Asymptotic structure. V. The coarse Menger conjecture in bounded path-width

Abstract

Menger's theorem tells us that if S,T are sets of vertices in a graph G, then (for k0) either there are k+1 vertex-disjoint paths between S and T, or there is a set of k vertices separating S and T. But what if we want the paths to be far apart, say at distance at least c? One might hope that we can find either k+1 paths pairwise far apart, or k sets of bounded radius that separate S and T, where the bound on the radius is some that depends only on k,c (the ``coarse Menger conjecture''). The last three authors showed in an earlier paper that this is false for all k 2 and c3, by constructing a sequence of finite graphs giving counterexamples for larger and larger values of with k=2 and c=3. These counterexamples contained subdivisions of uniform binary trees with arbitrarily large depth as subgraphs, and so had unbounded path-width. Here we show that, if H is a graph that can be drawn in the plane such that each region shares a vertex with the infinite region, then the coarse Menger conjecture is true for all graphs not containing H as a minor. Consequently, the conjecture is true for all graphs with bounded path-width (by taking H to be a sufficiently large tree), and it is true for series-parallel graphs (by taking H=K4). The first is somewhat surprising, since the conjecture is false for bounded tree-width.