Kim Jung-Hyun, Pieczonka Nicholas P W, Yang Li
Chemical & Materials Systems Laboratory, General Motors Global R&D Center, Warren, Michigan 48090 (USA).
Chemphyschem. 2014 Jul 21;15(10):1940-54. doi: 10.1002/cphc.201400052. Epub 2014 May 23.
Lithium-ion (Li-ion) batteries have been developed for electric vehicle (EV) applications, owing to their high energy density. Recent research and development efforts have been devoted to finding the next generation of cathode materials for Li-ion batteries to extend the driving distance of EVs and lower their cost. LiNi(0.5)Mn(1.5)O(4) (LNMO) high-voltage spinel is a promising candidate for a next-generation cathode material based on its high operating voltage (4.75 V vs. Li), potentially low material cost, and excellent rate capability. Over the last decade, much research effort has focused on achieving a fundamental understanding of the structure-property relationship in LNMO materials. Recent studies, however, demonstrated that the most critical barrier for the commercialization of high-voltage spinel Li-ion batteries is electrolyte decomposition and concurrent degradative reactions at electrode/electrolyte interfaces, which results in poor cycle life for LNMO/graphite full cells. Despite scattered reports addressing these processes in high-voltage spinel full cells, they have not been consolidated into a systematic review article. With this perspective, emphasis is placed herein on describing the challenges and the various approaches to mitigate electrolyte decomposition and other degradative reactions in high-voltage spinel cathodes in full cells.
锂离子(Li-ion)电池因其高能量密度而被开发用于电动汽车(EV)应用。最近的研发工作致力于寻找下一代锂离子电池的阴极材料,以延长电动汽车的行驶里程并降低成本。LiNi(0.5)Mn(1.5)O(4)(LNMO)高压尖晶石作为下一代阴极材料具有很大潜力,基于其高工作电压(相对于锂为4.75 V)、潜在的低成本以及出色的倍率性能。在过去十年中,大量研究工作集中在对LNMO材料的结构-性能关系达成基本理解。然而,最近的研究表明,高压尖晶石锂离子电池商业化的最关键障碍是电解质分解以及电极/电解质界面处同时发生的降解反应,这导致LNMO/石墨全电池的循环寿命较差。尽管有一些零散的报告涉及高压尖晶石全电池中的这些过程,但它们尚未被整合到一篇系统的综述文章中。基于此观点,本文重点描述在全电池中缓解高压尖晶石阴极中电解质分解和其他降解反应的挑战及各种方法。
