Giants through higher-order paths in random simplicial complexes

Abstract

We investigate the giant component formed via high-dimensional paths in the multi-parameter random simplicial complex (MRSC) model. For a d-dimensional simplicial complex, we define d-dimensional connectivity through incidence between (d-1)- and d-dimensional simplices. The phase transition of the largest d-dimensional connected component is determined in terms of the parameter λ that governs the number of d-simplices incident to a typical (d-1)-simplex. In the subcritical regime, we show that the largest component contains ( n) many (d-1)-simplices with high probability in the MRSC model. In the supercritical regime, we determine the asymptotic proportion of 1-simplices in the giant component in dimension 2, for λc < λ < λ, where λ > 4 is an explicit constant. In particular, for Linial-Meshulam complexes, this result holds throughout the entire supercritical regime. Additionally, we show that the number of vertices in the giant component undergoes a discontinuous phase transition in d-dimensional Linial-Meshulam complexes, in the sense that the asymptotic proportion of vertices in the giant jumps from 0 to 1. Our approach is based on local-weak convergence. We establish local-weak convergence in probability for the MRSC model and prove the concentration result via a refined analysis of the breadth-first exploration process, which tracks contributions from newly discovered and previously explored vertices.