Title :
Atom-cavity dynamics in the limit of ultraslow atomic decoherence
Author :
Greiner ; Boggs, B. ; Mossberg
Author_Institution :
Oregon Center for Opt. & Dept. of Phys., Oregon Univ., Eugene, OR, USA
Abstract :
Summary form only given. An underlying premise of quantum computing is the preservation of system coherence over long time scales. Here, we report studies of atom-cavity dynamics wherein behavior observed is distinctively related to the ultraslow atomic decoherence found in one such system. In our experiment, the atomic decoherence time is four orders of magnitude longer than the empty-cavity lifetime, making the atomic coherence the longest-lived system parameter. The phenomenon we observe here may be loosely thought of as cavity-mediated self-driven optical nutation, i.e., optical nutation driven by the active atoms own coherent emission into the cavity mode.
Keywords :
laser beams; light coherence; optical coherent transients; quantum computing; quantum optics; YAG:Tm; YAl5O12:Tm; active atoms; atom-cavity dynamics; atomic coherence; atomic decoherence time; cavity mode; cavity-mediated self-driven optical nutation; coherent emission; empty-cavity lifetime; long time scales; longest-lived system parameter; optical nutation; quantum computing; system coherence; ultraslow atomic decoherence; Atom optics; Coherence; Quantum computing; Stimulated emission;
Conference_Titel :
Quantum Electronics and Laser Science Conference, 2000. (QELS 2000). Technical Digest
Conference_Location :
San Francisco, CA, USA
Print_ISBN :
1-55752-608-7
