Mechanistic insights into electrochemical reduction of CO2 over Ag using density functional theory and transport models

Meenesh R. Singh; Jason D. Goodpaster; Adam Z. Weber; Martin Head-Gordon; Alexis T. Bell

doi:10.1073/pnas.1713164114

New Research In

Contributed by Alexis T. Bell, September 6, 2017 (sent for review July 24, 2017; reviewed by Ib Chorkendorff, Giulia Galli, and Kai Sundmacher)

Significance

Chemical storage of solar energy can be achieved by electrochemical reduction of CO₂ to CO and H₂, and subsequent conversion of this mixture to fuels. Identifying optimal conditions for electrochemical cell operation requires knowledge of the CO₂ reduction mechanism and the influence of all factors controlling cell performance. We report a multiscale model for predicting the current densities for H₂ and CO formation from first principles. Our approach brings together a quantum-chemical analysis of the reaction pathway, a microkinetic model of the reaction dynamics, and a continuum model for mass transport of all species through the electrolyte. This model is essential for identifying a physically correct representation of product current densities dependence on the cell voltage and CO₂ partial pressure.

Abstract

Electrochemical reduction of CO₂ using renewable sources of electrical energy holds promise for converting CO₂ to fuels and chemicals. Since this process is complex and involves a large number of species and physical phenomena, a comprehensive understanding of the factors controlling product distribution is required. While the most plausible reaction pathway is usually identified from quantum-chemical calculation of the lowest free-energy pathway, this approach can be misleading when coverages of adsorbed species determined for alternative mechanism differ significantly, since elementary reaction rates depend on the product of the rate coefficient and the coverage of species involved in the reaction. Moreover, cathode polarization can influence the kinetics of CO₂ reduction. Here, we present a multiscale framework for ab initio simulation of the electrochemical reduction of CO₂ over an Ag(110) surface. A continuum model for species transport is combined with a microkinetic model for the cathode reaction dynamics. Free energies of activation for all elementary reactions are determined from density functional theory calculations. Using this approach, three alternative mechanisms for CO₂ reduction were examined. The rate-limiting step in each mechanism is **COOH formation at higher negative potentials. However, only via the multiscale simulation was it possible to identify the mechanism that leads to a dependence of the rate of CO formation on the partial pressure of CO₂ that is consistent with experiments. Simulations based on this mechanism also describe the dependence of the H₂ and CO current densities on cathode voltage that are in strikingly good agreement with experimental observation.

Footnotes

↵¹M.R.S. and J.D.G. contributed equally to this work.
↵²To whom correspondence should be addressed. Email: alexbell{at}berkeley.edu.

Author contributions: M.R.S., J.D.G., M.H.-G., and A.T.B. designed research; M.R.S. and J.D.G. performed research; M.R.S., J.D.G., and A.T.B. analyzed data; and M.R.S., J.D.G., A.Z.W., M.H.-G., and A.T.B. wrote the paper.
Reviewers: I.C., Technical University of Denmark; G.G., University of Chicago; and K.S., Max Planck Institute.
The authors declare no conflict of interest.
This article contains supporting information online at www.pnas.org/lookup/suppl/doi:10.1073/pnas.1713164114/-/DCSupplemental.

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