Difference between revisions of "Optical Loading of Magnetic Traps"

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(Cold Beam)
(Overview)
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==Overview==
 
==Overview==
 
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[[File:Apparatus_for_Magnetically_Trapping_CaH.png|thumb|500px|A buffer gas cooled beam of CaH will be separated from helium buffer gas before being optically loaded into a magnetic trap.]]
 
We realize a continuous, high flux, cold molecular or atomic beam using buffer gas cooling techniques.  Recent efforts have focused on creating such a source by mixing hot vapor (up to 600K) with cold neon buffer gas (15K) before emitting the mixture in a high flux beam.  Neon buffer gas produces a beam with a forward velocity distribution and low energy tail comparable to much colder helium based beams.  Such a beam may be a good starting point for laser cooling, cold collision studies, and trapping .  Recent efforts have focused on magnetic trapping of potassium, but previous work realized cold beams of molecular oxygen and deuterated ammonia molecules.
 
We realize a continuous, high flux, cold molecular or atomic beam using buffer gas cooling techniques.  Recent efforts have focused on creating such a source by mixing hot vapor (up to 600K) with cold neon buffer gas (15K) before emitting the mixture in a high flux beam.  Neon buffer gas produces a beam with a forward velocity distribution and low energy tail comparable to much colder helium based beams.  Such a beam may be a good starting point for laser cooling, cold collision studies, and trapping .  Recent efforts have focused on magnetic trapping of potassium, but previous work realized cold beams of molecular oxygen and deuterated ammonia molecules.
  

Revision as of 08:57, 9 November 2010

Cold Beam

People

Post Docs

  • Matthew Wright

Grad Students

  • Hsin-I Lu
  • Julia Rasmussen

Overview

A buffer gas cooled beam of CaH will be separated from helium buffer gas before being optically loaded into a magnetic trap.

We realize a continuous, high flux, cold molecular or atomic beam using buffer gas cooling techniques. Recent efforts have focused on creating such a source by mixing hot vapor (up to 600K) with cold neon buffer gas (15K) before emitting the mixture in a high flux beam. Neon buffer gas produces a beam with a forward velocity distribution and low energy tail comparable to much colder helium based beams. Such a beam may be a good starting point for laser cooling, cold collision studies, and trapping . Recent efforts have focused on magnetic trapping of potassium, but previous work realized cold beams of molecular oxygen and deuterated ammonia molecules.

Recent Publications