Litcius/Paper detail

Universal Nonlinear Infection Kernel from Heterogeneous Exposure on Higher-Order Networks

Guillaume St-Onge, Hanlin Sun, Antoine Allard, Laurent Hébert-Dufresne, Ginestra Bianconi

2021Physical Review Letters103 citationsDOIOpen Access PDF

Abstract

The collocation of individuals in different environments is an important prerequisite for exposure to infectious diseases on a social network. Standard epidemic models fail to capture the potential complexity of this scenario by (1) neglecting the higher-order structure of contacts that typically occur through environments like workplaces, restaurants, and households, and (2) assuming a linear relationship between the exposure to infected contacts and the risk of infection. Here, we leverage a hypergraph model to embrace the heterogeneity of environments and the heterogeneity of individual participation in these environments. We find that combining heterogeneous exposure with the concept of minimal infective dose induces a universal nonlinear relationship between infected contacts and infection risk. Under nonlinear infection kernels, conventional epidemic wisdom breaks down with the emergence of discontinuous transitions, superexponential spread, and hysteresis.

Topics & Concepts

Leverage (statistics)Nonlinear systemComputer scienceKernel (algebra)Statistical physicsHypergraphTheoretical computer scienceLinear modelCorollaryApplied mathematicsEpidemic modelBiological systemMathematical optimizationMathematicsPoint processAlgorithmComplex Network Analysis TechniquesCOVID-19 epidemiological studiesOpinion Dynamics and Social Influence