Projector self-consistent DFT+U using non-orthogonal generalized Wannier functions
Abstract
We present a formulation of the density-functional theory + Hubbard model (DFT+U) method that is self-consistent over the choice of Hubbard projectors used to define the correlated subspaces. In order to overcome the arbitrariness in this choice, we propose the use of non-orthogonal generalized Wannier functions (NGWFs) as projectors for the DFT+U correction. We iteratively refine these NGWF projectors and, hence, the DFT+U functional, such that the correlated subspaces are fully self-consistent with the DFT+U ground-state. We discuss the convergence characteristics of this algorithm and compare ground-state properties thus computed with those calculated using hydrogenic projectors. Our approach is implemented within, but not restricted to, a linear-scaling DFT framework, opening the path to DFT+U calculations on systems of unprecedented size.
Keywords
Cite
@article{arxiv.1004.4813,
title = {Projector self-consistent DFT+U using non-orthogonal generalized Wannier functions},
author = {David D. O'Regan and Nicholas D. M. Hine and Mike C. Payne and Arash A. Mostofi},
journal= {arXiv preprint arXiv:1004.4813},
year = {2015}
}
Comments
4 pages, 3 figures. This version (v2) matches that accepted for Physical Review B Rapid Communications on 26th July 2010