• DocumentCode
    2938044
  • Title

    Preparation of single velocity atoms for matter wave interferometry

  • Author

    Binnewies, T. ; Sterr, U. ; Helmcke, J. ; Riehle, Fritz

  • Author_Institution
    Phys. Tech. Bundesanstalt, Braunschweig, Germany
  • fYear
    2000
  • fDate
    10-15 Sept. 2000
  • Abstract
    Summary form only given. Atoms without ground state splitting, e.g. alkaline earths, are of special interest for atom interferometry and frequency standards due to their small sensitivity to external fields and for BEC and the study of cold collisions due to the simplified theoretical interpretation of their interaction. We demonstrate Maxwell´s-demon cooling, a novel method which allows to further cool alkaline earth atoms in one dimension. It consists of three consecutive steps which are repeated several times. First, from a cloud of cooled atoms released from a standard magneto-optical trap a small part of the velocity distribution is selected by excitation on a narrow transition (intercombination transition). Second, these atoms are optically pumped to another long lived state. Third, the ground state velocity distribution is restored by turning on the optical molasses on the strong transition used for the magneto-optical trapping. In addition to Maxwell´s thought experiment, where a demon separates the cold atoms from the hot ones, in the novel scheme the hot atoms are furthermore cooled again to the original 3 mK. By repeating these steps slow atoms are accumulated in the excited state. The velocity distribution of the atoms is measured after the cold atoms are decayed to the ground state by recording the Doppler broadening of the intercombination transition.
  • Keywords
    Doppler broadening; alkaline earth metals; excited states; ground states; laser cooling; optical pumping; particle interferometry; radiation pressure; 3 mK; Doppler broadening; Maxwell´s-demon cooling; alkaline earth atoms; atom interferometry a; cloud of cooled atoms; excited state; ground state velocity distribution; intercombination transition; long lived state; magneto-optical trap; matter wave interferometry; optical molasses; optical pumping; single velocity atoms preparation; slow atoms; strong transition; Atom optics; Atomic measurements; Cooling; Earth; Frequency; Matter waves; Optical interferometry; Optical pumping; Optical sensors; Stationary state;
  • fLanguage
    English
  • Publisher
    ieee
  • Conference_Titel
    Quantum Electronics Conference, 2000. Conference Digest. 2000 International
  • Conference_Location
    Nice, France
  • Print_ISBN
    0-7803-6318-3
  • Type

    conf

  • DOI
    10.1109/IQEC.2000.907926
  • Filename
    907926