Vibrational and rotational excitation of molecular ions by slow electrons

Calculations are reported on the rotational transitions J--r J' = J. J\* 2, J = 0, \_ \_ . , 3 of H2, with the simultaneous excitation of a vibrational quantum, in the scattering of a SLOW electron. The method is based on the quantum mechanical impulse approximation, which neglects the kinetic ener

A theory of dissociative recombination has been developed which makes possible an investigation of this process in connection with the problem of scattering of slow electrons by molecular ions. The simultaneous influence of direct (non-reson~ce) interaction and ~homogeReit~ of the efectron continuum

Evidence is presented from a linewidth study of electron cyclotron resonance (ECR) absorption for efficient T+ V energy transfer between low-energy electrons (<O-S eV) and the fluorocarbons CF, and &Fe. It is suggested that this escitation proceeds by means of a direcr inechanism.

Analytical possibilities of the continued fraction method are demonstrated by solving two problems connected with a description of slow electron resonance scattering by positive molecular ions. Using the rotation adiabatic approximation, exact solutions of the multiquantum vibrational transition pro