Zero-temperature criticality in the Gaussian random bond Ising model on a square lattice

Abstract

The free energy and the specific heat of the two-dimensional Gaussian random bond Ising model on a square lattice are found with high accuracy using graph expansion method. At low temperatures the specific heat reveals a zero-temperature criticality described by the power law C T1+α, with α= 0.55(8). Interpretation of the free energy in terms of independent two-level excitations gives the density of states, that follows a novel power law (ε) εα at low energies. An exact high-temperature series for this model up to the term β29 is found. A proof that the density of one-site spin flip states vanishes at low energy is given.