Deviation probabilities and Sharp Berry-Esseen bound for rightmost eigenvalue of large non-Hermitian chiral random matrices

Abstract

This paper provides a quantitative analysis of the rightmost eigenvalue for a chiral non-Hermitian random Dirac matrix in the maximally non-Hermitian regime (τ=0). Let (σi)1 i n be the eigenvalues with positive real part. We define the normalization constants \[ sn = 4n(n+v)2n+v, γn = 12 sn - 54( sn) - (21/4π), \] and the centered and scaled variable \[ Xn = 2sn sn\,((nn+v)1/4\,1 i nσi \;-\; 1 \;-\; γn2sn sn). \] Our main result is the following sharp Berry--Esseen bound for the convergence of Xn to the Gumbel distribution: \[ x ∈ R |P(Xn x) - e-e-x| = 25 ( sn)216 e \, sn\,(1 + o(1)), \] which holds as n ∞ for an arbitrary parameter v 0 (which may depend on n). As a byproduct of our analysis, we also obtain precise large- and moderate-deviation principles for the scaled rightmost eigenvalue (nn+v)1/4 1 i nσi, characterizing its rate of convergence to the value 1.