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Quenched mean-field theory for the majority-vote model on complex networks

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arxiv 1712.09733 v1 pith:SYXB2POM submitted 2017-12-28 cond-mat.stat-mech physics.soc-ph

Quenched mean-field theory for the majority-vote model on complex networks

classification cond-mat.stat-mech physics.soc-ph
keywords networksmean-fieldmodelquenchedtheorycriticalmajority-votenoise
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The majority-vote (MV) model is one of the simplest nonequilibrium Ising-like model that exhibits a continuous order-disorder phase transition at a critical noise. In this paper, we present a quenched mean-field theory for the dynamics of the MV model on networks. We analytically derive the critical noise on arbitrary quenched unweighted networks, which is determined by the largest eigenvalue of a modified network adjacency matrix. By performing extensive Monte Carlo simulations on synthetic and real networks, we find that the performance of the quenched mean-field theory is superior to a heterogeneous mean-field theory proposed in a previous paper [Chen \emph{et al.}, Phys. Rev. E 91, 022816 (2015)], especially for directed networks.

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