尖晶石
阴极
材料科学
电池(电)
化学计量学
化学工程
可持续能源
相(物质)
铌
氟化物
工作(物理)
冶金
表征(材料科学)
无机化学
储能
分析化学(期刊)
作者
Yimeng Huang,Yaoshen Niu,Zhen Zhang,Zihan Lin,Weiyin Chen,V. Liu,Iradwikanari Waluyo,Adrian P. Hunt,Xianghui Xiao,Yanhao Dong,Ju Li
摘要
ABSTRACT Integrated rocksalt‐polyanion cathodes (DRXPS) are promising candidates for next‐generation lithium‐ion battery cathode materials that combine high energy density, stable cycling performance, and reduced reliance on Co and Ni. In this work, we investigated Li 3 Mn 1.6 P 0.4 O 5.4 F 0.6 , a new DRXPS cathode with fluoride incorporation. A pure spinel phase was formed and a discharge capacity retention of 84% was achieved after 200 cycles between 1.5 and 4.8 V versus Li/Li + . In comparison, the similarly synthesized Li 3 Mn 1.6 Nb 0.4 O 5.4 F 0.6 , in which all P 5+ was substituted by Nb 5+ while maintaining the same stoichiometry for all other elements, crystallized in a disordered rocksalt structure, and exhibited inferior capacity retention and rate capability than the P 5+ counterpart. Our findings expand the compositional space of DRXPS to include F − , justify the viability of integrating polyanion groups in rocksalt‐type cathodes, and highlight the superiority of P 5+ as a cation charge compensator compared to the commonly used Nb 5+ . This work thereby advances the design of robust, high‐performance cathode materials for sustainable batteries.
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