Sharp Square Root Bounds for Edge Eigenvector Universality in Sparse Random Regular Graphs

Abstract

We study how eigenvectors of random regular graphs behave when projected onto fixed directions. For a random d-regular graph with N vertices, where the degree d grows slowly with N, we prove that these projections follow approximately normal distributions. Our main result establishes a Berry-Esseen bound showing convergence to the Gaussian with error O(d · N-1/6+) for degrees d ≤ N1/4. This bound significantly improves upon previous results that had error terms scaling as d3, and we prove our d scaling is optimal by establishing a matching lower bound. Our proof combines three techniques: (1) refined concentration inequalities that exploit the specific variance structure of regular graphs, (2) a vector-based analysis of the resolvent that avoids iterative procedures, and (3) a framework combining Stein's method with graph-theoretic tools to control higher-order fluctuations. These results provide sharp constants for eigenvector universality in the transition from sparse to moderately dense graphs.