Electron transmission spectroscopy: Resonances in triatomic molecules and hydrocarbons

Abstract

Compound states of triatomic molecules and simple hydrocarbons are studied using electron transmission spectroscopy. Structures in the derivative of the current transmitted through a gas‐filled collision chamber are interpreted as resonances in the electron‐molecule cross sections. At low electron energies (0–6 eV) we observe, in N₂O, H₂S, and C₂H₄, broad and featureless structures which we identify as shape resonances. In the same energy range, the molecules CO₂, NO₂, C₆H₆, and SO₂ exhibit narrow structures which form vibrational progressions. In CO₂, NO₂, and C₆H₆, these vibrational progressions are identified as shape resonances; in SO₂, the interpretation is not clear cut. No low‐energy resonances are observed in H₂O and in CH₄. At higher energies (9–17 eV) we observe sharp structures for H₂O, H₂S, N₂O, CO₂, and C₂H₄ (but not for C₆H₆ and CH₄). These structures form bands, each band consisting of a vibrational progression. The states which are responsible for the bands consist of two Rydberg electrons moving in the field of a particular positive‐ion core. These bands are similar to those found previously in diatomic molecules.