English

Kohn-Sham theory with paramagnetic currents: compatibility and functional differentiability

Chemical Physics 2019-07-23 v2 Other Condensed Matter Mathematical Physics math.MP

Abstract

Recent work has established Moreau-Yosida regularization as a mathematical tool to achieve rigorous functional differentiability in density-functional theory. In this article, we extend this tool to paramagnetic current-density-functional theory, the most common density-functional framework for magnetic field effects. The extension includes a well-defined Kohn-Sham iteration scheme with a partial convergence result. To this end, we rely on a formulation of Moreau-Yosida regularization for reflexive and strictly convex function spaces. The optimal LpL^p-characterization of the paramagnetic current density L1L3/2L^1\cap L^{3/2} is derived from the NN-representability conditions. A crucial prerequisite for the convex formulation of paramagnetic current-density-functional theory, termed compatibility between function spaces for the particle density and the current density, is pointed out and analyzed. Several results about compatible function spaces are given, including their recursive construction. The regularized, exact functionals are calculated numerically for a Kohn-Sham iteration on a quantum ring, illustrating their performance for different regularization parameters.

Keywords

Cite

@article{arxiv.1902.09086,
  title  = {Kohn-Sham theory with paramagnetic currents: compatibility and functional differentiability},
  author = {Andre Laestadius and Erik I. Tellgren and Markus Penz and Michael Ruggenthaler and Simen Kvaal and Trygve Helgaker},
  journal= {arXiv preprint arXiv:1902.09086},
  year   = {2019}
}
R2 v1 2026-06-23T07:49:32.496Z