2023
DOI: 10.1088/1367-2630/acbc40
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A practical guide to electromagnetically induced transparency in atomic vapor

Abstract: This tutorial introduces the theoretical and experimental basics of Electromagnetically Induced Transparency (EIT) in thermal alkali vapors. We first give a brief phenomenological description of EIT in simple three-level systems of stationary atoms and derive analytical expressions for optical absorption and dispersion under EIT conditions. Then we focus on how the thermal motion of atoms affects various parameters of the EIT system. Specifically, we analyze the Doppler broadening of optical transitions, balli… Show more

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Cited by 39 publications
(29 citation statements)
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“…Therefore, D is of the order of a fraction of MHz. The typical microwave sources used in EIT experiments have linewidth in the range between a few hundred kHz to 2 MHz [36], which is of the same order as D. In such a situation, one may consider using an indirect pump to improve the Talbot peak intensities. Similarly, the Rabi frequency of the control field must also be optimized to obtain maximum peak intensities.…”
Section: Resultsmentioning
confidence: 99%
“…Therefore, D is of the order of a fraction of MHz. The typical microwave sources used in EIT experiments have linewidth in the range between a few hundred kHz to 2 MHz [36], which is of the same order as D. In such a situation, one may consider using an indirect pump to improve the Talbot peak intensities. Similarly, the Rabi frequency of the control field must also be optimized to obtain maximum peak intensities.…”
Section: Resultsmentioning
confidence: 99%
“…In order to establish a connection between simulations and experimental observations, the absorption of the quantum system is analyzed using Beer's law. In the case of Rydberg EIT for electric field sensing, this phenomenon is typically observed in a glass cell containing atoms of interest [4,5]. By introducing EIT beams into the cell and measuring the transmission of the probe beam, the resulting signal can be expressed as…”
Section: Beer's Lawmentioning
confidence: 99%
“…As noted earlier, often the parameter of interest is the probe coherence ρ 21 as this is proportional to the absorption of the probe laser through the medium. Since ρ 21 = ρ * 12 , we will usually extract ρ 12 from the vector of the solution as this is always at the same index within the vector ρ vect ( [1]) whereas the position of ρ 21 will vary depending on the number of levels. The probe absorption is then α 12 ∝ Im[ρ 12 ].…”
Section: Examplesmentioning
confidence: 99%
“…Up until this point we have not considered the effects of temperature on the atomic ensemble. These effects arise due to the motion of the atoms and can include collisional effects and modifications due to interactions with a laser beam of finite size [1]. In this tutorial we will only consider the firstorder Doppler effects due to the velocity of the atoms within the ensemble, and we will neglect any collisional or time-offlight effects.…”
Section: Thermal Vaporsmentioning
confidence: 99%
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