48 10 1460 90 40 50 Soevite
T 23 51 16 1920 70 49 50 Soevite
T 9 1 90 100 45 21 50 Soevite
T 9 5 85 490 40 23 50 Soevite and Hollaite
T 9 10 56 180 20 20 50 Soevite and Hollaite
T 9 13 20 150 10 12 50 Soevite and rodbergite
T 9 16 42 250 10 16 50 Soevite
T 9 19 35 250 10 19 50 Soevite
T 9 22 62 100 20 10 50 Soevite and hollaite
T 9 25 46 200 10 18 50 Soevite and hollaite
T 9 29 55 200 25 14 60 Soevite
T 9 33 88 140 20 10 50 Hollaite
T 9 36 45 270 25 22 50 Soevite
T 9 40 85 120 25 10 50 Hollaite
T 9 44 55 160 20 15 50 Soevite
T 9 47 58 190 35 21 50 Hollaite
T 9 50 64 280 10 22 50 Soevite and hollaite
T 9 54 55 150 15 19 50 Soevite
Ts 7 1 25 90 170 18 50
Ts 7 2 40 110 10 23 50
Ts 7 3 50 100 20 24 50
Ts 7 4 48 140 10 16 50
Ts 7 5 46 100 15 10 50
Table B11 of B12.
Page 42 of 47
DH ID Sample ID Year From [m] To [m]Density
[g/cm3]Th [ppm] Y [ppm] La [ppm] Ce [ppm] Sm [ppm] Eu [ppm] Gd [ppm] Yb [ppm] Rock type
Ts 7 6 48 110 10 10 50
Ts 7 7 40 190 15 18 50
Ts 7 8 38 210 10 15 50
Ts 7 9 36 180 15 13 50
Ts 7 10 48 60 20 10 50
Ts 7 11 40 140 10 16 50
Ts 7 12 86 140 15 14 50
Ts 7 13 45 120 10 17 50
Ts 7 14 45 130 10 10 50
Ts 7 15 45 120 10 19 50
Ts 7 16 48 30 10 10 50
Ts 7 17 40 110 15 21 50
Ts 7 18 35 220 65 25 50
Ts 7 19 55 160 20 25 50
Ts 7 20 52 170 35 10 50
Ts 7 21 50 150 15 10 50
Ts 7 22 55 140 210 16 50
Ts 7 23 45 1400 25 15 50
Ts 7 24 52 150 10 13 50
Ts 7 25 75 170 20 15 50
Table B12 of B12.
Page 43 of 47
THE FEN CARBONATITE COMPLEX,
ULEFOSS, SOUTH NORWAY
Summary of historic work and data
Compiled and prepared by 21st NORTH, Svendborg 12 May 2011 in commission for REE Minerals, Norway
Appendix C
Radiometry and rock sample anomaly maps
Page 44 of 47
Fig. C1 of C4. Aerial photo
of the Soeve-Gruveåsen
region with REE anomaly
pattern for NGU samples
collected between 1967
and 1970.
Page 45 of 47
Fig. C2 of C4. Aerial photo of
the Soeve-Gruveåsen area
draped by thorium levels based
on the 2006 NGU radiometric
survey and REE anomaly
pattern for NGU samples
collected between 1967 and
1970.
Page 46 of 47
C3 of C4. Close-up of the Gruveåsen area including thorium levels and rock samples collected by the NGU from 1967 to 1970.
Page 47 of 47
C4 of C4. Close-up of the Rauhaug-Vibeto area including thorium levels and rock samples collected by the NGU from 1967 to 1970.