Speaker
Dr
Dominik Smith
(Justus Liebig University - Gießen)
Description
Hybrid Monte Carlo is traditionally employed in lattice QCD calculations. In principle, however, its applicability extends to a wide range of other interacting Fermion systems. One such system which can be simulated without a fermion-sign problem is the extended Hubbard model at half-filling, which describes electrons that can hop between the sites of a crystal lattice and includes on-site ($U$) and nearest-neighbor ($V$) interaction terms. This model is of great interest in condensed matter physics, as it describes a wide range of electronic systems in good approximation. The extended Hubbard model on the hexagonal lattice in 2+1 space-time dimensions is of interest also to high-energy physicists, as its low-energy excitations provide a realization of Dirac fermions. In the case of strong coupling, various types of transitions to electronic gapped phases can occur, which possess analogies to chiral-symmetry breaking. - In this work we study the competition between spin-density wave and charge-density wave order in the $U-V$ plane through HMC. Our simulations do not include any explicit symmetry-breaking terms and are thus completely unbiased. We find an extended phase of spin-density wave order and determine that its border is characterized by critical scaling in the Gross-Neveu universality class.
Primary author
Dr
Dominik Smith
(Justus Liebig University - Gießen)
Co-authors
Prof.
Lorenz von Smekal
(Justus-Liebig-Universität Gießen)
Mr
Maksim Ulybyshev
(University of Regensburg)
Dr
Pavel Buividovich
(Regensburg University)