The Application of Density Functional, Local Orbitals, and Scattering Theory to Quantum Transport

The aim of this article is to present in a way accessible to most quantum chemists a general mathematical method which consists in deforming wave functions Ž . and density functions in the spirit of the local scaling transformation . This deformation method allows us to obtain several new results, i

Applications of the local-scaling transformation version of density functional theory, LS-DFT, to atoms and diatomic molecules are presented. In the case of atoms, explicit kinetic-and exchange-energy functionals for first-and second-row atoms at the Hartree᎐Fock level are constructed. The emphasis

It is shown that the claims that density functional theory DFT can handle orbitally degenerate states are ungrounded. The constraint search formulation of DFT allows one to determine a set of densities and eigenvalues for the degenerate term that, however, are neither observables, nor can they be us

Using the optimized effective potential method in conjunction with the semianalytical approximation due to Krieger, Li, and Iafrate, we performed fully selfconsistent exact exchange-only density functional calculations for diatomic molecules with a fully numerical basis-set-free molecular code. The

We advance a reformulation of the Hartree᎐Fock problem in the context of the local-scaling transformation version of density functional theory. Explicit functionals of the energy are obtained. These functionals are expressed in terms of both the one-particle density and the local-scaling transformat