English

Bootstrap percolation in power-law random graphs

Probability 2013-08-15 v2 Statistical Mechanics Combinatorics

Abstract

A bootstrap percolation process on a graph GG is an "infection" process which evolves in rounds. Initially, there is a subset of infected nodes and in each subsequent round each uninfected node which has at least rr infected neighbours becomes infected and remains so forever. The parameter r2r\geq 2 is fixed. Such processes have been used as models for the spread of ideas or trends within a network of individuals. We analyse bootstrap percolation process in the case where the underlying graph is an inhomogeneous random graph, which exhibits a power-law degree distribution, and initially there are a(n)a(n) randomly infected nodes. The main focus of this paper is the number of vertices that will have been infected by the end of the process. The main result of this work is that if the degree sequence of the random graph follows a power law with exponent β\beta, where 2<β<32 < \beta < 3, then a sublinear number of initially infected vertices is enough to spread the infection over a linear fraction of the nodes of the random graph, with high probability. More specifically, we determine explicitly a critical function ac(n)a_c(n) such that ac(n)=o(n)a_c(n)=o(n) with the following property. Assuming that nn is the number of vertices of the underlying random graph, if a(n)ac(n)a(n) \ll a_c(n), then the process does not evolve at all, with high probability as nn grows, whereas if a(n)ac(n)a(n)\gg a_c(n), then there is a constant \eps>0\eps>0 such that, with high probability, the final set of infected vertices has size at least \epsn\eps n. It turns out that when the maximum degree is o(n1/(β1))o(n^{1/(\beta -1)}), then ac(n)a_c(n) depends also on rr. But when the maximum degree is Θ(n1/(β1))\Theta (n^{1/(\beta -1)}), then ac(n)=nβ2β1a_c (n)=n^{\beta -2 \over \beta -1}.

Keywords

Cite

@article{arxiv.1111.1339,
  title  = {Bootstrap percolation in power-law random graphs},
  author = {Hamed Amini and Nikolaos Fountoulakis},
  journal= {arXiv preprint arXiv:1111.1339},
  year   = {2013}
}

Comments

23 pages

R2 v1 2026-06-21T19:31:30.526Z