English

Three Dimensional Raman Cooling using Velocity Selective Rapid Adiabatic Passage

Quantum Gases 2011-10-10 v2 Atomic Physics Quantum Physics

Abstract

We present a new and efficient implementation of Raman cooling of trapped atoms. It uses Raman pulses with an appropriate frequency chirp to realize a velocity selective excitation through a rapid adiabatic passage. This method allows to address in a single pulse a large number of non zero atomic velocity classes and it produces a nearly unity transfer efficiency. We demonstrate this cooling method using cesium atoms in a far-detuned crossed dipole trap. Three-dimensional cooling of 1×1051 \times 10^{5} atoms down to 2μ2 \muK is performed in 100 ms. In this preliminary experiment the final atomic density is 1.3×10121.3\times 10^{12} at/cm3^3 (within a factor of 2) and the phase-space density increase over the uncooled sample is 20. Numerical simulations indicate that temperatures below the single photon recoil temperature should be achievable with this method.

Keywords

Cite

@article{arxiv.1109.5237,
  title  = {Three Dimensional Raman Cooling using Velocity Selective Rapid Adiabatic Passage},
  author = {Axel Kuhn and Hélène Perrin and Wolfgang Hänsel and Christophe Salomon},
  journal= {arXiv preprint arXiv:1109.5237},
  year   = {2011}
}

Comments

OSA TOPS on Ultracold Atoms and BEC 7 (1997) 58

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