Los puntos clave no están disponibles para este artículo en este momento.
By utilizing the knowledge that a Hamiltonian is a unique functional of its ground-state density, the following fundamental connections between densities and Hamiltonians are revealed: Given that _, _, , _ are ground-level densities for interacting or noninteracting Hamiltonians H₁, H₂, , H₌ (M arbitrarily large) with local potentials v₁, v₂, , v₌, but given that we do not know which belongs with which H, the correct mapping is possible and is obtained by minimizing r v₁ (r) _ (r) +v₂ (r) _ (r) +v₌ (r) _ (r) with respect to optimum permutations of the 's among the v's. A tight rigorous bound connects a density to its interacting ground-state energy via the one-body potential of the interacting system and the Kohn-Sham effective one-body potential of the auxiliary noninteracting system. A modified Kohn-Sham effective potential is defined such that its sum of lowest orbital energies equals the true interacting ground-state energy. Moreover, of all those effective potentials which differ by additive constants and which yield the true interacting ground-state density, this modified effective potential is the most invariant with respect to changes in the one-body potential of the true Hamiltonian. With the exception of the occurrence of certain linear dependencies, a density will not generally be associated with any ground-state wave function (is not wave function v representable) if that density can be generated by a special linear combination of three or more densities that arise from a common set of degenerate ground-state wave functions. Applicability of the "constrained search" approach to density-functional theory is emphasized for non-v-representable as well as for v-representable densities. In fact, a particular constrained ensemble search is revealed which provides a general sufficient condition for non-v representability by a wave function. The possible appearance of noninteger occupation numbers is discussed in connection with the existence of non-v representability for some Kohn-Sham noninteracting systems.
Mel Levy (Wed,) studied this question.
Synapse has enriched 5 closely related papers on similar clinical questions. Consider them for comparative context: