Rubidium frequency standard with pulsed optical pumping and frequency instability of 2.5 × 10−13τ − 1/2

The work is dedicated to the further development of a compact quantum frequency standard based on a rubidium gas cell with a mixture of buffer gases. The results of frequency measurements and analysis of short-term frequency instability obtained on a laboratory prototype of a microwave rubidium atom...

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Bibliographic Details
Published in:Quantum electronics (Woodbury, N.Y.) N.Y.), 2022-06, Vol.52 (6), p.538-543
Main Authors: Baryshev, V.N., Osipenko, G.V., Novoselov, A.V., Sukhoverskaya, A.G., Boyko, A.I., Aleynikov, M.S.
Format: Article
Language:English
Subjects:
acousto-optic modulator
diode laser
Frequency analysis
Frequency measurement
frequency modulation spectroscopy
Frequency stability
Frequency standards
Optical pumping
pulsed optical pumping
quantum frequency standard on a rubidium gas cell
Ramsey microwave excitation scheme
Rubidium
Stability analysis
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Summary:The work is dedicated to the further development of a compact quantum frequency standard based on a rubidium gas cell with a mixture of buffer gases. The results of frequency measurements and analysis of short-term frequency instability obtained on a laboratory prototype of a microwave rubidium atomic frequency standard (RAFS) with pulsed optical pumping (POP) are presented. The main in magnitude contributions to the overall frequency instability of the RAFS with POP are estimated. Short-term frequency instability expressed in terms of the Allan deviation and measured at averaging times τ up to several tens of seconds, σ y ( τ ) = 2.5×10 −13 τ −1/2 , coincides satisfactorily with the calculated value of σ y ( τ ) = 2.1×10 −13 τ −1/2 .
ISSN:1063-7818
1468-4799
DOI:10.1070/QEL18057