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Hydrogen Production via Water–Gas Shift Reaction by Cu/SiO<sub>2</sub> Catalyst: A Case Study of CeO<sub>2</sub> Doping

Guohui Cai, Yuanyuan He, Hongju Ren, Yingying Zhan, Chongqi Chen, Yu Luo, Lilong Jiang

2021Energy & Fuels21 citationsDOI

Abstract

CeO2 was employed to modify the Cu/SiO2 catalyst for water–gas shift (WGS) reaction, and two different ways to introduce CeO2 were applied, i.e., ammonia evaporation hydrothermal (AEH) and impregnation (IM) methods. The sizes of Cu nanoparticles and strength of Cu–SiO2 synergetic interaction were analyzed by HRTEM and H2-TPR characterizations. The Cu+/Cu0 ratio and strength of Cu–CeO2 synergetic interaction were evaluated via XPS and XAES techniques. It was revealed that more Cu0 leads to higher CO conversion, based on its pronounced effect on water dissociation. The strength of the Cu–SiO2 synergetic interaction in the Cu/SiO2 catalyst varies with altering the state of CuO species. Cu–CeO2 synergetic interaction is associated with oxygen vacancies in CeO2, which also act as active sites for H2O dissociation. The Cu/SiO2–CeO2-AEH catalyst exhibits the best activity and stability among the three catalysts toward the WGS reaction, because it has a large number of Cu0 and strong synergetic interaction of Cu with SiO2 and CeO2.

Topics & Concepts

CatalysisWater-gas shift reactionHigh-resolution transmission electron microscopyDissociation (chemistry)X-ray photoelectron spectroscopyHydrogen productionAmmonia productionHydrogenHydrothermal circulationAmmoniaChemistryOxygenInorganic chemistryDopingChemical engineeringCopperMaterials sciencePhysical chemistryNanotechnologyEngineeringTransmission electron microscopyOptoelectronicsBiochemistryOrganic chemistryCatalytic Processes in Materials ScienceCatalysts for Methane ReformingNanomaterials for catalytic reactions