Localization of spectral Tur\'an-type theorems
Abstract
Let G be a graph, and let v and e be a vertex and an edge of G, respectively. Define c(v) (resp. c(e)) to be the order of the largest clique in G containing v (resp. e). Denote the adjacency eigenvalues of G by λ1 ·s λn. We study localized refinements of spectral Tur\'an-type theorems by replacing global parameters such as the clique number ω(G), size m and order n of G with local quantities c(v) and c(e). Motivated by a conjecture of Elphick, Linz and Wocjan (2024), we first propose a vertex-localized strengthening of Wilf's inequality: \[ s+(G) Σv∈ V(G)(1-1c(v)), \] where s+(G) = Σλi > 0λi2. Inspired by the Bollob\'as-Nikiforov conjecture (2007) on the first two eigenvalues, we then introduce an edge-localized analogue: \[λ12(G) + λ22(G) Σe∈ E(G) 2(1-1c(e)).\] As evidence of their validity, we verify the above conjectures for diamond-free graphs and random graphs. We also propose strengthening of the spectral versions of the Erdos, Stone and Simonovits Theorem by replacing the spectral radius with s+(G) and establish it for all F-free graphs with (F)=3. A key ingredient in our proofs is a general upper bound relating s+(G) to the triangle count t(G). Finally, we prove a localized version of Nikiforov's walk inequality and conjecture a stronger localized version. These results contribute to the broader program of localizing spectral extremal inequalities.
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