Reduced Density Matrix Functional Theory for Bosons
Abstract
Based on a generalization of Hohenberg-Kohn's theorem, we propose a ground state theory for bosonic quantum systems. Since it involves the one-particle reduced density matrix as a natural variable but still recovers quantum correlations in an exact way it is particularly well-suited for the accurate description of Bose-Einstein condensates. As a proof of principle we study the building block of optical lattices. The solution of the underlying -representability problem is found and its peculiar form identifies the constrained search formalism as the ideal starting point for constructing accurate functional approximations: The exact functionals for this -boson Hubbard dimer and general Bogoliubov-approximated systems are determined. The respective gradient forces are found to diverge in the regime of Bose-Einstein condensation, , providing a natural explanation for the absence of complete BEC in nature.
Cite
@article{arxiv.2002.06943,
title = {Reduced Density Matrix Functional Theory for Bosons},
author = {Carlos L. Benavides-Riveros and Jakob Wolff and Miguel A. L. Marques and Christian Schilling},
journal= {arXiv preprint arXiv:2002.06943},
year = {2020}
}