e+−H2 elastic scattering in the random phase approximation

This paper presents accurate computation of the differential cross sections for the elastic and vibrational excitation of ground state Hz by fast electrons. The electronic matrix elements are evaluated at 20 internuclear separations and proper averaging over vibrational wavefunctions is carried out.

The cIastic and inelastic intensities for the scattering of eIectrons from H':(lso ) are ~om~uted~in the Eirst Born approximation by using both the exact Born-Oppenheimer wavefunction and an LCAO ii0 function of&ptimizcd minim2 basis $ quality. Evaluation of the coherent X-rr?y scattering factor by

Total photoionization, cross sections for H2 are ulculared in the random phase approximation (RPA) through a nur;lerical analytic coniinuation procedure applied to the polarrability for complex val&s of the frequency. The reprcsentition of the polarizability that is required is obtained from 3 discr

Cubic response functions in the random phase approximation have been derived and their use for computations of static and dynamic second hyperpolarizabilities is demonstrated. The performance of implemented computer strategies in terms of direct one-index transformations and of direct atomic orbital