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The Mushiston Sn deposit in Tajik Tien Shan as the type locality for stannite-cassiterite-hydrostannate mineralization: New mineral chemistry data and genetic constraints. / Konopelko, Dmitry L.; Cherny, Ruslan I.; Petrov, Sergei V. и др.

в: Journal of Geochemical Exploration, Том 239, 107017, 08.2022.

Результаты исследований: Научные публикации в периодических изданияхстатьяРецензирование

Harvard

Konopelko, DL, Cherny, RI, Petrov, SV, Strekopytov, S, Seltmann, R, Vlasenko, NS, Strekopytov, VV, Mamadjanov, YM, Wang, XS, Plotinskaya, OY & Andreeva, EM 2022, 'The Mushiston Sn deposit in Tajik Tien Shan as the type locality for stannite-cassiterite-hydrostannate mineralization: New mineral chemistry data and genetic constraints', Journal of Geochemical Exploration, Том. 239, 107017. https://doi.org/10.1016/j.gexplo.2022.107017

APA

Konopelko, D. L., Cherny, R. I., Petrov, S. V., Strekopytov, S., Seltmann, R., Vlasenko, N. S., Strekopytov, V. V., Mamadjanov, Y. M., Wang, X. S., Plotinskaya, O. Y., & Andreeva, E. M. (2022). The Mushiston Sn deposit in Tajik Tien Shan as the type locality for stannite-cassiterite-hydrostannate mineralization: New mineral chemistry data and genetic constraints. Journal of Geochemical Exploration, 239, [107017]. https://doi.org/10.1016/j.gexplo.2022.107017

Vancouver

Konopelko DL, Cherny RI, Petrov SV, Strekopytov S, Seltmann R, Vlasenko NS и др. The Mushiston Sn deposit in Tajik Tien Shan as the type locality for stannite-cassiterite-hydrostannate mineralization: New mineral chemistry data and genetic constraints. Journal of Geochemical Exploration. 2022 авг.;239:107017. doi: 10.1016/j.gexplo.2022.107017

Author

BibTeX

@article{bd32f7ef7b0d43809c1a7fb95199da94,
title = "The Mushiston Sn deposit in Tajik Tien Shan as the type locality for stannite-cassiterite-hydrostannate mineralization: New mineral chemistry data and genetic constraints",
abstract = "The Mushiston Sn deposit is located in Hercynian South Tien Shan fold and thrust belt on the territory of Tajikistan. Unique features of the deposit include sulphide-dominated composition of the primary ore with stannite being the main ore mineral, and a thick oxidation zone where stannite is replaced by various hydrostannate minerals. Therefore, the Mushiston deposit is a rare example of stannite-cassiterite-hydrostannate mineralization and the type locality where several new hydrostannate minerals such as mushistonite, natanite and vismirnovite were first described. The structure of the deposit is characterized by a series of subvertical, generally NE-trending mineralized veins crosscutting the limbs of the large submeridional anticline composed of Paleozoic sedimentary strata. The primary ore mainly consists of a quartz-stannite group minerals – cassiterite mineral assemblage with other subordinate sulfides and minor sulfosalts. A 200–400 m thick zone of supergene oxidation is developed in the upper part of the deposit. New mineral chemistry data reveal compositional variations of the stannite group minerals, sphalerite and sulfosalts. The chemical compositions of co-existing stannite group minerals and sphalerite indicate extensive mutual substitution between Fe and Zn. The use of stannite-sphalerite geothermometry constrains the temperature for the main stage of the primary ore formation in the range of 257–308 °C. The tetrahedrite geothermometry yields temperatures in the range of 170–200 °C, which is in agreement with geological evidence for the late crystallization of sulfosalts at lower temperatures. The geological and mineralogical features of the Mushiston Sn deposit correspond to the mesothermal hydrothermal vein system mainly developed under intermediate sulfidation conditions. The proposed genetic model for the Mushiston deposit suggests formation of brittle fractures in the thermal aureole above the concealed causative granitoid intrusion, by regional analogue of Permo-Carboniferous age, where magmatic fluids mixed with meteoric water to form the hydrothermal system responsible for deposition of cassiterite-sulfide ore.",
keywords = "Mushiston deposit, ore mineral chemistry, stannite-hydrostannate mineralization, stannite-sphalerite geothermometry",
author = "Konopelko, {Dmitry L.} and Cherny, {Ruslan I.} and Petrov, {Sergei V.} and Stanislav Strekopytov and Reimar Seltmann and Vlasenko, {Natalia S.} and Strekopytov, {Vladislav V.} and Mamadjanov, {Yunus M.} and Wang, {Xin Shui} and Plotinskaya, {Olga Yu} and Andreeva, {Elena M.}",
note = "Funding Information: We would like to thank Tatiana Burova who provided additional materials and samples from the Mushiston deposit for this study. We appreciate thorough and constructive reviews of Fernando Noronha and Lisard Torr{\'o} that helped to improve the manuscript. DK was supported by the Russian Science Foundation , Project # 21-77-20022 . This is a contribution to the IGCP-662 Project “Orogenic Architecture and Crustal Growth from Accretion to Collision” under the patronage of UNESCO and IUGS. Funding Information: The authors declare the following financial interests/personal relationships which may be considered as potential competing interests: Konopelko Dmitry reports financial support was provided by Russian Science Foundation. Publisher Copyright: {\textcopyright} 2022 Elsevier B.V.",
year = "2022",
month = aug,
doi = "10.1016/j.gexplo.2022.107017",
language = "English",
volume = "239",
journal = "Journal of Geochemical Exploration",
issn = "0375-6742",
publisher = "Elsevier",

}

RIS

TY - JOUR

T1 - The Mushiston Sn deposit in Tajik Tien Shan as the type locality for stannite-cassiterite-hydrostannate mineralization: New mineral chemistry data and genetic constraints

AU - Konopelko, Dmitry L.

AU - Cherny, Ruslan I.

AU - Petrov, Sergei V.

AU - Strekopytov, Stanislav

AU - Seltmann, Reimar

AU - Vlasenko, Natalia S.

AU - Strekopytov, Vladislav V.

AU - Mamadjanov, Yunus M.

AU - Wang, Xin Shui

AU - Plotinskaya, Olga Yu

AU - Andreeva, Elena M.

N1 - Funding Information: We would like to thank Tatiana Burova who provided additional materials and samples from the Mushiston deposit for this study. We appreciate thorough and constructive reviews of Fernando Noronha and Lisard Torró that helped to improve the manuscript. DK was supported by the Russian Science Foundation , Project # 21-77-20022 . This is a contribution to the IGCP-662 Project “Orogenic Architecture and Crustal Growth from Accretion to Collision” under the patronage of UNESCO and IUGS. Funding Information: The authors declare the following financial interests/personal relationships which may be considered as potential competing interests: Konopelko Dmitry reports financial support was provided by Russian Science Foundation. Publisher Copyright: © 2022 Elsevier B.V.

PY - 2022/8

Y1 - 2022/8

N2 - The Mushiston Sn deposit is located in Hercynian South Tien Shan fold and thrust belt on the territory of Tajikistan. Unique features of the deposit include sulphide-dominated composition of the primary ore with stannite being the main ore mineral, and a thick oxidation zone where stannite is replaced by various hydrostannate minerals. Therefore, the Mushiston deposit is a rare example of stannite-cassiterite-hydrostannate mineralization and the type locality where several new hydrostannate minerals such as mushistonite, natanite and vismirnovite were first described. The structure of the deposit is characterized by a series of subvertical, generally NE-trending mineralized veins crosscutting the limbs of the large submeridional anticline composed of Paleozoic sedimentary strata. The primary ore mainly consists of a quartz-stannite group minerals – cassiterite mineral assemblage with other subordinate sulfides and minor sulfosalts. A 200–400 m thick zone of supergene oxidation is developed in the upper part of the deposit. New mineral chemistry data reveal compositional variations of the stannite group minerals, sphalerite and sulfosalts. The chemical compositions of co-existing stannite group minerals and sphalerite indicate extensive mutual substitution between Fe and Zn. The use of stannite-sphalerite geothermometry constrains the temperature for the main stage of the primary ore formation in the range of 257–308 °C. The tetrahedrite geothermometry yields temperatures in the range of 170–200 °C, which is in agreement with geological evidence for the late crystallization of sulfosalts at lower temperatures. The geological and mineralogical features of the Mushiston Sn deposit correspond to the mesothermal hydrothermal vein system mainly developed under intermediate sulfidation conditions. The proposed genetic model for the Mushiston deposit suggests formation of brittle fractures in the thermal aureole above the concealed causative granitoid intrusion, by regional analogue of Permo-Carboniferous age, where magmatic fluids mixed with meteoric water to form the hydrothermal system responsible for deposition of cassiterite-sulfide ore.

AB - The Mushiston Sn deposit is located in Hercynian South Tien Shan fold and thrust belt on the territory of Tajikistan. Unique features of the deposit include sulphide-dominated composition of the primary ore with stannite being the main ore mineral, and a thick oxidation zone where stannite is replaced by various hydrostannate minerals. Therefore, the Mushiston deposit is a rare example of stannite-cassiterite-hydrostannate mineralization and the type locality where several new hydrostannate minerals such as mushistonite, natanite and vismirnovite were first described. The structure of the deposit is characterized by a series of subvertical, generally NE-trending mineralized veins crosscutting the limbs of the large submeridional anticline composed of Paleozoic sedimentary strata. The primary ore mainly consists of a quartz-stannite group minerals – cassiterite mineral assemblage with other subordinate sulfides and minor sulfosalts. A 200–400 m thick zone of supergene oxidation is developed in the upper part of the deposit. New mineral chemistry data reveal compositional variations of the stannite group minerals, sphalerite and sulfosalts. The chemical compositions of co-existing stannite group minerals and sphalerite indicate extensive mutual substitution between Fe and Zn. The use of stannite-sphalerite geothermometry constrains the temperature for the main stage of the primary ore formation in the range of 257–308 °C. The tetrahedrite geothermometry yields temperatures in the range of 170–200 °C, which is in agreement with geological evidence for the late crystallization of sulfosalts at lower temperatures. The geological and mineralogical features of the Mushiston Sn deposit correspond to the mesothermal hydrothermal vein system mainly developed under intermediate sulfidation conditions. The proposed genetic model for the Mushiston deposit suggests formation of brittle fractures in the thermal aureole above the concealed causative granitoid intrusion, by regional analogue of Permo-Carboniferous age, where magmatic fluids mixed with meteoric water to form the hydrothermal system responsible for deposition of cassiterite-sulfide ore.

KW - Mushiston deposit

KW - ore mineral chemistry

KW - stannite-hydrostannate mineralization

KW - stannite-sphalerite geothermometry

UR - http://www.scopus.com/inward/record.url?scp=85130976596&partnerID=8YFLogxK

U2 - 10.1016/j.gexplo.2022.107017

DO - 10.1016/j.gexplo.2022.107017

M3 - Article

AN - SCOPUS:85130976596

VL - 239

JO - Journal of Geochemical Exploration

JF - Journal of Geochemical Exploration

SN - 0375-6742

M1 - 107017

ER -

ID: 36201561