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Quantitative simulation of a magneto-optical trap operating near the photon recoil limit

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 Added by Ryan Hanley
 Publication date 2017
  fields Physics
and research's language is English




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We present a quantitative model for magneto-optical traps operating on narrow transitions, where the transition linewidth and the recoil shift are comparable. We combine a quantum treatment of the light scattering process with a Monte-Carlo simulation of the atomic motion. By comparing our model to an experiment operating on the $5rm{s}^2~^1rm{S}_0 rightarrow 5rm{s}5rm{p}~^3rm{P}_1$ transition in strontium, we show that it quantitatively reproduces the cloud size, position, temperature and dynamics over a wide range of operating conditions, without any adjustable parameters. We also present an extension of the model that quantitatively reproduces the transfer of atoms into a far off-resonance dipole trap (FORT), highlighting its use as a tool for optimising complex cold atom experiments.



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