Constraints of fO▲2 and fS▲2 on the Paragenesis and Separation of Mineral Assemblages in Hongqi Pb-Zn Deposit， Xiuyan

doi:10.12068/j.issn.1005-3026.2020.07.014

Abstract

Abstract: Based on field investigation and microscopic mineral identification results， the thermodynamic lgfo₂-lgfs₂ parameter state diagrams of Fe-Pb-Zn-Cu-O-S system were plotted by calculating the oxygen-sulfur fugacity of main minerals in Hongqi Pb-Zn deposit， Xiuyan， at different temperatures. The controlling factors and physicochemical conditions of minerals paragenesis were studied to provide a reference for solving the ore-forming fluid evolution of the same type of deposits in the Liaoji metallogenic belt. The results indicated that T， fo₂， fs₂ are key factors for the precipitation of ore-forming elements and the paragenesis of mineral assemblage. The large stable range of sphalerite is controlled by fo₂， fs₂， making Zn⁺ still transportable after galena and pyrite precipitation. Cooling is conducive to mineralization because the minimum lgfo₂， lgfs₂ formed by minerals decrease when the temperature is lowered. The tectonic fracture zone provides a migration channel for fluid， and it is also a good geochemical barrier. In prospecting process， it is important to pay special attention to the places with fault structure， gossan and medium-low temperature alterations.

Key words: Liaoji metallogenic belt, Xiuyan, Hongqi Pb-Zn deposit, lgfo₂-lgfs₂ diagram, mineral assemblage

CLC Number:

TP20

WEN Shou-qin， TANG Tie-qiao， XIE Wei， FU Jian-fei. Constraints of f_O▲2 and f_S▲2 on the Paragenesis and Separation of Mineral Assemblages in Hongqi Pb-Zn Deposit， Xiuyan[J]. Journal of Northeastern University Natural Science, 2020, 41(7): 999-1007.

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Constraints of f_O▲2 and f_S▲2 on the Paragenesis and Separation of Mineral Assemblages in Hongqi Pb-Zn Deposit， Xiuyan

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