Diffractive and reactive scattering of (v=0, j=0) HD from Pt(111): Six-dimensional quantum dynamics compared with experiment

Abstract: We present results of (vϭ0, jϭ0) HD reacting on and scattering from Pt͑111͒ at off-normal angles of incidence, treating all six molecular degrees of freedom quantum mechanically. The six-dimensional potential energy surface ͑PES͒ used was obtained from density functional theory, using the generalized gradient approximation and a slab representation of the metal surface. Diffraction and rotational excitation probabilities are compared with experiment for two incidence directions, at normal incidence energies be… Show more

“…These factors decrease when E i increases simply because of the decrease of N ref ðJ f ¼ 0Þ for both molecules. A larger fraction of rotationally excited HD molecules compared to the case of H 2 has been also observed in Q results for H 2 and HD interacting with Pt(1 1 1) [2]. However, in the latter case, the difference between both molecules is larger than in the present case.…”

“…In the latter case, this difference was attributed to a competition between the adsorption and rotational excitation channels for HD stronger than for H 2 , because above the dissociation threshold (i.e. $50 meV) the rotational excitation probability, P rotexc , of HD molecules is much larger than for H 2 [2]. In contrast, for Cu(1 1 0), above the dissociation threshold ($400 meV) the rotational excitation probabilities of H 2 [28] and HD molecules are both large (see the inset of Fig.…”

“…The lower dissociative adsorption probability for HD was attributed to a stronger competition with rotational excitation channels whereas the higher rotational excitation probabilities were attributed to the following factors [2]: (i) for a given initial impact energy, there exist more open rotational excitation channels for HD than for H 2 because rotational transitions with both even and odd values of DJ ¼ J f À J i (the change of the rotational quantum number, J) are allowed for HD and a larger moment of inertia decreases the energy gaps between rotational states; (ii) for HD the molecular center of mass is displaced with respect to the molecular center of charge which increases the effective angular corrugation of the PES (for a fixed position of the molecular center of mass) which favors rotational excitation.…”

“…Most of them have considered the homonuclear isotopomer H 2 (and in less extent also D 2 ). In one of the very few theoretical investigations for the heteronuclear isotopomer HD, Kingma et al [2] presented a comparison of dissociative adsorption and rotational excitation probabilities of HD and H 2 molecules interacting with Pt(1 1 1) obtained in quantum dynamical calculations. For HD molecules, they reported slightly smaller dissociative adsorption probabilities and much larger total rotational excitation probabilities than for H 2 .…”

Comparative dynamical study of the HD and isotopomers interacting with Pd(111) and Cu(110) surfaces

“…These factors decrease when E i increases simply because of the decrease of N ref ðJ f ¼ 0Þ for both molecules. A larger fraction of rotationally excited HD molecules compared to the case of H 2 has been also observed in Q results for H 2 and HD interacting with Pt(1 1 1) [2]. However, in the latter case, the difference between both molecules is larger than in the present case.…”

“…In the latter case, this difference was attributed to a competition between the adsorption and rotational excitation channels for HD stronger than for H 2 , because above the dissociation threshold (i.e. $50 meV) the rotational excitation probability, P rotexc , of HD molecules is much larger than for H 2 [2]. In contrast, for Cu(1 1 0), above the dissociation threshold ($400 meV) the rotational excitation probabilities of H 2 [28] and HD molecules are both large (see the inset of Fig.…”

“…The lower dissociative adsorption probability for HD was attributed to a stronger competition with rotational excitation channels whereas the higher rotational excitation probabilities were attributed to the following factors [2]: (i) for a given initial impact energy, there exist more open rotational excitation channels for HD than for H 2 because rotational transitions with both even and odd values of DJ ¼ J f À J i (the change of the rotational quantum number, J) are allowed for HD and a larger moment of inertia decreases the energy gaps between rotational states; (ii) for HD the molecular center of mass is displaced with respect to the molecular center of charge which increases the effective angular corrugation of the PES (for a fixed position of the molecular center of mass) which favors rotational excitation.…”

“…Most of them have considered the homonuclear isotopomer H 2 (and in less extent also D 2 ). In one of the very few theoretical investigations for the heteronuclear isotopomer HD, Kingma et al [2] presented a comparison of dissociative adsorption and rotational excitation probabilities of HD and H 2 molecules interacting with Pt(1 1 1) obtained in quantum dynamical calculations. For HD molecules, they reported slightly smaller dissociative adsorption probabilities and much larger total rotational excitation probabilities than for H 2 .…”

Comparative dynamical study of the HD and isotopomers interacting with Pd(111) and Cu(110) surfaces

“…Nevertheless, it is worth bearing in mind that the PWP approach can be used with time-independent methods, if only to clarify that the PWP approach is a method of interpretation, rather than a numerical method of solving the Schro¨dinger equation. Regarding the latter, there are a variety of excellent methods in the literature [22][23][24][25][26][27][28][29], which could be adapted to implement efficiently the PWP approach.…”

The plane wave packet approach to quantum scattering theory

Theoretische Chemie 2003