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Dovyren Highlands, Severo-Baykalsky District, Buryatia, Russiai
Regional Level Types
Dovyren HighlandsHighlands
Severo-Baykalsky DistrictDistrict
BuryatiaRepublic
RussiaCountry

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PhotosMapsSearch
01023430016168383543892.jpg
Mt. Yoko and Mt. Dovyren

Yoko-Dovyrensky Massif, Dovyren Highlands, Severo-Baykalsky District, Buryatia, Russia
07470460014961304539546.jpg
Plombièrite

Yoko-Dovyrensky Massif, Dovyren Highlands, Severo-Baykalsky District, Buryatia, Russia
01161160014947505977670.jpg
Blue Diopside, etc.

Snezhniy prospect, Yoko-Dovyrensky Massif, Dovyren Highlands, Severo-Baykalsky District, Buryatia, Russia
06311440016161306971538.jpg
Mt. Yoko and Mt. Dovyren

Yoko-Dovyrensky Massif, Dovyren Highlands, Severo-Baykalsky District, Buryatia, Russia
07470460014961304539546.jpg
Plombièrite

Yoko-Dovyrensky Massif, Dovyren Highlands, Severo-Baykalsky District, Buryatia, Russia
01161160014947505977670.jpg
Blue Diopside, etc.

Snezhniy prospect, Yoko-Dovyrensky Massif, Dovyren Highlands, Severo-Baykalsky District, Buryatia, Russia
01112130016156007568922.jpg
Mt. Yoko and Mt. Dovyren

Yoko-Dovyrensky Massif, Dovyren Highlands, Severo-Baykalsky District, Buryatia, Russia
07769760014947536671166.jpg
Plombièrite

Yoko-Dovyrensky Massif, Dovyren Highlands, Severo-Baykalsky District, Buryatia, Russia
Latitude & Longitude:
55° North , 110° East (est.)
Estimate based on other nearby localities or region boundaries.
Margin of Error:
~205km
GRN:
N38E46
Type:
Highlands


No description has been added for this locality. Can you add one?

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

129 valid minerals. 1 (TL) - type locality of 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“˜ Actinolite
Formula: ◻Ca2(Mg4.5-2.5Fe0.5-2.5)Si8O22(OH)2
Reference: Spiridonov, E. M. (2020, September). Metamorphogenic–Hydrothermal Nielsenite, PdCu 3, in Sulfide-Bearing Anorthosites of the Yoko-Dovyren Intrusive in Baikalides of the Northern Baikal Region. In Doklady Earth Sciences (Vol. 494, pp. 704-706). Pleiades Publishing.
β“˜ Afwillite
Formula: Ca3(HSiO4)2 · 2H2O
Reference: American Mineralogist, Volume 94, pages 323–333, 2009
β“˜ Altaite
Formula: PbTe
Reference: Spiridonov, E. M., Orsoev, D. A., Ariskin, A. A., Kislov, E. V., Korotaeva, N. N., Nikolaev, G. S., & Yapaskurt, V. O. (2019). Germanium-Rich Palladium Minerals Palladogermanide Pd 2 Ge, Paolovite Pd 2 (Sn, Ge), and Zvyagintsevite in Sulfide-Bearing Anorthosites of the Yoko-Dovyren Pluton, Baikal Area. Geochemistry International, 57(5), 600-603.
β“˜ 'Amphibole Supergroup'
Formula: AB2C5((Si,Al,Ti)8O22)(OH,F,Cl,O)2
Reference: Spiridonov, E. M., Ariskin, A. A., Kislov, E. V., Korotaeva, N. N., Nikolaev, G. S., Pshenitsyn, I. V., & Yapaskurt, V. O. (2018). Laurite and Ir-osmium from plagioclase lherzolite of the Yoko–Dovyren mafic–ultramafic pluton, Northern Baikal Region. Geology of Ore Deposits, 60(3), 210-219.
β“˜ Anorthite
Formula: Ca(Al2Si2O8)
Reference: Spiridonov, E. M., Ariskin, A. A., Kislov, E. V., Korotaeva, N. N., Nikolaev, G. S., Pshenitsyn, I. V., & Yapaskurt, V. O. (2018). Laurite and Ir-osmium from plagioclase lherzolite of the Yoko–Dovyren mafic–ultramafic pluton, Northern Baikal Region. Geology of Ore Deposits, 60(3), 210-219.
β“˜ Anorthite var. Bytownite
Formula: (Ca,Na)[Al(Al,Si)Si2O8]
Reference: Spiridonov, E. M., Ariskin, A. A., Kislov, E. V., Korotaeva, N. N., Nikolaev, G. S., Pshenitsyn, I. V., & Yapaskurt, V. O. (2018). Laurite and Ir-osmium from plagioclase lherzolite of the Yoko–Dovyren mafic–ultramafic pluton, Northern Baikal Region. Geology of Ore Deposits, 60(3), 210-219.
β“˜ Antigorite
Formula: Mg3(Si2O5)(OH)4
Reference: Spiridonov, E. M. (2020, September). Metamorphogenic–Hydrothermal Nielsenite, PdCu 3, in Sulfide-Bearing Anorthosites of the Yoko-Dovyren Intrusive in Baikalides of the Northern Baikal Region. In Doklady Earth Sciences (Vol. 494, pp. 704-706). Pleiades Publishing.
β“˜ 'Apatite'
Formula: Ca5(PO4)3(Cl/F/OH)
Reference: Spiridonov, E. M., Ariskin, A. A., Kislov, E. V., Korotaeva, N. N., Nikolaev, G. S., Pshenitsyn, I. V., & Yapaskurt, V. O. (2018). Laurite and Ir-osmium from plagioclase lherzolite of the Yoko–Dovyren mafic–ultramafic pluton, Northern Baikal Region. Geology of Ore Deposits, 60(3), 210-219.; Kislov, E.V.; Khudyakova, L.I. (2020) Yoko–Dovyren Layered Massif: Composition, Mineralization, Overburden and Dump Rock Utilization. Minerals 10, 682.
β“˜ Atheneite
Formula: Pd2As0.75Hg0.25
Reference: Rudashevskiy N.S., Krecer D.A., Orsoev D.A., Kislov E.V. (2003) Palladium-platinum mineralization in vein Cu-Ni-ores of Yoko-Dovyrenskiy laiered massif, - DAN, 391(4), p. 519-522 (in Rus.)
β“˜ Atokite
Formula: (Pd,Pt)3Sn
Reference: Rudashevskiy N.S., Krecer D.A., Orsoev D.A., Kislov E.V. (2003) Palladium-platinum mineralization in vein Cu-Ni-ores of Yoko-Dovyrenskiy laiered massif, - DAN, 391(4), p. 519-522 (in Rus.); Spiridonov, E. M., Orsoev, D. A., Ariskin, A. A., Kislov, E. V., Korotaeva, N. N., Nikolaev, G. S., & Yapaskurt, V. O. (2019). Germanium-Rich Palladium Minerals Palladogermanide Pd 2 Ge, Paolovite Pd 2 (Sn, Ge), and Zvyagintsevite in Sulfide-Bearing Anorthosites of the Yoko-Dovyren Pluton, Baikal Area. Geochemistry International, 57(5), 600-603.
β“˜ Augite
Formula: (CaxMgyFez)(Mgy1Fez1)Si2O6
Reference: Galuskin, Evgeny V. et al. (2007) Dovyrenite Ca6Zr[Si2O7]2(OH)4: Vol. 38(1) , 15-27.
β“˜ Augite var. Fassaite
Formula: (Ca,Na)(Mg,Fe2+,Al,Fe3+,Ti)[(Si,Al)2O6]
Reference: Galuskin, Evgeny V. et al. (2007) Dovyrenite Ca6Zr[Si2O7]2(OH)4: Vol. 38(1) , 15-27.
β“˜ 'Axinite Group'
Reference: Kislov, E.V.; Khudyakova, L.I. (2020) Yoko–Dovyren Layered Massif: Composition, Mineralization, Overburden and Dump Rock Utilization. Minerals 10, 682.
β“˜ Baddeleyite
Formula: ZrO2
Reference: Spiridonov, E. M., Ariskin, A. A., Kislov, E. V., Korotaeva, N. N., Nikolaev, G. S., Pshenitsyn, I. V., & Yapaskurt, V. O. (2018). Laurite and Ir-osmium from plagioclase lherzolite of the Yoko–Dovyren mafic–ultramafic pluton, Northern Baikal Region. Geology of Ore Deposits, 60(3), 210-219.
β“˜ Baghdadite
Formula: Ca6Zr2(Si2O7)2O4
Reference: Galuskin, Evgeny V. et al. (2007) Dovyrenite Ca6Zr[Si2O7]2(OH)4: Vol. 38(1) , 15-27.
β“˜ 'Biotite'
Formula: K(Fe2+/Mg)2(Al/Fe3+/Mg/Ti)([Si/Al/Fe]2Si2O10)(OH/F)2 or Simplified: K(Mg,Fe)3AlSi3O10(OH)2
Reference: Konnikov, E.G., Meurer, W.P., Neruchev, S.S., Prasolov, E.M., Kislov, E.V., and Orsoev, D.A. (2000): Mineralium Deposita 35, 526-532.
β“˜ Bismuth
Formula: Bi
Reference: Galuskin, E. V. et al. (2007): Dovyrenite Ca6Zr[Si2O7]2(OH)4 – A New Mineral From Skarned Carbonate Xenoliths In Basic-Ultrabasic Rocks Of The Ioko-Dovyren Massif, Northern Baikal Region, Russia. Mineralogia Polonica, 38, 15-27
β“˜ Bornite
Formula: Cu5FeS4
Reference: Konnikov, E.G., Meurer, W.P., Neruchev, S.S., Prasolov, E.M., Kislov, E.V., and Orsoev, D.A. (2000): Mineralium Deposita 35, 526-532. Spiridonov, E. M. (2020, September). Metamorphogenic–Hydrothermal Nielsenite, PdCu 3, in Sulfide-Bearing Anorthosites of the Yoko-Dovyren Intrusive in Baikalides of the Northern Baikal Region. In Doklady Earth Sciences (Vol. 494, pp. 704-706). Pleiades Publishing.
β“˜ Brucite
Formula: Mg(OH)2
Reference: Galuskin, Evgeny V. et al. (2007) Dovyrenite Ca6Zr[Si2O7]2(OH)4: Vol. 38(1) , 15-27.
β“˜ Calcite
Formula: CaCO3
Reference: Galuskin, Evgeny V. et al. (2007) Dovyrenite Ca6Zr[Si2O7]2(OH)4: Vol. 38(1) , 15-27.
β“˜ Calzirtite
Formula: Ca2Zr5Ti2O16
Reference: Galuskin, Evgeny V. et al. (2007) Dovyrenite Ca6Zr[Si2O7]2(OH)4: Vol. 38(1) , 15-27.
β“˜ Chalcocite
Formula: Cu2S
Reference: Spiridonov, E. M. (2020, September). Metamorphogenic–Hydrothermal Nielsenite, PdCu 3, in Sulfide-Bearing Anorthosites of the Yoko-Dovyren Intrusive in Baikalides of the Northern Baikal Region. In Doklady Earth Sciences (Vol. 494, pp. 704-706). Pleiades Publishing.
β“˜ Chalcopyrite
Formula: CuFeS2
Reference: Konnikov, E.G., Meurer, W.P., Neruchev, S.S., Prasolov, E.M., Kislov, E.V., and Orsoev, D.A. (2000): Mineralium Deposita 35, 526-532.; Ariskin, A. A., Kislov, E. V., Danyushevsky, L. V., Nikolaev, G. S., Fiorentini, M. L., Gilbert, S., ... & Malyshev, A. (2016). Cu–Ni–PGE fertility of the Yoko-Dovyren layered massif (northern Transbaikalia, Russia): thermodynamic modeling of sulfide compositions in low mineralized dunite based on quantitative sulfide mineralogy. Mineralium Deposita, 51(8), 993-1011.; Spiridonov, E. M., Orsoev, D. A., Ariskin, A. A., Kislov, E. V., Korotaeva, N. N., Nikolaev, G. S., & Yapaskurt, V. O. (2019). Germanium-Rich Palladium Minerals Palladogermanide Pd 2 Ge, Paolovite Pd 2 (Sn, Ge), and Zvyagintsevite in Sulfide-Bearing Anorthosites of the Yoko-Dovyren Pluton, Baikal Area. Geochemistry International, 57(5), 600-603.; Kislov, E.V.; Khudyakova, L.I. (2020) Yoko–Dovyren Layered Massif: Composition, Mineralization, Overburden and Dump Rock Utilization. Minerals 10, 682. Spiridonov, E. M. (2020, September). Metamorphogenic–Hydrothermal Nielsenite, PdCu 3, in Sulfide-Bearing Anorthosites of the Yoko-Dovyren Intrusive in Baikalides of the Northern Baikal Region. In Doklady Earth Sciences (Vol. 494, pp. 704-706). Pleiades Publishing.
β“˜ Chlorapatite
Formula: Ca5(PO4)3Cl
Reference: Spiridonov, E. M., Orsoev, D. A., Ariskin, A. A., Kislov, E. V., Korotaeva, N. N., Nikolaev, G. S., & Yapaskurt, V. O. (2019, April). Palladogermanide PdGe 2 from Sulfidized Anorthosite of the Yoko-Dovyren Intrusion: First Finding in Russia. In Doklady Earth Sciences (Vol. 485, No. 2, pp. 458-460). Pleiades Publishing.
β“˜ 'Chlorite Group'
Reference: Spiridonov, E. M., Ariskin, A. A., Kislov, E. V., Korotaeva, N. N., Nikolaev, G. S., Pshenitsyn, I. V., & Yapaskurt, V. O. (2018). Laurite and Ir-osmium from plagioclase lherzolite of the Yoko–Dovyren mafic–ultramafic pluton, Northern Baikal Region. Geology of Ore Deposits, 60(3), 210-219.; Kislov, E.V.; Khudyakova, L.I. (2020) Yoko–Dovyren Layered Massif: Composition, Mineralization, Overburden and Dump Rock Utilization. Minerals 10, 682.
β“˜ 'Chrome-Spinel (of Dana)'
Reference: Kislov, E.V.; Khudyakova, L.I. (2020) Yoko–Dovyren Layered Massif: Composition, Mineralization, Overburden and Dump Rock Utilization. Minerals 10, 682.
β“˜ Chromite
Formula: Fe2+Cr3+2O4
Reference: Spiridonov, E. M., Ariskin, A. A., Kislov, E. V., Korotaeva, N. N., Nikolaev, G. S., Pshenitsyn, I. V., & Yapaskurt, V. O. (2018). Laurite and Ir-osmium from plagioclase lherzolite of the Yoko–Dovyren mafic–ultramafic pluton, Northern Baikal Region. Geology of Ore Deposits, 60(3), 210-219.; Kislov, E.V.; Khudyakova, L.I. (2020) Yoko–Dovyren Layered Massif: Composition, Mineralization, Overburden and Dump Rock Utilization. Minerals 10, 682.
β“˜ Chromite var. Aluminian Chromite
Formula: Fe(Cr,Al)2O4
Reference: Spiridonov, E. M., Ariskin, A. A., Kislov, E. V., Korotaeva, N. N., Nikolaev, G. S., Pshenitsyn, I. V., & Yapaskurt, V. O. (2018). Laurite and Ir-osmium from plagioclase lherzolite of the Yoko–Dovyren mafic–ultramafic pluton, Northern Baikal Region. Geology of Ore Deposits, 60(3), 210-219.
β“˜ 'Chrysolite'
Reference: Spiridonov, E. M., Ariskin, A. A., Kislov, E. V., Korotaeva, N. N., Nikolaev, G. S., Pshenitsyn, I. V., & Yapaskurt, V. O. (2018). Laurite and Ir-osmium from plagioclase lherzolite of the Yoko–Dovyren mafic–ultramafic pluton, Northern Baikal Region. Geology of Ore Deposits, 60(3), 210-219.
β“˜ Chrysotile
Formula: Mg3(Si2O5)(OH)4
Reference: Spiridonov, E. M., Ariskin, A. A., Kislov, E. V., Korotaeva, N. N., Nikolaev, G. S., Pshenitsyn, I. V., & Yapaskurt, V. O. (2018). Laurite and Ir-osmium from plagioclase lherzolite of the Yoko–Dovyren mafic–ultramafic pluton, Northern Baikal Region. Geology of Ore Deposits, 60(3), 210-219.
β“˜ Clausthalite
Formula: PbSe
Reference: Galuskin, E. V. et al. (2007): Dovyrenite Ca6Zr[Si2O7]2(OH)4 – A New Mineral From Skarned Carbonate Xenoliths In Basic-Ultrabasic Rocks Of The Ioko-Dovyren Massif, Northern Baikal Region, Russia. Mineralogia Polonica, 38, 15-27
β“˜ 'Clinopyroxene Subgroup'
Reference: Kislov, E.V.; Khudyakova, L.I. (2020) Yoko–Dovyren Layered Massif: Composition, Mineralization, Overburden and Dump Rock Utilization. Minerals 10, 682.
β“˜ Clinozoisite
Formula: (CaCa)(AlAlAl)O[Si2O7][SiO4](OH)
Reference: Spiridonov, E. M. (2020, September). Metamorphogenic–Hydrothermal Nielsenite, PdCu 3, in Sulfide-Bearing Anorthosites of the Yoko-Dovyren Intrusive in Baikalides of the Northern Baikal Region. In Doklady Earth Sciences (Vol. 494, pp. 704-706). Pleiades Publishing.
β“˜ Clintonite
Formula: CaAlMg2(SiAl3O10)(OH)2
Reference: Kislov, E.V.; Khudyakova, L.I. (2020) Yoko–Dovyren Layered Massif: Composition, Mineralization, Overburden and Dump Rock Utilization. Minerals 10, 682.
β“˜ Cobaltite
Formula: CoAsS
Reference: Kislov, E.V.; Khudyakova, L.I. (2020) Yoko–Dovyren Layered Massif: Composition, Mineralization, Overburden and Dump Rock Utilization. Minerals 10, 682.
β“˜ Cobaltpentlandite
Formula: Co9S8
Reference: Kislov, E.V.; Khudyakova, L.I. (2020) Yoko–Dovyren Layered Massif: Composition, Mineralization, Overburden and Dump Rock Utilization. Minerals 10, 682.
β“˜ Colusite
Formula: Cu13VAs3S16
Reference: Spiridonov, E. M., Orsoev, D. A., Ariskin, A. A., Kislov, E. V., Korotaeva, N. N., Nikolaev, G. S., & Yapaskurt, V. O. (2019). Germanium-Rich Palladium Minerals Palladogermanide Pd 2 Ge, Paolovite Pd 2 (Sn, Ge), and Zvyagintsevite in Sulfide-Bearing Anorthosites of the Yoko-Dovyren Pluton, Baikal Area. Geochemistry International, 57(5), 600-603.
β“˜ Copper
Formula: Cu
Reference: Spiridonov, E. M. (2020, September). Metamorphogenic–Hydrothermal Nielsenite, PdCu 3, in Sulfide-Bearing Anorthosites of the Yoko-Dovyren Intrusive in Baikalides of the Northern Baikal Region. In Doklady Earth Sciences (Vol. 494, pp. 704-706). Pleiades Publishing.
β“˜ Cubanite
Formula: CuFe2S3
Reference: Konnikov, E.G., Meurer, W.P., Neruchev, S.S., Prasolov, E.M., Kislov, E.V., and Orsoev, D.A. (2000): Mineralium Deposita 35, 526-532.; Ariskin, A. A., Kislov, E. V., Danyushevsky, L. V., Nikolaev, G. S., Fiorentini, M. L., Gilbert, S., ... & Malyshev, A. (2016). Cu–Ni–PGE fertility of the Yoko-Dovyren layered massif (northern Transbaikalia, Russia): thermodynamic modeling of sulfide compositions in low mineralized dunite based on quantitative sulfide mineralogy. Mineralium Deposita, 51(8), 993-1011.; Spiridonov, E. M., Orsoev, D. A., Ariskin, A. A., Kislov, E. V., Korotaeva, N. N., Nikolaev, G. S., & Yapaskurt, V. O. (2019). Germanium-Rich Palladium Minerals Palladogermanide Pd 2 Ge, Paolovite Pd 2 (Sn, Ge), and Zvyagintsevite in Sulfide-Bearing Anorthosites of the Yoko-Dovyren Pluton, Baikal Area. Geochemistry International, 57(5), 600-603.
β“˜ Cuprite
Formula: Cu2O
Reference: Kislov, E.V.; Khudyakova, L.I. (2020) Yoko–Dovyren Layered Massif: Composition, Mineralization, Overburden and Dump Rock Utilization. Minerals 10, 682.
β“˜ Cuspidine
Formula: Ca8(Si2O7)2F4
Reference: Kislov, E.V.; Khudyakova, L.I. (2020) Yoko–Dovyren Layered Massif: Composition, Mineralization, Overburden and Dump Rock Utilization. Minerals 10, 682.
β“˜ Diaphorite
Formula: Ag3Pb2Sb3S8
Reference: Spiridonov, E. M. (2020, September). Metamorphogenic–Hydrothermal Nielsenite, PdCu 3, in Sulfide-Bearing Anorthosites of the Yoko-Dovyren Intrusive in Baikalides of the Northern Baikal Region. In Doklady Earth Sciences (Vol. 494, pp. 704-706). Pleiades Publishing.
β“˜ Digenite
Formula: Cu9S5
Reference: Spiridonov, E. M. (2020, September). Metamorphogenic–Hydrothermal Nielsenite, PdCu 3, in Sulfide-Bearing Anorthosites of the Yoko-Dovyren Intrusive in Baikalides of the Northern Baikal Region. In Doklady Earth Sciences (Vol. 494, pp. 704-706). Pleiades Publishing.
β“˜ Diopside
Formula: CaMgSi2O6
Colour: blue, green
Reference: Galuskin, Evgeny V. et al. (2007) Dovyrenite Ca6Zr[Si2O7]2(OH)4: Vol. 38(1) , 15-27.; Khomenko VM, Platonov AN, Steshin VA The structure and conditions of formation of the centers of the blue color in diopside skarns of // ZVMO. 1986 Part 115 Issue. 6, pp. 689-698
trans.png
Blue Diopside, etc.

Snezhniy prospect, Yoko-Dovyrensky Massif, Dovyren Highlands, Severo-Baykalsky District, Buryatia, Russia
β“˜ Diopside var. Blue Diopside
Formula: CaMgSi2O6
Colour: blue
Reference: Khomenko VM, Platonov AN, Steshin VA (1986) The structure and conditions of formation of the centers of the blue color in diopside skarns of // ZVMO. Part 115 Issue. 6, pp. 689-698; Pavel M. Kartashov data
β“˜ Djerfisherite
Formula: K6(Fe,Cu,Ni)25S26Cl
Reference: Kislov, E.V.; Khudyakova, L.I. (2020) Yoko–Dovyren Layered Massif: Composition, Mineralization, Overburden and Dump Rock Utilization. Minerals 10, 682.
β“˜ Dolomite
Formula: CaMg(CO3)2
Reference: Spiridonov, E. M., Orsoev, D. A., Ariskin, A. A., Kislov, E. V., Korotaeva, N. N., Nikolaev, G. S., & Yapaskurt, V. O. (2019). Germanium-Rich Palladium Minerals Palladogermanide Pd 2 Ge, Paolovite Pd 2 (Sn, Ge), and Zvyagintsevite in Sulfide-Bearing Anorthosites of the Yoko-Dovyren Pluton, Baikal Area. Geochemistry International, 57(5), 600-603.; Kislov, E.V.; Khudyakova, L.I. (2020) Yoko–Dovyren Layered Massif: Composition, Mineralization, Overburden and Dump Rock Utilization. Minerals 10, 682.
trans.png
Dovyrenite

Yoko-Dovyrensky Massif, Dovyren Highlands, Severo-Baykalsky District, Buryatia, Russia
β“˜ Dovyrenite (TL)
Formula: Ca6Zr(Si2O7)2(OH)4
Reference: Galuskin, E. V. et al. (2007) Dovyrenite Ca6Zr[Si2O7]2(OH)4 - a new mineral from skarned carbonate xenoliths in basic-ultrabasic rocks of the Ioko-Dovyren Massif, Northern Baikal region, Russia. Mineralogia Polonica 38, 15-27.
β“˜ Edenite
Formula: NaCa2Mg5(Si7Al)O22(OH)2
Reference: Spiridonov, E. M., Ariskin, A. A., Kislov, E. V., Korotaeva, N. N., Nikolaev, G. S., Pshenitsyn, I. V., & Yapaskurt, V. O. (2018). Laurite and Ir-osmium from plagioclase lherzolite of the Yoko–Dovyren mafic–ultramafic pluton, Northern Baikal Region. Geology of Ore Deposits, 60(3), 210-219.
β“˜ 'Endiopside'
Reference: Spiridonov, E. M., Orsoev, D. A., Ariskin, A. A., Kislov, E. V., Korotaeva, N. N., Nikolaev, G. S., & Yapaskurt, V. O. (2019). Germanium-Rich Palladium Minerals Palladogermanide Pd 2 Ge, Paolovite Pd 2 (Sn, Ge), and Zvyagintsevite in Sulfide-Bearing Anorthosites of the Yoko-Dovyren Pluton, Baikal Area. Geochemistry International, 57(5), 600-603.
β“˜ Enstatite
Formula: Mg2Si2O6
Reference: Spiridonov, E. M., Ariskin, A. A., Kislov, E. V., Korotaeva, N. N., Nikolaev, G. S., Pshenitsyn, I. V., & Yapaskurt, V. O. (2018). Laurite and Ir-osmium from plagioclase lherzolite of the Yoko–Dovyren mafic–ultramafic pluton, Northern Baikal Region. Geology of Ore Deposits, 60(3), 210-219.
β“˜ Enstatite var. Bronzite
Formula: (Mg,Fe2+)2[SiO3]2
Reference: Spiridonov, E. M., Ariskin, A. A., Kislov, E. V., Korotaeva, N. N., Nikolaev, G. S., Pshenitsyn, I. V., & Yapaskurt, V. O. (2018). Laurite and Ir-osmium from plagioclase lherzolite of the Yoko–Dovyren mafic–ultramafic pluton, Northern Baikal Region. Geology of Ore Deposits, 60(3), 210-219.
β“˜ 'Fayalite-Forsterite Series'
Reference: Ariskin, A. A., Kislov, E. V., Danyushevsky, L. V., Nikolaev, G. S., Fiorentini, M. L., Gilbert, S., ... & Malyshev, A. (2016). Cu–Ni–PGE fertility of the Yoko-Dovyren layered massif (northern Transbaikalia, Russia): thermodynamic modeling of sulfide compositions in low mineralized dunite based on quantitative sulfide mineralogy. Mineralium Deposita, 51(8), 993-1011.; Spiridonov, E. M., Orsoev, D. A., Ariskin, A. A., Kislov, E. V., Korotaeva, N. N., Nikolaev, G. S., & Yapaskurt, V. O. (2019). Germanium-Rich Palladium Minerals Palladogermanide Pd 2 Ge, Paolovite Pd 2 (Sn, Ge), and Zvyagintsevite in Sulfide-Bearing Anorthosites of the Yoko-Dovyren Pluton, Baikal Area. Geochemistry International, 57(5), 600-603.; Kislov, E.V.; Khudyakova, L.I. (2020) Yoko–Dovyren Layered Massif: Composition, Mineralization, Overburden and Dump Rock Utilization. Minerals 10, 682.
β“˜ Ferro-edenite
Formula: NaCa2Fe2+5(Si7Al)O22(OH)2
Reference: Spiridonov, E. M., Orsoev, D. A., Ariskin, A. A., Kislov, E. V., Korotaeva, N. N., Nikolaev, G. S., & Yapaskurt, V. O. (2019, April). Palladogermanide PdGe 2 from Sulfidized Anorthosite of the Yoko-Dovyren Intrusion: First Finding in Russia. In Doklady Earth Sciences (Vol. 485, No. 2, pp. 458-460). Pleiades Publishing.
β“˜ Fluorapatite
Formula: Ca5(PO4)3F
Reference: Pavel M. Kartashov data; Konnikov, E.G., Meurer, W.P., Neruchev, S.S., Prasolov, E.M., Kislov, E.V., and Orsoev, D.A. (2000): Mineralium Deposita 35, 526-532.
β“˜ Forsterite
Formula: Mg2SiO4
Reference: Konnikov, E.G., Meurer, W.P., Neruchev, S.S., Prasolov, E.M., Kislov, E.V., and Orsoev, D.A. (2000): Mineralium Deposita 35, 526-532.; Ariskin, A. A., Spiridonov, E. M., Nikolaev, G. S., Danyushevsky, L. V., Fiorentini, M. L., Kislov, E. V., & Pshenitsyn, I. V. (2017). Sulphide Controlled Fractionation of PGE at Post-cumulus Crystallization of Primitive Olivine Cumulate Piles from the Yoko-dovyren Layered Intrusion. In Magmatism of the Earth and related strategic metal deposits (pp. 12-14).
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Foshagite, etc.

Snezhniy prospect, Yoko-Dovyrensky Massif, Dovyren Highlands, Severo-Baykalsky District, Buryatia, Russia
β“˜ Foshagite
Formula: Ca4(Si3O9)(OH)2
Colour: pink
Reference: Galuskin, Evgeny V. et al. (2007) Dovyrenite Ca6Zr[Si2O7]2(OH)4: Vol. 38(1) , 15-27.
β“˜ Froodite
Formula: α-PdBi2
Reference: Spiridonov, E. M., Orsoev, D. A., Ariskin, A. A., Kislov, E. V., Korotaeva, N. N., Nikolaev, G. S., & Yapaskurt, V. O. (2019, April). Palladogermanide PdGe 2 from Sulfidized Anorthosite of the Yoko-Dovyren Intrusion: First Finding in Russia. In Doklady Earth Sciences (Vol. 485, No. 2, pp. 458-460). Pleiades Publishing.
β“˜ Galena
Formula: PbS
Reference: Galuskin, E. V. et al. (2007): Dovyrenite Ca6Zr[Si2O7]2(OH)4 – A New Mineral From Skarned Carbonate Xenoliths In Basic-Ultrabasic Rocks Of The Ioko-Dovyren Massif, Northern Baikal Region, Russia. Mineralogia Polonica, 38, 15-27; Spiridonov, E. M., Orsoev, D. A., Ariskin, A. A., Kislov, E. V., Korotaeva, N. N., Nikolaev, G. S., & Yapaskurt, V. O. (2019). Germanium-Rich Palladium Minerals Palladogermanide Pd 2 Ge, Paolovite Pd 2 (Sn, Ge), and Zvyagintsevite in Sulfide-Bearing Anorthosites of the Yoko-Dovyren Pluton, Baikal Area. Geochemistry International, 57(5), 600-603.; Kislov, E.V.; Khudyakova, L.I. (2020) Yoko–Dovyren Layered Massif: Composition, Mineralization, Overburden and Dump Rock Utilization. Minerals 10, 682.
β“˜ Galena var. Selenium-bearing Galena
Formula: Pb(S,Se)
Reference: Galuskin, E. V. et al. (2007): Dovyrenite Ca6Zr[Si2O7]2(OH)4 – A New Mineral From Skarned Carbonate Xenoliths In Basic-Ultrabasic Rocks Of The Ioko-Dovyren Massif, Northern Baikal Region, Russia. Mineralogia Polonica, 38, 15-27
β“˜ 'Garnet Group'
Formula: X3Z2(SiO4)3
Reference: Kislov, E.V.; Khudyakova, L.I. (2020) Yoko–Dovyren Layered Massif: Composition, Mineralization, Overburden and Dump Rock Utilization. Minerals 10, 682.
β“˜ Germanite
Formula: Cu13Fe2Ge2S16
Reference: Kislov, E.V.; Khudyakova, L.I. (2020) Yoko–Dovyren Layered Massif: Composition, Mineralization, Overburden and Dump Rock Utilization. Minerals 10, 682.
β“˜ Germanocolusite
Formula: Cu26V2(Ge,As)6S32
Reference: Spiridonov, E. M., Orsoev, D. A., Ariskin, A. A., Kislov, E. V., Korotaeva, N. N., Nikolaev, G. S., & Yapaskurt, V. O. (2019, April). Palladogermanide PdGe 2 from Sulfidized Anorthosite of the Yoko-Dovyren Intrusion: First Finding in Russia. In Doklady Earth Sciences (Vol. 485, No. 2, pp. 458-460). Pleiades Publishing.
β“˜ Geversite
Formula: PtSb2
Reference: Rudashevskiy N.S., Krecer D.A., Orsoev D.A., Kislov E.V. (2003) Palladium-platinum mineralization in vein Cu-Ni-ores of Yoko-Dovyrenskiy laiered massif, - DAN, 391(4), p. 519-522 (in Rus.); Ariskin, A. A., Kislov, E. V., Danyushevsky, L. V., Nikolaev, G. S., Fiorentini, M. L., Gilbert, S., ... & Malyshev, A. (2016). Cu–Ni–PGE fertility of the Yoko-Dovyren layered massif (northern Transbaikalia, Russia): thermodynamic modeling of sulfide compositions in low mineralized dunite based on quantitative sulfide mineralogy. Mineralium Deposita, 51(8), 993-1011.
β“˜ Godlevskite
Formula: (Ni,Fe)9S8
Reference: Konnikov, E.G., Meurer, W.P., Neruchev, S.S., Prasolov, E.M., Kislov, E.V., and Orsoev, D.A. (2000): Mineralium Deposita 35, 526-532.
β“˜ Goethite
Formula: Ξ±-Fe3+O(OH)
Reference: Kislov, E.V.; Khudyakova, L.I. (2020) Yoko–Dovyren Layered Massif: Composition, Mineralization, Overburden and Dump Rock Utilization. Minerals 10, 682.
β“˜ Gold
Formula: Au
Reference: Ariskin, A. A., Spiridonov, E. M., Nikolaev, G. S., Danyushevsky, L. V., Fiorentini, M. L., Kislov, E. V., & Pshenitsyn, I. V. (2017). Sulphide Controlled Fractionation of PGE at Post-cumulus Crystallization of Primitive Olivine Cumulate Piles from the Yoko-dovyren Layered Intrusion. In Magmatism of the Earth and related strategic metal deposits (pp. 12-14).; Spiridonov, E. M., Orsoev, D. A., Ariskin, A. A., Kislov, E. V., Korotaeva, N. N., Nikolaev, G. S., & Yapaskurt, V. O. (2019). Germanium-Rich Palladium Minerals Palladogermanide Pd 2 Ge, Paolovite Pd 2 (Sn, Ge), and Zvyagintsevite in Sulfide-Bearing Anorthosites of the Yoko-Dovyren Pluton, Baikal Area. Geochemistry International, 57(5), 600-603.
β“˜ Gold var. Electrum
Formula: (Au,Ag)
Reference: Ariskin, A. A., Kislov, E. V., Danyushevsky, L. V., Nikolaev, G. S., Fiorentini, M. L., Gilbert, S., ... & Malyshev, A. (2016). Cu–Ni–PGE fertility of the Yoko-Dovyren layered massif (northern Transbaikalia, Russia): thermodynamic modeling of sulfide compositions in low mineralized dunite based on quantitative sulfide mineralogy. Mineralium Deposita, 51(8), 993-1011. Spiridonov, E. M. (2020, September). Metamorphogenic–Hydrothermal Nielsenite, PdCu 3, in Sulfide-Bearing Anorthosites of the Yoko-Dovyren Intrusive in Baikalides of the Northern Baikal Region. In Doklady Earth Sciences (Vol. 494, pp. 704-706). Pleiades Publishing.
β“˜ Grossular
Formula: Ca3Al2(SiO4)3
Reference: Kislov, E.V.; Khudyakova, L.I. (2020) Yoko–Dovyren Layered Massif: Composition, Mineralization, Overburden and Dump Rock Utilization. Minerals 10, 682.
β“˜ Grossular var. Hydrogrossular
Reference: Kislov, E.V.; Khudyakova, L.I. (2020) Yoko–Dovyren Layered Massif: Composition, Mineralization, Overburden and Dump Rock Utilization. Minerals 10, 682.
β“˜ Halite
Formula: NaCl
Reference: Kislov, E.V.; Khudyakova, L.I. (2020) Yoko–Dovyren Layered Massif: Composition, Mineralization, Overburden and Dump Rock Utilization. Minerals 10, 682.
β“˜ Heazlewoodite
Formula: Ni3S2
Reference: Konnikov, E.G., Meurer, W.P., Neruchev, S.S., Prasolov, E.M., Kislov, E.V., and Orsoev, D.A. (2000): Mineralium Deposita 35, 526-532. Spiridonov, E. M. (2020, September). Metamorphogenic–Hydrothermal Nielsenite, PdCu 3, in Sulfide-Bearing Anorthosites of the Yoko-Dovyren Intrusive in Baikalides of the Northern Baikal Region. In Doklady Earth Sciences (Vol. 494, pp. 704-706). Pleiades Publishing.
β“˜ Hercynite
Formula: Fe2+Al2O4
Reference: Kislov, E.V.; Khudyakova, L.I. (2020) Yoko–Dovyren Layered Massif: Composition, Mineralization, Overburden and Dump Rock Utilization. Minerals 10, 682.
β“˜ Hercynite var. Picotite
Formula: (Fe,Mg)(Al,Cr)2O4
Reference: Kislov, E.V.; Khudyakova, L.I. (2020) Yoko–Dovyren Layered Massif: Composition, Mineralization, Overburden and Dump Rock Utilization. Minerals 10, 682.
β“˜ Hessite
Formula: Ag2Te
Reference: Spiridonov, E. M., Orsoev, D. A., Ariskin, A. A., Kislov, E. V., Korotaeva, N. N., Nikolaev, G. S., & Yapaskurt, V. O. (2019). Germanium-Rich Palladium Minerals Palladogermanide Pd 2 Ge, Paolovite Pd 2 (Sn, Ge), and Zvyagintsevite in Sulfide-Bearing Anorthosites of the Yoko-Dovyren Pluton, Baikal Area. Geochemistry International, 57(5), 600-603.
β“˜ 'Hydrogarnet'
Reference: GALUSKIN, Evgeny V. et al. (2007), Dovyrenite Ca6Zr[Si2O7]2(OH)4. Mineralogia Polonica, Vol. 38, No 1, 15-27. Spiridonov, E. M. (2020, September). Metamorphogenic–Hydrothermal Nielsenite, PdCu 3, in Sulfide-Bearing Anorthosites of the Yoko-Dovyren Intrusive in Baikalides of the Northern Baikal Region. In Doklady Earth Sciences (Vol. 494, pp. 704-706). Pleiades Publishing.
β“˜ Hydroxylapatite
Formula: Ca5(PO4)3(OH)
Reference: Galuskin, E. V. et al. (2007): Dovyrenite Ca6Zr[Si2O7]2(OH)4 – A New Mineral From Skarned Carbonate Xenoliths In Basic-Ultrabasic Rocks Of The Ioko-Dovyren Massif, Northern Baikal Region, Russia. Mineralogia Polonica, 38, 15-27
β“˜ Hydroxylellestadite
Formula: Ca5(SiO4)1.5(SO4)1.5(OH)
Reference: American Mineralogist, Volume 94, pages 323–333, 2009
β“˜ Ilmenite
Formula: Fe2+TiO3
Reference: Rudashevskiy N.S., Krecer D.A., Orsoev D.A., Kislov E.V. (2003) Palladium-platinum mineralization in vein Cu-Ni-ores of Yoko-Dovyrenskiy laiered massif, - DAN, 391(4), p. 519-522 (in Rus.); Ariskin, A. A., Kislov, E. V., Danyushevsky, L. V., Nikolaev, G. S., Fiorentini, M. L., Gilbert, S., ... & Malyshev, A. (2016). Cu–Ni–PGE fertility of the Yoko-Dovyren layered massif (northern Transbaikalia, Russia): thermodynamic modeling of sulfide compositions in low mineralized dunite based on quantitative sulfide mineralogy. Mineralium Deposita, 51(8), 993-1011.; Spiridonov, E. M., Orsoev, D. A., Ariskin, A. A., Kislov, E. V., Korotaeva, N. N., Nikolaev, G. S., & Yapaskurt, V. O. (2019). Germanium-Rich Palladium Minerals Palladogermanide Pd 2 Ge, Paolovite Pd 2 (Sn, Ge), and Zvyagintsevite in Sulfide-Bearing Anorthosites of the Yoko-Dovyren Pluton, Baikal Area. Geochemistry International, 57(5), 600-603.
β“˜ Insizwaite
Formula: Pt(Bi,Sb)2
Reference: Spiridonov, E. M., Ariskin, A. A., Kislov, E. V., Korotaeva, N. N., Nikolaev, G. S., Pshenitsyn, I. V., & Yapaskurt, V. O. (2018). Laurite and Ir-osmium from plagioclase lherzolite of the Yoko–Dovyren mafic–ultramafic pluton, Northern Baikal Region. Geology of Ore Deposits, 60(3), 210-219.
β“˜ Irarsite
Formula: (Ir,Ru,Rh,Pt)AsS
Reference: Spiridonov, E. M., Ariskin, A. A., Kislov, E. V., Korotaeva, N. N., Nikolaev, G. S., Pshenitsyn, I. V., & Yapaskurt, V. O. (2018). Laurite and Ir-osmium from plagioclase lherzolite of the Yoko–Dovyren mafic–ultramafic pluton, Northern Baikal Region. Geology of Ore Deposits, 60(3), 210-219.
β“˜ Isoferroplatinum
Formula: Pt3Fe
Reference: Rudashevskiy N.S., Krecer D.A., Orsoev D.A., Kislov E.V. (2003) Palladium-platinum mineralization in vein Cu-Ni-ores of Yoko-Dovyrenskiy laiered massif, - DAN, 391(4), p. 519-522 (in Rus.)
β“˜ Kotulskite
Formula: Pd(Te,Bi)2-x (x ≈ 0.4)
Reference: Rudashevskiy N.S., Krecer D.A., Orsoev D.A., Kislov E.V. (2003) Palladium-platinum mineralization in vein Cu-Ni-ores of Yoko-Dovyrenskiy laiered massif, - DAN, 391(4), p. 519-522 (in Rus.); Spiridonov, E. M., Orsoev, D. A., Ariskin, A. A., Kislov, E. V., Korotaeva, N. N., Nikolaev, G. S., & Yapaskurt, V. O. (2019). Germanium-Rich Palladium Minerals Palladogermanide Pd 2 Ge, Paolovite Pd 2 (Sn, Ge), and Zvyagintsevite in Sulfide-Bearing Anorthosites of the Yoko-Dovyren Pluton, Baikal Area. Geochemistry International, 57(5), 600-603. Spiridonov, E. M. (2020, September). Metamorphogenic–Hydrothermal Nielsenite, PdCu 3, in Sulfide-Bearing Anorthosites of the Yoko-Dovyren Intrusive in Baikalides of the Northern Baikal Region. In Doklady Earth Sciences (Vol. 494, pp. 704-706). Pleiades Publishing.
β“˜ Laitakarite
Formula: Bi4Se2S
Reference: Galuskin, E. V. et al. (2007): Dovyrenite Ca6Zr[Si2O7]2(OH)4 – A New Mineral From Skarned Carbonate Xenoliths In Basic-Ultrabasic Rocks Of The Ioko-Dovyren Massif, Northern Baikal Region, Russia. Mineralogia Polonica, 38, 15-27
β“˜ Laurite
Formula: RuS2
Reference: Spiridonov, E. M., Ariskin, A. A., Kislov, E. V., Korotaeva, N. N., Nikolaev, G. S., Pshenitsyn, I. V., & Yapaskurt, V. O. (2018). Laurite and Ir-osmium from plagioclase lherzolite of the Yoko–Dovyren mafic–ultramafic pluton, Northern Baikal Region. Geology of Ore Deposits, 60(3), 210-219.
β“˜ 'Limonite'
Reference: Spiridonov, E. M., Orsoev, D. A., Ariskin, A. A., Kislov, E. V., Korotaeva, N. N., Nikolaev, G. S., & Yapaskurt, V. O. (2019). Germanium-Rich Palladium Minerals Palladogermanide Pd 2 Ge, Paolovite Pd 2 (Sn, Ge), and Zvyagintsevite in Sulfide-Bearing Anorthosites of the Yoko-Dovyren Pluton, Baikal Area. Geochemistry International, 57(5), 600-603.
β“˜ Lizardite
Formula: Mg3(Si2O5)(OH)4
Reference: Spiridonov, E. M. (2020, September). Metamorphogenic–Hydrothermal Nielsenite, PdCu 3, in Sulfide-Bearing Anorthosites of the Yoko-Dovyren Intrusive in Baikalides of the Northern Baikal Region. In Doklady Earth Sciences (Vol. 494, pp. 704-706). Pleiades Publishing.
β“˜ Mackinawite
Formula: (Fe,Ni)9S8
Reference: Rudashevskiy N.S., Krecer D.A., Orsoev D.A., Kislov E.V. (2003) Palladium-platinum mineralization in vein Cu-Ni-ores of Yoko-Dovyrenskiy laiered massif, - DAN, 391(4), p. 519-522 (in Rus.); Ariskin, A. A., Kislov, E. V., Danyushevsky, L. V., Nikolaev, G. S., Fiorentini, M. L., Gilbert, S., ... & Malyshev, A. (2016). Cu–Ni–PGE fertility of the Yoko-Dovyren layered massif (northern Transbaikalia, Russia): thermodynamic modeling of sulfide compositions in low mineralized dunite based on quantitative sulfide mineralogy. Mineralium Deposita, 51(8), 993-1011.
β“˜ Magnetite
Formula: Fe2+Fe3+2O4
Reference: Ariskin, A. A., Kislov, E. V., Danyushevsky, L. V., Nikolaev, G. S., Fiorentini, M. L., Gilbert, S., ... & Malyshev, A. (2016). Cu–Ni–PGE fertility of the Yoko-Dovyren layered massif (northern Transbaikalia, Russia): thermodynamic modeling of sulfide compositions in low mineralized dunite based on quantitative sulfide mineralogy. Mineralium Deposita, 51(8), 993-1011.; Spiridonov, E. M., Orsoev, D. A., Ariskin, A. A., Kislov, E. V., Korotaeva, N. N., Nikolaev, G. S., & Yapaskurt, V. O. (2019). Germanium-Rich Palladium Minerals Palladogermanide Pd 2 Ge, Paolovite Pd 2 (Sn, Ge), and Zvyagintsevite in Sulfide-Bearing Anorthosites of the Yoko-Dovyren Pluton, Baikal Area. Geochemistry International, 57(5), 600-603. Spiridonov, E. M. (2020, September). Metamorphogenic–Hydrothermal Nielsenite, PdCu 3, in Sulfide-Bearing Anorthosites of the Yoko-Dovyren Intrusive in Baikalides of the Northern Baikal Region. In Doklady Earth Sciences (Vol. 494, pp. 704-706). Pleiades Publishing.
β“˜ Magnetite var. Titanium-bearing Magnetite
Formula: Fe2+(Fe3+,Ti)2O4
Reference: Ariskin, A. A., Kislov, E. V., Danyushevsky, L. V., Nikolaev, G. S., Fiorentini, M. L., Gilbert, S., ... & Malyshev, A. (2016). Cu–Ni–PGE fertility of the Yoko-Dovyren layered massif (northern Transbaikalia, Russia): thermodynamic modeling of sulfide compositions in low mineralized dunite based on quantitative sulfide mineralogy. Mineralium Deposita, 51(8), 993-1011.; Spiridonov, E. M., Orsoev, D. A., Ariskin, A. A., Kislov, E. V., Korotaeva, N. N., Nikolaev, G. S., & Yapaskurt, V. O. (2019). Germanium-Rich Palladium Minerals Palladogermanide Pd 2 Ge, Paolovite Pd 2 (Sn, Ge), and Zvyagintsevite in Sulfide-Bearing Anorthosites of the Yoko-Dovyren Pluton, Baikal Area. Geochemistry International, 57(5), 600-603.
β“˜ Majakite
Formula: PdNiAs
Reference: Rudashevskiy N.S., Krecer D.A., Orsoev D.A., Kislov E.V. (2003) Palladium-platinum mineralization in vein Cu-Ni-ores of Yoko-Dovyrenskiy laiered massif, - DAN, 391(4), p. 519-522 (in Rus.); Spiridonov, E. M., Orsoev, D. A., Ariskin, A. A., Kislov, E. V., Korotaeva, N. N., Nikolaev, G. S., & Yapaskurt, V. O. (2019). Germanium-Rich Palladium Minerals Palladogermanide Pd 2 Ge, Paolovite Pd 2 (Sn, Ge), and Zvyagintsevite in Sulfide-Bearing Anorthosites of the Yoko-Dovyren Pluton, Baikal Area. Geochemistry International, 57(5), 600-603.
β“˜ Maslovite
Formula: PtBiTe
Reference: Rudashevskiy N.S., Krecer D.A., Orsoev D.A., Kislov E.V. (2003) Palladium-platinum mineralization in vein Cu-Ni-ores of Yoko-Dovyrenskiy laiered massif, - DAN, 391(4), p. 519-522 (in Rus.)
β“˜ Maucherite
Formula: Ni11As8
Reference: Rudashevskiy N.S., Krecer D.A., Orsoev D.A., Kislov E.V. (2003) Palladium-platinum mineralization in vein Cu-Ni-ores of Yoko-Dovyrenskiy laiered massif, - DAN, 391(4), p. 519-522 (in Rus.)
β“˜ 'Melilite Group'
Formula: Ca2M(XSiO7)
Reference: Galuskin, Evgeny V. et al. (2007) Dovyrenite Ca6Zr[Si2O7]2(OH)4: Vol. 38(1) , 15-27.
β“˜ Mertieite
Formula: Pd8Sb2.5As0.5
Reference: Ariskin, A. A., Kislov, E. V., Danyushevsky, L. V., Nikolaev, G. S., Fiorentini, M. L., Gilbert, S., ... & Malyshev, A. (2016). Cu–Ni–PGE fertility of the Yoko-Dovyren layered massif (northern Transbaikalia, Russia): thermodynamic modeling of sulfide compositions in low mineralized dunite based on quantitative sulfide mineralogy. Mineralium Deposita, 51(8), 993-1011.; Spiridonov, E. M., Orsoev, D. A., Ariskin, A. A., Kislov, E. V., Korotaeva, N. N., Nikolaev, G. S., & Yapaskurt, V. O. (2019). Germanium-Rich Palladium Minerals Palladogermanide Pd 2 Ge, Paolovite Pd 2 (Sn, Ge), and Zvyagintsevite in Sulfide-Bearing Anorthosites of the Yoko-Dovyren Pluton, Baikal Area. Geochemistry International, 57(5), 600-603.; Rudashevskiy N.S., Krecer D.A., Orsoev D.A., Kislov E.V. (2003) Palladium-platinum mineralization in vein Cu-Ni-ores of Yoko-Dovyrenskiy laiered massif, - DAN, 391(4), p. 519-522 (in Rus.)
β“˜ Merwinite
Formula: Ca3Mg(SiO4)2
Reference: American Mineralogist, Volume 94, pages 323–333, 2009
β“˜ Michenerite
Formula: PdBiTe
Reference: Spiridonov, E. M., Orsoev, D. A., Ariskin, A. A., Kislov, E. V., Korotaeva, N. N., Nikolaev, G. S., & Yapaskurt, V. O. (2019). Germanium-Rich Palladium Minerals Palladogermanide Pd 2 Ge, Paolovite Pd 2 (Sn, Ge), and Zvyagintsevite in Sulfide-Bearing Anorthosites of the Yoko-Dovyren Pluton, Baikal Area. Geochemistry International, 57(5), 600-603. Spiridonov, E. M. (2020, September). Metamorphogenic–Hydrothermal Nielsenite, PdCu 3, in Sulfide-Bearing Anorthosites of the Yoko-Dovyren Intrusive in Baikalides of the Northern Baikal Region. In Doklady Earth Sciences (Vol. 494, pp. 704-706). Pleiades Publishing.
β“˜ Molybdenite
Formula: MoS2
Reference: Ariskin, A. A., Kislov, E. V., Danyushevsky, L. V., Nikolaev, G. S., Fiorentini, M. L., Gilbert, S., ... & Malyshev, A. (2016). Cu–Ni–PGE fertility of the Yoko-Dovyren layered massif (northern Transbaikalia, Russia): thermodynamic modeling of sulfide compositions in low mineralized dunite based on quantitative sulfide mineralogy. Mineralium Deposita, 51(8), 993-1011.
β“˜ 'Monazite'
Formula: REE(PO4)
Reference: Spiridonov, E. M., Ariskin, A. A., Kislov, E. V., Korotaeva, N. N., Nikolaev, G. S., Pshenitsyn, I. V., & Yapaskurt, V. O. (2018). Laurite and Ir-osmium from plagioclase lherzolite of the Yoko–Dovyren mafic–ultramafic pluton, Northern Baikal Region. Geology of Ore Deposits, 60(3), 210-219.
β“˜ Moncheite
Formula: Pt(Te,Bi)2
Reference: Konnikov, E.G., Meurer, W.P., Neruchev, S.S., Prasolov, E.M., Kislov, E.V., and Orsoev, D.A. (2000): Mineralium Deposita 35, 526-532.; Rudashevskiy N.S., Krecer D.A., Orsoev D.A., Kislov E.V. (2003) Palladium-platinum mineralization in vein Cu-Ni-ores of Yoko-Dovyrenskiy laiered massif, - DAN, 391(4), p. 519-522 (in Rus.); Spiridonov, E. M., Orsoev, D. A., Ariskin, A. A., Kislov, E. V., Korotaeva, N. N., Nikolaev, G. S., & Yapaskurt, V. O. (2019). Germanium-Rich Palladium Minerals Palladogermanide Pd 2 Ge, Paolovite Pd 2 (Sn, Ge), and Zvyagintsevite in Sulfide-Bearing Anorthosites of the Yoko-Dovyren Pluton, Baikal Area. Geochemistry International, 57(5), 600-603. Spiridonov, E. M. (2020, September). Metamorphogenic–Hydrothermal Nielsenite, PdCu 3, in Sulfide-Bearing Anorthosites of the Yoko-Dovyren Intrusive in Baikalides of the Northern Baikal Region. In Doklady Earth Sciences (Vol. 494, pp. 704-706). Pleiades Publishing.
β“˜ Monticellite
Formula: CaMgSiO4
Reference: Galuskin, Evgeny V. et al. (2007) Dovyrenite Ca6Zr[Si2O7]2(OH)4: Vol. 38(1) , 15-27.; Konnikov, E.G., Meurer, W.P., Neruchev, S.S., Prasolov, E.M., Kislov, E.V., and Orsoev, D.A. (2000): Mineralium Deposita 35, 526-532.
β“˜ Naldrettite
Formula: Pd2Sb
Reference: Ariskin, A. A., Kislov, E. V., Danyushevsky, L. V., Nikolaev, G. S., Fiorentini, M. L., Gilbert, S., ... & Malyshev, A. (2016). Cu–Ni–PGE fertility of the Yoko-Dovyren layered massif (northern Transbaikalia, Russia): thermodynamic modeling of sulfide compositions in low mineralized dunite based on quantitative sulfide mineralogy. Mineralium Deposita, 51(8), 993-1011.
β“˜ Nepheline
Formula: Na3K(Al4Si4O16)
Reference: Kislov, E.V.; Khudyakova, L.I. (2020) Yoko–Dovyren Layered Massif: Composition, Mineralization, Overburden and Dump Rock Utilization. Minerals 10, 682.
β“˜ Nickeline
Formula: NiAs
Reference: Galuskin, E. V. et al. (2007): Dovyrenite Ca6Zr[Si2O7]2(OH)4 – A New Mineral From Skarned Carbonate Xenoliths In Basic-Ultrabasic Rocks Of The Ioko-Dovyren Massif, Northern Baikal Region, Russia. Mineralogia Polonica, 38, 15-27
β“˜ Nickelskutterudite
Formula: (Ni,Co,Fe)As3
Reference: Galuskin, E. V. et al. (2007): Dovyrenite Ca6Zr[Si2O7]2(OH)4 – A New Mineral From Skarned Carbonate Xenoliths In Basic-Ultrabasic Rocks Of The Ioko-Dovyren Massif, Northern Baikal Region, Russia. Mineralogia Polonica, 38, 15-27
β“˜ Nielsenite
Formula: PdCu3
Reference: Spiridonov, E. M. (2020, September). Metamorphogenic–Hydrothermal Nielsenite, PdCu 3, in Sulfide-Bearing Anorthosites of the Yoko-Dovyren Intrusive in Baikalides of the Northern Baikal Region. In Doklady Earth Sciences (Vol. 494, pp. 704-706). Pleiades Publishing.
β“˜ Niggliite
Formula: PtSn
Reference: Spiridonov, E. M., Ariskin, A. A., Kislov, E. V., Korotaeva, N. N., Nikolaev, G. S., Pshenitsyn, I. V., & Yapaskurt, V. O. (2018). Laurite and Ir-osmium from plagioclase lherzolite of the Yoko–Dovyren mafic–ultramafic pluton, Northern Baikal Region. Geology of Ore Deposits, 60(3), 210-219.
β“˜ Orthocuproplatinum
Formula: Pt3Cu
Reference: Spiridonov, E. M. (2020, September). Metamorphogenic–Hydrothermal Nielsenite, PdCu 3, in Sulfide-Bearing Anorthosites of the Yoko-Dovyren Intrusive in Baikalides of the Northern Baikal Region. In Doklady Earth Sciences (Vol. 494, pp. 704-706). Pleiades Publishing.
β“˜ 'Orthopyroxene Subgroup'
Reference: Spiridonov, E. M., Ariskin, A. A., Kislov, E. V., Korotaeva, N. N., Nikolaev, G. S., Pshenitsyn, I. V., & Yapaskurt, V. O. (2018). Laurite and Ir-osmium from plagioclase lherzolite of the Yoko–Dovyren mafic–ultramafic pluton, Northern Baikal Region. Geology of Ore Deposits, 60(3), 210-219.
β“˜ Osarsite
Formula: (Os,Ru)AsS
Reference: Spiridonov, E. M., Ariskin, A. A., Kislov, E. V., Korotaeva, N. N., Nikolaev, G. S., Pshenitsyn, I. V., & Yapaskurt, V. O. (2018). Laurite and Ir-osmium from plagioclase lherzolite of the Yoko–Dovyren mafic–ultramafic pluton, Northern Baikal Region. Geology of Ore Deposits, 60(3), 210-219.
β“˜ Palladogermanide
Formula: Pd2Ge
Reference: Spiridonov, E. M., Orsoev, D. A., Ariskin, A. A., Kislov, E. V., Korotaeva, N. N., Nikolaev, G. S., & Yapaskurt, V. O. (2019). Germanium-Rich Palladium Minerals Palladogermanide Pd 2 Ge, Paolovite Pd 2 (Sn, Ge), and Zvyagintsevite in Sulfide-Bearing Anorthosites of the Yoko-Dovyren Pluton, Baikal Area. Geochemistry International, 57(5), 600-603.
β“˜ Paolovite
Formula: Pd2Sn
Reference: Rudashevskiy N.S., Krecer D.A., Orsoev D.A., Kislov E.V. (2003) Palladium-platinum mineralization in vein Cu-Ni-ores of Yoko-Dovyrenskiy laiered massif, - DAN, 391(4), p. 519-522 (in Rus.); Spiridonov, E. M., Orsoev, D. A., Ariskin, A. A., Kislov, E. V., Korotaeva, N. N., Nikolaev, G. S., & Yapaskurt, V. O. (2019). Germanium-Rich Palladium Minerals Palladogermanide Pd 2 Ge, Paolovite Pd 2 (Sn, Ge), and Zvyagintsevite in Sulfide-Bearing Anorthosites of the Yoko-Dovyren Pluton, Baikal Area. Geochemistry International, 57(5), 600-603. Spiridonov, E. M. (2020, September). Metamorphogenic–Hydrothermal Nielsenite, PdCu 3, in Sulfide-Bearing Anorthosites of the Yoko-Dovyren Intrusive in Baikalides of the Northern Baikal Region. In Doklady Earth Sciences (Vol. 494, pp. 704-706). Pleiades Publishing.
β“˜ Pargasite
Formula: NaCa2(Mg4Al)(Si6Al2)O22(OH)2
Reference: Spiridonov, E. M., Ariskin, A. A., Kislov, E. V., Korotaeva, N. N., Nikolaev, G. S., Pshenitsyn, I. V., & Yapaskurt, V. O. (2018). Laurite and Ir-osmium from plagioclase lherzolite of the Yoko–Dovyren mafic–ultramafic pluton, Northern Baikal Region. Geology of Ore Deposits, 60(3), 210-219.; Kislov, E.V.; Khudyakova, L.I. (2020) Yoko–Dovyren Layered Massif: Composition, Mineralization, Overburden and Dump Rock Utilization. Minerals 10, 682.
β“˜ Pectolite
Formula: NaCa2Si3O8(OH)
Reference: Spiridonov, E. M. (2020, September). Metamorphogenic–Hydrothermal Nielsenite, PdCu 3, in Sulfide-Bearing Anorthosites of the Yoko-Dovyren Intrusive in Baikalides of the Northern Baikal Region. In Doklady Earth Sciences (Vol. 494, pp. 704-706). Pleiades Publishing.
β“˜ Pentlandite
Formula: (NixFey)Ξ£9S8
Reference: Galuskin, Evgeny V. et al. (2007) Dovyrenite Ca6Zr[Si2O7]2(OH)4: Vol. 38(1) , 15-27.; Konnikov, E.G., Meurer, W.P., Neruchev, S.S., Prasolov, E.M., Kislov, E.V., and Orsoev, D.A. (2000): Mineralium Deposita 35, 526-532.; Rudashevskiy N.S., Krecer D.A., Orsoev D.A., Kislov E.V. (2003) Palladium-platinum mineralization in vein Cu-Ni-ores of Yoko-Dovyrenskiy laiered massif, - DAN, 391(4), p. 519-522 (in Rus.); Ariskin, A. A., Kislov, E. V., Danyushevsky, L. V., Nikolaev, G. S., Fiorentini, M. L., Gilbert, S., ... & Malyshev, A. (2016). Cu–Ni–PGE fertility of the Yoko-Dovyren layered massif (northern Transbaikalia, Russia): thermodynamic modeling of sulfide compositions in low mineralized dunite based on quantitative sulfide mineralogy. Mineralium Deposita, 51(8), 993-1011.; Spiridonov, E. M., Orsoev, D. A., Ariskin, A. A., Kislov, E. V., Korotaeva, N. N., Nikolaev, G. S., & Yapaskurt, V. O. (2019). Germanium-Rich Palladium Minerals Palladogermanide Pd 2 Ge, Paolovite Pd 2 (Sn, Ge), and Zvyagintsevite in Sulfide-Bearing Anorthosites of the Yoko-Dovyren Pluton, Baikal Area. Geochemistry International, 57(5), 600-603. Spiridonov, E. M. (2020, September). Metamorphogenic–Hydrothermal Nielsenite, PdCu 3, in Sulfide-Bearing Anorthosites of the Yoko-Dovyren Intrusive in Baikalides of the Northern Baikal Region. In Doklady Earth Sciences (Vol. 494, pp. 704-706). Pleiades Publishing.
β“˜ Perovskite
Formula: CaTiO3
Reference: Galuskin, Evgeny V. et al. (2007) Dovyrenite Ca6Zr[Si2O7]2(OH)4: Vol. 38(1) , 15-27.
β“˜ Phlogopite
Formula: KMg3(AlSi3O10)(OH)2
Reference: Konnikov, E.G., Meurer, W.P., Neruchev, S.S., Prasolov, E.M., Kislov, E.V., and Orsoev, D.A. (2000): Mineralium Deposita 35, 526-532.; Spiridonov, E. M., Orsoev, D. A., Ariskin, A. A., Kislov, E. V., Korotaeva, N. N., Nikolaev, G. S., & Yapaskurt, V. O. (2019). Germanium-Rich Palladium Minerals Palladogermanide Pd 2 Ge, Paolovite Pd 2 (Sn, Ge), and Zvyagintsevite in Sulfide-Bearing Anorthosites of the Yoko-Dovyren Pluton, Baikal Area. Geochemistry International, 57(5), 600-603.
β“˜ Phlogopite var. Titanium-bearing Phlogopite
Reference: Spiridonov, E. M., Orsoev, D. A., Ariskin, A. A., Kislov, E. V., Korotaeva, N. N., Nikolaev, G. S., & Yapaskurt, V. O. (2019, April). Palladogermanide PdGe 2 from Sulfidized Anorthosite of the Yoko-Dovyren Intrusion: First Finding in Russia. In Doklady Earth Sciences (Vol. 485, No. 2, pp. 458-460). Pleiades Publishing.
β“˜ Pigeonite
Formula: (CaxMgyFez)(Mgy1Fez1)Si2O6
Reference: Spiridonov, E. M., Orsoev, D. A., Ariskin, A. A., Kislov, E. V., Korotaeva, N. N., Nikolaev, G. S., & Yapaskurt, V. O. (2019). Germanium-Rich Palladium Minerals Palladogermanide Pd 2 Ge, Paolovite Pd 2 (Sn, Ge), and Zvyagintsevite in Sulfide-Bearing Anorthosites of the Yoko-Dovyren Pluton, Baikal Area. Geochemistry International, 57(5), 600-603.
β“˜ 'Plagioclase'
Formula: (Na,Ca)[(Si,Al)AlSi2]O8
Reference: Ariskin, A. A., Spiridonov, E. M., Nikolaev, G. S., Danyushevsky, L. V., Fiorentini, M. L., Kislov, E. V., & Pshenitsyn, I. V. (2017). Sulphide Controlled Fractionation of PGE at Post-cumulus Crystallization of Primitive Olivine Cumulate Piles from the Yoko-dovyren Layered Intrusion. In Magmatism of the Earth and related strategic metal deposits (pp. 12-14).; Spiridonov, E. M., Orsoev, D. A., Ariskin, A. A., Kislov, E. V., Korotaeva, N. N., Nikolaev, G. S., & Yapaskurt, V. O. (2019). Germanium-Rich Palladium Minerals Palladogermanide Pd 2 Ge, Paolovite Pd 2 (Sn, Ge), and Zvyagintsevite in Sulfide-Bearing Anorthosites of the Yoko-Dovyren Pluton, Baikal Area. Geochemistry International, 57(5), 600-603.
β“˜ Platarsite
Formula: PtAsS
Reference: Spiridonov, E. M., Ariskin, A. A., Kislov, E. V., Korotaeva, N. N., Nikolaev, G. S., Pshenitsyn, I. V., & Yapaskurt, V. O. (2018). Laurite and Ir-osmium from plagioclase lherzolite of the Yoko–Dovyren mafic–ultramafic pluton, Northern Baikal Region. Geology of Ore Deposits, 60(3), 210-219.
β“˜ Platinum
Formula: Pt
Reference: Ariskin, A. A., Spiridonov, E. M., Nikolaev, G. S., Danyushevsky, L. V., Fiorentini, M. L., Kislov, E. V., & Pshenitsyn, I. V. (2017). Sulphide Controlled Fractionation of PGE at Post-cumulus Crystallization of Primitive Olivine Cumulate Piles from the Yoko-dovyren Layered Intrusion. In Magmatism of the Earth and related strategic metal deposits (pp. 12-14).
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Plombièrite

Yoko-Dovyrensky Massif, Dovyren Highlands, Severo-Baykalsky District, Buryatia, Russia
β“˜ PlombiΓ¨rite
Formula: [Ca4Si6O16(OH)2 · 2H2O] · (Ca · 5H2O)
Reference: Sergey Vasiliev
β“˜ Potarite
Formula: PdHg
Reference: Rudashevskiy N.S., Krecer D.A., Orsoev D.A., Kislov E.V. (2003) Palladium-platinum mineralization in vein Cu-Ni-ores of Yoko-Dovyrenskiy laiered massif, - DAN, 391(4), p. 519-522 (in Rus.); Spiridonov, E. M., Orsoev, D. A., Ariskin, A. A., Kislov, E. V., Korotaeva, N. N., Nikolaev, G. S., & Yapaskurt, V. O. (2019). Germanium-Rich Palladium Minerals Palladogermanide Pd 2 Ge, Paolovite Pd 2 (Sn, Ge), and Zvyagintsevite in Sulfide-Bearing Anorthosites of the Yoko-Dovyren Pluton, Baikal Area. Geochemistry International, 57(5), 600-603.
β“˜ Prehnite
Formula: Ca2Al2Si3O10(OH)2
Reference: Spiridonov, E. M. (2020, September). Metamorphogenic–Hydrothermal Nielsenite, PdCu 3, in Sulfide-Bearing Anorthosites of the Yoko-Dovyren Intrusive in Baikalides of the Northern Baikal Region. In Doklady Earth Sciences (Vol. 494, pp. 704-706). Pleiades Publishing.
β“˜ Pseudomertieite
Formula: Pd11(Sb,As)4
Reference: Ariskin, A. A., Kislov, E. V., Danyushevsky, L. V., Nikolaev, G. S., Fiorentini, M. L., Gilbert, S., ... & Malyshev, A. (2016). Cu–Ni–PGE fertility of the Yoko-Dovyren layered massif (northern Transbaikalia, Russia): thermodynamic modeling of sulfide compositions in low mineralized dunite based on quantitative sulfide mineralogy. Mineralium Deposita, 51(8), 993-1011.
β“˜ Pyrite
Formula: FeS2
Reference: Ariskin, A. A., Kislov, E. V., Danyushevsky, L. V., Nikolaev, G. S., Fiorentini, M. L., Gilbert, S., ... & Malyshev, A. (2016). Cu–Ni–PGE fertility of the Yoko-Dovyren layered massif (northern Transbaikalia, Russia): thermodynamic modeling of sulfide compositions in low mineralized dunite based on quantitative sulfide mineralogy. Mineralium Deposita, 51(8), 993-1011.; Spiridonov, E. M., Orsoev, D. A., Ariskin, A. A., Kislov, E. V., Korotaeva, N. N., Nikolaev, G. S., & Yapaskurt, V. O. (2019). Germanium-Rich Palladium Minerals Palladogermanide Pd 2 Ge, Paolovite Pd 2 (Sn, Ge), and Zvyagintsevite in Sulfide-Bearing Anorthosites of the Yoko-Dovyren Pluton, Baikal Area. Geochemistry International, 57(5), 600-603.; Kislov, E.V.; Khudyakova, L.I. (2020) Yoko–Dovyren Layered Massif: Composition, Mineralization, Overburden and Dump Rock Utilization. Minerals 10, 682.
β“˜ 'Pyrochlore Group'
Formula: A2Nb2(O,OH)6Z
Reference: Spiridonov, E. M., Ariskin, A. A., Kislov, E. V., Korotaeva, N. N., Nikolaev, G. S., Pshenitsyn, I. V., & Yapaskurt, V. O. (2018). Laurite and Ir-osmium from plagioclase lherzolite of the Yoko–Dovyren mafic–ultramafic pluton, Northern Baikal Region. Geology of Ore Deposits, 60(3), 210-219.
β“˜ 'Pyroxene Group'
Formula: ADSi2O6
Reference: Spiridonov, E. M., Ariskin, A. A., Kislov, E. V., Korotaeva, N. N., Nikolaev, G. S., Pshenitsyn, I. V., & Yapaskurt, V. O. (2018). Laurite and Ir-osmium from plagioclase lherzolite of the Yoko–Dovyren mafic–ultramafic pluton, Northern Baikal Region. Geology of Ore Deposits, 60(3), 210-219.
β“˜ Pyrrhotite
Formula: Fe1-xS
Reference: Galuskin, Evgeny V. et al. (2007) Dovyrenite Ca6Zr[Si2O7]2(OH)4: Vol. 38(1) , 15-27.; Konnikov, E.G., Meurer, W.P., Neruchev, S.S., Prasolov, E.M., Kislov, E.V., and Orsoev, D.A. (2000): Mineralium Deposita 35, 526-532.; Ariskin, A. A., Kislov, E. V., Danyushevsky, L. V., Nikolaev, G. S., Fiorentini, M. L., Gilbert, S., ... & Malyshev, A. (2016). Cu–Ni–PGE fertility of the Yoko-Dovyren layered massif (northern Transbaikalia, Russia): thermodynamic modeling of sulfide compositions in low mineralized dunite based on quantitative sulfide mineralogy. Mineralium Deposita, 51(8), 993-1011.; Spiridonov, E. M., Orsoev, D. A., Ariskin, A. A., Kislov, E. V., Korotaeva, N. N., Nikolaev, G. S., & Yapaskurt, V. O. (2019). Germanium-Rich Palladium Minerals Palladogermanide Pd 2 Ge, Paolovite Pd 2 (Sn, Ge), and Zvyagintsevite in Sulfide-Bearing Anorthosites of the Yoko-Dovyren Pluton, Baikal Area. Geochemistry International, 57(5), 600-603.; Kislov, E.V.; Khudyakova, L.I. (2020) Yoko–Dovyren Layered Massif: Composition, Mineralization, Overburden and Dump Rock Utilization. Minerals 10, 682. Spiridonov, E. M. (2020, September). Metamorphogenic–Hydrothermal Nielsenite, PdCu 3, in Sulfide-Bearing Anorthosites of the Yoko-Dovyren Intrusive in Baikalides of the Northern Baikal Region. In Doklady Earth Sciences (Vol. 494, pp. 704-706). Pleiades Publishing.
β“˜ Quartz
Formula: SiO2
Reference: Kislov, E.V.; Khudyakova, L.I. (2020) Yoko–Dovyren Layered Massif: Composition, Mineralization, Overburden and Dump Rock Utilization. Minerals 10, 682.
β“˜ Rammelsbergite
Formula: NiAs2
Reference: Galuskin, E. V. et al. (2007): Dovyrenite Ca6Zr[Si2O7]2(OH)4 – A New Mineral From Skarned Carbonate Xenoliths In Basic-Ultrabasic Rocks Of The Ioko-Dovyren Massif, Northern Baikal Region, Russia. Mineralogia Polonica, 38, 15-27
β“˜ Rankinite
Formula: Ca3Si2O7
Reference: Simakin, A.G., Kislov, E.V., Salova, T.P., Shaposhnikova, O.Y., & Nekrasov, A.N. (2019). Reduced CO2 Fluid as an Agent of Ore-Forming Processes: A Case Study of Dolomite-Replacement Skarns at the Yoko-Dovyren Massif. Petrology, 27, 1-16.
β“˜ Rustenburgite
Formula: (Pt,Pd)3Sn
Reference: Konnikov, E.G., Meurer, W.P., Neruchev, S.S., Prasolov, E.M., Kislov, E.V., and Orsoev, D.A. (2000): Mineralium Deposita 35, 526-532.; Rudashevskiy N.S., Krecer D.A., Orsoev D.A., Kislov E.V. (2003) Palladium-platinum mineralization in vein Cu-Ni-ores of Yoko-Dovyrenskiy laiered massif, - DAN, 391(4), p. 519-522 (in Rus.)
β“˜ Safflorite
Formula: (Co,Ni,Fe)As2
Reference: Galuskin, E. V. et al. (2007): Dovyrenite Ca6Zr[Si2O7]2(OH)4 – A New Mineral From Skarned Carbonate Xenoliths In Basic-Ultrabasic Rocks Of The Ioko-Dovyren Massif, Northern Baikal Region, Russia. Mineralogia Polonica, 38, 15-27
β“˜ 'Serpentine Subgroup'
Formula: D3[Si2O5](OH)4
Reference: Spiridonov, E. M., Ariskin, A. A., Kislov, E. V., Korotaeva, N. N., Nikolaev, G. S., Pshenitsyn, I. V., & Yapaskurt, V. O. (2018). Laurite and Ir-osmium from plagioclase lherzolite of the Yoko–Dovyren mafic–ultramafic pluton, Northern Baikal Region. Geology of Ore Deposits, 60(3), 210-219.; Kislov, E.V.; Khudyakova, L.I. (2020) Yoko–Dovyren Layered Massif: Composition, Mineralization, Overburden and Dump Rock Utilization. Minerals 10, 682.
β“˜ Siderite
Formula: FeCO3
Reference: Kislov, E.V.; Khudyakova, L.I. (2020) Yoko–Dovyren Layered Massif: Composition, Mineralization, Overburden and Dump Rock Utilization. Minerals 10, 682.
β“˜ Siderite var. Mg-rich Siderite
Formula: (Fe,Mg)CO3
Reference: Kislov, E.V.; Khudyakova, L.I. (2020) Yoko–Dovyren Layered Massif: Composition, Mineralization, Overburden and Dump Rock Utilization. Minerals 10, 682.
β“˜ Silver
Formula: Ag
Reference: Rudashevskiy N.S., Krecer D.A., Orsoev D.A., Kislov E.V. (2003) Palladium-platinum mineralization in vein Cu-Ni-ores of Yoko-Dovyrenskiy laiered massif, - DAN, 391(4), p. 519-522 (in Rus.); Spiridonov, E. M., Orsoev, D. A., Ariskin, A. A., Kislov, E. V., Korotaeva, N. N., Nikolaev, G. S., & Yapaskurt, V. O. (2019). Germanium-Rich Palladium Minerals Palladogermanide Pd 2 Ge, Paolovite Pd 2 (Sn, Ge), and Zvyagintsevite in Sulfide-Bearing Anorthosites of the Yoko-Dovyren Pluton, Baikal Area. Geochemistry International, 57(5), 600-603.
β“˜ Silver var. KΓΌstelite
Formula: Ag
Reference: Rudashevskiy N.S., Krecer D.A., Orsoev D.A., Kislov E.V. (2003) Palladium-platinum mineralization in vein Cu-Ni-ores of Yoko-Dovyrenskiy laiered massif, - DAN, 391(4), p. 519-522 (in Rus.)
β“˜ Silver var. Native Amalgam
Formula: (Ag,Hg)
Reference: Spiridonov, E. M., Orsoev, D. A., Ariskin, A. A., Kislov, E. V., Korotaeva, N. N., Nikolaev, G. S., & Yapaskurt, V. O. (2019). Germanium-Rich Palladium Minerals Palladogermanide Pd 2 Ge, Paolovite Pd 2 (Sn, Ge), and Zvyagintsevite in Sulfide-Bearing Anorthosites of the Yoko-Dovyren Pluton, Baikal Area. Geochemistry International, 57(5), 600-603.
β“˜ Sobolevskite
Formula: PdBi
Reference: Spiridonov, E. M., Orsoev, D. A., Ariskin, A. A., Kislov, E. V., Korotaeva, N. N., Nikolaev, G. S., & Yapaskurt, V. O. (2019, April). Palladogermanide PdGe 2 from Sulfidized Anorthosite of the Yoko-Dovyren Intrusion: First Finding in Russia. In Doklady Earth Sciences (Vol. 485, No. 2, pp. 458-460). Pleiades Publishing.
β“˜ Sperrylite
Formula: PtAs2
Reference: Rudashevskiy N.S., Krecer D.A., Orsoev D.A., Kislov E.V. (2003) Palladium-platinum mineralization in vein Cu-Ni-ores of Yoko-Dovyrenskiy laiered massif, - DAN, 391(4), p. 519-522 (in Rus.); Ariskin, A. A., Spiridonov, E. M., Nikolaev, G. S., Danyushevsky, L. V., Fiorentini, M. L., Kislov, E. V., & Pshenitsyn, I. V. (2017). Sulphide Controlled Fractionation of PGE at Post-cumulus Crystallization of Primitive Olivine Cumulate Piles from the Yoko-dovyren Layered Intrusion. In Magmatism of the Earth and related strategic metal deposits (pp. 12-14).; Ariskin, A. A., Kislov, E. V., Danyushevsky, L. V., Nikolaev, G. S., Fiorentini, M. L., Gilbert, S., ... & Malyshev, A. (2016). Cu–Ni–PGE fertility of the Yoko-Dovyren layered massif (northern Transbaikalia, Russia): thermodynamic modeling of sulfide compositions in low mineralized dunite based on quantitative sulfide mineralogy. Mineralium Deposita, 51(8), 993-1011.; Spiridonov, E. M., Orsoev, D. A., Ariskin, A. A., Kislov, E. V., Korotaeva, N. N., Nikolaev, G. S., & Yapaskurt, V. O. (2019). Germanium-Rich Palladium Minerals Palladogermanide Pd 2 Ge, Paolovite Pd 2 (Sn, Ge), and Zvyagintsevite in Sulfide-Bearing Anorthosites of the Yoko-Dovyren Pluton, Baikal Area. Geochemistry International, 57(5), 600-603. Spiridonov, E. M. (2020, September). Metamorphogenic–Hydrothermal Nielsenite, PdCu 3, in Sulfide-Bearing Anorthosites of the Yoko-Dovyren Intrusive in Baikalides of the Northern Baikal Region. In Doklady Earth Sciences (Vol. 494, pp. 704-706). Pleiades Publishing.
β“˜ Sphalerite
Formula: ZnS
Reference: Galuskin, Evgeny V. et al. (2007) Dovyrenite Ca6Zr[Si2O7]2(OH)4: Vol. 38(1) , 15-27.; Ariskin, A. A., Kislov, E. V., Danyushevsky, L. V., Nikolaev, G. S., Fiorentini, M. L., Gilbert, S., ... & Malyshev, A. (2016). Cu–Ni–PGE fertility of the Yoko-Dovyren layered massif (northern Transbaikalia, Russia): thermodynamic modeling of sulfide compositions in low mineralized dunite based on quantitative sulfide mineralogy. Mineralium Deposita, 51(8), 993-1011.; Spiridonov, E. M., Orsoev, D. A., Ariskin, A. A., Kislov, E. V., Korotaeva, N. N., Nikolaev, G. S., & Yapaskurt, V. O. (2019). Germanium-Rich Palladium Minerals Palladogermanide Pd 2 Ge, Paolovite Pd 2 (Sn, Ge), and Zvyagintsevite in Sulfide-Bearing Anorthosites of the Yoko-Dovyren Pluton, Baikal Area. Geochemistry International, 57(5), 600-603.; Kislov, E.V.; Khudyakova, L.I. (2020) Yoko–Dovyren Layered Massif: Composition, Mineralization, Overburden and Dump Rock Utilization. Minerals 10, 682.
β“˜ Spinel
Formula: MgAl2O4
Reference: American Mineralogist, Volume 94, pages 323–333, 2009; Konnikov, E.G., Meurer, W.P., Neruchev, S.S., Prasolov, E.M., Kislov, E.V., and Orsoev, D.A. (2000): Mineralium Deposita 35, 526-532.
β“˜ Stannopalladinite
Formula: (Pd,Cu)3Sn2
Reference: Kislov, E.V.; Khudyakova, L.I. (2020) Yoko–Dovyren Layered Massif: Composition, Mineralization, Overburden and Dump Rock Utilization. Minerals 10, 682.
β“˜ Sudburyite
Formula: PdSb
Reference: Rudashevskiy N.S., Krecer D.A., Orsoev D.A., Kislov E.V. (2003) Palladium-platinum mineralization in vein Cu-Ni-ores of Yoko-Dovyrenskiy laiered massif, - DAN, 391(4), p. 519-522 (in Rus.)
β“˜ Taimyrite
Formula: (Pd,Cu,Pt)3Sn
Reference: Rudashevskiy N.S., Krecer D.A., Orsoev D.A., Kislov E.V. (2003) Palladium-platinum mineralization in vein Cu-Ni-ores of Yoko-Dovyrenskiy laiered massif, - DAN, 391(4), p. 519-522 (in Rus.)
β“˜ Talnakhite
Formula: Cu9(Fe,Ni)8S16
Reference: Konnikov, E.G., Meurer, W.P., Neruchev, S.S., Prasolov, E.M., Kislov, E.V., and Orsoev, D.A. (2000): Mineralium Deposita 35, 526-532.; Spiridonov, E. M., Orsoev, D. A., Ariskin, A. A., Kislov, E. V., Korotaeva, N. N., Nikolaev, G. S., & Yapaskurt, V. O. (2019). Germanium-Rich Palladium Minerals Palladogermanide Pd 2 Ge, Paolovite Pd 2 (Sn, Ge), and Zvyagintsevite in Sulfide-Bearing Anorthosites of the Yoko-Dovyren Pluton, Baikal Area. Geochemistry International, 57(5), 600-603.
β“˜ Tazheranite
Formula: (Zr,Ti,Ca)(O,◻)2
Reference: Galuskin, Evgeny V. et al. (2007) Dovyrenite Ca6Zr[Si2O7]2(OH)4: Vol. 38(1) , 15-27.
β“˜ Telargpalite
Formula: (Pd,Ag)3(Te,Bi)
Reference: Spiridonov, E. M., Orsoev, D. A., Ariskin, A. A., Kislov, E. V., Korotaeva, N. N., Nikolaev, G. S., & Yapaskurt, V. O. (2019). Germanium-Rich Palladium Minerals Palladogermanide Pd 2 Ge, Paolovite Pd 2 (Sn, Ge), and Zvyagintsevite in Sulfide-Bearing Anorthosites of the Yoko-Dovyren Pluton, Baikal Area. Geochemistry International, 57(5), 600-603. Spiridonov, E. M. (2020, September). Metamorphogenic–Hydrothermal Nielsenite, PdCu 3, in Sulfide-Bearing Anorthosites of the Yoko-Dovyren Intrusive in Baikalides of the Northern Baikal Region. In Doklady Earth Sciences (Vol. 494, pp. 704-706). Pleiades Publishing.
β“˜ Tetra-auricupride
Formula: AuCu
Reference: Rudashevskiy N.S., Krecer D.A., Orsoev D.A., Kislov E.V. (2003) Palladium-platinum mineralization in vein Cu-Ni-ores of Yoko-Dovyrenskiy laiered massif, - DAN, 391(4), p. 519-522 (in Rus.)
β“˜ Tetraferroplatinum
Formula: PtFe
Reference: Konnikov, E.G., Meurer, W.P., Neruchev, S.S., Prasolov, E.M., Kislov, E.V., and Orsoev, D.A. (2000): Mineralium Deposita 35, 526-532.; Rudashevskiy N.S., Krecer D.A., Orsoev D.A., Kislov E.V. (2003) Palladium-platinum mineralization in vein Cu-Ni-ores of Yoko-Dovyrenskiy laiered massif, - DAN, 391(4), p. 519-522 (in Rus.); Spiridonov, E. M., Orsoev, D. A., Ariskin, A. A., Kislov, E. V., Korotaeva, N. N., Nikolaev, G. S., & Yapaskurt, V. O. (2019). Germanium-Rich Palladium Minerals Palladogermanide Pd 2 Ge, Paolovite Pd 2 (Sn, Ge), and Zvyagintsevite in Sulfide-Bearing Anorthosites of the Yoko-Dovyren Pluton, Baikal Area. Geochemistry International, 57(5), 600-603.
β“˜ Thorianite
Formula: ThO2
Reference: Spiridonov, E. M., Ariskin, A. A., Kislov, E. V., Korotaeva, N. N., Nikolaev, G. S., Pshenitsyn, I. V., & Yapaskurt, V. O. (2018). Laurite and Ir-osmium from plagioclase lherzolite of the Yoko–Dovyren mafic–ultramafic pluton, Northern Baikal Region. Geology of Ore Deposits, 60(3), 210-219.
β“˜ Thorite
Formula: Th(SiO4)
Reference: Spiridonov, E. M., Ariskin, A. A., Kislov, E. V., Korotaeva, N. N., Nikolaev, G. S., Pshenitsyn, I. V., & Yapaskurt, V. O. (2018). Laurite and Ir-osmium from plagioclase lherzolite of the Yoko–Dovyren mafic–ultramafic pluton, Northern Baikal Region. Geology of Ore Deposits, 60(3), 210-219.
β“˜ Troilite
Formula: FeS
Reference: Konnikov, E.G., Meurer, W.P., Neruchev, S.S., Prasolov, E.M., Kislov, E.V., and Orsoev, D.A. (2000): Mineralium Deposita 35, 526-532.; Ariskin, A. A., Kislov, E. V., Danyushevsky, L. V., Nikolaev, G. S., Fiorentini, M. L., Gilbert, S., ... & Malyshev, A. (2016). Cu–Ni–PGE fertility of the Yoko-Dovyren layered massif (northern Transbaikalia, Russia): thermodynamic modeling of sulfide compositions in low mineralized dunite based on quantitative sulfide mineralogy. Mineralium Deposita, 51(8), 993-1011.; Spiridonov, E. M., Orsoev, D. A., Ariskin, A. A., Kislov, E. V., Korotaeva, N. N., Nikolaev, G. S., & Yapaskurt, V. O. (2019). Germanium-Rich Palladium Minerals Palladogermanide Pd 2 Ge, Paolovite Pd 2 (Sn, Ge), and Zvyagintsevite in Sulfide-Bearing Anorthosites of the Yoko-Dovyren Pluton, Baikal Area. Geochemistry International, 57(5), 600-603.; Kislov, E.V.; Khudyakova, L.I. (2020) Yoko–Dovyren Layered Massif: Composition, Mineralization, Overburden and Dump Rock Utilization. Minerals 10, 682.
β“˜ Tulameenite
Formula: Pt2CuFe
Reference: Konnikov, E.G., Meurer, W.P., Neruchev, S.S., Prasolov, E.M., Kislov, E.V., and Orsoev, D.A. (2000): Mineralium Deposita 35, 526-532.; Rudashevskiy N.S., Krecer D.A., Orsoev D.A., Kislov E.V. (2003) Palladium-platinum mineralization in vein Cu-Ni-ores of Yoko-Dovyrenskiy laiered massif, - DAN, 391(4), p. 519-522 (in Rus.) Spiridonov, E. M. (2020, September). Metamorphogenic–Hydrothermal Nielsenite, PdCu 3, in Sulfide-Bearing Anorthosites of the Yoko-Dovyren Intrusive in Baikalides of the Northern Baikal Region. In Doklady Earth Sciences (Vol. 494, pp. 704-706). Pleiades Publishing.
β“˜ 'UM2005-32-SiOCO:CaH'
Formula: Ca4(Si2O6)(CO3)(OH)2
Reference: American Mineralogist, Volume 94, pages 323–333, 2009
β“˜ Vesuvianite
Formula: Ca19Fe3+Al4(Al6Mg2)(◻4)◻[Si2O7]4[(SiO4)10]O(OH)9
Reference: Galuskin, Evgeny V. et al. (2007) Dovyrenite Ca6Zr[Si2O7]2(OH)4: Vol. 38(1) , 15-27.
β“˜ Violarite
Formula: Fe2+Ni3+2S4
Reference: Rudashevskiy N.S., Krecer D.A., Orsoev D.A., Kislov E.V. (2003) Palladium-platinum mineralization in vein Cu-Ni-ores of Yoko-Dovyrenskiy laiered massif, - DAN, 391(4), p. 519-522 (in Rus.) Spiridonov, E. M. (2020, September). Metamorphogenic–Hydrothermal Nielsenite, PdCu 3, in Sulfide-Bearing Anorthosites of the Yoko-Dovyren Intrusive in Baikalides of the Northern Baikal Region. In Doklady Earth Sciences (Vol. 494, pp. 704-706). Pleiades Publishing.
β“˜ Wollastonite
Formula: Ca3(Si3O9)
Reference: Kislov, E.V.; Khudyakova, L.I. (2020) Yoko–Dovyren Layered Massif: Composition, Mineralization, Overburden and Dump Rock Utilization. Minerals 10, 682.
β“˜ Zircon
Formula: Zr(SiO4)
Reference: Spiridonov, E. M., Ariskin, A. A., Kislov, E. V., Korotaeva, N. N., Nikolaev, G. S., Pshenitsyn, I. V., & Yapaskurt, V. O. (2018). Laurite and Ir-osmium from plagioclase lherzolite of the Yoko–Dovyren mafic–ultramafic pluton, Northern Baikal Region. Geology of Ore Deposits, 60(3), 210-219.
β“˜ Zirconolite
Formula: CaZrTi2O7
Reference: Spiridonov, E. M., Ariskin, A. A., Kislov, E. V., Korotaeva, N. N., Nikolaev, G. S., Pshenitsyn, I. V., & Yapaskurt, V. O. (2018). Laurite and Ir-osmium from plagioclase lherzolite of the Yoko–Dovyren mafic–ultramafic pluton, Northern Baikal Region. Geology of Ore Deposits, 60(3), 210-219.
β“˜ Zvyagintsevite
Formula: Pd3Pb
Reference: Konnikov, E.G., Meurer, W.P., Neruchev, S.S., Prasolov, E.M., Kislov, E.V., and Orsoev, D.A. (2000): Mineralium Deposita 35, 526-532.; Rudashevskiy N.S., Krecer D.A., Orsoev D.A., Kislov E.V. (2003) Palladium-platinum mineralization in vein Cu-Ni-ores of Yoko-Dovyrenskiy laiered massif, - DAN, 391(4), p. 519-522 (in Rus.); Spiridonov, E. M., Orsoev, D. A., Ariskin, A. A., Kislov, E. V., Korotaeva, N. N., Nikolaev, G. S., & Yapaskurt, V. O. (2019). Germanium-Rich Palladium Minerals Palladogermanide Pd 2 Ge, Paolovite Pd 2 (Sn, Ge), and Zvyagintsevite in Sulfide-Bearing Anorthosites of the Yoko-Dovyren Pluton, Baikal Area. Geochemistry International, 57(5), 600-603. Spiridonov, E. M. (2020, September). Metamorphogenic–Hydrothermal Nielsenite, PdCu 3, in Sulfide-Bearing Anorthosites of the Yoko-Dovyren Intrusive in Baikalides of the Northern Baikal Region. In Doklady Earth Sciences (Vol. 494, pp. 704-706). Pleiades Publishing.

List of minerals arranged by Strunz 10th Edition classification

Group 1 - Elements
β“˜Atokite1.AG.10(Pd,Pt)3Sn
β“˜Bismuth1.CA.05Bi
β“˜Copper1.AA.05Cu
β“˜Gold1.AA.05Au
β“˜var. Electrum1.AA.05(Au,Ag)
β“˜Isoferroplatinum1.AG.35Pt3Fe
β“˜Nielsenite1.AG.70PdCu3
β“˜Niggliite1.AG.60PtSn
β“˜Orthocuproplatinum1.AH.Pt3Cu
β“˜Palladogermanide1.B0.10Pd2Ge
β“˜Paolovite1.AG.20Pd2Sn
β“˜Platinum1.AF.10Pt
β“˜Potarite1.AD.25PdHg
β“˜Rustenburgite1.AG.10(Pt,Pd)3Sn
β“˜Silver1.AA.05Ag
β“˜var. KΓΌstelite1.AA.05Ag
β“˜var. Native Amalgam1.AA.05(Ag,Hg)
β“˜Stannopalladinite1.AG.25(Pd,Cu)3Sn2
β“˜Taimyrite1.AG.15(Pd,Cu,Pt)3Sn
β“˜Tetra-auricupride1.AA.10bAuCu
β“˜Tetraferroplatinum1.AG.40PtFe
β“˜Tulameenite1.AG.40Pt2CuFe
β“˜Zvyagintsevite1.AG.10Pd3Pb
Group 2 - Sulphides and Sulfosalts
β“˜Altaite2.CD.10PbTe
β“˜Atheneite2.AC.05aPd2As0.75Hg0.25
β“˜Bornite2.BA.15Cu5FeS4
β“˜Chalcocite2.BA.05Cu2S
β“˜Chalcopyrite2.CB.10aCuFeS2
β“˜Clausthalite2.CD.10PbSe
β“˜Cobaltite2.EB.25CoAsS
β“˜Cobaltpentlandite2.BB.15Co9S8
β“˜Colusite2.CB.30Cu13VAs3S16
β“˜Cubanite2.CB.55aCuFe2S3
β“˜Diaphorite2.JB.05Ag3Pb2Sb3S8
β“˜Digenite2.BA.10Cu9S5
β“˜Djerfisherite2.FC.05K6(Fe,Cu,Ni)25S26Cl
β“˜Froodite2.AC.45aΞ±-PdBi2
β“˜Galena2.CD.10PbS
β“˜var. Selenium-bearing Galena2.CD.10Pb(S,Se)
β“˜Germanite2.CB.30Cu13Fe2Ge2S16
β“˜Germanocolusite2.CB.30Cu26V2(Ge,As)6S32
β“˜Geversite2.EB.05aPtSb2
β“˜Godlevskite2.BB.15(Ni,Fe)9S8
β“˜Heazlewoodite2.BB.05Ni3S2
β“˜Hessite2.BA.60Ag2Te
β“˜Insizwaite2.EB.05aPt(Bi,Sb)2
β“˜Irarsite2.EB.25(Ir,Ru,Rh,Pt)AsS
β“˜Kotulskite2.CC.05Pd(Te,Bi)2-x (x β‰ˆ 0.4)
β“˜Laitakarite2.DC.05Bi4Se2S
β“˜Laurite2.EB.05aRuS2
β“˜Mackinawite2.CC.25(Fe,Ni)9S8
β“˜Majakite2.AC.25ePdNiAs
β“˜Maslovite2.EB.25PtBiTe
β“˜Maucherite2.AB.15Ni11As8
β“˜Mertieite2.AC.10bPd8Sb2.5As0.5
β“˜Michenerite2.EB.25PdBiTe
β“˜Molybdenite2.EA.30MoS2
β“˜Moncheite2.EA.20Pt(Te,Bi)2
β“˜Naldrettite2.AC.25dPd2Sb
β“˜Nickeline2.CC.05NiAs
β“˜Nickelskutterudite2.EC.05(Ni,Co,Fe)As3
β“˜Osarsite2.EB.20(Os,Ru)AsS
β“˜Pentlandite2.BB.15(NixFey)Ξ£9S8
β“˜Platarsite2.EB.25PtAsS
β“˜Pseudomertieite2.AC.15bPd11(Sb,As)4
β“˜Pyrite2.EB.05aFeS2
β“˜Pyrrhotite2.CC.10Fe1-xS
β“˜Rammelsbergite2.EB.15aNiAs2
β“˜Safflorite2.EB.15a(Co,Ni,Fe)As2
β“˜Sobolevskite2.CC.05PdBi
β“˜Sperrylite2.EB.05aPtAs2
β“˜Sphalerite2.CB.05aZnS
β“˜Sudburyite2.CC.05PdSb
β“˜Talnakhite2.CB.10bCu9(Fe,Ni)8S16
β“˜Telargpalite2.BC.45(Pd,Ag)3(Te,Bi)
β“˜Troilite2.CC.10FeS
β“˜Violarite2.DA.05Fe2+Ni3+2S4
Group 3 - Halides
β“˜Halite3.AA.20NaCl
Group 4 - Oxides and Hydroxides
β“˜Baddeleyite4.DE.35ZrO2
β“˜Brucite4.FE.05Mg(OH)2
β“˜Calzirtite4.DL.10Ca2Zr5Ti2O16
β“˜Chromite4.BB.05Fe2+Cr3+2O4
β“˜var. Aluminian Chromite4.BB.05Fe(Cr,Al)2O4
β“˜Cuprite4.AA.10Cu2O
β“˜Goethite4.00.Ξ±-Fe3+O(OH)
β“˜Hercynite4.BB.05Fe2+Al2O4
β“˜var. Picotite4.BB.05(Fe,Mg)(Al,Cr)2O4
β“˜Ilmenite4.CB.05Fe2+TiO3
β“˜Magnetite4.BB.05Fe2+Fe3+2O4
β“˜var. Titanium-bearing Magnetite4.BB.05Fe2+(Fe3+,Ti)2O4
β“˜Perovskite4.CC.30CaTiO3
β“˜'Pyrochlore Group'4.00.A2Nb2(O,OH)6Z
β“˜Quartz4.DA.05SiO2
β“˜Spinel4.BB.05MgAl2O4
β“˜Tazheranite4.DL.10(Zr,Ti,Ca)(O,β—»)2
β“˜Thorianite4.DL.05ThO2
β“˜Zirconolite4.DH.30CaZrTi2O7
Group 5 - Nitrates and Carbonates
β“˜Calcite5.AB.05CaCO3
β“˜Dolomite5.AB.10CaMg(CO3)2
β“˜Siderite5.AB.05FeCO3
β“˜var. Mg-rich Siderite5.AB.05(Fe,Mg)CO3
Group 8 - Phosphates, Arsenates and Vanadates
β“˜Chlorapatite8.BN.05Ca5(PO4)3Cl
β“˜Fluorapatite8.BN.05Ca5(PO4)3F
β“˜Hydroxylapatite8.BN.05Ca5(PO4)3(OH)
Group 9 - Silicates
β“˜Actinolite9.DE.10β—»Ca2(Mg4.5-2.5Fe0.5-2.5)Si8O22(OH)2
β“˜Afwillite9.AG.75Ca3(HSiO4)2 Β· 2H2O
β“˜Anorthite9.FA.35Ca(Al2Si2O8)
β“˜var. Bytownite9.FA.35(Ca,Na)[Al(Al,Si)Si2O8]
β“˜Antigorite9.ED.15Mg3(Si2O5)(OH)4
β“˜Augite9.DA.15(CaxMgyFez)(Mgy1Fez1)Si2O6
β“˜var. Fassaite9.DA.15(Ca,Na)(Mg,Fe2+,Al,Fe3+,Ti)[(Si,Al)2O6]
β“˜Baghdadite9.BE.17Ca6Zr2(Si2O7)2O4
β“˜Chrysotile9..Mg3(Si2O5)(OH)4
β“˜Clinozoisite9.BG.05a(CaCa)(AlAlAl)O[Si2O7][SiO4](OH)
β“˜Clintonite9.EC.35CaAlMg2(SiAl3O10)(OH)2
β“˜Cuspidine9.BE.17Ca8(Si2O7)2F4
β“˜Diopside9.DA.15CaMgSi2O6
β“˜var. Blue Diopside9.DA.15CaMgSi2O6
β“˜Dovyrenite (TL)9.BE.23Ca6Zr(Si2O7)2(OH)4
β“˜Edenite9.DE.15NaCa2Mg5(Si7Al)O22(OH)2
β“˜Enstatite9.DA.05Mg2Si2O6
β“˜var. Bronzite9.DA.05(Mg,Fe2+)2[SiO3]2
β“˜Ferro-edenite9.DE.15NaCa2Fe2+5(Si7Al)O22(OH)2
β“˜Forsterite9.AC.05Mg2SiO4
β“˜Foshagite9.DG.15Ca4(Si3O9)(OH)2
β“˜Grossular9.AD.25Ca3Al2(SiO4)3
β“˜var. Hydrogrossular9.AD.25Ca3Al2(SiO4)3
β“˜Hydroxylellestadite9.AH.25Ca5(SiO4)1.5(SO4)1.5(OH)
β“˜Lizardite9.ED.15Mg3(Si2O5)(OH)4
β“˜Merwinite9.AD.15Ca3Mg(SiO4)2
β“˜Monticellite9.AC.10CaMgSiO4
β“˜Nepheline9.FA.05Na3K(Al4Si4O16)
β“˜Pargasite9.DE.15NaCa2(Mg4Al)(Si6Al2)O22(OH)2
β“˜Pectolite9.DG.05NaCa2Si3O8(OH)
β“˜Phlogopite9.EC.20KMg3(AlSi3O10)(OH)2
β“˜var. Titanium-bearing Phlogopite9.EC.20KMg3(AlSi3O10)(OH)2
β“˜Pigeonite9.DA.10(CaxMgyFez)(Mgy1Fez1)Si2O6
β“˜PlombiΓ¨rite9.DG.08[Ca4Si6O16(OH)2 Β· 2H2O] Β· (Ca Β· 5H2O)
β“˜Prehnite9.DP.20Ca2Al2Si3O10(OH)2
β“˜Rankinite9.BC.15Ca3Si2O7
β“˜Thorite9.AD.30Th(SiO4)
β“˜Vesuvianite9.BG.35Ca19Fe3+Al4(Al6Mg2)(β—»4)β—»[Si2O7]4[(SiO4)10]O(OH)9
β“˜Wollastonite9.DG.05Ca3(Si3O9)
β“˜Zircon9.AD.30Zr(SiO4)
Unclassified Minerals, Rocks, etc.
β“˜'Amphibole Supergroup'-AB2C5((Si,Al,Ti)8O22)(OH,F,Cl,O)2
β“˜'Apatite'-Ca5(PO4)3(Cl/F/OH)
β“˜'Axinite Group'-
β“˜'Biotite'-K(Fe2+/Mg)2(Al/Fe3+/Mg/Ti)([Si/Al/Fe]2Si2O10)(OH/F)2 or Simplified: K(Mg,Fe)3AlSi3O10(OH)2
β“˜'Chlorite Group'-
β“˜'Chrome-Spinel (of Dana)'-
β“˜'Chrysolite'-
β“˜'Clinopyroxene Subgroup'-
β“˜'Endiopside'-
β“˜'Fayalite-Forsterite Series'-
β“˜'Garnet Group'-X3Z2(SiO4)3
β“˜'Hydrogarnet'-
β“˜'Limonite'-
β“˜'Melilite Group'-Ca2M(XSiO7)
β“˜'Monazite'-REE(PO4)
β“˜'Orthopyroxene Subgroup'-
β“˜'Plagioclase'-(Na,Ca)[(Si,Al)AlSi2]O8
β“˜'Pyroxene Group'-ADSi2O6
β“˜'Serpentine Subgroup'-D3[Si2O5](OH)4
β“˜'UM2005-32-SiOCO:CaH'-Ca4(Si2O6)(CO3)(OH)2

List of minerals for each chemical element

HHydrogen
Hβ“˜ DovyreniteCa6Zr(Si2O7)2(OH)4
Hβ“˜ PlombiΓ¨rite[Ca4Si6O16(OH)2 · 2H2O] · (Ca · 5H2O)
Hβ“˜ BruciteMg(OH)2
Hβ“˜ FoshagiteCa4(Si3O9)(OH)2
Hβ“˜ VesuvianiteCa19Fe3+Al4(Al6Mg2)(◻4)◻[Si2O7]4[(SiO4)10]O(OH)9
Hβ“˜ UM2005-32-SiOCO:CaHCa4(Si2O6)(CO3)(OH)2
Hβ“˜ AfwilliteCa3(HSiO4)2 · 2H2O
Hβ“˜ HydroxylellestaditeCa5(SiO4)1.5(SO4)1.5(OH)
Hβ“˜ HydroxylapatiteCa5(PO4)3(OH)
Hβ“˜ BiotiteK(Fe2+/Mg)2(Al/Fe3+/Mg/Ti)([Si/Al/Fe]2Si2O10)(OH/F)2 or Simplified: K(Mg,Fe)3AlSi3O10(OH)2
Hβ“˜ PhlogopiteKMg3(AlSi3O10)(OH)2
Hβ“˜ Actinolite◻Ca2(Mg4.5-2.5Fe0.5-2.5)Si8O22(OH)2
Hβ“˜ Amphibole SupergroupAB2C5((Si,Al,Ti)8O22)(OH,F,Cl,O)2
Hβ“˜ ApatiteCa5(PO4)3(Cl/F/OH)
Hβ“˜ ChrysotileMg3(Si2O5)(OH)4
Hβ“˜ EdeniteNaCa2Mg5(Si7Al)O22(OH)2
Hβ“˜ PargasiteNaCa2(Mg4Al)(Si6Al2)O22(OH)2
Hβ“˜ Pyrochlore GroupA2Nb2(O,OH)6Z
Hβ“˜ Serpentine SubgroupD3[Si2O5](OH)4
Hβ“˜ Ferro-edeniteNaCa2Fe52+(Si7Al)O22(OH)2
Hβ“˜ ClintoniteCaAlMg2(SiAl3O10)(OH)2
Hβ“˜ GoethiteΞ±-Fe3+O(OH)
Hβ“˜ AntigoriteMg3(Si2O5)(OH)4
Hβ“˜ Clinozoisite(CaCa)(AlAlAl)O[Si2O7][SiO4](OH)
Hβ“˜ LizarditeMg3(Si2O5)(OH)4
Hβ“˜ PectoliteNaCa2Si3O8(OH)
Hβ“˜ PrehniteCa2Al2Si3O10(OH)2
CCarbon
Cβ“˜ CalciteCaCO3
Cβ“˜ UM2005-32-SiOCO:CaHCa4(Si2O6)(CO3)(OH)2
Cβ“˜ DolomiteCaMg(CO3)2
Cβ“˜ Siderite var. Mg-rich Siderite(Fe,Mg)CO3
Cβ“˜ SideriteFeCO3
OOxygen
Oβ“˜ DovyreniteCa6Zr(Si2O7)2(OH)4
Oβ“˜ PlombiΓ¨rite[Ca4Si6O16(OH)2 · 2H2O] · (Ca · 5H2O)
Oβ“˜ CalciteCaCO3
Oβ“˜ FluorapatiteCa5(PO4)3F
Oβ“˜ BaghdaditeCa6Zr2(Si2O7)2O4
Oβ“˜ BruciteMg(OH)2
Oβ“˜ CalzirtiteCa2Zr5Ti2O16
Oβ“˜ DiopsideCaMgSi2O6
Oβ“˜ Augite var. Fassaite(Ca,Na)(Mg,Fe2+,Al,Fe3+,Ti)[(Si,Al)2O6]
Oβ“˜ FoshagiteCa4(Si3O9)(OH)2
Oβ“˜ MonticelliteCaMgSiO4
Oβ“˜ PerovskiteCaTiO3
Oβ“˜ Tazheranite(Zr,Ti,Ca)(O,◻)2
Oβ“˜ VesuvianiteCa19Fe3+Al4(Al6Mg2)(◻4)◻[Si2O7]4[(SiO4)10]O(OH)9
Oβ“˜ Melilite GroupCa2M(XSiO7)
Oβ“˜ Diopside var. Blue DiopsideCaMgSi2O6
Oβ“˜ UM2005-32-SiOCO:CaHCa4(Si2O6)(CO3)(OH)2
Oβ“˜ SpinelMgAl2O4
Oβ“˜ MerwiniteCa3Mg(SiO4)2
Oβ“˜ AfwilliteCa3(HSiO4)2 · 2H2O
Oβ“˜ HydroxylellestaditeCa5(SiO4)1.5(SO4)1.5(OH)
Oβ“˜ HydroxylapatiteCa5(PO4)3(OH)
Oβ“˜ BiotiteK(Fe2+/Mg)2(Al/Fe3+/Mg/Ti)([Si/Al/Fe]2Si2O10)(OH/F)2 or Simplified: K(Mg,Fe)3AlSi3O10(OH)2
Oβ“˜ PhlogopiteKMg3(AlSi3O10)(OH)2
Oβ“˜ ForsteriteMg2SiO4
Oβ“˜ IlmeniteFe2+TiO3
Oβ“˜ Actinolite◻Ca2(Mg4.5-2.5Fe0.5-2.5)Si8O22(OH)2
Oβ“˜ Augite(CaxMgyFez)(Mgy1Fez1)Si2O6
Oβ“˜ Plagioclase(Na,Ca)[(Si,Al)AlSi2]O8
Oβ“˜ MagnetiteFe2+Fe23+O4
Oβ“˜ Magnetite var. Titanium-bearing MagnetiteFe2+(Fe3+,Ti)2O4
Oβ“˜ Chromite var. Aluminian ChromiteFe(Cr,Al)2O4
Oβ“˜ Amphibole SupergroupAB2C5((Si,Al,Ti)8O22)(OH,F,Cl,O)2
Oβ“˜ ApatiteCa5(PO4)3(Cl/F/OH)
Oβ“˜ BaddeleyiteZrO2
Oβ“˜ Enstatite var. Bronzite(Mg,Fe2+)2[SiO3]2
Oβ“˜ Anorthite var. Bytownite(Ca,Na)[Al(Al,Si)Si2O8]
Oβ“˜ ChrysotileMg3(Si2O5)(OH)4
Oβ“˜ EdeniteNaCa2Mg5(Si7Al)O22(OH)2
Oβ“˜ MonaziteREE(PO4)
Oβ“˜ PargasiteNaCa2(Mg4Al)(Si6Al2)O22(OH)2
Oβ“˜ Pyrochlore GroupA2Nb2(O,OH)6Z
Oβ“˜ Pyroxene GroupADSi2O6
Oβ“˜ Serpentine SubgroupD3[Si2O5](OH)4
Oβ“˜ ThorianiteThO2
Oβ“˜ ThoriteTh(SiO4)
Oβ“˜ ZirconZr(SiO4)
Oβ“˜ ZirconoliteCaZrTi2O7
Oβ“˜ ChromiteFe2+Cr23+O4
Oβ“˜ EnstatiteMg2Si2O6
Oβ“˜ AnorthiteCa(Al2Si2O8)
Oβ“˜ DolomiteCaMg(CO3)2
Oβ“˜ Pigeonite(CaxMgyFez)(Mgy1Fez1)Si2O6
Oβ“˜ Ferro-edeniteNaCa2Fe52+(Si7Al)O22(OH)2
Oβ“˜ ChlorapatiteCa5(PO4)3Cl
Oβ“˜ QuartzSiO2
Oβ“˜ WollastoniteCa3(Si3O9)
Oβ“˜ ClintoniteCaAlMg2(SiAl3O10)(OH)2
Oβ“˜ CupriteCu2O
Oβ“˜ CuspidineCa8(Si2O7)2F4
Oβ“˜ Garnet GroupX3Z2(SiO4)3
Oβ“˜ GoethiteΞ±-Fe3+O(OH)
Oβ“˜ GrossularCa3Al2(SiO4)3
Oβ“˜ Siderite var. Mg-rich Siderite(Fe,Mg)CO3
Oβ“˜ NephelineNa3K(Al4Si4O16)
Oβ“˜ Hercynite var. Picotite(Fe,Mg)(Al,Cr)2O4
Oβ“˜ SideriteFeCO3
Oβ“˜ HercyniteFe2+Al2O4
Oβ“˜ RankiniteCa3Si2O7
Oβ“˜ AntigoriteMg3(Si2O5)(OH)4
Oβ“˜ Clinozoisite(CaCa)(AlAlAl)O[Si2O7][SiO4](OH)
Oβ“˜ LizarditeMg3(Si2O5)(OH)4
Oβ“˜ PectoliteNaCa2Si3O8(OH)
Oβ“˜ PrehniteCa2Al2Si3O10(OH)2
FFluorine
Fβ“˜ FluorapatiteCa5(PO4)3F
Fβ“˜ BiotiteK(Fe2+/Mg)2(Al/Fe3+/Mg/Ti)([Si/Al/Fe]2Si2O10)(OH/F)2 or Simplified: K(Mg,Fe)3AlSi3O10(OH)2
Fβ“˜ Amphibole SupergroupAB2C5((Si,Al,Ti)8O22)(OH,F,Cl,O)2
Fβ“˜ ApatiteCa5(PO4)3(Cl/F/OH)
Fβ“˜ CuspidineCa8(Si2O7)2F4
NaSodium
Naβ“˜ Augite var. Fassaite(Ca,Na)(Mg,Fe2+,Al,Fe3+,Ti)[(Si,Al)2O6]
Naβ“˜ Plagioclase(Na,Ca)[(Si,Al)AlSi2]O8
Naβ“˜ Anorthite var. Bytownite(Ca,Na)[Al(Al,Si)Si2O8]
Naβ“˜ EdeniteNaCa2Mg5(Si7Al)O22(OH)2
Naβ“˜ PargasiteNaCa2(Mg4Al)(Si6Al2)O22(OH)2
Naβ“˜ Ferro-edeniteNaCa2Fe52+(Si7Al)O22(OH)2
Naβ“˜ HaliteNaCl
Naβ“˜ NephelineNa3K(Al4Si4O16)
Naβ“˜ PectoliteNaCa2Si3O8(OH)
MgMagnesium
Mgβ“˜ BruciteMg(OH)2
Mgβ“˜ DiopsideCaMgSi2O6
Mgβ“˜ Augite var. Fassaite(Ca,Na)(Mg,Fe2+,Al,Fe3+,Ti)[(Si,Al)2O6]
Mgβ“˜ MonticelliteCaMgSiO4
Mgβ“˜ VesuvianiteCa19Fe3+Al4(Al6Mg2)(◻4)◻[Si2O7]4[(SiO4)10]O(OH)9
Mgβ“˜ Diopside var. Blue DiopsideCaMgSi2O6
Mgβ“˜ SpinelMgAl2O4
Mgβ“˜ MerwiniteCa3Mg(SiO4)2
Mgβ“˜ BiotiteK(Fe2+/Mg)2(Al/Fe3+/Mg/Ti)([Si/Al/Fe]2Si2O10)(OH/F)2 or Simplified: K(Mg,Fe)3AlSi3O10(OH)2
Mgβ“˜ PhlogopiteKMg3(AlSi3O10)(OH)2
Mgβ“˜ ForsteriteMg2SiO4
Mgβ“˜ Actinolite◻Ca2(Mg4.5-2.5Fe0.5-2.5)Si8O22(OH)2
Mgβ“˜ Augite(CaxMgyFez)(Mgy1Fez1)Si2O6
Mgβ“˜ Enstatite var. Bronzite(Mg,Fe2+)2[SiO3]2
Mgβ“˜ ChrysotileMg3(Si2O5)(OH)4
Mgβ“˜ EdeniteNaCa2Mg5(Si7Al)O22(OH)2
Mgβ“˜ PargasiteNaCa2(Mg4Al)(Si6Al2)O22(OH)2
Mgβ“˜ EnstatiteMg2Si2O6
Mgβ“˜ DolomiteCaMg(CO3)2
Mgβ“˜ Pigeonite(CaxMgyFez)(Mgy1Fez1)Si2O6
Mgβ“˜ ClintoniteCaAlMg2(SiAl3O10)(OH)2
Mgβ“˜ Siderite var. Mg-rich Siderite(Fe,Mg)CO3
Mgβ“˜ Hercynite var. Picotite(Fe,Mg)(Al,Cr)2O4
Mgβ“˜ AntigoriteMg3(Si2O5)(OH)4
Mgβ“˜ LizarditeMg3(Si2O5)(OH)4
AlAluminium
Alβ“˜ Augite var. Fassaite(Ca,Na)(Mg,Fe2+,Al,Fe3+,Ti)[(Si,Al)2O6]
Alβ“˜ VesuvianiteCa19Fe3+Al4(Al6Mg2)(◻4)◻[Si2O7]4[(SiO4)10]O(OH)9
Alβ“˜ SpinelMgAl2O4
Alβ“˜ BiotiteK(Fe2+/Mg)2(Al/Fe3+/Mg/Ti)([Si/Al/Fe]2Si2O10)(OH/F)2 or Simplified: K(Mg,Fe)3AlSi3O10(OH)2
Alβ“˜ PhlogopiteKMg3(AlSi3O10)(OH)2
Alβ“˜ Plagioclase(Na,Ca)[(Si,Al)AlSi2]O8
Alβ“˜ Chromite var. Aluminian ChromiteFe(Cr,Al)2O4
Alβ“˜ Amphibole SupergroupAB2C5((Si,Al,Ti)8O22)(OH,F,Cl,O)2
Alβ“˜ Anorthite var. Bytownite(Ca,Na)[Al(Al,Si)Si2O8]
Alβ“˜ EdeniteNaCa2Mg5(Si7Al)O22(OH)2
Alβ“˜ PargasiteNaCa2(Mg4Al)(Si6Al2)O22(OH)2
Alβ“˜ AnorthiteCa(Al2Si2O8)
Alβ“˜ Ferro-edeniteNaCa2Fe52+(Si7Al)O22(OH)2
Alβ“˜ ClintoniteCaAlMg2(SiAl3O10)(OH)2
Alβ“˜ GrossularCa3Al2(SiO4)3
Alβ“˜ NephelineNa3K(Al4Si4O16)
Alβ“˜ Hercynite var. Picotite(Fe,Mg)(Al,Cr)2O4
Alβ“˜ HercyniteFe2+Al2O4
Alβ“˜ Clinozoisite(CaCa)(AlAlAl)O[Si2O7][SiO4](OH)
Alβ“˜ PrehniteCa2Al2Si3O10(OH)2
SiSilicon
Siβ“˜ DovyreniteCa6Zr(Si2O7)2(OH)4
Siβ“˜ PlombiΓ¨rite[Ca4Si6O16(OH)2 · 2H2O] · (Ca · 5H2O)
Siβ“˜ BaghdaditeCa6Zr2(Si2O7)2O4
Siβ“˜ DiopsideCaMgSi2O6
Siβ“˜ Augite var. Fassaite(Ca,Na)(Mg,Fe2+,Al,Fe3+,Ti)[(Si,Al)2O6]
Siβ“˜ FoshagiteCa4(Si3O9)(OH)2
Siβ“˜ MonticelliteCaMgSiO4
Siβ“˜ VesuvianiteCa19Fe3+Al4(Al6Mg2)(◻4)◻[Si2O7]4[(SiO4)10]O(OH)9
Siβ“˜ Melilite GroupCa2M(XSiO7)
Siβ“˜ Diopside var. Blue DiopsideCaMgSi2O6
Siβ“˜ UM2005-32-SiOCO:CaHCa4(Si2O6)(CO3)(OH)2
Siβ“˜ MerwiniteCa3Mg(SiO4)2
Siβ“˜ AfwilliteCa3(HSiO4)2 · 2H2O
Siβ“˜ HydroxylellestaditeCa5(SiO4)1.5(SO4)1.5(OH)
Siβ“˜ BiotiteK(Fe2+/Mg)2(Al/Fe3+/Mg/Ti)([Si/Al/Fe]2Si2O10)(OH/F)2 or Simplified: K(Mg,Fe)3AlSi3O10(OH)2
Siβ“˜ PhlogopiteKMg3(AlSi3O10)(OH)2
Siβ“˜ ForsteriteMg2SiO4
Siβ“˜ Actinolite◻Ca2(Mg4.5-2.5Fe0.5-2.5)Si8O22(OH)2
Siβ“˜ Augite(CaxMgyFez)(Mgy1Fez1)Si2O6
Siβ“˜ Plagioclase(Na,Ca)[(Si,Al)AlSi2]O8
Siβ“˜ Amphibole SupergroupAB2C5((Si,Al,Ti)8O22)(OH,F,Cl,O)2
Siβ“˜ Enstatite var. Bronzite(Mg,Fe2+)2[SiO3]2
Siβ“˜ Anorthite var. Bytownite(Ca,Na)[Al(Al,Si)Si2O8]
Siβ“˜ ChrysotileMg3(Si2O5)(OH)4
Siβ“˜ EdeniteNaCa2Mg5(Si7Al)O22(OH)2
Siβ“˜ PargasiteNaCa2(Mg4Al)(Si6Al2)O22(OH)2
Siβ“˜ Pyroxene GroupADSi2O6
Siβ“˜ Serpentine SubgroupD3[Si2O5](OH)4
Siβ“˜ ThoriteTh(SiO4)
Siβ“˜ ZirconZr(SiO4)
Siβ“˜ EnstatiteMg2Si2O6
Siβ“˜ AnorthiteCa(Al2Si2O8)
Siβ“˜ Pigeonite(CaxMgyFez)(Mgy1Fez1)Si2O6
Siβ“˜ Ferro-edeniteNaCa2Fe52+(Si7Al)O22(OH)2
Siβ“˜ QuartzSiO2
Siβ“˜ WollastoniteCa3(Si3O9)
Siβ“˜ ClintoniteCaAlMg2(SiAl3O10)(OH)2
Siβ“˜ CuspidineCa8(Si2O7)2F4
Siβ“˜ Garnet GroupX3Z2(SiO4)3
Siβ“˜ GrossularCa3Al2(SiO4)3
Siβ“˜ NephelineNa3K(Al4Si4O16)
Siβ“˜ RankiniteCa3Si2O7
Siβ“˜ AntigoriteMg3(Si2O5)(OH)4
Siβ“˜ Clinozoisite(CaCa)(AlAlAl)O[Si2O7][SiO4](OH)
Siβ“˜ LizarditeMg3(Si2O5)(OH)4
Siβ“˜ PectoliteNaCa2Si3O8(OH)
Siβ“˜ PrehniteCa2Al2Si3O10(OH)2
PPhosphorus
Pβ“˜ FluorapatiteCa5(PO4)3F
Pβ“˜ HydroxylapatiteCa5(PO4)3(OH)
Pβ“˜ ApatiteCa5(PO4)3(Cl/F/OH)
Pβ“˜ MonaziteREE(PO4)
Pβ“˜ ChlorapatiteCa5(PO4)3Cl
SSulfur
Sβ“˜ ChalcopyriteCuFeS2
Sβ“˜ Pentlandite(NixFey)Ξ£9S8
Sβ“˜ PyrrhotiteFe1-xS
Sβ“˜ SphaleriteZnS
Sβ“˜ HydroxylellestaditeCa5(SiO4)1.5(SO4)1.5(OH)
Sβ“˜ Galena var. Selenium-bearing GalenaPb(S,Se)
Sβ“˜ LaitakariteBi4Se2S
Sβ“˜ CubaniteCuFe2S3
Sβ“˜ BorniteCu5FeS4
Sβ“˜ TalnakhiteCu9(Fe,Ni)8S16
Sβ“˜ HeazlewooditeNi3S2
Sβ“˜ Godlevskite(Ni,Fe)9S8
Sβ“˜ TroiliteFeS
Sβ“˜ ViolariteFe2+Ni23+S4
Sβ“˜ Mackinawite(Fe,Ni)9S8
Sβ“˜ GalenaPbS
Sβ“˜ MolybdeniteMoS2
Sβ“˜ PyriteFeS2
Sβ“˜ Irarsite(Ir,Ru,Rh,Pt)AsS
Sβ“˜ LauriteRuS2
Sβ“˜ Osarsite(Os,Ru)AsS
Sβ“˜ PlatarsitePtAsS
Sβ“˜ ColusiteCu13VAs3S16
Sβ“˜ GermanocolusiteCu26V2(Ge,As)6S32
Sβ“˜ DjerfisheriteK6(Fe,Cu,Ni)25S26Cl
Sβ“˜ CobaltiteCoAsS
Sβ“˜ GermaniteCu13Fe2Ge2S16
Sβ“˜ CobaltpentlanditeCo9S8
Sβ“˜ ChalcociteCu2S
Sβ“˜ DiaphoriteAg3Pb2Sb3S8
Sβ“˜ DigeniteCu9S5
ClChlorine
Clβ“˜ Amphibole SupergroupAB2C5((Si,Al,Ti)8O22)(OH,F,Cl,O)2
Clβ“˜ ApatiteCa5(PO4)3(Cl/F/OH)
Clβ“˜ ChlorapatiteCa5(PO4)3Cl
Clβ“˜ DjerfisheriteK6(Fe,Cu,Ni)25S26Cl
Clβ“˜ HaliteNaCl
KPotassium
Kβ“˜ BiotiteK(Fe2+/Mg)2(Al/Fe3+/Mg/Ti)([Si/Al/Fe]2Si2O10)(OH/F)2 or Simplified: K(Mg,Fe)3AlSi3O10(OH)2
Kβ“˜ PhlogopiteKMg3(AlSi3O10)(OH)2
Kβ“˜ DjerfisheriteK6(Fe,Cu,Ni)25S26Cl
Kβ“˜ NephelineNa3K(Al4Si4O16)
CaCalcium
Caβ“˜ DovyreniteCa6Zr(Si2O7)2(OH)4
Caβ“˜ PlombiΓ¨rite[Ca4Si6O16(OH)2 · 2H2O] · (Ca · 5H2O)
Caβ“˜ CalciteCaCO3
Caβ“˜ FluorapatiteCa5(PO4)3F
Caβ“˜ BaghdaditeCa6Zr2(Si2O7)2O4
Caβ“˜ CalzirtiteCa2Zr5Ti2O16
Caβ“˜ DiopsideCaMgSi2O6
Caβ“˜ Augite var. Fassaite(Ca,Na)(Mg,Fe2+,Al,Fe3+,Ti)[(Si,Al)2O6]
Caβ“˜ FoshagiteCa4(Si3O9)(OH)2
Caβ“˜ MonticelliteCaMgSiO4
Caβ“˜ PerovskiteCaTiO3
Caβ“˜ Tazheranite(Zr,Ti,Ca)(O,◻)2
Caβ“˜ VesuvianiteCa19Fe3+Al4(Al6Mg2)(◻4)◻[Si2O7]4[(SiO4)10]O(OH)9
Caβ“˜ Melilite GroupCa2M(XSiO7)
Caβ“˜ Diopside var. Blue DiopsideCaMgSi2O6
Caβ“˜ UM2005-32-SiOCO:CaHCa4(Si2O6)(CO3)(OH)2
Caβ“˜ MerwiniteCa3Mg(SiO4)2
Caβ“˜ AfwilliteCa3(HSiO4)2 · 2H2O
Caβ“˜ HydroxylellestaditeCa5(SiO4)1.5(SO4)1.5(OH)
Caβ“˜ HydroxylapatiteCa5(PO4)3(OH)
Caβ“˜ Actinolite◻Ca2(Mg4.5-2.5Fe0.5-2.5)Si8O22(OH)2
Caβ“˜ Augite(CaxMgyFez)(Mgy1Fez1)Si2O6
Caβ“˜ Plagioclase(Na,Ca)[(Si,Al)AlSi2]O8
Caβ“˜ ApatiteCa5(PO4)3(Cl/F/OH)
Caβ“˜ Anorthite var. Bytownite(Ca,Na)[Al(Al,Si)Si2O8]
Caβ“˜ EdeniteNaCa2Mg5(Si7Al)O22(OH)2
Caβ“˜ PargasiteNaCa2(Mg4Al)(Si6Al2)O22(OH)2
Caβ“˜ ZirconoliteCaZrTi2O7
Caβ“˜ AnorthiteCa(Al2Si2O8)
Caβ“˜ DolomiteCaMg(CO3)2
Caβ“˜ Pigeonite(CaxMgyFez)(Mgy1Fez1)Si2O6
Caβ“˜ Ferro-edeniteNaCa2Fe52+(Si7Al)O22(OH)2
Caβ“˜ ChlorapatiteCa5(PO4)3Cl
Caβ“˜ WollastoniteCa3(Si3O9)
Caβ“˜ ClintoniteCaAlMg2(SiAl3O10)(OH)2
Caβ“˜ CuspidineCa8(Si2O7)2F4
Caβ“˜ GrossularCa3Al2(SiO4)3
Caβ“˜ RankiniteCa3Si2O7
Caβ“˜ Clinozoisite(CaCa)(AlAlAl)O[Si2O7][SiO4](OH)
Caβ“˜ PectoliteNaCa2Si3O8(OH)
Caβ“˜ PrehniteCa2Al2Si3O10(OH)2
TiTitanium
Tiβ“˜ CalzirtiteCa2Zr5Ti2O16
Tiβ“˜ Augite var. Fassaite(Ca,Na)(Mg,Fe2+,Al,Fe3+,Ti)[(Si,Al)2O6]
Tiβ“˜ PerovskiteCaTiO3
Tiβ“˜ Tazheranite(Zr,Ti,Ca)(O,◻)2
Tiβ“˜ BiotiteK(Fe2+/Mg)2(Al/Fe3+/Mg/Ti)([Si/Al/Fe]2Si2O10)(OH/F)2 or Simplified: K(Mg,Fe)3AlSi3O10(OH)2
Tiβ“˜ IlmeniteFe2+TiO3
Tiβ“˜ Magnetite var. Titanium-bearing MagnetiteFe2+(Fe3+,Ti)2O4
Tiβ“˜ Amphibole SupergroupAB2C5((Si,Al,Ti)8O22)(OH,F,Cl,O)2
Tiβ“˜ ZirconoliteCaZrTi2O7
VVanadium
Vβ“˜ ColusiteCu13VAs3S16
Vβ“˜ GermanocolusiteCu26V2(Ge,As)6S32
CrChromium
Crβ“˜ Chromite var. Aluminian ChromiteFe(Cr,Al)2O4
Crβ“˜ ChromiteFe2+Cr23+O4
Crβ“˜ Hercynite var. Picotite(Fe,Mg)(Al,Cr)2O4
FeIron
Feβ“˜ ChalcopyriteCuFeS2
Feβ“˜ Augite var. Fassaite(Ca,Na)(Mg,Fe2+,Al,Fe3+,Ti)[(Si,Al)2O6]
Feβ“˜ Pentlandite(NixFey)Ξ£9S8
Feβ“˜ PyrrhotiteFe1-xS
Feβ“˜ VesuvianiteCa19Fe3+Al4(Al6Mg2)(◻4)◻[Si2O7]4[(SiO4)10]O(OH)9
Feβ“˜ Nickelskutterudite(Ni,Co,Fe)As3
Feβ“˜ Safflorite(Co,Ni,Fe)As2
Feβ“˜ CubaniteCuFe2S3
Feβ“˜ BorniteCu5FeS4
Feβ“˜ TalnakhiteCu9(Fe,Ni)8S16
Feβ“˜ Godlevskite(Ni,Fe)9S8
Feβ“˜ TetraferroplatinumPtFe
Feβ“˜ TulameenitePt2CuFe
Feβ“˜ BiotiteK(Fe2+/Mg)2(Al/Fe3+/Mg/Ti)([Si/Al/Fe]2Si2O10)(OH/F)2 or Simplified: K(Mg,Fe)3AlSi3O10(OH)2
Feβ“˜ TroiliteFeS
Feβ“˜ ViolariteFe2+Ni23+S4
Feβ“˜ IlmeniteFe2+TiO3
Feβ“˜ Mackinawite(Fe,Ni)9S8
Feβ“˜ IsoferroplatinumPt3Fe
Feβ“˜ Actinolite◻Ca2(Mg4.5-2.5Fe0.5-2.5)Si8O22(OH)2
Feβ“˜ Augite(CaxMgyFez)(Mgy1Fez1)Si2O6
Feβ“˜ MagnetiteFe2+Fe23+O4
Feβ“˜ PyriteFeS2
Feβ“˜ Magnetite var. Titanium-bearing MagnetiteFe2+(Fe3+,Ti)2O4
Feβ“˜ Chromite var. Aluminian ChromiteFe(Cr,Al)2O4
Feβ“˜ Enstatite var. Bronzite(Mg,Fe2+)2[SiO3]2
Feβ“˜ ChromiteFe2+Cr23+O4
Feβ“˜ Pigeonite(CaxMgyFez)(Mgy1Fez1)Si2O6
Feβ“˜ Ferro-edeniteNaCa2Fe52+(Si7Al)O22(OH)2
Feβ“˜ DjerfisheriteK6(Fe,Cu,Ni)25S26Cl
Feβ“˜ GoethiteΞ±-Fe3+O(OH)
Feβ“˜ Siderite var. Mg-rich Siderite(Fe,Mg)CO3
Feβ“˜ Hercynite var. Picotite(Fe,Mg)(Al,Cr)2O4
Feβ“˜ SideriteFeCO3
Feβ“˜ HercyniteFe2+Al2O4
Feβ“˜ GermaniteCu13Fe2Ge2S16
CoCobalt
Coβ“˜ Nickelskutterudite(Ni,Co,Fe)As3
Coβ“˜ Safflorite(Co,Ni,Fe)As2
Coβ“˜ CobaltiteCoAsS
Coβ“˜ CobaltpentlanditeCo9S8
NiNickel
Niβ“˜ Pentlandite(NixFey)Ξ£9S8
Niβ“˜ RammelsbergiteNiAs2
Niβ“˜ Nickelskutterudite(Ni,Co,Fe)As3
Niβ“˜ NickelineNiAs
Niβ“˜ Safflorite(Co,Ni,Fe)As2
Niβ“˜ TalnakhiteCu9(Fe,Ni)8S16
Niβ“˜ HeazlewooditeNi3S2
Niβ“˜ Godlevskite(Ni,Fe)9S8
Niβ“˜ ViolariteFe2+Ni23+S4
Niβ“˜ Mackinawite(Fe,Ni)9S8
Niβ“˜ MaucheriteNi11As8
Niβ“˜ MajakitePdNiAs
Niβ“˜ DjerfisheriteK6(Fe,Cu,Ni)25S26Cl
CuCopper
Cuβ“˜ ChalcopyriteCuFeS2
Cuβ“˜ CubaniteCuFe2S3
Cuβ“˜ BorniteCu5FeS4
Cuβ“˜ TalnakhiteCu9(Fe,Ni)8S16
Cuβ“˜ TulameenitePt2CuFe
Cuβ“˜ Taimyrite(Pd,Cu,Pt)3Sn
Cuβ“˜ Tetra-auricuprideAuCu
Cuβ“˜ CopperCu
Cuβ“˜ ColusiteCu13VAs3S16
Cuβ“˜ GermanocolusiteCu26V2(Ge,As)6S32
Cuβ“˜ CupriteCu2O
Cuβ“˜ DjerfisheriteK6(Fe,Cu,Ni)25S26Cl
Cuβ“˜ GermaniteCu13Fe2Ge2S16
Cuβ“˜ Stannopalladinite(Pd,Cu)3Sn2
Cuβ“˜ ChalcociteCu2S
Cuβ“˜ DigeniteCu9S5
Cuβ“˜ NielsenitePdCu3
Cuβ“˜ OrthocuproplatinumPt3Cu
ZnZinc
Znβ“˜ SphaleriteZnS
GeGermanium
Geβ“˜ PalladogermanidePd2Ge
Geβ“˜ GermanocolusiteCu26V2(Ge,As)6S32
Geβ“˜ GermaniteCu13Fe2Ge2S16
AsArsenic
Asβ“˜ RammelsbergiteNiAs2
Asβ“˜ Nickelskutterudite(Ni,Co,Fe)As3
Asβ“˜ NickelineNiAs
Asβ“˜ Safflorite(Co,Ni,Fe)As2
Asβ“˜ SperrylitePtAs2
Asβ“˜ MaucheriteNi11As8
Asβ“˜ AtheneitePd2As0.75Hg0.25
Asβ“˜ MajakitePdNiAs
Asβ“˜ MertieitePd8Sb2.5As0.5
Asβ“˜ PseudomertieitePd11(Sb,As)4
Asβ“˜ Irarsite(Ir,Ru,Rh,Pt)AsS
Asβ“˜ Osarsite(Os,Ru)AsS
Asβ“˜ PlatarsitePtAsS
Asβ“˜ ColusiteCu13VAs3S16
Asβ“˜ GermanocolusiteCu26V2(Ge,As)6S32
Asβ“˜ CobaltiteCoAsS
SeSelenium
Seβ“˜ Galena var. Selenium-bearing GalenaPb(S,Se)
Seβ“˜ ClausthalitePbSe
Seβ“˜ LaitakariteBi4Se2S
ZrZirconium
Zrβ“˜ DovyreniteCa6Zr(Si2O7)2(OH)4
Zrβ“˜ BaghdaditeCa6Zr2(Si2O7)2O4
Zrβ“˜ CalzirtiteCa2Zr5Ti2O16
Zrβ“˜ Tazheranite(Zr,Ti,Ca)(O,◻)2
Zrβ“˜ BaddeleyiteZrO2
Zrβ“˜ ZirconZr(SiO4)
Zrβ“˜ ZirconoliteCaZrTi2O7
NbNiobium
Nbβ“˜ Pyrochlore GroupA2Nb2(O,OH)6Z
MoMolybdenum
Moβ“˜ MolybdeniteMoS2
RuRuthenium
Ruβ“˜ Irarsite(Ir,Ru,Rh,Pt)AsS
Ruβ“˜ LauriteRuS2
Ruβ“˜ Osarsite(Os,Ru)AsS
RhRhodium
Rhβ“˜ Irarsite(Ir,Ru,Rh,Pt)AsS
PdPalladium
Pdβ“˜ ZvyagintsevitePd3Pb
Pdβ“˜ Rustenburgite(Pt,Pd)3Sn
Pdβ“˜ KotulskitePd(Te,Bi)2-x (x ≈ 0.4)
Pdβ“˜ PotaritePdHg
Pdβ“˜ AtheneitePd2As0.75Hg0.25
Pdβ“˜ MajakitePdNiAs
Pdβ“˜ Atokite(Pd,Pt)3Sn
Pdβ“˜ Taimyrite(Pd,Cu,Pt)3Sn
Pdβ“˜ PaolovitePd2Sn
Pdβ“˜ SudburyitePdSb
Pdβ“˜ MertieitePd8Sb2.5As0.5
Pdβ“˜ PseudomertieitePd11(Sb,As)4
Pdβ“˜ NaldrettitePd2Sb
Pdβ“˜ MicheneritePdBiTe
Pdβ“˜ PalladogermanidePd2Ge
Pdβ“˜ Telargpalite(Pd,Ag)3(Te,Bi)
Pdβ“˜ Frooditeα-PdBi2
Pdβ“˜ SobolevskitePdBi
Pdβ“˜ Stannopalladinite(Pd,Cu)3Sn2
Pdβ“˜ NielsenitePdCu3
AgSilver
Agβ“˜ Silver var. KΓΌsteliteAg
Agβ“˜ SilverAg
Agβ“˜ Gold var. Electrum(Au,Ag)
Agβ“˜ HessiteAg2Te
Agβ“˜ Silver var. Native Amalgam(Ag,Hg)
Agβ“˜ Telargpalite(Pd,Ag)3(Te,Bi)
Agβ“˜ DiaphoriteAg3Pb2Sb3S8
SnTin
Snβ“˜ Rustenburgite(Pt,Pd)3Sn
Snβ“˜ Atokite(Pd,Pt)3Sn
Snβ“˜ Taimyrite(Pd,Cu,Pt)3Sn
Snβ“˜ PaolovitePd2Sn
Snβ“˜ NiggliitePtSn
Snβ“˜ Stannopalladinite(Pd,Cu)3Sn2
SbAntimony
Sbβ“˜ GeversitePtSb2
Sbβ“˜ SudburyitePdSb
Sbβ“˜ MertieitePd8Sb2.5As0.5
Sbβ“˜ PseudomertieitePd11(Sb,As)4
Sbβ“˜ NaldrettitePd2Sb
Sbβ“˜ InsizwaitePt(Bi,Sb)2
Sbβ“˜ DiaphoriteAg3Pb2Sb3S8
TeTellurium
Teβ“˜ MoncheitePt(Te,Bi)2
Teβ“˜ KotulskitePd(Te,Bi)2-x (x ≈ 0.4)
Teβ“˜ MaslovitePtBiTe
Teβ“˜ AltaitePbTe
Teβ“˜ HessiteAg2Te
Teβ“˜ MicheneritePdBiTe
Teβ“˜ Telargpalite(Pd,Ag)3(Te,Bi)
OsOsmium
Osβ“˜ Osarsite(Os,Ru)AsS
IrIridium
Irβ“˜ Irarsite(Ir,Ru,Rh,Pt)AsS
PtPlatinum
Ptβ“˜ TetraferroplatinumPtFe
Ptβ“˜ TulameenitePt2CuFe
Ptβ“˜ Rustenburgite(Pt,Pd)3Sn
Ptβ“˜ MoncheitePt(Te,Bi)2
Ptβ“˜ SperrylitePtAs2
Ptβ“˜ GeversitePtSb2
Ptβ“˜ IsoferroplatinumPt3Fe
Ptβ“˜ Taimyrite(Pd,Cu,Pt)3Sn
Ptβ“˜ MaslovitePtBiTe
Ptβ“˜ PlatinumPt
Ptβ“˜ InsizwaitePt(Bi,Sb)2
Ptβ“˜ Irarsite(Ir,Ru,Rh,Pt)AsS
Ptβ“˜ NiggliitePtSn
Ptβ“˜ PlatarsitePtAsS
Ptβ“˜ OrthocuproplatinumPt3Cu
AuGold
Auβ“˜ Tetra-auricuprideAuCu
Auβ“˜ GoldAu
Auβ“˜ Gold var. Electrum(Au,Ag)
HgMercury
Hgβ“˜ PotaritePdHg
Hgβ“˜ AtheneitePd2As0.75Hg0.25
Hgβ“˜ Silver var. Native Amalgam(Ag,Hg)
PbLead
Pbβ“˜ Galena var. Selenium-bearing GalenaPb(S,Se)
Pbβ“˜ ClausthalitePbSe
Pbβ“˜ ZvyagintsevitePd3Pb
Pbβ“˜ GalenaPbS
Pbβ“˜ AltaitePbTe
Pbβ“˜ DiaphoriteAg3Pb2Sb3S8
BiBismuth
Biβ“˜ BismuthBi
Biβ“˜ LaitakariteBi4Se2S
Biβ“˜ MoncheitePt(Te,Bi)2
Biβ“˜ KotulskitePd(Te,Bi)2-x (x ≈ 0.4)
Biβ“˜ MaslovitePtBiTe
Biβ“˜ InsizwaitePt(Bi,Sb)2
Biβ“˜ MicheneritePdBiTe
Biβ“˜ Telargpalite(Pd,Ag)3(Te,Bi)
Biβ“˜ Frooditeα-PdBi2
Biβ“˜ SobolevskitePdBi
ThThorium
Thβ“˜ ThorianiteThO2
Thβ“˜ ThoriteTh(SiO4)

Localities in this Region

Russia

Other Regions, Features and Areas containing this locality

Amur PlateTectonic Plate
AsiaContinent
Russia
Soviet Union (1922-1991)Country

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