Multiscale genesis of a tiny giant for percolation on scale-free random graphs

Abstract

We study the critical behavior for percolation on inhomogeneous random networks on n vertices, where the weights of the vertices follow a power-law distribution with exponent τ ∈ (2,3). Such networks, often referred to as scale-free networks, exhibit critical behavior when the percolation probability tends to zero at an appropriate rate, as n∞. We identify the critical window for a host of scale-free random graph models such as the Norros-Reittu model, Chung-Lu model and generalized random graphs. Surprisingly, there exists a finite time inside the critical window, after which, we see a sudden emergence of a tiny giant component. This is a novel behavior which is in contrast with the critical behavior in other known universality classes with τ ∈ (3,4) and τ >4. Precisely, for edge-retention probabilities πn = λ n-(3-τ)/2, there is an explicitly computable λc>0 such that the critical window is of the form λ ∈ (0,λc), where the largest clusters have size of order nβ with β=(τ2-4τ+5)/[2(τ-1)]∈[2-1, 12) and have non-degenerate scaling limits, while in the supercritical regime λ > λc, a unique `tiny giant' component of size n emerges. For λ ∈ (0,λc), the scaling limit of the maximum component sizes can be described in terms of components of a one-dimensional inhomogeneous percolation model on Z+ studied in a seminal work by Durrett and Kesten. For λ>λc, we prove that the sudden emergence of the tiny giant is caused by a phase transition inside a smaller core of vertices of weight (n).