Zero-temperature spinglass-ferromagnetic transition : scaling analysis of the domain-wall energy

Abstract

For the Ising model with Gaussian random coupling of average J0 and unit variance, the zero-temperature spinglass-ferromagnetic transition as a function of the control parameter J0 can be studied via the size-L dependent renormalized coupling defined as the domain-wall energy JR(L) EGS(AF)(L)-EGS(F)(L) (i.e. the difference between the ground state energies corresponding to AntiFerromagnetic and and Ferromagnetic boundary conditions in one direction). We study numerically the critical exponents of this zero-temperature transition within the Migdal-Kadanoff approximation as a function of the dimension d=2,3,4,5,6. We then compare with the mean-field spherical model. Our main conclusion is that in low dimensions, the critical stiffness exponent θc is clearly bigger than the spin-glass stiffness exponent θSG, but that they turn out to coincide in high enough dimension and in the mean-field spherical model. We also discuss the finite-size scaling properties of the averaged value and of the width of the distribution of the renormalized couplings.