Berlin 2008 –
wissenschaftliches Programm
HL 42: Optical Properties of Quantum dots: Theory and Simulation
Donnerstag, 28. Februar 2008, 09:30–13:00, EW 201
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09:30 |
HL 42.1 |
Gauge invariant k.p envelope function theory and g-factors in quantum dots — •Till Andlauer, Richard Morschl, and Peter Vogl
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09:45 |
HL 42.2 |
Gain reduction in semiconductor Quantum Dot systems — •Michael Lorke, Jan Seebeck, Paul Gartner, Frank Jahnke, and Weng Chow
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10:00 |
HL 42.3 |
Theoretical investigation of optical properties of semiconductor nanostructures — •Gudny Gudmundsdottir and Frank Grosse
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10:15 |
HL 42.4 |
Atomistic Theory of Excitonic Effects in Nanostructures — •Gabriel Bester
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10:30 |
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15 min. break
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10:45 |
HL 42.5 |
The phonon bottleneck revisited at low temperatures — •Jan Seebeck, Paul Gartner, and Frank Jahnke
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11:00 |
HL 42.6 |
Plane-Wave-implementation of the k· p-formalism including strain and piezoelectricity to study the optoelectronic properties of semiconductor nanostructures — •Oliver Marquardt, Tilmann Hickel, and Jörg Neugebauer
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11:15 |
HL 42.7 |
Input/Output Characteristics of Semiconductor Quantum Dot Lasers — •Christopher Gies, Jan Wiersig, and Frank Jahnke
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11:30 |
HL 42.8 |
Optical Spin Switching in a Quantum Dot with a Single Mn Atom — •Doris E. Reiter, Vollrath Martin Axt, and Tilmann Kuhn
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11:45 |
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15 min. break
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12:00 |
HL 42.9 |
Study of combined decoherence channels of optically controlled spin rotations in quantum dot systems — •Anna Grodecka, Paweł Machnikowski, Carsten Weber, Andreas Knorr, and Jens Förstner
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12:15 |
HL 42.10 |
The impact of travelling phonon wave packets on quantum dot spectra — •Jan Huneke, Vollrath Martin Axt, and Tilmann Kuhn
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12:30 |
HL 42.11 |
Coherence properties, photon statistics, and mode properties of quantum-dot based microcavity lasers — •Jan Wiersig, Christopher Gies, Michael Lorke, Frank Jahnke, and Martina Hentschel
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12:45 |
HL 42.12 |
Annealing of overgrown InAs/GaAs Quantum Dots:
A Tight-Binding Study — •Alexander Kleinsorge, Thomas Hammerschmidt, and Peter Kratzer
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