Abstract

The electrochemical reduction of carbon dioxide into carbon monoxide, hydrocarbons and formic acid has offered an interesting alternative for a sustainable energy scenario. In this context, Sn-based electrodes have attracted a great deal of attention because they present low price and toxicity, as well as high faradaic efficiency (FE) for formic acid (or formate) production at relatively low overpotentials. In this work, we investigate the role of tin oxide surfaces on Sn-based electrodes for carbon dioxide reduction into formate by means of experimental and theoretical methods. Cyclic voltammetry measurements of Sn-based electrodes, with different initial degree of oxidation, result in similar onset potentials for the CO2 reduction to formate, ca. −0.8 to −0.9 V vs. reversible hydrogen electrode (RHE), with faradaic efficiencies of about 90–92% at −1.25 V (vs. RHE). These results indicate that under in-situ conditions, the electrode surfaces might converge to very similar structures, with partially reduced or metastable Sn oxides, which serve as active sites for the CO2 reduction. The high faradaic efficiencies of the Sn electrodes brought by the etching/air exposition procedure is ascribed to the formation of a Sn oxide layer with optimized thickness, which is persistent under in situ conditions. Such oxide layer enables the CO2 “activation”, also favoring the electron transfer during the CO2 reduction reaction due to its better electric conductivity. In order to elucidate the reaction mechanism, we have performed density functional theory calculations on different slab models starting from the bulk SnO and Sn6O4(OH)4 compounds with focus on the formation of -OH groups at the water-oxide interface. We have found that the insertion of CO2 into the Sn-OH bond is thermodynamically favorable, leading to the stabilization of the tin-carbonate species, which is subsequently reduced to produce formic acid through a proton-coupled electron transfer process. The calculated potential for CO2 reduction (E = −1.09 V vs. RHE) displays good agreement with the experimental findings and, therefore, support the CO2 insertion onto Sn-oxide as a plausible mechanism for the CO2 reduction in the potential domain where metastable oxides are still present on the Sn surface. These results not only rationalize a number of literature divergent reports but also provide a guideline for the design of efficient CO2 reduction electrocatalysts.

Highlights

  • The increasing levels of carbon dioxide and other greenhouse gases in the atmosphere have been associated with a major problem, the so-called global warming, with roots in the use of coal and/or fossil fuels in energy power plants, transportation and cement industries, among others

  • The high faradaic efficiencies of the Sn electrodes brought by the etching/air exposition procedure can be attributed to the formation of an optimized thickness of the tin oxide layer, allowing the presence of Sn oxides that are important for the CO2 “activation”, besides the presence of good electric conductivity that favors the electron transfer during the CO2 reduction reaction

  • We have considered two sets of Sn electrode preparation, involving different exposures times to air after acid etching, producing electrodes with different initial extent of oxidation

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Summary

Introduction

The increasing levels of carbon dioxide and other greenhouse gases in the atmosphere have been associated with a major problem, the so-called global warming, with roots in the use of coal and/or fossil fuels in energy power plants, transportation and cement industries, among others. Converting carbon dioxide into organic fuels can be achieved by means of chemical reactions through either electrochemical or photoelectrochemical processes [6,7] In the former route, metals with high hydrogen evolution overpotential such as In, Pb and Sn exhibit good selectivity to produce formic acid (or formate, depending on the pH) in aqueous electrolyte, but Hg, Cd and Bi have shown electrocatalytic activity [3,5,8,9]. Materials with interesting results include alloys (e.g., Cu-Zn) [10], carbon nanotubes [11], metal oxides (e.g., Cu2 O, Bi2 O3 and In2 O3 ) [12,13], and in special, the Sn-based materials have attracted the attention of several researchers due to its low cost and toxicity [2,8,14,15,16]

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