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Iron isotope fractionation during skarn Cu-Fe mineralization

Xue, Song; Niu, Yaoling; Chen, Yanhong; Xia, Boyang; Wang, Peiyao; Gong, Hongmei; Wang, Xiaohong; Duan, Meng

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Authors

Song Xue

Yaoling Niu

Yanhong Chen

Boyang Xia

Peiyao Wang

Hongmei Gong

Xiaohong Wang

Meng Duan



Abstract

Fe isotopes have been applied to the petrogenesis of ore deposits. However, the behavior of iron isotopes in the mineralization of porphyry-skarn deposits is still poorly understood. In this study, we report the Fe isotopes of ore mineral separations (magnetite, pyrite, chalcopyrite and pyrrhotite ) from two different skarn deposits, i.e., the Tonglvshan Cu-Fe skarn deposit developed in an oxidized hydrothermal system and the Anqing Cu skarn deposit developed in a reduced hydro-thermal system. In both deposits, the Fe isotopes of calculated equilibrium fluids are lighter than those of the intrusions responsible for the skarn and porphyry mineralization, corroborating the “light-Fe fluid” hypothesis. Interestingly, chalcopyrite in the oxidized-Tonglvshan skarn deposit has lighter Fe than chalcopyrite in the reduced-Anqing skarn deposit, which is best understood as the result of the prior precipitation of magnetite (heavy Fe) from the ore fluid in the oxidized-Tonglvshan systems and the prior precipitation of pyrrhotite (light Fe) from the ore fluid in the reduced-Anqing system. The δ 56Fe for pyrite shows an inverse correlation with δ 56Fe of magnetite in the Tonglvshan. In both deposits, the Fe isotope fractionation between chalcopyrite and pyrite is offset from equilibrium line at 350℃ and lies between the FeS-chalcopyrite equilibrium line and pyrite-chalcopyrite equilibrium line at 350℃. These observations are consistent with the FeS pathway towards pyrite formation. That is, Fe isotopes fractionation during pyrite formation depends on a path, from the initial FeS-fluid equilibrium towards the pyrite-fluid equilibrium due to the increasing extent of Fe isotopic exchange with fluids. This finding, together with the data from other deposits, allows us to propose that the pathway effect of pyrite formation in the Porphyry-skarn deposit mineralization is the dominant mechanism that controls Fe isotope characteristics.

Citation

Xue, S., Niu, Y., Chen, Y., Xia, B., Wang, P., Gong, H., …Duan, M. (2021). Iron isotope fractionation during skarn Cu-Fe mineralization. Minerals, 11(5), Article 444. https://doi.org/10.3390/min11050444

Journal Article Type Article
Acceptance Date Apr 19, 2021
Online Publication Date Apr 22, 2021
Publication Date 2021
Deposit Date Apr 20, 2021
Publicly Available Date Mar 28, 2024
Journal Minerals
Publisher MDPI
Peer Reviewed Peer Reviewed
Volume 11
Issue 5
Article Number 444
DOI https://doi.org/10.3390/min11050444

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