Litcius/Paper detail

A Biodegradable, Waterproof, and Thermally Processable Cellulosic Bioplastic Enabled by Dynamic Covalent Modification

Guowen Zhou, Hai‐Shan Zhang, Zhiping Su, Xiaoqian Zhang, Haonan Zhou, Le Yu, Chaoji Chen, Xiaohui Wang

2023Advanced Materials203 citationsDOI

Abstract

Abstract The growing environmental concern over petrochemical‐based plastics continuously promotes the exploration of green and sustainable substitute materials. Compared with petrochemical products, cellulose has overwhelming superiority in terms of availability, cost, and biodegradability; however, cellulose's dense hydrogen‐bonding network and highly ordered crystalline structure make it hard to be thermoformed. A strategy to realize the partial disassociation of hydrogen bonds in cellulose and the reassembly of cellulose chains via constructing a dynamic covalent network, thereby endowing cellulose with thermal processability as indicated by the observation of a moderate glass transition temperature ( T g = 240 °C), is proposed. Moreover, the cellulosic bioplastic delivers a high tensile strength of 67 MPa, as well as excellent moisture and solvent resistance, good recyclability, and biodegradability in nature. With these advantageous features, the developed cellulosic bioplastic represents a promising alternative to traditional plastics.

Topics & Concepts

BioplasticMaterials scienceCelluloseBiodegradationPetrochemicalThermoformingCellulosic ethanolUltimate tensile strengthCellulose fiberGlass transitionCovalent bondComposite materialPolymer scienceChemical engineeringPolymerOrganic chemistryWaste managementFiberChemistryEngineeringAdvanced Cellulose Research Studiesbiodegradable polymer synthesis and propertiesPolymer composites and self-healing