橄榄石基纳米填充层赋予富镍层状阴极增强表面稳定性和抗热震性

Changhao Wang , Yawen Yan , Guifan Zeng , Haiyan Luo , Jianken Chen , Zixin Wu , Zhefei Sun , Xiaohong Wu , Haitang Zhang , Kai Fang , Yu Qiao , Shi-Gang Sun
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引用次数: 0

摘要

NCM811的不可逆相变和令人紧张的热失控,特别是在高电荷截止电位下循环,阻碍了其全面商业化。在本研究中,我们采用一种简单而强大的表面修饰策略构建了修饰的NCM811,其沟壑被砂磨LiMn0.6Fe0.4PO4 (LMFP)完全填充/嵌入,形成纳米填充的NCM811 (LMFP@NCM811)。凭借这种紧凑的& &;均匀的LMFP层,在LMFP@NCM811表面建立了一个薄而稳定的阴极-电解质界面(CEI)层,在100 mAh/g下循环450次后,其容量保持率高达80%。此外,由于橄榄石结构(LMFP)的固有稳定性,嵌入lfp的NCM811在高去锂化状态下表现出良好的热稳定性和抗热冲击性能。我们相信,这一在富镍三元阴极性能改进方面的成功可以为未来实现更高效的能量存储和利用工作提供良好的指导。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Olivine-based nano-filling layer empowering Ni-rich layered cathodes with enhanced surface stability and thermal shock resistance

Irreversible phase transition and nerve-racking thermal runaway of NCM811 especially cycled at high charge cut-off potential hinder its full-scale commercialization. In this study, we use a facile and powerful surface modification strategy to construct modified NCM811 whose ravines are completely filled/embedded by sand-milled LiMn0.6Fe0.4PO4 (LMFP), forming the nano-filled NCM811 (LMFP@NCM811). By virtue of this compact & uniform LMFP layer, a thin and stable cathode-electrolyte interface (CEI) layer can be established on the surface of LMFP@NCM811, which leads to prominent electrochemical properties with a high capacity retention of ∼ 80% after 450 cycles at 100 mAh/g. Moreover, due to the intrinsic stability of olivine structure (LMFP), the LMFP-embedded NCM811 showcases admirable thermal stability and thermal shock resistance at high de-lithiation state. We believe that such success at the performance improvement of Ni-rich ternary cathodes can provide a good guidance for future work to achieve more efficient energy storage and utilization.

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