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Proceedings Paper

Cavity quantum electrodynamics studies with site-controlled InGaAs quantum dots integrated into high quality microcavities
Author(s): S. Reitzenstein; C. Schneider; F. Albert; A. Huggenberger; T. Heindel; M. Lermer; S. Stobbe; P. Weinmann; P. Lodahl; S. Höfling; M. Kamp; L. Worschech; A. Forchel
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Paper Abstract

Semiconductor quantum dots (QDs) are fascinating nanoscopic structures for photonics and future quantum information technology. However, the random position of self-organized QDs inhibits a deterministic coupling in devices relying on cavity quantum electrodynamics (cQED) effects which complicates, e.g., the large scale fabrication of quantum light sources. As a result, large efforts focus on the growth and the device integration of site-controlled QDs. We present the growth of low density arrays of site-controlled In(Ga)As QDs where shallow etched nanoholes act as nucleation sites. The nanoholes are located relative to cross markers which allows for a precise spatial alignment of the site-controlled QDs (SCQDs) and the photonic modes of high quality microcavites with an accuracy better than 50 nm. We also address the optical quality of the SCQDs in terms of the single SCQD emission mode linewidth, the oscillator strength and the quantum efficiency. A stacked growth of strain coupled SCQDs forming on wet chemically etched nanoholes provide the smallest linewidth with an average value of 210 μeV. Using time resolved photoluminescence studies on samples with a varying thickness of the capping layer we determine a quantum efficiency of the SCQD close to 50 % and an oscillator strength of about 10. Finally, single photon emission with associated with g(2)(0) = 0.12 of a weakly coupled SCQD - micropillar system will be presented.

Paper Details

Date Published: 1 March 2011
PDF: 11 pages
Proc. SPIE 7947, Quantum Dots and Nanostructures: Synthesis, Characterization, and Modeling VIII, 794702 (1 March 2011); doi: 10.1117/12.876794
Show Author Affiliations
S. Reitzenstein, Julius-Maximilians-Univ. Würzburg (Germany)
C. Schneider, Julius-Maximilians-Univ. Würzburg (Germany)
F. Albert, Julius-Maximilians-Univ. Würzburg (Germany)
A. Huggenberger, Julius-Maximilians-Univ. Würzburg (Germany)
T. Heindel, Julius-Maximilians-Univ. Würzburg (Germany)
M. Lermer, Julius-Maximilians-Univ. Würzburg (Germany)
S. Stobbe, Technical Univ. of Denmark (Denmark)
P. Weinmann, Julius-Maximilians-Univ. Würzburg (Germany)
P. Lodahl, Technical Univ. of Denmark (Denmark)
S. Höfling, Julius-Maximilians-Univ. Würzburg (Germany)
M. Kamp, Julius-Maximilians-Univ. Würzburg (Germany)
L. Worschech, Julius-Maximilians-Univ. Würzburg (Germany)
A. Forchel, Julius-Maximilians-Univ. Würzburg (Germany)

Published in SPIE Proceedings Vol. 7947:
Quantum Dots and Nanostructures: Synthesis, Characterization, and Modeling VIII
Kurt G. Eyink; Frank Szmulowicz; Diana L. Huffaker, Editor(s)

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