Litcius/Paper detail

Unraveling the role of water in mechanism changes for economically viable catalytic plastic upcycling

Taeeun Kwon, Byeongchan Ahn, Ki Hyuk Kang, Wangyun Won, Insoo Ro

2024Nature Communications38 citationsDOIOpen Access PDF

Abstract

The surge in global plastic production, reaching 400.3 million tons in 2022, has exacerbated environmental pollution, with only 11% of plastic being recycled. Catalytic recycling, particularly through hydrogenolysis and hydrocracking, offers a promising avenue for upcycling polyolefin plastic, comprising 55% of global plastic waste. This study investigates the influence of water on polyolefin depolymerization using Ru catalysts, revealing a promotional effect only when both metal and acid sites, particularly Brønsted acid site, are present. Findings highlight the impact of Ru content, metal-acid balance, and their proximity on this interaction, as well as their role in modulating the isomerization process, affecting product selectivity. Additionally, the interaction facilitates the suppression of coke formation, ultimately enhancing catalyst stability. A comprehensive techno-economic and life cycle assessment underscores the viability and environmental benefits of the process, particularly in the presence of water. These insights advance understanding and offer strategies for optimizing polyolefin plastic recycling processes. Catalytic hydrogenolysis and hydrocracking present a promising approach for upcycling polyolefin plastics. Here, the authors highlight the role of water in catalytic plastic upcycling, emphasizing that catalysts with an optimal metal-acid balance significantly improve polyethylene depolymerization when water is present.

Topics & Concepts

PolyolefinHydrogenolysisDepolymerizationCatalysisMaterials sciencePolyethyleneChemistryOrganic chemistryWaste managementEngineeringLayer (electronics)Microplastics and Plastic PollutionRecycling and Waste Management Techniquesbiodegradable polymer synthesis and properties