English

Spectral skeletons and applications

Combinatorics 2025-03-17 v2

Abstract

For a graph GG, its spectral radius ρ(G)\rho(G) is the largest eigenvalue of its adjacency matrix. Let F\mathcal{F} be a finite family of graphs with minFFχ(F)=r+13\min_{F\in \mathcal{F}}\chi(F)=r+1\geq3, where χ(F)\chi(F) is the chromatic number of FF. Set t=maxFFFt=\max_{F\in\mathcal{F}}|F|. Let T(rt,r)T(rt,r) be the Tur\'{a}n graph of order rtrt with rr parts. Assume that some F0FF_{0}\subseteq\mathcal{F} is a subgraph of the graph obtained from T(rt,r)T(rt,r) by embedding a path or a matching in one part. Let EX(n,F){\rm EX}(n,\mathcal{F}) be the set of graphs with the maximum number of edges among all the graphs of order nn containing not any FFF\in\mathcal{F}. Simonovits \cite{S1,S2} gave general results on the graphs in EX(n,F){\rm EX}(n,\mathcal{F}). Let SPEX(n,F){\rm SPEX}(n,\mathcal{F}) be the set of graphs with the maximum spectral radius among all the graphs of order nn containing not any FFF\in\mathcal{F}. Motivated by the work of Simonovits, we characterize the specified structure of the graphs in SPEX(n,F){\rm SPEX}(n,\mathcal{F}) in this paper. Moreover, some applications are also included.

Keywords

Cite

@article{arxiv.2501.14218,
  title  = {Spectral skeletons and applications},
  author = {Wenqian Zhang},
  journal= {arXiv preprint arXiv:2501.14218},
  year   = {2025}
}
R2 v1 2026-06-28T21:15:43.189Z