Coarse Menger property of quasi-minor excluded graphs and length spaces

Abstract

Menger's theorem is an important building block of numerous results in the study of graph structure. We consider a variant in terms of coarse geometry. We say that a set of graphs has the weak coarse Menger property if there exist functions f and g such that for any graph G in this set, subsets X and Y of vertices of G, and positive integers k and r, either there exist k paths between X and Y pairwise at distance at least r, or there exists a union of at most f(k,r) balls of radius at most g(k,r) intersecting all paths between X and Y. Nguyen, Scott and Seymour proved that the set of all graphs does not have the weak coarse Menger property and asked whether every proper minor-closed family of finite graphs has it. In this paper, we provide a positive answer to this question in a stronger form: it is true for the set of locally finite graphs with an excluded finite minor, and the functions f and g can be chosen so that f only depends on the number k of the paths in the packing and the function g is a linear function of the distance threshold r and is independent of k, which is optimal up to a constant factor. Our result extends to every length space quasi-isometric to a locally finite graph or metric graph with an excluded finite minor, such as complete Riemannian surfaces of finite Euler genus, string graphs, and Cayley graphs of finitely generated minor-excluded groups.