A CASSCF-MRCI study of the ground and lower excited states of the CCCN radical

To compute the dissociation energy of MgO, the relationship amoog the size of the active space in CASSCF wavefunctions, the computed De and the continuity of aE/ar is studied. Basis set influence is also considered Finally, it is concluded that the dissociation energy of MgO referred to ground state

Complete-active-space SCF and multi-reference configuration interaction calculations employing large Gaussian basis sets of the general contraction type have been carried out to determine the equilibrium structures and relative stabilities of the ground electronic state R 'I& of the acetylene cation

## Lehn-tuhl ftir lleoreridle Chemie der Oiliversitiit Sorm.

## Abstract Using the complete active space self‐consistent field method with a large atomic natural orbital basis set, 10, 13, and 9 electronic states of the OClO radical, OClO^+^ cation, and OClO^−^ anion were calculated, respectively. Taking the further correlation effects into account, the seco

Ab initio SCF c&zulations using the generalized coupling operator method have been p&formed OR the ground and two excited states of methyl radical. Geometries of the ground and one excited state have been optimized. Vertical transition energies have also been calculated.