Local Turán inequalities for walks and the spectral radius

Abstract

Nikiforov's well-known spectral Turán inequality for walks states that, for every graph G with clique number ω(G), λr(G) wr(G)(1-1/ω(G)), where λ(G) is the largest eigenvalue of the adjacency matrix of G, and wr(G) is the number of walks with r vertices in G. For r=1, this is Wilf's inequality; for r=2, it gives Nikiforov's spectral Turán theorem. Recently, Liu and Ning proved local versions of these two inequalities, strengthening both Wilf's inequality and Nikiforov's spectral Turán theorem. It is natural to ask whether Nikiforov's spectral Turán inequality for walks also admits a local strengthening. Motivated by this question, Kannan, Kumar, and Pragada conjectured the vertex-local bound λr(G) Σv∈ V(G) wr(v)(1-1/cG(v)), where wr(v) denotes the number of walks with r vertices starting at v, and cG(v) is the maximum order of a clique containing v. This conjecture is important because it gives the most natural local form of Nikiforov's spectral Turán inequality for walks. In this paper, we confirm this conjecture. More precisely, for r 2, we prove the stronger edge-local inequality λr(G) Σuv∈ E(G) cG(uv)-1cG(uv) (wr-1(u)+wr-1(v)), where cG(uv) is the maximum order of a clique containing the edge uv. Our result implies Nikiforov's spectral Turán inequality for walks and unifies several local spectral extremal results of Liu and Ning. We also determine all extremal graphs for both the edge-local and vertex-local inequalities. The main new ingredient is a Markov-chain estimate whose transition matrix is constructed from a Perron vector of A(G); this estimate carries the local edge coefficient through walks of arbitrary length.