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Spatsum claim, Cache Creek, Kamloops Mining Division, British Columbia, Canadai
Regional Level Types
Spatsum claimClaim
Cache CreekCreek
Kamloops Mining DivisionDivision
British ColumbiaProvince
CanadaCountry

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Latitude & Longitude (WGS84):
50° 33' 28'' North , 121° 18' 11'' West
Latitude & Longitude (decimal):
50.55778,-121.30306
GeoHash:
G#: c2cxxevb3
GRN:
N34W57
Type:
Claim
KΓΆppen climate type:
Dfb : Warm-summer humid continental climate
Nearest Settlements:
PlacePopulationDistance
Ashcroft1,796 (2013)18.5km
Cache Creek1,061 (2010)28.1km
Nearest Clubs:
Local clubs are the best way to get access to collecting localities
ClubLocationDistance
High Country Rockhound ClubLogan Lake, British Columbia35km
Mindat Locality ID:
483
Long-form identifier:
mindat:1:2:483:2
GUID (UUID V4):
48777e95-90a7-4cc4-91ea-03564d2f85cf


The Spatsum property is located immediately west of Highway 1, across the Fraser River from the old Canadian Pacific Railway station of Spatsum, and the pumping station for water for the Highland Valley copper mine. It is about 26 kilometres south of Cache Creek, or 70 kilometres west of Kamloops, British Columbia, in the Kamloops Mining Division.
There is a description of the property, including regional geology, on the British Columbia β€œMinfile” site, current to 2014. Portions relative to geology are quoted below:
β€œThe Spatsum property covers calcalkaline andesite to rhyolite metavolcanics and related chemical and clastic metasediments. They occur as a north to north-northwest striking, west dipping monoclinal sequence that has been metamorphosed to the mid-greenschist facies. The volcanics and sedimentary units have been locally intruded by diorite, granite, dacite and rhyolite plugs and dikes. Most of the intrusions are thought to be subvolcanic equivalents of the volcanic units. The metavolcanics include primarily andesite, dacite and rhyolite tuffs and tuff breccias and the metasediments consist of thin limestone and chert beds.”
β€œThe most significant mineralization occurs where the rhyolite and locally the dacite units have been variably leached, silicified and pyritized and empregnated [sic - impregnated] with gypsum, trace talc and barite, and very small amounts of chalcopyrite, sphalerite and galena. The mineralized and altered zones are heavily gossaned and pyrite concentrations are difficult to estimate due to the intense surface weathering and leaching. Gypsum occurs in significant concentrations in the zones as massive and/or disseminated clots commonly distributed throughout the altered rhyolite pyroclastics. Two mineralized gypsum-rich zones are about 600 metres apart and stand out prominently as large white masses. The larger and more southerly gypsum outcrop occurs over a strike length of 60 metres and a vertical height of 90 metres and strikes north-northeast with a moderate dip to the northwest. In 1913, an 8-metre exploratory adit was driven at the base of the southerly exposure; from the end of the adit a winze was sunk to a depth of 9 metres. The adit intersected a band of nearly pure white massive gypsum, 1.5 metres wide, which analysed 32.70 per cent CaO, 46.72 per cent SO3, 20.60 per cent H2O and 0.04 per cent insolubles (CANMET Report 714) [Coles, 1930]”.
β€œThe alteration zones, because of the abundance of gypsum, are interpreted to represent a facies which commonly develops adjacent to many base metal-bearing Kuroko-type massive sulphide deposits. It is felt that base metal-bearing massive sulphide concentrations may exist along strike or downdip adjacent to these alteration zones. The only other mineralization observed on the property includes minor disseminated pyrite which occurs locally in some rhyolite units (Assessment Report 6918) [Casselman, 1978]”.

Giles Peatfield comments on History:
The Spatsum property has a long and interesting history. With each phase of work, different minerals were reported, as the thinking about the deposit changed, over almost a century. Hoffmann (1895) described alunogen as a coating on a β€œ. . . somewhat pyritiferous quartzo-feldspathic rock, . . . .”, presumably when he examined specimens collected by G. M. Dawson of the Geological Survey of Canada. Dawson (1896) had described these rocks in some detail, focusing interest on the occurrence of kaolinite, mentioning that the deposit had attracted attention for the occurrence of β€˜china-stone’ or β€˜china-clay’. In his opinion it was not likely that there would be any quantity of this material available free of iron stain. Dawson also noted gypsum, and in fact Government records note that the deposit was staked for gypsum in about 1896, but the claims were then dropped. The deposit was re-staked, probably in 1906, but no production resulted – see Cole (1913, 1930). Little was heard about the property until Jones (1972) described a small program of work, presumably to test the possibility of the occurrence of a copper deposit. The results were disappointing, and no further work was recommended. Following this, Cominco Ltd. explored the property as a potential β€˜Kuroko-style’ volcanogenic massive sulfide prospect – see Casselman (1978, 1980). Several more minerals were noted, but the work did not discover a deposit and there was no further work by the company. Allen Ingelson, then at the Geology Department of the Alberta Provincial Museum in Edmonton made a brief visit to the property and collected a suite of secondary minerals, several of which were unusual – see Ingelson (1984). Of interest is a suspected location error for the occurrence in his paper. The main area of interest is immediately west of the Trans Canada Highway. Ingelson gave the location as being 0.8 km (800 metres) west of the Highway, whereas it is almost exactly 800 metres west of the Canadian Pacific Railway line on the opposite side of the Fraser River. I provide this information for the benefit of future mineral collectors. Finally, Dasler and Smith (1987) described a brief program designed to test the property for the presence of an epithermal precious metal deposit. The results of this work were disappointing and work was not continued.
Giles Peatfield comments on the minerals reported:
Given the number of different workers and the time frame involved, I have chosen to comment on all the minerals so far reported at this property.
Alunite: Reported only by McMullin (1987) in thin section examination of β€˜probably felsic igneous rocks’.
Alunogen: Described by Hoffmann (1895), who wrote that it β€œHas been found in the form of white and faintly yellowish, silky, delicate fibrous masses . . . .” Note that none of the other workers whose work I have studied reported alunogen.
Baryte: Casselman (1978, 1980) reported trace amounts of barite [sic].
Brochantite: Reported by Ingelson (1984) as a β€˜bright green crust grading to blue-green’.
Calcite: Reported only by McMullin (1987) in thin section examination of a β€˜probably more mafic’ rock.
Chalcoalumite: Reported by Ingelson (1984) as a β€˜light blue botryoidal crust’.
Chalcopyrite: Reported in trace amounts by Jones (1972) and Casselman (1978, 1980).
Chlorite: Reported only by McMullin (1987) in thin section examination of a β€˜probably more mafic’ rock.
Copiapite : Reported by Ingelson (1984) to be β€˜yellow, crystalline, quite abundant’.
Coquimbite : Reported by Ingelson (1984) to be β€˜mauve, crystalline, rare’.
Epidote: Reported by Casselman (1980) in percussion drill cuttings, and by McMullin (1987) in thin section examination of a β€˜probably more mafic’ rock.
Galena: Trace amounts were reported by Casselman (1980).
Gypsum: Reported by almost all workers. See especially Cole (1913). Ingelson (1984) reported that some of the gypsum is variety selenite.
Halotrichite: Reported by Ingelson (1984) as a β€˜white fibrous aggregate, quite abundant’.
Hematite: Reported only by McMullin (1987) in thin section examination of various rocks.
Hexahydrite: Reported by Ingelson (1984) as β€˜amber, waxy, associated with rozenite’.
Jarosite: Reported only by McMullin (1987) in thin section examination of various rocks.
Kaolinite: Reported only by Dawson (1895), as possible β€˜china-clay’.
Limonite: Cole (1913) noted β€˜iron-oxide’, and McMullin (1987) described limonite in thin sections.
Magnetite: Casselman (1980) reported trace amounts of magnetite in percussion drill cuttings.
Pyrite: Reported by most workers, although not in large amounts.
RΓΆmerite: Reported by Ingelson (1984) as a β€˜reddish orange aggregate’.
Rozenite: Reported by Ingelson (1984) as β€˜dull white nodules’.
Quartz: Reported by most workers.
Sericite: Reported by several workers, including Ingelson (1984).
Sphalerite: Reported in trace amounts by Casselamn (1978, 1980).
Sulfur: Reported as β€˜common’ by Jones (1972) and by Casselman (1980).
Talc: Reported by Jones (1972) and by Casselman (1978, 1980).
Note also that McMullin (1987) reported β€˜leuxocene’ in thin section, although this is not a valid
Giles Peatfield comments on the rock types reported:
All these rock types, based on field identifications, were reported by Casselman (1978).


Ref.: Palache, C., Berman, H., & Frondel, C. (1951), The System of Mineralogy of James Dwight Dana and Edward Salisbury Dana, Yale University 1837-1892, Volume II: 539.

Select Mineral List Type

Standard Detailed Gallery Strunz Chemical Elements

Mineral List


26 valid minerals.

Rock Types Recorded

Note: data is currently VERY limited. Please bear with us while we work towards adding this information!

Select Rock List Type

Alphabetical List Tree Diagram

Detailed Mineral List:

β“˜ Alunite
Formula: KAl3(SO4)2(OH)6
β“˜ Alunogen
Formula: Al2(SO4)3 · 17H2O
Description: Occurs as fibrous masses.
β“˜ Baryte
Formula: BaSO4
β“˜ Brochantite
Formula: Cu4(SO4)(OH)6
β“˜ Calcite
Formula: CaCO3
β“˜ Chalcoalumite
Formula: CuAl4(SO4)(OH)12 · 3H2O
β“˜ Chalcopyrite
Formula: CuFeS2
β“˜ 'Chlorite Group'
β“˜ Copiapite
Formula: Fe2+Fe3+4(SO4)6(OH)2 · 20H2O
β“˜ Coquimbite
Formula: AlFe3(SO4)6(H2O)12 · 6H2O
β“˜ Epidote
Formula: (CaCa)(AlAlFe3+)O[Si2O7][SiO4](OH)
β“˜ Galena
Formula: PbS
β“˜ Gypsum
Formula: CaSO4 · 2H2O
β“˜ Halotrichite
Formula: FeAl2(SO4)4 · 22H2O
β“˜ Hematite
Formula: Fe2O3
β“˜ Hexahydrite
Formula: MgSO4 · 6H2O
β“˜ Jarosite
Formula: KFe3+3(SO4)2(OH)6
β“˜ Kaolinite
Formula: Al2(Si2O5)(OH)4
β“˜ 'Leucoxene'
β“˜ 'Limonite'
β“˜ Magnetite
Formula: Fe2+Fe3+2O4
β“˜ Muscovite
Formula: KAl2(AlSi3O10)(OH)2
β“˜ Muscovite var. Sericite
Formula: KAl2(AlSi3O10)(OH)2
β“˜ Pyrite
Formula: FeS2
β“˜ Quartz
Formula: SiO2
β“˜ RΓΆmerite
Formula: Fe2+Fe3+2(SO4)4 · 14H2O
β“˜ Rozenite
Formula: FeSO4 · 4H2O
β“˜ Sphalerite
Formula: ZnS
β“˜ Sulphur
Formula: S8
β“˜ Talc
Formula: Mg3Si4O10(OH)2

Gallery:

List of minerals arranged by Strunz 10th Edition classification

Group 1 - Elements
β“˜Sulphur1.CC.05S8
Group 2 - Sulphides and Sulfosalts
β“˜Sphalerite2.CB.05aZnS
β“˜Chalcopyrite2.CB.10aCuFeS2
β“˜Galena2.CD.10PbS
β“˜Pyrite2.EB.05aFeS2
Group 4 - Oxides and Hydroxides
β“˜Magnetite4.BB.05Fe2+Fe3+2O4
β“˜Hematite4.CB.05Fe2O3
β“˜Quartz4.DA.05SiO2
Group 5 - Nitrates and Carbonates
β“˜Calcite5.AB.05CaCO3
Group 7 - Sulphates, Chromates, Molybdates and Tungstates
β“˜Baryte7.AD.35BaSO4
β“˜Brochantite7.BB.25Cu4(SO4)(OH)6
β“˜Alunite7.BC.10KAl3(SO4)2(OH)6
β“˜Jarosite7.BC.10KFe3+3(SO4)2(OH)6
β“˜Rozenite7.CB.15FeSO4 Β· 4H2O
β“˜Hexahydrite7.CB.25MgSO4 Β· 6H2O
β“˜Alunogen7.CB.45Al2(SO4)3 Β· 17H2O
β“˜Coquimbite7.CB.55AlFe3(SO4)6(H2O)12 Β· 6H2O
β“˜RΓΆmerite7.CB.75Fe2+Fe3+2(SO4)4 Β· 14H2O
β“˜Halotrichite7.CB.85FeAl2(SO4)4 Β· 22H2O
β“˜Gypsum7.CD.40CaSO4 Β· 2H2O
β“˜Copiapite7.DB.35Fe2+Fe3+4(SO4)6(OH)2 Β· 20H2O
β“˜Chalcoalumite7.DD.75CuAl4(SO4)(OH)12 Β· 3H2O
Group 9 - Silicates
β“˜Epidote9.BG.05a(CaCa)(AlAlFe3+)O[Si2O7][SiO4](OH)
β“˜Talc9.EC.05Mg3Si4O10(OH)2
β“˜Muscovite9.EC.15KAl2(AlSi3O10)(OH)2
β“˜var. Sericite9.EC.15KAl2(AlSi3O10)(OH)2
β“˜Kaolinite9.ED.05Al2(Si2O5)(OH)4
Unclassified
β“˜'Limonite'-
β“˜'Chlorite Group'-
β“˜'Leucoxene'-

List of minerals for each chemical element

HHydrogen
Hβ“˜ AluniteKAl3(SO4)2(OH)6
Hβ“˜ AlunogenAl2(SO4)3 · 17H2O
Hβ“˜ BrochantiteCu4(SO4)(OH)6
Hβ“˜ ChalcoalumiteCuAl4(SO4)(OH)12 · 3H2O
Hβ“˜ CopiapiteFe2+Fe43+(SO4)6(OH)2 · 20H2O
Hβ“˜ CoquimbiteAlFe3(SO4)6(H2O)12 · 6H2O
Hβ“˜ Epidote(CaCa)(AlAlFe3+)O[Si2O7][SiO4](OH)
Hβ“˜ GypsumCaSO4 · 2H2O
Hβ“˜ HalotrichiteFeAl2(SO4)4 · 22H2O
Hβ“˜ HexahydriteMgSO4 · 6H2O
Hβ“˜ JarositeKFe33+(SO4)2(OH)6
Hβ“˜ KaoliniteAl2(Si2O5)(OH)4
Hβ“˜ MuscoviteKAl2(AlSi3O10)(OH)2
Hβ“˜ RΓΆmeriteFe2+Fe23+(SO4)4 · 14H2O
Hβ“˜ RozeniteFeSO4 · 4H2O
Hβ“˜ TalcMg3Si4O10(OH)2
Hβ“˜ Muscovite var. SericiteKAl2(AlSi3O10)(OH)2
CCarbon
Cβ“˜ CalciteCaCO3
OOxygen
Oβ“˜ AluniteKAl3(SO4)2(OH)6
Oβ“˜ AlunogenAl2(SO4)3 · 17H2O
Oβ“˜ BaryteBaSO4
Oβ“˜ BrochantiteCu4(SO4)(OH)6
Oβ“˜ CalciteCaCO3
Oβ“˜ ChalcoalumiteCuAl4(SO4)(OH)12 · 3H2O
Oβ“˜ CopiapiteFe2+Fe43+(SO4)6(OH)2 · 20H2O
Oβ“˜ CoquimbiteAlFe3(SO4)6(H2O)12 · 6H2O
Oβ“˜ Epidote(CaCa)(AlAlFe3+)O[Si2O7][SiO4](OH)
Oβ“˜ GypsumCaSO4 · 2H2O
Oβ“˜ HalotrichiteFeAl2(SO4)4 · 22H2O
Oβ“˜ HematiteFe2O3
Oβ“˜ HexahydriteMgSO4 · 6H2O
Oβ“˜ JarositeKFe33+(SO4)2(OH)6
Oβ“˜ KaoliniteAl2(Si2O5)(OH)4
Oβ“˜ MagnetiteFe2+Fe23+O4
Oβ“˜ MuscoviteKAl2(AlSi3O10)(OH)2
Oβ“˜ QuartzSiO2
Oβ“˜ RΓΆmeriteFe2+Fe23+(SO4)4 · 14H2O
Oβ“˜ RozeniteFeSO4 · 4H2O
Oβ“˜ TalcMg3Si4O10(OH)2
Oβ“˜ Muscovite var. SericiteKAl2(AlSi3O10)(OH)2
MgMagnesium
Mgβ“˜ HexahydriteMgSO4 · 6H2O
Mgβ“˜ TalcMg3Si4O10(OH)2
AlAluminium
Alβ“˜ AluniteKAl3(SO4)2(OH)6
Alβ“˜ AlunogenAl2(SO4)3 · 17H2O
Alβ“˜ ChalcoalumiteCuAl4(SO4)(OH)12 · 3H2O
Alβ“˜ CoquimbiteAlFe3(SO4)6(H2O)12 · 6H2O
Alβ“˜ Epidote(CaCa)(AlAlFe3+)O[Si2O7][SiO4](OH)
Alβ“˜ HalotrichiteFeAl2(SO4)4 · 22H2O
Alβ“˜ KaoliniteAl2(Si2O5)(OH)4
Alβ“˜ MuscoviteKAl2(AlSi3O10)(OH)2
Alβ“˜ Muscovite var. SericiteKAl2(AlSi3O10)(OH)2
SiSilicon
Siβ“˜ Epidote(CaCa)(AlAlFe3+)O[Si2O7][SiO4](OH)
Siβ“˜ KaoliniteAl2(Si2O5)(OH)4
Siβ“˜ MuscoviteKAl2(AlSi3O10)(OH)2
Siβ“˜ QuartzSiO2
Siβ“˜ TalcMg3Si4O10(OH)2
Siβ“˜ Muscovite var. SericiteKAl2(AlSi3O10)(OH)2
SSulfur
Sβ“˜ AluniteKAl3(SO4)2(OH)6
Sβ“˜ AlunogenAl2(SO4)3 · 17H2O
Sβ“˜ BaryteBaSO4
Sβ“˜ BrochantiteCu4(SO4)(OH)6
Sβ“˜ ChalcopyriteCuFeS2
Sβ“˜ ChalcoalumiteCuAl4(SO4)(OH)12 · 3H2O
Sβ“˜ CopiapiteFe2+Fe43+(SO4)6(OH)2 · 20H2O
Sβ“˜ CoquimbiteAlFe3(SO4)6(H2O)12 · 6H2O
Sβ“˜ GalenaPbS
Sβ“˜ GypsumCaSO4 · 2H2O
Sβ“˜ HalotrichiteFeAl2(SO4)4 · 22H2O
Sβ“˜ HexahydriteMgSO4 · 6H2O
Sβ“˜ JarositeKFe33+(SO4)2(OH)6
Sβ“˜ PyriteFeS2
Sβ“˜ RΓΆmeriteFe2+Fe23+(SO4)4 · 14H2O
Sβ“˜ RozeniteFeSO4 · 4H2O
Sβ“˜ SphaleriteZnS
Sβ“˜ SulphurS8
KPotassium
Kβ“˜ AluniteKAl3(SO4)2(OH)6
Kβ“˜ JarositeKFe33+(SO4)2(OH)6
Kβ“˜ MuscoviteKAl2(AlSi3O10)(OH)2
Kβ“˜ Muscovite var. SericiteKAl2(AlSi3O10)(OH)2
CaCalcium
Caβ“˜ CalciteCaCO3
Caβ“˜ Epidote(CaCa)(AlAlFe3+)O[Si2O7][SiO4](OH)
Caβ“˜ GypsumCaSO4 · 2H2O
FeIron
Feβ“˜ ChalcopyriteCuFeS2
Feβ“˜ CopiapiteFe2+Fe43+(SO4)6(OH)2 · 20H2O
Feβ“˜ CoquimbiteAlFe3(SO4)6(H2O)12 · 6H2O
Feβ“˜ Epidote(CaCa)(AlAlFe3+)O[Si2O7][SiO4](OH)
Feβ“˜ HalotrichiteFeAl2(SO4)4 · 22H2O
Feβ“˜ HematiteFe2O3
Feβ“˜ JarositeKFe33+(SO4)2(OH)6
Feβ“˜ MagnetiteFe2+Fe23+O4
Feβ“˜ PyriteFeS2
Feβ“˜ RΓΆmeriteFe2+Fe23+(SO4)4 · 14H2O
Feβ“˜ RozeniteFeSO4 · 4H2O
CuCopper
Cuβ“˜ BrochantiteCu4(SO4)(OH)6
Cuβ“˜ ChalcopyriteCuFeS2
Cuβ“˜ ChalcoalumiteCuAl4(SO4)(OH)12 · 3H2O
ZnZinc
Znβ“˜ SphaleriteZnS
BaBarium
Baβ“˜ BaryteBaSO4
PbLead
Pbβ“˜ GalenaPbS

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Link to British Columbia Minfile:092INW054

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This page contains all mineral locality references listed on mindat.org. This does not claim to be a complete list. If you know of more minerals from this site, please register so you can add to our database. This locality information is for reference purposes only. You should never attempt to visit any sites listed in mindat.org without first ensuring that you have the permission of the land and/or mineral rights holders for access and that you are aware of all safety precautions necessary.

References

Casselman, M. J. 1978. Assessment Report on the Lofar, Hifar and Sofar Claims, Geology Report, Kamloops Mining Division. British Columbia Mineral Resources Branch Assessment Report 6,918.
Casselman, M. J. 1980. Assessment Report on Percussion Drilling on the Lofar, Lofar 2 and Orion Claims, Kamloops Mining District. British Columbia Mineral Resources Branch Assessment Report 8,263.
Cole, L. H. 1913. Spatsum Deposits, in Gypsum in Canada, Its Occurrence, Exploitation, and Technology. Canada, Department of Mines, Mines Branch, Report 245.
Cole, L. H. 1930. Spatsum Deposits, in The Gypsum Industry of Canada. Canada, Department of Mines, Mines Branch, Report 714.
Dasler, Peter G. and Smith, F. Marshall. 1987. Summary Report on the Tom Property (Tom 1-3 Claims), Kamloops Mining Division. British Columbia Geological Branch Assessment Report 16,963.
Dawson, George M. 1895. Report on the area of the Kamloops Map-Sheet, British Columbia, Report B in Annual Report (New Series) Volume VII, 1894, Geological Survey of Canada, Published 1896, pp. 346B-347B.
Hoffmann, G. Christian. 1895. Mineralogical Notes: 1. – Alunogen, in Chemical Contributions of the Geology of Canada from the Laboratory of the Survey – Report R, in Geological Survey of Canada, Annual Report (New Series) Volume VI, 1892-93, pp. 24R-25R.
Ingelson, Allen. 1984. Spatsum Claim, in Mineral Occurrences in Western Canada. The Mineralogical Record, March-April, 1984, p. 92.
Johnston, R. A. A. 1915. A List of Canadian Mineral Occurrences. Canada, Department of Mines, Geological Survey, Memoir 74, p. 12.
Jones, Harold M. 1972. Geological and Geochemical Report on the Mars Nos. 1 – 8 Mineral Claims. British Columbia Department of Mines and Petroleum Resources, Assessment Report 3,680.
Traill, R.J. 1970. A catalogue of Canadian Minerals. Geological Survey of Canada, Paper 69-45, p. 23.
Traill, R. J. 1983. Catalogue of Canadian Minerals – Revised 1980. Geological Survey of Canada, Paper 80-18, p. 16.
Palache, Charles, Berman, Harry, Frondel, Clifford (1951) The System of Mineralogy (7th ed.) Vol. 2 - Halides, Nitrates, Borates, Carbonates, Sulfates, Phosphates, Arsenates, Tungstates, Molybdates, Ect. John Wiley and Sons, New York.
McMullin, D. W. A. 1987. Vancouver Petrographics Ltd. Petrological report. Appendix I in Dasler and Smith (1987).
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