ISBN-10:
1118346491
ISBN-13:
9781118346495
Pub. Date:
08/26/2013
Publisher:
Wiley
Orthogonally Polarized Lasers: Physical Phenomena and Engineering Applications / Edition 1

Orthogonally Polarized Lasers: Physical Phenomena and Engineering Applications / Edition 1

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Product Details

ISBN-13: 9781118346495
Publisher: Wiley
Publication date: 08/26/2013
Pages: 400
Product dimensions: 6.60(w) x 9.60(h) x 1.10(d)

About the Author

Shulian Zhang, Tsinghua University, P.R. China

Wolfgang Holzapfel, Tsinghua University, P.R. China

Table of Contents

Foreword xvii
by Zhou Bingkun

Foreword xix
by Konrad Herrmann

Preface xxi

Introduction xxv

Part One FUNDAMENTALS OF LASERS AND BEAMPOLARIZATIONS

1 Rigorous Introduction to Lasers and Beam Polarizations3

1.1 The Basic Amplifier/Cavity Configuration 3

1.2 Optical Waves of a Laser 4

1.3 Cavity Closed-Loop and Laser Threshold 8

1.4 Survey of Techniques for Generating and Converting LaserPolarization States 16

References 24

2 Basic Physical Effects Inside Lasers 25

2.1 Interaction between Light and Particles 25

2.2 Line Shape Function and the Line Broadening Mechanism 30

2.3 Gain Coefficient of Light in an Active Medium 38

2.4 Saturation of Gain in the Laser Active Medium 40

2.5 Threshold Condition, Gain for Stationary Operation, andLasing Bandwidth 44

2.6 Optical Cavities and Laser Modes 46

2.7 Laser Mode Competition 50

2.8 Mode Push/Pull and Locking Effects 54

2.9 Power Tuning Properties of Lasers 55

References 59

3 Specific Laser Technologies Applicable for OrthogonallyPolarized Beam Generation 61

3.1 Background 61

3.2 He–Ne lasers 62

3.3 Carbon Dioxide (CO2) Laser and Its Polarization State 68

3.4 Optically Pumped Nd:YAG Lasers (1.06 μm) 69

3.5 Semiconductor Lasers 72

3.6 Fiber Lasers 76

3.7 Conclusions on Relevant Orthogonally Polarized LaserTechnologies 78

References 80

Part Two GENERATION OF ORTHOGONAL LASER POLARIZATIONS

4 Zeeman Dual-Frequency Lasers and Multifrequency Ring Lasers– Orthogonally Polarized Lasers in Tradition 83

4.1 Introduction 83

4.2 Zeeman Dual-Frequency Lasers 84

4.3 Multifrequency Ring Laser 88

References 96

5 Matrix Theory of Anisotropic Laser Cavities – AFurther Approach to Orthogonally Polarized Dual-Frequency Lasers99

5.1 Background 99

5.2 Polarization-Dependent Properties of Optical Materials100

5.3 Introduction to the Jones Formalism 101

5.4 Mathematical Description of Polarized Light by the JonesVectors 102

5.5 Transfer Matrixes of Retarders, Rotators, and Polarizers103

5.6 Serial Connections of Anisotropic Elements and the JonesTheorem 105

5.7 Connection of Different Retardations within the SameAnisotropic Element 107

5.8 Calculation of Eigenpolarizations and Eigenfrequencies ofPassive Anisotropic Cavities 107

5.9 Conclusions 111

References 111

6 Orthogonal Polarization and Frequency Splitting inBirefringent Laser Cavities 113

6.1 Laser Frequency Splitting Due to Intracavity Birefringence113

6.2 Laser Frequency Splitting Caused by Intracavity QuartzCrystals 117

6.3 Laser Frequency Splitting Caused by IntracavityElectro-optic Crystals 125

6.4 Induced Stress Birefringence and Laser Frequency Splitting129

6.5 Frequency Splitting in Semiconductor Lasers 133

6.6 Frequency Splitting in Fiber Lasers 136

6.7 Observation and Readout of Frequency Splitting 137

6.8 Final Remark on Methods Used to Obtain Small and Also LargerFrequency Differences 143

References 143

7 Design of Orthogonally Polarized Lasers 145

7.1 Background 145

7.2 Quartz Birefringence He–Ne Laser 147

7.3 Stress-Induced Birefringence He–Ne Laser 150

7.4 Equidistant Frequency Split Ultrashort He–Ne Laser153

7.5 Zeeman Birefringence Dual-Frequency He–Ne Laser154

7.6 He–Ne Laser with Two Intracavity BirefringenceElements 158

7.7 Orthogonally Polarized Lasers with a Superposition LayerBirefringence Film 161

7.8 Laser Diode Pumped Birefringent Nd:YAG Laser with TunableFrequency Difference 163

7.9 Orthogonally Polarized Lasers with Electrically ControllableFrequency Differences 169

References 170

Part Three NONLINEAR BEHAVIOR OF ORTHOGONALLY POLARIZEDLASERS

8 Competition and Flipping Phenomena in OrthogonallyPolarized Lasers 175

8.1 Intensity Tuning, Mode Competition, and Frequency DifferenceTuning in Dual-Frequency Lasers 176

8.2 Properties of Intensity Tuning and Frequency DifferenceTuning in Birefringent Zeeman Lasers 184

8.3 Polarization Properties Caused by Optical Activity of anIntracavity Quartz Crystal 191

8.4 Effect of Optical Activity in the Frequency Difference198

8.5 Polarization Flipping and Optical Hysteresis in BirefringentLasers 201

References 209

9 Optical Feedback Effects in Orthogonally Polarized Lasers211

9.1 General Concept of Laser Feedback 212

9.2 Optical Feedback for Birefringent He–Ne Lasers 216

9.3 Optical Feedback of Birefringence Zeeman Lasers 235

9.4 Optical Feedback with an Orthogonally Polarized ExternalCavity 241

9.5 Narrow Feedback Fringes of Birefringent Dual-FrequencyLasers 248

9.6 Optical Feedback of a Microchip Nd:YAG Laser withBirefringence 256

9.7 Conclusions on the Feedback in Orthogonally Polarized Lasers266

References 269

10 Semi-classical Theory of Orthogonally Polarized Lasers273

10.1 Modeling of Orthogonally Polarized Lasers 273

10.2 Theoretical Analysis of Orthogonally Polarized Lasers288

10.3 Analysis of Optical Feedback Phenomena in BirefringentLasers 299

References 307

Part Four APPLICATIONS OF ORTHOGONALLY POLARIZEDLASERS

11 Introduction and Background of Applications 311

11.1 Survey of the Application Potential 311

11.2 What Is the Particularity of OPDF Laser Measurements?313

References 315

12 Measurements of Optical Anisotropies by OrthogonallyPolarized Lasers 317

12.1 Phase Retardation Measurement of Wave Plates by LaserFrequency Splitting 318

12.2 Phase Retardation Measurements of Optical Components Basedon Laser Feedback and Polarization Flipping 333

12.3 Intracavity Transmission Ellipsometry for OpticallyAnisotropic Components 340

References 343

13 Displacement Measurement by Orthogonally Polarized Lasers345

13.1 Background and Basic Considerations 345

13.2 Zeeman OPDF Laser Interferometer 347

13.3 Displacement Measurement Based on Cavity Tuning ofOrthogonal Polarized Lasers – OPMC Displacement Transducers350

13.4 Displacement Measurement Based on Feedback of OrthogonallyPolarized Lasers 364

13.5 Displacement Measurement Based on Feedback of the BZ-Laser369

13.6 Displacement Measurement Based on Orthogonal PolarizedFeedback of Nd:YAG Lasers 373

13.7 Microchip Nd:YAG Laser Interferometers withQuasi-Common-Path Feedback 376

References 382

14 Force and Pressure Measurement by Means of PhotoelasticNd:YAG Lasers 385

14.1 Principle and Experimental Setup of Force and PressureMeasurement 386

14.2 Force Measurement: Experimental Results 392

14.3 Pressure Measurement: Experimental Results 398

14.4 Advanced Studies in Force to Frequency Conversion 400

14.5 Prospects of Laser-Based Force Measurements 403

References 404

15 Measurements via Translation/Rotation of IntracavityQuartz Crystals 407

15.1 Displacement Measurement by Means of an Intracavity QuartzCrystal Wedge 407

15.2 Measurement of Earth’s Gravity by Means of anIntracavity Quartz Crystal Wedge 409

15.3 Vibration Measurement by Means of an Intracavity QuartzCrystal Wedge 410

15.4 Measuring Rotation Angles by Means of an Intracavity QuartzCrystal Plate 412

References 414

16 Combined Magnetometer/Rate Gyro Transducers byFour-Frequency Ring Lasers 415

16.1 Principle of the Frequency Splitting Ring Laser WeakMagnetic Field Transducer 415

16.2 Experimental Arrangement 418

16.3 Experimental Results and Discussions 419

16.4 Conclusions 420

References 420

17 Further Applications of Orthogonally Polarized Lasers421

17.1 Tunable Signal Generation 421

17.2 Polarized Lasers in Material Processing 422

References 423

18 Conclusions of Part Four 425

18.1 Phase Retardation Measurement Applications 425

18.2 Displacement Sensing Applications 426

18.3 Force, Pressure, and Acceleration Measurement Applications426

Index 429

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