Microstructure-resolved degradation simulation of lithium-ion batteries in space applications

IF 5.4 Q2 CHEMISTRY, PHYSICAL Journal of Power Sources Advances Pub Date : 2022-03-01 DOI:10.1016/j.powera.2022.100083

Linda J. Bolay , Tobias Schmitt , Simon Hein , Omar S. Mendoza-Hernandez , Eiji Hosono , Daisuke Asakura , Koichi Kinoshita , Hirofumi Matsuda , Minoru Umeda , Yoshitsugu Sone , Arnulf Latz , Birger Horstmann

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引用次数: 7

Abstract

In-orbit satellite REIMEI, developed by the Japan Aerospace Exploration Agency, has been relying on off-the-shelf Li-ion batteries since its launch in 2005. The performance and durability of Li-ion batteries is impacted by various degradation mechanisms, one of which is the growth of the solid-electrolyte interphase (SEI). In this article, we analyse the REIMEI battery and parameterize a full-cell model with electrochemical cycling data, computer tomography images, and capacity fading experiments using image processing and surrogate optimization. We integrate a recent model for SEI growth into a full-cell model and simulate the degradation of batteries during cycling. To validate our model, we use experimental and in-flight data of the satellite batteries. Our combination of SEI growth model and microstructure-resolved 3D simulation shows, for the first time, experimentally observed inhomogeneities in the SEI thickness throughout the negative electrode for the degraded cells.

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空间应用中锂离子电池微结构降解模拟

由日本宇宙航空研究开发机构开发的在轨卫星REIMEI自2005年发射以来一直依赖于现成的锂离子电池。锂离子电池的性能和耐久性受到多种降解机制的影响，其中一种降解机制是固体-电解质界面相(SEI)的生长。在本文中，我们分析了REIMEI电池，并利用电化学循环数据、计算机断层扫描图像和容量衰落实验，通过图像处理和代理优化，参数化了一个全电池模型。我们将最近的SEI生长模型整合到一个全电池模型中，并模拟了电池在循环过程中的退化。为了验证我们的模型，我们使用了卫星电池的实验和飞行数据。我们将SEI生长模型和微观结构分辨率的3D模拟相结合，首次在实验中观察到降解细胞负极上SEI厚度的不均匀性。

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