光催化
双功能
材料科学
催化作用
醋酸
级联
产量(工程)
白腐真菌
氮化碳
光化学
降级(电信)
激进的
辐照
核化学
化学工程
黄孢菌
双功能催化剂
透射电子显微镜
碳纤维
无机化学
可见光谱
反应机理
石墨氮化碳
氮气
高分辨率透射电子显微镜
嫁接
羧酸
作者
Wei Wei,Cheng Du,Jiawei Ge,Xiang Wang,Zuolong Chen,Meng Zhang,Tao Guo,Lei Wang,M. Wang,Yuzi Liu,Hua Zhou,Chengjun Sun,Ning Chen,Weifeng Chen,Brant Billinghurst,Mohsen Shakouri,Peter Sprenger,Fatemeh Fani Sani,Yulian Quan,Brian Kendall
标识
DOI:10.1002/aenm.202505453
摘要
ABSTRACT Plastic imposes a critical threat to the environment, ecosystems, and human health because of the low utilization efficiency of plastics. Here, we demonstrate a sustainable, highly efficient cascade photocatalysis for upcycle plastics to value‐added acetic acid using Fe single‐atom catalysts (Fe@C 3 N 4 SAC) at ambient conditions. Inspired by Phanerochaete chrysosporium microbial, the defective Fe@C 3 N 4 SAC acts as a bifunctional cascade photocatalyst for both Fenton‐like and CO 2 reduction reactions. During the reaction, hydroxyl radicals (*OH) form and subsequently oxidize plastics into CO 2 intermediates. These CO 2 intermediates are then photo‐reduced to CH 3 COOH on the same catalyst via cascade photocatalysis. The mechanism is confirmed by in situ multimodal microscopy and spectroscopies, with density functional theory calculations. A state‐of‐art CH 3 COOH yield of 63.8 mg h −1 g cat −1 from PVC, 12.7 mg h −1 g cat −1 from PE, 5.4 mg h −1 g cat −1 from PET, and 5.3 mg h −1 g cat −1 from PP are directly obtained under AM1.5G solar irradiation and further validated under real sunlight (≈0.6 sun), achieving 5.6 mg h −1 g cat −1 from PET, using low‐cost Fe@C 3 N 4 SAC in a sealed reactor by enhancing the photon transport and utilization efficiency. The techno‐economic analysis shows it is promising to practically mitigate plastic based on broader social welfare assessments.
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