An alternative mechanism for spin-forbidden photo-ionization of diatomic molecules and its rotation-electronic selection rules
Abstract
The spin-forbidden photo-ionization of diatomic molecules is proposed. Spin orbit interaction is invoked, resulting in the correction and mixing of the wave functions of different multiplicities. The rotation-electronic selection rules given by Dixit and McKoy (1986) for Hund's case a based on the conventional mechanism of electric dipole transition are rederived and expressed in a different format. This new format permits the generalization of the selection rules to other photoionization transitions caused by the magnetic dipole, the electric quadrupole, and the two- and three-photon operators. These selection rules, which are for transitions from one specific rotational level of a given Kronig reflection symmetry to another, will help understand rotational branching and the dynamics of interaction in the excited state. They will also help in the selective preparation of well-defined rovibronic states in resonant-enhanced multi-photon ionization processes.
- Publication:
-
Canadian Journal of Physics
- Pub Date:
- February 1990
- DOI:
- 10.1139/p90-025
- Bibcode:
- 1990CaJPh..68..177C
- Keywords:
-
- Diatomic Molecules;
- Forbidden Transitions;
- Photoionization;
- Rotational Spectra;
- Spin-Orbit Interactions;
- Angular Momentum;
- Electric Dipoles;
- Parity;
- Wave Functions;
- Atomic and Molecular Physics