Photonics of quantum dot nanomaterials and devices theory and modelling 1st Edition by Ortwin Hess, Edeltraud Gehrig ISBN 978-1848165212 1848165218
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Product details:
ISBN 10: 1848165218
ISBN 13: 978-1848165212
Author: Ortwin Hess, Edeltraud Gehrig
Table of contents:
1. Introduction to Photonic Quantum Dot
Nanomaterials and Devices
1.1 Physical Properties of Quantum Dots
1.2 Active Semiconductor Gain Media
Quantum Dot Lasers 1.3
1.3.1 Heterostructure lasers
1.3.2 Active nanomaterials
1.4 Laser Cavities
1.4.1 In-plane edge-emitting lasers
1.4.2 Vertical-cavity surface-emitting lasers
1.4.3 High-power laser amplifiers
1.4.4 Coupled-cavity systems
1.4.5 Optically excited nano systems
1.4.6 QD metastructures
References
2. Theory of Quantum Dot Light-Matter Dynamics
2.1 Rate Equations
2.2 Maxwell-Bloch Equations
2.2.1 Mesoscopic two-level approach
Mesoscopic Maxwell-Bloch description of multi-level quantum dot systems
2.2.2.1 Optical field dynamics
2.2.2.2 Carrier dynamics within a quantum dot
2.3 Quantum Luminescence Equations
2.4 Quantum Theoretical Description
References
3. Light Meets Matter I: Microscopic Carrier Effects and Fundamental Light-Matter Interaction
3.1 Dynamics in the Active Charge Carrier Plasma
3.1.1 Intra-dot carrier scattering
3.1.2 Phonon induced carrier scattering between quantum dots and wetting layer
3.1.3 Auger scattering processes involving OD and 2D carriers
3.1.4 Level and gain dynamics
3.1.5 Dynamics of carrier scattering rates
3.2 Dynamic Level Hole Burning
3.3 Ultrashort Nonlinear Gain and Index Dynamics
3.4 Conclusion
References
4. Light Meets Matter II: Mesoscopic Space-Time
Dynamics
4.1 Mode Dynamics Introduction: Transverse and Longitudinal
4.2 Influence of the Transverse Degree of Freedom and Nano-Structuring on Nearfield Dynamics and Spectra
4.3 Longitudinal Modes
4.4 Coupled Space-Time Dynamics in the Active Area
4.4.1 Influence of injection level and geometry
4.4.2 Influence of disorder: the spatially inhomogeneous quantum dot ensemble
4.4.3 Light fluctuations and mode competition in quantum dot cavities.
4.5 Conclusion
References
5. Performance and Characterisation: Properties on Large Time and Length Scales
5.1 Introduction.
5.2 Spatial and Spectral Beam Quality
5.3 Dynamic Amplitude Phase Coupling
5.4 Conclusion
References
6. Nonlinear Pulse Propagation in Semiconductor
Quantum Dot Lasers
6.1 Dynamic Shaping of Short Optical Pulses
6.2 Nonlinear Femtosecond Dynamics of Ultrashort Light Pulses
6.2.1 Self-induced propagation control: tunable propagation speed
6.2.2 Propagation control by a second pulse
6.3 Conclusion
References
7. High-Speed Dynamics
7.1 Mode-Locking in Multi-Section Quantum
Dot Lasers.
7.2 Dependence of Pulse Duration on Injection Current, Bias Voltage and Device Geometry
7.3 Radio Frequency Spectra of the Emitted Light
7.4 Short-Pulse Optimisation
7.5 Conclusion
References
8. Quantum Dot Random Lasers
8.1 Spatially Inhomogeneous Semiconductor Quantum Dot Ensembles
8.1.1 Gain spectra
8.1.2 Spatial and spectral hole burning
8.2 Coherence Properties.
8.3 Random Lasing in Semiconductor Quantum Dot Ensembles
8.3.1 The physics of random lasing.
8.3.2 Lasers with strong disorder:
incoherent feedback
8.3.3 Lasers with weak disorder:
coherent feedback
8.4 Conclusion
References
9. Coherence Properties of Quantum Dot
Micro-Cavity Lasers
9.1 Introduction.
9.2 Radial Signal Propagation and Coherence
Trapping
9.3 Influence of Disorder
9.4 Conclusions
References
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Tags: Ortwin Hess, Edeltraud Gehrig, Photonics of quantum, nanomaterials and devices