Pinball resonances in antidot optical lattices

Author

Triche, C. ; Guidoni, L. ; Petsas, K.I. ; Jurczak, C. ; Courtois, J.Y. ; Grynberg, G.

Author_Institution

Dept. de Phys., Ecole Normale Superieure, Paris, France

fYear

1998

fDate

8-8 May 1998

Firstpage

221

Lastpage

222

Abstract

Summary form only given.In the case of a transition connecting a ground level having an angular momentum toward an excited state of angular momentum, laser cooling can be achieved on the blue side of the transition, but the lowest potential is not because of the occurrence of an uncoupled state. When a static magnetic field is added, the optical potential becomes modulated, but it generally exhibits antidots rather than wells. As a result, atoms are free to move between the antidots. Actually atom trajectories calculated by numerical simulation show that atoms move by bouncing on the antidots as balls in billiards. We present experimental and numerical evidence of such trajectories. Cesium atoms are cooled in a four-beam lattice.

Keywords

angular momentum; caesium; laser cooling; quantum dots; quantum optics; Cs; Cs atom; angular momentum; antidot optical lattices; billiard balls; cesium atoms; excited state; four-beam lattice; ground level; laser cooling; pinball resonances; static magnetic field; uncoupled state; Atom optics; Cooling; Joining processes; Laser excitation; Laser transitions; Lattices; Magnetic fields; Magnetic modulators; Optical modulation; Resonance;

fLanguage

English

Publisher

ieee

Conference_Titel

Quantum Electronics Conference, 1998. IQEC 98. Technical Digest. Summaries of papers presented at the International

Conference_Location

San Francisco, CA, USA

Print_ISBN

1-55752-541-2

Type

conf

DOI

10.1109/IQEC.1998.680466

Filename

680466