Light scattering from dense cold atomic media

TL;DR

This paper presents theoretical models for light scattering in dense cold atomic media, analyzing how motion, density, and polarization affect emitted light, with implications for quantum systems and experimental setups.

Contribution

It introduces two microscopic models for light scattering in cold atomic media and extends them to include atomic motion effects, enhancing understanding of collective light behavior.

Findings

Atomic motion causes dephasing and reduces collective effects.

Models accurately predict linewidth, intensity, and line center of scattered light.

Results applicable to atomic clocks, quantum simulators, and nanophotonics.

Abstract

We theoretically study the propagation of light through a cold atomic medium, where the effects of motion, laser intensity, atomic density, and polarization can all modify the properties of the scattered light. We present two different microscopic models: the "coherent dipole model" and the "random walk model", both suitable for modeling recent experimental work done in large atomic arrays in the low light intensity regime. We use them to compute relevant observables such as the linewidth, peak intensity and line center of the emitted light. We further develop generalized models that explicitly take into account atomic motion. Those are relevant for hotter atoms and beyond the low intensity regime. We show that atomic motion can lead to drastic dephasing and to a reduction of collective effects, together with a distortion of the lineshape. Our results are applicable to model a full gamut of quantum systems that rely on atom-light interactions including atomic clocks, quantum simulators and nanophotonic systems.