Photorefractive materials for dynamic optical recording : fundamentals, characterization and technology /: fundamentals, characterization and technology. (2020)
- Record Type:
- Book
- Title:
- Photorefractive materials for dynamic optical recording : fundamentals, characterization and technology /: fundamentals, characterization and technology. (2020)
- Main Title:
- Photorefractive materials for dynamic optical recording : fundamentals, characterization and technology
- Further Information:
- Note: Jaime Frejlich Sochaczewsky.
- Authors:
- Sochaczewsky, Jaime Frejlich, 1946-
- Contents:
- List of Figures xi List of Tables xxxiii Preface xxxv Acknowledgments xxxvii Part I Fundamentals 1 Introduction 3 1 Electro-Optic Effect 5 1.1 Light Propagation in Crystals 5 1.1.1 Wave Propagation in Anisotropic Media 5 1.1.2 General Wave Equation 6 1.1.3 Index Ellipsoid 6 1.2 Tensorial Analysis 8 1.3 Electro-Optic Effect 8 1.4 Perovskite Crystals 11 1.5 Sillenite Crystals 11 1.5.1 Index Ellipsoid 11 1.5.1.1 Index Ellipsoid with Applied Electric Field 13 1.5.2 Other Cubic Noncentrosymmetric Crystals 15 1.5.3 Lithium Niobate 15 1.5.4 KDP-(KH2 PO4 ) 16 1.5.5 Bismuth Tellurium Oxide-Bi2 TeO5 (BTeO) 17 1.6 Concluding Remarks 17 2 Photoactive Centers and Photoconductivity 19 2.1 Photoactive Centers: Deep and Shallow Traps 20 2.1.1 Cadmium Telluride 21 2.1.2 Sillenite-Type Crystals 22 2.1.2.1 Doped Sillenites 25 2.1.3 Lithium Niobate 28 2.1.4 Bismuth Telluride Oxide: Bi2 TeO5 28 2.2 Luminescence 28 2.3 Photoconductivity 29 2.3.1 Localized States: Traps and Recombination Centers 29 2.3.2 Theoretical Models 32 2.3.2.1 One-Center Model 35 2.3.2.2 Two-Center/One-Charge Carrier Model 37 2.3.2.3 Dark Conductivity and Dopants 40 2.4 Photovoltaic Effect 40 2.4.1 Photovoltaic Crystals 41 2.4.1.1 Lithium Niobate and Other Ferroelectric Crystals 41 2.4.1.2 Some Photovoltaic Nonferroelectric Materials 41 2.4.2 Light Polarization-Dependent Photovoltaic Effect 43 2.5 Nonlinear Photovoltaic Effect 44 2.5.1 Light-Induced Absorption and Nonlinear Photovoltaic Effects 46 2.5.2 Deep and ShallowList of Figures xi List of Tables xxxiii Preface xxxv Acknowledgments xxxvii Part I Fundamentals 1 Introduction 3 1 Electro-Optic Effect 5 1.1 Light Propagation in Crystals 5 1.1.1 Wave Propagation in Anisotropic Media 5 1.1.2 General Wave Equation 6 1.1.3 Index Ellipsoid 6 1.2 Tensorial Analysis 8 1.3 Electro-Optic Effect 8 1.4 Perovskite Crystals 11 1.5 Sillenite Crystals 11 1.5.1 Index Ellipsoid 11 1.5.1.1 Index Ellipsoid with Applied Electric Field 13 1.5.2 Other Cubic Noncentrosymmetric Crystals 15 1.5.3 Lithium Niobate 15 1.5.4 KDP-(KH2 PO4 ) 16 1.5.5 Bismuth Tellurium Oxide-Bi2 TeO5 (BTeO) 17 1.6 Concluding Remarks 17 2 Photoactive Centers and Photoconductivity 19 2.1 Photoactive Centers: Deep and Shallow Traps 20 2.1.1 Cadmium Telluride 21 2.1.2 Sillenite-Type Crystals 22 2.1.2.1 Doped Sillenites 25 2.1.3 Lithium Niobate 28 2.1.4 Bismuth Telluride Oxide: Bi2 TeO5 28 2.2 Luminescence 28 2.3 Photoconductivity 29 2.3.1 Localized States: Traps and Recombination Centers 29 2.3.2 Theoretical Models 32 2.3.2.1 One-Center Model 35 2.3.2.2 Two-Center/One-Charge Carrier Model 37 2.3.2.3 Dark Conductivity and Dopants 40 2.4 Photovoltaic Effect 40 2.4.1 Photovoltaic Crystals 41 2.4.1.1 Lithium Niobate and Other Ferroelectric Crystals 41 2.4.1.2 Some Photovoltaic Nonferroelectric Materials 41 2.4.2 Light Polarization-Dependent Photovoltaic Effect 43 2.5 Nonlinear Photovoltaic Effect 44 2.5.1 Light-Induced Absorption and Nonlinear Photovoltaic Effects 46 2.5.2 Deep and Shallow Centers 47 2.6 Light-Induced Absorption or Photochromic Effect 48 2.6.1 Transmittance with Light-Induced Absorption 51 2.7 Dember or Light-Induced Schottky Effect 51 2.7.1 Dember and Photovoltaic Effects 54 Part II Holographic Recording 55 Introduction 56 3 Recording a Space-Charge Electric Field 57 3.1 Index-of-Refraction Modulation 60 3.2 General Formulation 63 3.2.1 Rate Equations 64 3.2.2 Solution for Steady-State 64 3.3 First Spatial Harmonic Approximation 66 3.3.1 Steady-State Stationary Process 68 3.3.1.1 Diffraction Efficiency 69 3.3.1.2 Hologram Phase Shift 70 3.3.2 Time-Evolution Process: Constant Modulation 70 3.4 Steady-State Nonstationary Process: Running Holograms 72 3.4.1 Running Holograms with Hole-Electron Competition 76 3.4.1.1 Mathematical Model 78 3.5 Photovoltaic Materials 84 3.5.1 Uniform Illumination: '�N /'�x = 0 84 3.5.2 Interference Pattern of Light 85 3.5.2.1 Influence of Donor Density 86 4 Volume Hologram with Wave Mixing 89 4.1 Coupled Wave Theory: Fixed Grating 89 4.1.1 Diffraction Efficiency 91 4.1.2 Out of Bragg Condition 91 4.2 Dynamic Coupled Wave Theory 92 4.2.1 Combined Phase-Amplitude Stationary Gratings 92 4.2.1.1 Fundamental Properties 94 4.2.1.2 Irradiance 95 4.2.2 Pure Phase Grating 96 4.2.2.1 Time Evolution 96 4.2.2.2 Stationary Hologram 100 4.2.2.3 Steady-State Nonstationary Hologram with Wave-Mixing and Bulk Absorption 106 4.2.2.4 Gain and Stability in Two-Wave Mixing 110 4.3 Phase Modulation 115 4.3.1 Phase Modulation in Dynamically Recorded Gratings 116 4.3.1.1 Phase Modulation in the Signal Beam 116 4.3.1.2 Output Phase Shift 118 4.4 Four-Wave Mixing 119 4.5 Conclusions 120 5 Anisotropic Diffraction 121 5.1 Coupled-Wave with Anisotropic Diffraction 121 5.2 Anisotropic Diffraction and Optical Activity 122 5.2.1 Diffraction Efficiency with Optical Activity, '� 123 5.2.2 Output Polarization Direction 123 6 Stabilized Holographic Recording 125 6.1 Introduction 125 6.2 Mathematical Formulation 127 6.2.1 Stabilized Stationary Recording 129 6.2.1.1 Stable Equilibrium Condition 130 6.2.2 Stabilized Recording of Running (Nonstationary) Holograms 130 6.2.2.1 Stable Equilibrium Condition 132 6.2.2.2 Speed of the Fringe-Locked Running Hologram 132 6.2.3 Self-Stabilized Recording with Arbitrarily Selected Phase Shift 133 6.3 Self-Stabilized Recording in Actual Materials 135 6.3.1 Self-Stabilized Recording in Sillenites 136 6.3.2 Self-Stabilized Recording in LiNbO3 136 6.3.2.1 Holographic Recording without Constraints 137 6.3.2.2 Self-Stabilized Recording 142 Part III Materials Characterization 151 Introduction 152 7 General Electrical and Optical Techniques 155 7.1 Electro-Optic Coefficient 155 7.2 Light-Induced Absorption 157 7.3 Dark Conductivity 161 7.4 Photoconductivity 162 7.4.1 Photoconductivity in Bulk Material 163 7.4.2 Alternating Current Technique 164 7.4.3 Wavelength-Resolved Photoconductivity 166 7.4.3.1 Transverse Configuration 166 7.4.3.2 Longitudinal Configuration 170 7.5 Photo-Electric Conversion 173 7.5.1 Wavelength-Resolved Photo-Electric Conversion (WRPC) 173 7.5.1.1 Undoped BTO 174 7.6 Modulated Photoconductivity 175 7.6.1 Quantum Efficiency and Mobility-Lifetime Product 176 7.7 Photo-Electromotive-Force Techniques (PEMF) 178 7.7.1 Speckle-Photo-Electromotive-Force (SPEMF) Techniques 178 7.7.1.1 Speckle Pattern onto a Photorefractive Material: Stationary State 179 8 Holographic Techniques 189 8.1 Holographic Recording and Erasing 189 8.2 Direct Holographic Techniques 189 8.2.1 Energy Coupling 190 8.2.2 Diffraction Efficiency 192 8.2.2.1 Debye Length Dependence on Light Intensity 193 8.2.3 Holographic Sensitivity 193 8.2.3.1 Computing S 195 8.3 Hologram Recording 195 8.4 Hologram Erasure 195 8.4.1 One Single Photoactive Center Involved 196 8.4.1.1 Bulk Absorption 196 8.4.2 Two (or More) Photoactive Centers (Localized States) Involved 197 8.4.2.1 Same Charge Carriers 197 8.4.2.2 Holes and Electrons on Different Photoactive Centers 197 8.5 Materials 197 8.5.1 Fe-doped LiNbO3 : Hologram Erasure under White Light Illumination 197 8.5.2 Bi12 TiO20 (BTO) 199 8.5.2.1 Undoped BTO under '� = 780 nm Illumination 199 8.5.2.2 Bi12 TiO20 :Pb (BTO:Pb) 200 8.5.2.3 Bi12 TiO20 :V (BTO:V) 202 8.5.2.4 Holographic Relaxation in the Dark: Dark Conductivity 203 8.6 Phase Modulation Techniques 205 8.6.1 Holographic Sensitivity 205 8.6.2 Holographic Phase-Shift Measurement 206 8.6.2.1 Wave-Mixing Effects 207 8.6.3 Photorefractive Response Time 207 8.6.4 Selective Two-Wave Mixing 210 8.6.4.1 Amplitude and Phase Effects in GaAs 212 8.6.5 Running Holograms 214 8.7 Holographic Photo-Electromotive-Force (HPEMF) Techniques 218 9 Self-Stabilized Holographic Techniques 229 9.1 Holographic Phase Shift 229 9.2 Fringe-Locked Running Holograms 232 9.2.1 Absorbing Materials 232 9.2.1.1 Low Absorption Approximation 234 9.2.2 Characterization of M … (more)
- Edition:
- 1st
- Publisher Details:
- Hoboken, New Jersey : John Wiley & Sons, Inc
- Publication Date:
- 2020
- Extent:
- 1 online resource
- Subjects:
- 621.38234
Laser recording -- Materials
Photorefractive materials - Languages:
- English
- ISBNs:
- 9781119563761
- Related ISBNs:
- 9781119563730
- Notes:
- Note: Description based on CIP data; resource not viewed.
- Access Rights:
- Legal Deposit; Only available on premises controlled by the deposit library and to one user at any one time; The Legal Deposit Libraries (Non-Print Works) Regulations (UK).
- Access Usage:
- Restricted: Printing from this resource is governed by The Legal Deposit Libraries (Non-Print Works) Regulations (UK) and UK copyright law currently in force.
- View Content:
- Available online (eLD content is only available in our Reading Rooms) ↗
- Physical Locations:
- British Library HMNTS - ELD.DS.492538
- Ingest File:
- 03_055.xml