O. I. Berdasov, A. Yu. Gribov, G. S. Belotelov, V. G. Pal'chikov, S. A. Strelkin, K. Yu. Khabarova, N. N. Kolachevsky, S. N. Slyusarev, “Ultrastable laser system for spectroscopy of the 1S0 – 3P0 clock transition in Sr atoms”, Kvantovaya Elektronika, 2017, Volume 47, Number 5,Pages 400

This article is cited in 13 papers

Physics of ultra cold atoms and their applications

Ultrastable laser system for spectroscopy of the ¹S₀ – ³P₀ clock transition in Sr atoms

O. I. Berdasov^ab, A. Yu. Gribov^ab, G. S. Belotelov^b, V. G. Pal'chikov^ab, S. A. Strelkin^ab, K. Yu. Khabarova^cb, N. N. Kolachevsky^cb, S. N. Slyusarev^b

^a Moscow Engineering Physics Institute (National Nuclear Research University)
^b All-Russian Scientific Research Institute of Physical-Technical and Radiotechnical Measurements, Mendeleevo, Moscow region
^c P. N. Lebedev Physical Institute, Russian Academy of Sciences, Moscow

Abstract: A laser system with a spectral linewidth less than 1 Hz for spectroscopy of the ¹S₀ – ³P₀ clock transition in strontium atoms has been demonstrated. A semiconductor laser emitting at a wavelength of 698 nm was stabilised to an external high-finesse Fabry–Perot cavity with vibration and temperature compensation near the zero expansion point. After laser cooling to a temperature below 3 μK, ⁸⁸Sr atoms were loaded into an optical lattice at a magic wavelength of 813 nm. The laser system was used to characterise the ⁸⁸Sr clock transition by magnetically induced spectroscopy. The resonance spectral width was determined to be 130 ± 17 Hz, which corresponds to a quality factor of 3 × 10¹².

Keywords: Sr atom, laser cooling, optical lattice, magnetically induced spectroscopy, clock transition, stable cavity.

Received: 09.03.2017
Revised: 30.03.2017