A classical analysis of quantum resonances in isotopic collinear H + H2 reactions

Results from a time-dependent quantum-mechanical study of the collinear reaction He+H: +HeH+ +H are reported in the form of reaction probability values as a function of the total energy of the system for different vibrational states of Hz. The resonances are related to flux patterns similar to that

The classical (CSC), prirnitive (PSC), md uniform (USC) semi-Jassical expressions for reactive transition probabilities of Miller and co-workers have been used to obtain reaction probabilities for the collinear H + Hz exchange reaction. Comparisons with exact quantum results for the 0 4 0 transition

A new potential surface for the collinear F+Hz reaction, generated using a combination of rotated Morse curves and an MRD-CI electronic structure calculation, gave a barrier height of 3.99 kcaI/mol. Quasiclassical (forward) trajectory calculations show product vibrational distributions with the same

## Reduced dimensionality quantum reaction probabilities are reported for the H + H, reaction using the ab initio potenttal surface of Liu, Siegbahn, Truhlar and Horowitz. Resonances are found for the ground and first two excited adiabatic bending states of H,. Comparison of the resonance energies

Ck~sical trajectory cakuk~tions for the collinea\_r H+H2 exchange reaction weie performed QSiIIg the same poten-. ## I&J merg surface pretiou+ly adopted for exact quantum mechanical calculationr Reactions of bath sound state amjv-ibrationdy excited aate reagent were wwidered, over a relative kine