A recrystallization approach to repairing spent LiFePO 4 black mass

Broad applications of lithium-ion batteries in the past decade have resulted in gigawatt-hours of spent batteries that perplex the recycling industry, especially for the industrially collected spent LiFePO 4 (LFP) cathode powders with binders, carbon, and electrolyte residues (“black mass”). Traditi...

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Published in:Journal of materials chemistry. A, Materials for energy and sustainability Materials for energy and sustainability, 2023-04, Vol.11 (16), p.9057-9065
Main Authors: Wang, Zhongheng, Xu, Hui, Liu, Zhiruo, Jin, Mingzhe, Deng, Linghao, Li, Sa, Huang, Yunhui
Format: Article
Language:English
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Summary:Broad applications of lithium-ion batteries in the past decade have resulted in gigawatt-hours of spent batteries that perplex the recycling industry, especially for the industrially collected spent LiFePO 4 (LFP) cathode powders with binders, carbon, and electrolyte residues (“black mass”). Traditional pyrometallurgical/hydrometallurgical recycling as well as direct regeneration via annealing cost too much time and energy. Thermodynamically FePO 4 , the main de-lithiated product that needs to be repaired in the spent LFP, constitutes only a small portion of the black mass. Thus the energy-consuming long annealing process (600–750 °C in 4–12 h in N 2 ) seems quite unnecessary. Herein, we propose a facile recrystallization approach by reacting black mass with LiNO 3 . Benefiting from the thermodynamic instability and low melting point (∼250 °C) of LiNO 3 , the spent LFP can be fully re-lithiated after 30 min of heating at 300 °C in air (right below the LFP oxidation temperature). The specific capacity of the repaired LFP was recovered to 162 mA h g −1 from 134 mA h g −1 with improved rate and cycling performance, competitive with the commercially available new LFP. Ecological and economic assessment of this recycling strategy reveals significantly lower CO 2 emission (0.93 kg/kg LFP) and cost ($2270 per t) thanks to the efficient reaction process, significantly lower than that of other direct recycling methods (2–4 kg/kg LFP, >$3000 per t).
ISSN:2050-7488
2050-7496
DOI:10.1039/D3TA00655G