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Machine generated contents note: Dedication Preface About the Author PART I: DIODE LASER ENGINEERING Overview 1. Basic Diode Laser Engineering Principles Introduction 1.1. Brief Recapitulation 1.1.1. Key Features of a Diode Laser 1.1.2. Homo-Junction Diode Laser 1.1.3. Double-Heterostructure Diode Laser 1.1.4. Quantum Well Diode Laser 1.1.5. Common Compounds for Semiconductor Lasers 1.2. Optical Output Power - Diverse Aspects 1.2.1. Approaches to High Power Diode Lasers 1.2.2. High Optical Power Considerations 1.2.3. Power Limitations 1.2.4. High Power versus Reliability Trade-Offs 1.2.5. Typical and Record-High CW Optical Output Powers 1.3. Selected Relevant Basic Diode Laser Characteristics 1.3.1. Threshold Gain 1.3.2. Material Gain Spectra 1.3.3. Optical Confinement 1.3.4. Threshold Current 1.3.5. Transverse Vertical and Transverse Lateral Modes 1.3.6. Fabry-Perot Longitudinal Modes 1.3.7. Operating Characteristics 1.3.8. Mirror Reflectivity Modifications 1.4. Laser Fabrication Technology 1.4.1. Laser Wafer Growth 1.4.2. Laser Wafer Processing 1.4.3. Laser Packaging References 2. Design Considerations for High Power Single Spatial Mode Operation Introduction 2.1. Basic High Power Design Approaches 2.1.1. Key Aspects 2.1.2. Output Power Scaling 2.1.3. Transverse Vertical Waveguides 2.1.4. Narrow Stripe Weakly Index Guided Transverse Lateral Waveguides 2.1.5. Thermal Management 2.1.6. Catastrophic Optical Damage Elimination 2.2. Single Spatial Mode and Kink Control 2.2.1. Key Aspects 2.3.1. Introduction 2.3.2. Selected Calculated Parameter Dependencies 2.3.3. Selected Experimental Parameter Dependencies 2.4.1. Introduction 2.4.2. Broad Area Lasers 2.4.3. Unstable Resonator Lasers 2.4.4. Tapered Amplifier Lasers 2.4.5. Linear Laser Array Structures References Part II: DIODE LASER RELIABILITY Overview 3. Basic Diode Laser Degradation Modes Introduction 3.1. Degradation and Stability Criteria of Critical Diode Laser Characteristics 3.1.1. Optical Power, Threshold, Efficiency and Transverse Modes 3.1.2. Lasing Wavelength and Longitudinal Modes 3.2. Classification of Degradation Modes 3.2.1. Classification of Degradation Phenomena by Location 3.2.2. Basic Degradation Mechanisms 3.3. Key Laser Robustness Factors References 4. Optical Strength Engineering Introduction 4.1. Mirror Facet Properties - Physical Origins of Failure 4.2. Mirror Facet Passivation and Protection 4.2.1. Scope and Effects 4.2.2. Facet Passivation Techniques 4.2.3. Facet Protection Techniques 4.3. Non-Absorbing Mirror Technologies 4.3.1. Concept 4.3.2. Window Grown on Facet 4.3.3. Quantum Well Intermixing Processes 4.3.4. Bent Waveguide 4.4. Further Optical Strength Enhancement Approaches 4.4.1. Current Blocking Mirrors and Material Optimization 4.4.2. Heat Spreader Layer, Device Mounting and Number of Quantum Wells 4.4.3. Mode Spot Widening Techniques References 5. Basic Reliability Engineering Concepts Introduction 5.1. Descriptive Reliability Statistics 5.1.1. Probability Density Function 5.1.2. Cumulative Distribution Function 5.1.3. Reliability Function 5.1.4. Instantaneous Failure Rate or Hazard Rate 5.1.5. Cumulative Hazard Function 5.1.6. Average Failure Rate 5.1.7. Failure Rate Units 5.1.8. Bathtub Failure Rate Curve 5.2. Failure Distribution Functions - Statistics Models for Non-Repairable Populations 5.2.1. Introduction 5.2.2. Lognormal Distribution 5.2.3. Weibull Distribution 5.2.4. Exponential Distribution 5.3. Reliability Data Plotting 5.3.1. Life Test Data Plotting 5.4. Further Reliability Concepts 5.4.1. Data Types 5.4.2. Confidence Limits 5.4.3. Mean Time to Failure Calculations 5.4.4. Reliability Estimations 5.5. Accelerated Reliability Testing - Physics-Statistics Models 5.5.1. Acceleration Relationships 5.5.2. Remarks on Acceleration Models 5.6. System Reliability Calculations 5.6.1. Introduction 5.6.2. Independent Elements Connected in Series 5.6.3. Parallel System of Independent Components References 6. Diode Laser Reliability Engineering Program Introduction 6.1. Reliability Test Plan 6.1.1. Main Purpose, Motivation and Goals 6.1.2. Up-Front Requirements and Activities 6.1.3. Relevant Parameters for Long Term Stability and Reliability 6.1.4. Test Preparations and Operation 6.1.5. Overview Reliability Program Building Blocks 6.1.6. Development Tests 6.1.7. Manufacturing Tests 6.2. Reliability Growth Program 6.3. Reliability Benefits and Costs 6.3.1. Types of Benefit 6.3.2. Reliability - Cost Trade Offs References PART III: DIODE LASER DIAGNOSTICS Overview 7. Novel Diagnostic Laser Data for Active Layer Material Integrity, Impurity Trapping Effects and Mirror Temperatures Introduction 7.1. Optical Integrity of Laser Wafer Substrates 7.1.1. Motivation 7.1.2. Experimental Details 7.1.3. Discussion of Wafer Photoluminescence Maps 7.2. Integrity of Laser Active Layers 7.2.1. Motivation 7.2.2. Experimental Details 7.2.3. Discussion of Quantum Well PL Spectra 7.3. Deep-Level Defects at Interfaces of Active Regions 7.3.1. Motivation 7.3.2. Experimental Details 7.3.3. Discussion of Deep-Level Transient Spectroscopy Results 7.4. Micro-Raman Spectroscopy for Diode Laser Diagnostics 7.4.1. Motivation 7.4.2. Basics of Raman Inelastic Light Scattering 7.4.3. Experimental Details 7.4.4. Raman on Standard Diode Laser Facets 7.4.5. Raman for Facet Temperature Measurements 7.4.6. Various Dependences of Diode Laser Mirror Temperatures References 8. Novel Diagnostic Laser Data for Mirror Facet Disorder Effects, Mechanical Stress Effects and Facet Coating Instability Introduction 8.1. Diode Laser Mirror Facet Studies by Raman 8.1.1. Motivation 8.1.2. Raman Microprobe Spectra 8.1.3. Possible Origins of the 193 cm-1 Mode in (Al)GaAs 8.1.4. Facet Disorder - Facet Temperature - Catastrophic Optical Mirror Damage Robustness Correlations 8.2. Local Mechanical Strain in Ridge-Waveguide Diode Lasers 8.2.1. Motivation 8.2.2. Measurements - Raman Shifts and Stress Profiles 8.2.3. Detection of "Weak Spots" 8.2.4. Stress Model Experiments 8.3. Diode Laser Mirror Facet Coating Structural Instability 8.3.1. Motivation 8.3.2. Experimental Details 8.3.3. Silicon Recrystallization by Internal Power Exposure 8.3.4. Silicon Recrystallization by External Power Exposure - Control Experiments References 9. Novel Diagnostic Data for Diverse Laser Temperature Effects, Dynamic Laser Degradation Effects and Mirror Temperature Maps Introduction 9.1. Thermoreflectance Microscopy for Diode Laser Diagnostics 9.1.1. Motivation 9.1.2. Concept and Signal Interpretation 9.1.3. Reflectance - Temperature Change Relationship 9.1.4. Experimental Details 9.1.5. Potential Perturbation Effects on Reflectance 9.2. Thermoreflectance versus Optical Spectroscopies 9.2.1. General 9.2.2. Comparison 9.3. Lowest Detectable Temperature Rise 9.4. Diode Laser Mirror Temperatures by Micro-Thermoreflectance 9.4.1. Motivation 9.4.2. Dependence on Number of Active Quantum Wells 9.4.3. Dependence on Heat Spreader 9.4.4. Dependence on Mirror Treatment and Coating 9.4.5. Bent-Waveguide Non-Absorbing Mirror 9.5. Diode Laser Mirror Studies by Micro-Thermoreflectance 9.5.1. Motivation 9.5.2. Real-Time Temperature-Monitored Laser Degradation 9.5.3. Local Optical Probe 9.5.3.1. Threshold and heating distribution within near-field spot 9.6. Diode Laser Cavity Temperatures by Micro-Electroluminescence 9.6.1. Motivation 9.6.2. Experimental Details - Sample and Setup 9.6.3. Temperature Profiles along Laser Cavity 9.7. Diode Laser Facet Temperature - Two-Dimensional Mapping 9.7.1. Motivation 9.7.2. Experimental Concept 9.7.3. First Temperature Maps Ever 9.7.4. Independent Temperature Line Scans Perpendicular Active Layer 9.7.5. Temperature Modelling References Index.

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