Dynamical Barriers in the Dyson Hierarchical model via Real Space Renormalization

Abstract

The Dyson hierarchical one-dimensional Ising model of parameter σ>0 contains long-ranged ferromagnetic couplings decaying as 1/r1+σ in terms of the distance r. We study the stochastic dynamics near zero-temperature via the Real Space Renormalization introduced in our previous work (C. Monthus and T. Garel, arxiv:1212.0643) in order to compute explicitly the equilibrium time teq(L) as a function of the system size L. For σ<1 where the static critical temperature for the ferromagnetic transition is finite Tc>0, we obtain that dynamical barriers grow as the power-law: teq(L) β (4 J03(21-σ-1)) L1-σ. For σ=1 where the static critical temperature vanishes Tc=0, we obtain that dynamical barriers grow logarithmically as : teq(L) [β (4 J03 2) -1] L . We also compute finite contributions to the dynamical barriers that can depend on the choice of transition rates satisfying detailed balance.