Density-Functional Theory Simulation of the Dissociative Chemisorption of Water Molecules on the MgO(001) Surface

Alvim, Raphael da Silva; Borges, Itamar; Costa, Débora Vargas Ferreira; Leitão, Alexandre A.

doi:10.1021/jp208007q

Cited by 47 publications

(46 citation statements)

References 54 publications

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“…In the following, we focus on water adsorption at low partial pressures (10 -8 -10 -5 mbar) or medium pressures (10 -5 -10 -3 mbar). At the lowest pressures, all of the previous theoretical investigations agree on the fact that the dissociative adsorption of water on flat MgO(100) terraces only occurs for water clusters and monolayers [23][24][25][26], while isolated water molecules adsorbs in a molecular form. In that pressure range, the main contributions to the IR spectra on small MgO nano-powders essentially come from dissociated water at defects [27].…”

Section: Theorysupporting

confidence: 62%

Water dissociation on the low-coordinated sites of MgO nanopowders

et al. 2019

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Section: Theorysupporting

confidence: 62%

Water dissociation on the low-coordinated sites of MgO nanopowders

et al. 2019

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“…Also exciting is the perspective to tune the properties of interfacial water by changing the oxide support. However, hydrogen-bonded water ad-molecules on MgO(001) can dissociate, giving rise to characteristic hydroxyl groups consisting of a surface O and a proton coming from the ad-molecule 14 . Although less relevant in geochemistry, biology and catalysis than other oxide surfaces, the (001) surface of MgO shows a simple atomic and electronic structure that is well established in dry conditions.…”

Section: Introductionmentioning

confidence: 99%

Strong electric fields at a prototypical oxide/water interface probed by ab initio molecular dynamics: MgO(001)

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Paulatto

et al. 2015

Phys. Chem. Chem. Phys.

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We report a density-functional theory (DFT)-based study of the interface of bulk water with a prototypical oxide surface, MgO(001), and focus our study on the often-overlooked surface electric field. In particular, we observe that the bare MgO(001) surface, although charge-neutral and defectless, has an intense electric field on the Å scale. The MgO(001) surface covered with 1 water monolayer (1 ML) is investigated via a supercell accounting for the experimentally-observed (2 × 3) reconstruction, stable at ambient temperature, and in which two out of six water molecules are dissociated. This 1 ML-hydrated surface is also found to have a high, albeit short-ranged, normal component of the field. Finally, the oxide/water interface is studied via room-temperature ab initio molecular dynamics (AIMD) using 34 H2O molecules between two MgO(001) surfaces. To our best knowledge this is the first AIMD study of the MgO(001)/liquid water interface in which all atoms are treated using DFT and including several layers above the first adsorbed layer. We observe that the surface electric field, averaged over the AIMD trajectories, is still very strong on the fully-wet surface, peaking at about 3 V Å(-1). Even in the presence of bulk-like water, the structure of the first layer in contact with the surface remains similar to the (2 × 3)-reconstructed ice ad-layer on MgO(001). Moreover, we observe proton exchange within the first layer, and between the first and second layers - indeed, the O-O distances close to the surface are found to be distributed towards shorter distances, a property which has been shown to directly promote proton transfer.

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“…The thermodynamic potentials for all the elementary reactions were calculated by using vibrational data, according to the procedure described in our previous works, [50][51][52][53][54] including the contribution from the lattice thermal vibrations and the zeropoint energy (ZPE).…”

Section: Calculation Of Thermodynamic Functions and Rate Constantsmentioning

confidence: 99%

DFT Study of Synergistic Catalysis of the Water‐Gas‐Shift Reaction on Cu–Au Bimetallic Surfaces

et al. 2016

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The water‐gas‐shift reaction (WGSR) is an important industrial process that can be significantly enhanced at suitable catalyst surfaces. In this work, we investigate the catalytic behavior of metallic Cu(1 0 0) and bimetallic Cu–Au(1 0 0) surfaces. With density functional theory calculations, the variation in the Gibbs free energy (ΔG°), the activation barriers, and the rate constants for the WGSR are calculated. The variation in ΔG° for water dissociation shows that the process is spontaneous up to 520 K on the bimetallic surface and up to 229 K on the Cu(1 0 0) surface. The calculated rate constants for the process also show that the bimetallic surface is much more reactive than the Cu(1 0 0) surface. The calculated pressure–temperature phase diagram for water dissociation shows that the partial pressure of H2O required for water dissociation on the bimetallic surface is substantially lower than that on the Cu(1 0 0) surface at all the studied temperatures. Additionally, the calculations demonstrate that the kinetics of the water‐gas‐shift reaction is dominated by redox processes on both the surfaces.

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Density-Functional Theory Simulation of the Dissociative Chemisorption of Water Molecules on the MgO(001) Surface

Cited by 47 publications

References 54 publications

Water dissociation on the low-coordinated sites of MgO nanopowders

Water dissociation on the low-coordinated sites of MgO nanopowders

Strong electric fields at a prototypical oxide/water interface probed by ab initio molecular dynamics: MgO(001)

DFT Study of Synergistic Catalysis of the Water‐Gas‐Shift Reaction on Cu–Au Bimetallic Surfaces

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