多波混频量子控制 英文版2025|PDF|Epub|mobi|kindle电子书版本百度云盘下载

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1 Introduction1

1.1 Suppression and Enhancement Conditions of the FWM Process2

1.1.1 Dressed State Theory2

1.1.2 Dark-State Theory in MWM Processes4

1.1.3 Suppression and Enhancement Conditions7

1.2 Fluorescence in MWM10

1.3 MWM Process in Ring Optical Cavity12

1.3.1 High-Order Cavity Mode Splitting with MWM Process13

1.3.2 Squeezed Noise Power with MWM14

1.3.3 Three-Mode Continuous-Variable Entanglement with MWM16

1.4 Photonic Band Gap17

1.4.1 Periodic Energy Level18

1.4.2 Method of Transfer Matrix19

1.4.3 Nonlinear Talbot Efflect20

1.4.4 Third-and Fifth-Order Nonlinearity21

1.5 MWM with Rydberg Blockade22

1.6 Summary24

References25

2 MWM Quantum Control via EIT29

2.1 Interference of Three MWM via EIT29

2.1.1 Experiment Setup30

2.1.2 Basic Theory31

2.1.3 Results and Discussions33

2.1.4 Conclusion39

2.2 Observation of EWM via EIT40

2.2.1 Basic Theory40

2.2.2 Experimental Results41

2.2.3 Conclusion46

2.3 Controlled MWM via Interacting Dark States46

2.3.1 Basic Theory47

2.3.2 Multi-Wave Mixing(MWM)49

2.3.2.1 Four-Wave Mixing(FWM)49

2.3.2.2 Four-Dressing SWM53

2.3.2.3 Four-Dressing EWM54

2.3.2.4 Four-Dressing EIT55

2.3.3 Numerical Results and Discussion55

2.3.3.1 Five-Dressing FWM56

2.3.3.2 Four-Dressing SWM62

2.3.3.3 Four-Dressing EWM62

2.3.3.4 Absorption and Dispersion in the Four-Dressing EIT System65

2.3.4 Discussion and Conclusion67

2.4 Observation of Dressed Odd-Order MWM68

2.4.1 Basic Theory and Experimental Scheme68

2.4.2 Dressed Odd-Order MWM70

2.4.3 Conclusion87

References87

3 Controllable Autler-Townes Splitting of MWM Process via Dark State91

3.1 Measurement of ac-Stark Shift via FWM91

3.1.1 Experiment and Basic Theory92

3.1.2 Experiment and Result95

3.1.3 Conclusion96

3.2 Evidence of AT Splitting in FWM97

3.2.1 Basic Theory97

3.2.2 Experimental Results99

3.3 Observation of AT Splitting in SWM103

3.3.1 Theoretical Model and Experimental Scheme103

3.3.2 Experiment and Result106

3.3.3 Conclusion110

References110

4 Controllable Enhancement and Suppression of MWM Process via Dark State113

4.1 Enhancing and Suppressing FWM in EIT Window113

4.1.1 Theory and Experimental Results114

4.1.2 Experiment and Result115

4.1.3 Conclusion119

4.2 Cascade Dressing Interaction of FWM Image119

4.2.1 Theoretical Model and Experimental Scheme120

4.2.2 Cascade Dressing Interaction123

4.2.3 Conclusion129

4.3 Multi-Dressing Interaction of FWM130

4.3.1 Theoretical Model131

4.3.2 Experimental Result133

4.3.2.1 Single-Dressed DFWM133

4.3.2.2 Doubly-Dressed DFWM134

4.3.2.3 Triply-Dressed DFWM139

4.3.2.4 Power Switching of Enhancement and Suppression142

4.4 Enhancement and Suppression of Two Coexisting SWM Processes144

4.4.1 Theoretical Model and Experimental Scheme145

4.4.2 Experimental Results147

4.4.3 Conclusion153

References154

5 Controllable Polarization of MWM Process via Dark State157

5.1 Enhancement and Suppression of FWM via Polarized Light157

5.1.1 Theoretical Model and Analysis158

5.1.2 Experimental Results160

5.1.3 Conclusion164

5.2 Polarization-Controlled Spatial Splitting of FWM165

5.2.1 Theoretical Model and Experimental Scheme165

5.2.2 Spatial Splitting of FWM Beam168

5.3 Coexisting Polarized FWM172

5.3.1 Experiment Setup172

5.3.2 Theoretical Model173

5.3.3 Results and Discussions178

5.4 Polarized Suppression and Enhancement of SWM184

5.4.1 Theoretical Model and Experimental Scheme184

5.4.2 Polarized Suppression and Enhancement188

5.4.3 Conclusion196

References196

6 Exploring Nonclassical Properties of MWM Process199

6.1 Opening Fluorescence and FWM via Dual EIT Windows199

6.1.1 Theory and Experimental Scheme200

6.1.2 Fluorescence and FWM via EIT Windows202

6.2 Phase Control of Bright and Dark States in FWM and Fluorescence Channels206

6.2.1 Theory and Experimental Scheme206

6.2.2 Theory and Experimental Results208

6.3 Observation of Angle Switching of Dressed FWM Image211

6.3.1 Introduction211

6.3.2 Theoretical Model and Experimental Scheme212

6.3.3 Experimental Results and Theoretical Analyses218

6.4 Three-Photon Correlation via Third-Order Nonlinear Optical Processes227

6.4.1 Theory and Experimental Scheme228

6.4.2 Theory and Experimental Results229

6.4.3 Conclusion232

6.5 Vacuum Rabi Splitting and Optical Bistability of MWM Signal Inside a Ring Cavity232

6.5.1 Introduction232

6.5.2 Basic Theory233

6.5.3 VRS of Zero-Order Mode235

6.5.3.1 Multi-Dressed VRS235

6.5.3.2 Avoided Crossing Plots237

6.5.3.3 Suppression and Enhancement of MWM238

6.5.4 VRS of High-Order Modes241

6.5.5 Steady-State Linear Gain and OPO Threshold244

6.5.6 OB Behavior of MWM246

6.5.6.1 OB of Zero-Order Mode246

6.5.6.2 OB of High-Order Modes248

6.5.7 Conclusion251

References251

7 Coherent Modulation of Photonic Band Gap in FWM Process255

7.1 Spatial Interplay of Two FWM Images255

7.1.1 Introduction255

7.1.2 Theoretical Model and Experimental Scheme256

7.1.3 The Interplay of Two FWM Beams260

7.2 Optical Vortices Induced in Nonlinear Multi-Level Atomic Vapors267

7.2.1 Introduction267

7.2.2 Theoretical Model and Numerical Simulation267

7.2.3 Conclusion271

7.3 Multi-Component Spatial Vector Solitons of FWM272

7.3.1 Basic Theory and Experimental Scheme273

7.3.2 Experimental Observation of Multi-Component Solitons277

7.3.3 Conclusion285

7.4 Surface Solitons of FWM in EIL285

7.4.1 Basic Theory and Experimental Scheme286

7.4.2 Fluorescence and FWM via EIT Windows289

7.4.3 Conclusion294

7.5 Multi-Wave Mixing Talbot Effect294

7.5.1 Introduction294

7.5.2 Theoretical Model and Analysis295

7.5.3 Suppression and Enhancement Conditions297

7.5.4 Talbot Effect of MWM Signals299

7.5.5 Conclusion303

References303

8 Optical Routing and Space Demultiplexer of MWM Process311

8.1 Optical Switching and Routing311

8.1.1 Introduction311

8.1.2 Theoretical Model and Experimental Scheme312

8.1.3 Optical Switching and Routing via Spatial Shift314

8.2 All-Optical Routing and Space Demultiplexer318

8.2.1 Theoretical Model and Experimental Scheme318

8.2.2 Optical Switching and Routing320

8.2.3 Conclusion328

References328

Index331