阴极
材料科学
离子半径
氧化物
纳米结构
结构稳定性
相(物质)
离子键合
离子
纳米尺度
材料设计
化学工程
半径
容量损失
化学物理
纳米技术
电解质
电极
物理化学
复合材料
化学
冶金
计算机科学
有机化学
工程类
结构工程
计算机安全
作者
Qinwen Cui,Yi Li,Yining Li,Wujie Qiu,Jianjun Liu
出处
期刊:ACS Nano
[American Chemical Society]
日期:2024-01-11
卷期号:18 (3): 2302-2311
被引量:18
标识
DOI:10.1021/acsnano.3c10193
摘要
Li-excess oxide cathodes have received increasing attention due to their high capacity derived from accumulated cation and anion redox activity. However, Li-excess layered oxides suffer from capacity and voltage decay due to the irreversible phase transition, while cation-disordered cathodes also have the problems of poor cycling stability and rate capability. The rocksalt oxides with a layered-disordered coexistence nanostructure can combine the advantages of both phases such as the inherent high capacity of Li-excess oxides, good rate capability of the layered phase, and structural stability resulting from the intergrown disordered phase. Herein, for rational design, we developed a descriptor by correlating the ionic radius and electronic configuration to predict layered, cation-disordered, and coexistent structures of Li-excess cathode materials. Accordingly, we experimentally synthesized Li1.2Ni0.4Mn0.2Nb0.2O2 oxide with a coexistent structure in which the layered and disordered phases are well combined in the nanoscale region, achieving a high capacity (312 mAh g–1) with good cycling stability and rate capability. The design principle with composition predicting structure provides a valuable strategy in controllably designing and preparing Li-excess cathode materials.
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