How communities shape epidemic spreading: A hierarchically structured metapopulation perspective (2504.05653v2)
Abstract: Recent outbreaks of COVID-19, Zika, Ebola, and influenza have renewed interest in advancing epidemic models to better reflect the complexities of disease spreading. Modern approaches incorporate social norms, mobility patterns, and heterogeneous community structures to capture the interplay between social and biological dynamics. This study examines epidemic propagation in hierarchically structured metapopulation networks, where individuals interact within localized communities -- such as schools, workplaces, and theaters -- and diffuse across them. Using mean-field averaging, we derive a scaling law linking contagion rates to the mean connectivity degree, while stability analysis identifies thresholds for infection surges. In networks with heterogeneous mean degrees, spectral perturbation theory reveals how structural variability accelerates and amplifies disease spreading. We find that nodes with above-average degrees are not only infected earlier but also act as key outbreak drivers. Framing epidemic dynamics as a continuous phase transition, we apply pattern formation theory to show that the critical eigenvectors governing system stability are shaped by the network's degree distribution. Crucially, by analyzing Laplacian eigenvector localization, we uncover a one-to-one correspondence between community infection densities and the entries of the critical eigenvector -- revealing how internal community structure directly shapes global infection patterns. This work provides a systematic framework for understanding and predicting epidemic dynamics in structured populations, while highlighting the fundamental role of community organization.