Minimally (k,k)-edge-connected graphs via spectral radius

Abstract

For l > 1, the l-edge-connectivity κ'l(G) of a connected graph G is defined as the minimum number of edges whose removal leaves a graph with at least l components. A graph is minimally (k,l)-edge-connected if κ'l(G)≥ k but for any edge e∈ E(G) satisfies that κ'l(G-e)< k. Motivated by two foundational extremal problems: Brualdi and Solheid's problem [SIAM J. Algebra Discrete Methods (1986)] for graphs of fixed order: determine sharp upper bounds for the spectral radius over graph families and characterize extremal graphs; and its fixed size analogue proposed by Brualdi and Hoffman [Linear Algebra Appl. (1985)], we resolve both problems for minimally (k,k)-edge-connected graphs. Building on the structural framework of Hennayake, Lai, Li, and Mao [J. Graph Theory (2003)], we combine edge-switching method and double eigenvectors skill to characterize the graphs maximizing the spectral radius among all minimally (k,k)-edge-connected graphs of prescribed order or size. Our results generalize the k=2 cases established by Lou, Min, and Huang [Electron. J. Comb. (2023)] and Chen and Guo [Discrete Math. (2019)].