High-order harmonic generation in laser plasma plumes [[electronic resource] /] / Rashid A. Ganeev |
Autore | Ganeev Rashid |
Pubbl/distr/stampa | Singapore, : World Scientific, 2013 |
Descrizione fisica | 1 online resource (250 p.) |
Disciplina | 530.443 |
Soggetto topico |
Harmonics (Electric waves)
Plasma (Ionized gases) |
Soggetto genere / forma | Electronic books. |
ISBN |
1-283-90015-7
1-84816-981-7 |
Formato | Materiale a stampa |
Livello bibliografico | Monografia |
Lingua di pubblicazione | eng |
Nota di contenuto |
Contents; Preface; List of Figures and Tables; Chapter 1. Introduction; References; Chapter 2. Basic Principles of Harmonic Generation in Plasmas; 2.1 Fundamentals of HHG in Isotropic Media; 2.2 High-Order Harmonic Generation in Various Laser Plasmas; 2.2.1 Boron; 2.2.2 Silver; 2.2.3 Gold; 2.3 Application of 400-nm Radiation for Harmonic Generation in Laser Plasma; 2.4 High-Order Harmonic Generation in Plasmas Produced by Laser Pulses of Different Durations; 2.5 Analysis of Laser-Produced Plasma Characteristics for Optimization of HHG; References
Chapter 3. Resonance-Induced Enhancement of High-Order Harmonic Generation in Plasma3.1 Giant Enhancement of 13th Harmonic Generation in Indium Plasma; 3.2 Single Harmonic Enhancement in Chromium, Gallium Arsenide, and Indium Antimonide Plasmas; 3.3 Single Harmonic Enhancement at Strong Excitation Conditions; 3.4 Resonance Enhancement of Odd and Even Harmonics in Tin Plasma During Two-Color Pumping; 3.5 Plasma Harmonic Enhancement Using Two-Color Pump and Chirp Variation of 1 kHz Ti:sapphire Laser; 3.5.1 Experimental; 3.5.2 Silver plasma; 3.5.3 Chromium plasma; 3.5.4 Vanadium plasma 3.6 Theoretical Approaches for Description of Observed Peculiarities of Resonant Enhancement of Single Harmonic in Laser PlasmaReferences; Chapter 4. Cluster-Containing Plasma Plumes: Attractive Media for High-Order Harmonic Generation of Laser Radiation; 4.1 Overview; 4.2 Ablation of Metal Nanoparticles; 4.3 Ablation of Bulk Metals; 4.4 Overview of Early Studies of Harmonic Generation in Cluster-Containing Media; 4.5 Application of Cluster-Containing Plasma for Efficient HHG; 4.6 Peculiarities of HHG in Nanoparticle-Containing Plasmas 4.7 Advantages and Disadvantages of the Application of Cluster-Containing Plasmas for the Enhancement of HHG EfficiencyReferences; Chapter 5. Application of Fullerenes for Harmonic Generation; 5.1 First Observation of HHG in Fullerene Plasma; 5.2 Influence of Various Experimental Parameters on HHG Efficiency in Fullerene Plasma; 5.3 Studies of Harmonic Modulation from Fullerene-Rich Plasmas; 5.4 Two-Color Pump for Harmonic Generation in C60; 5.5 Analysis of the Morphology of Fullerene Targets and Ablated Materials; 5.6 Theoretical Calculations of HHG in Fullerenes 5.7 Calculations of HHG in Endohedral Fullerenes5.8 Discussion; References; Chapter 6. Enhancement of Harmonic Yield from Ablation Plumes; 6.1 Two-Color Pump for Enhancement of Harmonic Output from Plasma over the Whole Plateau Region; 6.2 Application of Time-Resolved Spectroscopy of Laser Plasma for Enhancement of Harmonic Efficiency and Generation of Second Plateau in Harmonic Distribution; 6.3 Application of Carbon Aerogel Plumes as Efficient Media for HHG in the 40-90 nm Range; 6.4 Comparative Studies of HHG in Laser Plasmas and Gases; References Chapter 7. Recent Developments and Future Perspectives of Plasma HHG |
Record Nr. | UNINA-9910463682003321 |
Ganeev Rashid | ||
Singapore, : World Scientific, 2013 | ||
Materiale a stampa | ||
Lo trovi qui: Univ. Federico II | ||
|
High-order harmonic generation in laser plasma plumes [[electronic resource] /] / Rashid A. Ganeev |
Autore | Ganeev Rashid |
Pubbl/distr/stampa | Singapore, : World Scientific, 2013 |
Descrizione fisica | 1 online resource (250 p.) |
Disciplina | 530.443 |
Soggetto topico |
Harmonics (Electric waves)
Plasma (Ionized gases) |
ISBN |
1-283-90015-7
1-84816-981-7 |
Formato | Materiale a stampa |
Livello bibliografico | Monografia |
Lingua di pubblicazione | eng |
Nota di contenuto |
Contents; Preface; List of Figures and Tables; Chapter 1. Introduction; References; Chapter 2. Basic Principles of Harmonic Generation in Plasmas; 2.1 Fundamentals of HHG in Isotropic Media; 2.2 High-Order Harmonic Generation in Various Laser Plasmas; 2.2.1 Boron; 2.2.2 Silver; 2.2.3 Gold; 2.3 Application of 400-nm Radiation for Harmonic Generation in Laser Plasma; 2.4 High-Order Harmonic Generation in Plasmas Produced by Laser Pulses of Different Durations; 2.5 Analysis of Laser-Produced Plasma Characteristics for Optimization of HHG; References
Chapter 3. Resonance-Induced Enhancement of High-Order Harmonic Generation in Plasma3.1 Giant Enhancement of 13th Harmonic Generation in Indium Plasma; 3.2 Single Harmonic Enhancement in Chromium, Gallium Arsenide, and Indium Antimonide Plasmas; 3.3 Single Harmonic Enhancement at Strong Excitation Conditions; 3.4 Resonance Enhancement of Odd and Even Harmonics in Tin Plasma During Two-Color Pumping; 3.5 Plasma Harmonic Enhancement Using Two-Color Pump and Chirp Variation of 1 kHz Ti:sapphire Laser; 3.5.1 Experimental; 3.5.2 Silver plasma; 3.5.3 Chromium plasma; 3.5.4 Vanadium plasma 3.6 Theoretical Approaches for Description of Observed Peculiarities of Resonant Enhancement of Single Harmonic in Laser PlasmaReferences; Chapter 4. Cluster-Containing Plasma Plumes: Attractive Media for High-Order Harmonic Generation of Laser Radiation; 4.1 Overview; 4.2 Ablation of Metal Nanoparticles; 4.3 Ablation of Bulk Metals; 4.4 Overview of Early Studies of Harmonic Generation in Cluster-Containing Media; 4.5 Application of Cluster-Containing Plasma for Efficient HHG; 4.6 Peculiarities of HHG in Nanoparticle-Containing Plasmas 4.7 Advantages and Disadvantages of the Application of Cluster-Containing Plasmas for the Enhancement of HHG EfficiencyReferences; Chapter 5. Application of Fullerenes for Harmonic Generation; 5.1 First Observation of HHG in Fullerene Plasma; 5.2 Influence of Various Experimental Parameters on HHG Efficiency in Fullerene Plasma; 5.3 Studies of Harmonic Modulation from Fullerene-Rich Plasmas; 5.4 Two-Color Pump for Harmonic Generation in C60; 5.5 Analysis of the Morphology of Fullerene Targets and Ablated Materials; 5.6 Theoretical Calculations of HHG in Fullerenes 5.7 Calculations of HHG in Endohedral Fullerenes5.8 Discussion; References; Chapter 6. Enhancement of Harmonic Yield from Ablation Plumes; 6.1 Two-Color Pump for Enhancement of Harmonic Output from Plasma over the Whole Plateau Region; 6.2 Application of Time-Resolved Spectroscopy of Laser Plasma for Enhancement of Harmonic Efficiency and Generation of Second Plateau in Harmonic Distribution; 6.3 Application of Carbon Aerogel Plumes as Efficient Media for HHG in the 40-90 nm Range; 6.4 Comparative Studies of HHG in Laser Plasmas and Gases; References Chapter 7. Recent Developments and Future Perspectives of Plasma HHG |
Record Nr. | UNINA-9910788621103321 |
Ganeev Rashid | ||
Singapore, : World Scientific, 2013 | ||
Materiale a stampa | ||
Lo trovi qui: Univ. Federico II | ||
|
High-order harmonic generation in laser plasma plumes [[electronic resource] /] / Rashid A. Ganeev |
Autore | Ganeev Rashid |
Pubbl/distr/stampa | Singapore, : World Scientific, 2013 |
Descrizione fisica | 1 online resource (250 p.) |
Disciplina | 530.443 |
Soggetto topico |
Harmonics (Electric waves)
Plasma (Ionized gases) |
ISBN |
1-283-90015-7
1-84816-981-7 |
Formato | Materiale a stampa |
Livello bibliografico | Monografia |
Lingua di pubblicazione | eng |
Nota di contenuto |
Contents; Preface; List of Figures and Tables; Chapter 1. Introduction; References; Chapter 2. Basic Principles of Harmonic Generation in Plasmas; 2.1 Fundamentals of HHG in Isotropic Media; 2.2 High-Order Harmonic Generation in Various Laser Plasmas; 2.2.1 Boron; 2.2.2 Silver; 2.2.3 Gold; 2.3 Application of 400-nm Radiation for Harmonic Generation in Laser Plasma; 2.4 High-Order Harmonic Generation in Plasmas Produced by Laser Pulses of Different Durations; 2.5 Analysis of Laser-Produced Plasma Characteristics for Optimization of HHG; References
Chapter 3. Resonance-Induced Enhancement of High-Order Harmonic Generation in Plasma3.1 Giant Enhancement of 13th Harmonic Generation in Indium Plasma; 3.2 Single Harmonic Enhancement in Chromium, Gallium Arsenide, and Indium Antimonide Plasmas; 3.3 Single Harmonic Enhancement at Strong Excitation Conditions; 3.4 Resonance Enhancement of Odd and Even Harmonics in Tin Plasma During Two-Color Pumping; 3.5 Plasma Harmonic Enhancement Using Two-Color Pump and Chirp Variation of 1 kHz Ti:sapphire Laser; 3.5.1 Experimental; 3.5.2 Silver plasma; 3.5.3 Chromium plasma; 3.5.4 Vanadium plasma 3.6 Theoretical Approaches for Description of Observed Peculiarities of Resonant Enhancement of Single Harmonic in Laser PlasmaReferences; Chapter 4. Cluster-Containing Plasma Plumes: Attractive Media for High-Order Harmonic Generation of Laser Radiation; 4.1 Overview; 4.2 Ablation of Metal Nanoparticles; 4.3 Ablation of Bulk Metals; 4.4 Overview of Early Studies of Harmonic Generation in Cluster-Containing Media; 4.5 Application of Cluster-Containing Plasma for Efficient HHG; 4.6 Peculiarities of HHG in Nanoparticle-Containing Plasmas 4.7 Advantages and Disadvantages of the Application of Cluster-Containing Plasmas for the Enhancement of HHG EfficiencyReferences; Chapter 5. Application of Fullerenes for Harmonic Generation; 5.1 First Observation of HHG in Fullerene Plasma; 5.2 Influence of Various Experimental Parameters on HHG Efficiency in Fullerene Plasma; 5.3 Studies of Harmonic Modulation from Fullerene-Rich Plasmas; 5.4 Two-Color Pump for Harmonic Generation in C60; 5.5 Analysis of the Morphology of Fullerene Targets and Ablated Materials; 5.6 Theoretical Calculations of HHG in Fullerenes 5.7 Calculations of HHG in Endohedral Fullerenes5.8 Discussion; References; Chapter 6. Enhancement of Harmonic Yield from Ablation Plumes; 6.1 Two-Color Pump for Enhancement of Harmonic Output from Plasma over the Whole Plateau Region; 6.2 Application of Time-Resolved Spectroscopy of Laser Plasma for Enhancement of Harmonic Efficiency and Generation of Second Plateau in Harmonic Distribution; 6.3 Application of Carbon Aerogel Plumes as Efficient Media for HHG in the 40-90 nm Range; 6.4 Comparative Studies of HHG in Laser Plasmas and Gases; References Chapter 7. Recent Developments and Future Perspectives of Plasma HHG |
Record Nr. | UNINA-9910811800603321 |
Ganeev Rashid | ||
Singapore, : World Scientific, 2013 | ||
Materiale a stampa | ||
Lo trovi qui: Univ. Federico II | ||
|
Physics of nonneutral plasmas / Ronald C. Davidson |
Autore | Davidson, Ronald C. <1941- > |
Pubbl/distr/stampa | Redwood City, California : Addison-Wesley, 1990 |
Descrizione fisica | XVI, 735 p. : ill. ; 24 cm |
Disciplina | 530.443 |
Collana | Frontiers in physics |
Soggetto non controllato | Plasma non neutrale |
ISBN | 0-201-52223-3 |
Formato | Materiale a stampa |
Livello bibliografico | Monografia |
Lingua di pubblicazione | eng |
Record Nr. | UNINA-990000515110403321 |
Davidson, Ronald C. <1941- > | ||
Redwood City, California : Addison-Wesley, 1990 | ||
Materiale a stampa | ||
Lo trovi qui: Univ. Federico II | ||
|
Spectroscopy, dynamics and molecular theory of carbon plasmas and vapors [[electronic resource] ] : advances in the understanding of the most complex high-temperature elemental system / / editors, László Nemes, Stephan Irle ; foreword by Harold Kroto |
Pubbl/distr/stampa | Singapore ; ; London, : World Scientific, 2011 |
Descrizione fisica | 1 online resource (536 p.) |
Disciplina |
530.443
541.28 |
Altri autori (Persone) |
NemesL
IrleStephan KrotoHarold |
Soggetto topico |
Plasma (Ionized gases)
Nanostructured materials Vapors Carbon Quantum theory Molecular spectroscopy Atomic spectroscopy |
Soggetto genere / forma | Electronic books. |
ISBN |
1-283-43328-1
9786613433282 981-283-765-5 |
Formato | Materiale a stampa |
Livello bibliografico | Monografia |
Lingua di pubblicazione | eng |
Nota di contenuto |
Foreword; Preface; Contents; Experimental; Chapter 1 Spectroscopy of Carbon Nanotube Production Processes; 1. Introduction; 2. Arc Discharge; 3. Laser Plumes; 4. Glow Discharge; 5. Flames; 6. Conclusions; References; Chapter 2 Spectroscopic Studies on Laser-Produced Carbon Vapor; 1. Introduction; 2. Experimental Apparatus; 2.1. Laser ablation system; 2.2. Optical emission spectroscopy; 2.3. Laser-induced fluorescence imaging spectroscopy; 3. Optical Emission from Laser-Produced Carbon Vapor [Sasaki et al. (2002)]; 3.1. Temporal variation of optical emission intensity
3.2. Optical emission spectrum3.3. Spatial distribution of delayed continuum emission; 4. Spatiotemporal Variations of C2 and C3 Radical Densities [Sasaki et al. (2002)]; 4.1. C2 and C3 radical densities in vacuum; 4.2. C2 and C3 radical densities in ambient He gas at 1 Torr; 4.3. C2 and C3 radical densities in ambient He gas at 5 Torr; 5. Temporal Change in the Total Numbers of C2 and C3; 6. Spatiotemporal Variation of Plume Temperature [Sasaki and Aoki (2008)]; 6.1. Evaluation of plume temperature; 6.2. Spatial distribution of plume temperature; 6.3. Temporal variation of plume temperature 7. A Scenario for the Growth of Carbon Clusters8. Conclusions; References; Chapter 3 Kinetic and Diagnostic Studies of Carbon Containing Plasmas and Vapors Using Laser Absorption Techniques; 1. Introduction; 2. Plasma Chemistry and Reaction Kinetics; 2.1. General considerations; 2.2. Molecular microwave plasmas containing hydrocarbons; 3. Gas-Phase Characterization in Diamond Hot-Filament CVD; 4. Kinetic Studies and Molecular Spectroscopy of Radicals; 4.1. Line strengths and transition dipole moment of CH3; 4.2. Molecular spectroscopy of the CN radical 5. Quantum Cascade Laser Absorption Spectroscopy for Plasmas Diagnostics and Control5.1. General considerations; 5.2. Trace gas measurements using optically resonant cavities; 5.3. In situ monitoring of plasma etch processes with a QCL arrangement in semiconductor industrial environment; 6. Summary and Conclusions; Acknowledgements; References; Chapter 4 Spectroscopy of Carbon Containing Diatomic Molecules; 1. Introduction; 1.1. Differences between atomic and diatomic spectra; 1.2. The line strength; 2. Diatomic Quantum Theory; 2.1. Diatomic eigenfunctions; 2.2. Diatomic parity 2.3. Homonuclear diatomics2.4. Born-Oppenheimer approximation; 2.5. Hund's angular momentum coupling cases; 3. The Diatomic Hamiltonian; 3.1. The rotational Hamiltonian; 3.2. The fine structure Hamiltonian; 3.3. Hamiltonian matrix elements in Hund's case (a); 3.4. Centrifugal corrections to molecular parameters; 4. Finding the Molecular Parameters by Fitting a Measured Spectrum; 4.1. Example of a spectrum fit; 5. Diatomic Line Strengths in the Case (a) Basis; 5.1. RKR potentials and vibrational eigenfunctions; 5.2. Computation of the diatomic line strength 6. Example Applications of Line Strengths |
Record Nr. | UNINA-9910464537703321 |
Singapore ; ; London, : World Scientific, 2011 | ||
Materiale a stampa | ||
Lo trovi qui: Univ. Federico II | ||
|
Spectroscopy, dynamics and molecular theory of carbon plasmas and vapors [[electronic resource] ] : advances in the understanding of the most complex high-temperature elemental system / / editors, László Nemes, Stephan Irle ; foreword by Harold Kroto |
Pubbl/distr/stampa | Singapore ; ; London, : World Scientific, 2011 |
Descrizione fisica | 1 online resource (536 p.) |
Disciplina |
530.443
541.28 |
Altri autori (Persone) |
NemesL
IrleStephan KrotoHarold |
Soggetto topico |
Plasma (Ionized gases)
Nanostructured materials Vapors Carbon Quantum theory Molecular spectroscopy Atomic spectroscopy |
ISBN |
1-283-43328-1
9786613433282 981-283-765-5 |
Formato | Materiale a stampa |
Livello bibliografico | Monografia |
Lingua di pubblicazione | eng |
Nota di contenuto |
Foreword; Preface; Contents; Experimental; Chapter 1 Spectroscopy of Carbon Nanotube Production Processes; 1. Introduction; 2. Arc Discharge; 3. Laser Plumes; 4. Glow Discharge; 5. Flames; 6. Conclusions; References; Chapter 2 Spectroscopic Studies on Laser-Produced Carbon Vapor; 1. Introduction; 2. Experimental Apparatus; 2.1. Laser ablation system; 2.2. Optical emission spectroscopy; 2.3. Laser-induced fluorescence imaging spectroscopy; 3. Optical Emission from Laser-Produced Carbon Vapor [Sasaki et al. (2002)]; 3.1. Temporal variation of optical emission intensity
3.2. Optical emission spectrum3.3. Spatial distribution of delayed continuum emission; 4. Spatiotemporal Variations of C2 and C3 Radical Densities [Sasaki et al. (2002)]; 4.1. C2 and C3 radical densities in vacuum; 4.2. C2 and C3 radical densities in ambient He gas at 1 Torr; 4.3. C2 and C3 radical densities in ambient He gas at 5 Torr; 5. Temporal Change in the Total Numbers of C2 and C3; 6. Spatiotemporal Variation of Plume Temperature [Sasaki and Aoki (2008)]; 6.1. Evaluation of plume temperature; 6.2. Spatial distribution of plume temperature; 6.3. Temporal variation of plume temperature 7. A Scenario for the Growth of Carbon Clusters8. Conclusions; References; Chapter 3 Kinetic and Diagnostic Studies of Carbon Containing Plasmas and Vapors Using Laser Absorption Techniques; 1. Introduction; 2. Plasma Chemistry and Reaction Kinetics; 2.1. General considerations; 2.2. Molecular microwave plasmas containing hydrocarbons; 3. Gas-Phase Characterization in Diamond Hot-Filament CVD; 4. Kinetic Studies and Molecular Spectroscopy of Radicals; 4.1. Line strengths and transition dipole moment of CH3; 4.2. Molecular spectroscopy of the CN radical 5. Quantum Cascade Laser Absorption Spectroscopy for Plasmas Diagnostics and Control5.1. General considerations; 5.2. Trace gas measurements using optically resonant cavities; 5.3. In situ monitoring of plasma etch processes with a QCL arrangement in semiconductor industrial environment; 6. Summary and Conclusions; Acknowledgements; References; Chapter 4 Spectroscopy of Carbon Containing Diatomic Molecules; 1. Introduction; 1.1. Differences between atomic and diatomic spectra; 1.2. The line strength; 2. Diatomic Quantum Theory; 2.1. Diatomic eigenfunctions; 2.2. Diatomic parity 2.3. Homonuclear diatomics2.4. Born-Oppenheimer approximation; 2.5. Hund's angular momentum coupling cases; 3. The Diatomic Hamiltonian; 3.1. The rotational Hamiltonian; 3.2. The fine structure Hamiltonian; 3.3. Hamiltonian matrix elements in Hund's case (a); 3.4. Centrifugal corrections to molecular parameters; 4. Finding the Molecular Parameters by Fitting a Measured Spectrum; 4.1. Example of a spectrum fit; 5. Diatomic Line Strengths in the Case (a) Basis; 5.1. RKR potentials and vibrational eigenfunctions; 5.2. Computation of the diatomic line strength 6. Example Applications of Line Strengths |
Record Nr. | UNINA-9910789065803321 |
Singapore ; ; London, : World Scientific, 2011 | ||
Materiale a stampa | ||
Lo trovi qui: Univ. Federico II | ||
|
Spectroscopy, dynamics and molecular theory of carbon plasmas and vapors [[electronic resource] ] : advances in the understanding of the most complex high-temperature elemental system / / editors, László Nemes, Stephan Irle ; foreword by Harold Kroto |
Pubbl/distr/stampa | Singapore ; ; London, : World Scientific, 2011 |
Descrizione fisica | 1 online resource (536 p.) |
Disciplina |
530.443
541.28 |
Altri autori (Persone) |
NemesL
IrleStephan KrotoHarold |
Soggetto topico |
Plasma (Ionized gases)
Nanostructured materials Vapors Carbon Quantum theory Molecular spectroscopy Atomic spectroscopy |
ISBN |
1-283-43328-1
9786613433282 981-283-765-5 |
Formato | Materiale a stampa |
Livello bibliografico | Monografia |
Lingua di pubblicazione | eng |
Nota di contenuto |
Foreword; Preface; Contents; Experimental; Chapter 1 Spectroscopy of Carbon Nanotube Production Processes; 1. Introduction; 2. Arc Discharge; 3. Laser Plumes; 4. Glow Discharge; 5. Flames; 6. Conclusions; References; Chapter 2 Spectroscopic Studies on Laser-Produced Carbon Vapor; 1. Introduction; 2. Experimental Apparatus; 2.1. Laser ablation system; 2.2. Optical emission spectroscopy; 2.3. Laser-induced fluorescence imaging spectroscopy; 3. Optical Emission from Laser-Produced Carbon Vapor [Sasaki et al. (2002)]; 3.1. Temporal variation of optical emission intensity
3.2. Optical emission spectrum3.3. Spatial distribution of delayed continuum emission; 4. Spatiotemporal Variations of C2 and C3 Radical Densities [Sasaki et al. (2002)]; 4.1. C2 and C3 radical densities in vacuum; 4.2. C2 and C3 radical densities in ambient He gas at 1 Torr; 4.3. C2 and C3 radical densities in ambient He gas at 5 Torr; 5. Temporal Change in the Total Numbers of C2 and C3; 6. Spatiotemporal Variation of Plume Temperature [Sasaki and Aoki (2008)]; 6.1. Evaluation of plume temperature; 6.2. Spatial distribution of plume temperature; 6.3. Temporal variation of plume temperature 7. A Scenario for the Growth of Carbon Clusters8. Conclusions; References; Chapter 3 Kinetic and Diagnostic Studies of Carbon Containing Plasmas and Vapors Using Laser Absorption Techniques; 1. Introduction; 2. Plasma Chemistry and Reaction Kinetics; 2.1. General considerations; 2.2. Molecular microwave plasmas containing hydrocarbons; 3. Gas-Phase Characterization in Diamond Hot-Filament CVD; 4. Kinetic Studies and Molecular Spectroscopy of Radicals; 4.1. Line strengths and transition dipole moment of CH3; 4.2. Molecular spectroscopy of the CN radical 5. Quantum Cascade Laser Absorption Spectroscopy for Plasmas Diagnostics and Control5.1. General considerations; 5.2. Trace gas measurements using optically resonant cavities; 5.3. In situ monitoring of plasma etch processes with a QCL arrangement in semiconductor industrial environment; 6. Summary and Conclusions; Acknowledgements; References; Chapter 4 Spectroscopy of Carbon Containing Diatomic Molecules; 1. Introduction; 1.1. Differences between atomic and diatomic spectra; 1.2. The line strength; 2. Diatomic Quantum Theory; 2.1. Diatomic eigenfunctions; 2.2. Diatomic parity 2.3. Homonuclear diatomics2.4. Born-Oppenheimer approximation; 2.5. Hund's angular momentum coupling cases; 3. The Diatomic Hamiltonian; 3.1. The rotational Hamiltonian; 3.2. The fine structure Hamiltonian; 3.3. Hamiltonian matrix elements in Hund's case (a); 3.4. Centrifugal corrections to molecular parameters; 4. Finding the Molecular Parameters by Fitting a Measured Spectrum; 4.1. Example of a spectrum fit; 5. Diatomic Line Strengths in the Case (a) Basis; 5.1. RKR potentials and vibrational eigenfunctions; 5.2. Computation of the diatomic line strength 6. Example Applications of Line Strengths |
Record Nr. | UNINA-9910825750203321 |
Singapore ; ; London, : World Scientific, 2011 | ||
Materiale a stampa | ||
Lo trovi qui: Univ. Federico II | ||
|