English

Large deviations of the giant in supercritical kernel-based spatial random graphs

Probability 2025-11-12 v2

Abstract

We study cluster sizes in supercritical dd-dimensional inhomogeneous percolation models with long-range edges -- such as long-range percolation -- and/or heavy-tailed degree distributions -- such as geometric inhomogeneous random graphs and the age-dependent random connection model. Our focus is on large deviations of the size of the largest cluster in the graph restricted to a finite box as its volume tends to infinity. Compared to nearest-neighbor Bernoulli bond percolation on Zd\mathbb{Z}^d, we show that long edges can increase the exponent of the polynomial speed of the lower tail from (d1)/d(d-1)/d to any ζ((d1)/d,1)\zeta_\star\in\big((d-1)/d,1\big). We prove that this exponent ζ\zeta_\star also governs the size of the second-largest cluster, and the distribution of the size of the cluster containing the origin C(0)\mathcal{C}(0). For the upper tail of large deviations, we prove that its speed is logarithmic for models with power-law degree distributions. We express the rate function via the generating function of C(0)|\mathcal{C}(0)|. The upper tail in degree-homogeneous models decays much faster: the speed in long-range percolation is linear.

Keywords

Cite

@article{arxiv.2404.02984,
  title  = {Large deviations of the giant in supercritical kernel-based spatial random graphs},
  author = {Joost Jorritsma and Júlia Komjáthy and Dieter Mitsche},
  journal= {arXiv preprint arXiv:2404.02984},
  year   = {2025}
}

Comments

69 pages, 3 figures. To appear in Probability Theory & Related Fields

R2 v1 2026-06-28T15:43:24.259Z