Measurement of Volume Changes and Associated Stresses in Ge Electrodes Due to Na/Na+ Redox Reactions

arXiv: Materials Science Pub Date : 2020-11-25 DOI:10.1149/1945-7111/abd5fc

S. Rakshit, A. Pakhare, Olivia Ruiz, M. Khoshi, E. Detsi, Huixin He, V. Sethuraman, S. Nadimpalli

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引用次数: 4

Abstract

In situ electrochemical cells were assembled with an amorphous germanium (a-Ge) film as working electrode and sodium foil as reference and counter electrode. The stresses generated in a-Ge electrodes due to electrochemical reaction with sodium were measured in real-time during the galvanostatic cycling. A specially designed patterned a-Ge electrode was cycled against sodium and the corresponding volume changes were measured using an AFM; it was observed that sodiation/desodiation of a-Ge results in more than 300% volume change, consistent with literature. The potential and stress response showed that the a-Ge film undergoes irreversible changes during the first sodiation process, but the subsequent desodiation/sodiation cycles are reversible. The stress response of the film reached steady-state after the initial sodiation and is qualitatively similar to the response of Ge during lithiation, i.e., initial linear elastic response followed by extensive plastic deformation of the film to accommodate large volume changes. However, despite being bigger ion, sodiation of Ge generated lower stress levels compared to lithiation. Consequently, the mechanical dissipation losses associated with plastic deformation are lower during sodiation process than it is for lithiation.

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Na/Na+氧化还原反应引起的Ge电极体积变化和相关应力的测量

采用非晶锗(a-Ge)薄膜作为工作电极，钠箔作为参比电极和反电极组装原位电化学电池。实时测量了a-Ge电极在恒流循环过程中与钠发生电化学反应而产生的应力。特别设计的A - ge电极与钠循环，并使用原子力显微镜测量相应的体积变化;观察到，a-Ge的钠化/脱钠导致了300%以上的体积变化，与文献一致。电位和应力响应表明，a-Ge膜在第一次钠化过程中发生了不可逆的变化，但随后的脱钠/钠化循环是可逆的。初始化后薄膜的应力响应达到稳态，其性质与锗在锂化过程中的响应相似，即初始的线弹性响应，随后薄膜发生广泛的塑性变形以适应较大的体积变化。然而，尽管离子更大，但与锂化相比，锗的钠化产生的应力水平更低。因此，在酸化过程中与塑性变形相关的机械耗散损失低于锂化过程。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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arXiv: Materials Science

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