6533b82dfe1ef96bd1291302
RESEARCH PRODUCT
Natural occupation numbers: When do they vanish?
R. Van LeeuwenKlaas J. H. Giesbertzsubject
PhysicsDensity matrixCusp (singularity)Quantum Physics010304 chemical physicsSeries (mathematics)Basis (linear algebra)Strongly Correlated Electrons (cond-mat.str-el)ta114Atomic Physics (physics.atom-ph)General Physics and AstronomyFOS: Physical sciences01 natural sciencesPhysics - Atomic PhysicsCondensed Matter - Strongly Correlated Electrons0103 physical sciencesCoulombDensity functional theoryDifferentiable functionPhysical and Theoretical Chemistry010306 general physicsWave functionQuantum Physics (quant-ph)Mathematical physicsdescription
The non-vanishing of the natural orbital occupation numbers of the one-particle density matrix of many-body systems has important consequences for the existence of a density matrix-potential mapping for nonlocal potentials in reduced density matrix functional theory and for the validity of the extended Koopmans' Theorem. On the basis of Weyl's theorem we give a connection between the differentiability properties of the ground state wave function and the rate at which the natural occupations approach zero when ordered as a descending series. We show, in particular, that the presence of a Coulomb cusp in the wave function leads, in general, to a power law decay of the natural occupations, whereas infinitely differentiable wave-functions typically have natural occupations that decay exponentially. We analyze for a number of explicit examples of two-particle systems that in case the wave function is non-analytic at its spatial diagonal (for instance, due to the presence of a Coulomb cusp) the natural orbital occupations are non-vanishing. We further derive a more general criterium for the non-vanishing of NO occupations for two-particle wave functions with a certain separability structure. On the basis of this criterium we show that for a two-particle system of harmonically confined electrons with a Coulombic interaction (the so-called Hookium) the natural orbital occupations never vanish.
| year | journal | country | edition | language |
|---|---|---|---|---|
| 2013-09-01 | Journal of Chemical Physics |