Layered oxide cathodes: A comprehensive review of characteristics, research, and development in lithium and sodium ion batteries

Zhengwei Xu, Kangwei Song, Xinyue Chang, Li Li, Weicheng Zhang, Yixun Xue, Jiahui Zhang, Dewu Lin, Zheyuan Liu, Qian Wang, Yan Yu, Chengkai Yang
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Abstract

Layered oxide materials are widely used in the field of energy storage and conversion due to their high specific energy, high efficiency, long cycle life, and high safety. Herein, We summarize the latest research progress in the field of layered metal oxide cathode materials from three aspects: challenges faced, failure mechanisms, and modification methods. We also compare the characteristics of lithium-based layered oxides and sodium-based layered oxides, and predict future development directions. The layered oxide cathode materials for sodium-ion batteries and lithium-ion batteries exhibit overall structural and operational similarities. There are also some differences, such as lattice parameters and application extent. Sodium-ion battery cathode materials need to explore new materials and address structural instability issues, while lithium-ion batteries require finding alternative materials and improving production efficiency. Future challenges for both types of materials include enhancing capacity and cycle performance, elucidating deep mechanisms, reducing costs, and improving resource sustainability. Future development should focus on balancing cycle stability and charge cut-off voltage to meet the growing demand for battery applications.

Abstract Image

层状氧化物阴极:锂离子和钠离子电池的特性、研究和发展综述
层状氧化物材料具有比能量高、效率高、循环寿命长、安全性高等特点,被广泛应用于能量存储和转换领域。在此,我们从面临的挑战、失效机理和改性方法三个方面总结了层状金属氧化物正极材料领域的最新研究进展。我们还比较了锂基层状氧化物和钠基层状氧化物的特性,并预测了未来的发展方向。钠离子电池和锂离子电池的层状氧化物正极材料在整体结构和操作方面具有相似性。但也存在一些差异,如晶格参数和应用范围。钠离子电池阴极材料需要探索新材料并解决结构不稳定问题,而锂离子电池则需要寻找替代材料并提高生产效率。这两类材料未来面临的挑战包括提高容量和循环性能、阐明深层机理、降低成本以及改善资源的可持续性。未来的发展重点应放在平衡循环稳定性和充电截止电压上,以满足日益增长的电池应用需求。
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