A study of the performance of high-level correlated methods: The energy, dipole moment, and polarizability functions of CO

Many-body perturbation theory and coupled-cluster theory are used to determine the dipole moment, polarizabilities, and their derivatives with respect to internuclear separation for the CO molecule. There are sizable errors in the dipole moment and its derivative when evaluated in the MP4(SDTQ) appr

Atomic populations according to the Mulliken, electrostatic, natural population, and atomic polar tensor (APT) definitions were evaluated for first-and second-row compounds using different correlated ab initio techniques, DFT methods, and basis sets. All definitions except MuUiken exhibit modest bas

Many-body perturbation theory and coupled-cluster calculations for the energy and dipole moment of Hz0 are performed using different techniques to reduce the virtual space. The optimized virtual orbital space (OVOS) method is compared with frozen natural orbitals (FNO), defined from a relaxed densit

The potential energy curves, dipole, quadrupole and octopole moments and dipole polarisabilities have been calculated at CASSCF level using a [ 8s6p3d] basis for the ground X 2~ + state of CO + as a function of internuclear distance. In addition the potential energy curves, as well as the dipole, qu