Spectral extremal problems for non-bipartite graphs without odd cycles

Abstract

A well-known result of Mantel asserts that every n-vertex triangle-free graph G has at most n2/4 edges. Moreover, Erdos proved that if G is further non-bipartite, then e(G) (n-1)2/4 +1. Recently, Lin, Ning and Wu [Combin. Probab. Comput. 30 (2021)] established a spectral version by showing that if G is a triangle-free non-bipartite graph on n vertices, then λ (G) λ (S1(Tn-1,2)), with equality if and only if G=S1(Tn-1,2), where S1(Tn-1,2) is obtained from Tn-1,2 by subdividing an edge. In this paper, we investigate the maximum spectral radius of a non-bipartite graph without some short odd cycles. Let C2 +1(Tn-2, 2) be the graph obtained by identifying a vertex of C2+1 and a vertex of the smaller partite set of Tn-2 ,2. We prove that for 1 < k and n 187k, if G is an n-vertex \C3,… ,C2 -1,C2k+1\-free non-bipartite graph, then λ (G) λ (C2 +1(Tn-2, 2)), with equality if and only if G=C2 +1(Tn-2, 2). This result could be viewed as a spectral analogue of a min-degree result due to Yuan and Peng [European J. Combin. 127 (2025)]. Moreover, our result extends a result of Guo, Lin and Zhao [Linear Algebra Appl. 627 (2021)] as well as a recent result of Zhang and Zhao [Discrete Math. 346 (2023)] since we can get rid of the condition that n is sufficiently large. The argument in our proof is quite different and makes use of the classical spectral stability method and the double-eigenvector technique. The main innovation lies in a more clever argument that guarantees a subgraph to be bipartite after removing few vertices, which may be of independent interest.