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Unique CO-switched cellulose solution properties in the CO/DBU/DMSO solvent system and the preparation of regenerated materials

The reaction of cellulose with CO 2 in the presence of various organic superbases resulted in a novel CO 2 derivative dissolution strategy for cellulose, presenting a special solvent system for cellulose dissolution processing and derivatization. The properties of the cellulose solution are importan...

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Bibliographic Details
Published in:Green chemistry : an international journal and green chemistry resource : GC 2021-08, Vol.23 (16), p.5856-5865
Main Authors: Zhang, Lihua, Shi, Wentao, Sheng, Hailiang, Feng, Song, Yao, Minglong, Chen, Peng, Zheng, Qiang, Xie, Haibo
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Summary:The reaction of cellulose with CO 2 in the presence of various organic superbases resulted in a novel CO 2 derivative dissolution strategy for cellulose, presenting a special solvent system for cellulose dissolution processing and derivatization. The properties of the cellulose solution are important for the preparation of particular regenerated materials via dissolution processing. Herein, properties of the cellulose solution in a CO 2 /1.8-diazabicyclo[5.4.0]undec-7-ene/dimethyl sulfoxide (CO 2 /DBU/DMSO) solvent system were first systematically studied, and it was found that the apparent viscosities of cellulose solutions were highly dependent on the cellulose type, concentration and temperature. The overlap concentrations ( c *) were determined to be 2 and 0.6 wt% for the microcrystalline cellulose (MCC) and wood pulp solutions, respectively. The Cox-Merz rule was valid for cellulose solutions in the CO 2 /DBU/DMSO solvent system. Furthermore, taking advantage of the reversible chemistry of CO 2 in this solvent system, a reversible CO 2 -controlled sol-gel transition of the newly achieved cellulose solution in CO 2 /DBU/DMSO was identified by dynamic rheology of measuring the temperature dependence of storage modulus ( G ′) and loss modulus ( G ′′). Furthermore, the interesting CO 2 -controlled sol-gel transition was developed via integrated thermal-induced CO 2 release and anti-solvent extraction for the preparation of regenerated cellulosic gel materials and then cellulose films with a tensile strength of 44.3 MPa. Interestingly, it was found that the regenerated cellulose through this approach turned out to be a cellulose IV I crystalline structure. Taking advantage of the unique CO 2 -switched cellulose solution properties in CO 2 /DBU/DMSO solvent system, the thermal-induced CO 2 release provides an alternative approach to prepare regenerated cellulose materials with IV I crystalline structure.
ISSN:1463-9262
1463-9270
DOI:10.1039/d1gc01771c