English

Taming Density Functional Theory by Coarse-Graining

Mathematical Physics 2015-05-13 v3 Other Condensed Matter math.MP

Abstract

The standard (``fine-grained'') interpretation of quantum density functional theory, in which densities are specified with infinitely-fine spatial resolution, is mathematically unruly. Here, a coarse-grained version of DFT, featuring limited spatial resolution, and its relation to the fine-grained theory in the L1L3L^1\cap L^3 formulation of Lieb, is studied, with the object of showing it to be not only mathematically well-behaved, but consonant with the spirit of DFT, practically (computationally) adequate and sufficiently close to the standard interpretation as to accurately reflect its non-pathological properties. The coarse-grained interpretation is shown to be a good model of formal DFT in the sense that: all densities are (ensemble)-V-representable; the intrinsic energy functional FF is a continuous function of the density and the representing external potential is the (directional) functional derivative of the intrinsic energy. Also, the representing potential v[ρ]v[\rho] is quasi-continuous, in that v[ρ]ρv[\rho]\rho is continuous as a function of ρ\rho. The limit of coarse-graining scale going to zero is studied to see if convergence to the non-pathological aspects of the fine-grained theory is adequate to justify regarding coarse-graining as a good approximation. Suitable limiting behaviors or intrinsic energy, densities and representing potentials are found. Intrinsic energy converges monotonically, coarse-grained densities converge uniformly strongly to their low-intrinsic-energy fine-grainings, and L3/2+LL^{3/2}+L^\infty representability of a density is equivalent to the existence of a convergent sequence of coarse-grained potential/ground-state density pairs.

Keywords

Cite

@article{arxiv.0908.1263,
  title  = {Taming Density Functional Theory by Coarse-Graining},
  author = {Paul E. Lammert},
  journal= {arXiv preprint arXiv:0908.1263},
  year   = {2015}
}

Comments

All sections have been revised at least a little, but the significant technical improvements are in section 6

R2 v1 2026-06-21T13:33:53.163Z