<p>Recovering valuable metals from spent lithium-ion batteries (LIBs) is essential but highly limited by high energy consumption and significant waste emissions. Herein, we propose a solar-driven recycling strategy applicable to a wide range of LIB cathode materials. The core of this approach lies in the efficient and stable hydrogen peroxide (H<sub>2</sub>O<sub>2</sub>) production, enabled by a rationally engineered benzobisthiazole-linked polymeric photocatalyst. The in-situ photogenerated H<sub>2</sub>O<sub>2</sub> induces the redox reactions of metal species, promoting their dissolution and lithium-ion deintercalation. Under optimal conditions, this approach achieves Li<sup>+</sup> leaching rates of up to 14 mmol h<sup>−1</sup> g<sup>−1</sup> and transition metal extraction efficiencies exceeding 90%. Outdoor trials under natural sunlight demonstrate continuous and stable recycling of LiCoO<sub>2</sub> for over a 30-day period, achieving average daily leaching yields of 8.4 mmol Co<sup>2+</sup> and 8.7 mmol Li<sup>+</sup>. A techno-economic analysis further supports the practical feasibility of our photocatalytic recycling strategy, underscoring its potential as a scalable and sustainable solution for recovering critical metals from LIB waste.</p>

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Continuous solar-driven recycling of lithium-ion battery cathode materials enabled by a stable benzobisthiazole-linked polymeric photocatalyst

  • Xiaohan Yu,
  • Yuhua Fu,
  • Jingfan Shao,
  • Yuchen Yan,
  • Jingya Xin,
  • Jicheng Xu,
  • Wei Huang,
  • Yanguang Li

摘要

Recovering valuable metals from spent lithium-ion batteries (LIBs) is essential but highly limited by high energy consumption and significant waste emissions. Herein, we propose a solar-driven recycling strategy applicable to a wide range of LIB cathode materials. The core of this approach lies in the efficient and stable hydrogen peroxide (H2O2) production, enabled by a rationally engineered benzobisthiazole-linked polymeric photocatalyst. The in-situ photogenerated H2O2 induces the redox reactions of metal species, promoting their dissolution and lithium-ion deintercalation. Under optimal conditions, this approach achieves Li+ leaching rates of up to 14 mmol h−1 g−1 and transition metal extraction efficiencies exceeding 90%. Outdoor trials under natural sunlight demonstrate continuous and stable recycling of LiCoO2 for over a 30-day period, achieving average daily leaching yields of 8.4 mmol Co2+ and 8.7 mmol Li+. A techno-economic analysis further supports the practical feasibility of our photocatalytic recycling strategy, underscoring its potential as a scalable and sustainable solution for recovering critical metals from LIB waste.