Spin-noise spectroscopy of optical light shifts

J. Delpy; S. Liu; P. Neveu; E. Wu; F. Bretenaker; F. Goldfarb

doi:10.1103/PhysRevA.107.L011701

Spin-noise spectroscopy of optical light shifts

J. Delpy
, S. Liu
, P. Neveu
, E. Wu
, F. Bretenaker
, F. Goldfarb

ENS Paris-Saclay
State Key Laboratory of Precision Spectroscopy
Institut Universitaire de France

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

Abstract

Light-induced nonequilibrium spin-noise spectroscopy is theoretically and experimentally shown to be an efficient technique to reveal the structure and coherent effects in a probed transition. Indeed, using metastable helium, the spin-noise spectrum is shown to exhibit a dual-peak structure around the Larmor frequency. This feature is due to the light shifts of the involved levels and strongly depends on the probe power, detuning, and polarization orientation. Both numerical and analytical models reproduce very well the details of the split spin-noise spectra: This technique thus allows a simple and direct measurement of the light shifts, and its polarization dependence permits to reveal the level structure in a nonambiguous manner.

Original language	English
Article number	L011701
Journal	Physical Review A
Volume	107
Issue number	1
DOIs	https://doi.org/10.1103/PhysRevA.107.L011701
Publication status	Published - 1 Jan 2023
Externally published	Yes

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title = "Spin-noise spectroscopy of optical light shifts",

abstract = "Light-induced nonequilibrium spin-noise spectroscopy is theoretically and experimentally shown to be an efficient technique to reveal the structure and coherent effects in a probed transition. Indeed, using metastable helium, the spin-noise spectrum is shown to exhibit a dual-peak structure around the Larmor frequency. This feature is due to the light shifts of the involved levels and strongly depends on the probe power, detuning, and polarization orientation. Both numerical and analytical models reproduce very well the details of the split spin-noise spectra: This technique thus allows a simple and direct measurement of the light shifts, and its polarization dependence permits to reveal the level structure in a nonambiguous manner.",

author = "J. Delpy and S. Liu and P. Neveu and E. Wu and F. Bretenaker and F. Goldfarb",

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T1 - Spin-noise spectroscopy of optical light shifts

AU - Delpy, J.

AU - Liu, S.

AU - Neveu, P.

AU - Wu, E.

AU - Bretenaker, F.

AU - Goldfarb, F.

PY - 2023/1/1

Y1 - 2023/1/1

N2 - Light-induced nonequilibrium spin-noise spectroscopy is theoretically and experimentally shown to be an efficient technique to reveal the structure and coherent effects in a probed transition. Indeed, using metastable helium, the spin-noise spectrum is shown to exhibit a dual-peak structure around the Larmor frequency. This feature is due to the light shifts of the involved levels and strongly depends on the probe power, detuning, and polarization orientation. Both numerical and analytical models reproduce very well the details of the split spin-noise spectra: This technique thus allows a simple and direct measurement of the light shifts, and its polarization dependence permits to reveal the level structure in a nonambiguous manner.

AB - Light-induced nonequilibrium spin-noise spectroscopy is theoretically and experimentally shown to be an efficient technique to reveal the structure and coherent effects in a probed transition. Indeed, using metastable helium, the spin-noise spectrum is shown to exhibit a dual-peak structure around the Larmor frequency. This feature is due to the light shifts of the involved levels and strongly depends on the probe power, detuning, and polarization orientation. Both numerical and analytical models reproduce very well the details of the split spin-noise spectra: This technique thus allows a simple and direct measurement of the light shifts, and its polarization dependence permits to reveal the level structure in a nonambiguous manner.

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DO - 10.1103/PhysRevA.107.L011701

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JO - Physical Review A

JF - Physical Review A

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Spin-noise spectroscopy of optical light shifts

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