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Fundamentals of light sources and lasers [[electronic resource] /] / Mark Csele
| Fundamentals of light sources and lasers [[electronic resource] /] / Mark Csele |
| Autore | Csele Mark |
| Pubbl/distr/stampa | Hoboken, N.J., : J. Wiley, c2004 |
| Descrizione fisica | 1 online resource (362 p.) |
| Disciplina |
621.36/6
621.366 |
| Soggetto topico |
Light sources
Lasers |
| ISBN |
1-280-55688-9
9786610556885 0-471-67522-9 0-471-67521-0 |
| Formato | Materiale a stampa  |
| Livello bibliografico | Monografia |
| Lingua di pubblicazione | eng |
| Nota di contenuto |
FUNDAMENTALS OF LIGHT SOURCES AND LASERS; CONTENTS; Preface; 1. Light and Blackbody Emission; 1.1 Emission of Thermal Light; 1.2 Electromagnetic Spectrum; 1.3 Blackbody Radiation and the Stefan-Boltzmann Law; 1.4 Wein's Law; 1.5 Cavity Radiation and Cavity Modes; 1.6 Quantum Nature of Light; 1.7 Electromagnetic Spectrum Revisited; 1.8 Absorption and Emission Processes; 1.9 Boltzmann Distribution and Thermal Equilibrium; 1.10 Quantum View of Blackbody Radiation; 1.11 Blackbodies at Various Temperatures; 1.12 Applications; 1.13 Absorption and Color; 1.14 Efficiency of Light Sources; Problems
2. Atomic Emission2.1 Line Spectra; 2.2 Spectroscope; 2.3 Einstein and Planck: E = hv; 2.4 Photoelectric Effect; 2.5 Atomic Models and Light Emission; 2.6 Franck-Hertz Experiment; 2.7 Spontaneous Emission and Level Lifetime; 2.8 Fluorescence; 2.9 Semiconductor Devices; 2.10 Light-Emitting Diodes; Problems; 3. Quantum Mechanics; 3.1 Limitations of the Bohr Model; 3.2 Wave Properties of Particles (Duality); 3.3 Evidence of Wave Properties in Electrons; 3.4 Wavefunctions and the Particle-in-a-Box Model; 3.5 Reconciling Classical and Quantum Mechanics; 3.6 Angular Momentum in Quantum States 3.7 Spectroscopic Notation and Electron Configuration3.8 Energy Levels Described by Orbital Angular Momentum; 3.9 Magnetic Quantum Numbers; 3.10 Direct Evidence of Momentum: The Stern-Gerlach Experiment; 3.11 Electron Spin; 3.12 Summary of Quantum Numbers; 3.13 Example of Quantum Numbers: The Sodium Spectrum; 3.14 Multiple Electrons: The Mercury Spectrum; 3.15 Energy Levels and Transitions in Gas Lasers; 3.16 Molecular Energy Levels; 3.17 Infrared Spectroscopy Applications; Problems; 4. Lasing Processes; 4.1 Characteristics of Coherent Light; 4.2 Boltzmann Distribution and Thermal Equilibrium 4.3 Creating an Inversion4.4 Stimulated Emission; 4.5 Rate Equations and Criteria for Lasing; 4.6 Laser Gain; 4.7 Linewidth; 4.8 Thresholds for Lasing; 4.9 Calculating Threshold Gain; Problems; 5. Lasing Transitions and Gain; 5.1 Selective Pumping; 5.2 Three- and Four-Level Lasers; 5.3 CW Lasing Action; 5.4 Thermal Population Effects; 5.5 Depopulation of Lower Energy Levels in Four-Level Lasers; 5.6 Rate Equation Analysis for Atomic Transitions; 5.7 Rate Equation Analysis for Three- and Four-Level Lasers; 5.8 Gain Revisited; 5.9 Saturation; 5.10 Required Pump Power and Efficiency 5.11 Output PowerProblems; 6. Cavity Optics; 6.1 Requirements for a Resonator; 6.2 Gain and Loss in a Cavity; 6.3 Resonator as an Interferometer; 6.4 Longitudinal Modes; 6.5 Wavelength Selection in Multiline Lasers; 6.6 Single-Frequency Operation; 6.7 Characterization of a Resonator; 6.8 Gaussian Beam; 6.9 Resonator Stability; 6.10 Common Cavity Configurations; 6.11 Spatial Energy Distributions: Transverse Modes; 6.12 Limiting Modes; 6.13 Resonator Alignment: A Practical Approach; Problems; 7. Fast-Pulse Production; 7.1 Concept of Q-Switching; 7.2 Intracavity Switches 7.3 Energy Storage in Laser Media |
| Record Nr. | UNINA-9910146053803321 |
Csele Mark
|
||
| Hoboken, N.J., : J. Wiley, c2004 | ||
| Materiale a stampa | ||
| Lo trovi qui: Univ. Federico II | ||
| ||
Fundamentals of light sources and lasers [[electronic resource] /] / Mark Csele
| Fundamentals of light sources and lasers [[electronic resource] /] / Mark Csele |
| Autore | Csele Mark |
| Pubbl/distr/stampa | Hoboken, N.J., : J. Wiley, c2004 |
| Descrizione fisica | 1 online resource (362 p.) |
| Disciplina |
621.36/6
621.366 |
| Soggetto topico |
Light sources
Lasers |
| ISBN |
1-280-55688-9
9786610556885 0-471-67522-9 0-471-67521-0 |
| Formato | Materiale a stampa |
| Livello bibliografico | Monografia |
| Lingua di pubblicazione | eng |
| Nota di contenuto |
FUNDAMENTALS OF LIGHT SOURCES AND LASERS; CONTENTS; Preface; 1. Light and Blackbody Emission; 1.1 Emission of Thermal Light; 1.2 Electromagnetic Spectrum; 1.3 Blackbody Radiation and the Stefan-Boltzmann Law; 1.4 Wein's Law; 1.5 Cavity Radiation and Cavity Modes; 1.6 Quantum Nature of Light; 1.7 Electromagnetic Spectrum Revisited; 1.8 Absorption and Emission Processes; 1.9 Boltzmann Distribution and Thermal Equilibrium; 1.10 Quantum View of Blackbody Radiation; 1.11 Blackbodies at Various Temperatures; 1.12 Applications; 1.13 Absorption and Color; 1.14 Efficiency of Light Sources; Problems
2. Atomic Emission2.1 Line Spectra; 2.2 Spectroscope; 2.3 Einstein and Planck: E = hv; 2.4 Photoelectric Effect; 2.5 Atomic Models and Light Emission; 2.6 Franck-Hertz Experiment; 2.7 Spontaneous Emission and Level Lifetime; 2.8 Fluorescence; 2.9 Semiconductor Devices; 2.10 Light-Emitting Diodes; Problems; 3. Quantum Mechanics; 3.1 Limitations of the Bohr Model; 3.2 Wave Properties of Particles (Duality); 3.3 Evidence of Wave Properties in Electrons; 3.4 Wavefunctions and the Particle-in-a-Box Model; 3.5 Reconciling Classical and Quantum Mechanics; 3.6 Angular Momentum in Quantum States 3.7 Spectroscopic Notation and Electron Configuration3.8 Energy Levels Described by Orbital Angular Momentum; 3.9 Magnetic Quantum Numbers; 3.10 Direct Evidence of Momentum: The Stern-Gerlach Experiment; 3.11 Electron Spin; 3.12 Summary of Quantum Numbers; 3.13 Example of Quantum Numbers: The Sodium Spectrum; 3.14 Multiple Electrons: The Mercury Spectrum; 3.15 Energy Levels and Transitions in Gas Lasers; 3.16 Molecular Energy Levels; 3.17 Infrared Spectroscopy Applications; Problems; 4. Lasing Processes; 4.1 Characteristics of Coherent Light; 4.2 Boltzmann Distribution and Thermal Equilibrium 4.3 Creating an Inversion4.4 Stimulated Emission; 4.5 Rate Equations and Criteria for Lasing; 4.6 Laser Gain; 4.7 Linewidth; 4.8 Thresholds for Lasing; 4.9 Calculating Threshold Gain; Problems; 5. Lasing Transitions and Gain; 5.1 Selective Pumping; 5.2 Three- and Four-Level Lasers; 5.3 CW Lasing Action; 5.4 Thermal Population Effects; 5.5 Depopulation of Lower Energy Levels in Four-Level Lasers; 5.6 Rate Equation Analysis for Atomic Transitions; 5.7 Rate Equation Analysis for Three- and Four-Level Lasers; 5.8 Gain Revisited; 5.9 Saturation; 5.10 Required Pump Power and Efficiency 5.11 Output PowerProblems; 6. Cavity Optics; 6.1 Requirements for a Resonator; 6.2 Gain and Loss in a Cavity; 6.3 Resonator as an Interferometer; 6.4 Longitudinal Modes; 6.5 Wavelength Selection in Multiline Lasers; 6.6 Single-Frequency Operation; 6.7 Characterization of a Resonator; 6.8 Gaussian Beam; 6.9 Resonator Stability; 6.10 Common Cavity Configurations; 6.11 Spatial Energy Distributions: Transverse Modes; 6.12 Limiting Modes; 6.13 Resonator Alignment: A Practical Approach; Problems; 7. Fast-Pulse Production; 7.1 Concept of Q-Switching; 7.2 Intracavity Switches 7.3 Energy Storage in Laser Media |
| Record Nr. | UNINA-9910830550503321 |
|
Csele Mark
|
||
| Hoboken, N.J., : J. Wiley, c2004 | ||
| Materiale a stampa | ||
| Lo trovi qui: Univ. Federico II | ||
| ||
Fundamentals of light sources and lasers / / Mark Csele
| Fundamentals of light sources and lasers / / Mark Csele |
| Autore | Csele Mark |
| Pubbl/distr/stampa | Hoboken, N.J., : J. Wiley, c2004 |
| Descrizione fisica | 1 online resource (362 p.) |
| Disciplina |
621.36/6
621.366 |
| Soggetto topico |
Light sources
Lasers |
| ISBN |
1-280-55688-9
9786610556885 0-471-67522-9 0-471-67521-0 |
| Formato | Materiale a stampa |
| Livello bibliografico | Monografia |
| Lingua di pubblicazione | eng |
| Nota di contenuto |
FUNDAMENTALS OF LIGHT SOURCES AND LASERS; CONTENTS; Preface; 1. Light and Blackbody Emission; 1.1 Emission of Thermal Light; 1.2 Electromagnetic Spectrum; 1.3 Blackbody Radiation and the Stefan-Boltzmann Law; 1.4 Wein's Law; 1.5 Cavity Radiation and Cavity Modes; 1.6 Quantum Nature of Light; 1.7 Electromagnetic Spectrum Revisited; 1.8 Absorption and Emission Processes; 1.9 Boltzmann Distribution and Thermal Equilibrium; 1.10 Quantum View of Blackbody Radiation; 1.11 Blackbodies at Various Temperatures; 1.12 Applications; 1.13 Absorption and Color; 1.14 Efficiency of Light Sources; Problems
2. Atomic Emission2.1 Line Spectra; 2.2 Spectroscope; 2.3 Einstein and Planck: E = hv; 2.4 Photoelectric Effect; 2.5 Atomic Models and Light Emission; 2.6 Franck-Hertz Experiment; 2.7 Spontaneous Emission and Level Lifetime; 2.8 Fluorescence; 2.9 Semiconductor Devices; 2.10 Light-Emitting Diodes; Problems; 3. Quantum Mechanics; 3.1 Limitations of the Bohr Model; 3.2 Wave Properties of Particles (Duality); 3.3 Evidence of Wave Properties in Electrons; 3.4 Wavefunctions and the Particle-in-a-Box Model; 3.5 Reconciling Classical and Quantum Mechanics; 3.6 Angular Momentum in Quantum States 3.7 Spectroscopic Notation and Electron Configuration3.8 Energy Levels Described by Orbital Angular Momentum; 3.9 Magnetic Quantum Numbers; 3.10 Direct Evidence of Momentum: The Stern-Gerlach Experiment; 3.11 Electron Spin; 3.12 Summary of Quantum Numbers; 3.13 Example of Quantum Numbers: The Sodium Spectrum; 3.14 Multiple Electrons: The Mercury Spectrum; 3.15 Energy Levels and Transitions in Gas Lasers; 3.16 Molecular Energy Levels; 3.17 Infrared Spectroscopy Applications; Problems; 4. Lasing Processes; 4.1 Characteristics of Coherent Light; 4.2 Boltzmann Distribution and Thermal Equilibrium 4.3 Creating an Inversion4.4 Stimulated Emission; 4.5 Rate Equations and Criteria for Lasing; 4.6 Laser Gain; 4.7 Linewidth; 4.8 Thresholds for Lasing; 4.9 Calculating Threshold Gain; Problems; 5. Lasing Transitions and Gain; 5.1 Selective Pumping; 5.2 Three- and Four-Level Lasers; 5.3 CW Lasing Action; 5.4 Thermal Population Effects; 5.5 Depopulation of Lower Energy Levels in Four-Level Lasers; 5.6 Rate Equation Analysis for Atomic Transitions; 5.7 Rate Equation Analysis for Three- and Four-Level Lasers; 5.8 Gain Revisited; 5.9 Saturation; 5.10 Required Pump Power and Efficiency 5.11 Output PowerProblems; 6. Cavity Optics; 6.1 Requirements for a Resonator; 6.2 Gain and Loss in a Cavity; 6.3 Resonator as an Interferometer; 6.4 Longitudinal Modes; 6.5 Wavelength Selection in Multiline Lasers; 6.6 Single-Frequency Operation; 6.7 Characterization of a Resonator; 6.8 Gaussian Beam; 6.9 Resonator Stability; 6.10 Common Cavity Configurations; 6.11 Spatial Energy Distributions: Transverse Modes; 6.12 Limiting Modes; 6.13 Resonator Alignment: A Practical Approach; Problems; 7. Fast-Pulse Production; 7.1 Concept of Q-Switching; 7.2 Intracavity Switches 7.3 Energy Storage in Laser Media |
| Record Nr. | UNINA-9910841082303321 |
|
Csele Mark
|
||
| Hoboken, N.J., : J. Wiley, c2004 | ||
| Materiale a stampa | ||
| Lo trovi qui: Univ. Federico II | ||
| ||