结构稳定性
阴极
材料科学
电化学
氧化物
密度泛函理论
化学工程
结构变化
降级(电信)
替代(逻辑)
过渡金属
相(物质)
相变
格子(音乐)
结晶学
化学物理
锚固
金属
纳米技术
失真(音乐)
工作(物理)
不稳定性
分子
作者
Hai Yan Hu,Minwen Yang,Diancheng Chen,Neng-Hua Xu,Jia-Yang Li,Yan-Fang Zhu,Yuan-Bo Wu,Hang Hang Dong,Jiayi Wang,Chang‐Jiang Yao,Yaping Yan,Shuangqiang Chen,Nana Wang,Wei Kong Pang,Yang Sun,Jia Zhao Wang,Yao Xiao
标识
DOI:10.1002/anie.202519108
摘要
Abstract O3‐type layered transition metal oxides are considered promising cathode materials for sodium‐ion batteries (SIBs) due to their high capacity and favorable Na + storage characteristics. However, their practical application is severely hindered by structural instability associated with multiphase transitions during electrochemical cycling. Herein, we propose a spatially selective multi‐element substitution strategy that induces spatially differentiated distributions of Mg, Cu, Ti, and B, thereby enhancing structural robustness. This spatially differentiated substitution architecture synergistically improves structural stability by concurrently inhibiting interfacial degradation and strengthening the lattice framework. The optimized composition (NaNi 0.4 Mg 0.05 Cu 0.05 Mn 0.3 Ti 0.2 B 0.05 O 2 ) enables a stabilized O3 → P3 phase transition, which relieves lattice distortion and suppresses structural collapse upon cycling. Density functional theory (DFT) analysis reveals that the strong covalency of B─O bonds is crucial for anchoring the P3 framework. Hence, it delivers superior high‐temperature performance in half cells and durable cycling in full cells (85% capacity retention after 300 cycles at 0.5 C within 1.9–3.9 V). By elucidating the role of spatially selective substitution in structural stabilization, this work provides fundamental insights and paves the way for the design of advanced SIB cathodes.
科研通智能强力驱动
Strongly Powered by AbleSci AI