Signless Laplacian spectral conditions: Forbidden 4-cycle and star embeddings

Abstract

The signless Laplacian spectral radius has emerged as a crucial spectral parameter in network science. This paper establishes new extremal results in spectral graph theory by investigating the signless Laplacian spectral radius (Q-index) of graphs with forbidden subgraphs. We present a Q-spectral analog of classical Nosal-type theorems, providing sharp conditions that guarantee the existence of either a 4-cycle or a large star K1,m-k in a graph. The main theorem states that for integers k ≥ 0 and graphs G with size m ≥ \7k+31, k2+8(k+1)\, if q(G) ≥ q(S+m,k+1), then G must contain a 4-cycle or K1,m-k, unless G is isomorphic to the extremal graph S+m,k+1 formed by adding k+1 independent edges to the star K1,m-k-1. This result refines previous work on star embeddings by Wang and Guo [Journal of Algebraic Combinatorics, 59 (2024) 213--224], and completes the Q-spectral counterpart to Wang's adjacency spectral theorem for 4-cycle containment [Discrete Math., 345 (2022) 112973]. Our analysis reveals new insights into how signless Laplacian eigenvalues encode graph structure, with tight bounds demonstrated through explicit extremal graph constructions and asymptotic analysis.