Emergence of oscillations in fixed energy sandpile models on complex networks

Fixed-energy sandpile (FES) models, introduced to understand the self-organized criticality, show a continuous phase transition between absorbing and active phases. In this work, we study the dynamics of the deterministic FES models on random networks. We observe that close to absorbing transition t...

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Veröffentlicht in:	arXiv.org 2022-01
Hauptverfasser:	Fazli, Davood, Azimi-Tafreshi, Nahid
Format:	Artikel
Sprache:	eng
Schlagworte:	Density Dynamic structural analysis Networks Nodes Oscillations Phase transitions Physics - Statistical Mechanics Rewiring
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description	Fixed-energy sandpile (FES) models, introduced to understand the self-organized criticality, show a continuous phase transition between absorbing and active phases. In this work, we study the dynamics of the deterministic FES models on random networks. We observe that close to absorbing transition the density of active nodes oscillates and nodes topple in synchrony. The deterministic toppling rule and the small-world property of random networks lead to the emergence of sustained oscillations. The amplitude of oscillations becomes larger with increasing the value of network randomness. The bifurcation diagram for the density of active nodes is obtained. We use the activity-dependent rewiring rule and show that the interplay between the network structure and the FES dynamics leads to the emergence of a bistable region with a first-order transition between the absorbing and active states. Furthermore during the rewiring, the ordered activation pattern of the nodes is broken, which causes the oscillations to disappear.
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subjects	Density Dynamic structural analysis Networks Nodes Oscillations Phase transitions Physics - Statistical Mechanics Rewiring
title	Emergence of oscillations in fixed energy sandpile models on complex networks
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