Effect of reagent rotation on the reaction D+H2(ν=1)→DH+H

Classical trajectory c~cu~ations on fi + H&3 reactions have been carried out. At few collision ener$es the reaction cross section decreases for smnU j. reaching 3 minimum at j = 4, then increases as j increases. It isdso shown rbat rhe isotopic branching ratio is fairly sensitive xo reagent rotation

The moderately exotherrnic ion-molecule reaction O+ t Hz and its isotopic variants have been the subject of several dynamical studies in our group. In this work we report an extensive quasiclassical trajectory study on the dynamics of this system at different initial relative energies considering a

Simple "half-collision" classical trajectories on model potential surfaces show that the lack of leaving-atom isotope effects on initial rotational state distributions P(N) in reactions of the type M\*+H2 (HD) -+MH( v, N) +H (D) would result from decomposition of H-M-H( D) intermediates on anisotrop

The cone or acceptance for H+H= reactive collisions is shown Lo open up upon strelching of the H, bond. AL a given wtmslational energy, the sreric faclor is thus much larger for vibrzkonally cxcircd rcngems as demonswatcd by class&l IrajccLoq compulorions for H+ D?(U) and D+Hz(o). AI a given lolaI c