Monte Arsiccio Mine, Sant'Anna di Stazzema, Stazzema, Lucca Province, Tuscany, Italyi
Regional Level Types | |
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Monte Arsiccio Mine | Mine |
Sant'Anna di Stazzema | Village |
Stazzema | Commune |
Lucca Province | Province |
Tuscany | Region |
Italy | Country |
Monte Arsiccio Mine, Apuan Alps, Tuscany, Italy
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Key
Latitude & Longitude (WGS84):
43° 58' 0'' North , 10° 16' 59'' East
Latitude & Longitude (decimal):
Locality type:
Köppen climate type:
Nearest Settlements:
Place | Population | Distance |
---|---|---|
Farnocchia | 108 (2014) | 1.8km |
Monteggiori | 134 (2014) | 2.5km |
Camaiore | 26,746 (2015) | 2.9km |
Mulina | 139 (2014) | 3.0km |
Pontestazzemese | 177 (2014) | 3.4km |
Name(s) in local language(s):
Miniera di Monte Arsiccio, Sant'Anna di Stazzema, Stazzema, Alpi Apuane, Lucca, Toscana, Italia
Old iron mine that worked a baryte-iron oxide-pyrite deposit.
Known for several rare and unusual thallium sulphosalts.
Select Mineral List Type
Standard Detailed Gallery Strunz Dana Chemical ElementsMineral List
Mineral list contains entries from the region specified including sub-localities70 valid minerals. 10 (TL) - type locality of valid minerals.
Detailed Mineral List:
ⓘ Aktashite Formula: Cu6Hg3As4S12 Reference: Biagioni, C., Bonaccorsi, E., Moëlo, Y., Orlandi, P. (2014): Mercury-arsenic sulfosalts from Apuan Alps (Tuscany, Italy). II. Aktashite, Cu6Hg3As4S12, and laffittite, AgHgAsS3, from the Monte Arsiccio mine: occurrence and crystal structure. Periodico di Mineralogia, 83, 1-18.; Biagioni, C., Bonaccorsi, E., Moëlo, Y., & Orlandi, P. (2014). Mercury-arsenic sulfosalts from Apuan Alps (Tuscany, Italy). I. Routhierite,(Cu0. 8Ag0. 2) Hg2Tl (As1. 4Sb0. 6)∑= 2S6, from Monte Arsiccio mine: occurrence and crystal structure. European Journal of Mineralogy, 26(1), 163-170. |
ⓘ Alum-(K) Formula: KAl(SO4)2 · 12H2O Reference: Biagioni C, Bindi L, Mauro D, Hålenius U. (2019) Crystal Chemistry of Sulfates from the Apuan Alps (Tuscany, Italy). V. Scordariite, K8(Fe3+0.67□0.33)[Fe3+3O(SO4)6(H2O)3]2(H2O)11: A New Metavoltine-Related Mineral. Minerals. 9(11):702; Mauro, D. (2020). Crystal-chemistry of secondary minerals of thallium-rich pyrite from the Apuan Alps (Tuscany, Italy). Plinius, 46, 64-68. |
ⓘ Alunogen Formula: Al2(SO4)3 · 17H2O Reference: Biagioni C, Bindi L, Mauro D, Hålenius U. (2019) Crystal Chemistry of Sulfates from the Apuan Alps (Tuscany, Italy). V. Scordariite, K8(Fe3+0.67□0.33)[Fe3+3O(SO4)6(H2O)3]2(H2O)11: A New Metavoltine-Related Mineral. Minerals. 9(11):702; Mauro, D. (2020). Crystal-chemistry of secondary minerals of thallium-rich pyrite from the Apuan Alps (Tuscany, Italy). Plinius, 46, 64-68 |
ⓘ Anatase Formula: TiO2 Reference: Biagioni, C., Orlandi, P., Pasero, M. (2009): Ankangite from the Monte Arsiccio mine (Apuan Alps, Tuscany, Italy): occurrence, crystal structure, and classification problems in cryptomelane group minerals. Periodico di Mineralogia, 78(2), 3-11 |
ⓘ 'Andorite' Formula: AgPbSb3S6 Reference: Biagioni, C., Bonaccorsi, E., Moëlo, Y., & Orlandi, P. (2014). Mercury-arsenic sulfosalts from Apuan Alps (Tuscany, Italy). I. Routhierite,(Cu0. 8Ag0. 2) Hg2Tl (As1. 4Sb0. 6)∑= 2S6, from Monte Arsiccio mine: occurrence and crystal structure. European Journal of Mineralogy, 26(1), 163-170. |
ⓘ Andreadiniite (TL) Formula: CuHgAg7Pb7Sb24S48 Type Locality: Reference: Biagioni, C., Moëlo, Y., Orlandi, P. and Paar, W.H. (2014) Andreadiniite, IMA 2014-049. CNMNC Newsletter No. 22, October 2014, page 1244; Mineralogical Magazine, 78, 1241-1248; Biagioni, C., Moëlo, Y., Orlandi, P., Paar, W.H. (2018) Lead-antimony sulfosalts from Tuscany (Italy). XXIII. Andreadiniite, CuAg7HgPb7Sb24S48, a new oversubstituted (Cu,Hg)-rich member of the andorite homeotypic series from the Monte Arsiccio mine, Apuan Alps. European Journal of Mineralogy: 30: 1021-1035. |
ⓘ Annabergite Formula: Ni3(AsO4)2 · 8H2O Reference: Collection Lechner Alois |
ⓘ 'Apatite' Formula: Ca5(PO4)3(Cl/F/OH) Reference: Biagioni, C., Orlandi, P., Pasero, M. (2009): Ankangite from the Monte Arsiccio mine (Apuan Alps, Tuscany, Italy): occurrence, crystal structure, and classification problems in cryptomelane group minerals. Periodico di Mineralogia, 78(2), 3-11 |
ⓘ Aragonite Formula: CaCO3 |
ⓘ Arsenopyrite Formula: FeAsS Reference: Biagioni, C. (2009). Minerali della Provincia di Lucca. Associazione Micro-Mineralogica Italiana, Cremona, 352 pp.
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ⓘ Arsiccioite (TL) Formula: AgHg2Tl(As,Sb)2S6 Type Locality: Reference: Biagioni, C., Bonaccorsi, E., Moëlo, Y., Orlandi, P., Bindi, L., D’Orazio, M. and Vezzoni, S. (2013) Arsiccioite, IMA 2013-058. CNMNC Newsletter No. 17, October 2013, page 3003; Mineralogical Magazine, 77, 2997-3005; Biagioni, C., Bonaccorsi, E., Moëlo, Y., Orlandi, P., Bindi, L., D’Orazio, M., Vezzoni, S. (2014): Mercury-arsenic sulfosalts from the Apuan Alps (Tuscany, Italy). II. Arsiccioite, AgHg2TlAs2S6, a new mineral from the Monte Arsiccio mine: occurrence, crystal structure and crystal chemistry of the routhierite isotypic series. Mineralogical Magazine, 78, 101-117. |
ⓘ Baryte Formula: BaSO4 Reference: http://www.valdicastello.it/miniere.html; Biagioni, C., Orlandi, P., Pasero, M. (2009): Ankangite from the Monte Arsiccio mine (Apuan Alps, Tuscany, Italy): occurrence, crystal structure, and classification problems in cryptomelane group minerals. Periodico di Mineralogia, 78(2), 3-11; Biagioni, C., Bonaccorsi, E., Moëlo, Y., & Orlandi, P. (2014). Mercury-arsenic sulfosalts from Apuan Alps (Tuscany, Italy). I. Routhierite,(Cu0. 8Ag0. 2) Hg2Tl (As1. 4Sb0. 6)∑= 2S6, from Monte Arsiccio mine: occurrence and crystal structure. European Journal of Mineralogy, 26(1), 163-170. |
ⓘ Benstonite Formula: Ba6Ca6Mg(CO3)13 Reference: Biagioni, C. & Orlandi, P. (2010). Cymrite and benstonite from the Monte Arsiccio mine (Apuan Alps, Tuscany, Italy): first Italian occurrence. Plinius, 36, 365. |
ⓘ Beryl Formula: Be3Al2(Si6O18) Reference: Duchi G., Franzini M., Giamello M., Orlandi P., Riccobono F., 1993. The iron-rich beryls of Alpi Apuane. Mineralogy, chemistry and fluid inclusion. N. Jb. Mineral. Mh.: 193-207 |
ⓘ Beryl var. Emerald Formula: Be3Al2(Si6O18) Reference: Duchi G., Franzini M., Giamello M., Orlandi P., Riccobono F., 1993. The iron-rich beryls of Alpi Apuane. Mineralogy, chemistry and fluid inclusion. N. Jb. Mineral. Mh.: 193-207 |
ⓘ Bianchiniite (TL) Formula: Ba2(TiV)(As2O5)2OF Type Locality: Reference: Biagioni C., Pasero M., Hålenius U., Bosi F. (2019): Bianchiniite, IMA 2019-022. CNMNC Newsletter No. 50; Mineralogical Magazine: 31, doi: 10.1180/mgm.2019.46; http://forum.amiminerals.it/viewtopic.php?f=5&t=15578&sid=813c77a70706fa166a7b80754bd6a1e5 (visited 23.07.2019) |
ⓘ Boscardinite (TL) Formula: TlPb4(Sb7As2)S18 Type Locality: Description: TL added Reference: Orlandi, P., Biagioni, C., Bonaccorsi, E., Moëlo, Y., Paar, W.H. (2012): Lead-antomony sulfosalts from Tuscany (Italy). XII. Boscardinite, TlPb4(Sb7As2){sum}9S18, a new species from Monte Arsiccio mine: Occurrence and crystal structure. Canadian Mineralogist , 50 , 235-251; Biagioni, C., Bonaccorsi, E., Moëlo, Y., & Orlandi, P. (2014). Mercury-arsenic sulfosalts from Apuan Alps (Tuscany, Italy). I. Routhierite,(Cu0. 8Ag0. 2) Hg2Tl (As1. 4Sb0. 6)∑= 2S6, from Monte Arsiccio mine: occurrence and crystal structure. European Journal of Mineralogy, 26(1), 163-170; Biagioni, C. & Moëlo, Y. (2017): Lead-antimony sulfosalts from Tuscany (Italy). XVIII. New data on the crystal-chemistry of boscardinite. Mineralogical Magazine, 81, 47-60. |
ⓘ Calcite Formula: CaCO3 |
ⓘ Cerussite Formula: PbCO3 Reference: Collection Lechner Alois |
ⓘ Chabournéite Formula: Tl4Pb2(Sb,As)20S34 Reference: Biagioni, C., Moëlo, Y., and Zaccarini, F. (2017) Ferdowsiite from the Monte Arsiccio mine, Apuan Alps, Tuscany (Italy): occurrence and crystal structure. Atti della Società Toscana di Scienze Naturali, Memorie, 124, 5-11. |
ⓘ Chalcopyrite Formula: CuFeS2 Reference: http://www.valdicastello.it/miniere.html |
ⓘ Chovanite Formula: Pb15-2xSb14+2xS36Ox (x ~ 0.2) Localities: Reference: Biagioni, C., Moëlo, Y., Orlandi, P. (2014): Lead-antimony sulfosalts from Tuscany (Italy). XV. (Tl-Ag)-bearing rouxelite from Monte Arsiccio mine: occurrence and crystal-chemistry. Mineralogical Magazine, 78, 651–661. |
ⓘ Copiapite Formula: Fe2+Fe3+4(SO4)6(OH)2 · 20H2O Reference: Biagioni C, Bindi L, Mauro D, Hålenius U. (2019) Crystal Chemistry of Sulfates from the Apuan Alps (Tuscany, Italy). V. Scordariite, K8(Fe3+0.67□0.33)[Fe3+3O(SO4)6(H2O)3]2(H2O)11: A New Metavoltine-Related Mineral. Minerals. 9(11):702; Mauro, D. (2020). Crystal-chemistry of secondary minerals of thallium-rich pyrite from the Apuan Alps (Tuscany, Italy). Plinius, 46, 64-68. |
ⓘ Coquimbite Formula: AlFe3(SO4)6(H2O)12 · 6H2O Reference: Biagioni C, Bindi L, Mauro D, Hålenius U. (2019) Crystal Chemistry of Sulfates from the Apuan Alps (Tuscany, Italy). V. Scordariite, K8(Fe3+0.67□0.33)[Fe3+3O(SO4)6(H2O)3]2(H2O)11: A New Metavoltine-Related Mineral. Minerals. 9(11):702; Mauro, D. (2020). Crystal-chemistry of secondary minerals of thallium-rich pyrite from the Apuan Alps (Tuscany, Italy). Plinius, 46, 64-68. |
ⓘ Cymrite Formula: BaAl2Si2(O,OH)8 · H2O Reference: Biagioni, C. & Orlandi, P. (2010). Cymrite and benstonite from the Monte Arsiccio mine (Apuan Alps, Tuscany, Italy): first Italian occurrence. Plinius, 36, 365. ; Biagioni, C., Bonaccorsi, E., Moëlo, Y., & Orlandi, P. (2014). Mercury-arsenic sulfosalts from Apuan Alps (Tuscany, Italy). I. Routhierite,(Cu0. 8Ag0. 2) Hg2Tl (As1. 4Sb0. 6)∑= 2S6, from Monte Arsiccio mine: occurrence and crystal structure. European Journal of Mineralogy, 26(1), 163-170. |
ⓘ Derbylite Formula: Fe3+4Ti3Sb3+O13(OH) Reference: Biagioni, C., Bonaccorsi, E., Capalbo, C., Merlino, S., Orlandi, P., Pasero, M. & Perchiazzi, N. (2013) Cinque anni di ricerche mineralogichesulle Alpi Apuane - Sinergia fra collezionismo e ricerca scientifica. Giornate di Studio GNM “Nuovi minerali: tra ricerca e collezionismo” Padova, 18 giugno 2013, 48 pp. |
ⓘ Destinezite Formula: Fe3+2(PO4)(SO4)(OH) · 6H2O Reference: Mauro, D. (2020). Crystal-chemistry of secondary minerals of thallium-rich pyrite from the Apuan Alps (Tuscany, Italy). Plinius, 46, 64-68. |
ⓘ Dolomite Formula: CaMg(CO3)2 Reference: Biagioni, C., Orlandi, P., Pasero, M. (2009): Ankangite from the Monte Arsiccio mine (Apuan Alps, Tuscany, Italy): occurrence, crystal structure, and classification problems in cryptomelane group minerals. Periodico di Mineralogia, 78(2), 3-11; Biagioni, C., Bonaccorsi, E., Moëlo, Y., & Orlandi, P. (2014). Mercury-arsenic sulfosalts from Apuan Alps (Tuscany, Italy). I. Routhierite,(Cu0. 8Ag0. 2) Hg2Tl (As1. 4Sb0. 6)∑= 2S6, from Monte Arsiccio mine: occurrence and crystal structure. European Journal of Mineralogy, 26(1), 163-170. |
ⓘ Epsomite Formula: MgSO4 · 7H2O Reference: Mauro, D. (2020). Crystal-chemistry of secondary minerals of thallium-rich pyrite from the Apuan Alps (Tuscany, Italy). Plinius, 46, 64-68. |
ⓘ Ferdowsiite Formula: Ag8(Sb5As3)S16 Reference: Biagioni, C., Moëlo, Y., and Zaccarini, F. (2017) Ferdowsiite from the Monte Arsiccio mine, Apuan Alps, Tuscany (Italy): occurrence and crystal structure. Atti della Società Toscana di Scienze Naturali, Memorie, 124, 5-11. |
ⓘ Fluorophlogopite Formula: KMg3(Si3Al)O10F2 Reference: Lacalamita, M., Schingaro, E., Mesto, E., Zaccarini, F. and Biagioni, C. (2020) Crystal-chemistry of micas belonging to the yangzhumingite-fluorophologopite and phlogopite-fluorophlogopite series from the Apuan Alps (northern Tuscany, Italy). Physics and Chemistry of Minerals, 47, 54. |
ⓘ Galena Formula: PbS Reference: Biagioni, C. (2009). Minerali della Provincia di Lucca. Associazione Micro-Mineralogica Italiana, Cremona, 352 pp.
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ⓘ Gersdorffite Formula: NiAsS Reference: Zibaldone di mineralogia italiana – Riv. min. It., Fasc. 3, 1990, pag. 140 |
ⓘ Giacovazzoite (TL) Formula: K5Fe3+3O(SO4)6 · 10H2O Type Locality: Reference: Biagioni, B., Bindi, L., Mauro, D. and Pasero, M. (2019) Giacovazzoite, IMA 2018-165. CNMNC Newsletter No. 49, June 2019, page xxx; Mineralogical Magazine, 83: 323–328. ; Biagioni C, Bindi L, Mauro D, Hålenius U. (2019) Crystal Chemistry of Sulfates from the Apuan Alps (Tuscany, Italy). V. Scordariite, K8(Fe3+0.67□0.33)[Fe3+3O(SO4)6(H2O)3]2(H2O)11: A New Metavoltine-Related Mineral. Minerals. 9(11):702; Mauro, D. (2020). Crystal-chemistry of secondary minerals of thallium-rich pyrite from the Apuan Alps (Tuscany, Italy). Plinius, 46, 64-68. |
ⓘ Goldichite Formula: KFe(SO4)2 · 4H2O Reference: Biagioni C, Bindi L, Mauro D, Hålenius U. (2019) Crystal Chemistry of Sulfates from the Apuan Alps (Tuscany, Italy). V. Scordariite, K8(Fe3+0.67□0.33)[Fe3+3O(SO4)6(H2O)3]2(H2O)11: A New Metavoltine-Related Mineral. Minerals. 9(11):702; Mauro, D. (2020). Crystal-chemistry of secondary minerals of thallium-rich pyrite from the Apuan Alps (Tuscany, Italy). Plinius, 46, 64-68. |
✪ Graeserite Formula: (Fe3+ ,Ti)4Ti3AsO13(OH) Reference: Collection Lechner Alois |
ⓘ Gypsum Formula: CaSO4 · 2H2O Reference: Biagioni C, Bindi L, Mauro D, Hålenius U. (2019) Crystal Chemistry of Sulfates from the Apuan Alps (Tuscany, Italy). V. Scordariite, K8(Fe3+0.67□0.33)[Fe3+3O(SO4)6(H2O)3]2(H2O)11: A New Metavoltine-Related Mineral. Minerals. 9(11):702; Mauro, D. (2020). Crystal-chemistry of secondary minerals of thallium-rich pyrite from the Apuan Alps (Tuscany, Italy). Plinius, 46, 64-68. |
ⓘ Halotrichite Formula: FeAl2(SO4)4 · 22H2O Reference: Biagioni C, Bindi L, Mauro D, Hålenius U. (2019) Crystal Chemistry of Sulfates from the Apuan Alps (Tuscany, Italy). V. Scordariite, K8(Fe3+0.67□0.33)[Fe3+3O(SO4)6(H2O)3]2(H2O)11: A New Metavoltine-Related Mineral. Minerals. 9(11):702; Mauro, D. (2020). Crystal-chemistry of secondary minerals of thallium-rich pyrite from the Apuan Alps (Tuscany, Italy). Plinius, 46, 64-68. |
ⓘ Hematite Formula: Fe2O3 |
ⓘ Hörnesite Formula: Mg3(AsO4)2 · 8H2O Reference: Biagioni, C., Moëlo, Y., and Zaccarini, F. (2017) Ferdowsiite from the Monte Arsiccio mine, Apuan Alps, Tuscany (Italy): occurrence and crystal structure. Atti della Società Toscana di Scienze Naturali, Memorie, 124, 5-11. |
ⓘ Jarosite Formula: KFe3+ 3(SO4)2(OH)6 Reference: Biagioni C, Bindi L, Mauro D, Hålenius U. (2019) Crystal Chemistry of Sulfates from the Apuan Alps (Tuscany, Italy). V. Scordariite, K8(Fe3+0.67□0.33)[Fe3+3O(SO4)6(H2O)3]2(H2O)11: A New Metavoltine-Related Mineral. Minerals. 9(11):702; Mauro, D. (2020). Crystal-chemistry of secondary minerals of thallium-rich pyrite from the Apuan Alps (Tuscany, Italy). Plinius, 46, 64-68. |
ⓘ 'K Feldspar' Reference: Biagioni, C., Orlandi, P., Pasero, M. (2009): Ankangite from the Monte Arsiccio mine (Apuan Alps, Tuscany, Italy): occurrence, crystal structure, and classification problems in cryptomelane group minerals. Periodico di Mineralogia, 78(2), 3-11 |
ⓘ Khademite Formula: Al(SO4)F · 5H2O Reference: Biagioni C, Bindi L, Mauro D, Hålenius U. (2019) Crystal Chemistry of Sulfates from the Apuan Alps (Tuscany, Italy). V. Scordariite, K8(Fe3+0.67□0.33)[Fe3+3O(SO4)6(H2O)3]2(H2O)11: A New Metavoltine-Related Mineral. Minerals, 9(11):702; Mauro, D., Biagioni, C., Pasero, M., and Zaccarini, F. (2020) Crystal-chemistry of sulfates from the Apuan Alps, Tuscany, Italy. VIII. New data on khademite, Al(SO4)F(H2O)5. Mineralogical Magazine, 84, 4, 540-546; Mauro, D. (2020). Crystal-chemistry of secondary minerals of thallium-rich pyrite from the Apuan Alps (Tuscany, Italy). Plinius, 46, 64-68. |
ⓘ Krausite Formula: KFe(SO4)2 · H2O Reference: Biagioni C, Bindi L, Mauro D, Hålenius U. (2019) Crystal Chemistry of Sulfates from the Apuan Alps (Tuscany, Italy). V. Scordariite, K8(Fe3+0.67□0.33)[Fe3+3O(SO4)6(H2O)3]2(H2O)11: A New Metavoltine-Related Mineral. Minerals. 9(11):702; Mauro, D. (2020). Crystal-chemistry of secondary minerals of thallium-rich pyrite from the Apuan Alps (Tuscany, Italy). Plinius, 46, 64-68. |
ⓘ Laffittite Formula: AgHgAsS3 Reference: Biagioni, C., Bonaccorsi, E., Moëlo, Y., Orlandi, P. (2014): Mercury-arsenic sulfosalts from Apuan Alps (Tuscany, Italy). II. Aktashite, Cu6Hg3As4S12, and laffittite, AgHgAsS3, from the Monte Arsiccio mine: occurrence and crystal structure. Periodico di Mineralogia, 83, 1-18. |
ⓘ 'Limonite' |
ⓘ Magnanelliite (TL) Formula: K3Fe3+2(SO4)4(OH)(H2O)2 Type Locality: Reference: Biagioni, C., Bindi, L. and Kampf, A.R. (2019) Magnanelliite, IMA 2019-006. CNMNC Newsletter No. 49, June 2019, page xxx; Mineralogical Magazine, 83: 323–328. ; Biagioni C, Bindi L, Mauro D, Hålenius U. (2019) Crystal Chemistry of Sulfates from the Apuan Alps (Tuscany, Italy). V. Scordariite, K8(Fe3+0.67□0.33)[Fe3+3O(SO4)6(H2O)3]2(H2O)11: A New Metavoltine-Related Mineral. Minerals. 9(11):702; Mauro, D. (2020). Crystal-chemistry of secondary minerals of thallium-rich pyrite from the Apuan Alps (Tuscany, Italy). Plinius, 46, 64-68. |
ⓘ Magnetite Formula: Fe2+Fe3+2O4 |
ⓘ Mannardite Formula: Ba(Ti4+6V3+2)O16 Reference: Biagioni, C., Orlandi, P., & Pasero, M. (2008). Ankangite from Monte Arsiccio mine. (Apuan Alps, Tuscany): third world occurrence. Plinius, 34, 212; Biagioni, C., Orlandi, P., & Pasero, M. (2009). Ankangite from the Monte Arsiccio mine (Apuan Alps, Tuscany, Italy): occurrence, crystal structure, and classification problems in cryptomelane group minerals. Periodico di Mineralogia, 78, 3-11. |
ⓘ Mannardite var. Ankangite Formula: Ba(Ti,V3+,Cr)8O16 Reference: Biagioni, C., Orlandi, P., & Pasero, M. (2008). Ankangite from Monte Arsiccio mine. (Apuan Alps, Tuscany): third world occurrence. Plinius, 34, 212; Biagioni, C., Orlandi, P., & Pasero, M. (2009). Ankangite from the Monte Arsiccio mine (Apuan Alps, Tuscany, Italy): occurrence, crystal structure, and classification problems in cryptomelane group minerals. Periodico di Mineralogia, 78, 3-11. |
ⓘ Mapiquiroite (TL) Formula: (Sr,Pb)(U,Y)Fe2(Ti,Fe3+,Cr3+)18O38 Type Locality: Reference: Biagioni, C., Orlandi, P., Pasero, M., Nestola, F. and Bindi, L. (2013) Mapiquiroite, IMA 2013-010. CNMNC Newsletter No. 16, August 2013, page 2703; Mineralogical Magazine, 77, 2695-2709. ; Biagioni, C., Orlandi, P., Pasero, M., Nestola, F., Bindi, L. (2014): Mapiquiroite, (Sr,Pb)(U,Y)Fe2(Ti,Fe3+)18O38, a new member of the crichtonite group from the Apuan Alps, Tuscany, Italy. European Journal of Mineralogy, 26, 427-437. |
ⓘ Melanterite Formula: Fe2+(H2O)6SO4 · H2O Reference: Biagioni C, Bindi L, Mauro D, Hålenius U. (2019) Crystal Chemistry of Sulfates from the Apuan Alps (Tuscany, Italy). V. Scordariite, K8(Fe3+0.67□0.33)[Fe3+3O(SO4)6(H2O)3]2(H2O)11: A New Metavoltine-Related Mineral. Minerals. 9(11):702; Mauro, D. (2020). Crystal-chemistry of secondary minerals of thallium-rich pyrite from the Apuan Alps (Tuscany, Italy). Plinius, 46, 64-68. |
ⓘ Miargyrite Formula: AgSbS2 Reference: Biagioni, C., Moëlo, Y., and Zaccarini, F. (2017) Ferdowsiite from the Monte Arsiccio mine, Apuan Alps, Tuscany (Italy): occurrence and crystal structure. Atti della Società Toscana di Scienze Naturali, Memorie, 124, 5-11. |
ⓘ Mimetite Formula: Pb5(AsO4)3Cl Reference: Collection Lechner Alois |
ⓘ Molybdenite Formula: MoS2 Reference: Collection Lechner Alois |
ⓘ Parapierrotite Formula: TlSb5S8 Reference: Biagioni, C., Moëlo, Y., and Zaccarini, F. (2017) Ferdowsiite from the Monte Arsiccio mine, Apuan Alps, Tuscany (Italy): occurrence and crystal structure. Atti della Società Toscana di Scienze Naturali, Memorie, 124, 5-11. |
ⓘ Polhemusite ? Formula: (Zn,Hg)S Description: Costagliola et al. (1990) wrote: "The presence of a Fe-Zn-Hg sulfide whose optical and compositional (semiquantitative SEM/EDS analysis) properties are like those of polhemusite (LEONARD et al., 1978) is especially noteworthy. Further studies are being carried out to completely describe this mineral; if confirmed, it would be the first finding of polhemusite in Italy." Reference: Costagliola P., Benvenuti M., Tanelli G., Cortecci G.,Lattanzi P., 1990. The barite-pyrite-iron oxides deposit of Monte Arsiccio (Apuan Alps). Boll. Soc. Geol. Ital., 109: 267-277 |
ⓘ Protochabournéite (TL) Formula: Tl2Pb(Sb,As)10S17 Localities: Type Locality: Sant'Olga tunnel, Monte Arsiccio Mine, Sant'Anna di Stazzema, Stazzema, Lucca Province, Tuscany, Italy Reference: Orlandi, P., Biagioni, C.,Bonaccorsi, E., Moëlo, Y. and Paar, W.H.(2011): Protochabouréite, IMA 2011-054.CNMNC Newsletter No. 11, December 2011, page 2888; Mineralogical Magazine, 75, 2887-2893; Orlandi, P., Biagioni, C., Moëlo, Y., Bonaccorsi, E., Paar, W.H. (2013): Lead-antimony sulfosalts from Tuscany (Italy). XIII. Protochabournéite, ~ Tl2Pb(Sb9–8As1–2)∑10S17, from the Monte Arsiccio mine: Occurrence, crystal structure and relationship with chabournéite. Canadian Mineralogist, 51, 475-494. |
ⓘ Pyradoketosite (TL) Formula: Ag3SbS3 Type Locality: Reference: Biagioni, C., Bindi, L., Moëlo, Y., Stanley, C.J. and Zaccarini, F. (2020) Pyradoketosite, IMA 2019-132. CNMNC Newsletter No. 55; Mineralogical Magazine, 84, https://doi.org/10.1180/mgm.2020.39 |
ⓘ Pyrite Formula: FeS2 Reference: Biagioni, C., Orlandi, P., Pasero, M. (2009): Ankangite from the Monte Arsiccio mine (Apuan Alps, Tuscany, Italy): occurrence, crystal structure, and classification problems in cryptomelane group minerals. Periodico di Mineralogia, 78(2), 3-11; Biagioni, C., Bonaccorsi, E., Moëlo, Y., & Orlandi, P. (2014). Mercury-arsenic sulfosalts from Apuan Alps (Tuscany, Italy). I. Routhierite,(Cu0. 8Ag0. 2) Hg2Tl (As1. 4Sb0. 6)∑= 2S6, from Monte Arsiccio mine: occurrence and crystal structure. European Journal of Mineralogy, 26(1), 163-170. |
ⓘ Quartz Formula: SiO2 Reference: Biagioni, C., Orlandi, P., Pasero, M. (2009): Ankangite from the Monte Arsiccio mine (Apuan Alps, Tuscany, Italy): occurrence, crystal structure, and classification problems in cryptomelane group minerals. Periodico di Mineralogia, 78(2), 3-11; Biagioni, C., Bonaccorsi, E., Moëlo, Y., & Orlandi, P. (2014). Mercury-arsenic sulfosalts from Apuan Alps (Tuscany, Italy). I. Routhierite,(Cu0. 8Ag0. 2) Hg2Tl (As1. 4Sb0. 6)∑= 2S6, from Monte Arsiccio mine: occurrence and crystal structure. European Journal of Mineralogy, 26(1), 163-170. |
ⓘ Realgar Formula: As4S4 Reference: Biagioni, C., Bonaccorsi, E., Moëlo, Y., & Orlandi, P. (2014). Mercury-arsenic sulfosalts from Apuan Alps (Tuscany, Italy). I. Routhierite,(Cu0. 8Ag0. 2) Hg2Tl (As1. 4Sb0. 6)∑= 2S6, from Monte Arsiccio mine: occurrence and crystal structure. European Journal of Mineralogy, 26(1), 163-170.; Biagioni, C., Moëlo, Y., and Zaccarini, F. (2017) Ferdowsiite from the Monte Arsiccio mine, Apuan Alps, Tuscany (Italy): occurrence and crystal structure. Atti della Società Toscana di Scienze Naturali, Memorie, 124, 5-11. |
ⓘ Robinsonite Formula: Pb4Sb6S13 Localities: Reference: https://www.mindat.org/photo-715423.html
https://www.mindat.org/photo-789397.html
https://www.mindat.org/photo-789395.html |
ⓘ Römerite Formula: Fe2+Fe3+2(SO4)4 · 14H2O Reference: Biagioni C, Bindi L, Mauro D, Hålenius U. (2019) Crystal Chemistry of Sulfates from the Apuan Alps (Tuscany, Italy). V. Scordariite, K8(Fe3+0.67□0.33)[Fe3+3O(SO4)6(H2O)3]2(H2O)11: A New Metavoltine-Related Mineral. Minerals. 9(11):702; Mauro, D. (2020). Crystal-chemistry of secondary minerals of thallium-rich pyrite from the Apuan Alps (Tuscany, Italy). Plinius, 46, 64-68. |
ⓘ Routhierite Formula: Tl(Cu,Ag)(Hg,Zn)2(As,Sb)2S6 Reference: C. Biagioni, E. Bonaccorsi, Y. Moëlo, P. Orlandi & W. Paar (2011): Monte Arsiccio mine: The first thallium ore in Apuan Alps. Plinius 37, 401; Biagioni, C., Bonaccorsi, E., Moëlo, Y., Orlandi, P. (2012): Sb-rich routhierite from Monte Arsiccio mine (Apuan Alps, Tuscany, Italy): occurrence and crystal structure. European Mineralogical Conference Vol. 1, EMC2012-30 (abs.).; Biagioni, C., Bonaccorsi, E., Moëlo, Y., & Orlandi, P. (2014). Mercury-arsenic sulfosalts from Apuan Alps (Tuscany, Italy). I. Routhierite,(Cu0. 8Ag0. 2) Hg2Tl (As1. 4Sb0. 6)∑= 2S6, from Monte Arsiccio mine: occurrence and crystal structure. European Journal of Mineralogy, 26(1), 163-170. |
ⓘ Rouxelite Formula: Cu2HgPb23Sb27S65.5 Reference: Biagioni, C., Moelo, Y. & Orlandi, P. (2014) Lead-antimony sulfosalts from Tuscany (Italy). XV. (Tl-Ag)-bearing rouxelite from Monte Arsiccio mine: occurrence and crystal chemistry. Mineralogical Magazine, 78(3), 651-661. |
ⓘ Scordariite (TL) Formula: K8(Fe3+0.67◻0.33)[Fe3+3O(SO4)6]2 · 14H2O Type Locality: Reference: Biagioni C., Bindi L., Mauro D. (2019): Scordariite, IMA 2019-010. CNMNC
Newsletter No. 50; Mineralogical Magazine: 31, doi: 10.1180/mgm.2019.46; http://forum.amiminerals.it/viewtopic.php?f=5&t=15578&sid=813c77a70706fa166a7b80754bd6a1e5 (visited 23.07.2019); Biagioni C, Bindi L, Mauro D, Hålenius U. (2019) Crystal Chemistry of Sulfates from the Apuan Alps (Tuscany, Italy). V. Scordariite, K8(Fe3+0.67□0.33)[Fe3+3O(SO4)6(H2O)3]2(H2O)11: A New Metavoltine-Related Mineral. Minerals. 9(11):702; Mauro, D. (2020). Crystal-chemistry of secondary minerals of thallium-rich pyrite from the Apuan Alps (Tuscany, Italy). Plinius, 46, 64-68. |
ⓘ Senarmontite Formula: Sb2O3 Reference: Biagioni, C., Moëlo, Y., and Zaccarini, F. (2017) Ferdowsiite from the Monte Arsiccio mine, Apuan Alps, Tuscany (Italy): occurrence and crystal structure. Atti della Società Toscana di Scienze Naturali, Memorie, 124, 5-11. |
ⓘ Siderite Formula: FeCO3 |
ⓘ Spessartine Formula: Mn2+3Al2(SiO4)3 Reference: Leoni L., Orlandi P., 1975. Il granato di M.te Arsiccio. Rend. Soc. Ital. Mineral. Petrol., 31: 73-78. |
ⓘ Sphalerite Formula: ZnS Localities: Reference: http://www.valdicastello.it/miniere.html; Biagioni, C., Orlandi, P., Pasero, M. (2009): Ankangite from the Monte Arsiccio mine (Apuan Alps, Tuscany, Italy): occurrence, crystal structure, and classification problems in cryptomelane group minerals. Periodico di Mineralogia, 78(2), 3-11; Biagioni, C., Bonaccorsi, E., Moëlo, Y., & Orlandi, P. (2014). Mercury-arsenic sulfosalts from Apuan Alps (Tuscany, Italy). I. Routhierite,(Cu0. 8Ag0. 2) Hg2Tl (As1. 4Sb0. 6)∑= 2S6, from Monte Arsiccio mine: occurrence and crystal structure. European Journal of Mineralogy, 26(1), 163-170. |
ⓘ Stibivanite Formula: Sb2VO5 Reference: Biagioni, C., Bonaccorsi, E., Capalbo, C., Merlino, S., Orlandi, P., Pasero, M. & Perchiazzi, N. (2013) Cinque anni di ricerche mineralogichesulle Alpi Apuane - Sinergia fra collezionismo e ricerca scientifica. Giornate di Studio GNM “Nuovi minerali: tra ricerca e collezionismo” Padova, 18 giugno 2013, 48 pp. |
ⓘ Stibnite Formula: Sb2S3 Localities: Reference: Zibaldone di mineralogia italiana – Riv. min. It., Fasc. 3, 1990, pag. 137; Biagioni, C., Bonaccorsi, E., Moëlo, Y., & Orlandi, P. (2014). Mercury-arsenic sulfosalts from Apuan Alps (Tuscany, Italy). I. Routhierite,(Cu0. 8Ag0. 2) Hg2Tl (As1. 4Sb0. 6)∑= 2S6, from Monte Arsiccio mine: occurrence and crystal structure. European Journal of Mineralogy, 26(1), 163-170.; Biagioni, C., Moëlo, Y., and Zaccarini, F. (2017) Ferdowsiite from the Monte Arsiccio mine, Apuan Alps, Tuscany (Italy): occurrence and crystal structure. Atti della Società Toscana di Scienze Naturali, Memorie, 124, 5-11. |
ⓘ 'Tetrahedrite Subgroup' Formula: Cu6(Cu4 C2+2)Sb4S12S Description: Mercury rich Reference: http://www.valdicastello.it/miniere.html; Biagioni, C., Bonaccorsi, E., Moëlo, Y., & Orlandi, P. (2014). Mercury-arsenic sulfosalts from Apuan Alps (Tuscany, Italy). I. Routhierite,(Cu0. 8Ag0. 2) Hg2Tl (As1. 4Sb0. 6)∑= 2S6, from Monte Arsiccio mine: occurrence and crystal structure. European Journal of Mineralogy, 26(1), 163-170. |
ⓘ Valentinite Formula: Sb2O3 Reference: Biagioni, C., Orlandi, P., Pasero, M. (2009): Ankangite from the Monte Arsiccio mine (Apuan Alps, Tuscany, Italy): occurrence, crystal structure, and classification problems in cryptomelane group minerals. Periodico di Mineralogia, 78(2), 3-11 |
ⓘ Voltaite Formula: K2Fe2+5Fe3+3Al(SO4)12 · 18H2O Reference: Biagioni C, Bindi L, Mauro D, Hålenius U. (2019) Crystal Chemistry of Sulfates from the Apuan Alps (Tuscany, Italy). V. Scordariite, K8(Fe3+0.67□0.33)[Fe3+3O(SO4)6(H2O)3]2(H2O)11: A New Metavoltine-Related Mineral. Minerals. 9(11):702; Mauro, D. (2020). Crystal-chemistry of secondary minerals of thallium-rich pyrite from the Apuan Alps (Tuscany, Italy). Plinius, 46, 64-68. |
ⓘ Zinkenite Formula: Pb9Sb22S42 Localities: Reference: Biagioni, C., Orlandi, P., Pasero, M. (2009): Ankangite from the Monte Arsiccio mine (Apuan Alps, Tuscany, Italy): occurrence, crystal structure, and classification problems in cryptomelane group minerals. Periodico di Mineralogia, 78(2), 3-11 |
Gallery:
List of minerals arranged by Strunz 10th Edition classification
Group 2 - Sulphides and Sulfosalts | |||
---|---|---|---|
ⓘ | Aktashite | 2.GA.30 | Cu6Hg3As4S12 |
ⓘ | Andreadiniite (TL) | 2.JB. | CuHgAg7Pb7Sb24S48 |
ⓘ | Arsenopyrite | 2.EB.20 | FeAsS |
ⓘ | Arsiccioite (TL) | 2.GA. | AgHg2Tl(As,Sb)2S6 |
ⓘ | Boscardinite (TL) | 2.HD. | TlPb4(Sb7As2)S18 |
ⓘ | Chabournéite | 2.HC.05e | Tl4Pb2(Sb,As)20S34 |
ⓘ | Chalcopyrite | 2.CB.10a | CuFeS2 |
ⓘ | Chovanite | 2.JB.35e | Pb15-2xSb14+2xS36Ox (x ~ 0.2) |
ⓘ | Galena | 2.CD.10 | PbS |
ⓘ | Gersdorffite | 2.EB.25 | NiAsS |
ⓘ | Laffittite | 2.GA.35 | AgHgAsS3 |
ⓘ | Miargyrite | 2.HA.10 | AgSbS2 |
ⓘ | Molybdenite | 2.EA.30 | MoS2 |
ⓘ | Parapierrotite | 2.HC.05f | TlSb5S8 |
ⓘ | Polhemusite ? | 2.CB.05c | (Zn,Hg)S |
ⓘ | Pyrite | 2.EB.05a | FeS2 |
ⓘ | Realgar | 2.FA.15a | As4S4 |
ⓘ | Robinsonite | 2.HC.20 | Pb4Sb6S13 |
ⓘ | Routhierite | 2.GA.40 | Tl(Cu,Ag)(Hg,Zn)2(As,Sb)2S6 |
ⓘ | Rouxelite | 2.JB.25j | Cu2HgPb23Sb27S65.5 |
ⓘ | Sphalerite | 2.CB.05a | ZnS |
ⓘ | Stibnite | 2.DB.05 | Sb2S3 |
ⓘ | 'Tetrahedrite Subgroup' | 2.GB.05 | Cu6(Cu4C2+2)Sb4S12S |
ⓘ | Zinkenite | 2.JB.35a | Pb9Sb22S42 |
Group 4 - Oxides and Hydroxides | |||
ⓘ | Anatase | 4.DD.05 | TiO2 |
ⓘ | Derbylite | 4.JB.55 | Fe3+4Ti3Sb3+O13(OH) |
ⓘ | Graeserite | 4.JB.55 | (Fe3+,Ti)4Ti3AsO13(OH) |
ⓘ | Hematite | 4.CB.05 | Fe2O3 |
ⓘ | Magnetite | 4.BB.05 | Fe2+Fe3+2O4 |
ⓘ | Mannardite | 4.DK.05b | Ba(Ti4+6V3+2)O16 |
ⓘ | var. Ankangite | 4.DK.05b | Ba(Ti,V3+,Cr)8O16 |
ⓘ | Mapiquiroite (TL) | 4.00. | (Sr,Pb)(U,Y)Fe2(Ti,Fe3+,Cr3+)18O38 |
ⓘ | Quartz | 4.DA.05 | SiO2 |
ⓘ | Senarmontite | 4.CB.50 | Sb2O3 |
ⓘ | Stibivanite | 4.JA.55 | Sb2VO5 |
ⓘ | Valentinite | 4.CB.55 | Sb2O3 |
Group 5 - Nitrates and Carbonates | |||
ⓘ | Aragonite | 5.AB.15 | CaCO3 |
ⓘ | Benstonite | 5.AB.55 | Ba6Ca6Mg(CO3)13 |
ⓘ | Calcite | 5.AB.05 | CaCO3 |
ⓘ | Cerussite | 5.AB.15 | PbCO3 |
ⓘ | Dolomite | 5.AB.10 | CaMg(CO3)2 |
ⓘ | Siderite | 5.AB.05 | FeCO3 |
Group 7 - Sulphates, Chromates, Molybdates and Tungstates | |||
ⓘ | Alum-(K) | 7.CC.20 | KAl(SO4)2 · 12H2O |
ⓘ | Alunogen | 7.CB.45 | Al2(SO4)3 · 17H2O |
ⓘ | Baryte | 7.AD.35 | BaSO4 |
ⓘ | Copiapite | 7.DB.35 | Fe2+Fe3+4(SO4)6(OH)2 · 20H2O |
ⓘ | Coquimbite | 7.CB.55 | AlFe3(SO4)6(H2O)12 · 6H2O |
ⓘ | Epsomite | 7.CB.40 | MgSO4 · 7H2O |
ⓘ | Goldichite | 7.CC.40 | KFe(SO4)2 · 4H2O |
ⓘ | Gypsum | 7.CD.40 | CaSO4 · 2H2O |
ⓘ | Halotrichite | 7.CB.85 | FeAl2(SO4)4 · 22H2O |
ⓘ | Jarosite | 7.BC.10 | KFe3+3(SO4)2(OH)6 |
ⓘ | Khademite | 7.DB.10 | Al(SO4)F · 5H2O |
ⓘ | Krausite | 7.CC.05 | KFe(SO4)2 · H2O |
ⓘ | Melanterite | 7.CB.35 | Fe2+(H2O)6SO4 · H2O |
ⓘ | Römerite | 7.CB.75 | Fe2+Fe3+2(SO4)4 · 14H2O |
ⓘ | Voltaite | 7.CC.25 | K2Fe2+5Fe3+3Al(SO4)12 · 18H2O |
Group 8 - Phosphates, Arsenates and Vanadates | |||
ⓘ | Annabergite | 8.CE.40 | Ni3(AsO4)2 · 8H2O |
ⓘ | Destinezite | 8.DB.05 | Fe3+2(PO4)(SO4)(OH) · 6H2O |
ⓘ | Hörnesite | 8.CE.40 | Mg3(AsO4)2 · 8H2O |
ⓘ | Mimetite | 8.BN.05 | Pb5(AsO4)3Cl |
Group 9 - Silicates | |||
ⓘ | Beryl | 9.CJ.05 | Be3Al2(Si6O18) |
ⓘ | var. Emerald | 9.CJ.05 | Be3Al2(Si6O18) |
ⓘ | Cymrite | 9.EG.05 | BaAl2Si2(O,OH)8 · H2O |
ⓘ | Fluorophlogopite | 9.EC.20 | KMg3(Si3Al)O10F2 |
ⓘ | Spessartine | 9.AD.25 | Mn2+3Al2(SiO4)3 |
Unclassified Minerals, Rocks, etc. | |||
ⓘ | 'Andorite' | - | AgPbSb3S6 |
ⓘ | 'Apatite' | - | Ca5(PO4)3(Cl/F/OH) |
ⓘ | Bianchiniite (TL) | - | Ba2(TiV)(As2O5)2OF |
ⓘ | Ferdowsiite | - | Ag8(Sb5As3)S16 |
ⓘ | Giacovazzoite (TL) | - | K5Fe3+3O(SO4)6 · 10H2O |
ⓘ | 'K Feldspar' | - | |
ⓘ | 'Limonite' | - | |
ⓘ | Magnanelliite (TL) | - | K3Fe3+2(SO4)4(OH)(H2O)2 |
ⓘ | Protochabournéite (TL) | - | Tl2Pb(Sb,As)10S17 |
ⓘ | Pyradoketosite (TL) | - | Ag3SbS3 |
ⓘ | Scordariite (TL) | - | K8(Fe3+0.67◻0.33)[Fe3+3O(SO4)6]2 · 14H2O |
List of minerals arranged by Dana 8th Edition classification
Group 2 - SULFIDES | |||
---|---|---|---|
AmXp, with m:p = 1:1 | |||
ⓘ | Galena | 2.8.1.1 | PbS |
ⓘ | Polhemusite ? | 2.8.3.1 | (Zn,Hg)S |
ⓘ | Realgar | 2.8.21.1 | As4S4 |
ⓘ | Sphalerite | 2.8.2.1 | ZnS |
AmBnXp, with (m+n):p = 1:1 | |||
ⓘ | Chalcopyrite | 2.9.1.1 | CuFeS2 |
AmBnXp, with (m+n):p = 2:3 | |||
ⓘ | Stibnite | 2.11.2.1 | Sb2S3 |
AmBnXp, with (m+n):p = 1:2 | |||
ⓘ | Arsenopyrite | 2.12.4.1 | FeAsS |
ⓘ | Gersdorffite | 2.12.3.2 | NiAsS |
ⓘ | Molybdenite | 2.12.10.1 | MoS2 |
ⓘ | Pyrite | 2.12.1.1 | FeS2 |
Group 3 - SULFOSALTS | |||
3 <ø < 4 | |||
ⓘ | 'Tetrahedrite Subgroup' | 3.3.6.1 | Cu6(Cu4 C2+2)Sb4S12S |
ø = 3 | |||
ⓘ | Aktashite | 3.4.13.2 | Cu6Hg3As4S12 |
ⓘ | Laffittite | 3.4.10.2 | AgHgAsS3 |
ⓘ | Routhierite | 3.4.11.1 | Tl(Cu,Ag)(Hg,Zn)2(As,Sb)2S6 |
2 < ø < 2.49 | |||
ⓘ | Robinsonite | 3.6.16.1 | Pb4Sb6S13 |
ø = 2 | |||
ⓘ | Miargyrite | 3.7.3.2 | AgSbS2 |
1 < ø < 2 | |||
ⓘ | Chabournéite | 3.8.12.1 | Tl4Pb2(Sb,As)20S34 |
ⓘ | Parapierrotite | 3.8.14.1 | TlSb5S8 |
ⓘ | Zinkenite | 3.8.1.1 | Pb9Sb22S42 |
ⓘ | Chovanite | 3.10.4. | Pb15-2xSb14+2xS36Ox (x ~ 0.2) |
Group 4 - SIMPLE OXIDES | |||
A2X3 | |||
ⓘ | Hematite | 4.3.1.2 | Fe2O3 |
ⓘ | Senarmontite | 4.3.9.2 | Sb2O3 |
ⓘ | Valentinite | 4.3.11.1 | Sb2O3 |
AX2 | |||
ⓘ | Anatase | 4.4.4.1 | TiO2 |
Group 7 - MULTIPLE OXIDES | |||
AB2X4 | |||
ⓘ | Magnetite | 7.2.2.3 | Fe2+Fe3+2O4 |
AB8X16 | |||
ⓘ | Mannardite | 7.9.5.1 | Ba(Ti4+6V3+2)O16 |
Group 14 - ANHYDROUS NORMAL CARBONATES | |||
A(XO3) | |||
ⓘ | Calcite | 14.1.1.1 | CaCO3 |
ⓘ | Cerussite | 14.1.3.4 | PbCO3 |
ⓘ | Siderite | 14.1.1.3 | FeCO3 |
AB(XO3)2 | |||
ⓘ | Benstonite | 14.2.3.1 | Ba6Ca6Mg(CO3)13 |
ⓘ | Dolomite | 14.2.1.1 | CaMg(CO3)2 |
Group 28 - ANHYDROUS ACID AND NORMAL SULFATES | |||
AXO4 | |||
ⓘ | Baryte | 28.3.1.1 | BaSO4 |
Group 29 - HYDRATED ACID AND NORMAL SULFATES | |||
AB(XO4)2·xH2O | |||
ⓘ | Alum-(K) | 29.5.5.1 | KAl(SO4)2 · 12H2O |
ⓘ | Goldichite | 29.5.2.1 | KFe(SO4)2 · 4H2O |
ⓘ | Krausite | 29.5.1.1 | KFe(SO4)2 · H2O |
AXO4·xH2O | |||
ⓘ | Epsomite | 29.6.11.1 | MgSO4 · 7H2O |
ⓘ | Gypsum | 29.6.3.1 | CaSO4 · 2H2O |
ⓘ | Melanterite | 29.6.10.1 | Fe2+(H2O)6SO4 · H2O |
AB2(XO4)4·H2O | |||
ⓘ | Halotrichite | 29.7.3.2 | FeAl2(SO4)4 · 22H2O |
ⓘ | Römerite | 29.7.2.1 | Fe2+Fe3+2(SO4)4 · 14H2O |
A2(XO4)3·H2O | |||
ⓘ | Alunogen | 29.8.6.1 | Al2(SO4)3 · 17H2O |
ⓘ | Coquimbite | 29.8.3.1 | AlFe3(SO4)6(H2O)12 · 6H2O |
Miscellaneous | |||
ⓘ | Voltaite | 29.9.1.1 | K2Fe2+5Fe3+3Al(SO4)12 · 18H2O |
Group 30 - ANHYDROUS SULFATES CONTAINING HYDROXYL OR HALOGEN | |||
(AB)2(XO4)Zq | |||
ⓘ | Jarosite | 30.2.5.1 | KFe3+ 3(SO4)2(OH)6 |
Group 31 - HYDRATED SULFATES CONTAINING HYDROXYL OR HALOGEN | |||
(AB)(XO4)Zq·xH2O | |||
ⓘ | Khademite | 31.9.11.1 | Al(SO4)F · 5H2O |
Miscellaneous | |||
ⓘ | Copiapite | 31.10.5.1 | Fe2+Fe3+4(SO4)6(OH)2 · 20H2O |
Group 40 - HYDRATED NORMAL PHOSPHATES,ARSENATES AND VANADATES | |||
A3(XO4)2·xH2O | |||
ⓘ | Annabergite | 40.3.6.4 | Ni3(AsO4)2 · 8H2O |
ⓘ | Hörnesite | 40.3.6.7 | Mg3(AsO4)2 · 8H2O |
Group 41 - ANHYDROUS PHOSPHATES, ETC.CONTAINING HYDROXYL OR HALOGEN | |||
A5(XO4)3Zq | |||
ⓘ | Mimetite | 41.8.4.2 | Pb5(AsO4)3Cl |
Group 45 - ACID AND NORMAL ANTIMONITES AND ARSENITES | |||
Miscellaneous | |||
ⓘ | Stibivanite | 45.1.11.2 | Sb2VO5 |
Group 46 - ANTIMONITES AND ARSENITES CONTAINING HYDROXYL OR HALOGEN | |||
Miscellaneous | |||
ⓘ | Derbylite | 46.2.3.2 | Fe3+4Ti3Sb3+O13(OH) |
Group 51 - NESOSILICATES Insular SiO4 Groups Only | |||
Insular SiO4 Groups Only with cations in [6] and >[6] coordination | |||
ⓘ | Spessartine | 51.4.3a.3 | Mn2+3Al2(SiO4)3 |
Group 61 - CYCLOSILICATES Six-Membered Rings | |||
Six-Membered Rings with [Si6O18] rings; possible (OH) and Al substitution | |||
ⓘ | Beryl | 61.1.1.1 | Be3Al2(Si6O18) |
Group 75 - TECTOSILICATES Si Tetrahedral Frameworks | |||
Si Tetrahedral Frameworks - SiO2 with [4] coordinated Si | |||
ⓘ | Quartz | 75.1.3.1 | SiO2 |
Group 78 - Unclassified Silicates | |||
Miscellaneous | |||
ⓘ | Cymrite | 78.1.3.1 | BaAl2Si2(O,OH)8 · H2O |
Unclassified Minerals, Mixtures, etc. | |||
ⓘ | 'Andorite' | - | AgPbSb3S6 |
ⓘ | Andreadiniite (TL) | - | CuHgAg7Pb7Sb24S48 |
ⓘ | 'Apatite' | - | Ca5(PO4)3(Cl/F/OH) |
ⓘ | Aragonite | - | CaCO3 |
ⓘ | Arsiccioite (TL) | - | AgHg2Tl(As,Sb)2S6 |
ⓘ | Beryl var. Emerald | - | Be3Al2(Si6O18) |
ⓘ | Bianchiniite (TL) | - | Ba2(TiV)(As2O5)2OF |
ⓘ | Boscardinite (TL) | - | TlPb4(Sb7As2)S18 |
ⓘ | Destinezite | - | Fe3+2(PO4)(SO4)(OH) · 6H2O |
ⓘ | Ferdowsiite | - | Ag8(Sb5As3)S16 |
ⓘ | Fluorophlogopite | - | KMg3(Si3Al)O10F2 |
ⓘ | Giacovazzoite (TL) | - | K5Fe3+3O(SO4)6 · 10H2O |
ⓘ | Graeserite | - | (Fe3+ ,Ti)4Ti3AsO13(OH) |
ⓘ | 'K Feldspar' | - | |
ⓘ | 'Limonite' | - | |
ⓘ | Magnanelliite (TL) | - | K3Fe3+2(SO4)4(OH)(H2O)2 |
ⓘ | Mannardite var. Ankangite | - | Ba(Ti,V3+,Cr)8O16 |
ⓘ | Mapiquiroite (TL) | - | (Sr,Pb)(U,Y)Fe2(Ti,Fe3+,Cr3+)18O38 |
ⓘ | Protochabournéite (TL) | - | Tl2Pb(Sb,As)10S17 |
ⓘ | Pyradoketosite (TL) | - | Ag3SbS3 |
ⓘ | Rouxelite | - | Cu2HgPb23Sb27S65.5 |
ⓘ | Scordariite (TL) | - | K8(Fe3+0.67◻0.33)[Fe3+3O(SO4)6]2 · 14H2O |
List of minerals for each chemical element
H | Hydrogen | |
---|---|---|
H | ⓘ Giacovazzoite | K5Fe33+O(SO4)6 · 10H2O |
H | ⓘ Magnanelliite | K3Fe23+(SO4)4(OH)(H2O)2 |
H | ⓘ Scordariite | K8(Fe3+0.67◻0.33)[Fe33+O(SO4)6]2 · 14H2O |
H | ⓘ Graeserite | (Fe3+,Ti)4Ti3AsO13(OH) |
H | ⓘ Apatite | Ca5(PO4)3(Cl/F/OH) |
H | ⓘ Cymrite | BaAl2Si2(O,OH)8 · H2O |
H | ⓘ Derbylite | Fe43+Ti3Sb3+O13(OH) |
H | ⓘ Annabergite | Ni3(AsO4)2 · 8H2O |
H | ⓘ Hörnesite | Mg3(AsO4)2 · 8H2O |
H | ⓘ Alum-(K) | KAl(SO4)2 · 12H2O |
H | ⓘ Alunogen | Al2(SO4)3 · 17H2O |
H | ⓘ Copiapite | Fe2+Fe43+(SO4)6(OH)2 · 20H2O |
H | ⓘ Coquimbite | AlFe3(SO4)6(H2O)12 · 6H2O |
H | ⓘ Goldichite | KFe(SO4)2 · 4H2O |
H | ⓘ Gypsum | CaSO4 · 2H2O |
H | ⓘ Halotrichite | FeAl2(SO4)4 · 22H2O |
H | ⓘ Jarosite | KFe3+ 3(SO4)2(OH)6 |
H | ⓘ Khademite | Al(SO4)F · 5H2O |
H | ⓘ Krausite | KFe(SO4)2 · H2O |
H | ⓘ Melanterite | Fe2+(H2O)6SO4 · H2O |
H | ⓘ Römerite | Fe2+Fe23+(SO4)4 · 14H2O |
H | ⓘ Voltaite | K2Fe52+Fe33+Al(SO4)12 · 18H2O |
H | ⓘ Destinezite | Fe23+(PO4)(SO4)(OH) · 6H2O |
H | ⓘ Epsomite | MgSO4 · 7H2O |
Be | Beryllium | |
Be | ⓘ Beryl var. Emerald | Be3Al2(Si6O18) |
Be | ⓘ Beryl | Be3Al2(Si6O18) |
C | Carbon | |
C | ⓘ Aragonite | CaCO3 |
C | ⓘ Calcite | CaCO3 |
C | ⓘ Siderite | FeCO3 |
C | ⓘ Dolomite | CaMg(CO3)2 |
C | ⓘ Benstonite | Ba6Ca6Mg(CO3)13 |
C | ⓘ Cerussite | PbCO3 |
O | Oxygen | |
O | ⓘ Mapiquiroite | (Sr,Pb)(U,Y)Fe2(Ti,Fe3+,Cr3+)18O38 |
O | ⓘ Giacovazzoite | K5Fe33+O(SO4)6 · 10H2O |
O | ⓘ Magnanelliite | K3Fe23+(SO4)4(OH)(H2O)2 |
O | ⓘ Scordariite | K8(Fe3+0.67◻0.33)[Fe33+O(SO4)6]2 · 14H2O |
O | ⓘ Bianchiniite | Ba2(TiV)(As2O5)2OF |
O | ⓘ Graeserite | (Fe3+,Ti)4Ti3AsO13(OH) |
O | ⓘ Hematite | Fe2O3 |
O | ⓘ Aragonite | CaCO3 |
O | ⓘ Calcite | CaCO3 |
O | ⓘ Magnetite | Fe2+Fe23+O4 |
O | ⓘ Siderite | FeCO3 |
O | ⓘ Spessartine | Mn32+Al2(SiO4)3 |
O | ⓘ Baryte | BaSO4 |
O | ⓘ Beryl var. Emerald | Be3Al2(Si6O18) |
O | ⓘ Mannardite var. Ankangite | Ba(Ti,V3+,Cr)8O16 |
O | ⓘ Quartz | SiO2 |
O | ⓘ Valentinite | Sb2O3 |
O | ⓘ Dolomite | CaMg(CO3)2 |
O | ⓘ Anatase | TiO2 |
O | ⓘ Apatite | Ca5(PO4)3(Cl/F/OH) |
O | ⓘ Cymrite | BaAl2Si2(O,OH)8 · H2O |
O | ⓘ Benstonite | Ba6Ca6Mg(CO3)13 |
O | ⓘ Chovanite | Pb15-2xSb14+2xS36Ox (x ~ 0.2) |
O | ⓘ Stibivanite | Sb2VO5 |
O | ⓘ Derbylite | Fe43+Ti3Sb3+O13(OH) |
O | ⓘ Fluorophlogopite | KMg3(Si3Al)O10F2 |
O | ⓘ Beryl | Be3Al2(Si6O18) |
O | ⓘ Mannardite | Ba(Ti64+V23+)O16 |
O | ⓘ Annabergite | Ni3(AsO4)2 · 8H2O |
O | ⓘ Cerussite | PbCO3 |
O | ⓘ Mimetite | Pb5(AsO4)3Cl |
O | ⓘ Senarmontite | Sb2O3 |
O | ⓘ Hörnesite | Mg3(AsO4)2 · 8H2O |
O | ⓘ Alum-(K) | KAl(SO4)2 · 12H2O |
O | ⓘ Alunogen | Al2(SO4)3 · 17H2O |
O | ⓘ Copiapite | Fe2+Fe43+(SO4)6(OH)2 · 20H2O |
O | ⓘ Coquimbite | AlFe3(SO4)6(H2O)12 · 6H2O |
O | ⓘ Goldichite | KFe(SO4)2 · 4H2O |
O | ⓘ Gypsum | CaSO4 · 2H2O |
O | ⓘ Halotrichite | FeAl2(SO4)4 · 22H2O |
O | ⓘ Jarosite | KFe3+ 3(SO4)2(OH)6 |
O | ⓘ Khademite | Al(SO4)F · 5H2O |
O | ⓘ Krausite | KFe(SO4)2 · H2O |
O | ⓘ Melanterite | Fe2+(H2O)6SO4 · H2O |
O | ⓘ Römerite | Fe2+Fe23+(SO4)4 · 14H2O |
O | ⓘ Voltaite | K2Fe52+Fe33+Al(SO4)12 · 18H2O |
O | ⓘ Destinezite | Fe23+(PO4)(SO4)(OH) · 6H2O |
O | ⓘ Epsomite | MgSO4 · 7H2O |
F | Fluorine | |
F | ⓘ Bianchiniite | Ba2(TiV)(As2O5)2OF |
F | ⓘ Apatite | Ca5(PO4)3(Cl/F/OH) |
F | ⓘ Fluorophlogopite | KMg3(Si3Al)O10F2 |
F | ⓘ Khademite | Al(SO4)F · 5H2O |
Mg | Magnesium | |
Mg | ⓘ Dolomite | CaMg(CO3)2 |
Mg | ⓘ Benstonite | Ba6Ca6Mg(CO3)13 |
Mg | ⓘ Fluorophlogopite | KMg3(Si3Al)O10F2 |
Mg | ⓘ Hörnesite | Mg3(AsO4)2 · 8H2O |
Mg | ⓘ Epsomite | MgSO4 · 7H2O |
Al | Aluminium | |
Al | ⓘ Spessartine | Mn32+Al2(SiO4)3 |
Al | ⓘ Beryl var. Emerald | Be3Al2(Si6O18) |
Al | ⓘ Cymrite | BaAl2Si2(O,OH)8 · H2O |
Al | ⓘ Fluorophlogopite | KMg3(Si3Al)O10F2 |
Al | ⓘ Beryl | Be3Al2(Si6O18) |
Al | ⓘ Alum-(K) | KAl(SO4)2 · 12H2O |
Al | ⓘ Alunogen | Al2(SO4)3 · 17H2O |
Al | ⓘ Coquimbite | AlFe3(SO4)6(H2O)12 · 6H2O |
Al | ⓘ Halotrichite | FeAl2(SO4)4 · 22H2O |
Al | ⓘ Khademite | Al(SO4)F · 5H2O |
Al | ⓘ Voltaite | K2Fe52+Fe33+Al(SO4)12 · 18H2O |
Si | Silicon | |
Si | ⓘ Spessartine | Mn32+Al2(SiO4)3 |
Si | ⓘ Beryl var. Emerald | Be3Al2(Si6O18) |
Si | ⓘ Quartz | SiO2 |
Si | ⓘ Cymrite | BaAl2Si2(O,OH)8 · H2O |
Si | ⓘ Fluorophlogopite | KMg3(Si3Al)O10F2 |
Si | ⓘ Beryl | Be3Al2(Si6O18) |
P | Phosphorus | |
P | ⓘ Apatite | Ca5(PO4)3(Cl/F/OH) |
P | ⓘ Destinezite | Fe23+(PO4)(SO4)(OH) · 6H2O |
S | Sulfur | |
S | ⓘ Protochabournéite | Tl2Pb(Sb,As)10S17 |
S | ⓘ Boscardinite | TlPb4(Sb7As2)S18 |
S | ⓘ Arsiccioite | AgHg2Tl(As,Sb)2S6 |
S | ⓘ Andreadiniite | CuHgAg7Pb7Sb24S48 |
S | ⓘ Giacovazzoite | K5Fe33+O(SO4)6 · 10H2O |
S | ⓘ Magnanelliite | K3Fe23+(SO4)4(OH)(H2O)2 |
S | ⓘ Scordariite | K8(Fe3+0.67◻0.33)[Fe33+O(SO4)6]2 · 14H2O |
S | ⓘ Pyradoketosite | Ag3SbS3 |
S | ⓘ Arsenopyrite | FeAsS |
S | ⓘ Pyrite | FeS2 |
S | ⓘ Sphalerite | ZnS |
S | ⓘ Galena | PbS |
S | ⓘ Stibnite | Sb2S3 |
S | ⓘ Gersdorffite | NiAsS |
S | ⓘ Chalcopyrite | CuFeS2 |
S | ⓘ Baryte | BaSO4 |
S | ⓘ Tetrahedrite Subgroup | Cu6(Cu4 C22+)Sb4S12S |
S | ⓘ Zinkenite | Pb9Sb22S42 |
S | ⓘ Routhierite | Tl(Cu,Ag)(Hg,Zn)2(As,Sb)2S6 |
S | ⓘ Aktashite | Cu6Hg3As4S12 |
S | ⓘ Laffittite | AgHgAsS3 |
S | ⓘ Rouxelite | Cu2HgPb23Sb27S65.5 |
S | ⓘ Chovanite | Pb15-2xSb14+2xS36Ox (x ~ 0.2) |
S | ⓘ Andorite | AgPbSb3S6 |
S | ⓘ Realgar | As4S4 |
S | ⓘ Molybdenite | MoS2 |
S | ⓘ Ferdowsiite | Ag8(Sb5As3)S16 |
S | ⓘ Chabournéite | Tl4Pb2(Sb,As)20S34 |
S | ⓘ Parapierrotite | TlSb5S8 |
S | ⓘ Miargyrite | AgSbS2 |
S | ⓘ Alum-(K) | KAl(SO4)2 · 12H2O |
S | ⓘ Alunogen | Al2(SO4)3 · 17H2O |
S | ⓘ Copiapite | Fe2+Fe43+(SO4)6(OH)2 · 20H2O |
S | ⓘ Coquimbite | AlFe3(SO4)6(H2O)12 · 6H2O |
S | ⓘ Goldichite | KFe(SO4)2 · 4H2O |
S | ⓘ Gypsum | CaSO4 · 2H2O |
S | ⓘ Halotrichite | FeAl2(SO4)4 · 22H2O |
S | ⓘ Jarosite | KFe3+ 3(SO4)2(OH)6 |
S | ⓘ Khademite | Al(SO4)F · 5H2O |
S | ⓘ Krausite | KFe(SO4)2 · H2O |
S | ⓘ Melanterite | Fe2+(H2O)6SO4 · H2O |
S | ⓘ Römerite | Fe2+Fe23+(SO4)4 · 14H2O |
S | ⓘ Voltaite | K2Fe52+Fe33+Al(SO4)12 · 18H2O |
S | ⓘ Robinsonite | Pb4Sb6S13 |
S | ⓘ Destinezite | Fe23+(PO4)(SO4)(OH) · 6H2O |
S | ⓘ Epsomite | MgSO4 · 7H2O |
S | ⓘ Polhemusite | (Zn,Hg)S |
Cl | Chlorine | |
Cl | ⓘ Apatite | Ca5(PO4)3(Cl/F/OH) |
Cl | ⓘ Mimetite | Pb5(AsO4)3Cl |
K | Potassium | |
K | ⓘ Giacovazzoite | K5Fe33+O(SO4)6 · 10H2O |
K | ⓘ Magnanelliite | K3Fe23+(SO4)4(OH)(H2O)2 |
K | ⓘ Scordariite | K8(Fe3+0.67◻0.33)[Fe33+O(SO4)6]2 · 14H2O |
K | ⓘ Fluorophlogopite | KMg3(Si3Al)O10F2 |
K | ⓘ Alum-(K) | KAl(SO4)2 · 12H2O |
K | ⓘ Goldichite | KFe(SO4)2 · 4H2O |
K | ⓘ Jarosite | KFe3+ 3(SO4)2(OH)6 |
K | ⓘ Krausite | KFe(SO4)2 · H2O |
K | ⓘ Voltaite | K2Fe52+Fe33+Al(SO4)12 · 18H2O |
Ca | Calcium | |
Ca | ⓘ Aragonite | CaCO3 |
Ca | ⓘ Calcite | CaCO3 |
Ca | ⓘ Dolomite | CaMg(CO3)2 |
Ca | ⓘ Apatite | Ca5(PO4)3(Cl/F/OH) |
Ca | ⓘ Benstonite | Ba6Ca6Mg(CO3)13 |
Ca | ⓘ Gypsum | CaSO4 · 2H2O |
Ti | Titanium | |
Ti | ⓘ Mapiquiroite | (Sr,Pb)(U,Y)Fe2(Ti,Fe3+,Cr3+)18O38 |
Ti | ⓘ Bianchiniite | Ba2(TiV)(As2O5)2OF |
Ti | ⓘ Graeserite | (Fe3+,Ti)4Ti3AsO13(OH) |
Ti | ⓘ Mannardite var. Ankangite | Ba(Ti,V3+,Cr)8O16 |
Ti | ⓘ Anatase | TiO2 |
Ti | ⓘ Derbylite | Fe43+Ti3Sb3+O13(OH) |
Ti | ⓘ Mannardite | Ba(Ti64+V23+)O16 |
V | Vanadium | |
V | ⓘ Bianchiniite | Ba2(TiV)(As2O5)2OF |
V | ⓘ Mannardite var. Ankangite | Ba(Ti,V3+,Cr)8O16 |
V | ⓘ Stibivanite | Sb2VO5 |
V | ⓘ Mannardite | Ba(Ti64+V23+)O16 |
Cr | Chromium | |
Cr | ⓘ Mapiquiroite | (Sr,Pb)(U,Y)Fe2(Ti,Fe3+,Cr3+)18O38 |
Cr | ⓘ Mannardite var. Ankangite | Ba(Ti,V3+,Cr)8O16 |
Mn | Manganese | |
Mn | ⓘ Spessartine | Mn32+Al2(SiO4)3 |
Fe | Iron | |
Fe | ⓘ Mapiquiroite | (Sr,Pb)(U,Y)Fe2(Ti,Fe3+,Cr3+)18O38 |
Fe | ⓘ Giacovazzoite | K5Fe33+O(SO4)6 · 10H2O |
Fe | ⓘ Magnanelliite | K3Fe23+(SO4)4(OH)(H2O)2 |
Fe | ⓘ Scordariite | K8(Fe3+0.67◻0.33)[Fe33+O(SO4)6]2 · 14H2O |
Fe | ⓘ Graeserite | (Fe3+,Ti)4Ti3AsO13(OH) |
Fe | ⓘ Arsenopyrite | FeAsS |
Fe | ⓘ Pyrite | FeS2 |
Fe | ⓘ Hematite | Fe2O3 |
Fe | ⓘ Magnetite | Fe2+Fe23+O4 |
Fe | ⓘ Siderite | FeCO3 |
Fe | ⓘ Chalcopyrite | CuFeS2 |
Fe | ⓘ Derbylite | Fe43+Ti3Sb3+O13(OH) |
Fe | ⓘ Copiapite | Fe2+Fe43+(SO4)6(OH)2 · 20H2O |
Fe | ⓘ Coquimbite | AlFe3(SO4)6(H2O)12 · 6H2O |
Fe | ⓘ Goldichite | KFe(SO4)2 · 4H2O |
Fe | ⓘ Halotrichite | FeAl2(SO4)4 · 22H2O |
Fe | ⓘ Jarosite | KFe3+ 3(SO4)2(OH)6 |
Fe | ⓘ Krausite | KFe(SO4)2 · H2O |
Fe | ⓘ Melanterite | Fe2+(H2O)6SO4 · H2O |
Fe | ⓘ Römerite | Fe2+Fe23+(SO4)4 · 14H2O |
Fe | ⓘ Voltaite | K2Fe52+Fe33+Al(SO4)12 · 18H2O |
Fe | ⓘ Destinezite | Fe23+(PO4)(SO4)(OH) · 6H2O |
Ni | Nickel | |
Ni | ⓘ Gersdorffite | NiAsS |
Ni | ⓘ Annabergite | Ni3(AsO4)2 · 8H2O |
Cu | Copper | |
Cu | ⓘ Andreadiniite | CuHgAg7Pb7Sb24S48 |
Cu | ⓘ Chalcopyrite | CuFeS2 |
Cu | ⓘ Tetrahedrite Subgroup | Cu6(Cu4 C22+)Sb4S12S |
Cu | ⓘ Routhierite | Tl(Cu,Ag)(Hg,Zn)2(As,Sb)2S6 |
Cu | ⓘ Aktashite | Cu6Hg3As4S12 |
Cu | ⓘ Rouxelite | Cu2HgPb23Sb27S65.5 |
Zn | Zinc | |
Zn | ⓘ Sphalerite | ZnS |
Zn | ⓘ Polhemusite | (Zn,Hg)S |
As | Arsenic | |
As | ⓘ Protochabournéite | Tl2Pb(Sb,As)10S17 |
As | ⓘ Boscardinite | TlPb4(Sb7As2)S18 |
As | ⓘ Arsiccioite | AgHg2Tl(As,Sb)2S6 |
As | ⓘ Bianchiniite | Ba2(TiV)(As2O5)2OF |
As | ⓘ Graeserite | (Fe3+,Ti)4Ti3AsO13(OH) |
As | ⓘ Arsenopyrite | FeAsS |
As | ⓘ Gersdorffite | NiAsS |
As | ⓘ Routhierite | Tl(Cu,Ag)(Hg,Zn)2(As,Sb)2S6 |
As | ⓘ Aktashite | Cu6Hg3As4S12 |
As | ⓘ Laffittite | AgHgAsS3 |
As | ⓘ Realgar | As4S4 |
As | ⓘ Annabergite | Ni3(AsO4)2 · 8H2O |
As | ⓘ Mimetite | Pb5(AsO4)3Cl |
As | ⓘ Ferdowsiite | Ag8(Sb5As3)S16 |
As | ⓘ Chabournéite | Tl4Pb2(Sb,As)20S34 |
As | ⓘ Hörnesite | Mg3(AsO4)2 · 8H2O |
Sr | Strontium | |
Sr | ⓘ Mapiquiroite | (Sr,Pb)(U,Y)Fe2(Ti,Fe3+,Cr3+)18O38 |
Y | Yttrium | |
Y | ⓘ Mapiquiroite | (Sr,Pb)(U,Y)Fe2(Ti,Fe3+,Cr3+)18O38 |
Mo | Molybdenum | |
Mo | ⓘ Molybdenite | MoS2 |
Ag | Silver | |
Ag | ⓘ Arsiccioite | AgHg2Tl(As,Sb)2S6 |
Ag | ⓘ Andreadiniite | CuHgAg7Pb7Sb24S48 |
Ag | ⓘ Pyradoketosite | Ag3SbS3 |
Ag | ⓘ Laffittite | AgHgAsS3 |
Ag | ⓘ Andorite | AgPbSb3S6 |
Ag | ⓘ Ferdowsiite | Ag8(Sb5As3)S16 |
Ag | ⓘ Miargyrite | AgSbS2 |
Sb | Antimony | |
Sb | ⓘ Protochabournéite | Tl2Pb(Sb,As)10S17 |
Sb | ⓘ Boscardinite | TlPb4(Sb7As2)S18 |
Sb | ⓘ Arsiccioite | AgHg2Tl(As,Sb)2S6 |
Sb | ⓘ Andreadiniite | CuHgAg7Pb7Sb24S48 |
Sb | ⓘ Pyradoketosite | Ag3SbS3 |
Sb | ⓘ Stibnite | Sb2S3 |
Sb | ⓘ Tetrahedrite Subgroup | Cu6(Cu4 C22+)Sb4S12S |
Sb | ⓘ Valentinite | Sb2O3 |
Sb | ⓘ Zinkenite | Pb9Sb22S42 |
Sb | ⓘ Rouxelite | Cu2HgPb23Sb27S65.5 |
Sb | ⓘ Chovanite | Pb15-2xSb14+2xS36Ox (x ~ 0.2) |
Sb | ⓘ Stibivanite | Sb2VO5 |
Sb | ⓘ Derbylite | Fe43+Ti3Sb3+O13(OH) |
Sb | ⓘ Andorite | AgPbSb3S6 |
Sb | ⓘ Ferdowsiite | Ag8(Sb5As3)S16 |
Sb | ⓘ Chabournéite | Tl4Pb2(Sb,As)20S34 |
Sb | ⓘ Parapierrotite | TlSb5S8 |
Sb | ⓘ Senarmontite | Sb2O3 |
Sb | ⓘ Miargyrite | AgSbS2 |
Sb | ⓘ Robinsonite | Pb4Sb6S13 |
Ba | Barium | |
Ba | ⓘ Bianchiniite | Ba2(TiV)(As2O5)2OF |
Ba | ⓘ Baryte | BaSO4 |
Ba | ⓘ Mannardite var. Ankangite | Ba(Ti,V3+,Cr)8O16 |
Ba | ⓘ Cymrite | BaAl2Si2(O,OH)8 · H2O |
Ba | ⓘ Benstonite | Ba6Ca6Mg(CO3)13 |
Ba | ⓘ Mannardite | Ba(Ti64+V23+)O16 |
Hg | Mercury | |
Hg | ⓘ Arsiccioite | AgHg2Tl(As,Sb)2S6 |
Hg | ⓘ Andreadiniite | CuHgAg7Pb7Sb24S48 |
Hg | ⓘ Routhierite | Tl(Cu,Ag)(Hg,Zn)2(As,Sb)2S6 |
Hg | ⓘ Aktashite | Cu6Hg3As4S12 |
Hg | ⓘ Laffittite | AgHgAsS3 |
Hg | ⓘ Rouxelite | Cu2HgPb23Sb27S65.5 |
Hg | ⓘ Polhemusite | (Zn,Hg)S |
Tl | Thallium | |
Tl | ⓘ Protochabournéite | Tl2Pb(Sb,As)10S17 |
Tl | ⓘ Boscardinite | TlPb4(Sb7As2)S18 |
Tl | ⓘ Arsiccioite | AgHg2Tl(As,Sb)2S6 |
Tl | ⓘ Routhierite | Tl(Cu,Ag)(Hg,Zn)2(As,Sb)2S6 |
Tl | ⓘ Chabournéite | Tl4Pb2(Sb,As)20S34 |
Tl | ⓘ Parapierrotite | TlSb5S8 |
Pb | Lead | |
Pb | ⓘ Protochabournéite | Tl2Pb(Sb,As)10S17 |
Pb | ⓘ Boscardinite | TlPb4(Sb7As2)S18 |
Pb | ⓘ Mapiquiroite | (Sr,Pb)(U,Y)Fe2(Ti,Fe3+,Cr3+)18O38 |
Pb | ⓘ Andreadiniite | CuHgAg7Pb7Sb24S48 |
Pb | ⓘ Galena | PbS |
Pb | ⓘ Zinkenite | Pb9Sb22S42 |
Pb | ⓘ Rouxelite | Cu2HgPb23Sb27S65.5 |
Pb | ⓘ Chovanite | Pb15-2xSb14+2xS36Ox (x ~ 0.2) |
Pb | ⓘ Andorite | AgPbSb3S6 |
Pb | ⓘ Cerussite | PbCO3 |
Pb | ⓘ Mimetite | Pb5(AsO4)3Cl |
Pb | ⓘ Chabournéite | Tl4Pb2(Sb,As)20S34 |
Pb | ⓘ Robinsonite | Pb4Sb6S13 |
U | Uranium | |
U | ⓘ Mapiquiroite | (Sr,Pb)(U,Y)Fe2(Ti,Fe3+,Cr3+)18O38 |
References
Sort by
Year (asc) Year (desc) Author (A-Z) Author (Z-A)• Stella, A. (1921) Le miniere di ferro d’Italia. Lattes & C., Torino-Genova.
• Corpo delle Miniere (1927) Giacimento di pirite di ferro e di minerale di ferro di Monte Arsiccio in Comune di Stazzema, Provincia di Lucca. Congresso Geologico Internazionale 1926, Madrid: 12-15.
• Bassani, U. (1974) I giacimenti di Monte Arsiccio e del Monte Corsinello-Valdicastello Carducci (Lucca). Notizie del Gruppo Mineralogico Lombardo: 5(2) (June 1974): 42-46.
• De Michele, V. (1974) Guida mineralogica d'Italia. Istituto Geografico De Agostini, Novara, 2 volumes.
• Leoni, L., Orlandi, P. (1975) Il granato di M.te Arsiccio. Rendiconti della Societa Italiana di Mineralogia e Petrologia: 31: 73-78.
• Boscardin, M. (1976) Blende di Carrara e spessartina di Monte Arsiccio (Alpi Apuane). Notizie del Gruppo Mineralogico Lombardo: 10.
• Carmignani, L., Dessau, G., Duchi, G. (1976) I giacimenti a barite, pirite ed ossidi di ferro delle Alpi Apuane. Studio minerogenetico e strutturale. Nuove osservazioni sui giacimenti polimetallici. Bollettino della Società Geologica Italiana: 95: 1009-1061.
• Cortecci, G., Lattanzi, P., Tanelli, G. (1983) Barite-iron oxide-pyrite deposits from Apuan Alps (Northern Tuscany, Italy). Geologica Carpatica: 32.
• Cortecci, G., Lattanzi, P., Tanelli, G. (1985) Barite-iron oxides-pyrite deposits from Apuan Alps, northern Tuscany, Italy. Memorie della Società Geologica Italiana: 30: 337-345.
• Costagliola, P., Benvenuti, M., Tanelli, G., Cortecci, G., Lattanzi, P. (1990) The barite-pyrite-iron oxides deposit of Monte Arsiccio (Apuan Alps). Bolletino della Società Geologica Italiana: 109: 267-277.
• Benvenuti, M., Cortecci, G., Costagliola, P., Lattanzi, P., Ruggieri, G., Tanelli, G. (1992) The metamorphic precious- and base-metal deposits of the Bottino-Valdicastello region (Apuan Alps, Tuscany): an overview. Acta Vulcanologica: 2: 45-54.
• Duchi, G., Franzini, M., Giamello, M., Orlandi, P., Riccobono, F. (1993) The iron-rich beryls of Alpi Apuane. Mineralogy, chemistry and fluid inclusion. Neues Jahrbuch für Mineralogie, Monatshefte: 193-207.
• Biagioni, C. (2009) Minerali della Provincia di Lucca. Associazione Micro-Mineralogica Italiana, Cremona, 352 pages.
• Biagioni, C., Orlandi, P., Pasero, M. (2009) Ankangite from the Monte Arsiccio mine (Apuan Alps, Tuscany, Italy): occurrence, crystal structure, and classification problems in cryptomelane group minerals. Periodico di Mineralogia: 78: 3-11.
• Biagioni, C., Orlandi, P. (2010) Cymrite and benstonite from the Monte Arsiccio mine (Apuan Alps, Tuscany, Italy): first Italian occurrence. Plinius: 36: 365.
• Biagioni, C., Bonaccorsi, E., Moëlo, Y., Orlandi, P., Paar, W. (2011) Monte Arsiccio mine: The first thallium ore in Apuan Alps. Plinius: 37: 401.
• Biagioni, C., Bonaccorsi, E., Capalbo, C., Merlino, S., Orlandi, P., Pasero, M., Perchiazzi, N. (2013) Cinque anni di ricerche mineralogiche sulle Alpi Apuane - Sinergia fra collezionismo e ricerca scientifica. Giornate di Studio GNM “Nuovi minerali: tra ricerca e collezionismo” Padova, 18 June 2013, 48 pages.
• Biagioni, C., Bonaccorsi, E., Moëlo, Y., Orlandi, P. (2014) Mercury-arsenic sulfosalts from Apuan Alps (Tuscany, Italy). II. Aktashite, Cu6Hg3As4S12, and laffittite, AgHgAsS3, from the Monte Arsiccio mine: occurrence and crystal structure. Periodico di Mineralogia: 83: 1-18.
• Biagioni, C., Moëlo, Y., Orlandi, P. (2014) Lead-antimony sulfosalts from Tuscany (Italy). XV. (Tl-Ag)-bearing rouxelite from Monte Arsiccio mine: occurrence and crystal-chemistry. Mineralogical Magazine: 78: 651–661.
• Biagioni, C., Orlandi, P., Pasero, M., Nestola, F., Bindi, L. (2014) Mapiquiroite, (Sr,Pb)(U,Y)Fe2(Ti,Fe3+)18O38, a new member of the crichtonite group from the Apuan Alps, Tuscany, Italy. European Journal of Mineralogy: 26: 427-437.
• Biagioni, C., Bonaccorsi, E., Moëlo, Y., Orlandi, P. (2014) Mercury-arsenic sulfosalts from Apuan Alps (Tuscany, Italy). I. Routhierite, (Cu0. 8Ag0. 2) Hg2Tl (As1. 4Sb0. 6)∑= 2S6, from Monte Arsiccio mine: occurrence and crystal structure. European Journal of Mineralogy: 26(1): 163-170.
• Biagioni, C., Bonaccorsi, E., Moëlo, Y., Orlandi, P., Bindi, L., D'Orazio, M., Vezzoni, S. (2014) Mercury-arsenic sulfosalts from Apuan Alps (Tuscany, Italy). III. Arsiccioite, AgHg2TlAs2S6, a new mineral from the Monte Arsiccio mine: occurrence, crystal structure, and crystal chemistry of the routhierite isotypic series. Mineralogical Magazine: 78: 101-117.
• Biagioni, C., Moëlo, Y. (2017) Lead-antimony sulfosalts from Tuscany (Italy). XVIII. New data on the crystal-chemistry of boscardinite. Mineralogical Magazine: 81: 47-60.
• Biagioni, C., Moëlo, Y. (2017) Lead-antimony sulfosalts from Tuscany (Italy). XIX. Crystal-chemistry of chovanite from two new occurrences in Apuan Alps and its 8A crystal structure. Mineralogical Magazine: 81: 811-831.
• Biagioni, C., Moëlo, Y., Zaccarini, F. (2017) Ferdowsiite from the Monte Arsiccio mine, Apuan Alps, Tuscany (Italy): occurrence and crystal structure. Atti della Società Toscana di Scienze Naturali, Memorie: 124: 5-11.
• Biagioni, C., Moëlo, Y., Orlandi, P., Paar, W.H. (2018) Lead-antimony sulfosalts from Tuscany (Italy). XXIII. Andreadiniite, CuAg7HgPb7Sb24S48, a new oversubstituted (Cu,Hg)-rich member of the andorite homeotypic series from the Monte Arsiccio mine, Apuan Alps. European Journal of Mineralogy: 30: 1021-1035.
• Biagioni, C., Moëlo, Y., Perchiazzi, N., Demitri, N., Lepore, G.O. (2018) Lead-antimony sulfosalts from Tuscany (Italy). XXIV. Crystal structure of thallium-bearing chovanite, TlPb26(Sb,As)31S72O, from the Monte Arsiccio mine, Apuan Alps. Minerals: 8: 535.
• Biagioni, C., Bindi, L., Mauro, D., Hålenius, U. (2019) Crystal chemistry of sulfates from the Apuan Alps (Tuscany, Italy). V. Scordariite, K8(Fe3+0.67□0.33)[Fe3+3O(SO4)6(H2O)3]2(H2O)11, a new metavoltine-related mineral. Minerals: 9: 702.
• Biagioni, C., D'Orazio, M., Fulignati, P., George, L.L., Mauro, D., Zaccarini, F. (2020) Sulfide melts in ore deposits from low-grade metamorphic settings: insights from fluid and Tl-rich sulfosalt microinclusions from the Monte Arsiccio mine (Apuan Alps, Tuscany, Italy). Ore Geology Reviews: 103589.
• Biagioni, C., Bonaccorsi, E., Perchiazzi, N., Hålenius, U., Zaccarini, F. (2020): Derbylite and graeserite from the Monte Arsiccio mine (Apuan Alps, Tuscany, Italy): occurrence and crystal-chemistry. Mineralogical Magazine: 84 (in press); http://forum.amiminerals.it/viewtopic.php?f=5&t=16490&sid=896ab93854cfe605adcb73a79ca23ad4
• Mauro, D., Biagioni, C., Pasero, M., and Zaccarini, F. (2020) Crystal-chemistry of sulfates from the Apuan Alps, Tuscany, Italy. VIII. New data on khademite, Al(SO4)F(H2O)5. Mineralogical Magazine, 84, 4, 540-546.
• Mauro, D. (2020). Crystal-chemistry of secondary minerals of thallium-rich pyrite from the Apuan Alps (Tuscany, Italy). Plinius, 46, 64-68; https://www.socminpet.it/files/download/vol-46/mauro.pdf
• Lacalamita, M., Schingaro, E., Mesto, E., Zaccarini, F. and Biagioni, C. (2020) Crystal-chemistry of micas belonging to the yangzhumingite-fluorophologopite and phlogopite-fluorophlogopite series from the Apuan Alps (northern Tuscany, Italy). Physics and Chemistry of Minerals, 47, 54.
• Biagioni, C., Mauro, D. and Pasero, M. (2020) Sulfates from the pyrite ore deposits of the Apuan Alps (Tuscany, Italy): A review. Minerals, 10, 1092.
Localities in this Region
- Tuscany
- Lucca Province
- Stazzema
- Sant'Anna di Stazzema
- Monte Arsiccio Mine
- Sant'Anna di Stazzema
- Stazzema
- Lucca Province
Other Regions, Features and Areas containing this locality
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Monte Arsiccio Mine, Sant'Anna di Stazzema, Stazzema, Lucca Province, Tuscany, Italy