Chemically Accurate Simulation of a Prototypical Surface Reaction: H
            <sub>2</sub>
            Dissociation on Cu(111)

Dı́az, Cristina; Pijper, E.; Olsen, Roar A.; Busnengo, H. F.; Auerbach, Daniel J.; Kroes, Geert–Jan

doi:10.1126/science.1178722

Cited by 330 publications

(633 citation statements)

References 37 publications

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“…We study the (111) surface because an accurate 6D PES for this surface is already available in the literature. 35 Also in view of the rather similar experimental results obtained for the (100) and (110) surfaces, no major discrepancies would be expected between low-Miller-indices Cu surfaces. Keeping in mind that we perform our study for the (111) surface whereas the experiments we compare to were done for the (100) surface, we do not attempt a quantitative comparison with experiment.…”

Section: Introductionmentioning

confidence: 62%

“…In performing the DFT/GGA calculations, we have used the exchange-correlation functional PW91, 51 which yields a semi-quantitative description of the H 2 /Cu(111) system. 36 We also show results obtained with the specific reaction parameter (SRP) functional developed by Díaz et al, 35 which has been shown to give chemical accuracy for a significant number of H 2 /Cu(111) observables.…”

Section: Methodsmentioning

confidence: 78%

“…33), and H 2 /Cu(111). [34][35][36] In fact, for H 2 /Cu(111) it has been shown 35,36 that the choice of an appropriate functional in a high dimensional adiabatic calculation leads to a chemically accurate description of experiments on the dependence of reaction on incidence energy and initial rovibrational state, and of experiments on rotationally inelastic scattering. Nevertheless, the role of e-h pair excitations in the interaction of H 2 with copper surfaces has been studied not only indirectly through comparison between experiment and adiabatic theory, but also directly through non-adiabatic dynamics calculations.…”

Section: Introductionmentioning

confidence: 99%

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Vibrational deexcitation and rotational excitation of H2 and D2 scattered from Cu(111): Adiabatic versus non-adiabatic dynamics

Muzas

Juaristi

Alducin

et al. 2012

The Journal of Chemical Physics

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We have studied survival and rotational excitation probabilities of H 2 (v i = 1, J i = 1) and D 2 (v i = 1, J i = 2) upon scattering from Cu(111) using six-dimensional (6D) adiabatic (quantum and quasi-classical) and non-adiabatic (quasi-classical) dynamics. Non-adiabatic dynamics, based on a friction model, has been used to analyze the role of electron-hole pair excitations. Comparison between adiabatic and non-adiabatic calculations reveals a smaller influence of non-adiabatic effects on the energy dependence of the vibrational deexcitation mechanism than previously suggested by low-dimensional dynamics calculations. Specifically, we show that 6D adiabatic dynamics can account for the increase of vibrational deexcitation as a function of the incidence energy, as well as for the isotope effect observed experimentally in the energy dependence for H 2 (D 2 )/Cu(100). Furthermore, a detailed analysis, based on classical trajectories, reveals that in trajectories leading to vibrational deexcitation, the minimum classical turning point is close to the top site, reflecting the multidimensionally of this mechanism. On this site, the reaction path curvature favors vibrational inelastic scattering. Finally, we show that the probability for a molecule to get close to the top site is higher for H 2 than for D 2 , which explains the isotope effect found experimentally.

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Section: Introductionmentioning

confidence: 62%

Section: Methodsmentioning

confidence: 78%

Section: Introductionmentioning

confidence: 99%

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Vibrational deexcitation and rotational excitation of H2 and D2 scattered from Cu(111): Adiabatic versus non-adiabatic dynamics

Muzas

Juaristi

Alducin

et al. 2012

The Journal of Chemical Physics

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“…In contrast, the relevance of this dissipation channel in gas-surface interactions that involve energies up to a few eV is not so clear. It depends not only on the specific system, but also on the elementary process considered, as shown by different studies on scattering [5][6][7][8][9][10][11][12] and adsorption [6,[13][14][15][16][17][18][19][20][21][22][23][24][25][26] of atoms and molecules on surfaces. Low-energy e-h pair excitations have been detected as chemicurrents on Schottky diode devices during the chemisorption of atomic and molecular species on metals [13][14][15].…”

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confidence: 99%

Electronic Friction Dominates Hydrogen Hot-Atom Relaxation on Pd(100)

et al. 2014

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We study the dynamics of transient hot H atoms on Pd(100) that originated from dissociative adsorption of H 2 . The methodology developed here, denoted AIMDEF, consists of ab initio molecular dynamics simulations that include a friction force to account for the energy transfer to the electronic system. We find that the excitation of electron-hole pairs is the main channel for energy dissipation, which happens at a rate that is five times faster than energy transfer into Pd lattice motion. Our results show that electronic excitations may constitute the dominant dissipation channel in the relaxation of hot atoms on surfaces. DOI: 10.1103/PhysRevLett.112.103203 PACS numbers: 68.43.-h, 34.35.+a, 34.50.Bw, 82.20.Gk Electron-hole (e-h) pair excitations are an unquestioned efficient energy drain in the interaction of fast atoms with solids and surfaces [1][2][3][4]. In contrast, the relevance of this dissipation channel in gas-surface interactions that involve energies up to a few eV is not so clear. It depends not only on the specific system, but also on the elementary process considered, as shown by different studies on scattering [5][6][7][8][9][10][11][12] and adsorption [6,[13][14][15][16][17][18][19][20][21][22][23][24][25][26] of atoms and molecules on surfaces. Low-energy e-h pair excitations have been detected as chemicurrents on Schottky diode devices during the chemisorption of atomic and molecular species on metals [13][14][15]. The correlation found between chemicurrent intensities and adsorption energies is a strong indication that a large fraction of the energy dissipated in both the dissociative and nondissociative adsorption processes is used to excite e-h pairs. However, this strongly contrasts with examples showing that the dissociative adsorption is reasonably well described within the electronically adiabatic approach, which neglects the coupling between electronic excitations and the nuclear motion [6,[18][19][20]23,25], and that the effect of electronic energy dissipation seems negligible [21,24,26]. Therefore, a question that is raised here is at what stage of the dissociative adsorption process e-h pair excitations do become relevant.In a typical adsorption event, the incoming gas species gain additional kinetic energy when entering the attractive adsorption well. In the particular case of dissociative adsorption, this energy gain can lead to the formation of so-called "hot" atoms or fragments, with energies much larger than the corresponding thermal energies of the substrate atoms. The formed hot species will then propagate along the surface until they dissipate the excess kinetic energy and finally accommodate at a stable adsorption position. This stage of the dissociative adsorption process, where the relevance of e-h pair excitations has been traditionally neglected, is the focus of the present work.In this Letter we show that while e-h pair excitation may not be relevant on the molecule-bond-breaking time scale, it is an efficient dissipative channel in the subsequent relaxation of the...

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“…Six-dimensional quantum dynamics has already become a standard tool to study diatomic molecule/surface interactions at low incidence energy(<2 eV), from reactive scattering [20][21][22][23][24] to molecular diffraction [24][25][26]. However, its accuracy in reproducing experimental data, disregarding phonons * cristina.diaz@uam.es and electron-hole pair excitations effects, relies on the accuracy of the underlying potential energy surface (PES) on which the dynamics is carried out [23,27]. Thus the large progress made in the microscopic dynamics description of moleculesurface interaction processes has motivated, subsequently, the development of flexible and accurate methods to determine full-dimensional PESs.…”

Section: Introductionmentioning

confidence: 99%

H2/LiF(001) diffractive scattering under fast grazing incidence using a DFT-based potential energy surface

et al. 2017

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Grazing incidence fast molecule diffraction (GIFMD) has been recently used to study a number of surfaces, but this experimental effort has not been followed, to present, by a subsequent theoretical endeavor. Aiming at filling this gap, in this work, we have carried out GIFMD simulations for the benchmark system H 2 /LiF(001). To perform our study, we have built a six-dimensional potential energy surface (6D-PES) by applying a modified version of the corrugation reducing procedure (CRP) to a set of density functional theory (DFT) energies. Based on this CRP interpolated PES, we have conducted quantum dynamics calculations using both the multiconfiguration time-dependent Hartree and the time-dependent wave packet propagation methods. We have compared the results of our GIFMD simulations with available experimental spectra. From this comparison, we have uncovered a prominent role of the interaction between the quadrupole moment of H 2 and the electric field associated with LiF(001) for specific incidence crystallographic directions. We show that, on the one hand, the molecule's initial rotation strongly affects its diffractive scattering and, on the other hand, the scattering is predominantly rotationally elastic over a wide range of incidence conditions typical for GIFMD experiments.

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Chemically Accurate Simulation of a Prototypical Surface Reaction: H ₂ Dissociation on Cu(111)

Cited by 330 publications

References 37 publications

Vibrational deexcitation and rotational excitation of H2 and D2 scattered from Cu(111): Adiabatic versus non-adiabatic dynamics

Vibrational deexcitation and rotational excitation of H2 and D2 scattered from Cu(111): Adiabatic versus non-adiabatic dynamics

Electronic Friction Dominates Hydrogen Hot-Atom Relaxation on Pd(100)

H2/LiF(001) diffractive scattering under fast grazing incidence using a DFT-based potential energy surface

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Chemically Accurate Simulation of a Prototypical Surface Reaction: H 2 Dissociation on Cu(111)

Cited by 330 publications

References 37 publications

Vibrational deexcitation and rotational excitation of H2 and D2 scattered from Cu(111): Adiabatic versus non-adiabatic dynamics

Vibrational deexcitation and rotational excitation of H2 and D2 scattered from Cu(111): Adiabatic versus non-adiabatic dynamics

Electronic Friction Dominates Hydrogen Hot-Atom Relaxation on Pd(100)

H2/LiF(001) diffractive scattering under fast grazing incidence using a DFT-based potential energy surface

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Product

Resources

About

Chemically Accurate Simulation of a Prototypical Surface Reaction: H ₂ Dissociation on Cu(111)