Cooperative photon emission rates in random atomic clouds

Description

We investigate a family of $N\times N$ Euclidean random matrices $S$, whose entries are $\operatorname{sinc}$ functions of the distance between points independently sampled from a Gaussian distribution in three dimensions. This random matrix model arises in the study of cooperative photon emission rates of a random atomic cloud, initially excited by a laser in the linear regime. The spectral properties of $S$, in the large-$N$ limit, strongly depend on the atomic cloud density. We show that in the low-density regime the eigenvalue density of $S$ has a nontrivial limit that only depends on the so-called cooperativeness parameter $b_0$, the only parameter of the model. For small values $b_0\ll1$, we find that the limit eigenvalue density is approximatively triangular. We also study the nearest-neighbour spacing distribution and the eigenvector statistics. We find that, although $S$ is a Euclidean random matrix, the bulk of its spectrum is described by classical random matrix theory. In particular, in the bulk there is level repulsion and the eigenvectors are delocalized. Therefore, the bulk of the spectrum of $S$ exhibits the universal behaviour of chaotic quantum systems.

Abstract

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