Recent progress of interface modification of layered oxide cathode material for sodium-ion batteries

Electron Pub Date : 2024-04-04 DOI:10.1002/elt2.31
Luyi Sun, Jun Zeng, Xuanhong Wan, Chenxi Peng, Jiarui Wang, Chongjia Lin, Min Zhu, Jun Liu
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Abstract

With the advantages of similar theoretical basis to lithium batteries, relatively low budget and the abundance of sodium resources, sodium ion batteries (SIBs) are recognized as the most competitive alternative to lithium-ion batteries. Among various types of cathodes for SIBs, advantages of high theoretical capacity, nontoxic and facile synthesis are introduced for layered transition metal oxide cathodes and therefore they have attracted huge attention. Nevertheless, layered oxide cathodes suffer from various degradation issues. Among these issues, interface instability including surface residues, phase transitions, loss of active transition metal and oxygen loss takes up the major part of the degradation of layered oxides. These degradation mechanisms usually lead to irreversible structure collapse and cracking generation, which significantly influence the interface stability and electrochemical performance of layered cathodes. This review briefly introduces the background of researches on layered cathodes for SIBs and their basic structure types. Then the origins and effects on layered cathodes of degradation mechanisms are systematically concluded. Finally, we will summarize various interface modification methods including surface engineering, doping modification and electrolyte composition which are aimed to improve interface stability of layered cathodes, perspectives of future research on layered cathodes are mentioned to provide some theoretical proposals.

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钠离子电池层状氧化物阴极材料界面改性的最新进展
钠离子电池(SIB)具有与锂电池相似的理论基础、相对较低的成本以及丰富的钠资源等优势,被公认为是锂离子电池最具竞争力的替代品。在钠离子电池的各类阴极中,层状过渡金属氧化物阴极具有理论容量高、无毒、易于合成等优点,因此受到广泛关注。然而,层状氧化物阴极存在各种降解问题。在这些问题中,界面不稳定性(包括表面残留物、相变、活性过渡金属损失和氧气损失)是层状氧化物降解的主要原因。这些降解机制通常会导致不可逆的结构坍塌和裂纹产生,从而严重影响层状阴极的界面稳定性和电化学性能。本综述简要介绍了用于 SIB 的层状阴极的研究背景及其基本结构类型。然后系统地总结了降解机制的起源及其对层状阴极的影响。最后,总结了旨在提高层状阴极界面稳定性的各种界面改性方法,包括表面工程、掺杂改性和电解质组成,并对层状阴极的未来研究前景进行了展望,以提供一些理论建议。
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Issue Information Cover Image, Volume 2, Number 4, November 2024 Cover Image, Volume 2, Number 4, November 2024 Design of long-wavelength infrared InAs/InAsSb type-II superlattice avalanche photodetector with stepped grading layer Recent progress on heteroepitaxial growth of single crystal diamond films
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