Covalent Adaptable Polymer Networks with CO-facilitated Recyclability

Overview

Journal Nat Commun

Specialty Biology

Date 2024 Aug 4

PMID 39098918

Authors

Jiayao Chen

Lin Li

Jiancheng Luo

Lingyao Meng

Xiao Zhao

Shenghan Song

Zoriana Demchuk

Pei Li

Yi He

Alexei P Sokolov

Peng-Fei Cao

Affiliations

Soon will be listed here.

Abstract

Cross-linked polymers with covalent adaptable networks (CANs) can be reprocessed under external stimuli owing to the exchangeability of dynamic covalent bonds. Optimization of reprocessing conditions is critical since increasing the reprocessing temperature costs more energy and even deteriorates the materials, while reducing the reprocessing temperature via molecular design usually narrows the service temperature range. Exploiting CO gas as an external trigger for lowering the reprocessing barrier shows great promise in low sample contamination and environmental friendliness. Herein, we develop a type of CANs incorporated with ionic clusters that achieve CO-facilitated recyclability without sacrificing performance. The presence of CO can facilitate the rearrangement of ionic clusters, thus promoting the exchange of dynamic bonds. The effective stress relaxation and network rearrangement enable the system with rapid recycling under CO while retaining excellent mechanical performance in working conditions. This work opens avenues to design recyclable polymer materials with tunable dynamics and responsive recyclability.

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