书籍详情

介电体超晶格(上)

介电体超晶格(上)

作者:朱永元,王振林,陈延峰,陆延青,祝世宁 著

出版社:南京大学出版社

出版时间:2017-03-01

ISBN:9787305178405

定价:¥198.00

购买这本书可以去
内容简介
  介电体超晶格是一种在光电子学、声电子学、量子信息学领域有重大应用前景的新型功能材料,是南京大学闵乃本院士及其团队通过20多年系统深入研究开拓的一个新的研究方向。从基本原理的提出、到实验验证、到原型器件,直到实用化的仪器研制,形成了系统性的研究成果,并于2006年获得了连续空缺多年的国家自然科学一等奖。项目成果共汇总成上下两册,《介电体超晶格(上)》为上册,共分为四个专题,《介电体超晶格(上)》的出版对我国科学技术的发展具有重大价值。
作者简介
暂缺《介电体超晶格(上)》作者简介
目录
第一章 介电体超晶格的研究
第二章 准相位匹配概念的拓展和非线性光学新效应
2.1 Harmoic Generations in an Optical Fibonacci Superlattice
2.2 Second-harmonic Generation in a Fibonacci Optical Superlattice and the Dispersive
Effect of the Refractive Index
2.3 Quasi-Phase-Matched Third-Harmonic Generation in a Quasi-Periodic Optical Superlattice
2.4 Experimental Realization of Second Harmonic Generation in a Fibonacci Optical Superlattice of LiTaO3
2.5 Crucial Effects of Coupling Coefficients on Quasi-Phase-Matched Harmonic Generation
in an Optical Superlattice
2.6 Wave-Front Engineering by Huygens-Fresnel Principle for Nonlinear Optical Interactions in
Domain Engineered Structures
2.7 Conical Second Harmonic Generation in a Two-Dimensional X2 Photonic Crystal
A Hexagonally Poled LiTaO3 Crystal
2.8 Experimental Studies of Enhanced Raman Scattering from a Hexagonally Poled LiTaO3 Crystal
2.9 Nonlinear Cerenkov Radiation in Nonlinear Photonic Crystal Waveguides
2.10 Nonlinear Volume Holography for Wave-Front Engineering
2.11 Nonlinear Talbot Effect
2.12 Diffraction Interference Induced Superfocusing in Nonlinear Talbot Effect
2.13 Cavity Phase Matching via an Optical Parametric Oscillator Consisting of
a Dielectric Nonlinear Crystal Sheet
第三章 克尔非线性光学超晶格与光子晶体
3.1 Light Transmission in Two-dimensional Optical Superlattices
3.2 Optical Bistability in a Two-Dimensional Nonlinear Superlattice
3.3 Experimental Observations of Bistability and Instability in a Two-Dimensional Nonlinear Optical Superlattice
3.4 Gap Shift and Bistability in Two-dimensional Nonlinear Optical Superlattices
3.5 Optical Bistability in Two-dimensional Nonlinear Optical Superlattice with Two Incident Waves
3.6 Three-dimensional Self-assembly of Metal Nanoparticles. Possible Photonic Crystal with a Complete
Gap Below the Plasma Frequency
3.7 Parity-time Electromagnetic Diodes in a Two-dimensional Nonreciprocal Photonic Crystal
3.8 Nonreciprocal Light Propagation in a Silicon Photonic Circuit
3.9 Experimental Demonstration of a Unidirectional Reflectionless Parity-time Metamaterial at Optical Frequencies
3.10 Plasmonic Airy Beam Generated by In-Plane Diffraction
3.11 Collimated Plasmon Beam: Nondiffracting versus Linearly Focused
3.12 The Anomalous Infrared Transmission of Gold Films on Two-Dimensional Colloidal Crystals
3.13 Localized and Delocalized Surface-plasmon-mediated Light Tunneling Through Monolayer
Hexagonal-close-packed Metallic Nanoshells
3.14 Experimental Observation of Sharp Cavity Plasmon Resonances in Dielectric-metal Core-shell Resonators
3.15 Magnetic Field Enhancement at Optical Frequencies Through Diffraction Coupling of Magnetic
Plasmon Resonances in Metamaterials
第四章 声学超晶格和声子晶体
4.1 Acoustic Superlattice of LiNbO3 Crystals and Its Applications to Bulk-wave Transducers for Ultrasonic
Generation and Detection up to 800 MHz
4.2 High-frequency Resonance in Acoustic Superlattice of LiNbO3 Crystals
4.3 Ultrasonic Spectrum in Fibonacci Acoustic Superlattices
4.4 Ultrasonic Excitation and Propagation in an Acoustic Superlattice
4.5 High-frequency Resonance in Acoustic Superlattice of Periodically Poled LiTaO3
4.6 Bulk Acoustic Wave Delay Line in Acoustic Superlattice
4.7 Negative Refraction of Acoustic Waves in Two-dimensional Sonic Crystals
4.8 Acoustic Backward-Wave Negative Refractions in the Second Band of a Sonic Crystal
4.9 Negative Birefraction of Acoustic Waves in a Sonic Crystal
4.10 Extraordinary Acoustic Transmission through a 1D Grating with Very Narrow Apertures
4.11 Acoustic Surface Evanescent Wave and its Dominant Contribution to Extraordinary Acoustic
Transmission and Collimation of Sound
4.12 Tunable Unidirectional Sound Propagation through a Sonic-Crystal-Based Acoustic Diode
4.13 Acoustic Asymmetric Transmission Based on Time-dependent Dynamical Scattering
4.14 Acoustic Cloaking by a Near-zero-index Phononic Crystal
4.15 Acoustic Phase-reconstruction near the Dirac Point of a Triangular Phononic Crystal
4.16 Topologically Protected One-way Edge Mode in Networks of Acoustic Resonators with Circulating Air Flow
猜您喜欢

读书导航