A concentration inequality and a local law for the sum of two random matrices

Abstract

Let H=A+UBU* where A and B are two N-by-N Hermitian matrices and U is a Haar-distributed random unitary matrix, and let μH, μA, and μB be empirical measures of eigenvalues of matrices H, A, and B, respectively. Then, it is known (see, for example, Pastur-Vasilchuk, CMP, 2000, v.214, pp.249-286) that for large N, measure μH is close to the free convolution of measures μA and μB, where the free convolution is a non-linear operation on probability measures. The large deviations of the cumulative distribution function of μH from its expectation have been studied by Chatterjee in in JFA, 2007, v. 245, pp.379-389. In this paper we improve Chatterjee's concentration inequality and show that it holds with the rate which is quadratic in N. In addition, we prove a local law for eigenvalues of H, by showing that the normalized number of eigenvalues in an interval converges to the density of the free convolution of μA and μB provided that the interval has width (log N)-1/2.