Krahn--Szegő type inequalities and nodal domain methods on graphs

Abstract

We study discrete analogues of classical spectral geometric inequalities and extremal eigenvalue problems on graphs. The classical Krahn--Szegő inequality states that, among bounded open subsets of Rn with fixed volume, the minimum of λ2(Ω) is attained by the union of two congruent balls. Firstly, we establish a Krahn--Szegő type inequality for trees. For trees with a fixed number of interior vertices and boundary leaves, we completely characterize the extremal structures that minimize the second Dirichlet eigenvalue. Secondly, we develop a nodal domain method for adjacency matrices. By proving an adjacency version of the nodal domain theorem for graphs, we obtain upper bounds for the second largest adjacency eigenvalue ρ2(G) of G in given graph classes. These bounds imply some previous results. Finally, we settle the Aouchiche--Hansen conjecture (2010) on the second largest eigenvalue with given number of edges and clique number. We prove that for connected graphs G of odd order n ≥ 5, |ρ2| · ω≤ m-2, with equality if and only if G consists of two complete graphs of orders n+12 and n-12 joined by an edge or a path. For even n ≥ 2, the quantity |ρ2| · ω- m is maximized exactly when G is obtained by adding one edge between the two copies of Kn/2 by an edge. The core of the methods developed in this paper is to regard a connected graph as an internally disconnected graph with Dirichlet boundary condition. This perspective allows us to transfer nodal domain techniques from continuous spectral geometry to discrete settings and to obtain sharp extremal characterizations across diverse graph classes.