Three-state Majority-Vote Model on Barab\'asi-Albert and Cubic Networks and the Unitary Relation for Critical Exponents

Abstract

We investigate the three-state majority-vote model with noise on scale-free and regular networks. In this model, an individual selects an opinion equal to the opinion of the majority of its neighbors with probability 1 - q and opposite to it with probability q. The parameter q is called the noise parameter of the model. We build a network of interactions where z neighbors are selected by each added site in the system, yielding a preferential attachment network with degree distribution k-λ, where λ 3. In this work, z is called growth parameter. Using finite-size scaling analysis, we show that the critical exponents associated with the magnetization and magnetic susceptibility add up to unity when a volumetric scaling is used, regardless of the dimension of the network of interactions. Using Monte Carlo simulations, we calculate the critical noise parameter qc as a function of z for the scale-free networks and obtain the phase diagram of the model. We find that the critical noise is an increasing function of the growth parameter z, and we define and verify numerically the unitary relation for the critical exponents by calculating β /, γ / and 1/ for several values of the network parameter z. We also obtain the critical noise and the critical exponents for the two and three-state majority-vote model on cubic lattices networks where we illustrate the application of the unitary relation with a volumetric scaling.