Oxygen vacancy and support adsorption synergistic effect in aerobic oxidation of HMF to FDCA: A case study using nitrogen-doped porous carbon supported Bi-CeO2

Abstract

BackgroundThe conversion of 5-Hydroxymethylfurfural into high value-added 2,5-furandicarboxylic acid is of great significance for industrial production and people's life. Rationally regulation of oxygen vacancy and reactant adsorption are keys to developing an efficient metal oxide catalyst for aerobic oxidation of 5-hydroxymethylfurfural to 2,5-furandicarboxylic acid. MethodIn this research, nitrogen-doped porous carbon-supported Bi-doped CeO2 (x%Bi-CeO2/N-PCT) catalysts were successfully prepared by co-calcination method. Significant findingsOxygen vacancy concentration of CeO2 can be effectively enlarged by Bi-doping, which was strongly related to the catalytic performance. In-situ FTIR and adsorption experiment results showed that the introduction of N-PCT can enhance the HMF adsorption performance of catalyst. Density functional theory calculation and XPS results proved that the HMF adsorption performance depend on content of graphitic N in N-PCT, thus effecting the catalytic performance of HMF oxidation. Synergistic effect of oxygen vacancy and HMF adsorption ability can enhance the catalytic performance, the FDCA yield of 10%Bi-CeO2/N-PC800 was about 70 times higher than that of pure CeO2. 10%Bi-CeO2/N-PC800 as support for Au nanoparticles demonstrated an excellent yield of FDCA (92.8%). This study provides a novel idea for design of CeO2-based catalyst for oxidation of HMF to high value-added downstream chemicals.