Optical Transmission of an Atomic Vapor in the Mesoscopic Regime

T. Peyrot; Y. R.P. Sortais; J. J. Greffet; A. Browaeys; A. Sargsyan; J. Keaveney; I. G. Hughes; C. S. Adams

doi:10.1103/PhysRevLett.122.113401

Optical Transmission of an Atomic Vapor in the Mesoscopic Regime

T. Peyrot
, Y. R.P. Sortais
, J. J. Greffet
, A. Browaeys
, A. Sargsyan
, J. Keaveney
, I. G. Hughes
, C. S. Adams

Université Paris-Sud
Institute for Physical Research National Academy of Sciences of Armenia
Durham University

Résultats de recherche: Contribution à un journal › Article › Revue par des pairs

Résumé

By measuring the transmission of near-resonant light through an atomic vapor confined in a nanocell we demonstrate a mesoscopic optical response arising from the nonlocality induced by the motion of atoms with a phase coherence length larger than the cell thickness. Whereas conventional dispersion theory - where the local atomic response is simply convolved by the Maxwell-Boltzmann velocity distribution - is unable to reproduce the measured spectra, a model including a nonlocal, size-dependent susceptibility is found to be in excellent agreement with the measurements. This result improves our understanding of light-matter interaction in the mesoscopic regime and has implications for applications where mesoscopic effects may degrade or enhance the performance of miniaturized atomic sensors.

langue originale	Anglais
Numéro d'article	113401
journal	Physical Review Letters
Volume	122
Numéro de publication	11
Les DOIs	https://doi.org/10.1103/PhysRevLett.122.113401
état	Publié - 20 mars 2019
Modification externe	Oui

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10.1103/PhysRevLett.122.113401

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title = "Optical Transmission of an Atomic Vapor in the Mesoscopic Regime",

abstract = "By measuring the transmission of near-resonant light through an atomic vapor confined in a nanocell we demonstrate a mesoscopic optical response arising from the nonlocality induced by the motion of atoms with a phase coherence length larger than the cell thickness. Whereas conventional dispersion theory - where the local atomic response is simply convolved by the Maxwell-Boltzmann velocity distribution - is unable to reproduce the measured spectra, a model including a nonlocal, size-dependent susceptibility is found to be in excellent agreement with the measurements. This result improves our understanding of light-matter interaction in the mesoscopic regime and has implications for applications where mesoscopic effects may degrade or enhance the performance of miniaturized atomic sensors.",

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AU - Peyrot, T.

AU - Sortais, Y. R.P.

AU - Greffet, J. J.

AU - Browaeys, A.

AU - Sargsyan, A.

AU - Keaveney, J.

AU - Hughes, I. G.

AU - Adams, C. S.

PY - 2019/3/20

Y1 - 2019/3/20

N2 - By measuring the transmission of near-resonant light through an atomic vapor confined in a nanocell we demonstrate a mesoscopic optical response arising from the nonlocality induced by the motion of atoms with a phase coherence length larger than the cell thickness. Whereas conventional dispersion theory - where the local atomic response is simply convolved by the Maxwell-Boltzmann velocity distribution - is unable to reproduce the measured spectra, a model including a nonlocal, size-dependent susceptibility is found to be in excellent agreement with the measurements. This result improves our understanding of light-matter interaction in the mesoscopic regime and has implications for applications where mesoscopic effects may degrade or enhance the performance of miniaturized atomic sensors.

AB - By measuring the transmission of near-resonant light through an atomic vapor confined in a nanocell we demonstrate a mesoscopic optical response arising from the nonlocality induced by the motion of atoms with a phase coherence length larger than the cell thickness. Whereas conventional dispersion theory - where the local atomic response is simply convolved by the Maxwell-Boltzmann velocity distribution - is unable to reproduce the measured spectra, a model including a nonlocal, size-dependent susceptibility is found to be in excellent agreement with the measurements. This result improves our understanding of light-matter interaction in the mesoscopic regime and has implications for applications where mesoscopic effects may degrade or enhance the performance of miniaturized atomic sensors.

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VL - 122

JO - Physical Review Letters

JF - Physical Review Letters

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ER -

Optical Transmission of an Atomic Vapor in the Mesoscopic Regime

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