In–situ construction of LixFeyOz coatings on cobalt–free lithium–rich cathode materials for enhanced structural stability and electrochemical performance

IF 8.3 1区工程技术 Q1 ENGINEERING, CHEMICAL Desalination Pub Date : 2024-11-26 DOI:10.1016/j.desal.2024.118352

Dongmei Liu , Binfang He , Kaihan Hu , Songyuan Sun , Huigui Wu , Jingbo Chen , Xiangming He

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Abstract

Environmentally benign and cost–effective cobalt–free lithium–rich cathode materials have garnered significant interest. Nevertheless, the irreversible loss of lattice oxygen compromises their structural integrity, leading to capacity fade, voltage decay, and sluggish kinetics, which collectively impede their commercial viability. To address these challenges, this study introduces an in–situ formation of Li_xFe_yO_z coatings on the surface of cobalt–free lithium–rich materials by utilizing residual lithium compounds. At elevated temperatures, the residual lithium compounds on the surface of Li_1.2Mn_0.6Ni_0.2O₂ (LMNO) react with FeO to generate a Li_xFe_yO_z protective layer. This coating not only shields the bulk material from direct exposure to the electrolyte but also effectively consumes residual lithium compounds to suppress interfacial side reactions, thereby enhancing structural stability. The Li_xFe_yO_z layer acts as a lithium–ion conductor, facilitating the migration of lithium ions and markedly boosting the material's electrochemical performance. Experimental results indicate that at a current density of 1C, the initial discharge specific capacity of LMNO@Fe is 235.24 mAh g⁻¹ with a capacity retention of 91.33 % after 100 cycles, compared to 211.62 mAh g⁻¹ and 77.95 % for LMNO, respectively. Even at a higher current density of 5C, the LMNO@Fe maintains a discharge specific capacity of 148.30 mAh g⁻¹. This research demonstrates that the Li_xFe_yO_z coating on cobalt–free lithium–rich cathode materials offers a promising strategy for achieving high–performance lithium–ion batteries.

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在无钴富锂正极材料上原位构建LixFeyOz涂层，提高结构稳定性和电化学性能

环境友好且具有成本效益的无钴富锂正极材料已经引起了人们的极大兴趣。然而，晶格氧的不可逆损失损害了它们的结构完整性，导致容量衰减、电压衰减和缓慢的动力学，这些共同阻碍了它们的商业可行性。为了解决这些挑战，本研究引入了一种利用残余锂化合物在无钴富锂材料表面原位形成LixFeyOz涂层的方法。在高温下，Li1.2Mn0.6Ni0.2O2 （LMNO）表面残留的锂化合物与FeO反应生成LixFeyOz保护层。该涂层不仅可以防止大块材料直接暴露于电解质中，还可以有效地消耗残余的锂化合物以抑制界面副反应，从而提高结构稳定性。LixFeyOz层作为锂离子导体，促进锂离子的迁移，显著提高材料的电化学性能。实验结果表明，当电流密度为1C时，LMNO@Fe的初始放电比容量为235.24 mAh g−1，循环100次后容量保持率为91.33%，而LMNO的放电比容量为211.62 mAh g−1，循环100次后容量保持率为77.95%。即使在5C的高电流密度下，LMNO@Fe也能保持148.30 mAh g−1的放电比容量。这项研究表明，LixFeyOz涂层在无钴富锂正极材料上为实现高性能锂离子电池提供了一个有前途的策略。

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来源期刊

Desalination 工程技术-工程：化工

CiteScore

14.60

自引率

20.20%

发文量

619

审稿时长

41 days

期刊介绍： Desalination is a scholarly journal that focuses on the field of desalination materials, processes, and associated technologies. It encompasses a wide range of disciplines and aims to publish exceptional papers in this area. The journal invites submissions that explicitly revolve around water desalting and its applications to various sources such as seawater, groundwater, and wastewater. It particularly encourages research on diverse desalination methods including thermal, membrane, sorption, and hybrid processes. By providing a platform for innovative studies, Desalination aims to advance the understanding and development of desalination technologies, promoting sustainable solutions for water scarcity challenges.