Title :
Toward quantum entanglement in a quantum-dot nanocavity
Author :
Gibbs, H.M. ; Khitrova, G. ; Lee, E.S. ; Park, S. ; Ell, C. ; Deppe, D.G. ; Huffaker, D.L.
Author_Institution :
Opt. Sci. Center, Arizona Univ., Tucson, AZ, USA
Abstract :
Our semiconductor normal-mode-coupling microcavities, each containing a single narrow-linewidth quantum well (QW), exhibit record many-oscillator vacuum-field Rabi splitting (VRS). The question addressed here is: can the vacuum field be increased sufficiently by reducing the cavity-mode volume, so that a single quantum dot can exhibit VRS similar to an atom in a high-finesse cavity? The quantum-dot nanocavity has two advantages: a length close to the theoretical minimum and a much larger dipole moment; these permit strong coupling without an ultra high-Q cavity even for such a short length.
Keywords :
micro-optics; micromechanical resonators; nanostructured materials; quantum optics; semiconductor quantum dots; spectral line breadth; spontaneous emission; cavity-mode volume; dipole moment; high-finesse cavity; quantum entanglement; quantum-dot nanocavity; record many-oscillator vacuum-field Rabi splitting; semiconductor normal-mode-coupling microcavities; single narrow-linewidth quantum well; single quantum dot; strong coupling; ultra high-Q cavity; vacuum field; Atom optics; Atomic layer deposition; Elementary particle vacuum; Excitons; Microcavities; Optical recording; Oscillators; Quantum dots; Quantum entanglement; Quantum mechanics;
Conference_Titel :
Nanostructures and Quantum Dots/WDM Components/VCSELs and Microcavaties/RF Photonics for CATV and HFC Systems, 1999 Digest of the LEOS Summer Topical Meetings
Conference_Location :
San Diego, CA, USA
Print_ISBN :
0-7803-5633-0
DOI :
10.1109/LEOSST.1999.794705
