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Tailoring Hydronium ion Driven Dissociation-Chemical Cross-Linking for Superfast One-Pot Cellulose Dissolution and Derivatization to Build Robust Cellulose Films.

Yi ChenChengling HuangZhouyu MiaoYoujie GaoYanjuan DongKam Michael Chiu TamHou-Yong Yu
Published in: ACS nano (2024)
Concepts of sustainability must be developed to overcome the increasing environmental hazards caused by fossil resources. Cellulose derivatives with excellent properties are promising biobased alternatives for petroleum-derived materials. However, a one-pot route to achieve cellulose dissolution and derivatization is very challenging, requiring harsh conditions, high energy consumption, and complex solubilizing. Herein, we design a one-pot tailoring hydronium ion driven dissociation-chemical cross-linking strategy to achieve superfast cellulose dissolution and derivatization for orderly robust cellulose films. In this strategy, there is a powerful driving force from organic acid with a p K a below 3.75 to dissociate H + and trigger the dissolution and derivatization of cellulose under the addition of H 2 SO 4 . Nevertheless, the driving force can only trigger a partial swelling of cellulose but without dissolution when the p K a of organic acid is above 4.26 for the dissociation of H + is inhibited by the addition of inorganic acid. The cellulose film has high transmittance (up to ∼90%), excellent tensile strength (∼122 MPa), and is superior to commercial PE film. Moreover, the tensile strength is increased by 400% compared to cellulose film prepared by the ZnCl 2 solvent. This work provides an efficient solvent, which is of great significance for emerging cellulose materials from renewable materials.
Keyphrases
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