锂离子电池电极/电解质界面电化学反应的电子结构建模

K. Leung
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引用次数: 121

摘要

本文综述了近年来锂离子电池电极/电解质界面从头算分子动力学的研究进展。我们的目标是向实验学家介绍适用于模型的模拟技术,这些模型可以说是迄今为止最忠实于实验条件的,并向理论家强调,这一学科固有的跨学科性质需要弥合固体和液体状态观点之间的差距。我们考虑了液体碳酸乙烯(EC)在锂插层石墨、锂金属、氧化石墨和尖晶石锰氧化物表面上的分解。这些计算是在更广泛研究的水-固界面的背景下进行的。我们的主题包括动力学控制的双电子诱导反应,EC中先前被忽视的化学键的断裂,以及电子隧穿。未来在原子长度尺度上对电池进行建模的工作需要超越最先进的能力,这强调了应用电池研究可以并且可以…
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Electronic Structure Modeling of Electrochemical Reactions at Electrode/Electrolyte Interfaces in Lithium Ion Batteries
We review recent ab initio molecular dynamics studies of electrode/electrolyte interfaces in lithium ion batteries. Our goals are to introduce experimentalists to simulation techniques applicable to models which are arguably most faithful to experimental conditions so far, and to emphasize to theorists that the inherently interdisciplinary nature of this subject requires bridging the gap between solid and liquid state perspectives. We consider liquid ethylene carbonate (EC) decomposition on lithium intercalated graphite, lithium metal, oxide-coated graphite, and spinel manganese oxide surfaces. These calculations are put in the context of more widely studied water–solid interfaces. Our main themes include kinetically controlled two-electron-induced reactions, the breaking of a previously much neglected chemical bond in EC, and electron tunneling. Future work on modeling batteries at atomic length scales requires capabilities beyond state-of-the-art, which emphasizes that applied battery research can and s...
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