Robustness of the Sauer-Spencer Theorem

Abstract

We prove a robust version of a graph embedding theorem of Sauer and Spencer. To state this sparser analogue, we define G(p) to be a random subgraph of G obtained by retaining each edge of G independently with probability p ∈ [0,1], and let m1(H) be the maximum 1-density of a graph H. We show that for any constant and γ > 0, if G is an n-vertex host graph with minimum degree δ(G) ≥ (1 - 1/2 + γ)n and H is an n-vertex graph with maximum degree (H) ≤ , then for p ≥ Cn-1/m1(H) n, the random subgraph G(p) contains a copy of H with high probability. Our value for p is optimal up to a log-factor. In fact, we prove this result for a more general minimum degree condition on G, by introducing an extension threshold δ e(), such that the above result holds for graphs G with δ(G) ≥ (δ e() + γ)n. We show that δ e() ≤ (2-1)/2, and further conjecture that δ e() equals /(+1), which matches the minimum degree condition on G in the Bollob\'as-Eldridge-Catlin Conjecture. A main tool in our proof is a vertex-spread version of the blow-up lemma of Allen, B\"ottcher, H\`an, Kohayakawa, and Person, which we believe to be of independent interest.