Challenges and opportunities using Ni-rich layered oxide cathodes in Li-ion rechargeable batteries: the case of nickel cobalt manganese oxides

IF 3.2 Q2 CHEMISTRY, PHYSICAL Energy advances Pub Date : 2024-07-10 DOI:10.1039/D3YA00631J
Jitendra Pal Singh, Harsha Devnani, Aditya Sharma, Weon Cheol Lim, Archana Dhyani, Keun Hwa Chae and Sangsul Lee
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Abstract

This review provides an overview of recent advances in the utilization of Ni-rich nickel–cobalt–manganese (NCM) oxides as cathode materials for Li-ion rechargeable batteries (LIBs). In the past decade, Ni-rich NCM cathodes have been extensively investigated because of their rational capacity and easy accessibility of constituent elements. However, huge capacity fading and irreversible structural disorder, associated with oxygen release, are the major limitations which hinder the desired electrochemical performance of these cathodes. The LIB performance can be improved through several strategies such as doping, coating, composite formation, microstructure manipulation and replacing the Mn ions. Attempts are also made to amend the crystal orientation and achieve additive-induced surface engineering of NCM cathodes. However, the practical application of high-performance LIBs demand an effective modification of the intrinsic properties of NCMs. Substandard thermal stability is another safety aspect to be resolved in the Ni-rich NCMs. However, efforts in this context are not enough. Apart from designing NCM cathodes, there are major issues such as cost-effectiveness, supply and demand for constituent elements, and the reuse of spent batteries, which hinder the realisation of LIBs with high electrochemical performance. Keeping in mind the current research interests, this review article presents concise and in-depth strategies to design NCM cathodes for future energy demands of mankind by considering the cost and Co abundance-related issues.

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在锂离子充电电池中使用富镍层状氧化物阴极的挑战与机遇:镍钴锰氧化物案例
本综述概述了利用富镍钴锰(NCM)氧化物作为锂离子充电电池(LIB)阴极材料的最新进展。在过去十年中,富镍 NCM 阴极因其合理的容量和易于获得的组成元素而受到广泛研究。然而,与氧释放有关的巨大容量衰减和不可逆结构紊乱是阻碍这些阴极实现理想电化学性能的主要限制因素。可以通过掺杂、涂层、形成复合材料、微结构处理和替换锰离子等几种策略来改善 LIB 性能。此外,还尝试修正 NCM 阴极的晶体取向并实现添加剂诱导的表面工程。然而,高性能锂离子电池的实际应用要求对 NCM 的内在特性进行有效改造。热稳定性不达标是富镍 NCM 需要解决的另一个安全问题。然而,这方面的努力还远远不够。除了设计 NCM 阴极之外,还有一些重大问题,如成本效益、组成元素的供需以及废旧电池的再利用,这些都阻碍了具有高电化学性能的 LIB 的实现。考虑到当前的研究兴趣,本综述文章提出了简明而深入的策略,通过考虑与成本和 Co 丰度相关的问题来设计 NCM 阴极,以满足人类未来的能源需求。
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