English

The top eigenvalue of uniformly random trees

Probability 2024-04-03 v2

Abstract

Let Tn{\mathbf T}_n be a uniformly random tree with vertex set [n]={1,,n}[n]=\{1,\ldots,n\}, let ΔTn\Delta_{{\mathbf T}_n} be the largest vertex degree in Tn{\mathbf T}_n, and let λ1(Tn),,λn(Tn)\lambda_1({\mathbf T}_n),\ldots,\lambda_n({\mathbf T}_n) be the eigenvalues of its adjacency matrix, arranged in decreasing order. We prove that λ1(Tn)ΔTn0|\lambda_1({\mathbf T}_n)-\sqrt{\Delta_{{\mathbf T}_n}}| \to 0 in expectation as nn \to \infty, and additionally prove probability tail bounds for λ1(Tn)ΔTn|\lambda_1({\mathbf T}_n)-\sqrt{\Delta_{{\mathbf T}_n}}|. Writing ana_n for any median of ΔTn\Delta_{{\mathbf T}_n}, we also prove that λk(Tn)an0|\lambda_k({\mathbf T}_n)-\sqrt{a_n}| \to 0 in expectation, uniformly over 1kelogβ(n)1 \le k \le e^{\log^\beta(n)}, for any fixed β(0,1/2)\beta \in (0,1/2). The proof is based on the trace method and thus on counting closed walks in a random tree. To this end, we develop novel combinatorial tools for encoding walks in trees that we expect will find other applications. In order to apply these tools, we show that uniformly random trees -- after appropriate "surgery" -- satisfy, with high probability, the properties required for the combinatorial bounds to be effective.

Keywords

Cite

@article{arxiv.2403.08443,
  title  = {The top eigenvalue of uniformly random trees},
  author = {Louigi Addario-Berry and Gábor Lugosi and Roberto Imbuzeiro Oliveira},
  journal= {arXiv preprint arXiv:2403.08443},
  year   = {2024}
}

Comments

40 pages, 4 figures

R2 v1 2026-06-28T15:18:35.657Z