Low-energy behavior of exothermic dissociative electron attachment
Abstract
We discuss two models for electron attachment to molecules: the Vogt-Wannier model for capture into a polarization well and the resonance model for dissociative attachment. The Vogt-Wannier model is generalized for the case of a target with a permanent dipole moment, and results are presented for dissociative attachment to CH3I. It is shown that the resonance theory should incorporate in this case a weakly bound dipole-supported state of CH3I-, whereas the generalized Vogt-Wannier theory gives a reasonable estimate for the cross section in the meV and sub-meV region. The Vogt-Wannier model is also applied to the process of attachment to SF6, CCl4, and C60. In the first case the s-wave capture model provides a satisfactory description of the experimental data for energies below the first vibrational excitation threshold, whereas for CCl4 it underestimates the attachment cross section by a factor of 2 in the sub-meV region. For C60 we suggest that electron attachment is dominated by s-wave capture in the region below 2 meV and by p-wave capture in the energy range above 4 meV. Our model reproduces data for Rydberg electron and free-electron attachment observed in beam experiments. It is, however, at variance with the strong rise of the attachment rate coefficients with electron temperature observed in flowing afterglow-Langmuir probe measurements.
- Publication:
-
Physical Review A
- Pub Date:
- February 2001
- DOI:
- 10.1103/PhysRevA.63.022706
- Bibcode:
- 2001PhRvA..63b2706F
- Keywords:
-
- 34.80.Ht;
- Dissociation and dissociative attachment by electron impact