材料科学
纳米技术
电化学
锂(药物)
纳米结构
储能
双金属片
电极
钼
蜂巢
氧化钴
结构稳定性
氧化物
化学工程
复合材料
化学
冶金
金属
物理化学
功率(物理)
内分泌学
工程类
物理
医学
结构工程
量子力学
作者
Jun Mei,Ting Liao,Henry J. Spratt,Godwin A. Ayoko,Xin Zhao,Ziqi Sun
标识
DOI:10.1002/smtd.201900055
摘要
Abstract Nanostructure engineering has been proved to be an efficient approach for improving electrochemical properties for energy storage by accommodating volume changes, facilitating rapid mass transport paths, and enlarging ion storage sites and interfaces. The well‐designed fine nanostructures, unfortunately, are usually destroyed during long‐term cycles and ultimately lose their structural advantages. Herein, stimulated by the extraordinary structural stability, robust mechanical properties, and salient ventilation capacity of natural honeycomb species, bioinspired heterogeneous bimetallic Co–Mo oxide (CoMoO x ) nanoarchitectures assembled from 2D nanounits are successfully fabricated via a molybdenum‐mediated self‐assembly strategy for improving the rate capability of electrochemical lithium storage devices. Owing to the robust structural stability and the ultrathin 2D wall structure, CoMoO x nanostructures present well‐maintained honeycomb‐like structure, rapid capacitive insertion–desertion behaviors, and thus significantly enhanced lithium ion storage performance at high rates (5.0 A g −1 ). It is also revealed that the reversible transition of cobalt and molybdenum phases closely associated with the ultrathin 2D wall structures greatly contribute to the outstanding electrochemical lithium storage performances. This attractive integration of structural and functional advantages achieved by learning from nature offers new insights into the design of cost‐effective electrode materials for high‐performance energy devices.
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