Bragg scattering of slow atoms from a standing light wave

Open Access

10 May 1996

journal article
Published by IOP Publishing in Europhysics Letters

Vol. 34 (5) , 343-348
https://doi.org/10.1209/epl/i1996-00462-x

Abstract

Slow atoms from a magneto-optical trap are used to study diffraction from a near-resonant standing-wave light field. Long interaction times make it possible to observe unidirectional Bragg scattering. In particular, the Pendellösung interference effect between two resonant momentum states is demonstrated for first- and second-order diffraction. The oscillation frequency of second-order scattering shows a transition from a four-photon–type process at low light intensity to a two-photon–type process at higher intensity. The data are in quantitative agreement with a theoretical description which takes into account lowest-energy momentum states.

Keywords

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