Investigating the Temperature Dependency of Trimethyl Aluminum Assisted Atomic Surface Reduction of Li and Mn Rich NCM

Eliran Evenstein, Sarah Taragin, A. Saha, M. Noked, Rosy Rosy
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Abstract

Most next-generation electrode materials are prone to interfacial degradation, which eventually spreads to the bulk and impairs electrochemical performance. One promising method for reducing interfacial degradation is to surface engineer the electrode materials to form an artificial cathode electrolyte interphase as a protective layer. Nevertheless, the majority of coating techniques entail wet processes, high temperatures, or exposure to ambient conditions. These experimental conditions are only sometimes conducive and can adversely affect the material structure or composition. Therefore, we investigate the efficacy of a low-temperature, facile atomic surface reduction (ASR) using trimethylaluminum vapors as a surface modification strategy for Li and Mn-rich NCM (LMR-NCM). The results presented herein manifest that the extent of TMA-assisted ASR is temperature-dependent. All tested temperatures demonstrated improved electrochemical performance. However, ASR carried out at temperatures > 100°C was more effective in preserving the structural integrity and improving the electrochemical performance. Electrochemical testing revealed improved rate capabilities, cycling stability, and capacity retention of ASR-treated LMR-NCM. Additionally, post-cycling high-resolution scanning electron microscopy analysis verified that after extended cycling, ASR carried out at T > 100°C showed no cracks or cleavage, demonstrating the efficiency of this method in preventing surface degradation.
研究三甲基铝辅助原子表面还原富含锂和锰的 NCM 的温度依赖性
大多数下一代电极材料都容易发生界面降解,这种降解最终会扩散到体层,损害电化学性能。减少界面降解的一种可行方法是对电极材料进行表面工程处理,形成人工阴极电解质间相作为保护层。然而,大多数涂层技术都需要湿法工艺、高温或暴露在环境条件下。这些实验条件有时会对材料结构或成分产生不利影响。因此,我们研究了利用三甲基铝蒸汽进行低温、简易原子表面还原 (ASR) 作为富锂和富锰 NCM(LMR-NCM)表面改性策略的功效。本文介绍的结果表明,三甲基铝辅助原子表面还原的程度与温度有关。所有测试温度下的电化学性能都有所改善。不过,在温度大于 100°C 时进行的 ASR 更能有效地保持结构完整性和改善电化学性能。电化学测试表明,经过 ASR 处理的 LMR-NCM 的速率能力、循环稳定性和容量保持率均有所提高。此外,循环后的高分辨率扫描电子显微镜分析证实,在温度大于 100°C 的条件下进行的 ASR 经过长时间循环后,没有出现裂纹或断裂,证明这种方法能有效防止表面降解。
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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