A coarse Menger's Theorem for planar and bounded genus graphs

Abstract

Menger's Theorem is a fundamental result in graph theory. It states that if in a graph G with distinguished sets of terminal vertices S and T there are no k pairwise vertex-disjoint S-T paths, then there is a set of less than k vertices that intersects every S-T path. In this work, we give a coarse variant of this result for planar and bounded genus graphs. Precisely, we prove that for every surface there is a function f N× N N such that for every pair of integers d,k∈ N and a -embeddable graph G with distinguished sets of terminal vertices S and T, if G does not contain a family of k S-T paths that are pairwise at distance larger than d, then there is a set X consisting of at most f(d,k) vertices of G such that every S-T path is at distance at most d from a vertex of X. This partially answers questions of Nguyen, Scott, and Seymour [arXiv:2508.14332], who proved that such a result cannot hold in general graphs. A key ingredient of our proof is a structure theorem from the developing ''colorful'' graph minor theory, where the focus is on studying the structure in a graph relative to some fixed subsets of annotated vertices. In our case, these annotated vertices are S and T.