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Citation: Bo Duan, Hu Tu, Li-na Zhang. Material Research Progress of the Sustainable Polymer-Cellulose[J]. Acta Polymerica Sinica, ;2020, 51(1): 66-86. doi: 10.11777/j.issn1000-3304.2020.19160 shu

Material Research Progress of the Sustainable Polymer-Cellulose

  • College of Chemistry and Molecular Sciences, Wuhan University, Wuhan 430072

  • The “Green Chemistry” has become the strategy direction of research and development of the world in the 21th century. Cellulose, as the most abundant natural polymers, is a very important renewable resource and the main industrial raw material. The cellulose shows many great advances including biocompatibility, biodegradability, high structure stability. However, due to the large amounts of inter- and intra-hydrogen bonding among the cellulose molecules, the cellulose has a dense structure and is very hard to be processed through dissolution or melt, which limit the further exploitation of the cellulose resource. The traditional organic solution of the cellulose often has the problem of high cost and pollution. In recent decades, with the development of the “Green” solvent (alkaline/urea, ionic liquid, etc.) and the cellulose nanotechnology, the researchers have greatly expanded the cellulose application in biomedical, energy storage, optical fields in addition to the traditional spinning and papermaking industry. This review mainly introduces the new methods (“bottom to up” and “up to down”) for the exploitation of cellulose based materials in recent years through the following four sections: (1) the regenerated cellulose based materials from the “green” solution-alkaline/urea aqueous and ionic liquid; (2) the preparation and self-assembly of the nanocellulose; (3) the development and utilization of the wood nanotechnology; (4) bacterial cellulose based functional materials.
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