A self-consistent ground-state formulation of the first-principles Hubbard U parameter validated on one-electron self-interaction error
Abstract
In electronic structure methods based on the correction of approximate density-functional theory (DFT) for systematic inaccuracies, Hubbard parameters may be used to quantify and amend the self-interaction errors ascribed to selected subspaces. Here, in order to enable the accurate, computationally convenient calculation of by means of DFT algorithms that locate the ground-state by direct total-energy minimization, we introduce a reformulation of the successful linear-response method for in terms of the fully-relaxed constrained ground-state density. Defining as an implicit functional of the ground-state density implies the comparability of DFT + Hubbard (DFT+) total-energies, and related properties, as external parameters such as ionic positions are varied together with their corresponding first-principles values. Our approach provides a framework in which to address the partially unresolved question of self-consistency over , for which plausible schemes have been proposed, and to precisely define the energy associated with subspace many-body self-interaction error. We demonstrate that DFT+ precisely corrects the total energy for self-interaction error under ideal conditions, but only if a simple self-consistency condition is applied. Such parameters also promote to first-principles a recently proposed DFT+ based method for enforcing Koopmans' theorem.
Keywords
Cite
@article{arxiv.1704.08076,
title = {A self-consistent ground-state formulation of the first-principles Hubbard U parameter validated on one-electron self-interaction error},
author = {Glenn Moynihan and Gilberto Teobaldi and David D. O'Regan},
journal= {arXiv preprint arXiv:1704.08076},
year = {2017}
}
Comments
14 pages, 4 figures