Abstract
Experimental data on the Nb, Ta, Ti, Ce, and La concentrations in felsic magmatic melts of various alkalinity and alumina content upon dissolving ilmenorutile, ferrotapiolite, and loparite in them and the partitioning of these metals between the melt and the mineral at 650–850°C and 100 MPa, which allow one to obtain quantitative characteristics for creating physicochemical models of the genesis of rare metal and rare earth deposits, are presented. It is shown that ilmenorutile and ferrotapiolite are stable in the peraluminous melt. Ilmenorutile is also stable in the subaluminous melt and at 650°C in the alkalized melt, and loparite is unstable in all melts participating in the experiments. The dependences of the content and partitioning of Nb on dissolving ilmenorutile and loparite are similar to each other and to those on dissolving columbite and tantalite. At the same time, the dependence obtained by dissolving ferrotapiolite is similar to that obtained by dissolving microlite and pyrochlore.
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REFERENCES
R. I. Gulyaeva, S. A. Petrova, V. M. Chumarev, and A. N. Mansurova, Phys. Solid State 61 (10), 1947–1954 (2019).
S. A. Kukushkin, I. Yu. Tentilova, and I. P. Pronin, Phys. Solid State 54 (3), 611–617 (2012).
N. I. Suk, A. R. Kotel’nikov, and A. A. Viryus, Russ. Geol. Geophys. 54 (4), 436–453 (2013).
V. Yu. Chevychelov, Extended Abstract of Doctoral Dissertation in Geology and Mineralogy (Moscow, 2013) [in Russian].
V. Yu. Chevychelov, in Proc. 8th Int. Symp. “Mineral Variety: Research and Maintenance.” Sofia Enterprise “Mineral Variety Maintenance.” National Museum “Earth and Man” (Sofia, 2016), pp. 22–34 [in Russian].
V. Yu. Chevychelov, G. P. Borodulin, and G. P. Zaraiskiy, Geochem. Int. 48 (5), 456–465 (2010).
V. Yu. Chevychelov, A. A. Viryus, and Yu. B. Shapovalov, Dokl. Earth Sci. 489 (2), 1465–1469 (2019).
A. Bartels, F. Holtz, and R. L. Linnen, Am. Mineral. 95, 537–544 (2010).
T. H. Green, Chem. Geol. 120, 347–359 (1995).
A. W. Hoffman, Earth Planet. Sci. Lett. 90, 297–314 (1988).
R. L. Linnen and H. Keppler, Contrib. Mineral. Petrol. 128, 213–227 (1997).
A. G. McNeil, R. L. Linnen, and R. L. Flemming, Lithos 352–353, 105239 (2020).
M. Van Lichtervelde, F. Holtz, and J. M. Hanchar, Contrib. Mineral. Petrol. 160, 17–32 (2010).
ACKNOWLEDGMENTS
We are grateful to I.V. Pekov for kindly providing us with the samples of ilmenorutile, ferrotapiolite, and loparite, and are also thankful to O.G. Safonov, A.R. Kotel’nikov, and the reviewers selected by the journal editorial board for giving expert advice and comments.
Funding
This work was supported by the Russian Foundation for Basic Research, project no. 18–05–01001A, and was supported in part by the D.S. Korzhinskii Institute of Experimental Mineralogy, project no. AAAA–A18–118020590151–3.
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Translated by L. Mukhortova
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Chevychelov, V.Y., Viryus, A.A. & Shapovalov, Y.B. Partitioning of Nb, Ta, Ti, Ce, and La between Granitoid Magmatic Melts and Minerals. Dokl. Earth Sc. 495, 816–820 (2020). https://doi.org/10.1134/S1028334X20110045
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DOI: https://doi.org/10.1134/S1028334X20110045