Exact quantum, quasiclassical, and semiclassical reaction probabilities for the collinear F+D2 → FD+D reaction

Abstract

Exact quantum, quasiclassical, and semiclassical reaction probabilities and rate constants for the collinear reaction F+D₂ → FD+D are presented. In all calculations, a high degree of population inversion is predicted with P^R₀₃ and P^R₀₄ being the dominant reaction probabilities. In analogy with the F+H₂ reaction (preceding paper), the exact quantum 0→3 and 0→4 probabilities show markedly different energy dependence with P^R₀₃ having a much smaller effective threshold energy (E_T=0.014 eV) than P^R₀₄ (0.055 eV). The corresponding quasiclassical forward probabilities P^R₀₃ and P^R₀₄ are in poor agreement with the exact quantum ones, while their quasiclassical reverse and semiclassical counterparts provide much better approximations to the exact results. Similar comparisons are also made in the analysis of the corresponding EQ, QCF, QCR, and USC rate constants. An information theoretic analysis of the EQ and QCF reaction probabilities indicates nonlinear surprisal behavior as well as a significant isotope dependence. Additional quantum results at higher energies are presented and discussed in terms of threshold behavior and resonances. Exact quantum reaction probabilities for the related F+HD → FH+D and F+DH → FD+H reactions are given and an attempt to explain the observed isotope effects is made.