English

Optimal Eigenvalue Rigidity of Random Regular Graphs

Probability 2024-05-21 v1

Abstract

Consider the normalized adjacency matrices of random dd-regular graphs on NN vertices with fixed degree d3d\geq 3, and denote the eigenvalues as λ1=d/d1λ2λ3λN\lambda_1=d/\sqrt{d-1}\geq \lambda_2\geq\lambda_3\cdots\geq \lambda_N. We prove that the optimal (up to an extra NoN(1)N^{{\rm o}_N(1)} factor, where oN(1){\rm o}_N(1) can be arbitrarily small) eigenvalue rigidity holds. More precisely, denote γi\gamma_i as the classical location of the ii-th eigenvalue under the Kesten-Mckay law in decreasing order. Then with probability 1N1+oN(1)1-N^{-1+{\rm o}_N(1)}, \begin{align*} |\lambda_i-\gamma_i|\leq \frac{N^{{\rm o}_N(1)}}{N^{2/3} (\min\{i,N-i+1\})^{1/3}},\quad \text{ for all } i\in \{2,3,\cdots,N\}. \end{align*} In particular, the fluctuations of extreme eigenvalues are bounded by N2/3+oN(1)N^{-2/3+{\rm o}_N(1)}. This gives the same order of fluctuation as for the eigenvalues of matrices from the Gaussian Orthogonal Ensemble.

Keywords

Cite

@article{arxiv.2405.12161,
  title  = {Optimal Eigenvalue Rigidity of Random Regular Graphs},
  author = {Jiaoyang Huang and Theo McKenzie and Horng-Tzer Yau},
  journal= {arXiv preprint arXiv:2405.12161},
  year   = {2024}
}

Comments

62 pages, 2 figures

R2 v1 2026-06-28T16:33:18.565Z