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Copper Canyon mine, Battle Mountain Mining District, Lander County, Nevada, USAi
Regional Level Types
Copper Canyon mineMine
Battle Mountain Mining DistrictMining District
Lander CountyCounty
NevadaState
USACountry

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PhotosMapsSearch
Latitude & Longitude (WGS84):
40° 32' 54'' North , 117° 7' 57'' West
Latitude & Longitude (decimal):
40.54854,-117.13252
GeoHash:
G#: 9rhwwtdsq
GRN:
N28W64
Type:
Mine
KΓΆppen climate type:
BSk : Cold semi-arid (steppe) climate
Nearest Settlements:
PlacePopulationDistance
Battle Mountain3,635 (2011)19.7km
Golconda214 (2011)54.1km
Mindat Locality ID:
60113
Long-form identifier:
mindat:1:2:60113:0
GUID (UUID V4):
1a0db454-3741-42db-aa54-c82dbf58a164


Sec 27 T31N R43E.

Porphyry copper deposit.
Structure: The Fortitude upper and lower ore zones formed in place and were separated by the north-striking, west-dipping Virgin Fault and a granite porphyry dike intruded along the fault. The Copper Canyon and Virgin Faults acted as conduits for mineralizing hydrothermal fluids emanating from a granodiorite intrusive body and for later dikes emplaced along the same structures. The Dewitt, Golconda and Antler thrust faults coour at depth. The base of the ore at the West Deposit was defined by the Golconda Thrust fault.

Alteration: There is a general zonation of calc-silicate minerals around the intrusion that corresponds to the metal zonation in the skarn deposits. In the copper-gold-skarn zone near the contact, the skarn minerals consist of garnet plus chalcopyrite with relatively minor pyroxene, while farther away from the contact, in the gold-silver zone, skarn ore consists of pyroxene plus pyrrhotite with relatively minor garnet. There is strong silicic, potassic, propylitic, phyllic, and pyritic alteration, especially of the granite porphyry.

Commodity: Ore Materials: gold, electrum, chalcopyrite, pyrrhotite, pyrite, marcasite, arsenopyrite, sphalerite, galena, argentite, bismuthinite, hedleyite, hessite Gangue Materials: garnet (andradite), pyroxene (diopside), tremolite, actinolite, chlorite, epidote, calcite, sphene, biotite, potassium feldspar

Deposit: The East orebody and West orebody were copper-gold skarn deposits located along the north margins of the Copper Canyon granodiorite body, mined in the 1970s. The Fortitude Deposit is a world-class gold-silver skarn deposit that was discovered north of the West orebody in late 1980. The East ore body was within the lower part of the Battle Formation siliceous and calcareous conglomerate, which was altered to quartz, K-feldspar, biotite rock with sulfides distributed throughout. The West ore body was in a garnet skarn surrounded by an envelope of diopside, tremolite-actinolite, and biotite, north of and adjacent to granodiorite contact in Copper Canyon. Total sulfide content (mainly pyrite and pyrrhotite) increased to as much as 75% by volume toward granodiorite contact, with chalcopyrite important closer to the contact. Metal zoning was well developed. The average size of the West ore body was said to be 1,500 m x 600 m x 180 m. The Fortitude Deposit consists of an upper and lower ore zones that formed in place and were separated by the north-striking, west-dipping Virgin Fault and a granite porphyry dike intruded along the fault. The upper ore zone formed in calcareous siltstone and conglomerate of the Battle Formation, and is located east of and in the footwall of the Virgin Fault. The larger, higher grade lower ore zone of the Fortitude deposit formed in limestone of the Antler Peak Formation, located west of and in the hanging wall of the fault. Upper zone ore was discontinuous due to strong structural control and selective sulfide replacement of thin calc-silicate pods or lenses aligned along faults or at fault intersections. The lower zone ore was stratiform and stratabound, elongated NE up to 600 meters long, averaging 150 meters wide and 25-30 meters thick. The lower ore zone ends at a marble front to the north and is cut off to the east by an east-dipping normal fault. To the south, sulfide mineralization continued to the granodiorite contact with diminishing sub-economic grades. In 1992 a low-grade millable orebody of about 500,000 ounces of gold was found between the Fortitude and the West orebodies, called the Fortitude Extension. Although sulfide-bearing rock is continuous from the granodiorite contact on the south to the marble front on the north end of the Fortitude deposit, there is a general zonation of calc-silicate minerals around the intrusion that corresponds to the metal zonation. In the copper-gold-skarn zone near the contact, the skarn minerals consist of garnet plus chalcopyrite with relatively minor pyroxene, while farther away from the contact, in the gold-silver zone, skarn ore consists of pyroxene plus pyrrhotite with relatively minor garnet.

Deposit type: Skarn Au

Development: In 1863, silver was discovered in Galena Canyon and shortly thereafter in 1864, copper and silver were discovered in Copper Canyon with the first development in the district on the Virgin copper vein. The predominantly underground mines produced hand-sorted ore from 1868 through 1875 that was shipped via rail to San Francisco, and thence to smelters in Swansea, Wales. There was a decline in district mining from 1875 to 1900, but in 1909, gold was discovered in Philadelphia Canyon, prompting a rejuvenation of the district. 1916 saw the formation of the Copper Canyon Mining Company, which obtained the main property, discovered new orebodies in the footwall of the Virgin vein and became a major producer of copper from both Copper Canyon and Copper Basin during World War I. In 1936, Copper Canyon Mining Co. discovered a large tonnage of gold-copper orebodies from the surface down to the 300-ft. level. There was intermittent production until World War II when there was another production boom. While the property was under lease to International Smelting and Refining Company in 1941, a 50-ton mill and a 3-compartment vertical shaft were constructed. Copper Canyon Mining Co. later resumed work until a declining copper market forced them to switch to lead-zinc operations in the late 1940s to 1950s. ASARCO did exploration work in the district from 1959 to 1961, when Duval acquired the properties and continued the exploration and development that culminated in the opening of both Copper Canyon and Copper Basin open pit mines in 1967, placing Battle Mountain on the map as one of the largest copper producers in Nevada and the U.S. In 1977, Duval announced plans to phase out copper production in Copper Canyon milling operations because of a severely depressed copper market, while at the same time converting to a gold-producing facility, with the increase in gold prices. Battle Mountain Gold Company took over operations in 1985 and gold took precedence over copper as the primary commodity produced from the district mines through the 1980s and 1990s. The East and West copper-gold skarn orebodies were mined in the 1970s and the world-class Fortitude gold-silver skarn deposit was discovered north of the West orebody in late 1980. After three years of stripping and mining of the lower grade Upper Fortitude ore zone, production from the larger and richer lower Fortitude ore zone began in late 1984, ending in 1993 when reserves were depleted. In 1992, Battle Mountain Gold Company announced that it had outlined a low-grade millable orebody of about 500,000 ounces of gold between the Fortitude and the West orebodies, called the Fortitude Extension. In 2001, Newmont acquired Battle Mountain Gold Company, giving Newmont ownership of the Phoenix property where historic mining has left a halo of lower-grade gold and copper reserves. Gold and copper production is expected to begin at Phoenix in the first half of 2006 The skarn deposits at and near the Fortitude orebody are now part of Newmont?s Phoenix Mine deposit.

Geology: All dated Tertiary intrusive rocks in the Battle Mountain mining district are late Eocene to early Oligocene in age (41 to 31 Ma) and mostly monzogranitic to granodioritic in composition. Although Tertiary intrusive rocks are scattered throughout the mining district as small stocks and dikes, the main exposed Tertiary intrusive centers are in the Copper Canyon, Copper Basin, Elder Creek and Buffalo Valley gold mine areas. Associated with each of these intrusive centers are porphyry-style (Cu-Au and/or Mo-Cu) alteration assemblages, mineralized zones, and related base and precious metal deposits (Doebrich and Theodore, 1996). The Virgin Vein on west side of the ore zone ranges from 4 to 10 feet wide, up to 40 ft. locally. Oxidized ore persists to greater depths along the Virgin Vein than along the Superior Vein, which is more often characterized by primary base-metal sulfides. Detailed pit mapping of the Fortitude deposit showed that a prograde clinopyroxene-garnet skarn assemblage was overprinted by an actinolite-chlorite-epidote retrograde skarn assemblage accompanied by late-stage calcite.

Ore(s): Emplacement of the Granodiorite of Copper Canyon resulted in the development of a large pyritic alteration halo and to the formation of the copper-gold skarn and replacement deposits (West and East orebodies) as well as the gold-silver skarn deposits (Fortitude and Tomboy-Minnie). There is a series of subparallel N-trending fractures and faults.

Select Mineral List Type

Standard Detailed Gallery Strunz Chemical Elements

Commodity List

This is a list of exploitable or exploited mineral commodities recorded from this region.


Mineral List

Mineral list contains entries from the region specified including sub-localities

53 valid minerals.

Rock Types Recorded

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

Rock list contains entries from the region specified including sub-localities

Select Rock List Type

Alphabetical List Tree Diagram

Detailed Mineral List:

β“˜ Acanthite
Formula: Ag2S
β“˜ Actinolite
Formula: ◻Ca2(Mg4.5-2.5Fe0.5-2.5)Si8O22(OH)2
β“˜ 'Allanite Group'
Formula: (A12+REE3+)(M13+M23+M32+)O[Si2O7][SiO4](OH)
β“˜ Andradite
Formula: Ca3Fe3+2(SiO4)3
β“˜ Anorthite
Formula: Ca(Al2Si2O8)
β“˜ Arsenopyrite
Formula: FeAsS
β“˜ Azurite
Formula: Cu3(CO3)2(OH)2
β“˜ Baryte
Formula: BaSO4
β“˜ 'Biotite'
Formula: K(Fe2+/Mg)2(Al/Fe3+/Mg/Ti)([Si/Al/Fe]2Si2O10)(OH/F)2
β“˜ Bismuthinite
Formula: Bi2S3
β“˜ Bornite
Formula: Cu5FeS4
β“˜ Boulangerite
Formula: Pb5Sb4S11
β“˜ Calcite
Formula: CaCO3
β“˜ Chalcanthite
Formula: CuSO4 · 5H2O
β“˜ Chalcocite
Formula: Cu2S
β“˜ Chalcopyrite
Formula: CuFeS2
β“˜ 'Chlorite Group'
β“˜ Chrysocolla
Formula: Cu2-xAlx(H2-xSi2O5)(OH)4 · nH2O, x < 1
β“˜ 'Clay minerals'
β“˜ Copper
Formula: Cu
β“˜ Covellite
Formula: CuS
β“˜ Cubanite ?
Formula: CuFe2S3
β“˜ Cuprite
Formula: Cu2O
β“˜ Diopside
Formula: CaMgSi2O6
β“˜ Epidote
Formula: (CaCa)(AlAlFe3+)O[Si2O7][SiO4](OH)
β“˜ 'Feldspar Group'
β“˜ Fluorapatite
Formula: Ca5(PO4)3F
β“˜ 'Fluor-uvite-Uvite Series'
β“˜ Galena
Formula: PbS
β“˜ 'Garnet Group'
Formula: X3Z2(SiO4)3
β“˜ Gold
Formula: Au
β“˜ Gold var. Electrum
Formula: (Au,Ag)
β“˜ Halite
Formula: NaCl
Description: In fluid inclusions
β“˜ Hedleyite
Formula: Bi7Te3
β“˜ Hematite
Formula: Fe2O3
β“˜ Hessite
Formula: Ag2Te
β“˜ 'Limonite'
β“˜ Magnetite
Formula: Fe2+Fe3+2O4
β“˜ Malachite
Formula: Cu2(CO3)(OH)2
β“˜ Marcasite
Formula: FeS2
β“˜ Molybdenite
Formula: MoS2
β“˜ Muscovite
Formula: KAl2(AlSi3O10)(OH)2
β“˜ Muscovite var. Sericite
Formula: KAl2(AlSi3O10)(OH)2
β“˜ Orpiment
Formula: As2S3
β“˜ Orthoclase
Formula: K(AlSi3O8)
β“˜ Phlogopite
Formula: KMg3(AlSi3O10)(OH)2
β“˜ Pyrite
Formula: FeS2
β“˜ 'Pyroxene Group'
Formula: ADSi2O6
β“˜ Pyrrhotite
Formula: Fe1-xS
β“˜ Quartz
Formula: SiO2
β“˜ Realgar
Formula: As4S4
β“˜ Sanidine
Formula: K(AlSi3O8)
β“˜ Scheelite
Formula: Ca(WO4)
β“˜ Schorl
Formula: NaFe2+3Al6(Si6O18)(BO3)3(OH)3(OH)
β“˜ Siderite
Formula: FeCO3
β“˜ Sphalerite
Formula: ZnS
β“˜ Sylvite
Formula: KCl
Description: Daughter crystal in Fluid inclusions.
β“˜ Titanite
Formula: CaTi(SiO4)O
β“˜ 'Tourmaline'
Formula: AD3G6 (T6O18)(BO3)3X3Z
β“˜ Tremolite
Formula: ◻Ca2Mg5(Si8O22)(OH)2
β“˜ Vesuvianite
Formula: Ca19Fe3+Al4(Al6Mg2)(◻4)◻[Si2O7]4[(SiO4)10]O(OH)9
β“˜ Vivianite
Formula: Fe2+Fe2+2(PO4)2 · 8H2O
β“˜ Wollastonite
Formula: Ca3(Si3O9)
β“˜ Wulfenite
Formula: Pb(MoO4)
β“˜ Zircon
Formula: Zr(SiO4)

Gallery:

List of minerals arranged by Strunz 10th Edition classification

Group 1 - Elements
β“˜Gold1.AA.05Au
β“˜var. Electrum1.AA.05(Au,Ag)
β“˜Copper1.AA.05Cu
Group 2 - Sulphides and Sulfosalts
β“˜Chalcocite2.BA.05Cu2S
β“˜Bornite2.BA.15Cu5FeS4
β“˜Acanthite2.BA.35Ag2S
β“˜Hessite2.BA.60Ag2Te
β“˜Covellite2.CA.05aCuS
β“˜Sphalerite2.CB.05aZnS
β“˜Chalcopyrite2.CB.10aCuFeS2
β“˜Cubanite ?2.CB.55aCuFe2S3
β“˜Pyrrhotite2.CC.10Fe1-xS
β“˜Galena2.CD.10PbS
β“˜Bismuthinite2.DB.05Bi2S3
β“˜Hedleyite2.DC.05Bi7Te3
β“˜Molybdenite2.EA.30MoS2
β“˜Pyrite2.EB.05aFeS2
β“˜Marcasite2.EB.10aFeS2
β“˜Arsenopyrite2.EB.20FeAsS
β“˜Realgar2.FA.15aAs4S4
β“˜Orpiment2.FA.30As2S3
β“˜Boulangerite2.HC.15Pb5Sb4S11
Group 3 - Halides
β“˜Sylvite3.AA.20KCl
β“˜Halite3.AA.20NaCl
Group 4 - Oxides and Hydroxides
β“˜Cuprite4.AA.10Cu2O
β“˜Magnetite4.BB.05Fe2+Fe3+2O4
β“˜Hematite4.CB.05Fe2O3
β“˜Quartz4.DA.05SiO2
Group 5 - Nitrates and Carbonates
β“˜Siderite5.AB.05FeCO3
β“˜Calcite5.AB.05CaCO3
β“˜Azurite5.BA.05Cu3(CO3)2(OH)2
β“˜Malachite5.BA.10Cu2(CO3)(OH)2
Group 7 - Sulphates, Chromates, Molybdates and Tungstates
β“˜Baryte7.AD.35BaSO4
β“˜Chalcanthite7.CB.20CuSO4 Β· 5H2O
β“˜Wulfenite7.GA.05Pb(MoO4)
β“˜Scheelite7.GA.05Ca(WO4)
Group 8 - Phosphates, Arsenates and Vanadates
β“˜Fluorapatite8.BN.05Ca5(PO4)3F
β“˜Vivianite8.CE.40Fe2+Fe2+2(PO4)2 Β· 8H2O
Group 9 - Silicates
β“˜Andradite9.AD.25Ca3Fe3+2(SiO4)3
β“˜Zircon9.AD.30Zr(SiO4)
β“˜Titanite9.AG.15CaTi(SiO4)O
β“˜Epidote9.BG.05a(CaCa)(AlAlFe3+)O[Si2O7][SiO4](OH)
β“˜Vesuvianite9.BG.35Ca19Fe3+Al4(Al6Mg2)(β—»4)β—»[Si2O7]4[(SiO4)10]O(OH)9
β“˜Schorl9.CK.05NaFe2+3Al6(Si6O18)(BO3)3(OH)3(OH)
β“˜Diopside9.DA.15CaMgSi2O6
β“˜Actinolite9.DE.10β—»Ca2(Mg4.5-2.5Fe0.5-2.5)Si8O22(OH)2
β“˜Tremolite9.DE.10β—»Ca2Mg5(Si8O22)(OH)2
β“˜Wollastonite9.DG.05Ca3(Si3O9)
β“˜Muscovite9.EC.15KAl2(AlSi3O10)(OH)2
β“˜var. Sericite9.EC.15KAl2(AlSi3O10)(OH)2
β“˜Phlogopite9.EC.20KMg3(AlSi3O10)(OH)2
β“˜Chrysocolla9.ED.20Cu2-xAlx(H2-xSi2O5)(OH)4 Β· nH2O, x < 1
β“˜Sanidine9.FA.30K(AlSi3O8)
β“˜Orthoclase9.FA.30K(AlSi3O8)
β“˜Anorthite9.FA.35Ca(Al2Si2O8)
Unclassified
β“˜'Pyroxene Group'-ADSi2O6
β“˜'Garnet Group'-X3Z2(SiO4)3
β“˜'Biotite'-K(Fe2+/Mg)2(Al/Fe3+/Mg/Ti)([Si/Al/Fe]2Si2O10)(OH/F)2
β“˜'Fluor-uvite-Uvite Series'-
β“˜'Tourmaline'-AD3G6 (T6O18)(BO3)3X3Z
β“˜'Limonite'-
β“˜'Feldspar Group'-
β“˜'Clay minerals'-
β“˜'Chlorite Group'-
β“˜'Allanite Group'-(A12+REE3+)(M13+M23+M32+)O[Si2O7][SiO4](OH)

List of minerals for each chemical element

HHydrogen
Hβ“˜ Actinolite◻Ca2(Mg4.5-2.5Fe0.5-2.5)Si8O22(OH)2
Hβ“˜ AzuriteCu3(CO3)2(OH)2
Hβ“˜ BiotiteK(Fe2+/Mg)2(Al/Fe3+/Mg/Ti)([Si/Al/Fe]2Si2O10)(OH/F)2
Hβ“˜ ChalcanthiteCuSO4 · 5H2O
Hβ“˜ ChrysocollaCu2-xAlx(H2-xSi2O5)(OH)4 · nH2O, x < 1
Hβ“˜ Epidote(CaCa)(AlAlFe3+)O[Si2O7][SiO4](OH)
Hβ“˜ MalachiteCu2(CO3)(OH)2
Hβ“˜ MuscoviteKAl2(AlSi3O10)(OH)2
Hβ“˜ PhlogopiteKMg3(AlSi3O10)(OH)2
Hβ“˜ SchorlNaFe32+Al6(Si6O18)(BO3)3(OH)3(OH)
Hβ“˜ Tremolite◻Ca2Mg5(Si8O22)(OH)2
Hβ“˜ VivianiteFe2+Fe22+(PO4)2 · 8H2O
Hβ“˜ VesuvianiteCa19Fe3+Al4(Al6Mg2)(◻4)◻[Si2O7]4[(SiO4)10]O(OH)9
Hβ“˜ Muscovite var. SericiteKAl2(AlSi3O10)(OH)2
Hβ“˜ Allanite Group(A12+REE3+)(M13+M23+M32+)O[Si2O7][SiO4](OH)
BBoron
Bβ“˜ SchorlNaFe32+Al6(Si6O18)(BO3)3(OH)3(OH)
Bβ“˜ TourmalineAD3G6 (T6O18)(BO3)3X3Z
CCarbon
Cβ“˜ AzuriteCu3(CO3)2(OH)2
Cβ“˜ CalciteCaCO3
Cβ“˜ MalachiteCu2(CO3)(OH)2
Cβ“˜ SideriteFeCO3
OOxygen
Oβ“˜ Actinolite◻Ca2(Mg4.5-2.5Fe0.5-2.5)Si8O22(OH)2
Oβ“˜ AndraditeCa3Fe23+(SiO4)3
Oβ“˜ AnorthiteCa(Al2Si2O8)
Oβ“˜ AzuriteCu3(CO3)2(OH)2
Oβ“˜ BaryteBaSO4
Oβ“˜ BiotiteK(Fe2+/Mg)2(Al/Fe3+/Mg/Ti)([Si/Al/Fe]2Si2O10)(OH/F)2
Oβ“˜ CalciteCaCO3
Oβ“˜ ChalcanthiteCuSO4 · 5H2O
Oβ“˜ ChrysocollaCu2-xAlx(H2-xSi2O5)(OH)4 · nH2O, x < 1
Oβ“˜ CupriteCu2O
Oβ“˜ DiopsideCaMgSi2O6
Oβ“˜ Epidote(CaCa)(AlAlFe3+)O[Si2O7][SiO4](OH)
Oβ“˜ FluorapatiteCa5(PO4)3F
Oβ“˜ HematiteFe2O3
Oβ“˜ MagnetiteFe2+Fe23+O4
Oβ“˜ MalachiteCu2(CO3)(OH)2
Oβ“˜ MuscoviteKAl2(AlSi3O10)(OH)2
Oβ“˜ OrthoclaseK(AlSi3O8)
Oβ“˜ PhlogopiteKMg3(AlSi3O10)(OH)2
Oβ“˜ QuartzSiO2
Oβ“˜ SanidineK(AlSi3O8)
Oβ“˜ ScheeliteCa(WO4)
Oβ“˜ SchorlNaFe32+Al6(Si6O18)(BO3)3(OH)3(OH)
Oβ“˜ SideriteFeCO3
Oβ“˜ TitaniteCaTi(SiO4)O
Oβ“˜ TourmalineAD3G6 (T6O18)(BO3)3X3Z
Oβ“˜ Tremolite◻Ca2Mg5(Si8O22)(OH)2
Oβ“˜ VivianiteFe2+Fe22+(PO4)2 · 8H2O
Oβ“˜ VesuvianiteCa19Fe3+Al4(Al6Mg2)(◻4)◻[Si2O7]4[(SiO4)10]O(OH)9
Oβ“˜ WulfenitePb(MoO4)
Oβ“˜ WollastoniteCa3(Si3O9)
Oβ“˜ ZirconZr(SiO4)
Oβ“˜ Muscovite var. SericiteKAl2(AlSi3O10)(OH)2
Oβ“˜ Pyroxene GroupADSi2O6
Oβ“˜ Garnet GroupX3Z2(SiO4)3
Oβ“˜ Allanite Group(A12+REE3+)(M13+M23+M32+)O[Si2O7][SiO4](OH)
FFluorine
Fβ“˜ BiotiteK(Fe2+/Mg)2(Al/Fe3+/Mg/Ti)([Si/Al/Fe]2Si2O10)(OH/F)2
Fβ“˜ FluorapatiteCa5(PO4)3F
NaSodium
Naβ“˜ HaliteNaCl
Naβ“˜ SchorlNaFe32+Al6(Si6O18)(BO3)3(OH)3(OH)
MgMagnesium
Mgβ“˜ Actinolite◻Ca2(Mg4.5-2.5Fe0.5-2.5)Si8O22(OH)2
Mgβ“˜ BiotiteK(Fe2+/Mg)2(Al/Fe3+/Mg/Ti)([Si/Al/Fe]2Si2O10)(OH/F)2
Mgβ“˜ DiopsideCaMgSi2O6
Mgβ“˜ PhlogopiteKMg3(AlSi3O10)(OH)2
Mgβ“˜ Tremolite◻Ca2Mg5(Si8O22)(OH)2
Mgβ“˜ VesuvianiteCa19Fe3+Al4(Al6Mg2)(◻4)◻[Si2O7]4[(SiO4)10]O(OH)9
AlAluminium
Alβ“˜ AnorthiteCa(Al2Si2O8)
Alβ“˜ BiotiteK(Fe2+/Mg)2(Al/Fe3+/Mg/Ti)([Si/Al/Fe]2Si2O10)(OH/F)2
Alβ“˜ ChrysocollaCu2-xAlx(H2-xSi2O5)(OH)4 · nH2O, x < 1
Alβ“˜ Epidote(CaCa)(AlAlFe3+)O[Si2O7][SiO4](OH)
Alβ“˜ MuscoviteKAl2(AlSi3O10)(OH)2
Alβ“˜ OrthoclaseK(AlSi3O8)
Alβ“˜ PhlogopiteKMg3(AlSi3O10)(OH)2
Alβ“˜ SanidineK(AlSi3O8)
Alβ“˜ SchorlNaFe32+Al6(Si6O18)(BO3)3(OH)3(OH)
Alβ“˜ VesuvianiteCa19Fe3+Al4(Al6Mg2)(◻4)◻[Si2O7]4[(SiO4)10]O(OH)9
Alβ“˜ Muscovite var. SericiteKAl2(AlSi3O10)(OH)2
SiSilicon
Siβ“˜ Actinolite◻Ca2(Mg4.5-2.5Fe0.5-2.5)Si8O22(OH)2
Siβ“˜ AndraditeCa3Fe23+(SiO4)3
Siβ“˜ AnorthiteCa(Al2Si2O8)
Siβ“˜ BiotiteK(Fe2+/Mg)2(Al/Fe3+/Mg/Ti)([Si/Al/Fe]2Si2O10)(OH/F)2
Siβ“˜ ChrysocollaCu2-xAlx(H2-xSi2O5)(OH)4 · nH2O, x < 1
Siβ“˜ DiopsideCaMgSi2O6
Siβ“˜ Epidote(CaCa)(AlAlFe3+)O[Si2O7][SiO4](OH)
Siβ“˜ MuscoviteKAl2(AlSi3O10)(OH)2
Siβ“˜ OrthoclaseK(AlSi3O8)
Siβ“˜ PhlogopiteKMg3(AlSi3O10)(OH)2
Siβ“˜ QuartzSiO2
Siβ“˜ SanidineK(AlSi3O8)
Siβ“˜ SchorlNaFe32+Al6(Si6O18)(BO3)3(OH)3(OH)
Siβ“˜ TitaniteCaTi(SiO4)O
Siβ“˜ Tremolite◻Ca2Mg5(Si8O22)(OH)2
Siβ“˜ VesuvianiteCa19Fe3+Al4(Al6Mg2)(◻4)◻[Si2O7]4[(SiO4)10]O(OH)9
Siβ“˜ WollastoniteCa3(Si3O9)
Siβ“˜ ZirconZr(SiO4)
Siβ“˜ Muscovite var. SericiteKAl2(AlSi3O10)(OH)2
Siβ“˜ Pyroxene GroupADSi2O6
Siβ“˜ Garnet GroupX3Z2(SiO4)3
Siβ“˜ Allanite Group(A12+REE3+)(M13+M23+M32+)O[Si2O7][SiO4](OH)
PPhosphorus
Pβ“˜ FluorapatiteCa5(PO4)3F
Pβ“˜ VivianiteFe2+Fe22+(PO4)2 · 8H2O
SSulfur
Sβ“˜ AcanthiteAg2S
Sβ“˜ ArsenopyriteFeAsS
Sβ“˜ BaryteBaSO4
Sβ“˜ BismuthiniteBi2S3
Sβ“˜ BorniteCu5FeS4
Sβ“˜ BoulangeritePb5Sb4S11
Sβ“˜ ChalcopyriteCuFeS2
Sβ“˜ ChalcanthiteCuSO4 · 5H2O
Sβ“˜ ChalcociteCu2S
Sβ“˜ CovelliteCuS
Sβ“˜ CubaniteCuFe2S3
Sβ“˜ GalenaPbS
Sβ“˜ MarcasiteFeS2
Sβ“˜ MolybdeniteMoS2
Sβ“˜ OrpimentAs2S3
Sβ“˜ PyriteFeS2
Sβ“˜ PyrrhotiteFe1-xS
Sβ“˜ RealgarAs4S4
Sβ“˜ SphaleriteZnS
ClChlorine
Clβ“˜ HaliteNaCl
Clβ“˜ SylviteKCl
KPotassium
Kβ“˜ BiotiteK(Fe2+/Mg)2(Al/Fe3+/Mg/Ti)([Si/Al/Fe]2Si2O10)(OH/F)2
Kβ“˜ MuscoviteKAl2(AlSi3O10)(OH)2
Kβ“˜ OrthoclaseK(AlSi3O8)
Kβ“˜ PhlogopiteKMg3(AlSi3O10)(OH)2
Kβ“˜ SanidineK(AlSi3O8)
Kβ“˜ SylviteKCl
Kβ“˜ Muscovite var. SericiteKAl2(AlSi3O10)(OH)2
CaCalcium
Caβ“˜ Actinolite◻Ca2(Mg4.5-2.5Fe0.5-2.5)Si8O22(OH)2
Caβ“˜ AndraditeCa3Fe23+(SiO4)3
Caβ“˜ AnorthiteCa(Al2Si2O8)
Caβ“˜ CalciteCaCO3
Caβ“˜ DiopsideCaMgSi2O6
Caβ“˜ Epidote(CaCa)(AlAlFe3+)O[Si2O7][SiO4](OH)
Caβ“˜ FluorapatiteCa5(PO4)3F
Caβ“˜ ScheeliteCa(WO4)
Caβ“˜ TitaniteCaTi(SiO4)O
Caβ“˜ Tremolite◻Ca2Mg5(Si8O22)(OH)2
Caβ“˜ VesuvianiteCa19Fe3+Al4(Al6Mg2)(◻4)◻[Si2O7]4[(SiO4)10]O(OH)9
Caβ“˜ WollastoniteCa3(Si3O9)
TiTitanium
Tiβ“˜ BiotiteK(Fe2+/Mg)2(Al/Fe3+/Mg/Ti)([Si/Al/Fe]2Si2O10)(OH/F)2
Tiβ“˜ TitaniteCaTi(SiO4)O
FeIron
Feβ“˜ Actinolite◻Ca2(Mg4.5-2.5Fe0.5-2.5)Si8O22(OH)2
Feβ“˜ AndraditeCa3Fe23+(SiO4)3
Feβ“˜ ArsenopyriteFeAsS
Feβ“˜ BiotiteK(Fe2+/Mg)2(Al/Fe3+/Mg/Ti)([Si/Al/Fe]2Si2O10)(OH/F)2
Feβ“˜ BorniteCu5FeS4
Feβ“˜ ChalcopyriteCuFeS2
Feβ“˜ CubaniteCuFe2S3
Feβ“˜ Epidote(CaCa)(AlAlFe3+)O[Si2O7][SiO4](OH)
Feβ“˜ HematiteFe2O3
Feβ“˜ MagnetiteFe2+Fe23+O4
Feβ“˜ MarcasiteFeS2
Feβ“˜ PyriteFeS2
Feβ“˜ PyrrhotiteFe1-xS
Feβ“˜ SchorlNaFe32+Al6(Si6O18)(BO3)3(OH)3(OH)
Feβ“˜ SideriteFeCO3
Feβ“˜ VivianiteFe2+Fe22+(PO4)2 · 8H2O
Feβ“˜ VesuvianiteCa19Fe3+Al4(Al6Mg2)(◻4)◻[Si2O7]4[(SiO4)10]O(OH)9
CuCopper
Cuβ“˜ AzuriteCu3(CO3)2(OH)2
Cuβ“˜ BorniteCu5FeS4
Cuβ“˜ ChalcopyriteCuFeS2
Cuβ“˜ ChalcanthiteCuSO4 · 5H2O
Cuβ“˜ ChalcociteCu2S
Cuβ“˜ ChrysocollaCu2-xAlx(H2-xSi2O5)(OH)4 · nH2O, x < 1
Cuβ“˜ CovelliteCuS
Cuβ“˜ CubaniteCuFe2S3
Cuβ“˜ CupriteCu2O
Cuβ“˜ CopperCu
Cuβ“˜ MalachiteCu2(CO3)(OH)2
ZnZinc
Znβ“˜ SphaleriteZnS
AsArsenic
Asβ“˜ ArsenopyriteFeAsS
Asβ“˜ OrpimentAs2S3
Asβ“˜ RealgarAs4S4
ZrZirconium
Zrβ“˜ ZirconZr(SiO4)
MoMolybdenum
Moβ“˜ MolybdeniteMoS2
Moβ“˜ WulfenitePb(MoO4)
AgSilver
Agβ“˜ AcanthiteAg2S
Agβ“˜ Gold var. Electrum(Au,Ag)
Agβ“˜ HessiteAg2Te
SbAntimony
Sbβ“˜ BoulangeritePb5Sb4S11
TeTellurium
Teβ“˜ HedleyiteBi7Te3
Teβ“˜ HessiteAg2Te
BaBarium
Baβ“˜ BaryteBaSO4
WTungsten
Wβ“˜ ScheeliteCa(WO4)
AuGold
Auβ“˜ Gold var. Electrum(Au,Ag)
Auβ“˜ GoldAu
PbLead
Pbβ“˜ BoulangeritePb5Sb4S11
Pbβ“˜ GalenaPbS
Pbβ“˜ WulfenitePb(MoO4)
BiBismuth
Biβ“˜ BismuthiniteBi2S3
Biβ“˜ HedleyiteBi7Te3

Other Databases

Link to USGS MRDS:10310303

Localities in this Region

USA

Other Regions, Features and Areas containing this locality

North America PlateTectonic Plate

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

Hill, J.M., (1915), Some Mining Districts in Northeastern California and Northwestern Nevada: USGS Bull 594
Roberts, R.J. and Arnold, D.C., (1965); Ore Deposits of the Antler Peak Quadrangle, Humboldt and Lander Counties, Nevada: U.S.G.S. Prof. Paper 459-B
Sayers, R. W., Tippett, M. C., and Fields, E. D., (1968), The Ore Deposits at Copper Canyon and Copper Basin, Lander County, Nevada: AIME Annual Meeting Paper, N.Y.
Theodore, T.G., (1971), Geologic map of the Copper Canyon area, Battle Mountain mining district, Lander County, Nevada: U.S. Geological Survey Open-File Report 71-282, 1:4,800.
Theodore, T.G., Silberman, M.L., and Blake, D.W., (1973), Geochemistry and potassium-argon ages of plutonic rocks in the Battle Mountain mining district, Lander County, Nevada: U.S. Geological Survey Professional Paper 798-A, 24 .
Stewart, J.H., McKee, E.H., and Stager, H.K., (1977), Geology and Mineral Deposits of Lander County Nevada: NBMG Bull. 88.
Theodore, T.G., Blake, D.W., and Banks, N.G. (1978): Geology and geochemistry of the West Ore Body and associated skarns, Copper Canyon porphyry copper deposits, Lander County, Nevada, with a section on electron microprobe analyses of andradite and diopside. USGS Prof. Paper 798-C.
Theodore and Blake, (1978), Geology and geochemistry of the West orebody and associated skarns, Copper Canyon porphyry copper deposits, Lander County, Nevada, USGS Prof Paper798-C, 85 p.
Blake, D.W., Theodore, T.G., Batchelder, J.N, and Kretschmer, E.L., (1979), Structural relations of igneous rocks and mineralization in the Battle Mountain mining district, Lander County, Nevada, in Ridge, J.D., ed., Papers on mineral deposits of western North America: Nevada Bureau of Mines and Geology Report 33, p. 87-99.
Blake, D. W., Kretschmer, E. L., (1980), Gold Deposits at Copper Canyon, Lander Co., Nev., Abstract, Precious Metals Symposium, AIME, Sparks, Nevada.
Doebrich, Jeff, (1995), Geology and Mineral Deposits of the Antler Peak 7.5-minute quadrangle, Lander County, Nevada, NBMG Bull 109, 44 p.
Doebrich, J.L., Wotruba, P.R., Theodore, T.G., McGibbon, D.H., and Felder, R.P., (1995), Field guide for geology and ore deposits of the Battle Mountain mining district, Humboldt and Lander counties, Nevada, in Geology and ore deposits of the American Cordillera symposium: Geological Society of Nevada, U.S. Geological Survey and Sociedad Geologica de Chile, p. 327-376.
Doebrich, J.L., and Theodore, T.G., (1996), Geologic history of the Battle Mountain mining district, Nevada, and regional controls on the distribution of mineral systems, in Coyner, A.R and Fahey, P.L., eds., Geology and Ore Deposits of the American Cordillera: Geological Society of Nevada Symposium proceedings, Reno-Sparks, April 1995, p. 453-483, CD-ROM.
Long, K.R., DeYoung, J.H., Jr., and Ludington, S.D., (1998), Database of significant deposits of gold, silver, copper, lead, and zinc in the United States; Part A, Database description and analysis; part B, Digital database: U.S. Geological Survey Open-File Report 98-206, 33 p., one 3.5 inch diskette.
Kotlyar, B.B., and Theodore, T.G., (1998), Multilevel geochemical patterns at the Fortitude gold skarn, Battle Mountain Mining District, Nevada, in Tosdal, R.M., ed., Contributions to the gold metallogeny of northern Nevada: U.S. Geological Survey Open-File Report 98-338, p. 259-263.
Geological Society of Nevada, (1999), Geology and Gold Mineralization of the Buffalo Valley Area, Northwestern Battle Mountain Trend; GSN Special Publication No. 31, 1999 Fall field trip Guidebook..
Wendt, Clancy, (2004), Technical Report on the ICBM/COPPER BASIN Property, Lander and Humboldt Counties, Nevada, Staccato Gold website: http://www.staccatogold.com/i/pdf/icbm-43-101.pdf
Singer, Donald A., Berger, Vladimir Iosifovich, Moring, Barry C. (2005) Porphyry copper deposits of the world: database, map, and grade and tonnage models. Open-File Report 2005-1060. US Geological Survey doi:10.3133/ofr20051060
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