Edge spectra of Gaussian random symmetric matrices with correlated entries

Abstract

We study the largest eigenvalue of a Gaussian random symmetric matrix Xn, with zero-mean, unit variance entries satisfying the condition (i, j) (i', j')|E[Xij Xi'j']| = O(n-(1 + )), where > 0. It follows from Catalano et al. (2024) that the empirical spectral distribution of n-1/2 Xn converges weakly almost surely to the standard semi-circle law. Using a F\"uredi-Koml\'os-type high moment analysis, we show that the largest eigenvalue λ1(n-1/2 Xn) of n-1/2 Xn converges almost surely to 2. This result is essentially optimal in the sense that one cannot take = 0 and still obtain an almost sure limit of 2. We also derive Gaussian fluctuation results for the largest eigenvalue in the case where the entries have a common non-zero mean. Let Yn = Xn + λn1 1. When 1 and λ n1/4, we show that \[ n1/2(λ1(n-1/2 Yn) - λ - 1λ) d 2 Z, \] where Z is a standard Gaussian. On the other hand, when 0 < < 1, we have Var(1nΣi, jXij) = O(n1 - ). Assuming that Var(1nΣi, j Xij) = σ2 n1 - (1 + o(1)), if λ n/4, then we have \[ n/2(λ1(n-1/2 Yn) - λ - 1λ) d σ Z. \] While the ranges of λ in these fluctuation results are certainly not optimal, a striking aspect is that different scalings are required in the two regimes 0 < < 1 and 1.