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《激光在原子气体及电介质中的空间控制(英文版)》对作者在博士后期间在相关研究方向上取得的成果进行了详细介绍,内容紧紧围绕围绕";原子介质及电介质材料中的光束空间调控这一课题。
作者简介
作者:张贻齐、米利沃·贝里奇(Belic Milivoj)、张彦鹏
目录
《博士后文库》序言
FoREWORD
Chapter 1 BASIC THEORY
1.1 The paraxial wave equation
1.2 Susce Dtibilities in atomic vapors
REFERENCES
Chapter 2 SPATIAL LIGHT CONTROL
2.1 Photonic topological insulators in atomic ensembles
2.1.1 Theoretical model
2.1.2 Refractive index change
2.1.3 Topology of the photonic band gap structure
2.1.4 Photonic Floquet topological insulator
2.1.5 Discussion
2.1.6 Summary
Appendix Ⅰ:Band structure of a honeycomb lattice—the tight—binding
method
AⅠ.1 Full band structure
AⅠ.2 Strained band structure
Appendix Ⅱ: Band structure of a honeycomb lattice—the plane—wave
expansion method
2.2 Talbot effect of multi—wave mixings
2.2.1 Theoretical model and analysis
2.2.2 Suppression and enhancement conditions
2.2.3 Talbot effect of multi—wave mixing signals
2.2.4 Summary
2.3 Nonlinear Taibot effect from rogue waves
2.3.1 Basic rogue wave solutions
2.3.2 One—dimensional case
2.3.3 Two—dimensional case—linear ralbot effect
2.3.4 Two—dimensional case nonlinear Tallbot effect
2.3.5 Summary
2.4 Beam splitter and combiner based on Bloch oscillations
2.4.1 Waveguide array with m≤=0 members modulated
ⅷ Spatial Control of Laser Light in Atomic Vapors and Dielectric Media
2.4.2 Beam splitter based on the V—type modulated waveguide array
2.4.3 Beam combiner based on the A—type modulated waveguide array
2.4.4 Summary
REFERENCES
Chapter 3 NONLINEARITY—INDUCED SPATIAL
MODULATION
3.1 Introduction
3.2 Optical vortices induced in atomic vapors
3.2.1 Theoretical model
3.2.2 Simple vortex and necklace incidence
3.2.3 Azimuthon incidence
3.2.4 The enhancement region
3.2.5 The liquid—like behavior of light and potential experiment
3.2.6 Summary
3.3 Interactions between incoherent solitons
3.3.1 Theoretical model
3.3.2 Numerical simulations and discussions
3.3.3 Summary
3.4 Azimuthons in weakly nonlinear waveguides
3.4.1 Theoretical model
3.4.2 Rotating localized dipoles
3.4.3 Rotating higher order localized modes
3.4.4 Summary
REFERENCES
Chapter 4 SPATIAL CoNTRoL of NOVEL LIGHT BEAMS.
4.1 Introduction
4.2 Interactions between Airy beams
4.2.1 Theoretical model
4.2.2 Interactions of Airy beams
4.2.3 Interactions of nonlinear accelerating beams
4.2.4 Interactions of different accelerating beams
4.2.5 Summary
4.3 Airy beams with initial velocity
4.3.1 One—dimensional case
4.3.2 Two—dimensional case
4.3.3 A little discussion
4.3.4 Summary
4.4 Dual accelerating Airy—Talbot recurrence effect
4.4.1 Theoretical model
4.4.2 Numerical simulations
4.4.3 Superposition of finite—energy Airy beams
4.4.4 Summary
4.5 Nonparaxial self_accelerating beams
4.5.1 Theoretical model
4.5.2 Mathieu beams
4.5.3 Weber beams
4.5.4 Fresnel integrals
4.5.5 Summary
4.6 Fresnel diffraction patterns as self_accelerating beams
4.6.1 One—dimensional case
4.6.2 Two—dimensional case
4.6.3 Summary
4.7 Spatial control of light due to harmonic potential
4.7.1 Theoretical model
4.7.2 Solutions and numerical simulations
4.7.3 Chirped finite energy Airy beams
4.7.4 Two—dimensional Airy beams
4.7.5 Two—dimensional case—the rotating light
4.7.6 Summary
4.8 Self—Fourier beams
4.8.1 Theoretical model
4.8.2 Discussion
4.8.3 Analytical solutions
4.8.4 Self—Fourier beams
4.8.5 Summary
4.9 Spatial control in a fractional Schrsdinger equation
4.9.1 Theoretical model
4.9.2 One—dimensional case
4.9.3 Two—dimensional case
4.9.4 Summary
REFERENCES
Chap.ter 5 CONCLUSION AND OUTLOOK
5.1 Summary
5.2 Outlook
REFERENCES
编后记
文摘
版权页:
插图:
《激光在原子气体及电介质中的空间控制(英文版)》对作者在博士后期间在相关研究方向上取得的成果进行了详细介绍,内容紧紧围绕围绕";原子介质及电介质材料中的光束空间调控这一课题。
作者简介
作者:张贻齐、米利沃·贝里奇(Belic Milivoj)、张彦鹏
目录
《博士后文库》序言
FoREWORD
Chapter 1 BASIC THEORY
1.1 The paraxial wave equation
1.2 Susce Dtibilities in atomic vapors
REFERENCES
Chapter 2 SPATIAL LIGHT CONTROL
2.1 Photonic topological insulators in atomic ensembles
2.1.1 Theoretical model
2.1.2 Refractive index change
2.1.3 Topology of the photonic band gap structure
2.1.4 Photonic Floquet topological insulator
2.1.5 Discussion
2.1.6 Summary
Appendix Ⅰ:Band structure of a honeycomb lattice—the tight—binding
method
AⅠ.1 Full band structure
AⅠ.2 Strained band structure
Appendix Ⅱ: Band structure of a honeycomb lattice—the plane—wave
expansion method
2.2 Talbot effect of multi—wave mixings
2.2.1 Theoretical model and analysis
2.2.2 Suppression and enhancement conditions
2.2.3 Talbot effect of multi—wave mixing signals
2.2.4 Summary
2.3 Nonlinear Taibot effect from rogue waves
2.3.1 Basic rogue wave solutions
2.3.2 One—dimensional case
2.3.3 Two—dimensional case—linear ralbot effect
2.3.4 Two—dimensional case nonlinear Tallbot effect
2.3.5 Summary
2.4 Beam splitter and combiner based on Bloch oscillations
2.4.1 Waveguide array with m≤=0 members modulated
ⅷ Spatial Control of Laser Light in Atomic Vapors and Dielectric Media
2.4.2 Beam splitter based on the V—type modulated waveguide array
2.4.3 Beam combiner based on the A—type modulated waveguide array
2.4.4 Summary
REFERENCES
Chapter 3 NONLINEARITY—INDUCED SPATIAL
MODULATION
3.1 Introduction
3.2 Optical vortices induced in atomic vapors
3.2.1 Theoretical model
3.2.2 Simple vortex and necklace incidence
3.2.3 Azimuthon incidence
3.2.4 The enhancement region
3.2.5 The liquid—like behavior of light and potential experiment
3.2.6 Summary
3.3 Interactions between incoherent solitons
3.3.1 Theoretical model
3.3.2 Numerical simulations and discussions
3.3.3 Summary
3.4 Azimuthons in weakly nonlinear waveguides
3.4.1 Theoretical model
3.4.2 Rotating localized dipoles
3.4.3 Rotating higher order localized modes
3.4.4 Summary
REFERENCES
Chapter 4 SPATIAL CoNTRoL of NOVEL LIGHT BEAMS.
4.1 Introduction
4.2 Interactions between Airy beams
4.2.1 Theoretical model
4.2.2 Interactions of Airy beams
4.2.3 Interactions of nonlinear accelerating beams
4.2.4 Interactions of different accelerating beams
4.2.5 Summary
4.3 Airy beams with initial velocity
4.3.1 One—dimensional case
4.3.2 Two—dimensional case
4.3.3 A little discussion
4.3.4 Summary
4.4 Dual accelerating Airy—Talbot recurrence effect
4.4.1 Theoretical model
4.4.2 Numerical simulations
4.4.3 Superposition of finite—energy Airy beams
4.4.4 Summary
4.5 Nonparaxial self_accelerating beams
4.5.1 Theoretical model
4.5.2 Mathieu beams
4.5.3 Weber beams
4.5.4 Fresnel integrals
4.5.5 Summary
4.6 Fresnel diffraction patterns as self_accelerating beams
4.6.1 One—dimensional case
4.6.2 Two—dimensional case
4.6.3 Summary
4.7 Spatial control of light due to harmonic potential
4.7.1 Theoretical model
4.7.2 Solutions and numerical simulations
4.7.3 Chirped finite energy Airy beams
4.7.4 Two—dimensional Airy beams
4.7.5 Two—dimensional case—the rotating light
4.7.6 Summary
4.8 Self—Fourier beams
4.8.1 Theoretical model
4.8.2 Discussion
4.8.3 Analytical solutions
4.8.4 Self—Fourier beams
4.8.5 Summary
4.9 Spatial control in a fractional Schrsdinger equation
4.9.1 Theoretical model
4.9.2 One—dimensional case
4.9.3 Two—dimensional case
4.9.4 Summary
REFERENCES
Chap.ter 5 CONCLUSION AND OUTLOOK
5.1 Summary
5.2 Outlook
REFERENCES
编后记
文摘
版权页:
插图:
| ISBN | 9787030488725 |
|---|---|
| 出版社 | 科学出版社 |
| 作者 | 张贻齐 |
| 尺寸 | 5 |