The optimization of molecular orbitals for coupled cluster wavefunctions

Calculations were performed on the BC molecule using a method which combines the numerical MCSCF technique and the coupled cluster method involving single, double and triple excitations (CCSD+T(CCSD) level) in an attempt to determine, very accurately, r, in the ground electronic state. The result of

A new measure of orbital localiwbility is proposed. The actual improvement in classical electrostatic interpretations of elcctronie energy contributions on localization of CHg, NH3, H20, NF and NC LCAO wavefunctions is computed to be small. Substantial vttlence LMO spztiat overlappiq remains. A Borg

The Brueckner condition is analyzed as an approximation to the condition of stability of the total energy with respect lo variations in the orbitals. The recently introduced method of selfconsistent electron pairs is used to find Brueckner orbitals and it is shown that the Brueckner condttion can gi

The iterative coupling technique is described and applied to the partitioned self-consistent-field Xa scattered-\vave method. This technique allows the electronic coupling of a central cluster of atoms to its environment to be calculated iteriteratively. permitting scattered-wave molecular-orbital

We have discussed the utility of the cluster expansion of the wavefunction and proposed a pseudo+rbital theory which constitutes a generalization of the orbital-theoretic idea It has been applied to the calculation of spin densities of the fustrow atoms. The results are encouraging in comparison wit