介电体超晶格 下册
作者:朱永元 等编著
出版时间: 2017年版
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,《介电体超晶格(下)》是介电体超晶格的下半部分内容,是由作者团队从有关介电体超晶格研究的数百篇文章中精选出的部分内容,能清晰地描绘出该领域的发展轨迹、学术系统和科学内涵
目录
第五章 离子型声子晶体与超构材料
5.1 Optical Properties of an Ionic-Type Phononic Crystal
5.2 New Type of Polariton in a Piezoelectric Superlattice
5.3 Piezoelectric-Induced Polariton Coupling in a Superlattice
5.4 Phonon-polaritons in Quasiperiodic Piezoelectric Superlattices
5.5 Coupling of Electromagnetic Waves and Superlattice Vibrations in a
Piezomagnetic Superlattice: Creation of a Polariton Through the Piezomagnetic Effect
5.6 Coupled Phonon Polaritons in a Piezoelectric-piezomagnetic Superlattice
5.7 Mimicing Surface Phonon Polaritons in Microwave Band Based on Ionic-type Phononic Crystal
5.8 Magnetic Plasmon Hybridization and Optical Activity at Optical Frequencies in Metallic Nanostructures
5.9 Stereometamaterials
5.10 Magnetic Plasmon Propagation Along a Chain of Connected Subwavelength Resonators at Infrared Frequencies
5.11 Long-Wavelength Optical Properties of a Plasmonic Crystal
第六章 准相位匹配量子光学与光子芯片
6.1 Transforming Spatial Entanglement Using a Domain-Engineering Technique
6.2 Compact Engineering of Path-Entangled Sources from a Monolithic Quadratic Nonlinear Photonic Crystal
6.3 On-chip Steering of Entangled Photons in Nonlinear Photonic Crystals
6.4 Lensless Imaging by Entangled Photons from Quadratic Nonlinear Photonic Crystals
6.5 Observation of Quantum Talbot Effect from a Domain-engineered Nonlinear Photonic Crystal
6.6 Mode-locked Biphoton Generation by Concurrent Quasi-phase-matching
6.7 Generation of NOON State with Orbital Angular Momentum in a Twisted Nonlinear Photonic Crystal
6.8 Tailoring Entanglement Through Domain Engineering in a Lithium Niobate Waveguide
6.9 On-Chip Generation and Manipulation of Entangled Photons Based on Reconfigurable Lithium-Niobate Waveguide Circuits
6.10 Generation of Three-mode Continuous-variable Entanglement by Cascaded Nonlinear Interactions in a Quasiperiodic Superlattice
第七章 介电体超晶格与畴工程学
7.1 The Growth Striations and Ferroelectric Domain Structures in Czochralski-grown LiNbO3 Single Crystals
7.2 Growth of Optical Superlattice LiNbO3 with Different Modulating Periods and Its Applications in Second-harmonic Generation
7.3 Growth of Nd3+-doped LiNbO3 Optical Superlattice Crystals and Its Potential Applications in Self-frequency Doubling
7.4 Fabrication of Acoustic Superlattice LiNbO3 by Pulsed Current Induction and
Its Application for Crossed Field Ultrasonic Excitation
7.5 LiTaO3 Crystal Periodically Poled by Applying an External Pulsed Field
7.6 Poling Quality Evaluation of Optical Superlattice Using 2D Fourier Transform Method
7.7 Frequency Self-doubling Optical Parametric Amplification. Noncollinear Red-
green-blue Lightsource Generation based on a Hexagonally Poled Lithium Tantalate
7.8 Direct Observation of Ferroelectric Domains in LiTaO3 Using Environmental Scanning Electron Microscopy
7.9 Nondestructive Imaging of Dielectric-Constant Profiles and Ferroelectric Domains with
a Scanning-Tip Microwave Near-Field Microscope
第八章 光学超晶格的应用研究
8.1 Efficient Continuous Wave Blue Light Generation in Optical Superlattice
LiNbO3 by Direct Frequency Doubling a 978 nm InGaAs Diode Laser
8.2 Femtosecond Violet Light Generation by Quasi-phase-matched Frequency
Doubling in Optical Superlattice LiNbO3
8.3 Visible Dual-wavelength Light Generation in Optical Superlattice Er: LiNbO3
through Upconversion and Quasi-phase-matched Frequency Doubling
8.4 Frequency Tuning of Optical Parametric Generator in Periodically Poled
Optical Superlattice LiNbO3 by Electro-optic Effect
8.5 Electro-optic Effect of Periodically Poled Optical Superlattice LiNbO3
and Its Applications
8.6 High-power Red-green-blue Laser Light Source Based on Intermittent
Oscillating Dual-wavelength Nd.YAG Laser with a Cascaded LiTaO3 Superlattice
8.7 Diode-pumped 1988-nm Tm.YAP Laser Mode-locked by Intracavity
Second-harmonic Generation in Periodically Poled LiNbO3
8.8 Efficiency-enhanced Optical Parametric Down Conversion for Mid-infrared
Generation on a Tandem Periodically Poled MgO-doped Stoichiometric Lithium Tantalate Chip
8.9 Polarization-free Second-order Nonlinear Frequency Conversion Using the Optical Superlattice
8.10 Polarization Independent Quasi-phase-matched Sum Frequency Generation for Single Photon Detection
8.11 DFB Semiconductor Lasers based on Reconstruction-equivalent-chirp Technology
8.12 High Channel Count and High Precision Channel Spacing Multi-wavelength
第九章 总结与展望
附录 最新的重要成果收录