Lithium Metal under Static and Dynamic Mechanical Loading

IF 4.6 4区 化学 Q2 ELECTROCHEMISTRY
E. Darnbrough, David E. J. Armstrong
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Abstract

Macro-scale mechanical testing and finite element analysis of lithium metal in compression have been shown to suggest methods and parameters for producing thin lithium anodes. Consideration of engineering and geometrically corrected stress experiments shows that the increasing contact area dominates the stress increase observed during the compression, not strain hardening, of lithium. Under static loading, the lithium metal stress relaxes, which means there is a speed of deformation (engineering strainrate limit of 6.4×10−5 s−1) where there is no increase in stress during compression. Constant displacement tests show that stress relaxation depends on the initial applied stress and the amount of athermal plastic work within the material. The finite element analysis shows that barrelling during compression and the requirement for high applied stresses to compress lithium with a small height-to-width ratio are friction and geometric effects, respectively. The outcomes of this work are discussed in relation to the diminishing returns of stack pressure, the difficulty in closing voids, and potential methods for designing and producing sub-micron lithium anodes.
静态和动态机械负载下的金属锂
锂金属在压缩过程中的宏观机械测试和有限元分析表明,生产薄型锂阳极的方法和参数是可行的。对工程和几何校正应力实验的考虑表明,在锂的压缩过程中,接触面积的增加主导了应力的增加,而不是应变硬化。在静态加载情况下,金属锂的应力会松弛,这意味着存在一个变形速度(工程应变速率极限为 6.4×10-5 s-1),在压缩过程中应力不会增加。恒定位移试验表明,应力松弛取决于初始施加应力和材料内部的热塑性功。有限元分析表明,压缩过程中的 "桶状 "和压缩高宽比较小的锂需要较高的外加应力分别是摩擦和几何效应。这项工作的成果将结合堆叠压力的收益递减、封闭空隙的难度以及设计和生产亚微米锂阳极的潜在方法进行讨论。
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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来源期刊
Batteries
Batteries Energy-Energy Engineering and Power Technology
CiteScore
4.00
自引率
15.00%
发文量
217
审稿时长
7 weeks
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