Modified Epidemic Diffusive Process on the Apollonian Network

TL;DR

This paper analyzes a modified epidemic diffusion process on the Apollonian network using Monte Carlo simulations, revealing a continuous phase transition with unique critical exponents different from mean-field predictions.

Contribution

It introduces a modified diffusive epidemic model on complex networks and characterizes its critical behavior through finite-size scaling analysis.

Findings

Identifies a continuous phase transition with specific critical exponents.

Shows the critical exponents differ from mean-field universality class.

Demonstrates the model's applicability to realistic epidemic spreading scenarios.

Abstract

We present an analysis of an epidemic spreading process on the Apollonian network that can describe an epidemic spreading in a non-sedentary population. The modified diffusive epidemic process was employed in this analysis in a computational context by means of the Monte Carlo method. Our model has been useful for modeling systems closer to reality consisting of two classes of individuals: susceptible (A) and infected (B). The individuals can diffuse in a network according to constant diffusion rates $D_{A}$ and $D_{B}$, for the classes A and B, respectively, and obeying three diffusive regimes, i.e., $D_{A}<D_{B}$, $D_{A}=D_{B}$ and $D_{A}>D_{B}$. Into the same site $i$, the reaction occurs according to the dynamical rule based on Gillespie's algorithm. Finite-size scaling analysis has shown that our model exhibit continuous phase transition to an absorbing state with a set of critical exponents given by $\beta/\nu=0.66(1)$, $1/\nu=0.46(2)$, and $\gamma/\nu=-0.24(2)$ common to every investigated regime. In summary, the continuous phase transition, characterized by this set of critical exponents, does not have the same exponents of the Mean-Field universality class in both regular lattices and complex networks.