Universality of a family of Random Matrix Ensembles with logarithmic soft-confinement potentials

Abstract

Recently we introduced a family of U(N) invariant Random Matrix Ensembles which is characterized by a parameter λ describing logarithmic soft-confinement potentials V(H) [ H](1+λ) \:(λ>0). We showed that we can study eigenvalue correlations of these "λ-ensembles" based on the numerical construction of the corresponding orthogonal polynomials with respect to the weight function [- ( x)1+λ]. In this work, we expand our previous work and show that: i) the eigenvalue density is given by a power-law of the form (x) [ x]λ-1/x and ii) the two-level kernel has an anomalous structure, which is characteristic of the critical ensembles. We further show that the anomalous part, or the so-called "ghost-correlation peak", is controlled by the parameter λ; decreasing λ increases the anomaly. We also identify the two-level kernel of the λ-ensembles in the semiclassical regime, which can be written in a sinh-kernel form with more general argument that reduces to that of the critical ensembles for λ=1. Finally, we discuss the universality of the λ-ensembles, which includes Wigner-Dyson universality (λ ∞ limit), the uncorrelated Poisson-like behavior (λ 0 limit), and a critical behavior for all the intermediate λ (0<λ<∞) in the semiclassical regime. We also comment on the implications of our results in the context of the localization-delocalization problems as well as the N dependence of the two-level kernel of the fat-tail random matrices.