Electric field induced hyperfine level-crossings in (nD)Cs at two-step laser excitation: Experiment and theory

The pure electric field level-crossing of mF Zeeman sublevels of hyperfine F levels at two-step laser excitation is described theoretically and studied experimentally for the nD3/2 states in Cs with n=7, 9 and 10, by applying a diode laser in the first 6S1/2→6P3/2 step and a diode or dye laser for t...

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Bibliographic Details
Published in:Optics communications 2006-08, Vol.264 (2), p.333-341
Main Authors: Auzinsh, M., Blushs, K., Ferber, R., Gahbauer, F., Jarmola, A., Tamanis, M.
Format: Article
Language:English
Subjects:
Cesium
Dye lasers
Exact sciences and technology
Fundamental areas of phenomenology (including applications)
Hyperfine manifold
Laser materials
Lasers
Level-crossing spectroscopy
Optical materials
Optics
Physics
Polarizability
Semiconductor lasers
laser diodes
Two-step laser excitation
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Summary:The pure electric field level-crossing of mF Zeeman sublevels of hyperfine F levels at two-step laser excitation is described theoretically and studied experimentally for the nD3/2 states in Cs with n=7, 9 and 10, by applying a diode laser in the first 6S1/2→6P3/2 step and a diode or dye laser for the second 6P3/2→nD3/2 step. Level-crossing resonance signals are observed in the nD3/2→6P1/2 fluorescence. A theoretical model is presented to describe quantitatively the resonance signals by correlation analysis of the optical Bloch equations in the case when an atom simultaneously interacts with two laser fields in the presence of an external dc electric field. The simulations describe well the experimental signals. The tensor polarizabilities α2 (in a03) are determined to be 7.45(20)×104 for the 7D3/2 state and 1.183(35)×106 for the 9D3/2 state; the electric field calibration is based on measurements of the 10D3/2 state, for which α2 is well established. The α2 value for the 7D3/2 state differs by ca. 15% from the existing experimentally measured value.
ISSN:0030-4018
1873-0310
DOI:10.1016/j.optcom.2006.01.058