On Spielman's Laplacian Eigenratio Conjecture and Related Problems

Abstract

Let G be an n-vertex graph with Laplacian eigenvalues 0=λ1(G) λ2(G)·s λn(G). Motivated by the Alon-Boppana bound and the Ramanujan phenomenon for regular graphs, Spielman conjectured that, for every graph G with fixed average degree d 1, its Laplacian eigenratio satisfies λ2(G)λn(G) d-2d-1d+2d-1+on(1), where on(1) 0 as n∞. The main purpose of this paper is to investigate this conjecture. We show that the situation is mixed. On the negative side, the conjecture fails for infinitely many average degrees d>2, via constructions based on bipartite Ramanujan graphs. On the positive side, it holds in two important settings: we verify it for all average degrees d 2, and we prove it for all regular graphs. In fact, for regular graphs we obtain stronger bounds comparing higher Laplacian eigenvalues. As a consequence, we show that for every fixed d 3 and every >0, every sufficiently large d-regular Ramanujan graph has linearly many adjacency eigenvalues below -2d-1+, thereby strengthening earlier results of Li and Cioaba by giving an unconditional result of this form. We also settle two related conjectures: one of You and Liu concerning the maximum Laplacian eigenratio of trees, and one of Gu concerning the Hamiltonicity of graphs with large Laplacian eigenratio.