Non-Gaussian Correlations in the Steady State of Driven-Dissipative Clouds of Two-Level Atoms

Giovanni Ferioli; Sara Pancaldi; Antoine Glicenstein; David Clément; Antoine Browaeys; Igor Ferrier-Barbut

doi:10.1103/PhysRevLett.132.133601

Non-Gaussian Correlations in the Steady State of Driven-Dissipative Clouds of Two-Level Atoms

Giovanni Ferioli, Sara Pancaldi, Antoine Glicenstein, David Clément, Antoine Browaeys, Igor Ferrier-Barbut

Laboratoire Charles Fabry

Research output: Contribution to journal › Article › peer-review

Abstract

We report experimental measurements of the second-order coherence function g(2)(τ) of the light emitted by a laser-driven dense ensemble of Rb87 atoms. We observe a clear departure from the Siegert relation valid for Gaussian chaotic light. Measuring intensity and first-order coherence, we conclude that the violation is not due to the emergence of a coherent field. This indicates that the light obeys non-Gaussian statistics, stemming from non-Gaussian correlations in the atomic medium. More specifically, the steady state of this driven-dissipative many-body system sustains high-order correlations in the absence of first-order coherence. These findings call for new theoretical and experimental explorations to uncover their origin, and they open new perspectives for the realization of non-Gaussian states of light.

Original language	English
Article number	133601
Journal	Physical Review Letters
Volume	132
Issue number	13
DOIs	https://doi.org/10.1103/PhysRevLett.132.133601
Publication status	Published - 29 Mar 2024
Externally published	Yes

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title = "Non-Gaussian Correlations in the Steady State of Driven-Dissipative Clouds of Two-Level Atoms",

abstract = "We report experimental measurements of the second-order coherence function g(2)(τ) of the light emitted by a laser-driven dense ensemble of Rb87 atoms. We observe a clear departure from the Siegert relation valid for Gaussian chaotic light. Measuring intensity and first-order coherence, we conclude that the violation is not due to the emergence of a coherent field. This indicates that the light obeys non-Gaussian statistics, stemming from non-Gaussian correlations in the atomic medium. More specifically, the steady state of this driven-dissipative many-body system sustains high-order correlations in the absence of first-order coherence. These findings call for new theoretical and experimental explorations to uncover their origin, and they open new perspectives for the realization of non-Gaussian states of light.",

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AU - Pancaldi, Sara

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AU - Clément, David

AU - Browaeys, Antoine

AU - Ferrier-Barbut, Igor

PY - 2024/3/29

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AB - We report experimental measurements of the second-order coherence function g(2)(τ) of the light emitted by a laser-driven dense ensemble of Rb87 atoms. We observe a clear departure from the Siegert relation valid for Gaussian chaotic light. Measuring intensity and first-order coherence, we conclude that the violation is not due to the emergence of a coherent field. This indicates that the light obeys non-Gaussian statistics, stemming from non-Gaussian correlations in the atomic medium. More specifically, the steady state of this driven-dissipative many-body system sustains high-order correlations in the absence of first-order coherence. These findings call for new theoretical and experimental explorations to uncover their origin, and they open new perspectives for the realization of non-Gaussian states of light.

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Non-Gaussian Correlations in the Steady State of Driven-Dissipative Clouds of Two-Level Atoms

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