Ground-State and Domain-Wall Energies in the Spin-Glass Region of the 2D J Random-Bond Ising Model
Abstract
The statistics of the ground-state and domain-wall energies for the two-dimensional random-bond Ising model on square lattices with independent, identically distributed bonds of probability p of Jij= -1 and (1-p) of Jij= +1 are studied. We are able to consider large samples of up to 3202 spins by using sophisticated matching algorithms. We study L × L systems, but we also consider L × M samples, for different aspect ratios R = L / M. We find that the scaling behavior of the ground-state energy and its sample-to-sample fluctuations inside the spin-glass region (pc p 1 - pc) are characterized by simple scaling functions. In particular, the fluctuations exhibit a cusp-like singularity at pc. Inside the spin-glass region the average domain-wall energy converges to a finite nonzero value as the sample size becomes infinite, holding R fixed. Here, large finite-size effects are visible, which can be explained for all p by a single exponent ω≈ 2/3, provided higher-order corrections to scaling are included. Finally, we confirm the validity of aspect-ratio scaling for R 0: the distribution of the domain-wall energies converges to a Gaussian for R 0, although the domain walls of neighboring subsystems of size L × L are not independent.
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