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9780819449474
Introduction to Complex Mediums for Optics and Electromagnetics available in Hardcover
Introduction to Complex Mediums for Optics and Electromagnetics
by Werner S. Wieglhofer, A. Lakhtakia
Werner S. Wieglhofer
- ISBN-10:
- 0819449474
- ISBN-13:
- 9780819449474
- Pub. Date:
- 08/28/2003
- Publisher:
- SPIE Press
- ISBN-10:
- 0819449474
- ISBN-13:
- 9780819449474
- Pub. Date:
- 08/28/2003
- Publisher:
- SPIE Press
Introduction to Complex Mediums for Optics and Electromagnetics
by Werner S. Wieglhofer, A. Lakhtakia
Werner S. Wieglhofer
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Overview
This book is a collection of essays to explain complex mediums for optical and electromagnetic applications. The genesis of this book lies in a series of conferences organized at the successive Annual Meetings of SPIE from 1999 to 2002. The scope of Conference 3790, Engineered Nanostructural Thin Films and Materials, was not fully explained by its title. Subsequently, Conference 4097 was entitled Complex Mediums. Further explication being needed, Conference 4467 was named Complex Mediums II: Beyond Linear Isotropic Dielectrics and was followed by Conference 4806 Complex Mediums III: Beyond Linear Isotropic Dielectrics. All four were organized by me, very ably assisted by Werner S. Weiglhofer, Russell F. Messier, Ian J. Hodgkinson, Martin W. McCall, and Graeme Dewar. A multitude of CME researchers participated wholeheartedly.
Product Details
| ISBN-13: | 9780819449474 |
|---|---|
| Publisher: | SPIE Press |
| Publication date: | 08/28/2003 |
| Series: | SPIE Press Monograph Series |
| Pages: | 776 |
| Product dimensions: | 7.16(w) x 10.02(h) x 1.90(d) |
Table of Contents
| Foreword | xxi | |
| Preface | xxv | |
| List of Contributors | xxxi | |
| Part I | General | |
| Separating Field and Constitutive Equations in Electromagnetic Theory | 3 | |
| The beginnings | 4 | |
| Georgi's rationalization | 5 | |
| Georgi version of Minkowski electrodynamics | 7 | |
| SR(3)'s suffocating hold on field theories | 11 | |
| Mathematical specifics | 14 | |
| Conclusion | 22 | |
| References | 24 | |
| Constitutive Characterization of Simple and Complex Mediums | 27 | |
| Introduction: the curtain rises | 28 | |
| Basics: the Maxwell equations | 30 | |
| Setting the stage: constitutive relations | 32 | |
| Exploring the stage: simple mediums | 34 | |
| A plethora of complex mediums | 37 | |
| Regulating the stage: symmetries and constraints | 49 | |
| Preparing the stage: homogenization | 53 | |
| Concluding remarks | 55 | |
| References | 55 | |
| Isotropic Chiral Materials | 63 | |
| Introduction | 64 | |
| Polarization: the simple truth | 65 | |
| Circular birefringence and circular dichroism | 67 | |
| A digression on vectors | 70 | |
| Electromagnetic fields in a chiral material | 72 | |
| Essential reading | 76 | |
| References | 76 | |
| Point Group Symmetries | 79 | |
| Point groups | 80 | |
| Physical property tensors | 82 | |
| Tensor distinction of domains in ferroic crystals | 83 | |
| Domain tensors and tensor invariants | 92 | |
| Domain average engineering of ferroics | 94 | |
| Conclusions | 96 | |
| Appendix A | Point group symbols | 96 |
| Appendix B | Form of tensors | 97 |
| References | 98 | |
| Part II | Nonlinear Optical Materials | |
| Nonlinear Optics Using Semiconductor Quantum Wells | 105 | |
| Introduction | 106 | |
| Theoretical nonlinear optics | 108 | |
| Quantum wells | 110 | |
| Second-order quasi-phase-matching | 113 | |
| Third-order nonlinearity | 116 | |
| Conclusions | 118 | |
| References | 118 | |
| Organic Thin-Film Photorefractive Materials | 121 | |
| Introduction | 122 | |
| Photorefractive polymers | 123 | |
| Engineering photorefractive polymers | 124 | |
| Wave mixing in photorefractive polymers | 127 | |
| Real-time edge enhancement | 131 | |
| Edge-enhanced correlation | 133 | |
| Conclusion | 136 | |
| References | 137 | |
| Optical Energy Harvesting Materials | 141 | |
| Introduction | 142 | |
| Precepts from photobiology | 143 | |
| Resonance energy transfer | 145 | |
| Dendrimers | 149 | |
| Rare-earth materials for energy pooling | 151 | |
| Energy pooling in multichromophore arrays | 155 | |
| The future of energy pooling | 157 | |
| References | 158 | |
| Part III | Magnetic Materials | |
| Magnetoelectric Effects in Insulating Magnetic Materials | 167 | |
| Introduction | 168 | |
| Thermodynamic potential | 169 | |
| Linear and bilinear magnetoelectric effects | 172 | |
| Spontaneous magnetoelectric effects and related phenomenons | 178 | |
| Selected applications | 181 | |
| Conclusions | 187 | |
| References | 188 | |
| Magneto-optics: A Critical Review | 197 | |
| Introduction | 198 | |
| Linear magneto-optics of bulk material | 201 | |
| Envelopes in a waveguide | 207 | |
| Complex planar waveguide | 213 | |
| Vector solitons | 216 | |
| Concluding remarks | 217 | |
| References | 219 | |
| Static and Dynamic Magnetoelasticity | 223 | |
| Introduction | 224 | |
| Magnetoelastic interaction | 225 | |
| Static and dynamic measurements | 236 | |
| Villari and [Delta]E effects | 239 | |
| Wiedemann effect | 240 | |
| Conclusion | 241 | |
| References | 242 | |
| Frequency Shifts Induced by a Time-Varying Magnetoplasma Medium | 245 | |
| Introduction | 246 | |
| Frequency change due to a temporal discontinuity in the medium properties | 246 | |
| Time-varying plasma medium | 248 | |
| Sudden creation of an unbounded plasma medium | 251 | |
| Switched plasma slab | 253 | |
| Applications | 254 | |
| Time-varying magnetoplasma medium | 255 | |
| Conclusion | 262 | |
| References | 264 | |
| Magnetoimpedance in Multilayered Films for Miniature Magnetic Sensors | 267 | |
| Introduction | 268 | |
| Analysis of MI in multilayer structures | 269 | |
| Asymmetric magnetoimpedance (AMI) | 275 | |
| Experimental methods | 278 | |
| Film preparation and experimental results | 280 | |
| Practical MI sensor design | 286 | |
| Conclusions | 288 | |
| References | 289 | |
| Part IV | Composite Materials | |
| Metamaterials: An Introduction | 295 | |
| Introduction | 296 | |
| Conventional macroscopic composites | 297 | |
| Examples of metamaterials | 303 | |
| Electromagnetic metamaterials | 306 | |
| Conclusions | 313 | |
| References | 314 | |
| Homogenization of Linear and Nonlinear Complex Composite Materials | 317 | |
| Introduction | 318 | |
| Preliminaries | 319 | |
| Conventional approaches to homogenization | 322 | |
| SPFT homogenization | 325 | |
| Weakly nonlinear regime | 330 | |
| Concluding remarks | 337 | |
| Appendix 1 | 338 | |
| Appendix 2 | 341 | |
| References | 342 | |
| Negative Phase-Velocity Mediums | 347 | |
| Introduction | 348 | |
| Phenomenology | 350 | |
| Experimental evidence | 354 | |
| Terminology | 357 | |
| Research trends | 357 | |
| Concluding remarks | 358 | |
| References | 359 | |
| Scattering Theory of Photonic Crystals | 365 | |
| Introduction | 366 | |
| Scattering theory of photonic crystals | 367 | |
| Two-dimensional photonic crystals | 378 | |
| Resonant modes | 385 | |
| Current problems and future directions | 388 | |
| Concluding remarks | 390 | |
| References | 390 | |
| Part V | Nanostructured Materials | |
| Optical Properties of Metal-Dielectric Films | 397 | |
| Introduction | 398 | |
| Generalized Ohm's law approximation and giant fluctuations of local electromagnetic fields | 399 | |
| Surface plasmon polaritons | 403 | |
| Resonant transmission | 404 | |
| Light-induced resonant transmission | 408 | |
| Extraordinary optical transmittance through nanoholes | 409 | |
| Electric and magnetic resonances | 411 | |
| Light circuiting in nanoholes | 413 | |
| Concluding remarks | 414 | |
| References | 415 | |
| Nanostructured Thin Films | 421 | |
| Introduction | 422 | |
| Nanostructured films containing conductors: an overview | 426 | |
| Thin films containing nanoparticles | 429 | |
| Metal thin films on dielectric nanoparticles and nanostructures | 438 | |
| Dense arrays, clusters touching particles | 440 | |
| Conclusions | 442 | |
| References | 443 | |
| The Past, the Present, and the Future of Sculptured Thin Films | 447 | |
| Introduction | 448 | |
| From columnar to sculptured thin films | 449 | |
| Electromagnetic field equations | 458 | |
| Applications of STFs | 461 | |
| Future research directions | 467 | |
| References | 468 | |
| Towards Optoelectronic Applications of Chiral Sculptured Thin Films | 479 | |
| Introduction | 480 | |
| Preliminaries | 481 | |
| Chiral sculptured thin films | 484 | |
| Full electromagnetic analysis | 486 | |
| The optical response of a CSTF to axial excitation | 488 | |
| Coupled-wave techniques | 491 | |
| The multireflectivity model of CSTFs | 493 | |
| Applications | 495 | |
| Conclusion | 502 | |
| References | 504 | |
| Electromagnetics of Carbon Nanotubes | 507 | |
| Introduction | 508 | |
| Electron transport in carbon nanotubes | 509 | |
| Linear electrodynamics of carbon nanotubes | 515 | |
| Nonlinear processes in nanotubes | 524 | |
| Quantum electrodynamics of carbon nanotubes | 532 | |
| Conclusion | 539 | |
| References | 540 | |
| Part VI | Patterns and Statistics | |
| Randomness in Complex Materials | 549 | |
| Introduction | 550 | |
| Raw material for self-organization | 551 | |
| Random lasing in scattering solid-state materials | 552 | |
| Ease of manufacturing | 559 | |
| Uniformization of optical roperties | 563 | |
| Conclusion | 564 | |
| References | 566 | |
| Nonlinear Spatial Structures | 571 | |
| General introduction | 572 | |
| Pattern formation in nonlinear optics | 576 | |
| Solitonlike self-localized structures | 580 | |
| Conclusions | 585 | |
| References | 585 | |
| Statistical Approaches to Scattering | 591 | |
| Introduction | 592 | |
| Elements of the statistical vocabulary | 592 | |
| The statistical approach | 594 | |
| Application I: Crosstalk | 595 | |
| Transmission-line coupling | 600 | |
| Results | 601 | |
| Conclusion | 606 | |
| References | 606 | |
| Elastic Orthonormal Beams and Localized Fields | 609 | |
| Introduction | 610 | |
| Basic relations | 612 | |
| Superpositions of longitudinal eigenwaves | 621 | |
| Superpositions of transverse eigenwaves | 627 | |
| Complex field structures | 634 | |
| Conclusion | 637 | |
| References | 638 | |
| Part VII | Measurements | |
| Polarimeter for Anisotropic Optically Active Materials | 645 | |
| Introduction | 646 | |
| Optical activity | 649 | |
| Principle of high-accuracy universal polarimeter (HAUP) | 651 | |
| Examples of experimental results | 660 | |
| Chiral physics | 669 | |
| References | 671 | |
| Generalized Ellipsometry | 677 | |
| Introduction | 678 | |
| Experimental | 679 | |
| Birefringence in stratified mediums | 679 | |
| Generalized ellipsometry | 680 | |
| Light propagation in layered anisotropic mediums | 684 | |
| Generalized ellipsometry data analysis | 688 | |
| A survey of birefringent material applications | 690 | |
| Conclusions | 703 | |
| References | 704 | |
| In memoriam: Werner S. Weiglhofer | ||
| Professor Werner S. Weiglhofer (1962-2003) | 713 | |
| Personal Memories of Werner S. Weiglhofer | 719 | |
| Werner S. Weiglhofer--A Personal Tribute | 721 | |
| Memories of Werner S. Weiglhofer | 723 | |
| My Friend Werner | 725 | |
| Published Scientific Works of Werner S. Weiglhofer | 731 | |
| Index | 749 |
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