Submit an Article
Become a reviewer
Vol 243
Pages:
259
Download volume:
RUS ENG
Geology

Deep structure and geodynamic conditions of granitoid magmatism in the Eastern Russia

Authors:
Viktor I. Alekseev
About authors
Date submitted:
2020-06-13
Date accepted:
2020-06-14
Date published:
2020-06-30

Abstract

We investigated the deep structure of the lithosphere and the geodynamic conditions of granitoid magmatism in the Eastern Russia within the borders of the Far Eastern Federal District. The relevance of the work is determined by the need to establish the geotectonic and geodynamic conditions of the granitoids petrogenesis and ore genesis in the Russian sector of the Pacific Ore Belt. The purpose of the article is to study the deep structure of the lithosphere and determine the geodynamic conditions of granitoid magmatism in the East of Russia. The author's data on the magmatism of ore regions, regional granitoids correlations, archive and published State Geological Map data, survey mapping, deep seismic sounding of the earth's crust, gravimetric survey, geothermal exploration, and other geophysical data obtained along geotraverses. The magma-controlling concentric geostructures of the region are distinguished and their deep structure is studied. The connection of plume magmatism with deep structures is traced. The chain of concentric geostructures of Eastern Russia controls the trans-regional zone of leucocratization of the earth's crust with a width of more than 1000 km, which includes the Far Eastern zone of Li-F granites. Magmacontrolling concentric geostructures are concentrated in three granitoid provinces: Novosibirsk-Chukotka, Yano-Kolyma, and Sikhote-Alin. The driving force of geodynamic processes and granitoid magmatism was mantle heat fluxes in the reduced zones of the lithospheric slab. The distribution of slab windows along the Pacific mobile belt's strike determines the location of concentric geostructures and the magnitude of granitoid magmatism in the regional provinces. Mantle diapirs are the cores of granitoid ore-magmatic systems. The location of the most important ore regions of the Eastern Russia in concentric geostructures surrounded by annuli of negative gravity anomalies is the most important regional metallogenic pattern reflecting the correlation between ore content and deep structure of the earth's crust.

Keywords:
magma-controlling concentric geostructures lithosphere mantle diapir Moho gravity anomaly granitoid magmatism Eastern Russia
10.31897/pmi.2020.3.259
Go to volume 243

References

  1. Alekseev V.I. Far East Belt of Lithium-Fluoric Granites, Ongonites and Tin Ore Zwitters. Zapiski Gornogo Instituta. 2015. Vol. 212, p. 14-20 (in Russian).
  2. Alekseev V.I. Late Mesozoic tectonic development and granitoid magmatism of Northeast Asia. Zapiski Gornogo Instituta. 2016. Vol. 217, p. 5-12 (in Russian).
  3. Geodynamics, magmatism, and metallogeny of Eastern Russia: in 2 books. Ed. by A.I. Khanchuk. Vladivostok: Dalnauka, 2006, p. 981 (in Russian).
  4. Bryanskii L.I., Bormotov V.A., Romanovsky N.P. et al. The deep structure of the ore regions of the chamber type: the Central Asian segment of the Pacific ore belt. Мoscow: Nauka, 1992, p. 156. (in Russian).
  5. Deep structure and metallogeny of Eastern Asia Ed. by A.N.Didenko, Yu.F.Malyshev, B.G.Saksin. Vladivostok: Dalnauka, 2010, p. 332 (in Russian).
  6. Malyshev Yu.F., Goroshko M.V., Rodionov S.M., Romanovsky N.P. et al. Deep structure and prospects of the search in the Far East. Krupnye i superkrupnye mestorozhdeniya: zakonomernosti razmeshcheniya i usloviya obrazovaniya. Ed. by D.V.Rundkvist. Мoscow: IGEM, 2004, p. 423-430. (in Russian).
  7. Dobretsov N.L., Kirdjashkin A.G., Kirdjashkin A.A. Deep Geodynamics . Novosibirsk: Izd-vo SO RAN, filial «Geo», 2001, p. 409 (in Russian).
  8. Egorov A.S. Deep structure and geodynamics of the lithosphere of Northern Eurasia: according to the geological and geophysical modeling data along geotravers of Russia. St. Petersburg: VSEGEI, 2004, p. 200 (in Russian).
  9. Egorov A.S., Vinokurov I.Yu., Telegin A.N. Scientific methodology for increasing the geological and prospecting efficiency of the state geological mapping of the Russian Arctic shelf. Zapiski Gornogo instituta. 2018. Vol. 233, p. 447-458. DOI: 10.31897/PMI.2018.5.447 (in Russian).
  10. Mitrofanov N.P. Metallogenic zoning: state and prospects (evidence from the tin content of the East of Russia) . Otechestvennaya geologiya. 2006. N 3, p. 12-20 (in Russian).
  11. Parfenov L.M., Berzin N.A., Hanchuk A.I. et al. Model for the formation of Central and North-Eastern Asia orogenic zones . Tikhookeanskaya geologiya. 2003. Vol. 22. N 6, p. 7-41 (in Russian).
  12. Pavlov Yu.A., Reynlib E.L. Gravity anomalies and granitoid magmatism of the south of the Far East. Мoscow: Nauka, 1982, p. 86 (in Russian).
  13. Petrishchevsky A.M. Deep structures of the earth's crust and upper mantle of the North-East of Russia according to gravimetric data. Litosfera. 2007. Vol. 1, p. 46-64 (in Russian).
  14. Vashchilov Yu.Ya., Gayday N.K., Maximov A.E. et al. Polyastenosphere of the North-East of Russia – methods of study, structure, kinematics, dynamics. Astenosfera i litosfera Severo-Vostoka Rossii (struktura, geokinematika, evolyutsiya). Magadan: SVKNII, Far East Branch RAS. 2003, p. 135-142 (in Russian).
  15. Romanovskiy N.P. Pacific segment of the Earth: deep structure, granitoid ore-magmatic systems. Khabarovsk: DVO RAN, 1999, p. 167 (in Russian).
  16. Sakhno V.G. Late Mesozoic-Cenozoic continental volcanism of East Asia. Vladivostok: Dalnauka, 2002, p. 336 (in Russian).
  17. Tectonics, deep structure and minerageny of Amur Region and adjacent territories. Ed. by G.A.Shatkov, A.S.Volskiy. St. Petersburg: VSEGEI, 2004, p. 190 (in Russian).
  18. Tectonic map of North, Central and East Asia and related regions with a scale of 1:2 500 000 / Ed. by S.P.Shokalsky, I.L.Pospelov, Chen Bin Vey et al. St. Petersburg: VSEGEI, 2013.
  19. Radkevich E.A., Babich O.N., Govorov I.N., Zimin S.S., Korostelev P.G., Lennikov A.M., Mishkin M.A., Nedashkovskii P.G., Ognyanov N.V., Ratkin V.V., Khetchikov L.N. The Pacific margin of Asia. Metallogeny. Vladivostok: DVO AN SSSR, 1991, p. 204 (in Russian).
  20. Khain V.E., Tychkov S.A., Vladimirov A.G. Collision orogenesis: a model of a subducted plate break from the oceanic lithosphere during a continental collision. Geologiya i geofizika. 1996. Vol. 37. N 1. p. 5-16. (in Russian).
  21. N 1. p. 5-16. (in Russian). Paleogeodynamic analysis of the formation of ore deposits in the Russian Far East. Rudnye mestorozhdeniya kontinentalnykh okrain. Vladivostok: Dalnauka, 2000, p. 5-34. (in Russian).
  22. Lin W., Wang Q. Late Mesozoic extensional tectonics in the North China block: a crustal response to subcontinental mantle removal? Bulletin de la Societe Geologique de France. 2006. Vol. 177. N 6, p. 287-297. DOI: 10.2113/gssgfbull.177.6.287
  23. Li K., Wang Y., Zhao J., Zhao H., Di Y. Mantle plume, large igneous province and continental breakup. Acta Seimologica Sinica. 2003. Vol. 16, p. 330-339.
  24. Nokleberg W.J., Parfenov L.M., Monger J.W.H. et al. Phanerozoic tectonic evolution of the Circum-North Pacific. U.S. Geological Survey. Professional Paper 1626. 2000, p. 122.
  25. Pirajno F. The Geology and Tectonic Settings of China's Mineral Deposits. Dordrecht, the Netherlands: Springer Science + Business Media, 2013, p. 679.
Access statistics
Abstract Views
1131
Full-Text Views
529
Cited
Scopus:
8
Crossref:
6
Cited By
1. On Determination of the Electrical Conductivity of a Local Inclusion of a Piecewise-Сonstant Isotropic Medium. Izvestiya, Physics of the Solid Earth. December 2023, Vol. 59, P. 1056-1065. DOI: 10.1134/S1069351323060101 [Scopus]
2. Magmatic system of the Klyuchevskoy volcano according to seismic data and their geomechanical interpretation. Journal of Mining Institute. 2023, Vol. 263, P. 698-714. [Scopus]
3. Dynamic response of multi-scale geophysical systems: waves and practical applications. Philosophical Transactions of the Royal Society A: Mathematical, Physical and Engineering Sciences. 28 November 2022, Vol. 380, DOI: 10.1098/rsta.2021.0403 [Scopus] (cited: 7)
4. Type intrusive series of the Far East belt of lithium-fluoric granites and its ore content. Journal of Mining Institute. 26 July 2022, Vol. 255, P. 377-392. DOI: 10.31897/PMI.2022.21 [Scopus] (cited: 2)
5. Deep structure, tectonics and geodynamics of the Sea of Okhotsk region and structures of its folded frame. Journal of Mining Institute. 2022, Vol. 257, P. 703-719. DOI: 10.31897/PMI.2022.63 [Scopus] (cited: 4)
6. Tectonic and magmatic factors of Li-F granites localization of the east of Russia. Journal of Mining Institute. 2021, Vol. 248, P. 173-179. DOI: 10.31897/PMI.2021.2.1 [Scopus] (cited: 1)
7. The possibilities of using a qualitative interpretation of the potential for creating a zonal-block model of the northern flank of the Okhotsk Sea region. 17th Conference and Exhibition Engineering and Mining Geophysics 2021. 2021, DOI: 10.3997/2214-4609.202152157 [Scopus] (cited: 1)
8. Methodological and technical aspects of gamma spectrometry using the UAV complex «GeoSCAN 401 gamma». 17th Conference and Exhibition Engineering and Mining Geophysics 2021. 2021, DOI: 10.3997/2214-4609.202152138 [Scopus]
Article Menu
Deep structure and geodynamic conditions of granitoid magmatism in the Eastern Russia

Similar articles

Features of permeability anisotropy accounting in the hydrodynamic model
2020 Roman I. Yermekov, Vitaly P. Merkulov, Oksana S. Chernova, Mikhail O. Korovin
Justification of stripping and development of a modular mine site for a combined coal mining method in Kuzbass on the example Baikaimskaya mine site
2020 Roman I. Shishkov, Valerii A. Fedorin
Description of steady inflow of fluid to wells with different configurations and various partial drilling-in
2020 Valery A. Iktissanov
Improving the geological and hydrodynamic model of a carbonate oil object by taking into account the permeability anisotropy parameter
2020 Dmitry A. Martyushev
Multi-terminal dc grid overall control with modular multilevel converters
2020 Miguel Jiménez Carrizosa, Nikola Stankovic, Jean-Claude Vannier, Yaroslav E. Shklyarskiy, Aleksei I. Bardanov
Study of the technogenesis of the Degtyarsky mine by audio-magnetotelluric express sounding
2020 Vadim A. Davydov