Non-Ergodic Dynamics of the 2D Random-phase Sine-Gordon Model: Applications to Vortex-Glass Arrays and Disordered-Substrate Surfaces
Abstract
The dynamics of the random-phase sine-Gordon model, which describes 2D vortex-glass arrays and crystalline surfaces on disordered substrates, is investigated using the self-consistent Hartree approximation. The fluctuation-dissipation theorem is violated below the critical temperature Tc for large time t>t* where t* diverges in the thermodynamic limit. While above Tc the averaged autocorrelation function diverges as Tln(t), for T<Tc it approaches a finite value q* proportional to 1/(Tc-T) as q(t) = q* - c(t/t*)- (for t --> t*) where is a temperature-dependent exponent. On larger time scales t > t* the dynamics becomes non-ergodic. The static correlations behave as Tlnx for T>Tc and for T<Tc when x < * with * proportional to expA/(Tc-T). For scales x > *, they behave as (T/m)lnx where m is approximately T/Tc near Tc, in general agreement with the variational replica-symmetry breaking approach and with recent simulations of the disordered-substrate surface. For strong- coupling the transition becomes first-order.
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