Multiscale study of the mechanism of catalytic CO₂ hydrogenation: role of the Ni(111) facets

Abstract

The molecular mechanism of CO2 hydrogenation on a Ni(111) surface has been thoroughly investigated by means of periodic density functional theory calculations, including dispersion interactions, along with accurate kinetic Monte Carlo simulations, including lateral interactions between the adsorbates. The present reaction model involves 25 different species and a total of 86 elementary processes, including adsorptions, desorptions, surface chemical steps, and diffusions. The reaction network accounts for three different mechanisms for the reverse water-gas shift reaction and three different mechanisms for methanation. The kinetic Monte Carlo simulations reveal that the reverse water-gas shift reaction dominates the CO2 hydrogenation on Ni(111) with no evidence of methane formation. The reaction proceeds mainly through the redox route, with the carboxyl pathway also being active but to a lesser extent. Methane production is hindered by the H + CO → HCO endothermicity and the prohibitive energy barrier for CO dissociation, implying CO desorption rather than evolution through the Sabatier reaction. A detailed comparison to earlier theoretical studies supporting the methanation reaction shows that some unreliable assumptions along with limited theoretical approaches biased the former conclusion.