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Main Authors: Asselie, S., Nazon, J. -M., Caldani, R., Roux-Spitz, C., Guerin, W.
Format: Preprint
Published: 2025
Subjects:
Online Access:https://arxiv.org/abs/2505.19930
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author Asselie, S.
Nazon, J. -M.
Caldani, R.
Roux-Spitz, C.
Guerin, W.
author_facet Asselie, S.
Nazon, J. -M.
Caldani, R.
Roux-Spitz, C.
Guerin, W.
contents We study the temporal dynamics of light interacting with a one-dimensional lattice of cold atoms. In such a system, a photonic band gap opens up, yielding an efficient Bragg reflection for an incident field incoming with the right angle and detuning. Here, we report two new effects appearing in the Bragg reflection. First, for some detunings, there is a ``flash'', i.e., a transient increase of the reflected intensity when the incident field is switched off. Second, the subsequent extinction of the reflected field is clearly superradiant, with decay rates up to height times the natural decay rate of the atomic excited state. Numerical simulations are in qualitative agreement with the observations, which can be explained by a classical photonic model. Our results are a step towards exploiting this photonic band gap in atomic systems for quantum-optical applications.
format Preprint
id arxiv_https___arxiv_org_abs_2505_19930
institution arXiv
publishDate 2025
record_format arxiv
spellingShingle Temporal dynamics in the Bragg reflection of light by cold atoms: flash effect and superradiant decay
Asselie, S.
Nazon, J. -M.
Caldani, R.
Roux-Spitz, C.
Guerin, W.
Atomic Physics
Optics
Quantum Physics
We study the temporal dynamics of light interacting with a one-dimensional lattice of cold atoms. In such a system, a photonic band gap opens up, yielding an efficient Bragg reflection for an incident field incoming with the right angle and detuning. Here, we report two new effects appearing in the Bragg reflection. First, for some detunings, there is a ``flash'', i.e., a transient increase of the reflected intensity when the incident field is switched off. Second, the subsequent extinction of the reflected field is clearly superradiant, with decay rates up to height times the natural decay rate of the atomic excited state. Numerical simulations are in qualitative agreement with the observations, which can be explained by a classical photonic model. Our results are a step towards exploiting this photonic band gap in atomic systems for quantum-optical applications.
title Temporal dynamics in the Bragg reflection of light by cold atoms: flash effect and superradiant decay
topic Atomic Physics
Optics
Quantum Physics
url https://arxiv.org/abs/2505.19930