Role of Cr Redox and Dynamics in Electrochemical Cycling of H x CrS2−δ

H x CrS2−δ is produced by the proton exchange of NaCrS2 and features alternating layers of crystalline and amorphous lamella. It exhibits superior performance as a Na-ion battery electrode compared with its parent compound with faster Na+ diffusion, higher capacity, and better cyclability. This work...

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Veröffentlicht in:	Chemistry of materials 2024-10, Vol.36 (19), p.9469-9479
Hauptverfasser:	Stiles, Joseph W., Hoff, Brianna, Curria, Maria C., Lee, Scott B., Yuan, Fang, Cheng, Guangming, Katmer, Fatmagül, Skorupskii, Grigorii, Xie, Jiaze, Leeman, Josh, Yao, Nan, White, Claire E., Arnold, Craig B., Schoop, Leslie M.
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creator	Stiles, Joseph W. Hoff, Brianna Curria, Maria C. Lee, Scott B. Yuan, Fang Cheng, Guangming Katmer, Fatmagül Skorupskii, Grigorii Xie, Jiaze Leeman, Josh Yao, Nan White, Claire E. Arnold, Craig B. Schoop, Leslie M.
description	H x CrS2−δ is produced by the proton exchange of NaCrS2 and features alternating layers of crystalline and amorphous lamella. It exhibits superior performance as a Na-ion battery electrode compared with its parent compound with faster Na+ diffusion, higher capacity, and better cyclability. This work explores the nature of the unique biphasic structure of H x CrS2−δ using both powder and single-crystal X-ray diffraction, as well as electron microscopy. Additionally, ex situ characterizations using X-ray absorption spectroscopy, X-ray total scattering, and magnetometry are employed to study the mechanism by which this superiority arises. These reveal that migration of Cr does not impede battery performance and may, in fact, be crucial to the observed performance improvements. These studies show that Cr redox is not only possible but abundant in H x CrS2−δ while accessing it in NaCrS2 at lower voltages results in irreversible structural transitions that limit cycling stability. Additionally, we highlight the potential of biphasic structures such as H x CrS2−δ to enable high performance in energy storage electrodes.
doi_str_mv	10.1021/acs.chemmater.4c01232
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These reveal that migration of Cr does not impede battery performance and may, in fact, be crucial to the observed performance improvements. These studies show that Cr redox is not only possible but abundant in H x CrS2−δ while accessing it in NaCrS2 at lower voltages results in irreversible structural transitions that limit cycling stability. 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title	Role of Cr Redox and Dynamics in Electrochemical Cycling of H x CrS2−δ
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