Density functionals for the strong-interaction limit

Seidl, Michael and Perdew, John P. and Kurth, Stefan (2000) Density functionals for the strong-interaction limit. PHYSICAL REVIEW A, 62 (1). art. no.-012502. ISSN 1050-2947

Full text not available from this repository.

Abstract

The strong-interaction limit of density-functional (DF) theory is simple and provides information required for an accurate resummation of DF perturbation theory. Here we derive the point-charge-plus-continuum (PC) model for that limit, and its gradient expansion. The exchange-correlation (xc) energy E-xc[rho] equivalent to integral(0)(1)d alpha W-alpha[rho] follows from the re potential energies W-alpha at different interaction strengths alpha greater than or equal to 0 [but at fixed density rho(r)]. For small alpha approximate to 0, the integrand W-alpha is obtained accurately from perturbation theory, but the perturbation expansion requires resummation for moderate and large alpha. For that purpose, we present density functionals for the coefficients in the asymptotic expansion W-alpha-->W-infinity+W'(infinity)alpha(-1/2) for alpha-->infinity in the PC model. W-infinity(PC) arises from strict correlation, and W'(PC)(infinity) from zero-point vibration of the electrons around their strictly correlated distributions. The PC values for W-infinity and W'(infinity) agree with those from a self-correlation-free meta-generalized gradient approximation, both for atoms and for atomization energies of molecules. We also (i) explain the difference between the PC cell and the exchange-correlation hole, (ii) present a density-functional measure of correlation strength, (iii) describe the electron localization and spin polarization energy in a highly stretched H-2 molecule, and (iv) discuss the soft-plasmon instability of the low-density uniform electron gas.

Item Type: Article
Uncontrolled Keywords: GENERALIZED GRADIENT APPROXIMATION; COUPLING-CONSTANT DEPENDENCE; EXCHANGE-CORRELATION-ENERGY; ADIABATIC CONNECTION; ELECTRON-GAS; METALLIC DENSITIES; FORMALISM; ACCURATE; CONSTRUCTION; MOLECULES;
Subjects: 500 Science > 530 Physics
Divisions: Physics > Institute of Theroretical Physics
Depositing User: Dr. Gernot Deinzer
Date Deposited: 05 Apr 2022 12:09
Last Modified: 05 Apr 2022 12:09
URI: https://pred.uni-regensburg.de/id/eprint/42370

Actions (login required)

View Item View Item
pred is powered by EPrints 3.4 which is developed by the School of Electronics and Computer Science at the University of Southampton. More information and software credits.