Strong spectral stabilities for C2k+1-free graphs

Abstract

A stability result due to Ren, Wang, Wang and Yang [SIAM J. Discrete Math. 38 (2024)] shows that if 3 r 2k and n 318 (r-2)2k, and G is a C2k+1-free graph on n vertices with e(G) (n-r+1)2/4 +r 2, then G can be made bipartite by deleting at most r-2 vertices. Using a different method, we give a linear bound on n in terms of k and show a stronger structural result, which roughly says that G can be obtained from a large bipartite graph by suspending some small graphs that the total number of vertices is at most r-2. This improves a result of Yan and Peng (2024) by weakening the requirement on n and k. As a direct corollary, we obtain a tight upper bound on the size of an n-vertex C2k+1-free graph with chromatic number (G) r for every r 2k. The second part of this paper concerns the spectral extremal problem for C2k+1-free graphs. We denote by λ (G) the spectral radius of the adjacency matrix of a graph G. Let Tn-r+1,2 Kr be the graph obtained by identifying a vertex of the complete graph Kr and a vertex of the smaller partite set of the bipartite Tur\'an graph Tn-r+1 ,2. Using the spectral techniques, we prove that if 3 r 2k and n 712k, and G is an n-vertex C2k+1-free graph with chromatic number (G) r, then λ (G) λ (Tn-r+1,2 Kr), where the equality holds if and only if G=Tn-r+1,2 Kr. Our result not only extends a result of Guo, Lin and Zhao [Linear Algebra Appl. 627 (2021)] as well as a result of Zhang and Zhao [Discrete Math. 346 (2023)], but also provides the first solution to the spectral extremal problem for F-free graphs with high chromatic number.