Selective Asymmetric Hydrogenation of Waste Polyethylene Terephthalate via Controlled Sorption through Precisely Tuned Moderate Acid Sites
Yue Zhu, Zhouying Mao, Weixiang Wu, Buxing Han, Qingqing Mei
Abstract
The partial hydrogenation of waste polyethylene terephthalate (PET) offers a great opportunity to produce valuable chemicals, yet achieving precise catalytic control remains challenging. Herein, for the first time, we realized one-pot selective hydrogenation of waste PET to p -toluic acid ( p -TA) with a record-high yield of 53.4%, alongside a 36.4% yield of p -xylene (PX), using a specially designed PtW/MCM-48 catalyst. Mechanistic investigations revealed that the exceptional catalytic performance arises from synergistic interaction between Pt nanoparticles and WO x species. Low-valent WO x enhances Pt dispersion, while Pt stabilizes WO x as low-polymerized polytungstates. The moderate acidity of PtW 1.5 /MCM-48 ensures controlled desorption of p -TA, preventing overhydrogenation to PX. The catalyst demonstrated robust performance with real-world PET waste. Life cycle assessment and technical and economic evaluation further highlight its practical feasibility. This study establishes a sustainable pathway for PET chemical upcycling and provides a framework for designing advanced catalysts for selective hydrogenation reactions, addressing critical challenges in circular chemistry and plastic waste management.