材料科学
阴极
共价键
结构稳定性
氧化物
相容性(地球化学)
过渡金属
纳米技术
电池(电)
工作(物理)
债券
复合数
金属
制作
键能
结构变化
化学键
转化(遗传学)
粘结强度
粘结长度
协调数
配位复合体
化学物理
结构材料
电子结构
储能
债券定单
复合氧化物
机制(生物学)
碳纤维
作者
Kang Chen,Qilin Zheng,Min Wen,Wei Yuan,Junjie Liao,Fusheng Zhou,Zhen Qiu,Suyun Wang,Lili Wang,Lituo Zheng,Yiyin Huang,Jiaxin Li,Hurong Yao
标识
DOI:10.1021/acsami.5c18702
摘要
Designing composite structures to enhance the performance of manganese-based sodium-ion battery (SIB) cathodes now represents a significant research focus. However, the development of composite-phase cathodes is hindered by an incomplete understanding of their structural transformation mechanisms. Herein, we elucidate the relationship between the transition metal bond energy and material structure, proposing a coordination bond reorganization strategy to drive structural transformations. This concept is demonstrated using the cathode material Na0.63Mn1-xTixO2, showing that the bond energy of transition metals plays a critical role in the structural transformation process. By introducing stronger Ti-O covalent bonds, we achieved the transition from a layered to tunnel structure. Furthermore, the layered-tunnel intergrowth structure Na0.63Mn0.95Ti0.05O2 demonstrates a remarkable specific capacity of 194.68 mAh g-1 alongside excellent stability while exhibiting good compatibility with hard carbon anodes. This work validates the feasibility of coordination bond reorganization as a mechanism for autonomous structural transformations, offering new insights for the precise design of high-energy-density materials for next-generation SIBs.
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