Critical Behaviour in the Single Flavor Thirring Model in 2+1d

Abstract

Results of a lattice field theory simulation of the single-flavor Thirring model in 2+1 spacetime dimensions are presented. The lattice model is formulated using domain wall fermions as a means to recover the correct U(2) symmetries of the continuum model in the limit where wall separation Ls∞. Simulations on 123, 163× Ls, varying self-interaction strength g2 and bare mass m are performed with Ls = 8, … 48, and the results for the bilinear condensate fitted to a model equation of state assuming a U(2)(1)(1) symmetry-breaking phase transition at a critical gc2. First estimates for g-2a and critical exponents are presented, showing small but significant departures from mean-field values. The results confirm that a symmetry-breaking transition does exist and therefore the critical number of flavors for the Thirring model Nc > 1. Results for both condensate and associated susceptibility are also obtained in the broken phase on 163×48, suggesting that here the Ls∞ extrapolation is not yet under control. We also present results obtained with the associated 2+1d truncated overlap operator DOL demonstrating exponential localisation, a necessary condition for the recovery of U(2) global symmetry, but that recovery of the Ginsparg-Wilson condition as Ls∞ is extremely slow in the broken phase.