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锂及其合金的基本热力学、动力学和力学性能

Fundamental Thermodynamic, Kinetic, and Mechanical Properties of Lithium and Its Alloys.

作者信息

Behara Sesha Sai, Thomas Jeremiah, Van der Ven Anton

机构信息

Materials Department, University of California Santa Barbara, Santa Barbara, California 93106, United States.

出版信息

Chem Mater. 2024 Jul 30;36(15):7370-7387. doi: 10.1021/acs.chemmater.4c01279. eCollection 2024 Aug 13.

DOI:10.1021/acs.chemmater.4c01279
PMID:39156718
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC11325559/
Abstract

Lithium alloying reactions are beneficial in promoting uniform plating and stripping of lithium metal in all-solid-state batteries. First-principles calculations are performed to predict thermodynamic, kinetic, and mechanical properties of lithium and several important Li-M alloys (M = Mg, Ag, Zn, Al, Ga, In, Sn, Sb, and Bi). While the Li-Mg binary system forms a solid solution, most other lithium-metal alloys prefer stoichiometric intermetallic compounds with common local motifs that enable fast Li diffusion. Lithium and Li-rich alloys exhibit an unusually flat energy landscape along paths that connect BCC to close-packed structures like FCC and HCP, with important implications for mechanical properties. Very low migration barriers for Li diffusion that rival those of superion conductors are predicted, both in pure Li and in Li-M intermetallics. However, vacancy concentration, which is crucial for substitutional diffusion, is predicted to be low in metallic Li and most Li-M intermetallics. Compounds such as B32 LiAl and LiGa as well as D0 LiSb and LiBi exhibit structural vacancies at higher ends of their voltage windows, which together with low migration barriers leads to exceptionally high Li mobilities. In the Li-Mg solid solution, the addition of Mg is found to decrease the vacancy tracer diffusion coefficient by an order of magnitude.

摘要

锂合金化反应有利于促进全固态电池中锂金属的均匀沉积和脱嵌。通过第一性原理计算来预测锂以及几种重要的锂 - 金属合金(M = Mg、Ag、Zn、Al、Ga、In、Sn、Sb和Bi)的热力学、动力学和力学性能。虽然锂 - 镁二元体系形成固溶体,但大多数其他锂 - 金属合金更倾向于具有常见局部结构的化学计量金属间化合物,这些结构能够实现快速的锂扩散。锂和富锂合金在连接体心立方(BCC)结构与密堆积结构(如面心立方(FCC)和六方密堆积(HCP))的路径上呈现出异常平坦的能量态势,这对力学性能具有重要意义。预测在纯锂和锂 - 金属间化合物中,锂扩散的迁移势垒非常低,可与超离子导体相媲美。然而,对于替代扩散至关重要的空位浓度预计在金属锂和大多数锂 - 金属间化合物中较低。诸如B32 LiAl和LiGa以及D0 LiSb和LiBi等化合物在其电压窗口较高端呈现结构空位,这与低迁移势垒一起导致了极高的锂迁移率。在锂 - 镁固溶体中,发现添加镁会使空位示踪扩散系数降低一个数量级。

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