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HO selective cleavage FeS bond for FeS2 electrolysis in alkaline solution

Electrochemical oxidation of pyrite is a critical process in the operation of the semiconductor solar cell and mineral electrolytic desulfurization. However, the mechanism of pyrite electrochemical oxidation is still controversial. In this work, electron spin resonance (ESR) and electrochemical char...

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Bibliographic Details
Published in:Electrochimica acta 2019-05, Vol.306, p.327-338
Main Authors: Zhang, Tong, Wang, Yingqian, Hu, Yingnan, Wang, Zhi, Chen, Jianhua, Niu, Xiaopeng, Li, Yuqiong, Gong, Xuzhong
Format: Article
Language:English
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Summary:Electrochemical oxidation of pyrite is a critical process in the operation of the semiconductor solar cell and mineral electrolytic desulfurization. However, the mechanism of pyrite electrochemical oxidation is still controversial. In this work, electron spin resonance (ESR) and electrochemical characterizations indicated the presence of hydroxyl radical (HO) and the increase in HO concentration with time, verifying the importance of HO on pyrite electrolysis. Fe(III) were increased on the surface of pyrite after electrolysis, demonstrating the HO promoted oxidation of Fe(II) to form more Fe(III). The increased concentration in S2O32−in the solution indicated that the FeS bond was more labile than the SS bond during electrolysis process. DFT results further showed that the oxidation degree of Fe(II) determined the pathway of pyrite electrolysis. The pre-oxidation of Fe(II) to Fe(III) was prerequisite for the completed oxidation of S atom, resulting the selective breakage of FeS bond. The results above revealed that the synergistic effects between HO and pH of solution for FeS2 electrolysis. [Display omitted] •HO selective cleavage FeS bond during FeS2 oxidation process.•The strength of FeS and SS bond attributed to the oxidant.•FeS2 oxidized by HO trends to produce S2O32−.•Pre-oxidation of Fe(II) was pre-requisite for S completed oxidation.
ISSN:0013-4686
1873-3859
DOI:10.1016/j.electacta.2019.03.114