Fermionic quantum dimer and fully-packed loop models on the square lattice
Abstract
We consider fermionic fully-packed loop and quantum dimer models which serve as effective low-energy models for strongly correlated fermions on a checkerboard lattice at half and quarter filling, respectively. We identify a large number of fluctuationless states specific to each case, due to the fermionic statistics. We discuss the symmetries and conserved quantities of the system and show that for a class of fluctuating states in the half-filling case, the fermionic sign problem can be gauged away. This claim is supported by numerical evaluation of the low-lying states and can be understood by means of an algebraic construction. The elimination of the sign problem then allows us to analyze excitations at the Rokhsar-Kivelson point of the models using the relation to the height model and its excitations, within the single-mode approximation. We then discuss a mapping to a U(1) lattice gauge theory which relates the considered low-energy model to the compact quantum electrodynamics in 2+1 dimensions. Furthermore, we point out consequences and open questions in the light of these results.
Cite
@article{arxiv.1101.0335,
title = {Fermionic quantum dimer and fully-packed loop models on the square lattice},
author = {Frank Pollmann and Joseph J. Betouras and Kirill Shtengel and Peter Fulde},
journal= {arXiv preprint arXiv:1101.0335},
year = {2011}
}
Comments
12 pages, 9 figures