Engineering functional hydrochar based catalyst with corn stover and model components for efficient glucose isomerization

The conversion of biomass to functional hydrochar based catalysts for sustainable biorefinery application is critical but still challenging. In this study, mild hydrothermal treatment combined with limited oxygen calcination was developed to treat corn stover and model components for directional preparation of hydrochar based catalysts. The prepared catalysts with various Al active species, exhibited high specific surface area, hierarchical pores, cross-linked carbon microspheres, and excellent catalytic and recycling performances for glucose isomerization. After optimization, a fructose yield of 35.1% (selectivity 77.4%) was obtained at 160 degrees C for 20 min and it was still more than 25% after the fourth recycling. The reaction kinetics for glucose isomerization was studied. This study established the physicochemical properties performance relationships of hydrochar based catalysts. The optimized hydrothermal and calcination steps were crucial to improving performance by regulating the active sites and catalyst structures. Moreover, nitrogen, silicon and other elements coupled together could form functional compounds, which is vital for improving the catalytic performance by the synergy between support and Al active center. Three components in corn stover played distinct roles in the catalysis step. This study provides a novel way for developing efficient and recyclable catalysts from biomass, which could be applied in biorefining. (C) 2022 Elsevier Ltd. All rights reserved.

Automated summary

In this study, hydrochar based catalysts with high catalytic and recycling performances were successfully prepared through mild hydrothermal treatment and limited oxygen calcination. The reaction kinetics for glucose isomerization were studied, and the relationships between the physicochemical properties and performance of hydrochar based catalysts were established. The optimized hydrothermal and calcination steps were crucial for improving the catalyst performance.