A Time-Dependent Wave Packet Quantum Scattering Study of the Reaction HD+(v=0-3;jo=1) + He --> HeH+(HeD+) + D(H)

Abstract

Time-dependent wave packet quantum scattering (TWQS) calculations are presented for HD+(v=0; j0=l) + He collisions in the Center-of-mass collision energy (ET) range of 0.0-0.2 eV. The present TWQS approach accounts for Coriolis coupling and uses the ab initio potential energy surface of Palmieri et al. [Mol. Phys 98, 1839 (2000)]. For a fixed total angular momentum J, the energy dependence of reaction probabilities exhibits quantum resonance structure. The resonances are more pronounced for low J values and for the HeH+ + D channel than for the HeD+ + H channel and are particularly prominent near threshold. The quantum effects are no longer discernible in the integral cross sections, which compare closely to quasi-classical trajectory calculations conducted on the same potential energy surface. The integral cross sections also compare well to recent state-selected experimental values over the same reactant and translational energy range. Classical impulsive dynamics and steric arguments can account for the significant isotope effect in favor of the deuteron transfer channel observed for HD+(v<3) and low translational energies. At higher reactant energies, angular momentum constraints favor the proton-transfer channel, and isotopic differences in the integral cross sections are no longer significant. The integral cross sections as well as the J dependence of partial cross sections exhibit a significant alignment effect in favor of collisions with the HD+ rotational angular momentum vector perpendicular to the Jacobi R coordinate. This effect is most pronounced for the proton-transfer channel at low vibrational and translational energies.

Document Details

Document Type

Technical Report

Publication Date

Oct 30, 2007

Accession Number

ADA490908

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