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Reprocessable Covalent Adaptable Networks via Free-Radical Polymerization with an Aromatic Disulfide Cross-Linker

Mathew J. Suazo, John M. Torkelson

2024ACS Applied Polymer Materials24 citationsDOI

Abstract

Aromatic disulfides have seen widespread use in covalent adaptable networks (CANs), though previous studies have exclusively used step-growth methods to integrate them into CANs. Here, we describe a case in which an aromatic disulfide-based cross-linker, bis(4-methacryloyloxyphenyl) disulfide, also called BiPheS methacrylate or BPMA, is incorporated into a CAN by nonstep-growth polymerization. Free-radical copolymerization of n -hexyl methacrylate with 5 mol % BPMA results in a CAN which exhibits full recovery of cross-link density and thermomechanical properties across multiple reprocessing cycles. The CAN rubbery-plateau storage modulus is directly proportional to absolute temperature, characteristic of a constant cross-link density, even at temperatures where the CAN is reprocessable. Indeed, the BPMA-based CAN exhibits a constant cross-link density, and thus associative dynamic character, at temperatures up to at least 200 °C, enabling it to be used in elevated-temperature applications without risk of loss of network character. Under a 3.0 kPa shear stress, the CAN exhibits almost total arrest of creep up to 180 °C and major creep suppression at its reprocessing temperature of 200 °C, overcoming a potential Achilles’ heel associated with CANs. Thus, the integration of aromatic disulfides into CANs by free-radical polymerization provides a facile route to produce recyclable networks that maintain network character at very high temperature, contributing to polymer network sustainability. Finally, we determined an Arrhenius apparent activation energy of ∼100 kJ/mol for the CAN stress relaxation and creep viscosity. This value differs substantially from the BPMA bond dissociation energy but agrees with the activation energy for the alpha-relaxation of poly( n -hexyl methacrylate) (PHMA). This indicates that the temperature dependence of these viscoelastic responses in our associative-type CAN is defined by the temperature dependence of the cooperative segmental mobility of PHMA, which makes up 95 mol % of the CAN.

Topics & Concepts

Network covalent bondingPolymerizationMaterials scienceCovalent bondRadical polymerizationPolymerMethacrylatePolymer chemistryCopolymerChemical engineeringChemistryOrganic chemistryComposite materialEngineeringPolymer composites and self-healingAdvanced Polymer Synthesis and CharacterizationCarbon dioxide utilization in catalysis
Reprocessable Covalent Adaptable Networks via Free-Radical Polymerization with an Aromatic Disulfide Cross-Linker | Litcius