Expanders Are Universal for the Class of All Spanning Trees

Abstract

Given a class of graphs F, we say that a graph G is universal for F, or F-universal, if every H in F is contained in G as a subgraph. The construction of sparse universal graphs for various families F has received a considerable amount of attention. One is particularly interested in tight F-universal graphs, i.e., graphs whose number of vertices is equal to the largest number of vertices in a graph from F. Arguably, the most studied case is that when F is some class of trees. Given integers n and , we denote by T(n,) the class of all n-vertex trees with maximum degree at most . In this work, we show that every n-vertex graph satisfying certain natural expansion properties is T(n,)-universal or, in other words, contains every spanning tree of maximum degree at most . Our methods also apply to the case when is some function of n. The result has a few very interesting implications. Most importantly, we obtain that the random graph G(n,p) is asymptotically almost surely (a.a.s.) universal for the class of all bounded degree spanning (i.e., n-vertex) trees provided that p ≥ c n-1/3 2n where c > 0 is a constant. Moreover, a corresponding result holds for the random regular graph of degree pn. In fact, we show that if satisfies n ≤ ≤ n1/3, then the random graph G(n,p) with p ≥ c n-1/3 n and the random r-regular n-vertex graph with r ≥ c n2/3 n are a.a.s. T(n,)-universal. Another interesting consequence is the existence of locally sparse n-vertex T(n,)-universal graphs. For constant , we show that one can (randomly) construct n-vertex T(n,)-universal graphs with clique number at most five. Finally, we show robustness of random graphs with respect to being universal for T(n,) in the context of the Maker-Breaker tree-universality game.