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Scalable Top‐Down Approach for Recycling Highly Degraded Spent LiFePO<sub>4</sub> via Lattice Fragmentation‐Regeneration

Junwei Wang, Shuaijing Ji, Yuzhen Zhao, Qigao Han, Fengqian Wang, Wuxin Sha, Danpeng Cheng, Weixin Zhang, Shun Tang, Yuan‐Cheng Cao, Shijie Cheng

2024Small10 citationsDOI

Abstract

Abstract Designing efficient, scalable, and eco‐friendly recycling technologies is crucial for addressing the widespread decommissioning of spent lithium‐ion batteries. Here, an innovative top‐down regeneration method is introduced to rejuvenate highly degraded LiFePO 4 . Initially, the crystal structure of spent LiFePO 4 is destroyed via the oxidation process, followed by the reconstruction of the LiFePO 4 lattice through the reduction process. The regenerated LiFePO 4 features a uniform particle size and an intact crystal lattice, leading to substantial improvements in electrochemical performance. Specifically, it achieves a capacity of 142.6 mAh g −1 at 1 C, significantly surpassing the spent LiFePO 4 (only 55.6 mAh g −1 at 1 C). Furthermore, it demonstrates an exceptional retention of 86.7% after 450 cycles, in contrast to 55.8% retention of commercial LiFePO 4 . More importantly, spent LiFePO 4 with varying degrees of degradation is successfully regenerated using this technology, confirming its scalability. Therefore, this research highlights a transformative and sustainable approach to LiFePO 4 regeneration, achieving splendid advancements in both electrochemical performance and cycle stability, and offers a novel pathway for the effective recycling of LiFePO 4 ‐based energy storage systems.

Topics & Concepts

ScalabilityRegeneration (biology)Materials scienceNuclear decommissioningFragmentation (computing)Lithium (medication)IonNanotechnologyComputer scienceWaste managementChemistryDatabaseEngineeringOperating systemCell biologyEndocrinologyOrganic chemistryBiologyMedicineExtraction and Separation ProcessesAdvancements in Battery MaterialsRecycling and Waste Management Techniques