Nonequilibrium study of the J1-J2 Ising model with random J2 couplings in the square lattice
Abstract
We studied the critical behavior of the J1-J2 spin-1/2 Ising model in the square lattice by considering J1 fixed and J2 as random interactions following discrete and continuous probability distribution functions. The configuration of J2 in the lattice evolves in time through a competing kinetics using Monte Carlo simulations leading to a steady state without reaching the free-energy minimization. However, the resulting non-equilibrium phase diagrams are, in general, qualitatively similar to those obtained with quenched randomness at equilibrium in past works. Accordingly, through this dynamics the essential critical behavior at finite temperatures can be grasped for this model. The advantage is that simulations spend less computational resources, since the system does not need to be replicated or equilibrated with Parallel Tempering. A special attention was given for the value of the amplitude of the correlation length at the critical point of the superantiferromagnetic-paramagnetic transition.
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