Key Words:ETHYLENE-GLYCOL; SELECTIVE CONVERSION; HYDROGENATION; OXIDE; DEPOLYMERIZATION; TRANSFORMATION; PERFORMANCE; DEPOSITION; CHEMICALS; ETHANOL

Abstract:Converting cellulose into C2 alcohols presents a sustainable alternative to fossil fuels, contributing to the development of eco-friendly and economically viable biofuels and chemicals. Tungsten oxide (WO3) is a key solid acid catalyst for this process, yet limited research explores its diverse morphologies and unique catalytic effects. This study investigates diverse WO3 morphologies (nanosheets, nanoflowers, nanoblocks, and tetrahedral octahedra) in combination with Pd for converting cellulose to C2 alcohols. Optimized conditions with Pd/o-WO3 catalyst resulted in the highest C2 alcohols (ethylene glycol and ethanol, 80.9 %), notably yielding 64.8 % ethylene glycol. Extensive characterizations and DFT calculations reveal the smaller element occupancy rates and a longer W-O bond length led to a large number of crystal defects over Pd/o-WO3. It facilitated the formation of W5 -OH sites and Pd-O(H)-W interactions, further synergistically enhancing hydrogenation ability and acidity. Designed experiments to elucidate cellulose conversion pathways, including hydrolysis, retro-aldol condensation, and hydrogenation. This study emphasizes the unique impact of WO3 morphologies and underscores the importance of supporting crystal defects for catalytic performance in eco-friendly biofuel and chemical production.

Volume:442

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Translation or Not:no