Crystal dichroism and the orientation of molecular transition dipole moments

Within the Born-Oppenhcrmer approximation homopolar isotopically unsymmetric diatomic ions (ND', 14N1'N+, 35C137C1+, etc.) have D \_h symmetry and a non-vanishing dipole moment. This apparent paradox is reconciled here by treating carefully the transformation properties of the dipole moment operator

Potential energies for the ground state and several excited states of the CdHg system have been calculated using the MRCI(SD) procedure for the valence electrons, while all the core electrons are represented by semi-empirical I-dependent pseudopotentials. The effect of spin-orbit coupling has not be

Potential energies for the ground state and several excited states ofthe RHg system have heen calculated basedon the MRCI( SD) procedure for the valence electrons, while the core electronsare represented by semi-empirical I-dependent pseudopotentials. The spin-orbit coupling has not been considered.

The present work reports an ab initio MRD-CI calculation of the dipole moment surfaces for the electronic ground state of the H 2 Te molecule. Using the ab initio results, we calculate the vibrational transition moments, and we simulate the far-infrared spectrum of H 2 Te by means of the MORBID prog