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27 reviews(Ebook) Nanophotonic Materials Photonic Crystals Plasmonics and Metamaterials 1st Edition by Ralf B Wehrspohn, Heinz Siegfried Kitzerow, Kurt Busch - Ebook PDF Instant Download/Delivery: 9783527408580 ,3527408584
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Product details:
ISBN 10: 3527408584
ISBN 13: 9783527408580
Author: Ralf B Wehrspohn, Heinz Siegfried Kitzerow, Kurt Busch
(Ebook) Nanophotonic Materials Photonic Crystals Plasmonics and Metamaterials 1st Edition Table of contents:
I Linear and Non-linear Properties of Photonic Crystals
1.1 Introduction
1.2 Variational Approach to the NLCME
1.3 Radiation Losses
1.4 Results
1.5 Conclusions and Outlook
References
2.1 Introduction
2.2 Theoretical Approach
2.2.1 Spatially-Inhomogeneous Maxwell Equations in Semiconductor Photonic-Crystal Structures
2.2.1.2 Longitudinal Part: The Generalized Coulomb Interaction
2.2.2 Hamiltonian Describing the Material Dynamics
2.2.3 Semiconductor Bloch Equations in Real Space
2.2.3.1 Low-Intensity Limit
2.3.1 Semiconductor Photonic-Crystal Structure
2.3.2 Linear Excitonic Absorption
2.3.3 Coherent Wave Packet Dynamics
2.3.4 Wave Packet Dynamics with Dephasing and Relaxation
2.3.5 Quasi-Equilibrium Absorption and Gain Spectra
2.4 Summary
References
3.1 Introduction
3.2 Opals as Coloring Agents
3.2.2 Opaline Effect Pigments by Spray Induced Self-Assembly
3.3 Loading of Opals with Highly Fluorescent Dyes
3.4.1 Increase of Refractive Index
3.4.2 Robust Replica
3.4.3 Inert Replica for Chemistry and Catalysis at High Temperatures
3.5 Defect Incorporation into Opals
3.5.1 Patterning of the Opal Itself
3.5.2 Patterning of an Infiltrated Material
3.5.3 Chemistry in Defect Layers
References
4.1 Introduction
4.2 Experiment
4.3 Coherent Cavity Field Coupling in One-Dimensional CROWs
4.4 Mode Structure in Finite CROWs
4.5 Slowing Down Light in CROWs
4.6 Disorder and Detuning in CROWs
References
5.1 Introduction
5.2.1 Dispersion Tuning
5.2.2 Coupled Mode Model
5.3 Transmission Efficiency
5.4 Aperiodic Nanopillar Waveguides
5.5.1 Directional Coupler
5.5.2 Laser Resonators
5.6 Conclusion
References
6.1 Introduction
6.2 High-Refractive Index Inorganic–Organic Hybrid Polymers
6.3.1 Experimental Setup
6.3.2 Fabrication of PhC in Standard ORMOCER(®)
6.3.3 2PP of High Refractive Index Materials
6.3.4 Patterning and PhC Fabrication in Positive Resist Material S1813
6.4 Summary and Outlook
References
7.1 Introduction
7.2.1.1 General Remarks
7.2.1.2 Preparation Details
7.2.2 Characterization and Structure Determination of MSFs
7.2.3 Optical Properties of MSFs
7.2.4 Synthesis Mechanism
7.3.1 Polymer Waveguides
7.3.2 Ta(2)O(5) Waveguides and 2D PhC Structures
7.3.3 PZT Films
7.4 Conclusions
References
8.1 Introduction
8.2 Fabrication of Photonic Crystal Slabs
8.3 Linear Properties of Photonic Crystal Slabs
8.3.1 Transmission and High Dispersion of Line-Defect Waveguides
8.3.2 High-Quality Factor Microcavities in a Low-Index Photonic Crystal Membrane
8.3.3 Unusual Diffraction and Refraction Phenomena in Photonic Crystal Slabs
8.3.3.1 Self-Collimated Light at Infrared and Visible Wavelengths
8.3.3.2 Negative Refraction of Light
8.4.1 An Optical Parametric Oscillator in a Photonic Crystal Microcavity
8.4.2 Discrete Solitons in Coupled Defects in Photonic Crystals
References
9.1 Introduction
9.2.1 Macroporous Silicon Growth Model
9.2.3 Fabrication of Trenches and More Complex Geometries
9.3 Defects in 2D Macroporous Silicon Photonic Crystals
9.3.1 Waveguides
9.3.2 Beaming
9.3.3 Microcavities
9.4.1 Internal Emitter in Bulk 2D Silicon Photonic Crystals
9.4.2 Internal Emitter in Microcavities of 2D Silicon Photonic Crystals
9.4.3 Modified Thermal Emission
9.5.1 Liquid Crystals Tuning
9.5.2 Free-carrier Tuning
9.5.3 Nonlinear Optical Tuning
9.6 Summary
References
10.1 Introduction
10.2.1 Resonator Design
10.2.2 Fabrication
10.3 Transmission Measurements
10.4 Dispersion Measurements
10.5.1 Hilbert Transformation
10.5.2 Fabry–Perot Model
10.6 Postfabrication Tuning
10.7 Conclusion
References
II Tuneable Photonic Crystals
11.1 Introduction
11.2.1 Materials
11.2.2 Fabrication
11.3.1 Characterization
11.3.2 Experimental Results
11.4 Synthesis of Electro-Optically Active Polymers
11.5 Conclusions and Outlook
References
12.1 Introduction
12.2.1 Colloidal Crystals
12.2.2 Photonic Crystals Made of Macroporous Silicon
12.2.3 Photonic Crystal Fibres
12.3 Discussion
12.4 Conclusions
References
13.1 Introduction
13.2 Experiment
13.2.1.2 Cell Fabrication
13.2.1.4 The Experimental Setup
13.2.2 Lasing in Ferroelectric Liquid Crystals
13.2.2.1 Sample Preparation
13.2.2.3 Experimental Results
References
14.1 Introduction
14.2.1 Laser Action in Cholesteric Liquid Crystal
14.2.2 Low-Threshold Lasing Based on Band-Edge Excitation in CLC
14.2.3 Laser Action in Polymerized Cholesteric Liquid Crystal Film
14.2.4 Electrically Tunable Laser Action in Chiral Smectic Liquid Crystal
14.3 Twist Defect Mode in Cholesteric Liquid Crystal
14.4 Chiral Defect Mode Induced by Partial Deformation of Helix
14.5 Tunable Defect Mode Lasing in a Periodic Structure Containing CLC Layer as a Defect
14.6 Summary
References
15.1 Introduction
15.2.1 Origin of the Superprism Effect
15.2.2 Performance Considerations for Superprism Devices
15.2.4 Current State in Superprism Structures
15.3 Tunable Photonic Crystals
15.3.1 Liquid Crystals
15.3.2 Tuning by Pockels Effect
15.3.3 All-Optical Tuning
15.4 Tunable Superprism Structures
15.5.1 Survey of Optically Nonlinear Organic Materials
15.5.1.2 Electro-optic Organic Materials
15.5.1.3 All-optical Organic Materials
15.5.2 Numerical Simulation of a Doubly Resonant Structures for All-Optical Spatial Beam Switching
15.5.2.3 Beam Shifting for Active Coupling Layers
References
III Photonic Crystal Fibres
16.1 Introduction
16.3 Silica-Based PCFs with Index Guiding
16.3.1 Specific Properties of Pure Silica PCFs
16.3.2 PCF with Very Large Mode Field Parameter (VLMA-PCF)
16.3.3 Doped Silica PCF with Germanium-Doped Holey Core
16.3.4 Highly Germanium-Doped Index Guiding PCF
16.4 Photonic Band Gap Fibres
16.5 Non-Silica PCF
16.6.1 Spectral Sensing
16.6.2 Supercontinuum Generation
References
17.1 Introduction
17.2 Formulation of Propagation Mode Problem
17.3 Discretization of Maxwell's Equations with the Finite Element Method
17.4 Computation of Leaky Modes in Hollow Core Photonic Crystal Fibers
17.5 Goal Oriented Error Estimator
17.6 Convergence of Eigenvalues Using Different Error Estimators
17.7 Optimization of HCPCF Design
17.8 Kagome-Structured Fibers
17.9 Conclusion
References
IV Plasmonic and Metamaterials
18.2 Experimental Investigations
18.3 Calculation of Effective Permittivity
18.3.1 Extensions of the Method
18.4 Summary
References
19.1 Introduction
19.2 Sample Description and Disorder Models
19.3 Transmission Properties
19.4 Bandstructure
References
20.1 Introduction
20.2.1 Effective-Medium Approach
20.2.2 Direct Numerical Solution of Maxwell Equations for Photonic Crystals
20.3 Focusing of Scanning Light Beams Below the Diffraction Limit Using a Saturable Absorber and a Negative-Refraction Material
20.3.1 Effective-Medium Approach
20.3.2 Direct Numerical Solution of Maxwell Equations for Photonic Crystals
20.4.1 Effective-Medium Approach
20.4.2 Direct Numerical Solution of Maxwell Equations for Photonic Crystals
20.5 Conclusion
References
21.1 Introduction
21.2 Design
21.3.1 Wave Transmission Through the Superlattice Slab: Evidence for Negative Phase Velocity
21.3.2 Refraction Through a Superlattice Prism
21.3.3 Determination of the Refractive Indices Using the Equal Frequency Contours
21.4 Conclusions and Future Directions
References
22.1 Introduction
22.2.1 Transmission Line Analysis
22.2.1.1 Three Basic TL Circuits
22.2.1.2 Role of the Series Capacitance
22.2.2.1 Metamaterials with Different Unit Cells
22.2.2.2 Numerical Simulation of Meander Structures
22.3.1.1 Plane Metallic Matrices
22.3.1.2 Novel Meander Structure
22.3.2 Characterization of Fabricated Structures
22.3.2.1 Experimental Results of Meander Strips
22.3.2.2 Experimental Results of Meander Plates
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