Non-orthogonal atomic orbitals: Kinetic energy

The construction of non-orthogonal localized molecular orbitals (Wannier functions of extended systems) with maximal degree of localization according to the Magnasco-Perico localization criterion derived from Mulliken's population analysis is discussed and several forms of the equations giving these

A theorem is proven showing that one can always find a special non-orthogonal set of localized orbitals each of which contains only one of a starting set of approximate occupied orbitals (e.g. bonding orbitals of some subunits). A method of a posteriori determination and a specific perturbation theo

## X general version of the multi-configuration Hartree--Fock method is elaborated. An N-electron wavefunction is approximated as a linear combination of configurations which are constructed from space orbit& which are divided into disjoint subsets, with elements of the same subset being kept orth

Atomic orbital energy matching is a valid criterion of bond strength only for haifdilkd molec&xr orbitals. Doubly occupied molecular orbitals built from atomic orbital9 differing in energies may be strongly bonding due to high ionic bond-orders.

A kinetic energy analysis of total energy differences in 115 atomic multiplet states is presented. We show by numerical restricted Hartree-Fock calculations that there is a reasonably accurate linear relationship between the kinetic energy of the electrons in open subshells and the total energy with