Typical versus averaged overlap distribution in Spin-Glasses : Evidence for the droplet scaling theory

Abstract

We consider the statistical properties over disordered samples of the overlap distribution P J(q) which plays the role of an order parameter in spin-glasses. We show that near zero temperature (i) the typical overlap distribution is exponentially small in the central region of -1<q<1: Ptyp(q) = e P J(q) e- β Nθ φ(q) , where θ is the droplet exponent defined here with respect to the total number N of spins (in order to consider also fully connected models where the notion of length does not exist); (ii) the rescaled variable v = - ( P J(q))/Nθ remains an O(1) random positive variable describing sample-to sample fluctuations; (iii) the averaged distribution P J(q) is non-typical and dominated by rare anomalous samples. Similar statements hold for the cumulative overlap distribution I J(q0) ∫0q0 dq P J(q) . These results are derived explicitly for the spherical mean-field model with θ=1/3, φ(q)=1-q2 , and the random variable v corresponds to the rescaled difference between the two largest eigenvalues of GOE random matrices. Then we compare numerically the typical and averaged overlap distributions for the long-ranged one-dimensional Ising spin-glass with random couplings decaying as J(r) r-σ for various values of the exponent σ, corresponding to various droplet exponents θ(σ), and for the mean-field SK-model (corresponding formally to the σ=0 limit of the previous model). Our conclusion is that future studies on spin-glasses should measure the typical values of the overlap distribution or of the cumulative overlap distribution to obtain clearer conclusions on the nature of the spin-glass phase.