K. Yu. Khabarova, A. A. Galyshev, S. A. Strelkin, A. S. Kostin, G. S. Belotelov, O. I. Berdasov, A. Gribov, N. N. Kolachevsky, S. N. Slyusarev, “Spectroscopy of intercombination transition 1S0 – 3P1 for secondary cooling of strontium atoms”, Kvantovaya Elektronika, 2015, Volume 45, Number 2,Pages 166

This article is cited in 7 papers

Laser spectroscopy

Spectroscopy of intercombination transition ¹S₀ – ³P₁ for secondary cooling of strontium atoms

K. Yu. Khabarova^ab, A. A. Galyshev^bc, S. A. Strelkin^bc, A. S. Kostin^b, G. S. Belotelov^b, O. I. Berdasov^bc, A. Gribov^bc, N. N. Kolachevsky^abc, S. N. Slyusarev^b

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

Abstract: In the framework of the project aimed at creating an optical standard on cold Sr atoms we have realised sub-Doppler spectroscopy of the intercombination transition ¹S₀ – ³P₁ (689 nm) in a cell with Sr vapour and in a cloud of atoms loaded in a magneto- optical trap (MOT). By measuring Zeeman splitting of the ³P₁ level in the magnetic field of the MOT we have succeeded in fine adjustment of the MOT relative to a minimum of the magnetic field, which is necessary for successful secondary-stage cooling on the intercombination transition. In turn, absorption saturation spectroscopy in the vapour cell provides the long-term frequency stability of the second-stage cooling laser at λ = 689 nm.

Keywords: tical clock, strontium, saturation absorption spectroscopy, magneto-optical trap.

PACS: 42.62.Eh, 42.62.Fi, 37.10.De, 37.10.Gh

Received: 21.07.2014
Revised: 29.09.2014