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Geology, Composition, and Physicochemical Model of Sparry Magnesite Deposits of the Southern Urals. / Krupenin, M.T.; Kol'tsov, A.B.

In: Geology of Ore Deposits, Vol. 59, No. 1, 2017, p. 14-35.

Research output: Contribution to journalArticlepeer-review

Harvard

Krupenin, MT & Kol'tsov, AB 2017, 'Geology, Composition, and Physicochemical Model of Sparry Magnesite Deposits of the Southern Urals', Geology of Ore Deposits, vol. 59, no. 1, pp. 14-35. https://doi.org/10.1134/S1075701517010044

APA

Krupenin, M. T., & Kol'tsov, A. B. (2017). Geology, Composition, and Physicochemical Model of Sparry Magnesite Deposits of the Southern Urals. Geology of Ore Deposits, 59(1), 14-35. https://doi.org/10.1134/S1075701517010044

Vancouver

Krupenin MT, Kol'tsov AB. Geology, Composition, and Physicochemical Model of Sparry Magnesite Deposits of the Southern Urals. Geology of Ore Deposits. 2017;59(1):14-35. https://doi.org/10.1134/S1075701517010044

Author

Krupenin, M.T. ; Kol'tsov, A.B. / Geology, Composition, and Physicochemical Model of Sparry Magnesite Deposits of the Southern Urals. In: Geology of Ore Deposits. 2017 ; Vol. 59, No. 1. pp. 14-35.

BibTeX

@article{3a42eeb8c3be46ee9927aa77368fc3e7,
title = "Geology, Composition, and Physicochemical Model of Sparry Magnesite Deposits of the Southern Urals",
abstract = "The metasomatic nature of magnesite formation, sequence and timing of geological processes, and solution sources have been established by comprehensive geological and geochemical study of the typical Satka and Ismakaevo deposits of sparry magnesite in the South Ural province. The hydrothermal metasomatic formation of magnesite is related to injection of high-Mg evaporite brine into heated carbonate rocks within permeable rift zones. The numerical physicochemical simulation of solution–rock interaction allowed us to determine the necessary prerequisites for sparry magnesite formation: the occurrence of marine salt solutions with a high Mg/Ca ratio and heating of solutions before or during their interaction with host carbonate rocks. The contribution of compositionally various solution sources, the temperature variation regime, proportions of CO2 and H2S concentrations in solution created specific features of particular deposits.",
author = "M.T. Krupenin and A.B. Kol'tsov",
year = "2017",
doi = "10.1134/S1075701517010044",
language = "English",
volume = "59",
pages = "14--35",
journal = "Geology of Ore Deposits",
issn = "1075-7015",
publisher = "МАИК {"}Наука/Интерпериодика{"}",
number = "1",

}

RIS

TY - JOUR

T1 - Geology, Composition, and Physicochemical Model of Sparry Magnesite Deposits of the Southern Urals

AU - Krupenin, M.T.

AU - Kol'tsov, A.B.

PY - 2017

Y1 - 2017

N2 - The metasomatic nature of magnesite formation, sequence and timing of geological processes, and solution sources have been established by comprehensive geological and geochemical study of the typical Satka and Ismakaevo deposits of sparry magnesite in the South Ural province. The hydrothermal metasomatic formation of magnesite is related to injection of high-Mg evaporite brine into heated carbonate rocks within permeable rift zones. The numerical physicochemical simulation of solution–rock interaction allowed us to determine the necessary prerequisites for sparry magnesite formation: the occurrence of marine salt solutions with a high Mg/Ca ratio and heating of solutions before or during their interaction with host carbonate rocks. The contribution of compositionally various solution sources, the temperature variation regime, proportions of CO2 and H2S concentrations in solution created specific features of particular deposits.

AB - The metasomatic nature of magnesite formation, sequence and timing of geological processes, and solution sources have been established by comprehensive geological and geochemical study of the typical Satka and Ismakaevo deposits of sparry magnesite in the South Ural province. The hydrothermal metasomatic formation of magnesite is related to injection of high-Mg evaporite brine into heated carbonate rocks within permeable rift zones. The numerical physicochemical simulation of solution–rock interaction allowed us to determine the necessary prerequisites for sparry magnesite formation: the occurrence of marine salt solutions with a high Mg/Ca ratio and heating of solutions before or during their interaction with host carbonate rocks. The contribution of compositionally various solution sources, the temperature variation regime, proportions of CO2 and H2S concentrations in solution created specific features of particular deposits.

U2 - 10.1134/S1075701517010044

DO - 10.1134/S1075701517010044

M3 - Article

VL - 59

SP - 14

EP - 35

JO - Geology of Ore Deposits

JF - Geology of Ore Deposits

SN - 1075-7015

IS - 1

ER -

ID: 7736658