General properties of the response function in a class of solvable non-equilibrium models
Abstract
We study the non-equilibrium response function Rij(t,t'), namely the variation of the local magnetization Si(t) on site i at time t as an effect of a perturbation applied at the earlier time t' on site j, in a class of solvable spin models characterized by the vanishing of the so-called asymmetry. This class encompasses both systems brought out of equilibrium by the variation of a thermodynamic control parameter, as after a temperature quench, or intrinsically out of equilibrium models with violation of detailed balance. The one-dimensional Ising model and the voter model (on an arbitrary graph) are prototypical examples of these two situations which are used here as guiding examples. Defining the fluctuation-dissipation ratio Xij(t,t')=β Rij/(∂ Gij/∂ t'), where Gij(t,t')= Si(t)Sj(t') is the spin-spin correlation function and β is a parameter regulating the strength of the perturbation (corresponding to the inverse temperature when detailed balance holds), we show that, in the quite general case of a kinetics obeying dynamical scaling, on equal sites this quantity has a universal formXii(t,t') = (t+t')/(2t), whereas t ∞Xij(t,t')=1/2 for any ij couple. The specific case of voter models with long-range interactions is thoroughly discussed.
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