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11:15 |
HL 3.1 |
Optical properties of ZnSe-based quantum dot pillar microcavities at elevated temperatures — •Joachim Kalden, Henning Lohmeyer, Kathrin Sebald, Thomas Meeser, Jürgen Gutowski, Carsten Kruse, Arne Gust, and Detlef Hommel
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11:30 |
HL 3.2 |
Electrically driven high–Q quantum dot–micropillar cavities — •Caroline Kistner, Carolin Böckler, Stephan Reitzenstein, Ralph Debusmann, Andreas Löffler, Takayuki Kida, Sven Höfling, Alfred Forchel, Laurent Grenouillet, Julien Claudon, and Jean-Michel Gérad
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11:45 |
HL 3.3 |
Observation of Non-Resonant Dot-Cavity Coupling in Two-Dimensional Photonic Crystal Nanocavities — •Michael Kaniber, Arne Laucht, Andre Neumann, Max Bichler, and Jonathan J. Finley
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12:00 |
HL 3.4 |
Influence of the Spontaneous Emission Factor β on the Coherence Time of Semiconductor Microcavity Lasers — •Serkan Ateş, Christopher Gies, Sven M. Ulrich, Jan Wiersig, Stephan Reitzenstein, Andreas Loeffler, Alfred Forchel, Frank Jahnke, and Peter Michler
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12:15 |
HL 3.5 |
Realization of Electrically Tunable Single Quantum Dot - Cavity Systems — Felix Hofbauer, •Jakob Angele, Michael Kaniber, Gerhard Böhm, and Jonathan J. Finley
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12:30 |
HL 3.6 |
Hybrid microcavities with embedded CdHgTe quantum dots — •David Zingelmann, Johannes Renner, Lukas Worschech, Andreas Löffler, Matthias Schäfer, Charles Becker, Laurens Molenkamp, and Alfred Forchel
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12:45 |
HL 3.7 |
Efficient single photon generation using single quantum dots in two-dimensional photonic crystals — •Arne Laucht, Michael Kaniber, Andre Neumann, Max Bichler, and Jonathan J. Finley
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