Litcius/Paper detail

Impact of Potential and Active-Site Environment on Single-Iron-Atom-Catalyzed Electrochemical CO <sub>2</sub> Reduction from Accurate Quantum Many-Body Simulations

Jincheng Lei, Tianyu Zhu

2024ACS Catalysis21 citationsDOI

Abstract

Single iron atoms supported on nitrogen-doped graphene (Fe–N–C) have shown promise in catalyzing electrochemical reduction of CO 2 to CO with low overpotential and high selectivity. However, the nature of its rate-limiting step and the effect of active-site environment on catalytic activity are still under debate. Previous theoretical studies exclusively rely on density functional theory (DFT), but their predictions are limited by inherent errors in DFT functionals, leading to diverging conclusions on catalytic mechanisms. Herein, we employ an efficient quantum embedding strategy to enable high-level coupled-cluster (CCSD(T)) simulations of the thermodynamics of Fe–N–C-catalyzed CO 2 reduction reaction (CO 2 RR) and its competing hydrogen evolution reaction. Our calculations accurately predict experimental CO binding energy, onset potential, and potential of maximal Faradaic efficiency (FE) with FeN 4 as the catalytic active site. We find that the thermodynamic-limiting step is the formation of a *COOH intermediate at low overpotential, which becomes CO 2 adsorption and CO desorption at higher overpotential. Our simulation reveals that the potential-dependent high selectivity of FeN 4 originates from the higher charge capacity of *COOH compared to *H. Furthermore, our calculations elucidate distinct roles of active-site environments, including vacancy defect and nitrogen doping. Particularly, graphitic nitrogen doping simultaneously lowers the CO 2 RR onset potential and allows a wider potential range for high CO FE. This work highlights the importance of robust many-body quantum chemical simulations in achieving quantitative understanding of multistep electrocatalytic reaction mechanisms.

Topics & Concepts

OverpotentialDensity functional theoryCatalysisChemistryFaraday efficiencyChemical physicsElectrochemistryElectrocatalystComputational chemistryPhysical chemistryElectrodeOrganic chemistryCO2 Reduction Techniques and CatalystsElectrocatalysts for Energy ConversionIonic liquids properties and applications