Simulation Assisted Design of LCO Cathode Materials With High Performance Stability

Volume 11A: 46th Design Automation Conference (DAC) Pub Date : 2020-08-17 DOI:10.1115/detc2020-22357

Zhuoyuan Zheng, Parth Bansal, Pingfeng Wang, Yumeng Li

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Abstract

Lithium cobalt oxide (LCO) cathode is one of the most commonly used positive active materials for lithium ion batteries (LIBs). However, one reliability issue that limits its applications is the presence of moisture adsorbing on the LCO cathode surface, which may react with the electrolyte and lead to detrimental effects. In this study, a novel LCO thin film cathode is proposed, by adding a layer of high diffusion resistant (003) phase of LCO as the protective coating onto the diffusion favorable (110) phase, in order to simultaneously achieve good electrochemical performance and chemical stability of the LIB. A multi-physics-based finite element model is built to investigate the performance of the cathode and the influences of the design and operation variables, including the layout the two crystal phases, the fraction of each phase and the lithiation C rate. In addition, a Gaussian Process based surrogate model is developed, using the simulated results from the FE model as training data, to efficiently explore the design space of the cathode. It is found that, the 110//003 layout cathode could provide high capacity and good rate performance; meanwhile, the 003//110 design may lead to a largely reduced capacity, especially at high lithiation C rates.

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高性能稳定LCO正极材料的仿真辅助设计

锂钴氧化物(LCO)阴极是锂离子电池(LIBs)最常用的正极活性材料之一。然而，限制其应用的一个可靠性问题是LCO阴极表面存在水分吸附，这可能与电解质发生反应并导致有害影响。本研究提出了一种新型的LCO薄膜阴极，通过在扩散良好的(110)相上添加一层高抗扩散(003)相的LCO作为保护涂层，从而同时获得锂离子电池良好的电化学性能和化学稳定性。建立了基于多物理场的有限元模型，研究了阴极的性能以及设计和操作变量(包括两相布局、每相比例和锂化率)对阴极性能的影响。此外，利用有限元模型的模拟结果作为训练数据，建立了基于高斯过程的替代模型，以有效地探索阴极的设计空间。研究发现，110//003布局阴极具有高容量和良好的倍率性能;同时，003//110设计可能会导致容量大幅降低，特别是在高锂化速率下。

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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Volume 11A: 46th Design Automation Conference (DAC)

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