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Intrinsically Re-curable Photopolymers Containing Dynamic Thiol-Michael Bonds

Connor J. Stubbs, Anissa L. Khalfa, Viviane Chiaradia, Joshua C. Worch, Andrew P. Dove

2022Journal of the American Chemical Society41 citationsDOIOpen Access PDF

Abstract

The development of photopolymers that can be depolymerized and subsequently re-cured using the same light stimulus presents a significant technical challenge. A bio-sourced terpenoid structure, l-carvone, inspired the creation of a re-curable photopolymer in which the orthogonal reactivity of an irreversible thioether and a dynamic thiol-Michael bond enables both photopolymerization and thermally driven depolymerization of mechanically robust polymer networks. The di-alkene containing l-carvone was partially reacted with a multi-arm thiol to generate a non-crosslinked telechelic photopolymer. Upon further UV exposure, the photopolymer crosslinked into a mechanically robust network featuring reversible Michael bonds at junction points that could be activated to revert, or depolymerize, the network into a viscous telechelic photopolymer. The regenerated photopolymer displayed intrinsic re-curability over two recycles while maintaining the desirable thermomechanical properties of a conventional network: insolubility, resistance to stress relaxation, and structural integrity up to 170 °C. Our findings present an on-demand, re-curable photopolymer platform based on a sustainable feedstock.

Topics & Concepts

PhotopolymerChemistryPolymerPolymerizationPolymer chemistryPhotochemistryOrganic chemistryPolymer composites and self-healingPhotochromic and Fluorescence ChemistryPolydiacetylene-based materials and applications
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