Title :
Manipulating individual atoms in microscopic optical dipole traps
Author :
Reymond, G. ; Bergamini, S. ; Browaeys, A. ; Darquie, B. ; Grangier, P.
Author_Institution :
Lab. Charles Fabry, Inst. d´Optique, Orsay, France
Abstract :
We have realized very small optical dipole traps to store and manipulate individual atoms. Due to the small trap volume, a "collisional blockade" mechanism limits the number of trapped atoms to 1 over a large range of loading rates. We have studied this collisional blockade effect, and measured the oscillation frequencies and temperature of a single trapped atom, that appears to be in the sub-Doppler regime. Various mechanisms for turner cooling will be described, as well as the perspectives for using this system for quantum information processing.
Keywords :
laser cooling; quantum entanglement; quantum gates; quantum optics; radiation pressure; atomic manipulation; collisional blockade; microscopic dipole traps; optical dipole traps; quantum information processing; subDoppler regime; trapped atom; turner cooling; Atom optics; Atomic beams; Atomic measurements; Charge carrier processes; Fluorescence; Frequency measurement; Optical microscopy; Optical saturation; Temperature distribution; Temperature measurement;
Conference_Titel :
Quantum Electronics and Laser Science, 2003. QELS. Postconference Digest
Conference_Location :
Baltimore, MD, USA
Print_ISBN :
1-55752-749-0
DOI :
10.1109/QELS.2003.238373
