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引用次数: 0
摘要
钠离子电池(SIB)作为固定式储能系统的候选电池,因其基于廉价而丰富的钠离子插层化学的良好电化学性能而备受关注。层状氧化物是现代锂离子电池的主力军,它们在 SIB 方面的成功经验重新引起了人们的兴趣。钠层状氧化物的一个独特之处在于,它们能够结晶成热力学上稳定的 P2- 型层状结构,且 Na 的含量低于化学计量。这种结构为 Na 离子提供了高度开放的三棱柱环境,允许 Na+ 具有高流动性和出色的结构稳定性。本综述深入探讨了 P2 型阴极的内在特性和面临的主要挑战,然后全面总结了从成分设计、元素掺杂、相混合、形态控制、表面改性到钠补偿等改性策略的最新进展。本综述中介绍的最新认识有望指导并加快 P2- 型层状氧化物阴极在实际 SIB 应用中的开发。
Na-deficient P2-type layered oxide cathodes for practical sodium-ion batteries
Sodium-ion batteries (SIBs) have attracted enormous attention as candidates in stationary energy storage systems, because of the decent electrochemical performance based on cheap and abundant Na-ion intercalation chemistry. Layered oxides, the workhorses of modern lithium-ion batteries, have regained interest for replicating their success in enabling SIBs. A unique feature of sodium layered oxides is their ability to crystallize into a thermodynamically stable P2-type layered structure with under-stoichiometric Na content. This structure provides highly open trigonal prismatic environments for Na ions, permitting high Na+ mobility and excellent structural stability. This review delves into the intrinsic characteristics and key challenges faced by P2-type cathodes and then comprehensively summarizes the up-to-date advances in modification strategies from compositional design, elemental doping, phase mixing, morphological control, and surface modification to sodium compensation. The updated understanding presented in this review is anticipated to guide and expedite the development of P2-type layered oxide cathodes for practical SIB applications.
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