Abstract The economic recovery of anodes in lithium‐ion batteries remains challenging due to their low value. Here, the study presents a cross‐sector battery‐plastic co‐upcycling strategy that transforms spent graphite anodes into bifunctional photothermal catalysts for efficient Polyethylene terephthalate (PET) depolymerization. Upon reaction with ethylene glycol (EG), lithiated graphite spontaneously enables copper foil detachment, graphite regeneration, and in situ formation of organolithium species (C 2 H 4 O 2 Li 2‐x H x). The resulting catalyst system achieves 95% PET conversion and 64. 6% BHET yield within 15 minutes under 0. 71 W/cm 2 sunlight. Mechanistically, a synergistic effect between solid electrolyte interphase (SEI) ‐derived Li 2 CO 3 /Li 2 O and organolithium intermediates significantly accelerates glycolysis. Techno‐economic modeling for a 90 000 ton/year facility reveals a minimum selling price of 0. 956/kg for BHET and annual energy savings of 5. 039 × 10 11 kJ. This work highlights a scalable, low‐cost approach to integrate battery and plastic waste recycling, offering a new paradigm for sustainable urban mining and circular polymer economy.
Xie et al. (Wed,) studied this question.
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