Dynamics of Ising models near zero temperature : Real Space Renormalization Approach

Abstract

We consider the stochastic dynamics of Ising ferromagnets (either pure or random) near zero temperature. The master equation satisfying detailed balance can be mapped onto a quantum Hamiltonian which has an exact zero-energy ground state representing the thermal equilibrium. The largest relaxation time teq governing the convergence towards this Boltzmann equilibrium in finite-size systems is determined by the lowest non-vanishing eigenvalue E1=1/teq of the quantum Hamiltonian H. We introduce and study a real-space renormalization procedure for the quantum Hamiltonian associated to the single-spin-flip dynamics of Ising ferromagnets near zero temperature. We solve explicitly the renormalization flow for two cases. (i) For the one-dimensional random ferromagnetic chain with free boundary conditions, the largest relaxation time teq can be expressed in terms of the set of random couplings for various choices of the dynamical transition rates. The validity of these RG results in d=1 is checked by comparison with another approach. (ii) For the pure Ising model on a Cayley tree of branching ratio K, we compute the exponential growth of teq(N) with the number N of generations.