Complex Random Matrices have no Real Eigenvalues

Abstract

Let ζ = + i' where , ' are iid copies of a mean zero, variance one, subgaussian random variable. Let Nn be a n × n random matrix with entries that are iid copies of ζ. We prove that there exists a c ∈ (0,1) such that the probability that Nn has any real eigenvalues is less than cn where c only depends on the subgaussian moment of . The bound is optimal up to the value of the constant c. The principal component of the proof is an optimal tail bound on the least singular value of matrices of the form Mn := M + Nn where M is a deterministic complex matrix with the condition that \|M\| ≤ K n1/2 for some constant K depending on the subgaussian moment of . For this class of random variables, this result improves on the results of Pan-Zhou and Rudelson-Vershynin. In the proof of the tail bound, we develop an optimal small-ball probability bound for complex random variables that generalizes the Littlewood-Offord theory developed by Tao-Vu and Rudelson-Vershynin.