Nano-rods in Ni-rich layered cathodes for practical batteries

IF 40.4 1区 化学 Q1 CHEMISTRY, MULTIDISCIPLINARY
Geon-Tae Park, Nam-Yung Park, Hoon-Hee Ryu, H. Hohyun Sun, Jang-Yeon Hwang and Yang-Kook Sun
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Abstract

Lithium transition metal oxide layers, Li[Ni1−xyCox(Mn and/or Al)y]O2, are widely used and mass-produced for current rechargeable battery cathodes. Development of cathode materials has focused on increasing the Ni content by simply controlling the chemical composition, but as the Ni content has almost reached its limit, a new breakthrough is required. In this regard, microstructural modification is rapidly emerging as a prospective approach, namely in the production of nano-rod layered cathode materials. A comprehensive review of the physicochemical properties and electrochemical performances of cathodes bearing the nano-rod microstructure is provided herein. A detailed discussion is regarding the structural stability of the cathode, which should be maximized to suppress microcrack formation, the main cause of capacity fading in Ni-rich cathode materials. In addition, the morphological features required to achieve optimal performance are examined. Following a discussion of the initial nano-rod cathodes, which were based on compositional concentration gradients, the preparation of nano-rod cathodes without the inclusion of a concentration gradient is reviewed, highlighting the importance of the precursor. Subsequently, the challenges and advances associated with the nano-rod structure are discussed, including considerations for synthesizing nano-rod cathodes and surface shielding of the nano-rod structure. It goes on to cover nano-rod cathode materials for next-generation batteries (e.g., all-solid-state, lithium-metal, and sodium-ion batteries), inspiring the battery community and other materials scientists looking for clues to the solution of the challenges that they encounter.

Abstract Image

Abstract Image

用于实用电池的富镍层状阴极中的纳米棒
锂过渡金属氧化物层 Li[Ni1-x-yCox(Mn 和/或 Al)y]O2 被广泛应用于当前的可充电电池阴极,并已大规模生产。阴极材料的开发主要集中在通过简单地控制化学成分来增加镍含量,但由于镍含量已接近极限,因此需要新的突破。在这方面,微结构改性正迅速成为一种有前景的方法,即生产纳米棒层状阴极材料。本文全面综述了纳米棒微结构阴极的物理化学特性和电化学性能。本文详细讨论了阴极的结构稳定性,应最大限度地提高阴极的结构稳定性,以抑制微裂纹的形成,微裂纹是富镍阴极材料容量衰减的主要原因。此外,还研究了实现最佳性能所需的形态特征。在讨论了最初基于成分浓度梯度的纳米棒阴极之后,回顾了不包含浓度梯度的纳米棒阴极的制备,强调了前驱体的重要性。随后,讨论了与纳米棒结构相关的挑战和进展,包括合成纳米棒阴极和纳米棒结构表面屏蔽的注意事项。报告还介绍了用于下一代电池(如全固态电池、锂金属电池和钠离子电池)的纳米棒阴极材料,激励电池界和其他材料科学家寻找解决所遇挑战的线索。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
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来源期刊
Chemical Society Reviews
Chemical Society Reviews 化学-化学综合
CiteScore
80.80
自引率
1.10%
发文量
345
审稿时长
6.0 months
期刊介绍: Chemical Society Reviews is published by: Royal Society of Chemistry. Focus: Review articles on topics of current interest in chemistry; Predecessors: Quarterly Reviews, Chemical Society (1947–1971); Current title: Since 1971; Impact factor: 60.615 (2021); Themed issues: Occasional themed issues on new and emerging areas of research in the chemical sciences
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