Phase transitions and edge scaling of number variance in Gaussian random matrices

Abstract

We consider N× N Gaussian random matrices, whose average density of eigenvalues has the Wigner semi-circle form over [-2,2]. For such matrices, using a Coulomb gas technique, we compute the large N behavior of the probability P N,L(NL) that NL eigenvalues lie within the box [-L,L]. This probability scales as P N,L(NL=L N)≈(-β N2 L(L)), where β is the Dyson index of the ensemble and L(L) is a β-independent rate function that we compute exactly. We identify three regimes as L is varied: (i) \, N-1 L<2 (bulk), (ii) \ L2 on a scale of O(N-2/3) (edge) and (iii) \ L > 2 (tail). We find a dramatic non-monotonic behavior of the number variance VN(L) as a function of L: after a logarithmic growth (N L) in the bulk (when L O(1/N)), VN(L) decreases abruptly as L approaches the edge of the semi-circle before it decays as a stretched exponential for L > 2. This "drop-off" of VN(L) at the edge is described by a scaling function Vβ which smoothly interpolates between the bulk (i) and the tail (iii). For β = 2 we compute V2 explicitly in terms of the Airy kernel. These analytical results, verified by numerical simulations, directly provide for β=2 the full statistics of particle-number fluctuations at zero temperature of 1d spinless fermions in a harmonic trap.