Signatures of site-specific reaction of H2 on Cu(100)

Somers, Mark F.; McCormack, Drew A.; Kroes, Geert–Jan; Olsen, Roar A.; Baerends, Evert Jan; Mowrey, R. C.

doi:10.1063/1.1506141

Cited by 37 publications

(49 citation statements)

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“…Impact on the top site has been found to be relevant for vibrationally inelastic scattering and for dissociation of vibrationally excited and highly rotationally excited H 2 on Cu(100). 40,46,57 The 2D elbow for this dissociation route shows a large curvature of the reaction path and an especially late barrier (occurring at a large H-H distance r, see Fig. 3 and Table I).…”

Section: B Computational Methodsmentioning

confidence: 99%

“…45 The system was also used to uncover experimental signatures of site reactivity in work bearing a close relationship to the present work, as the suggested experimental signature involves the relationship between measured rotational quadrupole alignment parameters of H 2 (v = 0, j) and (v = 1, j) just above the reaction threshold. 46, 47 H 2 + Cu(100) was also used as a benchmark to demonstrate a new, symmetry adapted pseudospectral method. 48 Finally, more recently the system has been used to explore the applicability of a mean field quantum dynamics method to investigate the effect of phonons on reactive and non-reactive scattering of H 2 from copper surfaces.…”

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confidence: 99%

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Reactive scattering of H2 from Cu(100): Comparison of dynamics calculations based on the specific reaction parameter approach to density functional theory with experiment

Sementa

Wijzenbroek²,

Kolck³

et al. 2013

The Journal of Chemical Physics

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201

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We present new experimental and theoretical results for reactive scattering of dihydrogen from Cu(100). In the new experiments, the associative desorption of H 2 is studied in a velocity resolved and final rovibrational state selected manner, using time-of-flight techniques in combination with resonance-enhanced multi-photon ionization laser detection. Average desorption energies and rotational quadrupole alignment parameters were obtained in this way for a number of (v = 0, 1) rotational states, v being the vibrational quantum number. Results of quantum dynamics calculations based on a potential energy surface computed with a specific reaction parameter (SRP) density functional, which was derived earlier for dihydrogen interacting with Cu (111), are compared with the results of the new experiments and with the results of previous molecular beam experiments on sticking of H 2 and on rovibrationally elastic and inelastic scattering of H 2 and D 2 from Cu(100). The calculations use the Born-Oppenheimer and static surface approximations. With the functional derived semi-empirically for dihydrogen + Cu(111), a chemically accurate description is obtained of the molecular beam experiments on sticking of H 2 on Cu(100), and a highly accurate description is obtained of rovibrationally elastic and inelastic scattering of D 2 from Cu(100) and of the orientational dependence of the reaction of (v = 1, j = 2 − 4) H 2 on Cu(100). This suggests that a SRP density functional derived for H 2 interacting with a specific low index face of a metal will yield accurate results for H 2 reactively scattering from another low index face of the same metal, and that it may also yield accurate results for H 2 interacting with a defected (e.g., stepped) surface of that same metal, in a system of catalytic interest. However, the description that was obtained of the average desorption energies, of rovibrationally elastic and inelastic scattering of H 2 from Cu(100), and of the orientational dependence of reaction of (v = 0, j = 3 − 5, 8) H 2 on Cu(100) compares less well with the available experiments. More research is needed to establish whether more accurate SRP-density functional theory dynamics results can be obtained for these observables if surface atom motion is added to the dynamical model. The experimentally and theoretically found dependence of the rotational quadrupole alignment parameter on the rotational quantum number provides evidence for rotational enhancement of reaction at low translational energies.

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Section: B Computational Methodsmentioning

confidence: 99%

mentioning

confidence: 99%

Reactive scattering of H2 from Cu(100): Comparison of dynamics calculations based on the specific reaction parameter approach to density functional theory with experiment

Sementa

Wijzenbroek²,

Kolck³

et al. 2013

The Journal of Chemical Physics

Self Cite

201

View full text Add to dashboard Cite

show abstract

“…Many previous researches showed that the catalytic properties of clusters are structure dependent, leading to different adsorption energies and sites for different structures of clusters [1][2][3][4][5][6]. Hydrogen is employed in many modern technologies [7][8][9][10][11][12][13][14][15][16][17][18][19][20][21], so surface reactions of hydrogen molecules in transition metals have been carried out over the adsorption and desorption of hydrogen and deuterium molecules on well-defined single crystal metals. Axel Pramann et al [22] studied hydrogen chemisorption rates and electronic structures of small Nb n Al -clusters by photoelectron spectroscopic method.…”

Section: Introductionmentioning

confidence: 99%

Theoretical Study of Hydrogen Adsorption on Ruthenium Clusters

Yan

Jing

et al. 2011

J Clust Sci

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The geometries, stabilities, electronic, and magnetic properties of hydrogen adsorption on Ru n clusters have been systematically investigated by using density functional theory with generalized gradient approximation. The result indicates the absorbed species does not lead to a rearrangement of the basic cluster. For n [ 2, three different adsorption patterns are found for the Ru n H 2 complexes: One H atom binds to the Ru top site, and another H binds to the bridge site for n = 3, 5, 6, 8; bridge site adsorption for n = 4; hollow site and top site adsorption for n = 7. The adsorption energies display oscillation and reach the peak at n = 2, 4, 7, implying their high chemical reactivity. The small electron transferred number between H atoms and Ru n clusters indicates that the interaction between H atoms and Ru n clusters is small. When H 2 is absorbed on the Ru n clusters, the chemical activity of corresponding clusters is dramatically increased. The absorbed H 2 can lead to an oscillatory behavior of the magnetic moments, and this behavior is rooted in the electronic structure of the preceding cluster and the changes in the magnetic moment are indicative of the relative ordering of the majority and minority LUMO's. The second order difference indicates 5 is magic number in Ru n H 2 and Ru n clusters.

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“…Such a preference is often seen in activated reactions at low collision energies and arises because the anisotropy of the PES is generally large in the polar angle, leading to enhanced reaction due to rotational deexcitation of rotational states with low ͉m J ͉. 39,52 This is also the likely cause in this case: the ͑J =2, m J =0͒ state can deexcite, freeing some energy to overcome any low barriers encountered. In addition, the ͑J =2, m J =2͒ state is more tilted with respect to the surface plane than helicopter states for higher J. Helicoptering molecules for J = 2 are thus less favorably aligned to react than they are for higher initial rotational states.…”

Section: Alignmentmentioning

confidence: 99%

“…5͑a͔͒. 16,32,[37][38][39] In the HE range, the dissociation is predominantly direct in nature, while in the LE range the direct and indirect components both contribute ͓Fig. 5͑b͔͒.…”

Section: -7mentioning

confidence: 99%

Away from generalized gradient approximation: Orbital-dependent exchange-correlation functionals

Baerends¹,

Gritsenko

2005

The Journal of Chemical Physics

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Rotational effects in the dissociative adsorption of H 2 on the Pt͑211͒ stepped surface have been studied using classical trajectory calculations on a six-dimensional, density-functional theory potential-energy surface. Reaction of rotating molecules via an indirect trapping mechanism exhibits an unexpected nonmonotonic dependence on the initial rotational quantum number J. Indirect reaction is first quenched with increasing J but is enhanced again for high J initial states. The quenching is attributed to rotational-to-translational energy transfer, which facilitates escape from the chemisorption wells responsible for molecular trapping. For high J, rotational and translational motions decouple, and the energy transfer is no longer possible, which leads again to trapping. Degeneracy-resolved calculations show that for high initial J, molecules rotating in a "cartwheel" fashion ͑m J =0͒ are more likely to become trapped and react indirectly than "helicoptering" molecules ͑m J = J͒. Experimental confirmation of this finding would lend strong support to the existence of the chemisorption wells that trap molecules prior to reaction.

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Signatures of site-specific reaction of H2 on Cu(100)

Cited by 37 publications

References 100 publications

Reactive scattering of H2 from Cu(100): Comparison of dynamics calculations based on the specific reaction parameter approach to density functional theory with experiment

Reactive scattering of H2 from Cu(100): Comparison of dynamics calculations based on the specific reaction parameter approach to density functional theory with experiment

Theoretical Study of Hydrogen Adsorption on Ruthenium Clusters

Away from generalized gradient approximation: Orbital-dependent exchange-correlation functionals

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