What question did this study set out to answer?

This research aims to improve the recycling efficiency of polyolefin plastics through optimized catalysts.

April 25, 2026

Engineering Interfacial Compatibility and Dynamic Active Hydrogen Pools to Accelerate Polyolefin Hydrogenolysis

Key Points

This research aims to improve the recycling efficiency of polyolefin plastics through optimized catalysts.
Developed a Ru/TiO2-CNT catalyst to enhance interfacial compatibility and dynamic active hydrogen pools.
Evaluated the catalyst performance under mild conditions for polypropylene and polyethylene wastes.
The catalyst showed effective C−C bond cleavage with enhanced electronic states of Ru.
Dynamic hydrogen pools facilitated efficient hydrogenation and desorption of intermediates.
The catalyst demonstrated broad applicability towards various real-world polyolefin wastes.

Abstract

The chemical inertness of polyolefin plastics poses a significant challenge to their efficient recycling. In this work, a Ru/TiO2-CNT catalyst is developed by engineering interfacial compatibility and dynamic active hydrogen pools to accelerate polyolefin hydrogenolysis. Enhanced interfacial compatibility between Ru and TiO2 optimizes the electronic state of Ru, thereby facilitating effective C−C bond cleavage. Meanwhile, dynamic active hydrogen pools, enabled by a reversible hydrogen spillover pathway mediated by CNTs as a hydrogen-transfer channel, promote efficient hydrogenation and desorption of reaction intermediates. Under mild conditions, the catalyst exhibits broad applicability toward a variety of real-world polypropylene (PP) and polyethylene (PE) wastes. This work presents an effective catalyst construction strategy and offers fundamental insights into the hydrogenolysis of waste polyolefins.

Engineering Interfacial Compatibility and Dynamic Active Hydrogen Pools to Accelerate Polyolefin Hydrogenolysis

Key Points

Abstract

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