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Blocking Methanation during Reverse Water Gas Shift Reaction on Ni/SiO<sub>2</sub> Catalysts by Surface Ag

Chu Zhang, Ruoyu Zhang, Yuxin Liu, Xiaoxia Wu, Hua Wang, Qingfeng Ge, Xinli Zhu

2022ChemCatChem30 citationsDOI

Abstract

Abstract Reverse water gas shift (RWGS) reaction is an attractive approach to convert CO 2 with renewable H 2 to produce CO. However, this reaction is always accompanied by undesirable methanation reaction lowering the CO selectivity, particularly, at low reaction temperature and on Ni catalysts. Herein, a strategy of deposition of inert Ag on the surface of Ni to block methanation reaction during RWGS for selective conversion of CO 2 toward CO was reported. Characterizations showed that in contrast to formation of bulk Ni−Ag alloy, both Ag particle and highly dispersed Ag are direct contacting with Ni particle. Surface Ag modifies the property of Ni geometrically and electronically, resulting in reduced accessible surface Ni sites and Ni ensemble size, as well as electron transfer from Ni to Ag. Consequently, both the amount and strength of CO adsorption are reduced, which facilitates CO desorption and reduces CO methanation activity. The Ag modification tunes Ni/SiO 2 from selective methanation to selective RWGS, with 100 % CO selectivity on Ni‐0.3 Ag/SiO 2 (Ag/Ni=0.3) at 400 °C with gas hourly space velocity (GHSV) &gt;300 L g −1 h −1 and CO selectivity is &gt;80.7 % even at a low GHSV of 15 L g −1 h −1 . Moreover, the Ni‐0.3 Ag/SiO 2 appears to be very stable for RWGS reaction.

Topics & Concepts

MethanationWater-gas shift reactionCatalysisSelectivitySpace velocityChemical engineeringMaterials scienceAdsorptionInert gasDesorptionInorganic chemistryParticle sizeChemistryPhysical chemistryComposite materialOrganic chemistryEngineeringCatalysts for Methane ReformingCatalytic Processes in Materials ScienceAmmonia Synthesis and Nitrogen Reduction