Highly Efficient 5-Hydroxymethylfurfural Production from Glucose over Bifunctional SnOx/C catalyst

Catalytic conversion of glucose to 5-hydroxymethylfurfural (HMF) is a highly desirable routine for producing value-added chemicals. Herein, by using glucose as carbon source to fabricate porous carbon support, SnCl4 and citric acid were selected for forming Lewis acidic/basic SnOx and Bronsted -COOH over support, respectively, bifunctional solid acid tin oxide/carbon catalysts were prepared by a hydrothermal-pyrolysis strategy. It is found that the acid density of SnOx/C could be tuned by adjusting SnCl4 dosage and pyrolysis temperature. In a H2O-NaCl/THF biphasic system, 92.1% glucose conversion and 84.1% HMF yield were achieved over an optimized 3.0-SnOx/C-500 catalyst at 180 degrees C for 2 h. This catalyst demonstrates excellent recyclability in this reaction for five times and is also versatile for one-pot transformation of cellulose to HMF with 39.9% yield. The superior performance of 3.0-SnOx/C-500 could be ascribed to its highly dispersed SnOx nanoparticles, a suitable ratio of Bronsted to Lewis acids, as well as accessible pore-structure of the catalyst.

Automated summary

A bifunctional solid acid tin oxide/carbon catalyst, prepared from glucose as a carbon source, showed efficient catalytic conversion of glucose to 5-hydroxymethylfurfural (HMF) with high conversion and yield under optimized conditions. The catalyst also demonstrated excellent recyclability and versatility for one-pot transformation of cellulose to HMF, attributed to its highly dispersed SnOx nanoparticles, suitable ratio of Bronsted to Lewis acids, and accessible pore-structure.