Southern Tyrrhenian Sea, Tyrrhenian Sea, Italyi
| Regional Level Types | |
|---|---|
| Southern Tyrrhenian Sea | Sea |
| Tyrrhenian Sea | Sea |
| Italy | - not defined - |
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Latitude & Longitude (WGS84):
38° North , 14° East (est.)
Estimate based on other nearby localities or region boundaries.
Margin of Error:
~83km
Type:
Köppen climate type:
Mindat Locality ID:
311280
Long-form identifier:
mindat:1:2:311280:2
GUID (UUID V4):
e427e4f4-482a-4145-a4d9-4970515b39d2
Other Languages:
Italian:
Mar Tirreno Meridionale, Mar Tirreno, Italia
The southern Tyrrhenian basin represents an example of an active volcanic arc/back-arc system where there is the coexistence of Island Arc Basalt
(IAB)-type and Ocean Island Basalt (OIB)-type magmas. IAB-type lavas are widespread, occurring in the Aeolian volcanic arc, the Marsili and Aeolian Arc seamounts and as seamount remnats and lava flows flooring the basement of the Marsili and Vavilov Basins. By contrast, the few OIB-type lavas are represented by isolated volcanic centres or lava flows (i.e., Magnaghi, Vavilov and Aceste seamounts; Ustica island; rocks drilled, dredged and
cored in the East Sardinia rifted margin and the Prometeo submarine lava field).
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Standard Detailed Gallery Strunz Chemical ElementsMineral List
Mineral list contains entries from the region specified including sub-localities32 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
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Alphabetical List Tree DiagramDetailed Mineral List:
| ⓘ 'Amphibole Supergroup' Formula: AB2C5((Si,Al,Ti)8O22)(OH,F,Cl,O)2 Reference: Trua, T., Marani, M., and Barca, D. (2014) Lower crustal differentiation processes beneath a back-arc spreading ridge (Marsili seamount, Southern Tyrrhenian Sea). Lithos, 190-191, 349-362. |
| ⓘ Anorthite Formula: Ca(Al2Si2O8) Reference: Trua, T., Serri, G., Marani, M.P., Renzulli, A., and Gamberi, F. (2002) Volcanological and petrological evolution of Marsili seamount (southern Tyrrhenian Sea). Journal of Volcanology and Geothermal Research, 114, 441– 464; Trua, T., Marani, M., and Barca, D. (2014) Lower crustal differentiation processes beneath a back-arc spreading ridge (Marsili seamount, Southern Tyrrhenian Sea). Lithos, 190-191, 349-362. |
| ⓘ Aragonite Formula: CaCO3 Localities: Reference: Eckhardt, J.-D., Glasby, G.P., Puchelt, H., and Berner, Z. (1997) Hydrothermal manganese crusts from Enarete and Palinuro seamounts in the Tyrrhenian Sea. Marine Georesources & Geotechnology, 15, 2, 175-208. |
| ⓘ Baryte Formula: BaSO4 Reference: Tufar, W. (1992) Paragenesis of Complex Massive Sulfide Ores from the Tyrrhenian Sea. Mitteilungen der Österreichischen Geologischen Gesellschaft, 84, 265-300.
Hollis, S. P., Foury, S., Caruso, S., Johnson, S., Barrote, V., & Pumphrey, A. (2021). Lithogeochemical and Hyperspectral Halos to Ag-Zn-Au Mineralization at Nimbus in the Eastern Goldfields Superterrane, Western Australia. Minerals, 11(3), 254.
Fallon, Emily K., Matthias Frische, Sven Petersen, Richard A. Brooker, and Thomas B. Scott. (2019) "Geological, Mineralogical and Textural Impacts on the Distribution of Environmentally Toxic Trace Elements in Seafloor Massive Sulfide Occurrences" Minerals 9, no. 3: 162. https://doi.org/10.3390/min9030162 |
| ⓘ Birnessite Formula: (Na,Ca)0.5(Mn4+,Mn3+)2O4 · 1.5H2O Localities: Reference: Eckhardt, J.-D., Glasby, G.P., Puchelt, H., and Berner, Z. (1997) Hydrothermal manganese crusts from Enarete and Palinuro seamounts in the Tyrrhenian Sea. Marine Georesources & Geotechnology, 15, 2, 175-208. |
| ⓘ Bismuthinite Formula: Bi2S3 Reference: Minniti, M., and Bonavia, F. (1984) Copper-ore grade hydrothermal mineralization discovered in a seamount in the Tyrrhenian sea (Mediterranean): is the mineralization related to porphyry-copper or to base metal lodes? Marine Geology, 59, 271-282. |
| ⓘ Bournonite Formula: PbCuSbS3 Reference: Hollis, S. P., Foury, S., Caruso, S., Johnson, S., Barrote, V., & Pumphrey, A. (2021). Lithogeochemical and Hyperspectral Halos to Ag-Zn-Au Mineralization at Nimbus in the Eastern Goldfields Superterrane, Western Australia. Minerals, 11(3), 254. |
| ⓘ Calcite Formula: CaCO3 Localities: Reference: Eckhardt, J.-D., Glasby, G.P., Puchelt, H., and Berner, Z. (1997) Hydrothermal manganese crusts from Enarete and Palinuro seamounts in the Tyrrhenian Sea. Marine Georesources & Geotechnology, 15, 2, 175-208. |
| ⓘ Chalcopyrite Formula: CuFeS2 Reference: Tufar, W. (1992) Paragenesis of Complex Massive Sulfide Ores from the Tyrrhenian Sea. Mitteilungen der Österreichischen Geologischen Gesellschaft, 84, 265-300.
Hollis, S. P., Foury, S., Caruso, S., Johnson, S., Barrote, V., & Pumphrey, A. (2021). Lithogeochemical and Hyperspectral Halos to Ag-Zn-Au Mineralization at Nimbus in the Eastern Goldfields Superterrane, Western Australia. Minerals, 11(3), 254.
Fallon, Emily K., Matthias Frische, Sven Petersen, Richard A. Brooker, and Thomas B. Scott. (2019) "Geological, Mineralogical and Textural Impacts on the Distribution of Environmentally Toxic Trace Elements in Seafloor Massive Sulfide Occurrences" Minerals 9, no. 3: 162. https://doi.org/10.3390/min9030162 |
| ⓘ Cinnabar Formula: HgS Reference: Hollis, S. P., Foury, S., Caruso, S., Johnson, S., Barrote, V., & Pumphrey, A. (2021). Lithogeochemical and Hyperspectral Halos to Ag-Zn-Au Mineralization at Nimbus in the Eastern Goldfields Superterrane, Western Australia. Minerals, 11(3), 254. |
| ⓘ 'Clinopyroxene Subgroup' Reference: Trua, T., Serri, G., Marani, M.P., Renzulli, A., and Gamberi, F. ( 2002) Volcanological and petrological evolution of Marsili seamount (southern Tyrrhenian Sea). Journal of Volcanology and Geothermal Research, 114, 441– 464; Trua, T., Marani, M., and Barca, D. (2014) Lower crustal differentiation processes beneath a back-arc spreading ridge (Marsili seamount, Southern Tyrrhenian Sea). Lithos, 190-191, 349-362. |
| ⓘ Copper Formula: Cu Reference: Minniti, M., and Bonavia, F. (1984) Copper-ore grade hydrothermal mineralization discovered in a seamount in the Tyrrhenian sea (Mediterranean): is the mineralization related to porphyry-copper or to base metal lodes? Marine Geology, 59, 271-282. |
| ⓘ Covellite Formula: CuS Reference: Tufar, W. (1992) Paragenesis of Complex Massive Sulfide Ores from the Tyrrhenian Sea. Mitteilungen der Österreichischen Geologischen Gesellschaft, 84, 265-300.
Hollis, S. P., Foury, S., Caruso, S., Johnson, S., Barrote, V., & Pumphrey, A. (2021). Lithogeochemical and Hyperspectral Halos to Ag-Zn-Au Mineralization at Nimbus in the Eastern Goldfields Superterrane, Western Australia. Minerals, 11(3), 254. |
| ⓘ Enargite Formula: Cu3AsS4 Reference: Tufar, W. (1992) Paragenesis of Complex Massive Sulfide Ores from the Tyrrhenian Sea. Mitteilungen der Österreichischen Geologischen Gesellschaft, 84, 265-300.
Hollis, S. P., Foury, S., Caruso, S., Johnson, S., Barrote, V., & Pumphrey, A. (2021). Lithogeochemical and Hyperspectral Halos to Ag-Zn-Au Mineralization at Nimbus in the Eastern Goldfields Superterrane, Western Australia. Minerals, 11(3), 254. |
| ⓘ Famatinite Formula: Cu3SbS4 Reference: Hollis, S. P., Foury, S., Caruso, S., Johnson, S., Barrote, V., & Pumphrey, A. (2021). Lithogeochemical and Hyperspectral Halos to Ag-Zn-Au Mineralization at Nimbus in the Eastern Goldfields Superterrane, Western Australia. Minerals, 11(3), 254. |
| ⓘ Forsterite Formula: Mg2SiO4 Description: The olivine composition in the studied IAB-type lava samples is in the range Fo83.23-88.47 (Trua et al., 2010). Olivine is more forsteritic (Fo91–75) in the basalts than in the basaltic andesite (Fo78–74) (Trua et al. 2014). Reference: Trua, T., Serri, G., Marani, M.P., Renzulli, A., and Gamberi, F. ( 2002) Volcanological and petrological evolution of Marsili seamount (southern Tyrrhenian Sea). Journal of Volcanology and Geothermal Research, 114, 441– 464; Trua, T., Clocchiatti, R., Schiano, P., Ottolini, L., and Marani, M. (2010) The heterogeneous nature of the Southern Tyrrhenian mantle: Evidence fromolivine-hosted melt inclusions from back-arc magmas of the Marsili seamount. Lithos, 118, 1-16; Trua, T., Marani, M., and Barca, D. (2014) Lower crustal differentiation processes beneath a back-arc spreading ridge (Marsili seamount, Southern Tyrrhenian Sea). Lithos, 190-191, 349-362. |
| ⓘ Galena Formula: PbS Reference: Tufar, W. (1992) Paragenesis of Complex Massive Sulfide Ores from the Tyrrhenian Sea. Mitteilungen der Österreichischen Geologischen Gesellschaft, 84, 265-300.
Hollis, S. P., Foury, S., Caruso, S., Johnson, S., Barrote, V., & Pumphrey, A. (2021). Lithogeochemical and Hyperspectral Halos to Ag-Zn-Au Mineralization at Nimbus in the Eastern Goldfields Superterrane, Western Australia. Minerals, 11(3), 254.
Fallon, Emily K., Matthias Frische, Sven Petersen, Richard A. Brooker, and Thomas B. Scott. (2019) "Geological, Mineralogical and Textural Impacts on the Distribution of Environmentally Toxic Trace Elements in Seafloor Massive Sulfide Occurrences" Minerals 9, no. 3: 162. https://doi.org/10.3390/min9030162 |
| ⓘ 'Glass' Reference: Trua, T., Clocchiatti, R., Schiano, P., Ottolini, L., and Marani, M. (2010) The heterogeneous nature of the Southern Tyrrhenian mantle: Evidence fromolivine-hosted melt inclusions from back-arc magmas of the Marsili seamount. Lithos, 118, 1-16. |
| ⓘ Goethite Formula: α-Fe3+O(OH) Localities: Reference: Eckhardt, J.-D., Glasby, G.P., Puchelt, H., and Berner, Z. (1997) Hydrothermal manganese crusts from Enarete and Palinuro seamounts in the Tyrrhenian Sea. Marine Georesources & Geotechnology, 15, 2, 175-208. |
| ⓘ Jordanite ? Formula: Pb14As6S23 Reference: Tufar, W. (1992) Paragenesis of Complex Massive Sulfide Ores from the Tyrrhenian Sea. Mitteilungen der Österreichischen Geologischen Gesellschaft, 84, 265-300. |
| ⓘ Luzonite Formula: Cu3AsS4 Reference: Minniti, M., and Bonavia, F. (1984) Copper-ore grade hydrothermal mineralization discovered in a seamount in the Tyrrhenian sea (Mediterranean): is the mineralization related to porphyry-copper or to base metal lodes? Marine Geology, 59, 271-282. |
| ⓘ Marcasite Formula: FeS2 Reference: Tufar, W. (1992) Paragenesis of Complex Massive Sulfide Ores from the Tyrrhenian Sea. Mitteilungen der Österreichischen Geologischen Gesellschaft, 84, 265-300.
Hollis, S. P., Foury, S., Caruso, S., Johnson, S., Barrote, V., & Pumphrey, A. (2021). Lithogeochemical and Hyperspectral Halos to Ag-Zn-Au Mineralization at Nimbus in the Eastern Goldfields Superterrane, Western Australia. Minerals, 11(3), 254. |
| ⓘ 'Melnikovite' Reference: Tufar, W. (1992) Paragenesis of Complex Massive Sulfide Ores from the Tyrrhenian Sea. Mitteilungen der Österreichischen Geologischen Gesellschaft, 84, 265-300. |
| ⓘ Montmorillonite Formula: (Na,Ca)0.33(Al,Mg)2(Si4O10)(OH)2 · nH2O Localities: Reference: Eckhardt, J.-D., Glasby, G.P., Puchelt, H., and Berner, Z. (1997) Hydrothermal manganese crusts from Enarete and Palinuro seamounts in the Tyrrhenian Sea. Marine Georesources & Geotechnology, 15, 2, 175-208. |
| ⓘ Muscovite Formula: KAl2(AlSi3O10)(OH)2 Localities: Reference: Eckhardt, J.-D., Glasby, G.P., Puchelt, H., and Berner, Z. (1997) Hydrothermal manganese crusts from Enarete and Palinuro seamounts in the Tyrrhenian Sea. Marine Georesources & Geotechnology, 15, 2, 175-208. |
| ⓘ Muscovite var. Illite Formula: K0.65Al2.0[Al0.65Si3.35O10](OH)2 Localities: Reference: Eckhardt, J.-D., Glasby, G.P., Puchelt, H., and Berner, Z. (1997) Hydrothermal manganese crusts from Enarete and Palinuro seamounts in the Tyrrhenian Sea. Marine Georesources & Geotechnology, 15, 2, 175-208. |
| ⓘ Nontronite Formula: Na0.3Fe2((Si,Al)4O10)(OH)2 · nH2O Reference: Dekov, V.M., Kamenov, G.D., Stummeyer, J., Thiry, M., Savelli, C., Shanks, W.C., Fortin, D., Kuzmann, E., and Vértes, A. (2007) Hydrothermal nontronite formation at Eolo Seamount (Aeolian volcanic arc, Tyrrhenian Sea). Chemical Geology, 245, 103–119. |
| ⓘ Opal Formula: SiO2 · nH2O Reference: Hollis, S. P., Foury, S., Caruso, S., Johnson, S., Barrote, V., & Pumphrey, A. (2021). Lithogeochemical and Hyperspectral Halos to Ag-Zn-Au Mineralization at Nimbus in the Eastern Goldfields Superterrane, Western Australia. Minerals, 11(3), 254. |
| ⓘ 'Plagioclase' Formula: (Na,Ca)[(Si,Al)AlSi2]O8 Localities: Reference: Eckhardt, J.-D., Glasby, G.P., Puchelt, H., and Berner, Z. (1997) Hydrothermal manganese crusts from Enarete and Palinuro seamounts in the Tyrrhenian Sea. Marine Georesources & Geotechnology, 15, 2, 175-208. |
| ⓘ Pyrite Formula: FeS2 Reference: Tufar, W. (1992) Paragenesis of Complex Massive Sulfide Ores from the Tyrrhenian Sea. Mitteilungen der Österreichischen Geologischen Gesellschaft, 84, 265-300.
Hollis, S. P., Foury, S., Caruso, S., Johnson, S., Barrote, V., & Pumphrey, A. (2021). Lithogeochemical and Hyperspectral Halos to Ag-Zn-Au Mineralization at Nimbus in the Eastern Goldfields Superterrane, Western Australia. Minerals, 11(3), 254.
Fallon, Emily K., Matthias Frische, Sven Petersen, Richard A. Brooker, and Thomas B. Scott. (2019) "Geological, Mineralogical and Textural Impacts on the Distribution of Environmentally Toxic Trace Elements in Seafloor Massive Sulfide Occurrences" Minerals 9, no. 3: 162. https://doi.org/10.3390/min9030162 |
| ⓘ Pyrite var. Bravoite Formula: (Fe,Ni)S2 Reference: Tufar, W. (1992) Paragenesis of Complex Massive Sulfide Ores from the Tyrrhenian Sea. Mitteilungen der Österreichischen Geologischen Gesellschaft, 84, 265-300. |
| ⓘ Quartz Formula: SiO2 Localities: Reference: Minniti, M., and Bonavia, F. (1984) Copper-ore grade hydrothermal mineralization discovered in a seamount in the Tyrrhenian sea (Mediterranean): is the mineralization related to porphyry-copper or to base metal lodes? Marine Geology, 59, 271-282. |
| ⓘ Rutile Formula: TiO2 Reference: Minniti, M., and Bonavia, F. (1984) Copper-ore grade hydrothermal mineralization discovered in a seamount in the Tyrrhenian sea (Mediterranean): is the mineralization related to porphyry-copper or to base metal lodes? Marine Geology, 59, 271-282. |
| ⓘ Semseyite Formula: Pb9Sb8S21 Reference: Hollis, S. P., Foury, S., Caruso, S., Johnson, S., Barrote, V., & Pumphrey, A. (2021). Lithogeochemical and Hyperspectral Halos to Ag-Zn-Au Mineralization at Nimbus in the Eastern Goldfields Superterrane, Western Australia. Minerals, 11(3), 254. |
| ⓘ Silver Formula: Ag Reference: Minniti, M., and Bonavia, F. (1984) Copper-ore grade hydrothermal mineralization discovered in a seamount in the Tyrrhenian sea (Mediterranean): is the mineralization related to porphyry-copper or to base metal lodes? Marine Geology, 59, 271-282. |
| ⓘ 'Smectite Group' Formula: A0.3D2-3[T4O10]Z2 · nH2O Reference: Kidd, R.B., and Ármannson, H. (1979) Manganese and iron micronodules from a volcanic seamount in the Tyrrhenian Sea. Journal of the Geological Society, 136, 71-76. |
| ⓘ Sphalerite Formula: ZnS Reference: Tufar, W. (1992) Paragenesis of Complex Massive Sulfide Ores from the Tyrrhenian Sea. Mitteilungen der Österreichischen Geologischen Gesellschaft, 84, 265-300.
Hollis, S. P., Foury, S., Caruso, S., Johnson, S., Barrote, V., & Pumphrey, A. (2021). Lithogeochemical and Hyperspectral Halos to Ag-Zn-Au Mineralization at Nimbus in the Eastern Goldfields Superterrane, Western Australia. Minerals, 11(3), 254.
Fallon, Emily K., Matthias Frische, Sven Petersen, Richard A. Brooker, and Thomas B. Scott. (2019) "Geological, Mineralogical and Textural Impacts on the Distribution of Environmentally Toxic Trace Elements in Seafloor Massive Sulfide Occurrences" Minerals 9, no. 3: 162. https://doi.org/10.3390/min9030162 |
| ⓘ Stibnite Formula: Sb2S3 Reference: Minniti, M., and Bonavia, F. (1984) Copper-ore grade hydrothermal mineralization discovered in a seamount in the Tyrrhenian sea (Mediterranean): is the mineralization related to porphyry-copper or to base metal lodes? Marine Geology, 59, 271-282. |
| ⓘ 'Tennantite Subgroup' Formula: Cu6(Cu4C2+2)As4S12S Reference: Tufar, W. (1992) Paragenesis of Complex Massive Sulfide Ores from the Tyrrhenian Sea. Mitteilungen der Österreichischen Geologischen Gesellschaft, 84, 265-300. |
| ⓘ 'Tetrahedrite Subgroup' Formula: Cu6(Cu4C2+2)Sb4S12S Reference: Hollis, S. P., Foury, S., Caruso, S., Johnson, S., Barrote, V., & Pumphrey, A. (2021). Lithogeochemical and Hyperspectral Halos to Ag-Zn-Au Mineralization at Nimbus in the Eastern Goldfields Superterrane, Western Australia. Minerals, 11(3), 254.
Fallon, Emily K., Matthias Frische, Sven Petersen, Richard A. Brooker, and Thomas B. Scott. (2019) "Geological, Mineralogical and Textural Impacts on the Distribution of Environmentally Toxic Trace Elements in Seafloor Massive Sulfide Occurrences" Minerals 9, no. 3: 162. https://doi.org/10.3390/min9030162 |
| ⓘ Todorokite Formula: (Na,Ca,K,Ba,Sr)1-x(Mn,Mg,Al)6O12 · 3-4H2O Localities: Reference: Eckhardt, J.-D., Glasby, G.P., Puchelt, H., and Berner, Z. (1997) Hydrothermal manganese crusts from Enarete and Palinuro seamounts in the Tyrrhenian Sea. Marine Georesources & Geotechnology, 15, 2, 175-208. |
| ⓘ Wurtzite Formula: (Zn,Fe)S Reference: Tufar, W. (1992) Paragenesis of Complex Massive Sulfide Ores from the Tyrrhenian Sea. Mitteilungen der Österreichischen Geologischen Gesellschaft, 84, 265-300. |
Gallery:
List of minerals arranged by Strunz 10th Edition classification
| Group 1 - Elements | |||
|---|---|---|---|
| ⓘ | Copper | 1.AA.05 | Cu |
| ⓘ | Silver | 1.AA.05 | Ag |
| Group 2 - Sulphides and Sulfosalts | |||
| ⓘ | Bismuthinite | 2.DB.05 | Bi2S3 |
| ⓘ | Bournonite | 2.GA.50 | PbCuSbS3 |
| ⓘ | Chalcopyrite | 2.CB.10a | CuFeS2 |
| ⓘ | Cinnabar | 2.CD.15a | HgS |
| ⓘ | Covellite | 2.CA.05a | CuS |
| ⓘ | Enargite | 2.KA.05 | Cu3AsS4 |
| ⓘ | Famatinite | 2.KA.10 | Cu3SbS4 |
| ⓘ | Galena | 2.CD.10 | PbS |
| ⓘ | Jordanite ? | 2.JB.30a | Pb14As6S23 |
| ⓘ | Luzonite | 2.KA.10 | Cu3AsS4 |
| ⓘ | Marcasite | 2.EB.10a | FeS2 |
| ⓘ | Pyrite | 2.EB.05a | FeS2 |
| ⓘ | var. Bravoite | 2.EB.05a | (Fe,Ni)S2 |
| ⓘ | Semseyite | 2.HC.10d | Pb9Sb8S21 |
| ⓘ | Sphalerite | 2.CB.05a | ZnS |
| ⓘ | Stibnite | 2.DB.05 | Sb2S3 |
| ⓘ | 'Tennantite Subgroup' | 2.GB.05 | Cu6(Cu4C2+2)As4S12S |
| ⓘ | 'Tetrahedrite Subgroup' | 2.GB.05 | Cu6(Cu4C2+2)Sb4S12S |
| ⓘ | Wurtzite | 2.CB.45 | (Zn,Fe)S |
| Group 4 - Oxides and Hydroxides | |||
| ⓘ | Birnessite | 4.FL.45 | (Na,Ca)0.5(Mn4+,Mn3+)2O4 · 1.5H2O |
| ⓘ | Goethite | 4.00. | α-Fe3+O(OH) |
| ⓘ | Opal | 4.DA.10 | SiO2 · nH2O |
| ⓘ | Quartz | 4.DA.05 | SiO2 |
| ⓘ | Rutile | 4.DB.05 | TiO2 |
| ⓘ | Todorokite | 4.DK.10 | (Na,Ca,K,Ba,Sr)1-x(Mn,Mg,Al)6O12 · 3-4H2O |
| Group 5 - Nitrates and Carbonates | |||
| ⓘ | Aragonite | 5.AB.15 | CaCO3 |
| ⓘ | Calcite | 5.AB.05 | CaCO3 |
| Group 7 - Sulphates, Chromates, Molybdates and Tungstates | |||
| ⓘ | Baryte | 7.AD.35 | BaSO4 |
| Group 9 - Silicates | |||
| ⓘ | Anorthite | 9.FA.35 | Ca(Al2Si2O8) |
| ⓘ | Forsterite | 9.AC.05 | Mg2SiO4 |
| ⓘ | Montmorillonite | 9.EC.40 | (Na,Ca)0.33(Al,Mg)2(Si4O10)(OH)2 · nH2O |
| ⓘ | Muscovite | 9.EC.15 | KAl2(AlSi3O10)(OH)2 |
| ⓘ | var. Illite | 9.EC.15 | K0.65Al2.0[Al0.65Si3.35O10](OH)2 |
| ⓘ | Nontronite | 9.EC.40 | Na0.3Fe2((Si,Al)4O10)(OH)2 · nH2O |
| Unclassified Minerals, Rocks, etc. | |||
| ⓘ | 'Amphibole Supergroup' | - | AB2C5((Si,Al,Ti)8O22)(OH,F,Cl,O)2 |
| ⓘ | 'Clinopyroxene Subgroup' | - | |
| ⓘ | 'Glass' | - | |
| ⓘ | 'Melnikovite' | - | |
| ⓘ | 'Plagioclase' | - | (Na,Ca)[(Si,Al)AlSi2]O8 |
| ⓘ | 'Smectite Group' | - | A0.3D2-3[T4O10]Z2 · nH2O |
List of minerals for each chemical element
| H | Hydrogen | |
|---|---|---|
| H | ⓘ Todorokite | (Na,Ca,K,Ba,Sr)1-x(Mn,Mg,Al)6O12 · 3-4H2O |
| H | ⓘ Birnessite | (Na,Ca)0.5(Mn4+,Mn3+)2O4 · 1.5H2O |
| H | ⓘ Muscovite var. Illite | K0.65Al2.0[Al0.65Si3.35O10](OH)2 |
| H | ⓘ Montmorillonite | (Na,Ca)0.33(Al,Mg)2(Si4O10)(OH)2 · nH2O |
| H | ⓘ Goethite | α-Fe3+O(OH) |
| H | ⓘ Smectite Group | A0.3D2-3[T4O10]Z2 · nH2O |
| H | ⓘ Nontronite | Na0.3Fe2((Si,Al)4O10)(OH)2 · nH2O |
| H | ⓘ Muscovite | KAl2(AlSi3O10)(OH)2 |
| H | ⓘ Amphibole Supergroup | AB2C5((Si,Al,Ti)8O22)(OH,F,Cl,O)2 |
| H | ⓘ Opal | SiO2 · nH2O |
| C | Carbon | |
| C | ⓘ Calcite | CaCO3 |
| C | ⓘ Aragonite | CaCO3 |
| O | Oxygen | |
| O | ⓘ Baryte | BaSO4 |
| O | ⓘ Rutile | TiO2 |
| O | ⓘ Quartz | SiO2 |
| O | ⓘ Todorokite | (Na,Ca,K,Ba,Sr)1-x(Mn,Mg,Al)6O12 · 3-4H2O |
| O | ⓘ Birnessite | (Na,Ca)0.5(Mn4+,Mn3+)2O4 · 1.5H2O |
| O | ⓘ Calcite | CaCO3 |
| O | ⓘ Aragonite | CaCO3 |
| O | ⓘ Muscovite var. Illite | K0.65Al2.0[Al0.65Si3.35O10](OH)2 |
| O | ⓘ Montmorillonite | (Na,Ca)0.33(Al,Mg)2(Si4O10)(OH)2 · nH2O |
| O | ⓘ Plagioclase | (Na,Ca)[(Si,Al)AlSi2]O8 |
| O | ⓘ Goethite | α-Fe3+O(OH) |
| O | ⓘ Smectite Group | A0.3D2-3[T4O10]Z2 · nH2O |
| O | ⓘ Nontronite | Na0.3Fe2((Si,Al)4O10)(OH)2 · nH2O |
| O | ⓘ Muscovite | KAl2(AlSi3O10)(OH)2 |
| O | ⓘ Forsterite | Mg2SiO4 |
| O | ⓘ Anorthite | Ca(Al2Si2O8) |
| O | ⓘ Amphibole Supergroup | AB2C5((Si,Al,Ti)8O22)(OH,F,Cl,O)2 |
| O | ⓘ Opal | SiO2 · nH2O |
| F | Fluorine | |
| F | ⓘ Amphibole Supergroup | AB2C5((Si,Al,Ti)8O22)(OH,F,Cl,O)2 |
| Na | Sodium | |
| Na | ⓘ Todorokite | (Na,Ca,K,Ba,Sr)1-x(Mn,Mg,Al)6O12 · 3-4H2O |
| Na | ⓘ Birnessite | (Na,Ca)0.5(Mn4+,Mn3+)2O4 · 1.5H2O |
| Na | ⓘ Montmorillonite | (Na,Ca)0.33(Al,Mg)2(Si4O10)(OH)2 · nH2O |
| Na | ⓘ Plagioclase | (Na,Ca)[(Si,Al)AlSi2]O8 |
| Na | ⓘ Nontronite | Na0.3Fe2((Si,Al)4O10)(OH)2 · nH2O |
| Mg | Magnesium | |
| Mg | ⓘ Todorokite | (Na,Ca,K,Ba,Sr)1-x(Mn,Mg,Al)6O12 · 3-4H2O |
| Mg | ⓘ Montmorillonite | (Na,Ca)0.33(Al,Mg)2(Si4O10)(OH)2 · nH2O |
| Mg | ⓘ Forsterite | Mg2SiO4 |
| Al | Aluminium | |
| Al | ⓘ Todorokite | (Na,Ca,K,Ba,Sr)1-x(Mn,Mg,Al)6O12 · 3-4H2O |
| Al | ⓘ Muscovite var. Illite | K0.65Al2.0[Al0.65Si3.35O10](OH)2 |
| Al | ⓘ Montmorillonite | (Na,Ca)0.33(Al,Mg)2(Si4O10)(OH)2 · nH2O |
| Al | ⓘ Plagioclase | (Na,Ca)[(Si,Al)AlSi2]O8 |
| Al | ⓘ Nontronite | Na0.3Fe2((Si,Al)4O10)(OH)2 · nH2O |
| Al | ⓘ Muscovite | KAl2(AlSi3O10)(OH)2 |
| Al | ⓘ Anorthite | Ca(Al2Si2O8) |
| Al | ⓘ Amphibole Supergroup | AB2C5((Si,Al,Ti)8O22)(OH,F,Cl,O)2 |
| Si | Silicon | |
| Si | ⓘ Quartz | SiO2 |
| Si | ⓘ Muscovite var. Illite | K0.65Al2.0[Al0.65Si3.35O10](OH)2 |
| Si | ⓘ Montmorillonite | (Na,Ca)0.33(Al,Mg)2(Si4O10)(OH)2 · nH2O |
| Si | ⓘ Plagioclase | (Na,Ca)[(Si,Al)AlSi2]O8 |
| Si | ⓘ Nontronite | Na0.3Fe2((Si,Al)4O10)(OH)2 · nH2O |
| Si | ⓘ Muscovite | KAl2(AlSi3O10)(OH)2 |
| Si | ⓘ Forsterite | Mg2SiO4 |
| Si | ⓘ Anorthite | Ca(Al2Si2O8) |
| Si | ⓘ Amphibole Supergroup | AB2C5((Si,Al,Ti)8O22)(OH,F,Cl,O)2 |
| Si | ⓘ Opal | SiO2 · nH2O |
| S | Sulfur | |
| S | ⓘ Pyrite | FeS2 |
| S | ⓘ Sphalerite | ZnS |
| S | ⓘ Galena | PbS |
| S | ⓘ Marcasite | FeS2 |
| S | ⓘ Enargite | Cu3AsS4 |
| S | ⓘ Wurtzite | (Zn,Fe)S |
| S | ⓘ Covellite | CuS |
| S | ⓘ Pyrite var. Bravoite | (Fe,Ni)S2 |
| S | ⓘ Chalcopyrite | CuFeS2 |
| S | ⓘ Tennantite Subgroup | Cu6(Cu4C22+)As4S12S |
| S | ⓘ Baryte | BaSO4 |
| S | ⓘ Bismuthinite | Bi2S3 |
| S | ⓘ Stibnite | Sb2S3 |
| S | ⓘ Luzonite | Cu3AsS4 |
| S | ⓘ Bournonite | PbCuSbS3 |
| S | ⓘ Cinnabar | HgS |
| S | ⓘ Famatinite | Cu3SbS4 |
| S | ⓘ Semseyite | Pb9Sb8S21 |
| S | ⓘ Tetrahedrite Subgroup | Cu6(Cu4C22+)Sb4S12S |
| S | ⓘ Jordanite | Pb14As6S23 |
| Cl | Chlorine | |
| Cl | ⓘ Amphibole Supergroup | AB2C5((Si,Al,Ti)8O22)(OH,F,Cl,O)2 |
| K | Potassium | |
| K | ⓘ Todorokite | (Na,Ca,K,Ba,Sr)1-x(Mn,Mg,Al)6O12 · 3-4H2O |
| K | ⓘ Muscovite var. Illite | K0.65Al2.0[Al0.65Si3.35O10](OH)2 |
| K | ⓘ Muscovite | KAl2(AlSi3O10)(OH)2 |
| Ca | Calcium | |
| Ca | ⓘ Todorokite | (Na,Ca,K,Ba,Sr)1-x(Mn,Mg,Al)6O12 · 3-4H2O |
| Ca | ⓘ Birnessite | (Na,Ca)0.5(Mn4+,Mn3+)2O4 · 1.5H2O |
| Ca | ⓘ Calcite | CaCO3 |
| Ca | ⓘ Aragonite | CaCO3 |
| Ca | ⓘ Montmorillonite | (Na,Ca)0.33(Al,Mg)2(Si4O10)(OH)2 · nH2O |
| Ca | ⓘ Plagioclase | (Na,Ca)[(Si,Al)AlSi2]O8 |
| Ca | ⓘ Anorthite | Ca(Al2Si2O8) |
| Ti | Titanium | |
| Ti | ⓘ Rutile | TiO2 |
| Ti | ⓘ Amphibole Supergroup | AB2C5((Si,Al,Ti)8O22)(OH,F,Cl,O)2 |
| Mn | Manganese | |
| Mn | ⓘ Todorokite | (Na,Ca,K,Ba,Sr)1-x(Mn,Mg,Al)6O12 · 3-4H2O |
| Mn | ⓘ Birnessite | (Na,Ca)0.5(Mn4+,Mn3+)2O4 · 1.5H2O |
| Fe | Iron | |
| Fe | ⓘ Pyrite | FeS2 |
| Fe | ⓘ Marcasite | FeS2 |
| Fe | ⓘ Wurtzite | (Zn,Fe)S |
| Fe | ⓘ Pyrite var. Bravoite | (Fe,Ni)S2 |
| Fe | ⓘ Chalcopyrite | CuFeS2 |
| Fe | ⓘ Goethite | α-Fe3+O(OH) |
| Fe | ⓘ Nontronite | Na0.3Fe2((Si,Al)4O10)(OH)2 · nH2O |
| Ni | Nickel | |
| Ni | ⓘ Pyrite var. Bravoite | (Fe,Ni)S2 |
| Cu | Copper | |
| Cu | ⓘ Enargite | Cu3AsS4 |
| Cu | ⓘ Covellite | CuS |
| Cu | ⓘ Chalcopyrite | CuFeS2 |
| Cu | ⓘ Tennantite Subgroup | Cu6(Cu4C22+)As4S12S |
| Cu | ⓘ Copper | Cu |
| Cu | ⓘ Luzonite | Cu3AsS4 |
| Cu | ⓘ Bournonite | PbCuSbS3 |
| Cu | ⓘ Famatinite | Cu3SbS4 |
| Cu | ⓘ Tetrahedrite Subgroup | Cu6(Cu4C22+)Sb4S12S |
| Zn | Zinc | |
| Zn | ⓘ Sphalerite | ZnS |
| Zn | ⓘ Wurtzite | (Zn,Fe)S |
| As | Arsenic | |
| As | ⓘ Enargite | Cu3AsS4 |
| As | ⓘ Tennantite Subgroup | Cu6(Cu4C22+)As4S12S |
| As | ⓘ Luzonite | Cu3AsS4 |
| As | ⓘ Jordanite | Pb14As6S23 |
| Sr | Strontium | |
| Sr | ⓘ Todorokite | (Na,Ca,K,Ba,Sr)1-x(Mn,Mg,Al)6O12 · 3-4H2O |
| Ag | Silver | |
| Ag | ⓘ Silver | Ag |
| Sb | Antimony | |
| Sb | ⓘ Stibnite | Sb2S3 |
| Sb | ⓘ Bournonite | PbCuSbS3 |
| Sb | ⓘ Famatinite | Cu3SbS4 |
| Sb | ⓘ Semseyite | Pb9Sb8S21 |
| Sb | ⓘ Tetrahedrite Subgroup | Cu6(Cu4C22+)Sb4S12S |
| Ba | Barium | |
| Ba | ⓘ Baryte | BaSO4 |
| Ba | ⓘ Todorokite | (Na,Ca,K,Ba,Sr)1-x(Mn,Mg,Al)6O12 · 3-4H2O |
| Hg | Mercury | |
| Hg | ⓘ Cinnabar | HgS |
| Pb | Lead | |
| Pb | ⓘ Galena | PbS |
| Pb | ⓘ Bournonite | PbCuSbS3 |
| Pb | ⓘ Semseyite | Pb9Sb8S21 |
| Pb | ⓘ Jordanite | Pb14As6S23 |
| Bi | Bismuth | |
| Bi | ⓘ Bismuthinite | Bi2S3 |
References
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Year (asc) Year (desc) Author (A-Z) Author (Z-A)Peccerillo, A. (2005) Plio-Quaternary Volcanism in Italy. Petrology, Geochemistry, Geodynamics. Springer, Berlin Heidelberg New York, 364 pp.
Localities in this Region
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Southern Tyrrhenian Sea, Tyrrhenian Sea, Italy