Clique factors in randomly perturbed graphs: the transition points
Abstract
A randomly perturbed graph Gp = Gα G(n,p) is obtained by taking a deterministic n-vertex graph Gα = (V, E) with minimum degree δ(G)≥ α n and adding the edges of the binomial random graph G(n,p) defined on the same vertex set V. For which value p (depending on α) does the graph Gp contain a Kr-factor (a spanning collection of vertex-disjoint Kr-copies) with high probability? The order of magnitude of the minimal value of p has been determined whenever α ≠ 1- sr for an integer s (see Han, Morris, and Treglown [RSA, 2021] and Balogh, Treglown, and Wagner [CPC, 2019]). We establish the minimal probability ps (up to a constant factor) for all values of α = 1-sr ≤ 12, and show that the threshold exhibits a polynomial jump at α = 1-sr compared to the surrounding intervals. An extremal example Gα which shows that ps is optimal up to a constant factor differs from the previous (usually multipartite) examples in containing a pseudorandom induced subgraph.
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