Geochemistry International

, Volume 54, Issue 8, pp 732–738 | Cite as

Behavior of lanthanides during the formation of the Svetloe deposit, Chukotka

  • Yu. A. Popova
  • A. Yu. Bychkov
  • S. S. Matveeva
Short Communications


ore-forming (Sn, W) fluid rare-earth elements composition of minerals mechanisms of ore formation 


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  1. M. Bau, “Rare-earth element mobility during hydrothermal and metamorphic fluid-rock interaction state of europium,” Chem. Geol. 93, 219–230 1991.CrossRefGoogle Scholar
  2. V. D. Kozlov, D. V. Dudkinskii, and Yu. K. Eliass, Geochemistry and Ore Potential of Central Chukotka (Nauka, Moscow, 1995) [in Russian].Google Scholar
  3. S. S. Matveeva, “Evolution of ore-forming processes at the Akchatau greisen-type deposit: evidence from geochemical indicators,” Petrology 5 (3), 291–299 1997.Google Scholar
  4. S. S. Matveeva, M. Yu. Spasennykh, T. M. Sushchevskaya, A. Yu. Bychkov, and A. V. Ignat’ev, “Geochemical model of the formation of the Spokoininsk tungsten deposit (eastern Transbaikal Region, Russia),” Geol. Ore Deposits 44 (2), 111–131 2002.Google Scholar
  5. H. Palme and A. Jones, “Solar system abundances of the elements,” in Treatise on Geochemistry, Volume 1. Meteorites, Comets, and Planets, Ed. by A. M. Davis (Elsevier, 2003) pp. 41–61.Google Scholar
  6. Yu. A. Popova, A. Yu. Bychkov, S. S. Matveeva, and T. M. Sushchevskaya, “Behavior of lanthanides during the formation of the Iul’tin Deposit, Chukchi Peninsula,” Geochem. Int. 52 (12), 1078–1083 2014.CrossRefGoogle Scholar
  7. Yu. A. Popova, A. Yu. Bychkov, S. S. Matveeva, and Ya. V. Bychkova, “Experimental study of lanthanide partition coefficients in the scheelite–fluid system,” in Proceedings of All-Russian Annual Seminar on Experimental Mineralogy, Petrology, and Geochemistry Moscow, Russia, 2015 (Moscow, 2015) [in Russian].Google Scholar
  8. L. Raimbault, “Utilizationdsspectresdeterresraresdes mineraux hydrothermaux (apatite, fluorite, scheelite, wolframite) pour la characterisation des fluids mineralisateurs et l’identification des magmas sorses et des processus evolutifs,” Bull. Mineral. 108, 737–744 1985.Google Scholar
  9. T. M. Suschevskaya, M. Ju. Spasennykh, A. V. Ignatev, A. L. Devirts, and A. M. Erokhin, “Genesis of mineralforming fluids of the Svetloe Deposit, Chukotka, Russia: oxygen and hydrogen isotopic data,” Geochem. Int. 38, S23–S30 (2000).Google Scholar
  10. T. M. Sushchevskaya and A. Yu. Bychkov, “Physicochemical mechanisms of cassiterite and wolframite precipitation in the granite-related hydrothermal system: thermodynamic modeling,” Geochem. Int. 48 (12). 1246–1253 (2010).CrossRefGoogle Scholar
  11. T. M. Sushchevskaya and I. V. Tokarev, “Argon in mineralforming fluids at the Iultin and Svetloe Sn–W deposits,” Geochem. Int. 41 (11), 1123–1125 2003.Google Scholar
  12. T. M. Sushchevskaya, Ya. Dyurishiva, A. M. Erokhin, et al., “Study of chemical characteristics of mineral-forming medium during formation of the cassiterite–quartz mineralization,” Geokhimiya, No. 6, 36–45(1995).Google Scholar

Copyright information

© Pleiades Publishing, Ltd. 2016

Authors and Affiliations

  • Yu. A. Popova
    • 1
  • A. Yu. Bychkov
    • 1
    • 2
  • S. S. Matveeva
    • 1
  1. 1.Faculty of GeologyMoscow State UniversityMoscowRussia
  2. 2.Vernadsky Institute of Geochemistry and Analytical ChemistryRussian Academy of SciencesMoscowRussia

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