Inhomogeneities in the 2-Flavor Chiral Gross-Neveu Model

Abstract

We investigate the finite-temperature and -density chiral Gross-Neveu model with an axial UA(1) symmetry in 1+1 dimensions on the lattice. In the limit where the number of flavors Nf tends to infinity the continuum model has been solved analytically and shows two phases: a symmetric high-temperature phase with a vanishing condensate and a low-temperature phase in which the complex condensate forms a chiral spiral which breaks translation invariance. In the lattice simulations we employ chiral SLAC fermions with exact axial symmetry. Similarly to Nf∞, we find for 8 flavors, where quantum and thermal fluctuations are suppressed, two distinct regimes in the (T,μ) phase diagram, characterized by qualitatively different behavior of the two-point functions of the condensate fields. More surprisingly, at Nf=2, where fluctuations are no longer suppressed, the model still behaves similarly to the Nf∞ model and we conclude that the chiral spiral leaves its footprints even on systems with a small number of flavors. For example, at low temperature the two-point functions are still dominated by chiral spirals with pitches proportional to the inverse chemical potential, although in contrast to large-Nf their amplitudes decrease with distance. We argue that these results should not be interpreted as the spontaneous breaking of a continuous symmetry, which is forbidden in two dimensions. Finally, using Dyson-Schwinger equations we calculate the decay of the UA(1)-invariant fermion four-point function in search for a BKT phase at zero temperature.