Diatomics-in-molecules model for penning ionization in the He(2 1S)-H2 system

## Potcntulenergysurfxesnnd thcnutororuzattonwrdthforthcPenrung1oluzationtr~rllonHe(Z~S)+H~~He+H2+ +ehave been cakulalcd usmg the DIM method. The surfxcs cornpam fwounbly wtb the eustmg ab UUIIO cakul~lrons, and the approuuncltton to the nutolonlzation wdth appcx to be rcclsonlblc.

Thhe first measurement of a doubly ddferenhal cross scctmn for Penmng loruzatlon 1s reported\_ At an energy of 0.33 eV, the protons are scattered sharply forward, and an adchtlonal 0.26 eV IS released as translational energy. A completely ab uutlo prcchctlon compares favorably ~11th these results.

The method of diatomics-in-molecules (DIM) which constructs the hamiltonian matrix semi-empirically from known atomic and diatomic fragment energy data, is used to generate approximate 3D potential energy hypersurfaces and nonadiabatic coupling coefficients for the system (HeHH) +. To reduce the siz

Penning ionization of He(2%) +HrO and DzO has been studied by observing the A\*A,-a \*B, emission system of HrO+ and DzO+ in a low-pressure flowing afterglow. The vibrational distributions of HrO+ (A) and DrO+(& were consistent with those predicted from Franck-Condon-type vertical excitation. A stro

A theoretical picture of the dynamics of the autoionization event He(23S)-D2(v " = 0) ~ [He...D~-(v')] + e-is obtained for a collision energy ranging from 10 to 150 meV (average --51 meV). The treatment of the dynamics consists of 2D classical trajectory calculations based on static characteristics