Facile Solid-State Synthesis to In Situ Generate a Composite Coating Layer Composed of Spinel-Structural Compounds and Li3PO4 for Stable Cycling of LiCoO2 at 4.6 V

• Published in: ACS applied materials & interfaces Vol. 15; no. 44; pp. 51262 - 51273
• Main Authors: Li, Yu, Zan, Mingwei, Chen, Penghao, Huang, Yuli, Xu, Xilin, Zhang, Chengzhen, Cai, Zhuoyuan, Yu, Xiqian, Li, Hong
• Format: Journal Article
• Language: English
• Published: American Chemical Society 08.11.2023
• Subjects: Energy, Environmental, and Catalysis Applications; high-voltage LiCoO2; lithium-ion batteries; cathode; spinel-structured compounds; in situ coating; Li3PO4
• ISSN: 1944-8244; 1944-8252
• DOI: 10.1021/acsami.3c12738

Due to its high energy density, high-voltage LiCoO2 is the preferred cathode material for consumer electronic products. However, its commercial viability is hindered by rapid capacity decay resulting from structural degradation and surface passivation during cycling at 4.6 V. The key to achieving stable cycling of LiCoO2 at high voltages lies in constructing a highly stable interface to mitigate surface side reactions. In this study, we present a facile in situ coating strategy that is amenable to mass production through a simple wet-mixing process, followed by high-temperature calcination. By capitalizing on the facile dispersion characteristics of nano-TiO2 in ethanol and the ethanol dissolubility of LiPO2F2, we construct a uniform precoating layer on LiCoO2 with nano-TiO2 and LiPO2F2. The subsequent thermal treatment triggers an in situ reaction between the coating reagents and LiCoO2, yielding a uniform composite coating layer. This composite layer comprises spinel-structured compounds (e.g., LiCoTiO4) and Li3PO4, which exhibit excellent chemical and structural stability under high-voltage conditions. The uniform and stable coating layer effectively prevents direct contact between LiCoO2 and the electrolyte, thereby reducing side reactions and suppressing the surface passivation of LiCoO2 particles. As a result, coated LiCoO2 maintains favorable electronic and ionic conductivity even after prolonged cycling. The synergistic effects of spinel-structured compounds and Li3PO4 contribute to the superior performance of LiCoO2, demonstrating a high capacity of 202.1 mA h g–1 (3.0–4.6 V, 0.5 C, 1 C = 274 mA g–1), with a capacity retention rate of 96.7% after 100 cycles.