Hyperfine Paschen–Back regime in alkali metal atoms: consistency of two theoretical considerations and experiment

Sargsyan, A.; Hakhumyan, G.; Leroy, Claude; Pashayan-Leroy, Y.; Papoyan, A.; Sarkisyan, D.; Auzinsh, M.

doi:10.1364/josab.31.001046

Cited by 48 publications

(41 citation statements)

References 18 publications

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“…Despite the fact that the amplitudes of the EIT components decrease with an increase of the magnetic field, the components are well resolved up to 1 kG. The magnetic-field dependent decrease of the amplitudes of the EIT components has two reasons: an increase in the magnetic field leads to an increase in the detuning Δ of the frequency ν C from the respective atomic transition, and (more importantly [16]) a decrease of the atomic transition probabilities at frequencies ν C and ν P [17][18][19].…”

Section: Nano-cellmentioning

confidence: 90%

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EIT resonance features in strong magnetic fields in rubidium atomic columns with length varying by 4 orders

et al. 2016

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Electromagnetically induced transparency (EIT) resonances are investigated with the 85 Rb D 1 line (795 nm) in strong magnetic fields (up to 2 kG) with three different types of spectroscopic vapor cells: the nano-cell with a thickness along the direction of laser light L ≈ 795 nm, the micro-cell with L = 30 μm with the addition of a neon buffer gas, and the centimeter-long glass cell. These cells allowed us to observe systematic changes of the EIT spectra when the increasing magnetic field systematically decoupled the total atomic electron and nuclear angular moments (the Paschen-Back/Back-Goudsmit effects). The observations agree well with a theoretical model. The advantages and disadvantages of a particular type of cell are discussed along with the possible practical applications.

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Section: Nano-cellmentioning

confidence: 90%

“…The energies of the Zeeman sublevels can easily be calculated as, e.g. in [17,19]. Figure 5 shows the calculated curves (solid lines) for the EIT-components with the numbers 1-5 corresponding to the configuration of the ν P and ν C frequencies, such as shown in the inset in Fig.…”

Section: Centimeter-long Cellsmentioning

confidence: 99%

EIT resonance features in strong magnetic fields in rubidium atomic columns with length varying by 4 orders

et al. 2016

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“…5, which shows some lower (F g = 3, 4) and upper (F e = 3, 4, 5) energy levels and their mag netic sublevels m F . A perturbation induced by the external magnetic field (under σ + excitation) only couples the magnetic sublevels with Δm F = 0 (indi cated by circular arrows), which must also obey the selection rules ΔL = 0, ΔJ = 0, and ΔF = ±1 [20,21]. To modify the probability of atomic transitions between magnetic sublevels, it is necessary that at least one magnetic sublevel m F be "mixed" with another sublevel.…”

Section: Single Pass Absorption Spectra Of Mcs With Cesium Vapor In Smentioning

confidence: 99%

“…4b) are described by the following expression [17]: (1) Here, A HFS and B HFS are the hyperfine structure cou pling coefficients for levels 6S 1/2 and 6P 3/2 , respec tively; g J and g I are the Lande factors for the total angular momentum J of electron and nuclear spin I, respectively [17]. As was shown in [21], a theoretical model that exactly describes the frequencies of transi tions in the magnetic field and formula (1) give close values for B ≥ 10B 0 (with discrepancies below 2%), which implies B ≥ 16 kG for Cs. Figure 7 shows the frequency corrections that must be added to the values It should be noted that excitation with σ -(right handed) polarized light in the hyperfine Paschen-Back regime also yields 16 transitions in two groups, each with eight transitions, but these are situated in the low frequency wing of transition F g = 4 F e = 3.…”

Section: Single Pass Absorption Spectra Of Mcs With Cesium Vapor In Smentioning

confidence: 99%

Micron-thick spectroscopic cells for studying the Paschen-Back regime on the hyperfine structure of cesium atoms

Sargsyan

Glushko

Sarkisyan

2015

J. Exp. Theor. Phys.

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It is shown that the use of spectroscopic cells of micron thickness (L = 10-50 μm) allows one to effectively study the behavior of individual levels of the Cs D 2 line in strong magnetic fields up to 9 kG. In particular, the absorption spectrum of Cs excited by circularly polarized light in fields above 8 kG consists of two fully separated groups, each containing eight atomic transitions. The intensities of atomic transitions and their frequency slopes (vs. magnetic field) in each group are almost the same. The physical explanation for the observed features is given; in particular, it is shown that one of the 54 possible atomic transitions in mod erate magnetic fields (denoted F g = 4, m F = 4 F e = 5, m F = 5) has unique characteristics that make it possible to predict the intensities and frequency slopes of seven atomic transitions in the same group. Practical applications of devices based on micrometric thin cells in strong magnetic fields are considered.

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“…Thus, with increasing B, the majority of Zeeman transitions vanish. The calculated probabilities of all transitions allowed in the BG regime (1-10) as a function of B-field can be found in [16]. They all smoothly increase with B and reach their maximum values for B of several kilogauss.…”

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Saturated-absorption spectroscopy revisited: atomic transitions in strong magnetic fields (>20 mT) with a micrometer-thin cell

et al. 2014

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The existence of crossover resonances makes saturated-absorption (SA) spectra very complicated when external magnetic field B is applied. It is demonstrated for the first time, to the best of our knowledge, that the use of micrometric-thin cells (MTCs, L ≈ 40 μm) allows application of SA for quantitative studies of frequency splitting and shifts of the Rb atomic transitions in a wide range of external magnetic fields, from 0.2 up to 6 kG (20-600 mT). We compare the SA spectra obtained with the MTC with those obtained with other techniques and present applications for optical magnetometry with micrometer spatial resolution and a broadly tunable optical frequency lock.

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Hyperfine Paschen–Back regime in alkali metal atoms: consistency of two theoretical considerations and experiment

Cited by 48 publications

References 18 publications

EIT resonance features in strong magnetic fields in rubidium atomic columns with length varying by 4 orders

EIT resonance features in strong magnetic fields in rubidium atomic columns with length varying by 4 orders

Micron-thick spectroscopic cells for studying the Paschen-Back regime on the hyperfine structure of cesium atoms

Saturated-absorption spectroscopy revisited: atomic transitions in strong magnetic fields (>20 mT) with a micrometer-thin cell

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