材料科学
固态
原子单位
阴极
比例(比率)
电池(电)
纳米技术
工程物理
化学
物理化学
热力学
物理
量子力学
功率(物理)
作者
Yue Gong,Yuyang Chen,Qinghua Zhang,Fanqi Meng,Jinan Shi,Xinyu Liu,Xiaozhi Liu,Jienan Zhang,Hao Wang,Jiangyong Wang,Qian Yu,Ze Zhang,Qiang Xu,Ruijuan Xiao,Yong‐Sheng Hu,Lin Gu,Hong Li,Xuejie Huang,Liquan Chen
标识
DOI:10.1038/s41467-018-05833-x
摘要
Abstract Most technologically important electrode materials for lithium-ion batteries are essentially lithium ions plus a transition-metal oxide framework. However, their atomic and electronic structure evolution during electrochemical cycling remains poorly understood. Here we report the in situ observation of the three-dimensional structural evolution of the transition-metal oxide framework in an all-solid-state battery. The in situ studies LiNi 0.5 Mn 1.5 O 4 from various zone axes reveal the evolution of both atomic and electronic structures during delithiation, which is found due to the migration of oxygen and transition-metal ions. Ordered to disordered structural transition proceeds along the <100>, <110>, <111> directions and inhomogeneous structural evolution along the <112> direction. Uneven extraction of lithium ions leads to localized migration of transition-metal ions and formation of antiphase boundaries. Dislocations facilitate transition-metal ions migration as well. Theoretical calculations suggest that doping of lower valence-state cations effectively stabilize the structure during delithiation and inhibit the formation of boundaries.
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