Large Minors in Expanders

Abstract

In this paper we study expander graphs and their minors. Specifically, we attempt to answer the following question: what is the largest function f(n,α,d), such that every n-vertex α-expander with maximum vertex degree at most d contains every graph H with at most f(n,α,d) edges and vertices as a minor? Our main result is that there is some universal constant c, such that f(n,α,d)≥ nc n· (αd )c. This bound achieves a tight dependence on n: it is well known that there are bounded-degree n-vertex expanders, that do not contain any grid with (n/ n) vertices and edges as a minor. The best previous result showed that f(n,α,d) ≥ (n/n), where depends on both α and d. Additionally, we provide a randomized algorithm, that, given an n-vertex α-expander with maximum vertex degree at most d, and another graph H containing at most nc n· (αd )c vertices and edges, with high probability finds a model of H in G, in time poly(n)· (d/α)O( (d/α) ). We note that similar but stronger results were independently obtained by Krivelevich and Nenadov: they show that f(n,α,d)= (nα2d2 n ), and provide an efficient algorithm, that, given an n-vertex α-expander of maximum vertex degree at most d, and a graph H with O( nα2d2 n ) vertices and edges, finds a model of H in G. Finally, we observe that expanders are the `most minor-rich' family of graphs in the following sense: for every n-vertex and m-edge graph G, there exists a graph H with O ( n+m n ) vertices and edges, such that H is not a minor of G.