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Atlantic Ocean | |
- Mid-Atlantic Ridge complex
| Ondréas, H., Cannat, M., Fouquet, Y., & Normand, A. (2012). Geological context and vents morphology of the ultramafic‐hosted Ashadze hydrothermal areas (Mid‐Atlantic Ridge 13° N). Geochemistry, Geophysics, Geosystems, 13(11). |
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| Ayupova, N. R., Melekestseva, I. Y., Maslennikov, V. V., Tseluyko, A. S., Blinov, I. A., & Beltenev, V. E. (2018). Uranium accumulation in modern and ancient Fe-oxide sediments: Examples from the Ashadze-2 hydrothermal sulfide field (Mid-Atlantic Ridge) and Yubileynoe massive sulfide deposit (South Urals, Russia). Sedimentary Geology, 367, 164-174. |
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| Mozgova, N. N., Borodaev, Y. S., Gablina, I. F., Stepanova, T. V., Cherkashev, G. A., & Uspenskaya, T. Y. Y. (2007). Features of transformation of the mineral paragenetic assemblages from copper sulfide ores of the Krasnov hydrothermal field (16° 38'N Mid Atlantic Ridge). New Data on Minerals, 62. |
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| 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
Gablina, I.F., Semkova, T.A., Stepanova, T.V., and Gor'kova, N.V. (2006): Lithology and Mineral Resources 41(1), 27-44. |
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| Earth and Planetary Science Letters 48 (1997) 69-91 |
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| Gablina, I. F., Dobretsova, I. G., Narkevskii, E. V., Gustaitis, A. N., Sadchikova, T. A., Gor’kova, N. V., ... & Dara, O. M. (2017). Influence of hydrothermal-metasomatic processes on the formation of present-day sulfide ores in carbonate bottom sediments of the Mid-Atlantic Ridge (19°–20° N). Lithology and Mineral Resources, 52, 335-357.
Ozhogina E.G., Yakushina O. A., Astakhova Yu.M. (2015) Seafloor Massive Polymetallic Sulphidic Ores as the Potential Source of Non-ferrous Metals. XII International Conference «New Ideas in Earth Sciences» p69-70 |
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| Maslennikov, Valeriy V., Georgy A. Cherkashov, Anna V. Firstova, Nuriya R. Ayupova, Victor E. Beltenev, Irina Yu. Melekestseva, Dmitry A. Artemyev, Aleksandr S. Tseluyko, and Ivan A. Blinov. (2023) "Trace Element Assemblages of Pseudomorphic Iron Oxyhydroxides of the Pobeda-1 Hydrothermal Field, 17°08.7′ N, Mid-Atlantic Ridge: The Development of a Halmyrolysis Model from LA-ICP-MS Data" Minerals 13, no. 1: 4. https://doi.org/10.3390/min13010004
Gablina, I. F., Dobretzova, I. G., Laiba, A. A., Narkevsky, E. V., Maksimov, F. E., & Kuznetsov, V. Y. (2018). Specific Features of Sulfide Ores in the Pobeda Hydrothermal Cluster, Mid-Atlantic Rise 17° 07′–17° 08′ N. Lithology and Mineral Resources, 53(6), 431-454. |
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| Gablina, I. F., Dobretzova, I. G., Laiba, A. A., Narkevsky, E. V., Maksimov, F. E., & Kuznetsov, V. Y. (2018). Specific Features of Sulfide Ores in the Pobeda Hydrothermal Cluster, Mid-Atlantic Rise 17° 07′–17° 08′ N. Lithology and Mineral Resources, 53(6), 431-454. |
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| Bonatti, E., Guerstein-Honnorez, B.-M., Honnorez, J. (1976) Copper-iron sulfide mineralizations from the equatorial Mid-Atlantic Ridge: Economic Geology: 71: 1515-1525. |
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| Vlasov E.A., Pertsev A.N., Kotova M.S., Beltenev V.E. (2010) Ore-hosting metasomatic rocks of hydrothermal fields in the ore cluster «Semenov» region (Mid-Atlantic ridge, 13°31'). Abstracts of XXVII International conference School «Geochemistry of Alkaline rocks». – Moscow-Koktebel’. pp. 240 pp. |
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| Firstova, A., Stepanova, T., Sukhanova, A., Cherkashov, G., & Poroshina, I. (2019). Au and Te Minerals in Seafloor Massive Sulphides from Semyenov-2 Hydrothermal Field, Mid-Atlantic Ridge. Minerals, 9(5), 294. |
- Sierra Leone fracture zone
| Bortnikov, N. S., Mochalov, A. G., & Cherkashev, G. A. (2006, July). Native minerals and intermetallides of noble and nonferrous metals in sediments of the Markov Deep, Mid-Atlantic Ridge. In Doklady earth sciences (Vol. 409, No. 2, p. 929). Springer Nature BV. |
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| Sharkov, E.V., Abramov, S.S., Simonov, V.A., Krinov, D.I., Skolotnev, S.G., Bel’tenev, V.E., and Bortnikov, N.S. (2007): Geology of Ore Deposits 49(6), 467-486. |
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| Fouquet, Y., Wafik, A., Cambon, P., Mevel, C., Meyer, G., & Gente, P. (1993). Tectonic setting and mineralogical and geochemical zonation in the Snake Pit sulfide deposit (Mid-Atlantic Ridge at 23 degrees N). Economic geology, 88(8), 2018-2036. |
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| Bogdanov, Y.A., Vikent’ev, I.V., Lein, A.Y., Bogdanova, O.Y., Sagalevich, A.M., and Sivtsov, A.V. (2008): LGeology of Ore Deposits 50(2), 119-134. |
- Trans-Atlantic Geotraverse hydrothermal field (TAG)
| Dekov, V. M., Damyanov, Z. K., Kamenov, G. D., Bonev, I. K., Rajta, I., & Grime, G. W. (2001). Sorosite (η-Cu6Sn5)-bearing native tin and lead assemblage from the Mir zone (Mid-Atlantic Ridge, 26° N). Oceanologica acta, 24(3), 205-220.
Dekov, V., Z. Damyanov, G. Kamenov, I. Bonev, I. Rajta, G. Grime. 2001. Sorosite (h-Cu6Sn5)-bearing native tin and lead assemblage from the Mir zone (Mid-Atlantic Ridge, 26oN). – Oceanologica Acta, 24, 3, 205-220. |
|
| Canadian Mineralogist Vol.26, pp. 697-711 (1988) |
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| Gablina, I. F., Dobretsova, I. G., Narkevskii, E. V., Gustaitis, A. N., Sadchikova, T. A., Gor’kova, N. V., ... & Dara, O. M. (2017). Influence of hydrothermal-metasomatic processes on the formation of present-day sulfide ores in carbonate bottom sediments of the Mid-Atlantic Ridge (19°–20° N). Lithology and Mineral Resources, 52, 335-357. |
- Southern Mid-Atlantic Ridge complex
| Li, Bing, Shi, Xuefa, Li, Chuanshun, Wang, Sai, Fan, Lei, Ye, Jun, Dang, Yuan, Yan, Quanshu (2024) Subseafloor hydrothermal mineralization in a non-transform offset: Mineralogy and LA-ICP-MS study of sulfide from the Taiji-2 hydrothermal field, Southern Mid-Atlantic Ridge. Ore Geology Reviews, 167. 105975 doi:10.1016/j.oregeorev.2024.105975 |
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| Meng, X., Jin, X., Li, X., Chu, F., Zhang, W., Wang, H., ... & Li, Z. (2021). Mineralogy and geochemistry of secondary minerals and oxyhydroxides from the Xunmei hydrothermal field, Southern Mid-Atlantic Ridge (26 S): Insights for metal mobilization during the oxidation of submarine sulfides. Marine Geology, 442, 106654. |
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DR Congo | |
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| Kampunzu, A.B., Cailteux, J.L.H., Kamona, A.F., Intiomale, M.M., Melcher, F. (2009) Sediment-hosted Zn–Pb–Cu deposits in the Central African Copperbelt. Ore Geology Reviews, 35, 263-297.
Deliens, M. (1996) Overzicht van de mineralogie van de koper-, kobalt- en uraniumvoorkomens in Zuid-Shaba (Zaïre). Pages 35-49 in: Schatten der Aarde. Van mineraal tot juweel. Tentoonstelling in de abdij Saint-Gérard de Brogne van 27 april tot 27 oktober 1996. Catalogus opgemaakt onder de leiding van R. Warin, AGAB en P. Van hee, MKA (in Dutch). |
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| Gécamines (1977) Johari - Minéraux du Shaba Méridional. Malvaux, Brussels. |
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Egypt | |
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| El Aref, M., Abd El-Rahman, Y., Zoheir, B., Surour, A., Helmy, H. M., Abdelnasser, A., ... & Ibrahim, M. E. A. (2020). Mineral Resources in Egypt (I): Metallic Ores. In The Geology of Egypt (pp. 521-587). Springer, Cham.
Ismail, A. M. (2017). Um Samra-Um Bakra Shear Zone, Central Eastern Desert, Egypt: example of vein-type base metal mineralization. International Journal of Mining Science (IJMS) 3(2):9-25 |
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| Ibrahim, M. E., Saleh, G. M., Dawood, N. A., & Aly, G. M. (2013). Ocellar lamprophyre dyke bearing mineralization, Wadi Nugrus, Eastern Desert, Egypt: Geology, mineralogy and geochemical implications. Journal of Geology and Mining Research, 2(4), 74-86. |
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| Kamar, M. S., El Tohamy, A. M., Mira, H. I., & Ismail, A. M. (2022, August). Geology and Environmental Impact Assessment of Psammitic Gneiss and Lamprophyre Dykes at Wadi Sikait, South Eastern Desert, Egypt. In Journal of Physics: Conference Series (Vol. 2305, No. 1, p. 012001). IOP Publishing. |
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| Afify, A. M., Osman, R. A., Wanas, H. A., & Khater, T. M. (2022). Mineralogical and geochemical studies of copper mineralization in the Paleozoic sedimentary section in southwestern Sinai, Egypt. Ore Geology Reviews, 147, 104994. |
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| Afify, A. M., Osman, R. A., Wanas, H. A., & Khater, T. M. (2022). Mineralogical and geochemical studies of copper mineralization in the Paleozoic sedimentary section in southwestern Sinai, Egypt. Ore Geology Reviews, 147, 104994. |
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| Sallam, O. R., Alshami, A. S., & Abbas, A. E. (2019). Geology And Mineralogy Of A Radioactive Pegmatite Body At Wadi Zaghra Area, Southeastern Sinai, Egypt. Nuclear Sciences Scientific Journal (Print), 8(A), 191-205. |
|
Italy | |
- Metropolitan City of Catania
| Del Caldo, Moro, Gramaccioli, Boscardin - "Il Collezionista" - Fabbri Editori - pag180 |
|
Morocco | |
- Bou Skour mining district
| Georges Favreau collection |
|
Namibia | |
|
| Schoeman, P. (1996). Overview and comparison of Besshi-type deposits: ancient and recent (Doctoral dissertation, Rhodes University).
Bürg, G. , Die Nutzbaren Minerallagerstätten von Deutsch-Südwestafrika (1942), p. 86-89
www.attawaygems.com/NMFG/lets_talk_gemstones_staurolite.htm |
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| von Bezing, Ludi (2007) Namibia - Minerals and Localities. Bode Verlag GmbH, Haltern. |
|
| Anthony, J. W. et al. (1997): Handbook of Mineralogy, Vol. 3, 29 |
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| von Bezing, Ludi (2007) Namibia - Minerals and Localities. Bode Verlag GmbH, Haltern.
Borg, G., Karner, K., Buxton, M., Armstrong, R., Schalk van der Merwe, W. (2003): Geology of the Skorpion supergene zinc deposit, southern Namibia. Economic Geology, 98, 749-771 |
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| von Bezing, Ludi (2007) Namibia - Minerals and Localities. Bode Verlag GmbH, Haltern.
von Bezing, Ludi (2007) Namibia - Minerals and Localities. Bode Verlag GmbH, Haltern. |
|
South Africa | |
- Namakwa District Municipality
- Khâi-Ma Local Municipality
| Cairncross, B., Dixon, R. (1995) Minerals of South Africa. Geological Society of South Africa, Linden . |
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| Meyer, T. Q., van der Westhuizen, W. A., Beukes, G. J., de Bruiyn, H., Schoch, A. E. (1986) An occurrence of the hydrous lead-copper-iron silicate creaseyite in South Africa. Mineralogical Magazine, 50 (356) 346-348 doi:10.1180/minmag.1986.050.356.28 |
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| Schoch, A. E., Beukes, G. J., Praekelt, H. E. (1985) A natroalunite - zaherite - hotsonite paragenesis from Pofadder, Bushmanland, South Africa. The Canadian Mineralogist, 23 (1) 29-34 |
Tsumeb Mine, Tsumeb, Oshikoto Region, Namibia