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Neves-Corvo Mine, Santa Bárbara de Padrões, Castro Verde, Beja, Portugali
Regional Level Types
Neves-Corvo MineMine (Active)
Santa Bárbara de Padrões- not defined -
Castro Verde- not defined -
BejaDistrict
PortugalCountry

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Key
Latitude & Longitude (WGS84):
37° 34' 23'' North , 7° 58' 14'' West
Latitude & Longitude (decimal):
Locality type:
Mine (Active) - last checked 2018
Nearest Settlements:
PlacePopulationDistance
Almodôvar7,449 (2018)10.3km
Castro Verde4,857 (2014)17.2km
Mértola7,274 (2018)28.4km
Aljustrel5,334 (2018)37.9km
Cabeça Gorda1,386 (2018)42.0km
Owned/operated by:
Name(s) in local language(s):
Mina de Neves-Corvo, Santa Bárbara de Padrões, Castro Verde, Distrito de Beja, Portugal


A volcanic-hosted massive sulfide (VHMS) deposit of the Iberian pyrite belt, which consists of five orebodies (Corvo, Graça, Neves, Lombador and Zambujal). This is one of the most gigantic deposits of massive sulphides in the world. It was discovered in 1977.
The copper-zinc-silver mine started 1984. Was to have produced 1 million tons/year ore by 1987. Previously owned by RTZ (49%) & Somincor. Lundin Mining acquired Neves-Corvo as part of the company's 2006 merger with EuroZinc Mining.

Located 100 km north of Faro.

Seven massive sulphide lenses have been defined at Neves-Corvo comprising Neves (divided into North and South), Corvo, Graça, Zambujal, Lombador (divided North, South and East), Semblana and Monte Branco. The base metal grades are segregated by the strong metal zoning into copper, tin and zinc zones, as well as barren massive pyrite. The massive sulphide deposits are typically underlain by stockwork sulphide zones which form an important part of the copper orebodies.

Select Mineral List Type

Standard Detailed Gallery Strunz Dana Chemical Elements

Commodity List

This is a list of exploitable or exploited mineral commodities recorded at this locality.


Mineral List


60 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:

Aikinite
Formula: PbCuBiS3
Reference: Gaspar, O.C. (2002): Mineralogy and sulfide mineral chemistry of the Neves–Corvo Ores, Portugal: insight into their genesis. Canadian Mineralogist 40, 611-636.
Alloclasite
Formula: Co1-xFexAsS
Reference: Cabri, L. J., Gaspar, O. C., Lastra, R., & McMahon, G. (1998). Distribution of gold in tin-rich samples from the Corvo orebody, Portugal. The Canadian Mineralogist, 36(5), 1347-1360.
Ankerite
Formula: Ca(Fe2+,Mg)(CO3)2
Reference: Relvas, J. M. R. S. et al. (2006): Hydrothermal Alteration and Mineralization in the Neves-Corvo Volcanic-Hosted Massive Sulfide Deposit, Portugal. I. Geology, Mineralogy, and Geochemistry. Econ. Geology 101, 753-790.
Arsenopyrite
Formula: FeAsS
Reference: Relvas, J. M. R. S. et al. (2006): Hydrothermal Alteration and Mineralization in the Neves-Corvo Volcanic-Hosted Massive Sulfide Deposit, Portugal. I. Geology, Mineralogy, and Geochemistry. Econ. Geology 101, 753-790.; Serranti, S., Ferrini, V., Masi, U., & Cabri, L. J. (2002). Trace-element distribution in cassiterite and sulfides from rubané and massive ores of the Corvo deposit, Portugal. The Canadian Mineralogist, 40(3), 815-835.; Cabri, L. J., Gaspar, O. C., Lastra, R., & McMahon, G. (1998). Distribution of gold in tin-rich samples from the Corvo orebody, Portugal. The Canadian Mineralogist, 36(5), 1347-1360.; Gaspar, O.C. (2002): Mineralogy and sulfide mineral chemistry of the Neves–Corvo Ores, Portugal: insight into their genesis. Canadian Mineralogist 40, 611-636.
Baryte
Formula: BaSO4
Betekhtinite
Formula: (Cu,Fe)21Pb2S15
Reference: Gaspar, O.C. (2002): Mineralogy and sulfide mineral chemistry of the Neves–Corvo Ores, Portugal: insight into their genesis. Canadian Mineralogist 40, 611-636.
Bismuth
Formula: Bi
Reference: Cabri, L. J., Gaspar, O. C., Lastra, R., & McMahon, G. (1998). Distribution of gold in tin-rich samples from the Corvo orebody, Portugal. The Canadian Mineralogist, 36(5), 1347-1360.
Bismuthinite
Formula: Bi2S3
Reference: Relvas, J.M.R.S., Tassinari, C.C.G., Munhá, J., and Barriga, F.J.A.S. (2001): Mineralium Deposita 36, 416-427.
Bohdanowiczite
Formula: AgBiSe2
Reference: Gaspar, O.C. (2002): Mineralogy and sulfide mineral chemistry of the Neves–Corvo Ores, Portugal: insight into their genesis. Canadian Mineralogist 40, 611-636.
Bornite
Formula: Cu5FeS4
Reference: Relvas, J.M.R.S., Tassinari, C.C.G., Munhá, J., and Barriga, F.J.A.S. (2001): Mineralium Deposita 36, 416-427.; Gaspar, O.C. (2002): Mineralogy and sulfide mineral chemistry of the Neves–Corvo Ores, Portugal: insight into their genesis. Canadian Mineralogist 40, 611-636.
Bournonite
Formula: PbCuSbS3
Reference: Relvas, J.M.R.S., Tassinari, C.C.G., Munhá, J., and Barriga, F.J.A.S. (2001): Mineralium Deposita 36, 416-427.; Gaspar, O.C. (2002): Mineralogy and sulfide mineral chemistry of the Neves–Corvo Ores, Portugal: insight into their genesis. Canadian Mineralogist 40, 611-636.
Calcite
Formula: CaCO3
Reference: Cabri, L. J., Gaspar, O. C., Lastra, R., & McMahon, G. (1998). Distribution of gold in tin-rich samples from the Corvo orebody, Portugal. The Canadian Mineralogist, 36(5), 1347-1360.
Carrollite
Formula: Cu(Co,Ni)2S4
Reference: Pinto, A., Bowles, J. F. W., & Gaspar, O. C. (1994). The mineral chemistry and textures of wittichenite, miharaite, carrolite, mawsonite and In±Bi±Hg tennantite from Neves-Corvo, Portugal. IMA 94. In XVI General Meeting of IMA, Pisa, ItaÂlia, Abstracts.; Cabri, L. J., Gaspar, O. C., Lastra, R., & McMahon, G. (1998). Distribution of gold in tin-rich samples from the Corvo orebody, Portugal. The Canadian Mineralogist, 36(5), 1347-1360.; Gaspar, O.C. (2002): Mineralogy and sulfide mineral chemistry of the Neves–Corvo Ores, Portugal: insight into their genesis. Canadian Mineralogist 40, 611-636.
Cassiterite
Formula: SnO2
Reference: Relvas, J. M. R. S. et al. (2006): Hydrothermal Alteration and Mineralization in the Neves-Corvo Volcanic-Hosted Massive Sulfide Deposit, Portugal. I. Geology, Mineralogy, and Geochemistry. Econ. Geology 101, 753-790.; Benzaazoua, M., Marion, P., Pinto, A., Migeon, H., & Wagner, F. E. (2003). Tin and indium mineralogy within selected samples from the Neves Corvo ore deposit (Portugal): a multidisciplinary study. Minerals Engineering, 16(11), 1291-1302.; Serranti, S., Ferrini, V., Masi, U., & Cabri, L. J. (2002). Trace-element distribution in cassiterite and sulfides from rubané and massive ores of the Corvo deposit, Portugal. The Canadian Mineralogist, 40(3), 815-835.; Cabri, L. J., Gaspar, O. C., Lastra, R., & McMahon, G. (1998). Distribution of gold in tin-rich samples from the Corvo orebody, Portugal. The Canadian Mineralogist, 36(5), 1347-1360.; Gaspar, O.C. (2002): Mineralogy and sulfide mineral chemistry of the Neves–Corvo Ores, Portugal: insight into their genesis. Canadian Mineralogist 40, 611-636.
Chalcopyrite
Formula: CuFeS2
Reference: Relvas, J. M. R. S. et al. (2006): Hydrothermal Alteration and Mineralization in the Neves-Corvo Volcanic-Hosted Massive Sulfide Deposit, Portugal. I. Geology, Mineralogy, and Geochemistry. Econ. Geology 101, 753-790.; Benzaazoua, M., Marion, P., Pinto, A., Migeon, H., & Wagner, F. E. (2003). Tin and indium mineralogy within selected samples from the Neves Corvo ore deposit (Portugal): a multidisciplinary study. Minerals Engineering, 16(11), 1291-1302.; Serranti, S., Ferrini, V., Masi, U., & Cabri, L. J. (2002). Trace-element distribution in cassiterite and sulfides from rubané and massive ores of the Corvo deposit, Portugal. The Canadian Mineralogist, 40(3), 815-835.; Cabri, L. J., Gaspar, O. C., Lastra, R., & McMahon, G. (1998). Distribution of gold in tin-rich samples from the Corvo orebody, Portugal. The Canadian Mineralogist, 36(5), 1347-1360.; Gaspar, O.C. (2002): Mineralogy and sulfide mineral chemistry of the Neves–Corvo Ores, Portugal: insight into their genesis. Canadian Mineralogist 40, 611-636.
Chalcostibite
Formula: CuSbS2
Reference: Gaspar, O.C. (2002): Mineralogy and sulfide mineral chemistry of the Neves–Corvo Ores, Portugal: insight into their genesis. Canadian Mineralogist 40, 611-636.
Chamosite
Formula: (Fe2+,Mg,Al,Fe3+)6(Si,Al)4O10(OH,O)8
Reference: Relvas, J. M. R. S. et al. (2006): Hydrothermal Alteration and Mineralization in the Neves-Corvo Volcanic-Hosted Massive Sulfide Deposit, Portugal. I. Geology, Mineralogy, and Geochemistry. Econ. Geology 101, 753-790.; Cabri, L. J., Gaspar, O. C., Lastra, R., & McMahon, G. (1998). Distribution of gold in tin-rich samples from the Corvo orebody, Portugal. The Canadian Mineralogist, 36(5), 1347-1360.
'Chlorite Group'
Reference: Relvas, J. M. R. S. et al. (2006): Hydrothermal Alteration and Mineralization in the Neves-Corvo Volcanic-Hosted Massive Sulfide Deposit, Portugal. I. Geology, Mineralogy, and Geochemistry. Econ. Geology 101, 753-790.; Serranti, S., Ferrini, V., Masi, U., & Cabri, L. J. (2002). Trace-element distribution in cassiterite and sulfides from rubané and massive ores of the Corvo deposit, Portugal. The Canadian Mineralogist, 40(3), 815-835.; Cabri, L. J., Gaspar, O. C., Lastra, R., & McMahon, G. (1998). Distribution of gold in tin-rich samples from the Corvo orebody, Portugal. The Canadian Mineralogist, 36(5), 1347-1360.
Clausthalite
Formula: PbSe
Reference: Cabri, L. J., Gaspar, O. C., Lastra, R., & McMahon, G. (1998). Distribution of gold in tin-rich samples from the Corvo orebody, Portugal. The Canadian Mineralogist, 36(5), 1347-1360.
Cobaltite
Formula: CoAsS
Reference: Relvas, J.M.R.S., Tassinari, C.C.G., Munhá, J., and Barriga, F.J.A.S. (2001): Mineralium Deposita 36, 416-427.; Cabri, L. J., Gaspar, O. C., Lastra, R., & McMahon, G. (1998). Distribution of gold in tin-rich samples from the Corvo orebody, Portugal. The Canadian Mineralogist, 36(5), 1347-1360.
Coloradoite
Formula: HgTe
Reference: Gaspar, O.C. (2002): Mineralogy and sulfide mineral chemistry of the Neves–Corvo Ores, Portugal: insight into their genesis. Canadian Mineralogist 40, 611-636.
Colusite
Formula: Cu13VAs3S16
Reference: Cabri, L. J., Gaspar, O. C., Lastra, R., & McMahon, G. (1998). Distribution of gold in tin-rich samples from the Corvo orebody, Portugal. The Canadian Mineralogist, 36(5), 1347-1360.
Dolomite
Formula: CaMg(CO3)2
Reference: Rui Nunes collection; Serranti, S., Ferrini, V., Masi, U., & Cabri, L. J. (2002). Trace-element distribution in cassiterite and sulfides from rubané and massive ores of the Corvo deposit, Portugal. The Canadian Mineralogist, 40(3), 815-835.; Cabri, L. J., Gaspar, O. C., Lastra, R., & McMahon, G. (1998). Distribution of gold in tin-rich samples from the Corvo orebody, Portugal. The Canadian Mineralogist, 36(5), 1347-1360.
Donbassite
Formula: Al4.33(AlSi3O10)(OH)8
Reference: Relvas, J. M. R. S. et al. (2006): Hydrothermal Alteration and Mineralization in the Neves-Corvo Volcanic-Hosted Massive Sulfide Deposit, Portugal. I. Geology, Mineralogy, and Geochemistry. Econ. Geology 101, 753-790.
'Freibergite Subgroup'
Formula: ([Ag6]4+,(Ag,Cu)6)((Cu,Ag)4X2+2)Sb4S12S0-1
Reference: Relvas, J.M.R.S., Tassinari, C.C.G., Munhá, J., and Barriga, F.J.A.S. (2001): Mineralium Deposita 36, 416-427.
Galena
Formula: PbS
Reference: Relvas, J. M. R. S. et al. (2006): Hydrothermal Alteration and Mineralization in the Neves-Corvo Volcanic-Hosted Massive Sulfide Deposit, Portugal. I. Geology, Mineralogy, and Geochemistry. Econ. Geology 101, 753-790.; Gaspar, O.C. (2002): Mineralogy and sulfide mineral chemistry of the Neves–Corvo Ores, Portugal: insight into their genesis. Canadian Mineralogist 40, 611-636.
Galenobismutite
Formula: PbBi2S4
Reference: Gaspar, O.C. (2002): Mineralogy and sulfide mineral chemistry of the Neves–Corvo Ores, Portugal: insight into their genesis. Canadian Mineralogist 40, 611-636.
Glaucodot
Formula: (Co0.50Fe0.50)AsS
Reference: Cabri, L. J., Gaspar, O. C., Lastra, R., & McMahon, G. (1998). Distribution of gold in tin-rich samples from the Corvo orebody, Portugal. The Canadian Mineralogist, 36(5), 1347-1360.
Gold
Formula: Au
Reference: Relvas, J.M.R.S., Tassinari, C.C.G., Munhá, J., and Barriga, F.J.A.S. (2001): Mineralium Deposita 36, 416-427.; Gaspar, O.C. (2002): Mineralogy and sulfide mineral chemistry of the Neves–Corvo Ores, Portugal: insight into their genesis. Canadian Mineralogist 40, 611-636.
Gold var. Electrum
Formula: (Au,Ag)
Reference: Relvas, J.M.R.S., Tassinari, C.C.G., Munhá, J., and Barriga, F.J.A.S. (2001): Mineralium Deposita 36, 416-427.
Graphite
Formula: C
Reference: Relvas, J.M.R.S., Tassinari, C.C.G., Munhá, J., and Barriga, F.J.A.S. (2001): Mineralium Deposita 36, 416-427.
Gudmundite
Formula: FeSbS
Reference: Gaspar, O.C. (2002): Mineralogy and sulfide mineral chemistry of the Neves–Corvo Ores, Portugal: insight into their genesis. Canadian Mineralogist 40, 611-636.
Hematite
Formula: Fe2O3
Reference: Gaspar, O.C. (2002): Mineralogy and sulfide mineral chemistry of the Neves–Corvo Ores, Portugal: insight into their genesis. Canadian Mineralogist 40, 611-636.
Joséite-B
Formula: Bi4Te2S
Reference: Cabri, L. J., Gaspar, O. C., Lastra, R., & McMahon, G. (1998). Distribution of gold in tin-rich samples from the Corvo orebody, Portugal. The Canadian Mineralogist, 36(5), 1347-1360.
Kaolinite
Formula: Al2(Si2O5)(OH)4
Reference: Relvas, J. M. R. S. et al. (2006): Hydrothermal Alteration and Mineralization in the Neves-Corvo Volcanic-Hosted Massive Sulfide Deposit, Portugal. I. Geology, Mineralogy, and Geochemistry. Econ. Geology 101, 753-790.
Kësterite
Formula: Cu2ZnSnS4
Reference: Relvas, J. M. R. S. et al. (2006): Hydrothermal Alteration and Mineralization in the Neves-Corvo Volcanic-Hosted Massive Sulfide Deposit, Portugal. I. Geology, Mineralogy, and Geochemistry. Econ. Geology 101, 753-790.; Serranti, S., Ferrini, V., Masi, U., & Cabri, L. J. (2002). Trace-element distribution in cassiterite and sulfides from rubané and massive ores of the Corvo deposit, Portugal. The Canadian Mineralogist, 40(3), 815-835.; Gaspar, O.C. (2002): Mineralogy and sulfide mineral chemistry of the Neves–Corvo Ores, Portugal: insight into their genesis. Canadian Mineralogist 40, 611-636.
Kiddcreekite ?
Formula: Cu6SnWS8
Reference: Benzaazoua, M., Marion, P., Pinto, A., Migeon, H., & Wagner, F. E. (2003). Tin and indium mineralogy within selected samples from the Neves Corvo ore deposit (Portugal): a multidisciplinary study. Minerals Engineering, 16(11), 1291-1302.
Kobellite
Formula: Pb22Cu4(Bi,Sb)30S69
Reference: Gaspar, O.C. (2002): Mineralogy and sulfide mineral chemistry of the Neves–Corvo Ores, Portugal: insight into their genesis. Canadian Mineralogist 40, 611-636.
Laitakarite
Formula: Bi4Se2S
Reference: Gaspar, O.C. (2002): Mineralogy and sulfide mineral chemistry of the Neves–Corvo Ores, Portugal: insight into their genesis. Canadian Mineralogist 40, 611-636.
Löllingite
Formula: FeAs2
Reference: Relvas, J. M. R. S. et al. (2006): Hydrothermal Alteration and Mineralization in the Neves-Corvo Volcanic-Hosted Massive Sulfide Deposit, Portugal. I. Geology, Mineralogy, and Geochemistry. Econ. Geology 101, 753-790.; Cabri, L. J., Gaspar, O. C., Lastra, R., & McMahon, G. (1998). Distribution of gold in tin-rich samples from the Corvo orebody, Portugal. The Canadian Mineralogist, 36(5), 1347-1360.; Gaspar, O.C. (2002): Mineralogy and sulfide mineral chemistry of the Neves–Corvo Ores, Portugal: insight into their genesis. Canadian Mineralogist 40, 611-636.
Magnetite
Formula: Fe2+Fe3+2O4
Reference: Gaspar, O.C. (2002): Mineralogy and sulfide mineral chemistry of the Neves–Corvo Ores, Portugal: insight into their genesis. Canadian Mineralogist 40, 611-636.
Mawsonite
Formula: Cu6Fe2SnS8
Reference: Relvas, J. M. R. S. et al. (2006): Hydrothermal Alteration and Mineralization in the Neves-Corvo Volcanic-Hosted Massive Sulfide Deposit, Portugal. I. Geology, Mineralogy, and Geochemistry. Econ. Geology 101, 753-790.; Benzaazoua, M., Marion, P., Pinto, A., Migeon, H., & Wagner, F. E. (2003). Tin and indium mineralogy within selected samples from the Neves Corvo ore deposit (Portugal): a multidisciplinary study. Minerals Engineering, 16(11), 1291-1302.; Pinto, A., Bowles, J. F. W., & Gaspar, O. C. (1994). The mineral chemistry and textures of wittichenite, miharaite, carrolite, mawsonite and In±Bi±Hg tennantite from Neves-Corvo, Portugal. IMA 94. In XVI General Meeting of IMA, Pisa, ItaÂlia, Abstracts.; Cabri, L. J., Gaspar, O. C., Lastra, R., & McMahon, G. (1998). Distribution of gold in tin-rich samples from the Corvo orebody, Portugal. The Canadian Mineralogist, 36(5), 1347-1360.; Gaspar, O.C. (2002): Mineralogy and sulfide mineral chemistry of the Neves–Corvo Ores, Portugal: insight into their genesis. Canadian Mineralogist 40, 611-636.
Meneghinite
Formula: Pb13CuSb7S24
Reference: Gaspar, O.C. (2002): Mineralogy and sulfide mineral chemistry of the Neves–Corvo Ores, Portugal: insight into their genesis. Canadian Mineralogist 40, 611-636.
Miharaite
Formula: Cu4FePbBiS6
Reference: Pinto, A., Bowles, J. F. W., & Gaspar, O. C. (1994). The mineral chemistry and textures of wittichenite, miharaite, carrolite, mawsonite and In±Bi±Hg tennantite from Neves-Corvo, Portugal. IMA 94. In XVI General Meeting of IMA, Pisa, ItaÂlia, Abstracts.; Cabri, L. J., Gaspar, O. C., Lastra, R., & McMahon, G. (1998). Distribution of gold in tin-rich samples from the Corvo orebody, Portugal. The Canadian Mineralogist, 36(5), 1347-1360.; Gaspar, O.C. (2002): Mineralogy and sulfide mineral chemistry of the Neves–Corvo Ores, Portugal: insight into their genesis. Canadian Mineralogist 40, 611-636.
Muscovite
Formula: KAl2(AlSi3O10)(OH)2
Reference: Relvas, J. M. R. S. et al. (2006): Hydrothermal Alteration and Mineralization in the Neves-Corvo Volcanic-Hosted Massive Sulfide Deposit, Portugal. I. Geology, Mineralogy, and Geochemistry. Econ. Geology 101, 753-790.; Serranti, S., Ferrini, V., Masi, U., & Cabri, L. J. (2002). Trace-element distribution in cassiterite and sulfides from rubané and massive ores of the Corvo deposit, Portugal. The Canadian Mineralogist, 40(3), 815-835.
Muscovite var. Sericite
Formula: KAl2(AlSi3O10)(OH)2
Reference: Relvas, J. M. R. S. et al. (2006): Hydrothermal Alteration and Mineralization in the Neves-Corvo Volcanic-Hosted Massive Sulfide Deposit, Portugal. I. Geology, Mineralogy, and Geochemistry. Econ. Geology 101, 753-790.; Serranti, S., Ferrini, V., Masi, U., & Cabri, L. J. (2002). Trace-element distribution in cassiterite and sulfides from rubané and massive ores of the Corvo deposit, Portugal. The Canadian Mineralogist, 40(3), 815-835.
Naumannite
Formula: Ag2Se
Reference: Relvas, J.M.R.S., Tassinari, C.C.G., Munhá, J., and Barriga, F.J.A.S. (2001): Mineralium Deposita 36, 416-427.; Cabri, L. J., Gaspar, O. C., Lastra, R., & McMahon, G. (1998). Distribution of gold in tin-rich samples from the Corvo orebody, Portugal. The Canadian Mineralogist, 36(5), 1347-1360.
Paraguanajuatite
Formula: Bi2Se3
Reference: Gaspar, O.C. (2002): Mineralogy and sulfide mineral chemistry of the Neves–Corvo Ores, Portugal: insight into their genesis. Canadian Mineralogist 40, 611-636.
Pyrite
Formula: FeS2
Reference: Relvas, J. M. R. S. et al. (2006): Hydrothermal Alteration and Mineralization in the Neves-Corvo Volcanic-Hosted Massive Sulfide Deposit, Portugal. I. Geology, Mineralogy, and Geochemistry. Econ. Geology 101, 753-790.; Serranti, S., Ferrini, V., Masi, U., & Cabri, L. J. (2002). Trace-element distribution in cassiterite and sulfides from rubané and massive ores of the Corvo deposit, Portugal. The Canadian Mineralogist, 40(3), 815-835.; Gaspar, O.C. (2002): Mineralogy and sulfide mineral chemistry of the Neves–Corvo Ores, Portugal: insight into their genesis. Canadian Mineralogist 40, 611-636.
Pyrrhotite
Formula: Fe1-xS
Reference: Gaspar, O.C. (2002): Mineralogy and sulfide mineral chemistry of the Neves–Corvo Ores, Portugal: insight into their genesis. Canadian Mineralogist 40, 611-636.
Quartz
Formula: SiO2
Reference: Relvas, J. M. R. S. et al. (2006): Hydrothermal Alteration and Mineralization in the Neves-Corvo Volcanic-Hosted Massive Sulfide Deposit, Portugal. I. Geology, Mineralogy, and Geochemistry. Econ. Geology 101, 753-790.; Serranti, S., Ferrini, V., Masi, U., & Cabri, L. J. (2002). Trace-element distribution in cassiterite and sulfides from rubané and massive ores of the Corvo deposit, Portugal. The Canadian Mineralogist, 40(3), 815-835.; Cabri, L. J., Gaspar, O. C., Lastra, R., & McMahon, G. (1998). Distribution of gold in tin-rich samples from the Corvo orebody, Portugal. The Canadian Mineralogist, 36(5), 1347-1360.; Gaspar, O.C. (2002): Mineralogy and sulfide mineral chemistry of the Neves–Corvo Ores, Portugal: insight into their genesis. Canadian Mineralogist 40, 611-636.
Quartz var. Jasper
Reference: Moura, A. (2008): Ore Geology Reviews 34, 354-368.; Gaspar, O.C. (2002): Mineralogy and sulfide mineral chemistry of the Neves–Corvo Ores, Portugal: insight into their genesis. Canadian Mineralogist 40, 611-636.
Roquesite
Formula: CuInS2
Reference: Bachmann, K., Frenzel, M., Krause, J. and Gutzmer, J. (2017): Advanced identification and quantification of In-bearing minerals by scanning electron microscope-based image analysis. Microscopy and Microanalysis 23, 527-537.; Gaspar, O.C. (2002): Mineralogy and sulfide mineral chemistry of the Neves–Corvo Ores, Portugal: insight into their genesis. Canadian Mineralogist 40, 611-636.
Rutile
Formula: TiO2
Reference: Moura, A. (2008): Ore Geology Reviews 34, 354-368.; Gaspar, O.C. (2002): Mineralogy and sulfide mineral chemistry of the Neves–Corvo Ores, Portugal: insight into their genesis. Canadian Mineralogist 40, 611-636.
Sakuraiite
Formula: (Cu,Zn,Fe)3(In,Sn)S4
Reference: Bachmann, K., Frenzel, M., Krause, J. and Gutzmer, J. (2017): Advanced identification and quantification of In-bearing minerals by scanning electron microscope-based image analysis. Microscopy and Microanalysis 23, 527-537.
Siderite
Formula: FeCO3
Reference: Relvas, J. M. R. S. et al. (2006): Hydrothermal Alteration and Mineralization in the Neves-Corvo Volcanic-Hosted Massive Sulfide Deposit, Portugal. I. Geology, Mineralogy, and Geochemistry. Econ. Geology 101, 753-790.; Serranti, S., Ferrini, V., Masi, U., & Cabri, L. J. (2002). Trace-element distribution in cassiterite and sulfides from rubané and massive ores of the Corvo deposit, Portugal. The Canadian Mineralogist, 40(3), 815-835.
Skutterudite
Formula: CoAs3
Reference: Gaspar, O.C. (2002): Mineralogy and sulfide mineral chemistry of the Neves–Corvo Ores, Portugal: insight into their genesis. Canadian Mineralogist 40, 611-636.
Sphalerite
Formula: ZnS
Reference: Relvas, J. M. R. S. et al. (2006): Hydrothermal Alteration and Mineralization in the Neves-Corvo Volcanic-Hosted Massive Sulfide Deposit, Portugal. I. Geology, Mineralogy, and Geochemistry. Econ. Geology 101, 753-790.; Serranti, S., Ferrini, V., Masi, U., & Cabri, L. J. (2002). Trace-element distribution in cassiterite and sulfides from rubané and massive ores of the Corvo deposit, Portugal. The Canadian Mineralogist, 40(3), 815-835.; Gaspar, O.C. (2002): Mineralogy and sulfide mineral chemistry of the Neves–Corvo Ores, Portugal: insight into their genesis. Canadian Mineralogist 40, 611-636.
Stannite
Formula: Cu2FeSnS4
Reference: Relvas, J. M. R. S. et al. (2006): Hydrothermal Alteration and Mineralization in the Neves-Corvo Volcanic-Hosted Massive Sulfide Deposit, Portugal. I. Geology, Mineralogy, and Geochemistry. Econ. Geology 101, 753-790.; Benzaazoua, M., Marion, P., Pinto, A., Migeon, H., & Wagner, F. E. (2003). Tin and indium mineralogy within selected samples from the Neves Corvo ore deposit (Portugal): a multidisciplinary study. Minerals Engineering, 16(11), 1291-1302.; Serranti, S., Ferrini, V., Masi, U., & Cabri, L. J. (2002). Trace-element distribution in cassiterite and sulfides from rubané and massive ores of the Corvo deposit, Portugal. The Canadian Mineralogist, 40(3), 815-835.; Cabri, L. J., Gaspar, O. C., Lastra, R., & McMahon, G. (1998). Distribution of gold in tin-rich samples from the Corvo orebody, Portugal. The Canadian Mineralogist, 36(5), 1347-1360.; Gaspar, O.C. (2002): Mineralogy and sulfide mineral chemistry of the Neves–Corvo Ores, Portugal: insight into their genesis. Canadian Mineralogist 40, 611-636.
Stannoidite
Formula: Cu+6Cu2+2(Fe2+,Zn)3Sn2S12
Reference: Relvas, J. M. R. S. et al. (2006): Hydrothermal Alteration and Mineralization in the Neves-Corvo Volcanic-Hosted Massive Sulfide Deposit, Portugal. I. Geology, Mineralogy, and Geochemistry. Econ. Geology 101, 753-790.; Benzaazoua, M., Marion, P., Pinto, A., Migeon, H., & Wagner, F. E. (2003). Tin and indium mineralogy within selected samples from the Neves Corvo ore deposit (Portugal): a multidisciplinary study. Minerals Engineering, 16(11), 1291-1302.; Gaspar, O.C. (2002): Mineralogy and sulfide mineral chemistry of the Neves–Corvo Ores, Portugal: insight into their genesis. Canadian Mineralogist 40, 611-636.
Stromeyerite
Formula: AgCuS
Reference: Gaspar, O.C. (2002): Mineralogy and sulfide mineral chemistry of the Neves–Corvo Ores, Portugal: insight into their genesis. Canadian Mineralogist 40, 611-636.
'Tennantite Subgroup'
Formula: Cu6(Cu4X2+2)As4S12S
Reference: Moura, A. (2008): Ore Geology Reviews 34, 354-368.; Serranti, S., Ferrini, V., Masi, U., & Cabri, L. J. (2002). Trace-element distribution in cassiterite and sulfides from rubané and massive ores of the Corvo deposit, Portugal. The Canadian Mineralogist, 40(3), 815-835.; Pinto, A., Bowles, J. F. W., & Gaspar, O. C. (1994). The mineral chemistry and textures of wittichenite, miharaite, carrolite, mawsonite and In±Bi±Hg tennantite from Neves-Corvo, Portugal. IMA 94. In XVI General Meeting of IMA, Pisa, ItaÂlia, Abstracts.; Gaspar, O.C. (2002): Mineralogy and sulfide mineral chemistry of the Neves–Corvo Ores, Portugal: insight into their genesis. Canadian Mineralogist 40, 611-636.
Tetradymite
Formula: Bi2Te2S
Reference: Cabri, L. J., Gaspar, O. C., Lastra, R., & McMahon, G. (1998). Distribution of gold in tin-rich samples from the Corvo orebody, Portugal. The Canadian Mineralogist, 36(5), 1347-1360.; Gaspar, O.C. (2002): Mineralogy and sulfide mineral chemistry of the Neves–Corvo Ores, Portugal: insight into their genesis. Canadian Mineralogist 40, 611-636.
'Tetrahedrite Group'
Formula: M2(A6)M1(D4C2)X3(E4)S1(Y12)S2(Z)
Reference: Rui Nunes collection
'Tetrahedrite Subgroup'
Formula: Cu6(Cu4X2+2)Sb4S12S
Reference: Moura, A. (2008): Ore Geology Reviews 34, 354-368.; Serranti, S., Ferrini, V., Masi, U., & Cabri, L. J. (2002). Trace-element distribution in cassiterite and sulfides from rubané and massive ores of the Corvo deposit, Portugal. The Canadian Mineralogist, 40(3), 815-835.; Cabri, L. J., Gaspar, O. C., Lastra, R., & McMahon, G. (1998). Distribution of gold in tin-rich samples from the Corvo orebody, Portugal. The Canadian Mineralogist, 36(5), 1347-1360.; Gaspar, O.C. (2002): Mineralogy and sulfide mineral chemistry of the Neves–Corvo Ores, Portugal: insight into their genesis. Canadian Mineralogist 40, 611-636.
Tiemannite
Formula: HgSe
Reference: Gaspar, O.C. (2002): Mineralogy and sulfide mineral chemistry of the Neves–Corvo Ores, Portugal: insight into their genesis. Canadian Mineralogist 40, 611-636.
Vinciennite
Formula: Cu+7Cu2+3Fe2+2Fe3+2Sn(As,Sb)S16
Reference: Cabri, L. J., Gaspar, O. C., Lastra, R., & McMahon, G. (1998). Distribution of gold in tin-rich samples from the Corvo orebody, Portugal. The Canadian Mineralogist, 36(5), 1347-1360.
Wittichenite
Formula: Cu3BiS3
Reference: Pinto, A., Bowles, J. F. W., & Gaspar, O. C. (1994). The mineral chemistry and textures of wittichenite, miharaite, carrolite, mawsonite and In±Bi±Hg tennantite from Neves-Corvo, Portugal. IMA 94. In XVI General Meeting of IMA, Pisa, ItaÂlia, Abstracts.; Cabri, L. J., Gaspar, O. C., Lastra, R., & McMahon, G. (1998). Distribution of gold in tin-rich samples from the Corvo orebody, Portugal. The Canadian Mineralogist, 36(5), 1347-1360.

Gallery:

List of minerals arranged by Strunz 10th Edition classification

Group 1 - Elements
Bismuth1.CA.05Bi
Gold1.AA.05Au
var. Electrum1.AA.05(Au,Ag)
Graphite1.CB.05aC
Group 2 - Sulphides and Sulfosalts
Aikinite2.HB.05aPbCuBiS3
Alloclasite2.EB.10bCo1-xFexAsS
Arsenopyrite2.EB.20FeAsS
Betekhtinite2.BE.05(Cu,Fe)21Pb2S15
Bismuthinite2.DB.05Bi2S3
Bohdanowiczite2.JA.20AgBiSe2
Bornite2.BA.15Cu5FeS4
Bournonite2.GA.50PbCuSbS3
Carrollite2.DA.05Cu(Co,Ni)2S4
Chalcopyrite2.CB.10aCuFeS2
Chalcostibite2.HA.05CuSbS2
Clausthalite2.CD.10PbSe
Cobaltite2.EB.25CoAsS
Coloradoite2.CB.05aHgTe
Colusite2.CB.30Cu13VAs3S16
'Freibergite Subgroup'2.GB.05([Ag6]4+,(Ag,Cu)6)((Cu,Ag)4X2+2)Sb4S12S0-1
Galena2.CD.10PbS
Galenobismutite2.JC.25ePbBi2S4
Glaucodot2.EB.10c(Co0.50Fe0.50)AsS
Gudmundite2.EB.20FeSbS
Joséite-B2.DC.05Bi4Te2S
Kiddcreekite ?2.CB.35aCu6SnWS8
Kobellite2.HB.10aPb22Cu4(Bi,Sb)30S69
Kësterite 2.CB.15aCu2ZnSnS4
Laitakarite2.DC.05Bi4Se2S
Löllingite2.EB.15aFeAs2
Mawsonite2.CB.20Cu6Fe2SnS8
Meneghinite2.HB.05bPb13CuSb7S24
Miharaite2.LB.05Cu4FePbBiS6
Naumannite2.BA.55Ag2Se
Paraguanajuatite2.DC.05Bi2Se3
Pyrite2.EB.05aFeS2
Pyrrhotite2.CC.10Fe1-xS
Roquesite2.CB.10aCuInS2
Sakuraiite2.CB.05b(Cu,Zn,Fe)3(In,Sn)S4
Skutterudite2.EC.05CoAs3
Sphalerite2.CB.05aZnS
Stannite2.CB.15aCu2FeSnS4
Stannoidite2.CB.15cCu+6Cu2+2(Fe2+,Zn)3Sn2S12
Stromeyerite2.BA.40AgCuS
'Tennantite Subgroup'2.GB.05Cu6(Cu4X2+2)As4S12S
Tetradymite2.DC.05Bi2Te2S
'Tetrahedrite Subgroup'2.GB.05Cu6(Cu4X2+2)Sb4S12S
Tiemannite2.CB.05aHgSe
Vinciennite2.CB.35aCu+7Cu2+3Fe2+2Fe3+2Sn(As,Sb)S16
Wittichenite2.GA.20Cu3BiS3
Group 4 - Oxides and Hydroxides
Cassiterite4.DB.05SnO2
Hematite4.CB.05Fe2O3
Magnetite4.BB.05Fe2+Fe3+2O4
Quartz4.DA.05SiO2
var. Jasper4.DA.05SiO2
Rutile4.DB.05TiO2
Group 5 - Nitrates and Carbonates
Ankerite5.AB.10Ca(Fe2+,Mg)(CO3)2
Calcite5.AB.05CaCO3
Dolomite5.AB.10CaMg(CO3)2
Siderite5.AB.05FeCO3
Group 7 - Sulphates, Chromates, Molybdates and Tungstates
Baryte7.AD.35BaSO4
Group 9 - Silicates
Chamosite9.EC.55(Fe2+,Mg,Al,Fe3+)6(Si,Al)4O10(OH,O)8
Donbassite9.EC.55Al4.33(AlSi3O10)(OH)8
Kaolinite9.ED.05Al2(Si2O5)(OH)4
Muscovite9.EC.15KAl2(AlSi3O10)(OH)2
var. Sericite9.EC.15KAl2(AlSi3O10)(OH)2
Unclassified Minerals, Rocks, etc.
'Chlorite Group'-
'Tetrahedrite Group'-M2(A6)M1(D4C2)X3(E4)S1(Y12)S2(Z)

List of minerals arranged by Dana 8th Edition classification

Group 1 - NATIVE ELEMENTS AND ALLOYS
Metals, other than the Platinum Group
Gold1.1.1.1Au
Semi-metals and non-metals
Bismuth1.3.1.4Bi
Graphite1.3.6.2C
Group 2 - SULFIDES
AmBnXp, with (m+n):p = 2:1
Naumannite2.4.1.2Ag2Se
Stromeyerite2.4.6.1AgCuS
AmBnXp, with (m+n):p = 3:2
Bornite2.5.2.1Cu5FeS4
AmBnXp, with (m+n):p = 4:3
Joséite-B2.6.2.2Bi4Te2S
Laitakarite2.6.2.4Bi4Se2S
AmXp, with m:p = 1:1
Clausthalite2.8.1.2PbSe
Coloradoite2.8.2.5HgTe
Galena2.8.1.1PbS
Pyrrhotite2.8.10.1Fe1-xS
Sphalerite2.8.2.1ZnS
Tiemannite2.8.2.4HgSe
AmBnXp, with (m+n):p = 1:1
Chalcopyrite2.9.1.1CuFeS2
Kiddcreekite ?2.9.6.2Cu6SnWS8
Kësterite 2.9.2.9Cu2ZnSnS4
Mawsonite2.9.3.1Cu6Fe2SnS8
Roquesite2.9.1.4CuInS2
Sakuraiite2.9.2.5(Cu,Zn,Fe)3(In,Sn)S4
Stannite2.9.2.1Cu2FeSnS4
Stannoidite2.9.3.3Cu+6Cu2+2(Fe2+,Zn)3Sn2S12
AmBnXp, with (m+n):p = 3:4
Carrollite2.10.1.2Cu(Co,Ni)2S4
AmBnXp, with (m+n):p = 2:3
Bismuthinite2.11.2.3Bi2S3
Paraguanajuatite2.11.7.4Bi2Se3
Tetradymite2.11.7.1Bi2Te2S
AmBnXp, with (m+n):p = 1:2
Alloclasite2.12.6.2Co1-xFexAsS
Arsenopyrite2.12.4.1FeAsS
Cobaltite2.12.3.1CoAsS
Glaucodot2.12.6.1(Co0.50Fe0.50)AsS
Gudmundite2.12.4.2FeSbS
Löllingite2.12.2.9FeAs2
Pyrite2.12.1.1FeS2
Skutterudite2.12.17.1CoAs3
Miscellaneous
Betekhtinite2.16.8.1(Cu,Fe)21Pb2S15
Group 3 - SULFOSALTS
ø > 4
Colusite3.1.1.1Cu13VAs3S16
Miharaite3.1.5.1Cu4FePbBiS6
Vinciennite3.1.2.1Cu+7Cu2+3Fe2+2Fe3+2Sn(As,Sb)S16
3 <ø < 4
'Freibergite Subgroup'3.3.6.3([Ag6]4+,(Ag,Cu)6)((Cu,Ag)4X2+2)Sb4S12S0-1
Meneghinite3.3.5.1Pb13CuSb7S24
'Tennantite Subgroup'3.3.6.2Cu6(Cu4X2+2)As4S12S
'Tetrahedrite Subgroup'3.3.6.1Cu6(Cu4X2+2)Sb4S12S
ø = 3
Aikinite3.4.5.1PbCuBiS3
Bournonite3.4.3.2PbCuSbS3
Wittichenite3.4.8.1Cu3BiS3
2 < ø < 2.49
Kobellite3.6.19.1Pb22Cu4(Bi,Sb)30S69
ø = 2
Bohdanowiczite3.7.1.2AgBiSe2
Chalcostibite3.7.5.1CuSbS2
Galenobismutite3.7.9.1PbBi2S4
Group 4 - SIMPLE OXIDES
A2X3
Hematite4.3.1.2Fe2O3
AX2
Cassiterite4.4.1.5SnO2
Rutile4.4.1.1TiO2
Group 7 - MULTIPLE OXIDES
AB2X4
Magnetite7.2.2.3Fe2+Fe3+2O4
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 28 - ANHYDROUS ACID AND NORMAL SULFATES
AXO4
Baryte28.3.1.1BaSO4
Group 71 - PHYLLOSILICATES Sheets of Six-Membered Rings
Sheets of 6-membered rings with 2:1 layers
Muscovite71.2.2a.1KAl2(AlSi3O10)(OH)2
Sheets of 6-membered rings interlayered 1:1, 2:1, and octahedra
Chamosite71.4.1.7(Fe2+,Mg,Al,Fe3+)6(Si,Al)4O10(OH,O)8
Donbassite71.4.1.1Al4.33(AlSi3O10)(OH)8
Group 75 - TECTOSILICATES Si Tetrahedral Frameworks
Si Tetrahedral Frameworks - SiO2 with [4] coordinated Si
Quartz75.1.3.1SiO2
Unclassified Minerals, Mixtures, etc.
'Chlorite Group'-
Gold
var. Electrum
-(Au,Ag)
Kaolinite-Al2(Si2O5)(OH)4
Muscovite
var. Sericite
-KAl2(AlSi3O10)(OH)2
Quartz
var. Jasper
-SiO2
'Tetrahedrite Group'-M2(A6)M1(D4C2)X3(E4)S1(Y12)S2(Z)

List of minerals for each chemical element

HHydrogen
H DonbassiteAl4.33(AlSi3O10)(OH)8
H KaoliniteAl2(Si2O5)(OH)4
H Chamosite(Fe2+,Mg,Al,Fe3+)6(Si,Al)4O10(OH,O)8
H Muscovite var. SericiteKAl2(AlSi3O10)(OH)2
H MuscoviteKAl2(AlSi3O10)(OH)2
CCarbon
C CalciteCaCO3
C DolomiteCaMg(CO3)2
C SideriteFeCO3
C AnkeriteCa(Fe2+,Mg)(CO3)2
C GraphiteC
C Tetrahedrite GroupM2(A6)M1(D4C2)X3(E4)S1(Y12)S2(Z)
OOxygen
O BaryteBaSO4
O CassiteriteSnO2
O CalciteCaCO3
O DolomiteCaMg(CO3)2
O DonbassiteAl4.33(AlSi3O10)(OH)8
O KaoliniteAl2(Si2O5)(OH)4
O Chamosite(Fe2+,Mg,Al,Fe3+)6(Si,Al)4O10(OH,O)8
O QuartzSiO2
O SideriteFeCO3
O AnkeriteCa(Fe2+,Mg)(CO3)2
O Muscovite var. SericiteKAl2(AlSi3O10)(OH)2
O RutileTiO2
O MuscoviteKAl2(AlSi3O10)(OH)2
O HematiteFe2O3
O MagnetiteFe2+Fe23+O4
MgMagnesium
Mg DolomiteCaMg(CO3)2
Mg Chamosite(Fe2+,Mg,Al,Fe3+)6(Si,Al)4O10(OH,O)8
Mg AnkeriteCa(Fe2+,Mg)(CO3)2
AlAluminium
Al DonbassiteAl4.33(AlSi3O10)(OH)8
Al KaoliniteAl2(Si2O5)(OH)4
Al Chamosite(Fe2+,Mg,Al,Fe3+)6(Si,Al)4O10(OH,O)8
Al Muscovite var. SericiteKAl2(AlSi3O10)(OH)2
Al MuscoviteKAl2(AlSi3O10)(OH)2
SiSilicon
Si DonbassiteAl4.33(AlSi3O10)(OH)8
Si KaoliniteAl2(Si2O5)(OH)4
Si Chamosite(Fe2+,Mg,Al,Fe3+)6(Si,Al)4O10(OH,O)8
Si QuartzSiO2
Si Muscovite var. SericiteKAl2(AlSi3O10)(OH)2
Si MuscoviteKAl2(AlSi3O10)(OH)2
SSulfur
S BaryteBaSO4
S Tetrahedrite SubgroupCu6(Cu4X22+)Sb4S12S
S PyriteFeS2
S ChalcopyriteCuFeS2
S StanniteCu2FeSnS4
S Tennantite SubgroupCu6(Cu4X22+)As4S12S
S ArsenopyriteFeAsS
S MawsoniteCu6Fe2SnS8
S GalenaPbS
S SphaleriteZnS
S Kësterite Cu2ZnSnS4
S StannoiditeCu6+Cu22+(Fe2+,Zn)3Sn2S12
S Freibergite Subgroup([Ag6]4+,(Ag,Cu)6)((Cu,Ag)4X22+)Sb4S12S0-1
S CobaltiteCoAsS
S BorniteCu5FeS4
S BournonitePbCuSbS3
S BismuthiniteBi2S3
S Sakuraiite(Cu,Zn,Fe)3(In,Sn)S4
S Tetrahedrite GroupM2(A6)M1(D4C2)X3(E4)S1(Y12)S2(Z)
S RoquesiteCuInS2
S WitticheniteCu3BiS3
S MiharaiteCu4FePbBiS6
S CarrolliteCu(Co,Ni)2S4
S Glaucodot(Co0.50Fe0.50)AsS
S AlloclasiteCo1-xFexAsS
S TetradymiteBi2Te2S
S Joséite-BBi4Te2S
S VincienniteCu7+Cu32+Fe22+Fe23+Sn(As,Sb)S16
S ColusiteCu13VAs3S16
S Betekhtinite(Cu,Fe)21Pb2S15
S MeneghinitePb13CuSb7S24
S PyrrhotiteFe1-xS
S GudmunditeFeSbS
S KobellitePb22Cu4(Bi,Sb)30S69
S AikinitePbCuBiS3
S LaitakariteBi4Se2S
S StromeyeriteAgCuS
S ChalcostibiteCuSbS2
S GalenobismutitePbBi2S4
S KiddcreekiteCu6SnWS8
KPotassium
K Muscovite var. SericiteKAl2(AlSi3O10)(OH)2
K MuscoviteKAl2(AlSi3O10)(OH)2
CaCalcium
Ca CalciteCaCO3
Ca DolomiteCaMg(CO3)2
Ca AnkeriteCa(Fe2+,Mg)(CO3)2
TiTitanium
Ti RutileTiO2
VVanadium
V ColusiteCu13VAs3S16
FeIron
Fe PyriteFeS2
Fe ChalcopyriteCuFeS2
Fe StanniteCu2FeSnS4
Fe ArsenopyriteFeAsS
Fe MawsoniteCu6Fe2SnS8
Fe Chamosite(Fe2+,Mg,Al,Fe3+)6(Si,Al)4O10(OH,O)8
Fe LöllingiteFeAs2
Fe SideriteFeCO3
Fe AnkeriteCa(Fe2+,Mg)(CO3)2
Fe StannoiditeCu6+Cu22+(Fe2+,Zn)3Sn2S12
Fe BorniteCu5FeS4
Fe Sakuraiite(Cu,Zn,Fe)3(In,Sn)S4
Fe MiharaiteCu4FePbBiS6
Fe Glaucodot(Co0.50Fe0.50)AsS
Fe AlloclasiteCo1-xFexAsS
Fe VincienniteCu7+Cu32+Fe22+Fe23+Sn(As,Sb)S16
Fe Betekhtinite(Cu,Fe)21Pb2S15
Fe HematiteFe2O3
Fe MagnetiteFe2+Fe23+O4
Fe PyrrhotiteFe1-xS
Fe GudmunditeFeSbS
Fe KobellitePb22Cu4(Bi,Sb)30S69
CoCobalt
Co CobaltiteCoAsS
Co CarrolliteCu(Co,Ni)2S4
Co Glaucodot(Co0.50Fe0.50)AsS
Co AlloclasiteCo1-xFexAsS
Co SkutteruditeCoAs3
NiNickel
Ni CarrolliteCu(Co,Ni)2S4
CuCopper
Cu Tetrahedrite SubgroupCu6(Cu4X22+)Sb4S12S
Cu ChalcopyriteCuFeS2
Cu StanniteCu2FeSnS4
Cu Tennantite SubgroupCu6(Cu4X22+)As4S12S
Cu MawsoniteCu6Fe2SnS8
Cu Kësterite Cu2ZnSnS4
Cu StannoiditeCu6+Cu22+(Fe2+,Zn)3Sn2S12
Cu Freibergite Subgroup([Ag6]4+,(Ag,Cu)6)((Cu,Ag)4X22+)Sb4S12S0-1
Cu BorniteCu5FeS4
Cu BournonitePbCuSbS3
Cu Sakuraiite(Cu,Zn,Fe)3(In,Sn)S4
Cu RoquesiteCuInS2
Cu WitticheniteCu3BiS3
Cu MiharaiteCu4FePbBiS6
Cu CarrolliteCu(Co,Ni)2S4
Cu VincienniteCu7+Cu32+Fe22+Fe23+Sn(As,Sb)S16
Cu ColusiteCu13VAs3S16
Cu Betekhtinite(Cu,Fe)21Pb2S15
Cu MeneghinitePb13CuSb7S24
Cu KobellitePb22Cu4(Bi,Sb)30S69
Cu AikinitePbCuBiS3
Cu StromeyeriteAgCuS
Cu ChalcostibiteCuSbS2
Cu KiddcreekiteCu6SnWS8
ZnZinc
Zn SphaleriteZnS
Zn Kësterite Cu2ZnSnS4
Zn StannoiditeCu6+Cu22+(Fe2+,Zn)3Sn2S12
Zn Sakuraiite(Cu,Zn,Fe)3(In,Sn)S4
AsArsenic
As Tennantite SubgroupCu6(Cu4X22+)As4S12S
As ArsenopyriteFeAsS
As LöllingiteFeAs2
As CobaltiteCoAsS
As Glaucodot(Co0.50Fe0.50)AsS
As AlloclasiteCo1-xFexAsS
As VincienniteCu7+Cu32+Fe22+Fe23+Sn(As,Sb)S16
As ColusiteCu13VAs3S16
As SkutteruditeCoAs3
SeSelenium
Se NaumanniteAg2Se
Se ClausthalitePbSe
Se TiemanniteHgSe
Se ParaguanajuatiteBi2Se3
Se LaitakariteBi4Se2S
Se BohdanowicziteAgBiSe2
YYttrium
Y Tetrahedrite GroupM2(A6)M1(D4C2)X3(E4)S1(Y12)S2(Z)
AgSilver
Ag Freibergite Subgroup([Ag6]4+,(Ag,Cu)6)((Cu,Ag)4X22+)Sb4S12S0-1
Ag NaumanniteAg2Se
Ag Gold var. Electrum(Au,Ag)
Ag BohdanowicziteAgBiSe2
Ag StromeyeriteAgCuS
InIndium
In Sakuraiite(Cu,Zn,Fe)3(In,Sn)S4
In RoquesiteCuInS2
SnTin
Sn CassiteriteSnO2
Sn StanniteCu2FeSnS4
Sn MawsoniteCu6Fe2SnS8
Sn Kësterite Cu2ZnSnS4
Sn StannoiditeCu6+Cu22+(Fe2+,Zn)3Sn2S12
Sn Sakuraiite(Cu,Zn,Fe)3(In,Sn)S4
Sn VincienniteCu7+Cu32+Fe22+Fe23+Sn(As,Sb)S16
Sn KiddcreekiteCu6SnWS8
SbAntimony
Sb Tetrahedrite SubgroupCu6(Cu4X22+)Sb4S12S
Sb Freibergite Subgroup([Ag6]4+,(Ag,Cu)6)((Cu,Ag)4X22+)Sb4S12S0-1
Sb BournonitePbCuSbS3
Sb VincienniteCu7+Cu32+Fe22+Fe23+Sn(As,Sb)S16
Sb MeneghinitePb13CuSb7S24
Sb GudmunditeFeSbS
Sb KobellitePb22Cu4(Bi,Sb)30S69
Sb ChalcostibiteCuSbS2
TeTellurium
Te TetradymiteBi2Te2S
Te Joséite-BBi4Te2S
Te ColoradoiteHgTe
BaBarium
Ba BaryteBaSO4
WTungsten
W KiddcreekiteCu6SnWS8
AuGold
Au Gold var. Electrum(Au,Ag)
Au GoldAu
HgMercury
Hg TiemanniteHgSe
Hg ColoradoiteHgTe
PbLead
Pb GalenaPbS
Pb BournonitePbCuSbS3
Pb MiharaiteCu4FePbBiS6
Pb ClausthalitePbSe
Pb Betekhtinite(Cu,Fe)21Pb2S15
Pb MeneghinitePb13CuSb7S24
Pb KobellitePb22Cu4(Bi,Sb)30S69
Pb AikinitePbCuBiS3
Pb GalenobismutitePbBi2S4
BiBismuth
Bi BismuthiniteBi2S3
Bi WitticheniteCu3BiS3
Bi MiharaiteCu4FePbBiS6
Bi BismuthBi
Bi TetradymiteBi2Te2S
Bi Joséite-BBi4Te2S
Bi KobellitePb22Cu4(Bi,Sb)30S69
Bi AikinitePbCuBiS3
Bi ParaguanajuatiteBi2Se3
Bi LaitakariteBi4Se2S
Bi BohdanowicziteAgBiSe2
Bi GalenobismutitePbBi2S4

References

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Year (asc) Year (desc) Author (A-Z) Author (Z-A)
Mining Annual Review (1985): 203, 488.
Gaspar, O.C. (1996): Ore microscopy and petrology applied to the genesis, exploitation and beneficiation of Aljustrel and Neves Corvo massive sulphide deposits. Estudos Notas Trabalhos, Instituto Geológico e Mineiro, 38, 3-195 (in Portuguese, with extended abstract in English).
Cabri, L. J., Gaspar, O. C., Lastra, R., & McMahon, G. (1998). Distribution of gold in tin-rich samples from the Corvo orebody, Portugal. The Canadian Mineralogist, 36(5), 1347-1360.
Fernando Real (1999). A Perspective on Neves - Corvo Mining Project Development: A Success Against an EU Trend. Mining Development Strategies With a Focus on the Case of the Iberian Pyrite Belt. Technical Journey 25th September 1998 Lisbon, Portugal
Relvas, J.M.R.S., Tassinari, C.C.G., Munhá, J., and Barriga, F.J.A.S. (2001): Multiple sources for ore-forming fluids in the Neves Corvo VHMS Deposit of the Iberian Pyrite Belt (Portugal): strontium, neodymium and lead isotope evidence. Mineralium Deposita 36, 416-427. DOI 10.1007/s001260100168
Gaspar, O.C. (2002): Mineralogy and sulfide mineral chemistry of the Neves–Corvo Ores, Portugal: insight into their genesis. Canadian Mineralogist 40, 611-636.
Serranti, S., Ferrini, V., Masi, U., & Cabri, L. J. (2002). Trace-element distribution in cassiterite and sulfides from rubané and massive ores of the Corvo deposit, Portugal. The Canadian Mineralogist, 40(3), 815-835.
Benzaazoua, M., Marion, P., Pinto, A., Migeon, H., & Wagner, F. E. (2003). Tin and indium mineralogy within selected samples from the Neves Corvo ore deposit (Portugal): a multidisciplinary study. Minerals Engineering, 16(11), 1291-1302.
De Ascencao Guedes, R. (2004): Un gîte européen: l'amas sulfuré de Neves-Corvo, Portugal. Le Règne Minéral 56, 47-49.
Rosa, C.J.P.; Relvas, J.R.M.S.; Pereira, Z.; Pacheco, N.; McPhie, J. (2005): Felsic pyroclastic and effusive volcanic facies hosting the Neves Corvo massive sulfide deposit, Iberian Pyrite Belt, Portugal. In Mao, J. & Bierlein, F.P., Mineral Deposit Research: Meeting the Global Challenge, 1, Springer, p. 691.
Relvas, J.M.R.S. et al. (2006): Hydrothermal Alteration and Mineralization in the Neves-Corvo Volcanic-Hosted Massive Sulfide Deposit, Portugal. I. Geology, Mineralogy, and Geochemistry. Econ. Geology 101, 753-790.
Moura, A. (2008): Metallogenesis at the Neves Corvo VHMS deposit (Portugal): A contribution from the study of fluid inclusions. Ore Geology Reviews 34, 354-368.
Pinto, A.M.M., Relvas, J.M.R.S., Carvalho, J.R.S., Pacheco, N. & Liu, Y. (2013). Mineralogy and distribution of indium and selenium metals within zinc-rich ore types of the Neves Corvo deposit, Portugal. Mineral. Mag. 77, 1973 (Abs.).
Carvalho, J.R.S., Fernandes, A.S., Moreira, B.B., Pinto, A.M.M., Relvas, J.M.R.S., Pacheco, N., Pinto, F. & Fonseca, R. (2013). Hydrothermal alteration and ore mineralogy at the Lombador massive sulphide orebody, Neves Corvo, Portugal: An on-going study. Proceedings of the 12th SGA Biennial Meeting: “Mineral Deposits Research for a High-Tech World”, Jonsson, E. (Ed.), Uppsala, Sweden, pp. 514–517.
Carvalho, J., Relvas, J., Pinto, Á., Marques, F., Rosa, C., Pacheco, N. & Fonseca, R. (2014). New insights on the metallogenesis of the Neves Corvo deposit: Mineralogy and geochemistry of the zinc-rich Lombador orebody. Goldschmidt Abstracts 2014, 353.
Frenzel, M., Bachmann, K., Krause, J., Carvalho, J. R., Relvas, J. M. R. S., Pacheco, N., & Gutzmer, J. (2015). Mineralogical deportment of indium in the Neves-Corvo deposit–Implications for recovery and extraction. In Society of Economic Geologists (SEG) 2015 Conference, Hobart, Australia.
Bachmann, K., Frenzel, M., Krause, J. and Gutzmer, J. (2017): Advanced identification and quantification of In-bearing minerals by scanning electron microscope-based image analysis. Microscopy and Microanalysis 23, 527-537.

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