Abstract

In heterogeneous catalysis, bifunctional catalysts often outperform one-component catalysts. The activity is also strongly influenced by the morphology, size, and distribution of catalytic particles. For CO2 hydrogenation, the size of the active copper area on top of the SrTiO3 perovskite catalyst support can affect the activity, selectivity, and stability. Here, a detailed theoretical study of the effect of bifunctionality on an important chemical CO2 transformation reaction, the reverse water gas shift (RWGS) reaction, is presented. Using density functional theory computation results for the RWGS pathway on three surfaces, namely, Cu(111), SrTiO3, and the Cu/SrTiO3 interface between both solid phases, we construct the energy landscape of the reaction. The adsorbate–adsorbate lateral interactions are taken into account for catalytic surfaces, which show a sufficient intermediate coverage. The mechanism, combining all three surfaces, is used in mesoscale kinetic Monte Carlo simulations to study the turnover and yield for CO production as a function of particle size. It is shown that the reaction proceeds faster at the interface. However, including copper and the support sites in addition to the interface accelerates the conversion even further, showing that the bifunctionality of the catalyst manifests in a more complex interplay between the phases than just the interface effect, such as the hydrogen spillover. We identify three distinct effects, the electronic, cooperative, and geometric effects, and show that the surrounded smaller Cu features on the set of supporting SrTiO3 show a higher CO formation rate, resulting in a decreasing RWGS model trend with the increasing Cu island size. The findings are in parallel with experiments, showing that they explain the previously observed phenomena and confirming the size sensitivity for the catalytic RWGS reaction.

Highlights

  • In the field of heterogeneous catalysis, the quest for the “perfect” catalyst has been the central topic since time immemorial

  • We study the effect of the active site region in a bifunctional Cu/SrTiO3 catalyst for the reverse water gas shift (RWGS) reaction

  • We show that the SrTiO3 support material is catalytically inactive for the RWGS reaction

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Summary

Introduction

In the field of heterogeneous catalysis, the quest for the “perfect” catalyst has been the central topic since time immemorial. Through more than a century of experiments and several decades of simulations, we have learnt that choosing the right catalytic material is only one part of the puzzle. The effectiveness of a catalyst is in large part determined by the structural and geometric parameters of the surface, such as the facet exposed, the abundance of crystallite boundaries, the aggregation (sintering) in multicomponent catalysts, and so forth. Bifunctional catalysts often outperform pure catalysts, where the interface between different components is believed to play a decisive role. The amount of interface active sites is intimately connected to the dispersion of both active phases. The behavior of nano-sized catalytic particles is completely different from the large-scale activity of the same material

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