Photonic Crystals and Light Localization in the 21st CenturyC.M. Soukoulis Springer Science & Business Media, 31 mei 2001 - 605 pagina's This volume contains papers presented at the NATO Advanced Study Institute (ASI) Photonic Crystals and Light Localization held at the Creta Maris Hotel in Limin Hersonissou, Crete, June 18-30, 2000. Photonic crystals offer unique ways to tailor light and the propagation of electromagnetic waves (EM). In analogy to electrons in a crystal, EM waves propagating in a structure with a periodically modulated dielectric constant are organized into photonic bands, separated by gaps where propagating states are forbidden. There have been proposals for novel applications ofthese photonic band gap (PBG) crystals, with operating frequencies ranging from microwave to the optical regime, that include zero threshold lasers, low-loss resonators and cavities, and efficient microwave antennas. Spontaneous emission, suppressed for photons in the photonic band gap, offers novel approaches to manipulate the EM field and create high-efficiency light-emitting structures. Innovative ways to manipulate light can have a profound iofluence on science and technology. |
Inhoudsopgave
PHOTONIC CRYSTALS INTRODUCTION | 1 |
3D PHOTONIC CRYSTALS FROM MICROWAVES TO OPTICAL FREQUENCIES | 25 |
TUNABLE PHOTONIC CRYSTALS | 41 |
ACOUSTIC BAND GAP MATERIALS | 59 |
THE FINITE DIFFERENCE TIME DOMAIN METHOD FOR THE STUDY OF TWODIMENSIONAL ACOUSTIC AND ELASTIC BAND GAP MA... | 69 |
PHOTONIC CRYSTALS FABRICATION AND APPLICATION | 83 |
SEMICONDUCTOR PHOTONIC CRYSTALS | 93 |
LIGHT PROPAGATION CHARACTERISTICS OF DEFECT WAVEGUIDES IN A PHOTONIC CRYSTAL SLAB | 105 |
PHOTONIC CRYSTALS METALLIC STRUCTURES | 329 |
LEFTHANDED METAMATERIALS | 351 |
TOWARDS COMPLETE PHOTONIC BAND GAP STRUCTURES BELOW INFRARED WAVELENGTHS | 373 |
EFFECT OF MODERATE DISORDER ON THE ABSORBANCE OF PLASMA SPHERES DISTRIBUTED IN A HOST DIELECTRIC MEDIUM | 383 |
RANDOM LASERS | 389 |
ANALYSIS OF RANDOM LASERS IN THIN FILMS OF CONJUGATED POLYMERS | 405 |
THEORY AND SIMULATIONS OF RANDOM LASERS | 417 |
CAVITY APPROACH TOWARDS A COHERENT RANDOM LASER | 435 |
APPLICATIONS OF TWODIMENSIONAL PHOTONIC CRYSTALS TO SEMICONDUCTOR OPTOELECTRONIC DEVICES | 117 |
PATTERNED PHOTONIC CRYSTAL WAVEGUIDES | 129 |
PHOTONIC CRYSTALS FROM MACROPOROUS SILICON | 143 |
CHARACTERIZATION OF A THREEDIMENSIONAL MICROWAVE PHOTONIC BANDGAP CRYSTAL | 155 |
ONEDIMENSIONAL PERIODIC STRUCTURES UNDER A NEW LIGHT | 173 |
DEFECT MODES IN QUASIONEDIMENSIONAL PHOTONIC WAVEGUIDESAPPLICATION TO THE RESONANT TUNNELING BETWEEN T... | 181 |
PHOTONIC CRYSTALS FABRICATION BY SELF ORGANIZATION | 191 |
INVERSE OPALS FABRICATION | 219 |
THE COMPLETE PHOTONIC BAND GAP IN INVERTED OPALS HOW CAN WE PROVE IT EXPERIMENTALLY? | 229 |
MANIPULATING COLLOIDAL CRYSTALLIZATION FOR PHOTONIC APPLICATIONS FROM SELFORGANIZATION TO DOITYOURSELF O... | 239 |
THIN OPALINE PHOTONIC CRYSTALS | 253 |
TUNABLE SHEARORDERED FACECENTERED CUBIC PHOTONIC CRYSTALS | 263 |
PHOTONIC CRYSTALS APPLICATIONS | 279 |
PHOTONIC CRYSTAL FIBERS EFFECTIVEINDEX AND BANDGAP GUIDANCE | 305 |
APPLICATIONS OF PHOTONIC CRYSTALS TO DIRECTIONAL ANTENNAS | 321 |
LOCALIZATION OF LIGHT | 447 |
RADIATIVE TRANSFER OF LOCALIZED WAVES | 475 |
DYNAMICS OF LOCALIZATION IN A WAVEGUIDE | 489 |
FROM PROXIMITY RESONANCES TO ANDERSON LOCALIZATION | 509 |
PHOTONIC CRYSTALS AND NONLINEARITIES | 519 |
MULTIPOLE METHODS FOR PHOTONIC CRYSTAL CALCULATIONS | 527 |
UNDERSTANDING SOME PHOTONIC BAND GAP PROBLEMS BY USING PERTURBATION | 535 |
TIGHTBINDING WANNER FUNCTION METHOD FOR PHOTONIC BAND GAP MATERIALS | 545 |
12 AND 3 DIMENSIONAL PHOTONIC MATERIALS MADE USING ION BEAMS FABRICATION AND OPTICAL DENSITYOFSTATES | 555 |
PERCOLATION COMPOSITES LOCALIZATION OF SURFACE PLASMONS AND ENHANCED OPTICAL NONLINEARITIES | 567 |
QUADRATIC NONLINEAR INTERACTIONS IN 1DIMENSIONAL PHOTONIC CRYSTALS | 577 |
QUADRATIC NONLINEAR INTERACTIONS IN 3DEMENSIONAL PHOTONIC CRYSTALS | 589 |
AUTHOR INDEX | 601 |
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Overige edities - Alles bekijken
Photonic Crystals and Light Localization in the 21st Century C.M. Soukoulis Gedeeltelijke weergave - 2012 |
Veelvoorkomende woorden en zinsdelen
3D photonic absorption amplitude Anderson localization angle antenna band structure Bragg Bragg diffraction Brillouin zone C.M. Soukoulis calculated cavity colloidal crystal corresponding coupling curve cylinders defect density dielectric diffraction diffusion dipole direction disorder dispersion effective electric field electromagnetic electron equations etching experimental fabricated FDTD fiber Figure film finite frequency function group velocity incident intensity inverse opal Lagendijk lattice lattice constant layer length Lett measured medium metal method microwave mirrors monopole antenna nonlinear obtained optical parameters particles peak periodic phase photonic band gap photonic crystal Phys plane wave propagation properties pulse radiation radius random laser reflection refractive index refractive index contrast resonant rods sample scattering semiconductor shown in Fig silica silicon SiO2 slab solid line spectra spectrum spheres spontaneous emission stop gap substrate surface symmetry theoretical thickness three-dimensional transmission coefficient unit cell wave vector waveguide wavelength width
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