Effects of an external drive on the fluctuation-dissipation relation of phase-ordering systems

Abstract

The relation between the autocorrelation C(t,tw) and the integrated linear response function (t,tw) is studied in the context of the large-N model for phase-ordering systems subjected to a shear flow. In the high temperature phase T>Tc a non-equilibrium stationary state is entered which is characterized by a non-trivial fluctuation-dissipation relation (t-tw)= (C(t-tw)). For quenches below Tc the splitting of the order parameter field into two statistically independent components, responsible for the stationary Cst(t-tw) and aging Cag(t/tw) part of the autocorrelation function, can be explicitly exhibited in close analogy with the undriven case. In the regime t-tw tw the same relation (t-tw)= (Cst(t-tw)) is found between the response and Cst(t-tw), as for T>Tc . The aging part of (t,tw) is negligible for tw ∞, as without drive, resulting in a flat (C) in the aging regime t-tw tw.

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