TY - JOUR
T1 - Faraday–Ramsey Rotation in Ultrathin Alkali Vapor Cells as an Analogy to Atomic-Beam Systems
AU - Dikopoltsev, Mark
AU - Talker, Eliran
AU - Barash, Yefim
AU - Mazurski, Noa
AU - Levy, Uriel
N1 - Publisher Copyright:
© 2026 The Author(s). Laser & Photonics Reviews published by Wiley-VCH GmbH.
PY - 2026
Y1 - 2026
N2 - Atomic beams are powerful tools for measuring fundamental physical constants, probing atomic interactions, and developing precision metrology techniques such as atomic clocks and interferometry. However, most atomic-beam devices are bulky, which limits their miniaturization. Recent efforts toward the miniaturization of atomic beams have been reported (see, Ref. [10]). Here, we demonstrate an alternative approach, showing that micrometer-scale vapor cells can emulate atomic-beam behavior through geometry-dependent velocity filtering. Specifically, in a 5-µm-thick rubidium vapor cell, coherence is preserved for atoms moving parallel to the cell walls, enabling observation of the Faraday–Ramsey effect in the absence of buffer gas or anti-relaxation coatings. Using a spatially displaced pump–probe scheme and magnetic-field scanning, we observe distinct Ramsey fringes in excellent agreement with the theoretical model. This technique enables compact implementations of Faraday–Ramsey measurements in microfabricated alkali-vapor cells.
AB - Atomic beams are powerful tools for measuring fundamental physical constants, probing atomic interactions, and developing precision metrology techniques such as atomic clocks and interferometry. However, most atomic-beam devices are bulky, which limits their miniaturization. Recent efforts toward the miniaturization of atomic beams have been reported (see, Ref. [10]). Here, we demonstrate an alternative approach, showing that micrometer-scale vapor cells can emulate atomic-beam behavior through geometry-dependent velocity filtering. Specifically, in a 5-µm-thick rubidium vapor cell, coherence is preserved for atoms moving parallel to the cell walls, enabling observation of the Faraday–Ramsey effect in the absence of buffer gas or anti-relaxation coatings. Using a spatially displaced pump–probe scheme and magnetic-field scanning, we observe distinct Ramsey fringes in excellent agreement with the theoretical model. This technique enables compact implementations of Faraday–Ramsey measurements in microfabricated alkali-vapor cells.
KW - Faraday–Ramsey spectroscopy
KW - atomic-beam analogy
KW - chip-scale quantum sensors
KW - microscale alkali vapor cells
KW - nonlinear Faraday effect
UR - https://www.scopus.com/pages/publications/105026892464
U2 - 10.1002/lpor.202502129
DO - 10.1002/lpor.202502129
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AN - SCOPUS:105026892464
SN - 1863-8880
JO - Laser and Photonics Reviews
JF - Laser and Photonics Reviews
ER -