Dispersion Engineering for Integrated Nanophotonics

This document was uploaded by one of our users. The uploader already confirmed that they had the permission to publish it. If you are author/publisher or own the copyright of this documents, please report to us by using this DMCA report form.

Simply click on the Download Book button.

Yes, Book downloads on Ebookily are 100% Free.

Sometimes the book is free on Amazon As well, so go ahead and hit "Search on Amazon"

This book shows how dispersion engineering in two dimensional dielectric photonic crystals can provide new effects for the precise control of light propagation for integrated nanophotonics.
Dispersion engineering in regular and graded photonic crystals to promote anomalous refraction effects is studied from the concepts to experimental demonstration via nanofabrication considerations. Self collimation, ultra and negative refraction, second harmonic generation, mirage and invisibility effects which lead to an unprecedented control of light propagation at the (sub-)wavelength scale for the field of integrated nanophotonics are detailed and commented upon.

Author(s): Olivier Vanbésien, Emmanuel Centeno
Series: Focus
Publisher: Wiley-ISTE
Year: 2014

Language: English
Pages: x+106
Tags: Electrical Electronics Circuits Digital Design Electric Machinery Motors Fiber Optics Networks Superconductivity Engineering Transportation Electromagnetism Electricity Magnetism Physics Science Math Light New Used Rental Textbooks Business Finance Communication Journalism Computer Education Humanities Law Medicine Health Sciences Reference Mathematics Social Test Prep Study Guides Specialty Boutique

INTRODUCTION vii

CHAPTER 1. Two-Dimensional Dielectric Photonic Crystals 1
1.1. Context 1
1.2. Concepts: photonic band structures and equi-frequency curves 2
1.2.1. Basic concepts on electromagnetic waves in 2D PhCs 3
1.2.2. Dispersion surfaces, equi-frequency curves and group velocity 6
1.3. Fundamental dispersion effects 8
1.3.1. The construction line method 8
1.3.2. A beam propagation model 9
1.3.3. The self-collimation effect 12
1.3.4. Mesoscopic self-collimation of light 14
1.3.5. The superprism effect 18
1.3.6. Negative refraction and -1 effective index in photonic crystals and metamaterials 20
1.4. From concepts to reality 26
1.4.1. 2D½ prototype design 27
1.4.2. Thick substrate versus membrane approach 27
1.4.3. 2D patterning and prototype designs 29
1.4.4. The 3D reality 34
1.5. Conclusion 35

CHAPTER 2. Flat Lenses 37
2.1. Context 37
2.2. Negative refraction based flat lenses 38
2.2.1. Effective parameters 38
2.2.2. A 2D photonic crystal based flat lens: dimensioning 42
2.2.3. Experiments 51
2.3. Gradient index lenses 56
2.3.1. GRIN lens concept 56
2.3.2. Negative index based GRIN lens (the hole case) 57
2.3.3. Positive index based GRIN lens (the pillar case) 59
2.3.4. Experimental evaluation of GRIN lenses 60
2.4. Conclusion 62

CHAPTER 3. Towards Transform Optics Based Devices 63
3.1. Context 63
3.2. From transform Optics to Hamiltonian optics 64
3.2.1. Transform Optics 64
3.2.2. Conformal mapping 69
3.2.3. Hamiltonian optics 70
3.3. 1D graded photonic crystals 72
3.3.1. D graded photonic crystals 75
3.4. Cloaking devices 78
3.4.1. A brief overview of optical cloaking 79
3.4.2. A III-V based photonic crystal carpet: design and fabrication 81
3.4.3. A III-V based photonic crystal carpet: evaluation and discussion 83
3.5. Conclusion 85

CONCLUSION 87
BIBLIOGRAPHY 91
INDEX 105