A Closure Lemma for tough graphs and Hamiltonian degree conditions

Abstract

The closure of a graph G is the graph G* obtained from G by repeatedly adding edges between pairs of non-adjacent vertices whose degree sum is at least n, where n is the number of vertices of G. The well-known Closure Lemma proved by Bondy and Chv\'atal states that a graph G is Hamiltonian if and only if its closure G* is. This lemma can be used to prove several classical results in Hamiltonian graph theory. We prove a version of the Closure Lemma for tough graphs. A graph G is t-tough if for any set S of vertices of G, the number of components of G-S is at most t |S|. A Hamiltonian graph must necessarily be 1-tough. Conversely, Chv\'atal conjectured that there exists a constant t such that every t-tough graph is Hamiltonian. The t-closure of a graph G is the graph Gt* obtained from G by repeatedly adding edges between pairs of non-adjacent vertices whose degree sum is at least n-t. We prove that, for t≥ 2, a 3t-12-tough graph G is Hamiltonian if and only if its t-closure Gt* is. Ho\`ang conjectured the following: Let G be a graph with degree sequence d1 ≤ d2 ≤ … ≤ dn; then G is Hamiltonian if G is t-tough and, ∀ i <n2, if di≤ i then dn-i+t≥ n-i. This conjecture is analogous to the well known theorem of Chv\'atal on Hamiltonian ideals. Ho\`ang proved the conjecture for t ≤ 3. Using the closure lemma for tough graphs, we prove the conjecture for t = 4.