Green synthesis of cellulose formate and its efficient conversion into 5-hydroxymethylfurfural

5-hydroxymethylfurfural (HMF) production from cellulose is a hot topic, while the rigidity of cellulose limits its efficient conversion into HMF. Cellulose formate has exhibited the great potential for HMF production but it's synthesis via direct formylation of cellulose in formic acid is difficult. Herein, we reported a green synthetic route of cellulose formate and its efficient conversion into HMF. Ball milled cellulose formate (BCF) was synthesized via ball milling followed by formylation in formic acid at 80 degrees C for 0.5 h. The structure of BCF was thoroughly characterized and BCF was subsequently converted to HMF catalyzed by AlCl3 and HCl in dimethyl sulfoxide (DMSO)-H2O media. Results showed that ball milling of cellulose for 1-1.5 h efficiently deconstructed its crystallinity and degree of polymerization, boosting its further formylation and catalytic conversion. An overall 66.9% HMF yield from cellulose was achieved at 150 degrees C for 20 min using BCF derived from cellulose ball milled for 1.5 h as the substrate. BCF exhibits high reactivity toward HMF due to its excellent solubility and accessibility in DMSO-H2O media, and the release of formic acid in reaction further facilitates HMF production. BCF synthesized with different ball milling times shows different degrees of substitution of formyl groups, which could serve as an indicator and regulate the HMF production. The green synthesis of cellulose formate creates an efficient pathway for HMF production.

Automated summary

This study presents a green synthetic route of cellulose formate and its efficient conversion into 5-hydroxymethylfurfural (HMF). Ball milling was used to improve the formylation and catalytic conversion of cellulose formate (BCF) into HMF. The use of BCF derived from cellulose ball milled for 1.5 h achieved a 66.9% HMF yield at 150 degrees C for 20 min. BCF exhibited high reactivity towards HMF due to its excellent solubility and accessibility in DMSO-H2O media.