Chang Xin, Fan Min, Yuan Boheng, He Wei-Huan, Gu Chao-Fan, Li Chen, Meng Qinghai, Guo Yu-Guo
CAS Key Laboratory of Molecular Nanostructure and Nanotechnology, CAS Research/Education Centre for Excellence in Molecular Sciences, Beijing National Laboratory for Molecular Sciences (BNLMS), Institute of Chemistry, Chinese Academy of Sciences, Beijing, 100190, P. R. China.
University of Chinese Academy of Sciences (UCAS), Beijing, 100049, P. R. China.
Angew Chem Int Ed Engl. 2024 Aug 5;63(32):e202406557. doi: 10.1002/anie.202406557. Epub 2024 Jul 4.
The surge in lithium-ion batteries has heightened concerns regarding metal resource depletion and the environmental impact of spent batteries. Battery recycling has become paramount globally, but conventional techniques, while effective at extracting transition metals like cobalt and nickel from cathodes, often overlook widely used spent LiFePO due to its abundant and low-cost iron content. Direct regeneration, a promising approach for restoring deteriorated cathodes, is hindered by practicality and cost issues despite successful methods like solid-state sintering. Hence, a smart prelithiation separator based on surface-engineered sacrificial lithium agents is proposed. Benefiting from the synergistic anionic and cationic redox, the prelithiation separator can intelligently release or intake active lithium via voltage regulation. The staged lithium replenishment strategy was implemented, successfully restoring spent LiFePO's capacity to 163.7 mAh g and a doubled life. Simultaneously, the separator can absorb excess active lithium up to approximately 600 mAh g below 2.5 V to prevent over-lithiation of the cathode This innovative, straightforward, and cost-effective strategy paves the way for the direct regeneration of spent batteries, expanding the possibilities in the realm of lithium-ion battery recycling.
锂离子电池的激增加剧了人们对金属资源枯竭以及废旧电池环境影响的担忧。电池回收在全球范围内已变得至关重要,但传统技术虽然能有效地从阴极中提取钴和镍等过渡金属,却常常因磷酸铁锂(LiFePO)中铁含量丰富且成本低廉而忽视了广泛使用的废旧LiFePO。直接再生是一种恢复退化阴极的有前景的方法,尽管有像固态烧结这样成功的方法,但仍受到实用性和成本问题的阻碍。因此,提出了一种基于表面工程牺牲锂剂的智能预锂化隔膜。得益于协同的阴离子和阳离子氧化还原作用,预锂化隔膜可通过电压调节智能地释放或摄取活性锂。实施了分阶段锂补充策略,成功地将废旧LiFePO的容量恢复到163.7 mAh g,寿命延长了一倍。同时,该隔膜可在2.5 V以下吸收高达约600 mAh g的过量活性锂,以防止阴极过度锂化。这种创新、直接且具有成本效益的策略为废旧电池的直接再生铺平了道路,拓展了锂离子电池回收领域的可能性。
