Trajectory calculations for the reaction H2+ + He → H + HeH+

An ink& equation ieection path techtique hzs been used to calculate, within. the collkc~ app;oximaSon, rcnc:Ion piOb2bilitieSfOi the reStion He + Hz\* HC& r H over the ener\_g rans 0.95 G E Q 1.19 eV. Tkis rextion diffsis from those that have been studied previously v~ithin the coPib.ezr zpprotiiati

A vibrationally selected beam of Hf2 was used to investigate experimentally the reaction dynamics of the lowest two (cndoergic) channels of the process Hs(u = 0.1) + He = HeH++ H at the relative co!lision energy 3.58 eV, and to provide data for comparison with quasi-classical trajector# calculations

## Clxsical trajectory cahdations zwe presented for the reaction N\*+ II2 -MI++ II using a single potenthI surface. At Iow initkd rchtive encr+s q mmctric product distributions arc obtained and complex trajcctorres predommnte\_ At hi.gher cnergics direct reaction gives forward peaking\_

An improved version of the S-matrix Kohn variational method has been applied to calculating 3D quantum reaction probabilities of the ion-molecular reaction He+ HT (u) AHeH+ + H. The calculation is carried out for total angular momentum J= 0 and employs the DIM potential surface of Kuntz. Our results

State-selected reaction probabilities for the collinear reaction He+H~-(v)~HeH++H have been computed for v = 0-4 over a wide range of energies (to the dissociation limit), using the time-dependent wavepacket approach via time-energy mapping of the reactive flux. The results reproduce quantitatively