Oliver Fartmann, Martin Jutisz, Amir Mahdian, Vladimir Schkolnik, Ingmari C. Tietje, Conrad Zimmermann, Markus Krutzik
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Ramsey-Borde Atom Interferometry with a Thermal Strontium Beam for a Compact Optical Clock
Compact optical atomic clocks have become increasingly important in field
applications and clock networks. Systems based on Ramsey-Borde interferometry
(RBI) with a thermal atomic beam seem promising to fill a technology gap in
optical atomic clocks, as they offer higher stability than optical vapour cell
clocks while being less complex than cold atomic clocks. Here, we demonstrate
RBI with strontium atoms, utilizing the narrow 1S0 -> 3P1 intercombination line
at 689 nm, yielding a 60 kHz broad spectral feature. The obtained Ramsey
fringes for varying laser power are analyzed and compared with a numerical
model. The 1S0 -> 1P1 transition at 461 nm is used for fluorescence detection.
Analyzing the slope of the RBI signal and the fluorescence detection noise
yields an estimated short-term stability of 4x10-14 / sqrt{tau}. We present our
experimental setup in detail, including the atomic beam source,
frequency-modulation spectroscopy to lock the 461 nm laser, laser power
stabilization and the high-finesse cavity pre-stabilization of the 689 nm
laser. Our system serves as a ground testbed for future clock systems in mobile
and space applications.
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