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Directionality reduces the impact of epidemics in multilayer networks

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arxiv 1904.06959 v1 pith:IHJZEX3K submitted 2019-04-15 physics.soc-ph cond-mat.stat-mech

Directionality reduces the impact of epidemics in multilayer networks

classification physics.soc-ph cond-mat.stat-mech
keywords networksmultilayerdifferentdirectedlayersclassdegreedirectionality
verification ladder T0 review T1 audit T2 compute T3 formal T4 reserved
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The study of how diseases spread has greatly benefited from advances in network modeling. Recently, a class of networks known as multilayer graphs has been shown to describe more accurately many real systems, making it possible to address more complex scenarios in epidemiology such as the interaction between different pathogens or multiple strains of the same disease. In this work, we study in depth a class of networks that have gone unnoticed up to now, despite of its relevance for spreading dynamics. Specifically, we focus on directed multilayer networks, characterized by the existence of directed links, either within the layers or across layers. Using the generating function approach and numerical simulations of a stochastic susceptible-infected-susceptible (SIS) model, we calculate the epidemic threshold for these networks for different degree distributions of the networks. Our results show that the main feature that determines the value of the epidemic threshold is the directionality of the links connecting different layers, regardless of the degree distribution chosen. Our findings are of utmost interest given the ubiquitous presence of directed multilayer networks and the widespread use of disease-like spreading processes in a broad range of phenomena such as diffusion processes in social and transportation systems.

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