Structure effects on the energetics of the electrochemical reduction of CO2 by copper surfaces

Structure effects on the energetics of the electrochemical reduction of CO2 by copper surfaces

Polycrystalline copper electrocatalysts have been experimentally shown to be capable of reducing CO{sub 2} into CH{sub 4} and C{sub 2}H{sub 4} with relatively high selectivity, and a mechanism has recently been proposed for this reduction on the fcc(211) surface of copper, which was assumed to be th...

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Bibliographic Details
Published in:Surface science Vol. 605; no. 15-16; pp. 1354 - 1359
Main Authors: DURAND, William J, PETERSON, Andrew A, STUDT, Felix, ABILD-PEDERSEN, Frank, NØRSKOV, Jens K
Format: Journal Article
Language:English
Published: Kidlington Elsevier 01-08-2011
Subjects:
BY-PRODUCTS
CHEM, MATSCI
Condensed matter: electronic structure, electrical, magnetic, and optical properties
Condensed matter: structure, mechanical and thermal properties
COPPER
Cross-disciplinary physics: materials science; rheology
ELECTROCATALYSTS
Exact sciences and technology
FORECASTING
FORMATES
NANOSCIENCE AND NANOTECHNOLOGY
NANOSTRUCTURES
Physics
PRODUCTION
Inorganic compounds
Transition elements
Density functional method
Density functional calculations
Catalysis
Copper
Carbon oxides
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Summary:Polycrystalline copper electrocatalysts have been experimentally shown to be capable of reducing CO{sub 2} into CH{sub 4} and C{sub 2}H{sub 4} with relatively high selectivity, and a mechanism has recently been proposed for this reduction on the fcc(211) surface of copper, which was assumed to be the most active facet. In the current work, we use computational methods to explore the effects of the nanostructure of the copper surface and compare the effects of the fcc(111), fcc(100) and fcc(211) facets of copper on the energetics of the electroreduction of CO{sub 2}. The calculations performed in this study generally show that the intermediates in CO{sub 2} reduction are most stabilized by the (211) facet, followed by the (100) facet, with the (111) surface binding the adsorbates most weakly. This leads to the prediction that the (211) facet is the most active surface among the three in producing CH{sub 4} from CO{sub 2}, as well as the by-products H{sub 2} and CO. HCOOH production may be mildly enhanced on the more close-packed surfaces ((111) and (100)) as compared to the (211) facet, due to a change in mechanism from a carboxyl intermediate to a formate intermediate. The results are compared to experimental data on these same surfaces; the predicted trends in voltage requirements are consistent between the experimental and computational data.
Bibliography:SLAC-PUB-14396
USDOE
AC02-76SF00515
ISSN:0039-6028
1879-2758
DOI:10.1016/j.susc.2011.04.028