Maximum flow and self-avoiding walk on bunkbed graphs

Abstract

We consider two combinatorial models on bunkbed graphs: maximum flow and self-avoiding walks. A bunkbed graph is defined as the Cartesian product G× K2, where G is a finite graph and K2 is the complete graph on two vertices, labelled 0 and 1. For the maximum flow problem, we show that if the bunkbed graph G× K2 has non-negative, reflection-symmetric edge capacities, then for any u, v∈ V(G), the maximum flow strength from (u,0) to (v,0) in G× K2 is at least as large as that from (u,0) to (v,1). For the self-avoiding walk model on a bunkbed graph G× K2, we investigate whether there are more self-avoiding walks from (u,0) to (v,1) than from (u,0) to (v,0). We prove that this holds when G=Kn is a complete graph and n is sufficiently large. Additionally, we provide examples where the statement does not holds and pose the question of whether it remains true when \u,v\ is not a cut-edge of G.

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