A theoretical investigation of the electronic structure and excited states of copper porphin

We present a description of the valence electronic structure of the metal-free porphine macrocycle. The valence effective Hamiltonian (VEH) theoretical results are used to interpret in detail the gas-phase and solid-state UPS spectra of porphine. The overall agreement between theory and experiment i

Ab initio calculations for a series of excited states of the HZ02 molecule have been performed in order to discuss some recent photofragmentation experiments with laser light. For understanding these experiments the direction of the transition moments is of great interest, as well as the possibility

Complete active space MC SCF (CAS SCF) followed by second-order CI calculations are carried out on low-lying states of SeH. Spin-orbit interaction is introduced through a relativistic CI method for the 2113,2, zlI ,,z, zZ &, 3/2 (II) and 5/2 states. Spectroscopic properties of the bound states (R,,

Near-equilibrium four-dimensional potential energy surfaces (stretching coordinates only) have been calculated for the two lowest electronic states of HC,NC+ (B'II and A 'X). With a large dipole moment of A= -4.33 D and a B0 value of 4949( 10) MHz, the 3 \*l-l state appears to be a suitable candidat