Miguel A. Muñoz, Róbert Juhász, Claudio Castellano, Géza Ódor
Published 2010-09-02Version 1
Quenched disorder is known to play a relevant role in dynamical processes and phase transitions. Its effects on the dynamics of complex networks have hardly been studied. Aimed at filling this gap, we analyze the Contact Process, i.e. the simplest propagation model, with quenched disorder on complex networks. We find Griffiths phases and other rare region effects, leading rather generically to anomalously slow (algebraic, logarithmic, ...) relaxation, on Erd\H os-R\'enyi networks. Similar effects are predicted to exist for other topologies with a finite percolation threshold. More surprisingly, we find that Griffiths phases can also emerge in the absence of quenched disorder, as a consequence of topological heterogeneity in networks with finite topological dimension. These results have a broad spectrum of implications for propagation phenomena and other dynamical processes on networks.
Comments: 4 pages, 3 figures, to appear in Phys. Rev. Lett
Journal: Phys. Rev. Lett. 105, 128701 (2010)
Curvature and temperature of complex networks
How clustering affects the bond percolation threshold in complex networks
Griffiths phases in the contact process on complex networks
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