Emergence of second-order coherence in the superradiant emission from a free-space atomic ensemble

TL;DR

This paper studies how second-order coherence develops during superradiant emission from a cold atomic ensemble, revealing the emergence of correlations and subradiant effects beyond traditional models.

Contribution

It provides experimental measurements of second-order coherence dynamics in superradiance and compares results with the Dicke model, highlighting finite size and subradiant effects.

Findings

Second-order coherence emerges during the superradiant burst.

The Dicke model captures early-time behavior but not long-time subradiance.

Anti-correlations appear during the burst when starting from an excited state.

Abstract

We investigate the evolution of the second-order temporal coherence during the emission of a superradiant burst by an elongated cloud of cold Rb atoms in free space. To do so, we measure the two-times intensity correlation function $g_N^{(2)}(t_1, t_2)$ following the pulsed excitation of the cloud. By monitoring $g_N^{(2)}(t, t)$ during the burst, we observe the establishment of second-order coherence, and contrast it with the situation where the cloud is initially prepared in a steady state. We compare our findings to the predictions of the Dicke model, using an effective atom number to account for finite size effects, finding that the model reproduces the observed trend at early time. For longer times, we observe a subradiant decay, a feature that goes beyond Dicke's model. Finally, we measure the $g_N^{(2)}(t_1, t_2)$ at different times and observe the appearance of anti-correlations during the burst, that are not present when starting from a steady state.