Furfural hydrodeoxygenation (HDO) over silica-supported metal phosphides - The influence of metal-phosphorus stoichiometry on catalytic properties

The gas-phase hydrodeoxygenation (HDO) of furfural, a model compound for bio-based conversion, was investigated over transition metal phosphide catalysts. The HDO activity decreases in the order Ni2P approximate to MoP > Co2P approximate to WP >> Cu3P > Fe2P. Nickel phosphide phases (e.g., Ni2P, Ni12P5, Ni3P) are the most promising catalysts in the furfural HDO. Their selectivity to the gasoline additives 2-methylfuran and tetrahydro-2-methylfuran can be adjusted by varying the P/Ni ratio. The effect of P on catalyst properties as well as on the reaction mechanism of furfural HDO were investigated in depth for the first time. An increase of the P stoichiometry weakens the furan-ring/catalyst interaction, which contributes to a lower ring-opening and ring-hydrogenation activity. On the other hand, an increasing P content does lead to a stronger carbonyl/catalyst interaction, i.e., to a stronger eta(2)(C, O) adsorption configuration, which weakens the C1-O1 bond (Scheme 1) in the carbonyl group and enhances the carbonyl conversion. Phosphorus species can also act as Bronsted acid sites promoting C1-O1 (Scheme 1) hydrogenolysis of furfuryl alcohol, hence contributing to higher production of 2-methylfuran. (C) 2021 The Author(s). Published by Elsevier Inc.

Automated summary

Gas-phase hydrodeoxygenation (HDO) of furfural, a model compound for bio-based conversion, was studied using transition metal phosphide catalysts, with nickel phosphide phases showing the most promising catalytic activity. The selectivity of the catalysts for gasoline additives can be adjusted by varying the phosphorus-to-nickel ratio. The impact of phosphorus content on catalyst properties and reaction mechanisms in furfural HDO was investigated in depth for the first time.