Quantitative Edge Eigenvector Universality for Random Regular Graphs: Berry-Esseen Bounds with Explicit Constants

Abstract

We establish the first quantitative Berry-Esseen bounds for edge eigenvector statistics in random regular graphs. For any d-regular graph on N vertices with fixed d ≥ 3 and deterministic unit vector q e, we prove that the normalized overlap N q, u2 satisfies \[ x ∈ R |P(N q, u2 ≤ x) - (x)| ≤ Cd N-1/6+ \] where u2 is the second eigenvector and Cd ≤ Cd3-10 for an absolute constant C. This provides the first explicit convergence rate for the recent edge eigenvector universality results of He, Huang, and Yau HHY25. Our proof introduces a single-scale comparison method using constrained Dyson Brownian motion that preserves the degree constraint Hte = 0 throughout the evolution. The key technical innovation is a sharp edge isotropic local law with explicit constant C(d,) ≤ Cd-5, enabling precise control of eigenvector overlap dynamics. At the critical time t* = N-1/3+, we perform a fourth-order cumulant comparison with constrained GOE, achieving optimal error bounds through a single comparison rather than the traditional multi-scale approach. We extend our results to joint universality for the top K edge eigenvectors with K ≤ N1/10-δ, showing they converge to independent Gaussians. Through analysis of eigenvalue spacing barriers, critical time scales, and comparison across multiple proof methods, we provide evidence that the N-1/6 rate is optimal for sparse regular graphs. All constants are tracked explicitly throughout, enabling finite-size applications in spectral algorithms and network analysis.