Distorted-wave calculations for the three dimensional chemical reaction H + H2(v ⩽ 2, j = 0) → H2(v′ ⩽ 2, j′, mj) + H

A close-coupling calculation of integral cross sections for the reaction F + Hz (u= 0, j= 0) +FH ( v'f ) + H has been performed in the threshold energy range using hyperspherical coordinates, The convergence of partial reaction probabilities with respect to a,, the maximum magnitude of the total ang

## Anestimateoftherateconstant forthevibration-to-vibrationenergy transferprocess2Hz(v = I)-H2(~ = O)+ Hz& = 2) is made by analyzing the dependence of the effective rate of relaxation on the degee of laser excitation. At 82 K it is (6.3 f 2.1) X 1O-'6 cm3 molecule-t s-~.

The reaction D + H2 + HD + H has been investigated in two molecular beam scattering experiments. Angular and time-of-flight distributions have been measured for the initial vibrational ground state ( u = 0) at a most probable collision energy of E,, = 1.5 eV and for the first vibrational excited sta

Integral and differential state-resolved cross sections have been calculated by the method of quasiclassical trajectories for the H t D,+HD+D reaction in the range of initial conditions of interest to recent experiments. When possible, the results are compared to exact quantum-mechanical calculation

## Static-static distorted wave and vibrationally adiabatic distorted wave calculations have been performed for the product rotational distributions of the H.+ Dz + HD + D reaction using an accurate ab initio potential energy surface. Comparison is made with coupled states and quasiclassical traje