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Engineering bimetallic interfaces and revealing the mechanism for carbon dioxide electroreduction to C3+ liquid chemicals

Yuting Xu, Michael B. Ross, Hongliang Xin, Fanglin Che

2023Cell Reports Physical Science10 citationsDOIOpen Access PDF

Abstract

The reduction reaction of carbon dioxide (CO2RR) to liquid C3+ chemicals is a potential net-zero carbon process that can increase local resiliency to power outages and fuel consumption. However, the mechanism and catalyst design rules to promote CO2RR-to-C3+ are unknown. Engineering bimetallic interfaces (e.g., palladium/gold) to tune intermediate adsorption is promising for promoting C3+ formation. Our density functional theory calculations find that ∗CH2 could be the key intermediate, and C1–CH2 coupling could be the rate-limiting step to generate C3+. High CO surface coverages can promote the bimetallic interfacial sites, lower the energetics of the C1–CH2 coupling step, and enhance C3+ formation. We further construct a volcano plot of C1–CH2 kinetics as a function of the binding strength of key intermediate ∗CH2 via engineering the d-band center of the interfacial site. Our findings could guide the rational design of bimetallic interfaces and their near-surface microenvironment for enhancing CO2RR-to-C3+.

Topics & Concepts

Bimetallic stripCatalysisAdsorptionMaterials scienceDensity functional theoryRedoxRate-determining stepCarbon fibersChemical engineeringNanotechnologyCarbon dioxideChemical physicsPalladiumChemistryInorganic chemistryComputational chemistryPhysical chemistryOrganic chemistryComposite materialComposite numberEngineeringCO2 Reduction Techniques and CatalystsAmmonia Synthesis and Nitrogen ReductionCatalytic Processes in Materials Science
Engineering bimetallic interfaces and revealing the mechanism for carbon dioxide electroreduction to C3+ liquid chemicals | Litcius