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Chemically circular, mechanically tough, and melt-processable polyhydroxyalkanoates

Li Zhou, Zhen Zhang, Changxia Shi, Miriam Scoti, Deepak Kumar Barange, Ravikumar R. Gowda, Eugene Y.‐X. Chen

2023Science206 citationsDOI

Abstract

Polyhydroxyalkanoates (PHAs) have attracted increasing interest as sustainable plastics because of their biorenewability and biodegradability in the ambient environment. However, current semicrystalline PHAs face three long-standing challenges to broad commercial implementation and application: lack of melt processability, mechanical brittleness, and unrealized recyclability, the last of which is essential for achieving a circular plastics economy. Here we report a synthetic PHA platform that addresses the origin of thermal instability by eliminating α-hydrogens in the PHA repeat units and thus precluding facile cis-elimination during thermal degradation. This simple α,α-disubstitution in PHAs enhances the thermal stability so substantially that the PHAs become melt-processable. Synergistically, this structural modification also endows the PHAs with the mechanical toughness, intrinsic crystallinity, and closed-loop chemical recyclability.

Topics & Concepts

PolyhydroxyalkanoatesCrystallinityToughnessMaterials scienceThermal stabilityBrittlenessBiodegradationDegradation (telecommunications)PolymerPolymer scienceComposite materialChemistryOrganic chemistryBiologyBacteriaGeneticsComputer scienceTelecommunicationsbiodegradable polymer synthesis and propertiesPolymer crystallization and propertiesAdditive Manufacturing and 3D Printing Technologies
Chemically circular, mechanically tough, and melt-processable polyhydroxyalkanoates | Litcius