材料科学
化学工程
电化学
阴极
退火(玻璃)
吸附
再生(生物学)
储能
电池(电)
锂(药物)
热的
锂离子电池
纳米技术
重新使用
热处理
锂电池
表面工程
高能
阳极
纳米结构
环境友好型
分子工程
复合数
作者
Chengzhi Feng,Wei Mao,Peiji Yin,Xuan Cao,Jian Cheng,Wei Xü,Qingchun Zhang,Lixian Song,Zhongti Sun,Yingze Song
出处
期刊:ACS Nano
[American Chemical Society]
日期:2026-01-02
卷期号:20 (2): 2413-2423
被引量:1
标识
DOI:10.1021/acsnano.5c19806
摘要
The rapid growth of the electric vehicle industry has led to a large accumulation of lithium-ion batteries. Direct regeneration of spent cathode materials is a promising recycling strategy, yet its industrial application is often constrained by the energy-intensive processes required for lithium replenishment and structural repair under harsh conditions. In this work, the uniform and lithium-rich layer is constructed on the surface of spent LiFePO 4 (S-LFP) via the spontaneous adsorption of organic lithium carboxylate salts. This tailored interface serves as an ideal precursor state for the subsequent thermal annealing step, enabling the synergistic completion of the lithium insertion into the lattice and effective defect healing. This adsorption-mediated interfacial engineering is pivotal to the whole regeneration process. The regenerated LFP (R-LFP) exhibits favorable electrochemical performance, delivering a high specific discharge capacity of 145.5 mAh g –1 at 1.0 C and retaining 88.1% of its capacity after 400 cycles. Compared with conventional one-step solid-state methods, this hybrid approach reduces overall energy consumption and presents a compelling, scalable pathway for the direct regeneration of S-LFP, thereby advancing the development of sustainable and cost-effective battery recycling solutions.
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