Photonic Crystals: Introduction, Applications and TheoryAlessandro Massaro BoD – Books on Demand, 2012年3月30日 - 358 頁 The first volume of the book concerns the introduction of photonic crystals and applications including design and modeling aspects. Photonic crystals are attractive optical materials for controlling and manipulating the flow of light. In particular, photonic crystals are of great interest for both fundamental and applied research, and the two dimensional ones are beginning to find commercial applications such as optical logic devices, micro electro-mechanical systems (MEMS), sensors. The first commercial products involving two-dimensionally periodic photonic crystals are already available in the form of photonic-crystal fibers, which use a microscale structure to confine light with radically different characteristics compared to conventional optical fiber for applications in nonlinear devices and guiding wavelengths. The goal of the first volume is to provide an overview about the listed issues. |
內容
Chapter | 3 |
Chapter | 9 |
Basics of the Photonic Crystal Gratings | 25 |
MEMS Based Deep 1D Photonic Crystal | 81 |
and Photonic Logic Gate Design | 133 |
Interferometer for Humidity Sensing | 159 |
Optical Solitons from a Photonic Crystal | 201 |
LongPeriod Gratings Based | 225 |
MultiWavelength Photonic Crystal Fiber Laser | 253 |
Overview of Computational | 267 |
Coupled Mode Theory of Photonic Crystal Lasers | 291 |
Fourier Factorization in the Plane Wave | 325 |
其他版本 - 查看全部
常見字詞
applied band beam blue Bragg calculated cavity cell coefficient coloration components consider core corresponding coupling dependence detection device dielectric direction dispersion distribution effect electric elements equation et al example factorization fiber fibre field Figure filter frequency function fusion grating holes humidity incident increases input intensity interference laser lattice layer length light logic gates loss material matrix measured medium method mirror mode Model normal observed obtained operation optical output parameters peak periodic phase photonic crystal Physics plane polarization presented probe propagation properties pulse range reflection refractive index relative resonance respectively RGWN scattering sensitivity sensor shift shown in Fig shows signal single soliton pulse space spectral spectrum splice square strain structure surface temperature transmission transmittance values vector wave waveguides wavelength