Distribution of pseudo-critical temperatures and lack of self-averaging in disordered Poland-Scheraga models with different loop exponents

Abstract

According to recent progresses in the finite size scaling theory of disordered systems, thermodynamic observables are not self-averaging at critical points when the disorder is relevant in the Harris criterion sense. This lack of self-averageness at criticality is directly related to the distribution of pseudo-critical temperatures Tc(i,L) over the ensemble of samples (i) of size L. In this paper, we apply this analysis to disordered Poland-Scheraga models with different loop exponents c,corresponding to marginal and relevant disorder. In all cases, we numerically obtain a Gaussian histogram of pseudo-critical temperatures Tc(i,L) with mean Tcav(L) and width Tc(L). For the marginal case c=1.5 corresponding to two-dimensional wetting, both the width Tc(L) and the shift [Tc(∞)-Tcav(L)] decay as L-1/2, so the exponent is unchanged (random=2=pure) but disorder is relevant and leads to non self-averaging at criticality. For relevant disorder c=1.75, the width Tc(L) and the shift [Tc(∞)-Tcav(L)] decay with the same new exponent L-1/random (where random 2.7 > 2 > pure) and there is again no self-averaging at criticality. Finally for the value c=2.15, of interest in the context of DNA denaturation, the transition is first-order in the pure case. In the presence of disorder, the width Tc(L) L-1/2 dominates over the shift [Tc(∞)-Tcav(L)] L-1, i.e. there are two correlation length exponents =2 and =1 that govern respectively the averaged/typical loop distribution.

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