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Trunilina, Vera A., Prokopiev, Andrei V. (2024) Aptian Li-F Granites of the Northern Verkhoyansk–Kolyma Orogenic Belt, Eastern Russia: Composition, Genesis, and Ore Potential. Minerals, 14 (2) doi:10.3390/min14020173

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Reference TypeJournal (article/letter/editorial)
TitleAptian Li-F Granites of the Northern Verkhoyansk–Kolyma Orogenic Belt, Eastern Russia: Composition, Genesis, and Ore Potential
JournalMinerals
AuthorsTrunilina, Vera A.Author
Prokopiev, Andrei V.Author
Year2024Volume<   14   >
Issue<   2   >
URL
DOIdoi:10.3390/min14020173Search in ResearchGate
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Mindat Ref. ID17145508Long-form Identifiermindat:1:5:17145508:5
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Full ReferenceTrunilina, Vera A., Prokopiev, Andrei V. (2024) Aptian Li-F Granites of the Northern Verkhoyansk–Kolyma Orogenic Belt, Eastern Russia: Composition, Genesis, and Ore Potential. Minerals, 14 (2) doi:10.3390/min14020173
Plain TextTrunilina, Vera A., Prokopiev, Andrei V. (2024) Aptian Li-F Granites of the Northern Verkhoyansk–Kolyma Orogenic Belt, Eastern Russia: Composition, Genesis, and Ore Potential. Minerals, 14 (2) doi:10.3390/min14020173
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Abstract/NotesThis paper reports the results from an investigation on the geochemistry and petrogenesis of the Aptian Li-F granites from the Omchikandya, Burgali, and Arga Ynnakh Khaya ore fields in the northern Verkhoyansk–Kolyma orogenic belt in eastern Russia. Li-F microcline–albite granites intrude the Late Jurassic to Early Cretaceous syn-collisional granitoids. According to their geochemical composition, they are close to A-type granites and can be subdivided into low-P and high-P varieties, differing in their geochemistry and genesis. The low-P microcline–albite granites (Omchikandya massif) intrude syn-collisional biotite granites. It is assumed that the formation of their parent melt occurred at deep levels in the same magma chamber that produced biotite granites. The high-P granites (Verkhne–Burgali ethmolith and Kester harpolith) are supposed to have been derived from melts originated from a high-grade metamorphosed lower crustal protolith under the influence of deep-seated fluid flows related to diapirs of alkaline-ultrabasic or alkaline-basic composition. It is supposed that their formation was related to post-collisional extension during the early stages of the evolution of the Aptian–Late Cretaceous Indigirka belt of crust extension. All studied Li-F granites are enriched with rare metals and have associated Li deposits with accompanying Sn, W, Ta, and Nb mineralization. In the low-P Li-F Omchikandya massif, mineralization tends to occur within greisenized granites and greisens in their apical parts. In the high-P granite massifs, mineralization is found throughout their volume, and, therefore, the Verkhne–Burgali ethmolith and Kester harpolith can be considered as large ore bodies. There is a direct dependence of the content and reserves of Li2O on the content of P2O5. Minimum Li2O reserves are established in low-P Li-F microcline–albite granites of the Polyarnoe deposit of the Omchikandya ore field, whereas in the high-P granites of the Verkhne–Burgali and Kester deposits, the Li2O reserves are significantly higher.

Map of Localities

Locality Pages

LocalityCitation Details
Burgali Ore Field, Tomponsky District, Sakha, Russia
Polyarnoe Deposit, Omchikandya Ore Field, Ust-Yansky District, Sakha, Russia
Arga-Ynnakh-Khaya granite Massif, Yana-Adycha Region, Yana River Basin, Verkhoyansk District, Sakha, Russia
Kester deposit, Kester harpolith, Arga-Ynnakh-Khaya granite Massif, Yana-Adycha Region, Yana River Basin, Verkhoyansk District, Sakha, Russia

Mineral Occurrences

LocalityMineral(s)
Burgali Ore Field, Tomponsky District, Sakha, Russia A-type granite, Albite, Alkali Feldspar, Allanite Group, Almandine, Amblygonite, Amphibole Supergroup, Amphibolite, Andesine, Apatite, Aplite, Augite, Biotite, Calcium Amphibole Subgroup, Cassiterite, Columbite-(Fe)-Columbite-(Mn) Series, Dacite, Diorite, Eastonite, Feldspar Group, Ferrosilite, Gedrite, Granite, Granitoid, Granodiorite, Greisen, Hornblende, Ilmenite, K Feldspar, Leucogranite, Magnetite, Microcline, Monazite Group, Montebrasite, Muscovite, Muscovite-biotite granite, Orthoclase, Pegmatite, Pegmatoid, Plagioclase, Polylithionite, Porphyry, Pyrite, Pyrrhotite, Quartz, Restite, S-type granite, Sandstone, Siderophyllite, Siltstone, Spodumene, Stibnite, Syenite, Syenogranite, Tantalite, Titanium-bearing Magnetite, Tonalite, Topaz, Tourmaline, Xenotime, Zinnwaldite, Zircon
Polyarnoe Deposit, Omchikandya Ore Field, Ust-Yansky District, Sakha, Russia A-type granite, Albite, Apatite, Aplite, Biotite, Biotite granite, Cassiterite, Columbite-(Fe)-Columbite-(Mn) Series, Corundum, Eastonite, Feldspar Group, Fluorite, Gabbro, Granite, Granitoid, Granodiorite, Greisen, Ilmenite, K Feldspar, Kaolinite, Leucogranite, Magnetite, Metagraywacke, Microcline, Monazite Group, Monzogranite, Oligoclase, Orthoclase, Pegmatoid, Porphyry, Protolithionite, Quartz, Rutile, S-type granite, Shoshonite, Siderophyllite, Syenite, Tantalite, Titanium-bearing Magnetite, Topaz, Tourmaline, Trilithionite, Wolframite Group, Zircon
Arga-Ynnakh-Khaya granite Massif, Yana-Adycha Region, Yana River Basin, Verkhoyansk District, Sakha, Russia A-type granite, Albite, Allanite Group, Almandine, Amblygonite, Anatase, Andesine, Aplite, Augite, Biotite, Calcium Amphibole Subgroup, Cassiterite, Columbite-(Fe)-Columbite-(Mn) Series, Cordierite, Dacite, Eastonite, Feldspar Group, Ferrosilite, Fluorapatite, Fluorite, Gedrite, Granite, Granitoid, Granodiorite, Greisen, Hastingsite, Hornblende, Ilmenite, K Feldspar, Kaolinite, Kësterite, Kyanite, Lepidolite, Leucogranite, Magnetite, Magniotriplite, Metamudstone, Microcline, Monazite Group, Montebrasite, Monzogranite, Muscovite, Muscovite-biotite granite, Native Iron, Oligoclase, Orthoclase, Perthite, Phengite, Polylithionite, Pyrrhotite, Quartz, Rutile, S-type granite, Siderophyllite, Spodumene, Syenite, Syenogranite, Tantalite, Titanite, Titanium-bearing Magnetite, Tonalite, Topaz, Tourmaline, Trilithionite, Tschermakite, Wagnerite, Xenotime, Zircon
Kester deposit, Kester harpolith, Arga-Ynnakh-Khaya granite Massif, Yana-Adycha Region, Yana River Basin, Verkhoyansk District, Sakha, Russia Albite, Amblygonite, Cassiterite, Columbite-(Fe)-Columbite-(Mn) Series, Elbaite, Granite, Greisen, Microcline, Montebrasite, Pegmatite, Quartz, Tantalite, Topaz

See Also

These are possibly similar items as determined by title/reference text matching only.

Trunilina, Vera A., Prokopiev, Andrei V. (2022) Petrology of Granites of the Tommot Rare-Earth Ore Field (Verkhoyansk–Kolyma Orogenic Belt) Minerals, 12 (11) 1347 doi:10.3390/min12111347
Trunilina, Vera A., Prokopiev, Andrei V. (2021) Ore-Bearing Magmatic Systems with Complex Sn–Au–Ag Mineralization in the North-Eastern Verkhoyansk–Kolyma Orogenic Belt, Russia. Minerals, 11 (3) 266 doi:10.3390/min11030266
Trunilina, Vera A. (2021) Evolution of the Late Mesozoic Magmatism of the Omulevka Terrane of the North Part of the Verkhoyansk–Kolyma Orogenic Region. Minerals, 11 (11) 1208 doi:10.3390/min11111208
Trunilina, Vera (2021) Petrology of Granitoids of the Selennyakh Ridge (Verkhoyansk-Kolyma Orogenic Belt) IOP Conference Series: Earth and Environmental Science, 906 (1) 12084pp. doi:10.1088/1755-1315/906/1/012084
Trunilina, V. A., Orlov, Yu. S., Zaitsev, A. I., Roev, S. P. (2019) High-Phosphorous Lithium–Fluorine Granites of Eastern Yakutia (Verkhoyansk–Kolyma Orogenic Region) Russian Journal of Pacific Geology, 13 (1) 82-98 doi:10.1134/s1819714019010068
Trunilina, V. A., Roev, S. P. (2019) Petrology of granites in the Geramdachansky massif (Verkhoyansk-Kolyma orogenic region). IOP Conference Series: Earth and Environmental Science, 362. 12145pp. doi:10.1088/1755-1315/362/1/012145
Trunilina, V.A., , , Orlov, Yu.S., Zaitsev, A.I., Roev, S.P., , , , , , (2019) HIGH-PHOSPHOROUS LITHIUM-FLUORINE GRANITES OF EASTERN YAKUTIA (VERKHOYANSK-KOLYMA OROGENIC REGION). Tikhookeanskaya Geologiya, 38 (1). 86-101 doi:10.30911/0207-4028-2019-38-1-86-101
Prokopiev, Andrei V., Ershova, Victoria B., Stockli, Daniel F. (2021) Detrital Zircon U-Pb Data for Jurassic–Cretaceous Strata from the South-Eastern Verkhoyansk-Kolyma Orogen—Correlations to Magmatic Arcs of the North-East Asia Active Margin. Minerals, 11 (3) 291 doi:10.3390/min11030291
Fridovsky, V. Y. (2018). Structural control of orogenic gold deposits of the Verkhoyansk-Kolyma folded region, northeast Russia. Ore Geology Reviews, 103, 38-55.
Trunilina, V. A., Roev, S. P., & Orlov, Y. S. (2015). Mineralogy, petro-, and geochemistry of the composite dikes of the Takalkan ore-magmatic cluster (Polousny synclinorium of the Verkhoyansk–Kolyma orogenic area). Russian Journal of Pacific Geology, 9(5), 359-372.
Parfenov, L. M., Prokopiev, A. V., Gaiduk, V. V. (1995) Cretaceous frontal thrusts of the Verkhoyansk fold belt, eastern Siberia. Tectonics, 14 (2). 342-358 doi:10.1029/94tc03088
 
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