Nonequilibrium dynamics of fully frustrated Ising models at T=0

Abstract

We consider two fully frustrated Ising models: the antiferromagnetic triangular model in a field of strength, h=H T kB, as well as the Villain model on the square lattice. After a quench from a disordered initial state to T=0 we study the nonequilibrium dynamics of both models by Monte Carlo simulations. In a finite system of linear size, L, we define and measure sample dependent "first passage time", tr, which is the number of Monte Carlo steps until the energy is relaxed to the ground-state value. The distribution of tr, in particular its mean value, < tr(L) >, is shown to obey the scaling relation, < tr(L) > L2 (L/L0), for both models. Scaling of the autocorrelation function of the antiferromagnetic triangular model is shown to involve logarithmic corrections, both at H=0 and at the field-induced Kosterlitz-Thouless transition, however the autocorrelation exponent is found to be H dependent.