Eigenvalue method to compute the largest relaxation time of disordered systems

Abstract

We consider the dynamics of finite-size disordered systems as defined by a master equation satisfying detailed balance. The master equation can be mapped onto a Schr\"odinger equation in configuration space, where the quantum Hamiltonian H has the generic form of an Anderson localization tight-binding model. The largest relaxation time teq governing the convergence towards Boltzmann equilibrium is determined by the lowest non-vanishing eigenvalue E1=1/teq of H (the lowest eigenvalue being E0=0). So the relaxation time teq can be computed without simulating the dynamics by any eigenvalue method able to compute the first excited energy E1. Here we use the 'conjugate gradient' method to determine E1 in each disordered sample and present numerical results on the statistics of the relaxation time teq over the disordered samples of a given size for two models : (i) for the random walk in a self-affine potential of Hurst exponent H on a two-dimensional square of size L × L, we find the activated scaling teq(L) L with =H as expected; (ii) for the dynamics of the Sherrington-Kirkpatrick spin-glass model of N spins, we find the growth teq(N) N with =1/3 in agreement with most previous Monte-Carlo measures. In addition, we find that the rescaled distribution of ( teq) decays as e- uη for large u with a tail exponent of order η 1.36. We give a rare-event interpretation of this value, that points towards a sample-to-sample fluctuation exponent of order width 0.26 for the barrier.