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Sankt Jakob Mine, Sankt Jakob vein, Neuenberg, Ste Marie-aux-Mines, Colmar-Ribeauvillé, Haut-Rhin, Grand Est, Francei
Regional Level Types
Sankt Jakob MineMine
Sankt Jakob veinVein
Neuenberg- not defined -
Ste Marie-aux-MinesCommune
Colmar-RibeauvilléArrondissement
Haut-RhinDepartment
Grand EstRegion
FranceCountry

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Key
Latitude & Longitude (WGS84):
48° North , 7° East (est.)
Estimate based on other nearby localities or region boundaries.
Margin of Error:
~1km
Locality type:
Köppen climate type:
Other/historical names associated with this locality:
Alsace
Name(s) in local language(s):
Mine St Jacques (Grube Jakob), Sainte-Marie-aux-Mines, Haut-Rhin, Alsace, France


Upper and lower Sankt-Jacob mine are known.

As this locality lies in the Sainte Marie-aux-Mines district, the place is protected by a archaeological mining district status and all collecting is prohibited.

Select Mineral List Type

Standard Detailed Strunz Dana Chemical Elements

Mineral List


77 valid minerals.

Detailed Mineral List:

Acanthite
Formula: Ag2S
Reference: This mine worked the same vein as Gabe gottes mine. From the 19th century, ore from a large part of the Saint-Jacques mine network was transported to level -40 of Gabe Gottes before being sent to the processing plant. The mineralization of this sector is therefore very comparable to that of Gabe-Gotes.
Aikinite
Formula: PbCuBiS3
Reference: This mine worked the same vein as Gabe gottes mine. From the 19th century, ore from a large part of the Saint-Jacques mine network was transported to level -40 of Gabe Gottes before being sent to the processing plant. The mineralization of this sector is therefore very comparable to that of Gabe-Gotes.
Ankerite
Formula: Ca(Fe2+,Mg)(CO3)2
Reference: This mine worked the same vein as Gabe gottes mine. From the 19th century, ore from a large part of the Saint-Jacques mine network was transported to level -40 of Gabe Gottes before being sent to the processing plant. The mineralization of this sector is therefore very comparable to that of Gabe-Gotes.
Annabergite
Formula: Ni3(AsO4)2 · 8H2O
Reference: Wittern, Journée: "Mineralien finden in den Vogesen", 1997
Aragonite
Formula: CaCO3
Reference: Wittern, Journée: "Mineralien finden in den Vogesen", 1997
Aragonite var: Flos Ferri
Formula: CaCO3
Reference: Wittern, Journée: "Mineralien finden in den Vogesen", 1997
Aramayoite
Formula: Ag3Sb2(Bi,Sb)S6
Reference: This mine worked the same vein as Gabe gottes mine. From the 19th century, ore from a large part of the Saint-Jacques mine network was transported to level -40 of Gabe Gottes before being sent to the processing plant. The mineralization of this sector is therefore very comparable to that of Gabe-Gotes.
Argentopyrite
Formula: AgFe2S3
Reference: This mine worked the same vein as Gabe gottes mine. From the 19th century, ore from a large part of the Saint-Jacques mine network was transported to level -40 of Gabe Gottes before being sent to the processing plant. The mineralization of this sector is therefore very comparable to that of Gabe-Gotes.
Arsenic
Formula: As
Reference: Mineralogical Museum of the City : Sainte Marie aux Mines; This mine worked the same vein as Gabe gottes mine. From the 19th century, ore from a large part of the Saint-Jacques mine network was transported to level -40 of Gabe Gottes before being sent to the processing plant. The mineralization of this sector is therefore very comparable to that of Gabe-Gotes.
Arsenolamprite
Formula: As
Reference: This mine worked the same vein as Gabe gottes mine. From the 19th century, ore from a large part of the Saint-Jacques mine network was transported to level -40 of Gabe Gottes before being sent to the processing plant. The mineralization of this sector is therefore very comparable to that of Gabe-Gotes.
Arsenolite
Formula: As2O3
Reference: This mine worked the same vein as Gabe gottes mine. From the 19th century, ore from a large part of the Saint-Jacques mine network was transported to level -40 of Gabe Gottes before being sent to the processing plant. The mineralization of this sector is therefore very comparable to that of Gabe-Gotes.
Arsenopyrite
Formula: FeAsS
Reference: This mine worked the same vein as Gabe gottes mine. From the 19th century, ore from a large part of the Saint-Jacques mine network was transported to level -40 of Gabe Gottes before being sent to the processing plant. The mineralization of this sector is therefore very comparable to that of Gabe-Gotes.
Baumstarkite
Formula: Ag3Sb3S6
Reference: This mine worked the same vein as Gabe gottes mine. From the 19th century, ore from a large part of the Saint-Jacques mine network was transported to level -40 of Gabe Gottes before being sent to the processing plant. The mineralization of this sector is therefore very comparable to that of Gabe-Gotes.
Berryite
Formula: Cu3Ag2Pb3Bi7S16
Reference: This mine worked the same vein as Gabe gottes mine. From the 19th century, ore from a large part of the Saint-Jacques mine network was transported to level -40 of Gabe Gottes before being sent to the processing plant. The mineralization of this sector is therefore very comparable to that of Gabe-Gotes.
Bismuth
Formula: Bi
Reference: This mine worked the same vein as Gabe gottes mine. From the 19th century, ore from a large part of the Saint-Jacques mine network was transported to level -40 of Gabe Gottes before being sent to the processing plant. The mineralization of this sector is therefore very comparable to that of Gabe-Gotes.
Bismuthinite
Formula: Bi2S3
Reference: This mine worked the same vein as Gabe gottes mine. From the 19th century, ore from a large part of the Saint-Jacques mine network was transported to level -40 of Gabe Gottes before being sent to the processing plant. The mineralization of this sector is therefore very comparable to that of Gabe-Gotes.
Bournonite
Formula: PbCuSbS3
Reference: This mine worked the same vein as Gabe gottes mine. From the 19th century, ore from a large part of the Saint-Jacques mine network was transported to level -40 of Gabe Gottes before being sent to the processing plant. The mineralization of this sector is therefore very comparable to that of Gabe-Gotes.
Calcite
Formula: CaCO3
Reference: This mine worked the same vein as Gabe gottes mine. From the 19th century, ore from a large part of the Saint-Jacques mine network was transported to level -40 of Gabe Gottes before being sent to the processing plant. The mineralization of this sector is therefore very comparable to that of Gabe-Gotes.
Chalcopyrite
Formula: CuFeS2
Reference: This mine worked the same vein as Gabe gottes mine. From the 19th century, ore from a large part of the Saint-Jacques mine network was transported to level -40 of Gabe Gottes before being sent to the processing plant. The mineralization of this sector is therefore very comparable to that of Gabe-Gotes.
Chlorargyrite
Formula: AgCl
Reference: This mine worked the same vein as Gabe gottes mine. From the 19th century, ore from a large part of the Saint-Jacques mine network was transported to level -40 of Gabe Gottes before being sent to the processing plant. The mineralization of this sector is therefore very comparable to that of Gabe-Gotes.
Cornubite
Formula: Cu5(AsO4)2(OH)4
Reference: Wittern, Journée: "Mineralien finden in den Vogesen", 1997
Cosalite
Formula: Pb2Bi2S5
Reference: This mine worked the same vein as Gabe gottes mine. From the 19th century, ore from a large part of the Saint-Jacques mine network was transported to level -40 of Gabe Gottes before being sent to the processing plant. The mineralization of this sector is therefore very comparable to that of Gabe-Gotes.
Cubanite
Formula: CuFe2S3
Reference: This mine worked the same vein as Gabe gottes mine. From the 19th century, ore from a large part of the Saint-Jacques mine network was transported to level -40 of Gabe Gottes before being sent to the processing plant. The mineralization of this sector is therefore very comparable to that of Gabe-Gotes.
Dervillite
Formula: Ag2AsS2
Reference: This mine worked the same vein as Gabe gottes mine. From the 19th century, ore from a large part of the Saint-Jacques mine network was transported to level -40 of Gabe Gottes before being sent to the processing plant. The mineralization of this sector is therefore very comparable to that of Gabe-Gotes.
Dolomite
Formula: CaMg(CO3)2
Reference: This mine worked the same vein as Gabe gottes mine. From the 19th century, ore from a large part of the Saint-Jacques mine network was transported to level -40 of Gabe Gottes before being sent to the processing plant. The mineralization of this sector is therefore very comparable to that of Gabe-Gotes.
Dyscrasite
Formula: Ag3Sb
Reference: This mine worked the same vein as Gabe gottes mine. From the 19th century, ore from a large part of the Saint-Jacques mine network was transported to level -40 of Gabe Gottes before being sent to the processing plant. The mineralization of this sector is therefore very comparable to that of Gabe-Gotes.
Emplectite
Formula: CuBiS2
Reference: This mine worked the same vein as Gabe gottes mine. From the 19th century, ore from a large part of the Saint-Jacques mine network was transported to level -40 of Gabe Gottes before being sent to the processing plant. The mineralization of this sector is therefore very comparable to that of Gabe-Gotes.
Ferrarisite
Formula: Ca5(AsO4)2(HAsO4)2 · 9H2O
Reference: This mine worked the same vein as Gabe gottes mine. From the 19th century, ore from a large part of the Saint-Jacques mine network was transported to level -40 of Gabe Gottes before being sent to the processing plant. The mineralization of this sector is therefore very comparable to that of Gabe-Gotes.
Fluckite
Formula: CaMn2+(HAsO4)2 · 2H2O
Reference: This mine worked the same vein as Gabe gottes mine. From the 19th century, ore from a large part of the Saint-Jacques mine network was transported to level -40 of Gabe Gottes before being sent to the processing plant. The mineralization of this sector is therefore very comparable to that of Gabe-Gotes.
Galena
Formula: PbS
Reference: This mine worked the same vein as Gabe gottes mine. From the 19th century, ore from a large part of the Saint-Jacques mine network was transported to level -40 of Gabe Gottes before being sent to the processing plant. The mineralization of this sector is therefore very comparable to that of Gabe-Gotes.
Giftgrubeite
Formula: CaMn2Ca2(AsO4)2(AsO3OH)2·4H2O
Reference: This mine worked the same vein as Gabe gottes mine. From the 19th century, ore from a large part of the Saint-Jacques mine network was transported to level -40 of Gabe Gottes before being sent to the processing plant. The mineralization of this sector is therefore very comparable to that of Gabe-Gotes.
Guérinite
Formula: Ca5(AsO4)2(HAsO4)2 · 9H2O
Reference: This mine worked the same vein as Gabe gottes mine. From the 19th century, ore from a large part of the Saint-Jacques mine network was transported to level -40 of Gabe Gottes before being sent to the processing plant. The mineralization of this sector is therefore very comparable to that of Gabe-Gotes.
Gypsum
Formula: CaSO4 · 2H2O
Reference: This mine worked the same vein as Gabe gottes mine. From the 19th century, ore from a large part of the Saint-Jacques mine network was transported to level -40 of Gabe Gottes before being sent to the processing plant. The mineralization of this sector is therefore very comparable to that of Gabe-Gotes.
Haidingerite
Formula: CaHAsO4 · H2O
Reference: This mine worked the same vein as Gabe gottes mine. From the 19th century, ore from a large part of the Saint-Jacques mine network was transported to level -40 of Gabe Gottes before being sent to the processing plant. The mineralization of this sector is therefore very comparable to that of Gabe-Gotes.
Hematite
Formula: Fe2O3
Reference: This mine worked the same vein as Gabe gottes mine. From the 19th century, ore from a large part of the Saint-Jacques mine network was transported to level -40 of Gabe Gottes before being sent to the processing plant. The mineralization of this sector is therefore very comparable to that of Gabe-Gotes.
Hörnesite
Formula: Mg3(AsO4)2 · 8H2O
Reference: This mine worked the same vein as Gabe gottes mine. From the 19th century, ore from a large part of the Saint-Jacques mine network was transported to level -40 of Gabe Gottes before being sent to the processing plant. The mineralization of this sector is therefore very comparable to that of Gabe-Gotes.
Kaolinite
Formula: Al2(Si2O5)(OH)4
Reference: This mine worked the same vein as Gabe gottes mine. From the 19th century, ore from a large part of the Saint-Jacques mine network was transported to level -40 of Gabe Gottes before being sent to the processing plant. The mineralization of this sector is therefore very comparable to that of Gabe-Gotes.
Kobellite
Formula: Pb22Cu4(Bi,Sb)30S69
Reference: This mine worked the same vein as Gabe gottes mine. From the 19th century, ore from a large part of the Saint-Jacques mine network was transported to level -40 of Gabe Gottes before being sent to the processing plant. The mineralization of this sector is therefore very comparable to that of Gabe-Gotes.
Lautite
Formula: CuAsS
Reference: This mine worked the same vein as Gabe gottes mine. From the 19th century, ore from a large part of the Saint-Jacques mine network was transported to level -40 of Gabe Gottes before being sent to the processing plant. The mineralization of this sector is therefore very comparable to that of Gabe-Gotes.
'Limonite'
Formula: (Fe,O,OH,H2O)
Reference: This mine worked the same vein as Gabe gottes mine. From the 19th century, ore from a large part of the Saint-Jacques mine network was transported to level -40 of Gabe Gottes before being sent to the processing plant. The mineralization of this sector is therefore very comparable to that of Gabe-Gotes.
Löllingite
Formula: FeAs2
Reference: This mine worked the same vein as Gabe gottes mine. From the 19th century, ore from a large part of the Saint-Jacques mine network was transported to level -40 of Gabe Gottes before being sent to the processing plant. The mineralization of this sector is therefore very comparable to that of Gabe-Gotes.
Malachite
Formula: Cu2(CO3)(OH)2
Reference: This mine worked the same vein as Gabe gottes mine. From the 19th century, ore from a large part of the Saint-Jacques mine network was transported to level -40 of Gabe Gottes before being sent to the processing plant. The mineralization of this sector is therefore very comparable to that of Gabe-Gotes.
Marcasite
Formula: FeS2
Reference: This mine worked the same vein as Gabe gottes mine. From the 19th century, ore from a large part of the Saint-Jacques mine network was transported to level -40 of Gabe Gottes before being sent to the processing plant. The mineralization of this sector is therefore very comparable to that of Gabe-Gotes.
Matildite
Formula: AgBiS2
Reference: This mine worked the same vein as Gabe gottes mine. From the 19th century, ore from a large part of the Saint-Jacques mine network was transported to level -40 of Gabe Gottes before being sent to the processing plant. The mineralization of this sector is therefore very comparable to that of Gabe-Gotes.
Mcnearite
Formula: NaCa5(AsO4)(HAsO4)4 · 4H2O
Reference: This mine worked the same vein as Gabe gottes mine. From the 19th century, ore from a large part of the Saint-Jacques mine network was transported to level -40 of Gabe Gottes before being sent to the processing plant. The mineralization of this sector is therefore very comparable to that of Gabe-Gotes.
Miargyrite
Formula: AgSbS2
Reference: This mine worked the same vein as Gabe gottes mine. From the 19th century, ore from a large part of the Saint-Jacques mine network was transported to level -40 of Gabe Gottes before being sent to the processing plant. The mineralization of this sector is therefore very comparable to that of Gabe-Gotes.
Mimetite
Formula: Pb5(AsO4)3Cl
Reference: This mine worked the same vein as Gabe gottes mine. From the 19th century, ore from a large part of the Saint-Jacques mine network was transported to level -40 of Gabe Gottes before being sent to the processing plant. The mineralization of this sector is therefore very comparable to that of Gabe-Gotes.
Mirabilite
Formula: Na2SO4 · 10H2O
Reference: This mine worked the same vein as Gabe gottes mine. From the 19th century, ore from a large part of the Saint-Jacques mine network was transported to level -40 of Gabe Gottes before being sent to the processing plant. The mineralization of this sector is therefore very comparable to that of Gabe-Gotes.
Nickeline
Formula: NiAs
Reference: Wittern, Journée: "Mineralien finden in den Vogesen", 1997
Nickelskutterudite
Formula: (Ni,Co,Fe)As3
Reference: Wittern, Journée: "Mineralien finden in den Vogesen", 1997; This mine worked the same vein as Gabe gottes mine. From the 19th century, ore from a large part of the Saint-Jacques mine network was transported to level -40 of Gabe Gottes before being sent to the processing plant. The mineralization of this sector is therefore very comparable to that of Gabe-Gotes.
Orpiment
Formula: As2S3
Reference: This mine worked the same vein as Gabe gottes mine. From the 19th century, ore from a large part of the Saint-Jacques mine network was transported to level -40 of Gabe Gottes before being sent to the processing plant. The mineralization of this sector is therefore very comparable to that of Gabe-Gotes.
Orthoserpierite
Formula: Ca(Cu,Zn)4(SO4)2(OH)6 · 3H2O
Reference: This mine worked the same vein as Gabe gottes mine. From the 19th century, ore from a large part of the Saint-Jacques mine network was transported to level -40 of Gabe Gottes before being sent to the processing plant. The mineralization of this sector is therefore very comparable to that of Gabe-Gotes.
Pararammelsbergite
Formula: NiAs2
Reference: Wittern, Journée: "Mineralien finden in den Vogesen", 1997
Pavonite
Formula: AgBi3S5
Reference: This mine worked the same vein as Gabe gottes mine. From the 19th century, ore from a large part of the Saint-Jacques mine network was transported to level -40 of Gabe Gottes before being sent to the processing plant. The mineralization of this sector is therefore very comparable to that of Gabe-Gotes.
Pearceite
Formula: [Ag9CuS4][(Ag,Cu)6(As,Sb)2S7]
Reference: This mine worked the same vein as Gabe gottes mine. From the 19th century, ore from a large part of the Saint-Jacques mine network was transported to level -40 of Gabe Gottes before being sent to the processing plant. The mineralization of this sector is therefore very comparable to that of Gabe-Gotes.
Pharmacolite
Formula: Ca(HAsO4) · 2H2O
Reference: This mine worked the same vein as Gabe gottes mine. From the 19th century, ore from a large part of the Saint-Jacques mine network was transported to level -40 of Gabe Gottes before being sent to the processing plant. The mineralization of this sector is therefore very comparable to that of Gabe-Gotes.
Phaunouxite
Formula: Ca3(AsO4)2 · 11H2O
Reference: This mine worked the same vein as Gabe gottes mine. From the 19th century, ore from a large part of the Saint-Jacques mine network was transported to level -40 of Gabe Gottes before being sent to the processing plant. The mineralization of this sector is therefore very comparable to that of Gabe-Gotes.
Picropharmacolite
Formula: Ca4Mg(AsO4)2(HAsO4)2 · 11H2O
Reference: This mine worked the same vein as Gabe gottes mine. From the 19th century, ore from a large part of the Saint-Jacques mine network was transported to level -40 of Gabe Gottes before being sent to the processing plant. The mineralization of this sector is therefore very comparable to that of Gabe-Gotes.
Polybasite
Formula: [(Ag,Cu)6(Sb,As)2S7][Ag9CuS4]
Reference: This mine worked the same vein as Gabe gottes mine. From the 19th century, ore from a large part of the Saint-Jacques mine network was transported to level -40 of Gabe Gottes before being sent to the processing plant. The mineralization of this sector is therefore very comparable to that of Gabe-Gotes.
Proustite
Formula: Ag3AsS3
Reference: This mine worked the same vein as Gabe gottes mine. From the 19th century, ore from a large part of the Saint-Jacques mine network was transported to level -40 of Gabe Gottes before being sent to the processing plant. The mineralization of this sector is therefore very comparable to that of Gabe-Gotes.
Pyrargyrite
Formula: Ag3SbS3
Reference: This mine worked the same vein as Gabe gottes mine. From the 19th century, ore from a large part of the Saint-Jacques mine network was transported to level -40 of Gabe Gottes before being sent to the processing plant. The mineralization of this sector is therefore very comparable to that of Gabe-Gotes.
Pyrite
Formula: FeS2
Reference: This mine worked the same vein as Gabe gottes mine. From the 19th century, ore from a large part of the Saint-Jacques mine network was transported to level -40 of Gabe Gottes before being sent to the processing plant. The mineralization of this sector is therefore very comparable to that of Gabe-Gotes.
Pyromorphite
Formula: Pb5(PO4)3Cl
Reference: This mine worked the same vein as Gabe gottes mine. From the 19th century, ore from a large part of the Saint-Jacques mine network was transported to level -40 of Gabe Gottes before being sent to the processing plant. The mineralization of this sector is therefore very comparable to that of Gabe-Gotes.
Quartz
Formula: SiO2
Reference: This mine worked the same vein as Gabe gottes mine. From the 19th century, ore from a large part of the Saint-Jacques mine network was transported to level -40 of Gabe Gottes before being sent to the processing plant. The mineralization of this sector is therefore very comparable to that of Gabe-Gotes.
Quartz var: Chalcedony
Formula: SiO2
Reference: This mine worked the same vein as Gabe gottes mine. From the 19th century, ore from a large part of the Saint-Jacques mine network was transported to level -40 of Gabe Gottes before being sent to the processing plant. The mineralization of this sector is therefore very comparable to that of Gabe-Gotes.
Rammelsbergite
Formula: NiAs2
Reference: Wittern, Journée: "Mineralien finden in den Vogesen", 1997; This mine worked the same vein as Gabe gottes mine. From the 19th century, ore from a large part of the Saint-Jacques mine network was transported to level -40 of Gabe Gottes before being sent to the processing plant. The mineralization of this sector is therefore very comparable to that of Gabe-Gotes.
Rauenthalite
Formula: Ca3(AsO4)2 · 10H2O
Reference: in the collection of Joachim Esche; This mine worked the same vein as Gabe gottes mine. From the 19th century, ore from a large part of the Saint-Jacques mine network was transported to level -40 of Gabe Gottes before being sent to the processing plant. The mineralization of this sector is therefore very comparable to that of Gabe-Gotes.
Realgar
Formula: As4S4
Reference: This mine worked the same vein as Gabe gottes mine. From the 19th century, ore from a large part of the Saint-Jacques mine network was transported to level -40 of Gabe Gottes before being sent to the processing plant. The mineralization of this sector is therefore very comparable to that of Gabe-Gotes.
Rößlerite
Formula: Mg(HAsO4) · 7H2O
Reference: This mine worked the same vein as Gabe gottes mine. From the 19th century, ore from a large part of the Saint-Jacques mine network was transported to level -40 of Gabe Gottes before being sent to the processing plant. The mineralization of this sector is therefore very comparable to that of Gabe-Gotes.
Safflorite
Formula: (Co,Ni,Fe)As2
Reference: This mine worked the same vein as Gabe gottes mine. From the 19th century, ore from a large part of the Saint-Jacques mine network was transported to level -40 of Gabe Gottes before being sent to the processing plant. The mineralization of this sector is therefore very comparable to that of Gabe-Gotes.
Sainfeldite
Formula: Ca5(AsO4)2(AsO3OH)2 · 4H2O
Reference: This mine worked the same vein as Gabe gottes mine. From the 19th century, ore from a large part of the Saint-Jacques mine network was transported to level -40 of Gabe Gottes before being sent to the processing plant. The mineralization of this sector is therefore very comparable to that of Gabe-Gotes.
Scorodite
Formula: Fe3+AsO4 · 2H2O
Reference: This mine worked the same vein as Gabe gottes mine. From the 19th century, ore from a large part of the Saint-Jacques mine network was transported to level -40 of Gabe Gottes before being sent to the processing plant. The mineralization of this sector is therefore very comparable to that of Gabe-Gotes.
Semseyite
Formula: Pb9Sb8S21
Reference: This mine worked the same vein as Gabe gottes mine. From the 19th century, ore from a large part of the Saint-Jacques mine network was transported to level -40 of Gabe Gottes before being sent to the processing plant. The mineralization of this sector is therefore very comparable to that of Gabe-Gotes.
Siderite
Formula: FeCO3
Reference: This mine worked the same vein as Gabe gottes mine. From the 19th century, ore from a large part of the Saint-Jacques mine network was transported to level -40 of Gabe Gottes before being sent to the processing plant. The mineralization of this sector is therefore very comparable to that of Gabe-Gotes.
Silver
Formula: Ag
Reference: This mine worked the same vein as Gabe gottes mine. From the 19th century, ore from a large part of the Saint-Jacques mine network was transported to level -40 of Gabe Gottes before being sent to the processing plant. The mineralization of this sector is therefore very comparable to that of Gabe-Gotes.
Skutterudite
Formula: CoAs3
Reference: This mine worked the same vein as Gabe gottes mine. From the 19th century, ore from a large part of the Saint-Jacques mine network was transported to level -40 of Gabe Gottes before being sent to the processing plant. The mineralization of this sector is therefore very comparable to that of Gabe-Gotes.
Sphalerite
Formula: ZnS
Reference: This mine worked the same vein as Gabe gottes mine. From the 19th century, ore from a large part of the Saint-Jacques mine network was transported to level -40 of Gabe Gottes before being sent to the processing plant. The mineralization of this sector is therefore very comparable to that of Gabe-Gotes.
'Tennantite'
Formula: Cu6(Cu4X2)As4S12S
Reference: This mine worked the same vein as Gabe gottes mine. From the 19th century, ore from a large part of the Saint-Jacques mine network was transported to level -40 of Gabe Gottes before being sent to the processing plant. The mineralization of this sector is therefore very comparable to that of Gabe-Gotes.
'Tetrahedrite'
Formula: Cu6(Cu4X2)Sb4S13
Reference: This mine worked the same vein as Gabe gottes mine. From the 19th century, ore from a large part of the Saint-Jacques mine network was transported to level -40 of Gabe Gottes before being sent to the processing plant. The mineralization of this sector is therefore very comparable to that of Gabe-Gotes.
Weilite
Formula: Ca(HAsO4)
Reference: This mine worked the same vein as Gabe gottes mine. From the 19th century, ore from a large part of the Saint-Jacques mine network was transported to level -40 of Gabe Gottes before being sent to the processing plant. The mineralization of this sector is therefore very comparable to that of Gabe-Gotes.
Wittichenite
Formula: Cu3BiS3
Reference: This mine worked the same vein as Gabe gottes mine. From the 19th century, ore from a large part of the Saint-Jacques mine network was transported to level -40 of Gabe Gottes before being sent to the processing plant. The mineralization of this sector is therefore very comparable to that of Gabe-Gotes.
Xanthoconite
Formula: Ag3AsS3
Reference: This mine worked the same vein as Gabe gottes mine. From the 19th century, ore from a large part of the Saint-Jacques mine network was transported to level -40 of Gabe Gottes before being sent to the processing plant. The mineralization of this sector is therefore very comparable to that of Gabe-Gotes.

List of minerals arranged by Strunz 10th Edition classification

Group 1 - Elements
Arsenic1.CA.05As
Arsenolamprite1.CA.10As
Bismuth1.CA.05Bi
Silver1.AA.05Ag
Group 2 - Sulphides and Sulfosalts
Acanthite2.BA.35Ag2S
Aikinite2.HB.05aPbCuBiS3
Aramayoite2.HA.25Ag3Sb2(Bi,Sb)S6
Argentopyrite2.CB.65AgFe2S3
Arsenopyrite2.EB.20FeAsS
Baumstarkite2.HA.25Ag3Sb3S6
Berryite2.HB.20dCu3Ag2Pb3Bi7S16
Bismuthinite2.DB.05Bi2S3
Bournonite2.GA.50PbCuSbS3
Chalcopyrite2.CB.10aCuFeS2
Cosalite2.JB.10Pb2Bi2S5
Cubanite2.CB.55aCuFe2S3
Dervillite2.LA.10Ag2AsS2
Dyscrasite2.AA.35Ag3Sb
Emplectite2.HA.05CuBiS2
Galena2.CD.10PbS
Kobellite2.HB.10aPb22Cu4(Bi,Sb)30S69
Lautite2.CB.40CuAsS
Löllingite2.EB.15aFeAs2
Marcasite2.EB.10aFeS2
Matildite2.JA.20AgBiS2
Miargyrite2.HA.10AgSbS2
Nickeline2.CC.05NiAs
Nickelskutterudite2.EC.05(Ni,Co,Fe)As3
Orpiment2.FA.30As2S3
Pararammelsbergite2.EB.10eNiAs2
Pavonite2.JA.05aAgBi3S5
Pearceite2.GB.15[Ag9CuS4][(Ag,Cu)6(As,Sb)2S7]
Polybasite2.GB.15[(Ag,Cu)6(Sb,As)2S7][Ag9CuS4]
Proustite2.GA.05Ag3AsS3
Pyrargyrite2.GA.05Ag3SbS3
Pyrite2.EB.05aFeS2
Rammelsbergite2.EB.15aNiAs2
Realgar2.FA.15aAs4S4
Safflorite2.EB.15a(Co,Ni,Fe)As2
Semseyite2.HC.10dPb9Sb8S21
Skutterudite2.EC.05CoAs3
Sphalerite2.CB.05aZnS
'Tennantite'2.GB.05Cu6(Cu4X2)As4S12S
'Tetrahedrite'2.GB.05Cu6(Cu4X2)Sb4S13
Wittichenite2.GA.20Cu3BiS3
Xanthoconite2.GA.10Ag3AsS3
Group 3 - Halides
Chlorargyrite3.AA.15AgCl
Group 4 - Oxides and Hydroxides
Arsenolite4.CB.50As2O3
Hematite4.CB.05Fe2O3
Quartz4.DA.05SiO2
var: Chalcedony4.DA.05SiO2
Group 5 - Nitrates and Carbonates
Ankerite5.AB.10Ca(Fe2+,Mg)(CO3)2
Aragonite5.AB.15CaCO3
var: Flos Ferri5.AB.15CaCO3
Calcite5.AB.05CaCO3
Dolomite5.AB.10CaMg(CO3)2
Malachite5.BA.10Cu2(CO3)(OH)2
Siderite5.AB.05FeCO3
Group 7 - Sulphates, Chromates, Molybdates and Tungstates
Gypsum7.CD.40CaSO4 · 2H2O
Mirabilite7.CD.10Na2SO4 · 10H2O
Orthoserpierite7.DD.30Ca(Cu,Zn)4(SO4)2(OH)6 · 3H2O
Group 8 - Phosphates, Arsenates and Vanadates
Annabergite8.CE.40Ni3(AsO4)2 · 8H2O
Cornubite8.BD.30Cu5(AsO4)2(OH)4
Ferrarisite8.CJ.30Ca5(AsO4)2(HAsO4)2 · 9H2O
Fluckite8.CB.15CaMn2+(HAsO4)2 · 2H2O
Guérinite8.CJ.75Ca5(AsO4)2(HAsO4)2 · 9H2O
Haidingerite8.CJ.20CaHAsO4 · H2O
Hörnesite8.CE.40Mg3(AsO4)2 · 8H2O
Mcnearite8.CJ.55NaCa5(AsO4)(HAsO4)4 · 4H2O
Mimetite8.BN.05Pb5(AsO4)3Cl
Pharmacolite8.CJ.50Ca(HAsO4) · 2H2O
Phaunouxite8.CJ.40Ca3(AsO4)2 · 11H2O
Picropharmacolite8.CH.15Ca4Mg(AsO4)2(HAsO4)2 · 11H2O
Pyromorphite8.BN.05Pb5(PO4)3Cl
Rauenthalite8.CJ.40Ca3(AsO4)2 · 10H2O
Rößlerite8.CE.20Mg(HAsO4) · 7H2O
Sainfeldite8.CB.10Ca5(AsO4)2(AsO3OH)2 · 4H2O
Scorodite8.CD.10Fe3+AsO4 · 2H2O
Weilite8.AD.10Ca(HAsO4)
Group 9 - Silicates
Kaolinite9.ED.05Al2(Si2O5)(OH)4
Unclassified Minerals, Rocks, etc.
Giftgrubeite-CaMn2Ca2(AsO4)2(AsO3OH)2·4H2O
'Limonite'-(Fe,O,OH,H2O)

List of minerals arranged by Dana 8th Edition classification

Group 1 - NATIVE ELEMENTS AND ALLOYS
Metals, other than the Platinum Group
Silver1.1.1.2Ag
Semi-metals and non-metals
Arsenic1.3.1.1As
Arsenolamprite1.3.2.1As
Bismuth1.3.1.4Bi
Group 2 - SULFIDES
AmBnXp, with (m+n):p = 3:1
Dyscrasite2.2.1.1Ag3Sb
AmBnXp, with (m+n):p = 2:1
Acanthite2.4.1.1Ag2S
AmXp, with m:p = 1:1
Galena2.8.1.1PbS
Nickeline2.8.11.1NiAs
Realgar2.8.21.1As4S4
Sphalerite2.8.2.1ZnS
AmBnXp, with (m+n):p = 1:1
Argentopyrite2.9.13.2AgFe2S3
Chalcopyrite2.9.1.1CuFeS2
Cubanite2.9.13.1CuFe2S3
AmBnXp, with (m+n):p = 2:3
Bismuthinite2.11.2.3Bi2S3
Orpiment2.11.1.1As2S3
AmBnXp, with (m+n):p = 1:2
Arsenopyrite2.12.4.1FeAsS
Lautite2.12.8.1CuAsS
Löllingite2.12.2.9FeAs2
Marcasite2.12.2.1FeS2
Nickelskutterudite2.12.17.2(Ni,Co,Fe)As3
Pararammelsbergite2.12.5.1NiAs2
Pyrite2.12.1.1FeS2
Rammelsbergite2.12.2.12NiAs2
Safflorite2.12.2.11(Co,Ni,Fe)As2
Skutterudite2.12.17.1CoAs3
Group 3 - SULFOSALTS
ø > 4
Pearceite3.1.8.1[Ag9CuS4][(Ag,Cu)6(As,Sb)2S7]
Polybasite3.1.7.2[(Ag,Cu)6(Sb,As)2S7][Ag9CuS4]
3 <ø < 4
'Tennantite'3.3.6.2Cu6(Cu4X2)As4S12S
'Tetrahedrite'3.3.6.1Cu6(Cu4X2)Sb4S13
ø = 3
Aikinite3.4.5.1PbCuBiS3
Bournonite3.4.3.2PbCuSbS3
Proustite3.4.1.1Ag3AsS3
Pyrargyrite3.4.1.2Ag3SbS3
Wittichenite3.4.8.1Cu3BiS3
Xanthoconite3.4.2.1Ag3AsS3
2.5 < ø < 3
Cosalite3.5.9.1Pb2Bi2S5
2 < ø < 2.49
Berryite3.6.15.1Cu3Ag2Pb3Bi7S16
Kobellite3.6.19.1Pb22Cu4(Bi,Sb)30S69
Semseyite3.6.20.4Pb9Sb8S21
ø = 2
Aramayoite3.7.4.1Ag3Sb2(Bi,Sb)S6
Dervillite3.7.17.1Ag2AsS2
Emplectite3.7.5.2CuBiS2
Matildite3.7.1.1AgBiS2
Miargyrite3.7.3.2AgSbS2
1 < ø < 2
Pavonite3.8.10.1AgBi3S5
Group 4 - SIMPLE OXIDES
A2X3
Arsenolite4.3.9.1As2O3
Hematite4.3.1.2Fe2O3
Group 9 - NORMAL HALIDES
AX
Chlorargyrite9.1.4.1AgCl
Group 14 - ANHYDROUS NORMAL CARBONATES
A(XO3)
Calcite14.1.1.1CaCO3
Siderite14.1.1.3FeCO3
AB(XO3)2
Ankerite14.2.1.2Ca(Fe2+,Mg)(CO3)2
Dolomite14.2.1.1CaMg(CO3)2
Group 16a - ANHYDROUS CARBONATES CONTAINING HYDROXYL OR HALOGEN
Malachite16a.3.1.1Cu2(CO3)(OH)2
Group 29 - HYDRATED ACID AND NORMAL SULFATES
A2XO4·xH2O
Mirabilite29.2.2.1Na2SO4 · 10H2O
AXO4·xH2O
Gypsum29.6.3.1CaSO4 · 2H2O
Group 31 - HYDRATED SULFATES CONTAINING HYDROXYL OR HALOGEN
(AB)5(XO4)2Zq·xH2O
Orthoserpierite31.6.7.1Ca(Cu,Zn)4(SO4)2(OH)6 · 3H2O
Group 37 - ANHYDROUS ACID PHOSPHATES, ARSENATES AND VANADATES
Miscellaneous
Weilite37.1.1.2Ca(HAsO4)
Group 39 - HYDRATED ACID PHOSPHATES,ARSENATES AND VANADATES
A[HXO4]·xH2O
Fluckite39.1.2.1CaMn2+(HAsO4)2 · 2H2O
Haidingerite39.1.5.1CaHAsO4 · H2O
Pharmacolite39.1.1.2Ca(HAsO4) · 2H2O
Rößlerite39.1.9.1Mg(HAsO4) · 7H2O
(AB)5[HXO4]2[XO4]2.xH2O
Ferrarisite39.2.3.1Ca5(AsO4)2(HAsO4)2 · 9H2O
Guérinite39.2.2.2Ca5(AsO4)2(HAsO4)2 · 9H2O
Picropharmacolite39.2.4.1Ca4Mg(AsO4)2(HAsO4)2 · 11H2O
Sainfeldite39.2.1.2Ca5(AsO4)2(AsO3OH)2 · 4H2O
Miscellaneous
Mcnearite39.3.7.1NaCa5(AsO4)(HAsO4)4 · 4H2O
Group 40 - HYDRATED NORMAL PHOSPHATES,ARSENATES AND VANADATES
A3(XO4)2·xH2O
Annabergite40.3.6.4Ni3(AsO4)2 · 8H2O
Hörnesite40.3.6.7Mg3(AsO4)2 · 8H2O
Phaunouxite40.3.12.1Ca3(AsO4)2 · 11H2O
Rauenthalite40.3.11.1Ca3(AsO4)2 · 10H2O
(AB)5(XO4)2·xH2O
Scorodite40.4.1.3Fe3+AsO4 · 2H2O
Group 41 - ANHYDROUS PHOSPHATES, ETC.CONTAINING HYDROXYL OR HALOGEN
(AB)5(XO4)2Zq
Cornubite41.4.2.1Cu5(AsO4)2(OH)4
A5(XO4)3Zq
Mimetite41.8.4.2Pb5(AsO4)3Cl
Pyromorphite41.8.4.1Pb5(PO4)3Cl
Group 75 - TECTOSILICATES Si Tetrahedral Frameworks
Si Tetrahedral Frameworks - SiO2 with [4] coordinated Si
Quartz75.1.3.1SiO2
Unclassified Minerals, Mixtures, etc.
Aragonite-CaCO3
var: Flos Ferri-CaCO3
Baumstarkite-Ag3Sb3S6
Giftgrubeite-CaMn2Ca2(AsO4)2(AsO3OH)2·4H2O
Kaolinite-Al2(Si2O5)(OH)4
'Limonite'-(Fe,O,OH,H2O)
Quartz
var: Chalcedony
-SiO2

List of minerals for each chemical element

HHydrogen
H AnnabergiteNi3(AsO4)2 · 8H2O
H CornubiteCu5(AsO4)2(OH)4
H RauenthaliteCa3(AsO4)2 · 10H2O
H FerrarisiteCa5(AsO4)2(HAsO4)2 · 9H2O
H FluckiteCaMn2+(HAsO4)2 · 2H2O
H GiftgrubeiteCaMn2Ca2(AsO4)2(AsO3OH)2·4H2O
H GuériniteCa5(AsO4)2(HAsO4)2 · 9H2O
H GypsumCaSO4 · 2H2O
H HaidingeriteCaHAsO4 · H2O
H HörnesiteMg3(AsO4)2 · 8H2O
H KaoliniteAl2(Si2O5)(OH)4
H Limonite(Fe,O,OH,H2O)
H MalachiteCu2(CO3)(OH)2
H McneariteNaCa5(AsO4)(HAsO4)4 · 4H2O
H MirabiliteNa2SO4 · 10H2O
H OrthoserpieriteCa(Cu,Zn)4(SO4)2(OH)6 · 3H2O
H PharmacoliteCa(HAsO4) · 2H2O
H PhaunouxiteCa3(AsO4)2 · 11H2O
H PicropharmacoliteCa4Mg(AsO4)2(HAsO4)2 · 11H2O
H RößleriteMg(HAsO4) · 7H2O
H SainfelditeCa5(AsO4)2(AsO3OH)2 · 4H2O
H ScoroditeFe3+AsO4 · 2H2O
H WeiliteCa(HAsO4)
CCarbon
C Aragonite (var: Flos Ferri)CaCO3
C AragoniteCaCO3
C AnkeriteCa(Fe2+,Mg)(CO3)2
C CalciteCaCO3
C DolomiteCaMg(CO3)2
C MalachiteCu2(CO3)(OH)2
C SideriteFeCO3
OOxygen
O Aragonite (var: Flos Ferri)CaCO3
O AnnabergiteNi3(AsO4)2 · 8H2O
O CornubiteCu5(AsO4)2(OH)4
O AragoniteCaCO3
O RauenthaliteCa3(AsO4)2 · 10H2O
O AnkeriteCa(Fe2+,Mg)(CO3)2
O ArsenoliteAs2O3
O CalciteCaCO3
O Quartz (var: Chalcedony)SiO2
O DolomiteCaMg(CO3)2
O FerrarisiteCa5(AsO4)2(HAsO4)2 · 9H2O
O FluckiteCaMn2+(HAsO4)2 · 2H2O
O GiftgrubeiteCaMn2Ca2(AsO4)2(AsO3OH)2·4H2O
O GuériniteCa5(AsO4)2(HAsO4)2 · 9H2O
O GypsumCaSO4 · 2H2O
O HaidingeriteCaHAsO4 · H2O
O HematiteFe2O3
O HörnesiteMg3(AsO4)2 · 8H2O
O KaoliniteAl2(Si2O5)(OH)4
O Limonite(Fe,O,OH,H2O)
O MalachiteCu2(CO3)(OH)2
O McneariteNaCa5(AsO4)(HAsO4)4 · 4H2O
O MimetitePb5(AsO4)3Cl
O MirabiliteNa2SO4 · 10H2O
O OrthoserpieriteCa(Cu,Zn)4(SO4)2(OH)6 · 3H2O
O PharmacoliteCa(HAsO4) · 2H2O
O PhaunouxiteCa3(AsO4)2 · 11H2O
O PicropharmacoliteCa4Mg(AsO4)2(HAsO4)2 · 11H2O
O PyromorphitePb5(PO4)3Cl
O QuartzSiO2
O RößleriteMg(HAsO4) · 7H2O
O SainfelditeCa5(AsO4)2(AsO3OH)2 · 4H2O
O ScoroditeFe3+AsO4 · 2H2O
O SideriteFeCO3
O WeiliteCa(HAsO4)
NaSodium
Na McneariteNaCa5(AsO4)(HAsO4)4 · 4H2O
Na MirabiliteNa2SO4 · 10H2O
MgMagnesium
Mg AnkeriteCa(Fe2+,Mg)(CO3)2
Mg DolomiteCaMg(CO3)2
Mg HörnesiteMg3(AsO4)2 · 8H2O
Mg PicropharmacoliteCa4Mg(AsO4)2(HAsO4)2 · 11H2O
Mg RößleriteMg(HAsO4) · 7H2O
AlAluminium
Al KaoliniteAl2(Si2O5)(OH)4
SiSilicon
Si Quartz (var: Chalcedony)SiO2
Si KaoliniteAl2(Si2O5)(OH)4
Si QuartzSiO2
PPhosphorus
P PyromorphitePb5(PO4)3Cl
SSulfur
S AcanthiteAg2S
S AikinitePbCuBiS3
S AramayoiteAg3Sb2(Bi,Sb)S6
S ArgentopyriteAgFe2S3
S ArsenopyriteFeAsS
S BaumstarkiteAg3Sb3S6
S BerryiteCu3Ag2Pb3Bi7S16
S BismuthiniteBi2S3
S BournonitePbCuSbS3
S ChalcopyriteCuFeS2
S CosalitePb2Bi2S5
S CubaniteCuFe2S3
S DervilliteAg2AsS2
S EmplectiteCuBiS2
S GalenaPbS
S GypsumCaSO4 · 2H2O
S KobellitePb22Cu4(Bi,Sb)30S69
S LautiteCuAsS
S MarcasiteFeS2
S MatilditeAgBiS2
S MiargyriteAgSbS2
S MirabiliteNa2SO4 · 10H2O
S OrpimentAs2S3
S OrthoserpieriteCa(Cu,Zn)4(SO4)2(OH)6 · 3H2O
S PavoniteAgBi3S5
S Pearceite[Ag9CuS4][(Ag,Cu)6(As,Sb)2S7]
S Polybasite[(Ag,Cu)6(Sb,As)2S7][Ag9CuS4]
S ProustiteAg3AsS3
S PyrargyriteAg3SbS3
S PyriteFeS2
S RealgarAs4S4
S SemseyitePb9Sb8S21
S SphaleriteZnS
S TennantiteCu6(Cu4X2)As4S12S
S TetrahedriteCu6(Cu4X2)Sb4S13
S WitticheniteCu3BiS3
S XanthoconiteAg3AsS3
ClChlorine
Cl ChlorargyriteAgCl
Cl MimetitePb5(AsO4)3Cl
Cl PyromorphitePb5(PO4)3Cl
CaCalcium
Ca Aragonite (var: Flos Ferri)CaCO3
Ca AragoniteCaCO3
Ca RauenthaliteCa3(AsO4)2 · 10H2O
Ca AnkeriteCa(Fe2+,Mg)(CO3)2
Ca CalciteCaCO3
Ca DolomiteCaMg(CO3)2
Ca FerrarisiteCa5(AsO4)2(HAsO4)2 · 9H2O
Ca FluckiteCaMn2+(HAsO4)2 · 2H2O
Ca GiftgrubeiteCaMn2Ca2(AsO4)2(AsO3OH)2·4H2O
Ca GuériniteCa5(AsO4)2(HAsO4)2 · 9H2O
Ca GypsumCaSO4 · 2H2O
Ca HaidingeriteCaHAsO4 · H2O
Ca McneariteNaCa5(AsO4)(HAsO4)4 · 4H2O
Ca OrthoserpieriteCa(Cu,Zn)4(SO4)2(OH)6 · 3H2O
Ca PharmacoliteCa(HAsO4) · 2H2O
Ca PhaunouxiteCa3(AsO4)2 · 11H2O
Ca PicropharmacoliteCa4Mg(AsO4)2(HAsO4)2 · 11H2O
Ca SainfelditeCa5(AsO4)2(AsO3OH)2 · 4H2O
Ca WeiliteCa(HAsO4)
MnManganese
Mn FluckiteCaMn2+(HAsO4)2 · 2H2O
Mn GiftgrubeiteCaMn2Ca2(AsO4)2(AsO3OH)2·4H2O
FeIron
Fe Nickelskutterudite(Ni,Co,Fe)As3
Fe AnkeriteCa(Fe2+,Mg)(CO3)2
Fe ArgentopyriteAgFe2S3
Fe ArsenopyriteFeAsS
Fe ChalcopyriteCuFeS2
Fe CubaniteCuFe2S3
Fe HematiteFe2O3
Fe KobellitePb22Cu4(Bi,Sb)30S69
Fe Limonite(Fe,O,OH,H2O)
Fe LöllingiteFeAs2
Fe MarcasiteFeS2
Fe PyriteFeS2
Fe ScoroditeFe3+AsO4 · 2H2O
Fe SideriteFeCO3
CoCobalt
Co Nickelskutterudite(Ni,Co,Fe)As3
Co Safflorite(Co,Ni,Fe)As2
Co SkutteruditeCoAs3
NiNickel
Ni Nickelskutterudite(Ni,Co,Fe)As3
Ni PararammelsbergiteNiAs2
Ni NickelineNiAs
Ni AnnabergiteNi3(AsO4)2 · 8H2O
Ni RammelsbergiteNiAs2
CuCopper
Cu CornubiteCu5(AsO4)2(OH)4
Cu AikinitePbCuBiS3
Cu BerryiteCu3Ag2Pb3Bi7S16
Cu BournonitePbCuSbS3
Cu ChalcopyriteCuFeS2
Cu CubaniteCuFe2S3
Cu EmplectiteCuBiS2
Cu KobellitePb22Cu4(Bi,Sb)30S69
Cu LautiteCuAsS
Cu MalachiteCu2(CO3)(OH)2
Cu OrthoserpieriteCa(Cu,Zn)4(SO4)2(OH)6 · 3H2O
Cu Pearceite[Ag9CuS4][(Ag,Cu)6(As,Sb)2S7]
Cu Polybasite[(Ag,Cu)6(Sb,As)2S7][Ag9CuS4]
Cu TennantiteCu6(Cu4X2)As4S12S
Cu TetrahedriteCu6(Cu4X2)Sb4S13
Cu WitticheniteCu3BiS3
ZnZinc
Zn OrthoserpieriteCa(Cu,Zn)4(SO4)2(OH)6 · 3H2O
Zn SphaleriteZnS
AsArsenic
As Nickelskutterudite(Ni,Co,Fe)As3
As PararammelsbergiteNiAs2
As NickelineNiAs
As AnnabergiteNi3(AsO4)2 · 8H2O
As CornubiteCu5(AsO4)2(OH)4
As RammelsbergiteNiAs2
As RauenthaliteCa3(AsO4)2 · 10H2O
As ArsenicAs
As ArsenolampriteAs
As ArsenoliteAs2O3
As ArsenopyriteFeAsS
As DervilliteAg2AsS2
As FerrarisiteCa5(AsO4)2(HAsO4)2 · 9H2O
As FluckiteCaMn2+(HAsO4)2 · 2H2O
As GiftgrubeiteCaMn2Ca2(AsO4)2(AsO3OH)2·4H2O
As GuériniteCa5(AsO4)2(HAsO4)2 · 9H2O
As HaidingeriteCaHAsO4 · H2O
As HörnesiteMg3(AsO4)2 · 8H2O
As LautiteCuAsS
As LöllingiteFeAs2
As McneariteNaCa5(AsO4)(HAsO4)4 · 4H2O
As MimetitePb5(AsO4)3Cl
As OrpimentAs2S3
As Pearceite[Ag9CuS4][(Ag,Cu)6(As,Sb)2S7]
As PharmacoliteCa(HAsO4) · 2H2O
As PhaunouxiteCa3(AsO4)2 · 11H2O
As PicropharmacoliteCa4Mg(AsO4)2(HAsO4)2 · 11H2O
As Polybasite[(Ag,Cu)6(Sb,As)2S7][Ag9CuS4]
As ProustiteAg3AsS3
As RealgarAs4S4
As RößleriteMg(HAsO4) · 7H2O
As Safflorite(Co,Ni,Fe)As2
As SainfelditeCa5(AsO4)2(AsO3OH)2 · 4H2O
As ScoroditeFe3+AsO4 · 2H2O
As SkutteruditeCoAs3
As TennantiteCu6(Cu4X2)As4S12S
As WeiliteCa(HAsO4)
As XanthoconiteAg3AsS3
AgSilver
Ag AcanthiteAg2S
Ag AramayoiteAg3Sb2(Bi,Sb)S6
Ag ArgentopyriteAgFe2S3
Ag BaumstarkiteAg3Sb3S6
Ag BerryiteCu3Ag2Pb3Bi7S16
Ag ChlorargyriteAgCl
Ag DervilliteAg2AsS2
Ag DyscrasiteAg3Sb
Ag MatilditeAgBiS2
Ag MiargyriteAgSbS2
Ag PavoniteAgBi3S5
Ag Pearceite[Ag9CuS4][(Ag,Cu)6(As,Sb)2S7]
Ag Polybasite[(Ag,Cu)6(Sb,As)2S7][Ag9CuS4]
Ag ProustiteAg3AsS3
Ag PyrargyriteAg3SbS3
Ag SilverAg
Ag XanthoconiteAg3AsS3
SbAntimony
Sb AramayoiteAg3Sb2(Bi,Sb)S6
Sb BaumstarkiteAg3Sb3S6
Sb BournonitePbCuSbS3
Sb DyscrasiteAg3Sb
Sb KobellitePb22Cu4(Bi,Sb)30S69
Sb MiargyriteAgSbS2
Sb Pearceite[Ag9CuS4][(Ag,Cu)6(As,Sb)2S7]
Sb Polybasite[(Ag,Cu)6(Sb,As)2S7][Ag9CuS4]
Sb PyrargyriteAg3SbS3
Sb SemseyitePb9Sb8S21
Sb TetrahedriteCu6(Cu4X2)Sb4S13
PbLead
Pb AikinitePbCuBiS3
Pb BerryiteCu3Ag2Pb3Bi7S16
Pb BournonitePbCuSbS3
Pb CosalitePb2Bi2S5
Pb GalenaPbS
Pb KobellitePb22Cu4(Bi,Sb)30S69
Pb MimetitePb5(AsO4)3Cl
Pb PyromorphitePb5(PO4)3Cl
Pb SemseyitePb9Sb8S21
BiBismuth
Bi AikinitePbCuBiS3
Bi AramayoiteAg3Sb2(Bi,Sb)S6
Bi BerryiteCu3Ag2Pb3Bi7S16
Bi BismuthBi
Bi BismuthiniteBi2S3
Bi CosalitePb2Bi2S5
Bi EmplectiteCuBiS2
Bi KobellitePb22Cu4(Bi,Sb)30S69
Bi MatilditeAgBiS2
Bi PavoniteAgBi3S5
Bi WitticheniteCu3BiS3

Other Regions, Features and Areas containing this locality

Eurasian PlateTectonic Plate
EuropeContinent

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