Abstract
Bioplastics derived from renewable food crops or agricultural feedstocks are alternatives to petrochemical materials, but it is challenging to balance their mechanical properties, thermal stability, and shapeability. Here, we report a thermally stimulated supramolecular bioplastic that employs polyethylene glycol to optimize the assembly of cellulose and polyvinyl alcohol molecules. The resulting bioplastic showed a reinforced supramolecular architecture, with a mechanical elastic modulus of 3.23 GPa and an impact resistance higher than 8.15 kJ·m(-1). It also showed thermal stability from -40 to 135 °C while maintaining its structural integrity and toughness, giving it potential applications for various shaping processes, including weaving, pouring, and molding. The bioplastic could also undergo natural soil biodegradation within 55 d and exhibited promising recyclability and economic feasibility. This study provides a strategy for configuring supramolecular structures and enhancing the design and manufacture of bioplastics with optimal comprehensive properties.