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Direct and Catalyst-Free Ester Metathesis Reaction for Covalent Adaptable Networks

Shijia Yang, Wenxing Liu, Jing Guo, Zhusheng Yang, Zhi Qiao, Chenguang Zhang, Jikun Li, Jian Xu, Ning Zhao

2023Journal of the American Chemical Society36 citationsDOI

Abstract

Thermosetting polymers possess excellent environmental resistance and mechanical properties but cannot be reprocessed due to their covalently cross-linked structures. Recycling of thermosets via the implantation of dynamic covalent bonds offers a promising solution. Here, we report the direct and catalyst-free ester metathesis of N -acyloxyphthalimide (NAPI) at about 100 °C without the requirement of hydroxyl groups and its utilization for the fabrication of covalent adaptable networks (CANs). NAPI metathesis has interesting sigmoid kinetics with a fast exchange rate, which proceeds via a free radical chain mechanism, guaranteeing a fast associative exchange under a rather low dissociation. The bifunctional molecule of NAPI as both the radical precursor and substrate is the key to the dissociatively initiated associative (DAssociative) mechanism and kinetic behavior. Based on the efficient NAPI metathesis, polyester networks, poly( N -acyloxyphthalimides) (PNAPIs), show excellent malleability. Notably, PNAPIs exhibit exceptional solvent resistance and mechanical stability at elevated temperatures owing to the unique DAssociative mechanism, suggesting exciting opportunities for designing recyclable thermosetting polymers.

Topics & Concepts

ChemistryCovalent bondMetathesisThermosetting polymerDynamic covalent chemistryBifunctionalCatalysisPolymerCombinatorial chemistryPolyesterPolymer chemistryMoleculeOrganic chemistryPolymerizationSupramolecular chemistrySynthetic Organic Chemistry MethodsPolymer composites and self-healingAdvanced Polymer Synthesis and Characterization
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