This book describes theoretical studies and how to gain detailed control over multi-wave mixing processes in the frequency and spatial domains on a fundamental level. An introductory chapter provides an overview of the evolution of multi-wave mixing as well as basic physical concepts and mathematical techniques. A comprehensive and systematic framework is used to guide readers through the versatile range of effects and techniques associated with multi-wave mixing. These include Autler-Townes splitting of wave mixing, the controllable suppression and enhancement, and the switching of an atomic medium between transparent and absorptive states. Applications of the phenomena and techniques discussed are presented as motivation at the beginning of each chapter, while instructive exercise sections support a hands-on understanding of even complicated issues.

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Yangpeng Zhang Yangpeng Zhang received his PhD in Physics Electronics and Optical Electronics in 2000 and is now Tengfei Chair Professor at Xi'an Jiaotong University. He received numerous national science and technology young researchers awards for his theoretical studies on photonics, especially wave mixing. More than 100 papers in peer review journals and two books on all aspects of multi-wave mixing make him an ideal author for this topic. Feng Wen Feng Wen is currently PhD student at Xi'an Jiaotong University. Min Xiao Min Xiao is Distinguished Professor of Physics and holder of the 21st Century Chair in Nanotechnology at the University of Arkansas. He held positions in Shanxi University, China, and the Massachussetts Institute of Technology, received the NSF Young Investigator Award in 1994, and is a Fellow of the American Physical Society and the Optical Society of America. With more than 240 publications on related topics he is one of the experts in the field of multi-wave mixing.

InhaltsangabeChapter 1: Introduction 1.1 Suppression and enhancement conditions 1.2 Fluorescence in MWM 1.3 MWM Process in the Optical Cavity 1.4 Photonic band gap 1.4.1 Periodic Energy level 1.4.2 Method of transfer matrix 1.4.3 Nonlinear Talbot Effect 1.5 Summary Chapter 2: MWM Quantum Control via Electromagnetically Induced Transparency 2.1 Control of multi-transparency windows via dark-state phase manipulation 2.2 Controlled multi-wave mixing via interacting dark states in a five-level system 2.3 EITassisted Fourwave Mixing Process in the Diamondtype Fourlevel Atomic Systerm 2.4 Dressed odd-order multi-wave mixing in five-level atomic system 2.5 Observation of eight-wave mixing via electromagnetically induced transparency 2.6 Interference of three multi-wave mixings via electromagnetically induced transparency 2.7 Summary Chapter 3: Controllable Autler-Townes Splitting of MWM Process via Dark State 3.1 Measurement of ac-Stark shift by a two-photon dressing process via four-wave mixing 3.2 AutlerTownes splitting of FourWave Mixing image 3.3 Evidence of Autler-Townes splitting in high-order nonlinear processes 3.4 Observation of Autler-Townes splitting in six-wave mixing 3.5 Multiwave mixing AutlerTownes splitting in the fivelevel atomic system 3.6 Summary Chapter 4: Controllable Enhancement and Suppression of MWM Process via Dark State 4.1 Enhancement and suppression of four-wave mixing in EIT window 4.2 Switching between enhancement and suppression of four-wave mixing via a dressing field 4.3 Controlling the transition of bright and dark states via scanning dressing field 4.4 Multidressing Interaction of Fourwave Mixing in Threelevel Atomic System 4.5 Enhancement and suppression of two coexisting six-wave-mixing processes 4.6 Switching between enhancement and suppression of four-wave mixing via the power (zyr) 4.7 Controlling cascade dressing interaction of four-wave mixing image 4.8 Summary Chapter 5: MWM Process with Polarizable Dark State 5.1 Controlling enhancement and suppression of four-wave mixing via polarized light 5.2 Coexisting polarized four-wave mixings in two-level atomic system 5.3 Polarization Dressings of Four-wave Mixing Process in a V-type Three-level Atomic System 5.3 Observation of polarization-controlled spatial splitting of four-wave mixing in a three-level atomic systems 5.4 Polarized SWM Suppression and Enhancement 5.5 Summary Chapter 6: Exploring Non-Classical Properties of MWM Process 6.1 Opening Fluorescence Channels via Dual Electromagnetically Induced Transparency Windows 6.2 Enhancement and Suppression of Four-Wave Mixing Fluorescence 6.3 Threefield noise correlation via thirdorder nonlinear optical processes 6.4 Controllable four-wave mixing transmission signal inside an optical cavity 6.5 Continuous variable entanglement between FWM and SWM signal 6.6 Summary Chapter 7: Coherent Modulation of Photonic Band Gap in FWM Process 7.1 Surface solitons of four-wave mixing in electromagnetically induced lattice 7.2 Fourwave mixing and Sixwave mixing with Talbot effect 7.3 Spatial Interplay of Two Four-Wave Mixing Images 7.4 Observation of multi-component spatial vector solitons of four-wave mixing 7.5 Summary Chapter 8: Optical Routing and Space Demultiplexer of MWM Process 8.1 Experimental demonstration of optical switching and routing via four-wave mixing spatial shift 8.2 Alloptical routing and space demultiplexer via fourwave mixing spatial splitting 8.3 Circulator of FWM vortex 8.5 Summary References Index