High-Power Lasers and Laser Plasmas / Moshchnye Lazery I Lazernaya Plazma /
(Sprache: Englisch)
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Inhaltsverzeichnis zu „High-Power Lasers and Laser Plasmas / Moshchnye Lazery I Lazernaya Plazma / “
Stimulated Mandel' shtam - Brillouin Scattering Lasers V. V. Ragul'skii.- I Conditions for Obtaining Stationary Lasing with Stimulated Scattering of Light.- 1. Influence of Intensity, Energy Density, and Exciting-Radiation Pulse Duration on the Laser Operation.-
2. Experimental Verification of the Conditions for Stationary Lasing.- II Gains and Line Widths for SMBS in Gases.- III Single-Frequency SMBS Ring Laser.-
1. Feasibility of Effective Conversion of Pump Radiation.-
2. Single-Frequency SMBS Laser.- IV Operation of SMBS Amplifier in the Saturation Regime.-
1. Characteristics of SMBS Amplifier in the Stationary Regime.-
2. Experimental Investigation of Amplifier Operation in the Saturation Region.- V Q Switching by SMBS.-
1. Lasing Dynamics.-
2. Conditions under Which Q Switching Is Possible.-
3. Experimental Verification of the Q-Switching Conditions.- VI Inversion of the Exciting-Radiation Wave Front in SMBS.-
1. Comparison of the Wave Fronts of the Exciting and Scattered Light with the Aid of a Phase Plate.-
2. Influence of the Structure of the Exciting Radiation Field on the Shape of the Scattered-Light Front.-
3. Compensation for the Phase Distortions in an Amplifying Medium with the Aid of a "Brillouin Mirror".- VII SMBS in the Case of Exciting Radiation with a Broad Spectrum.- Appendix Experimental Technique.-
1. Divergence Measurement Procedure.-
2. Cell for Optical Investigations of Compressed Gases.-
3. Faraday Decoupler.-
4. Single-Mode Ruby Laser with Pulse Duration 60 nsec.-
5. Single-Mode Ruby Laser with Pulse Duration 60-200 nsec.-
6. Fabry - Perot Etalon with 46-cm Base..- Literature Cited.- Compressed-Gas Lasers V. A. Danilychev, O. M. Kerimov, and I. B. Kovsh.- I Electroionization Method of Exciting Compressed-Gas Lasers.-
1. Mechanism of Current Flow through the Active Medium of an Electroionization Laser.-
2. Experimental Technique.- 2.1. Construction of Laser Chambers.- 2.2. Optical
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Resonators.- 2.3. Measurements of Laser Parameters.-
3. Electric Characteristics of Active Medium.- 3.1. Calculation of the Characteristics of the Discharge Excited by the Electroionization Method.- 3.2. Experimental Investigation of a Nonautonomous Discharge Initiated in a Compressed Gas by an Intense Electron Beam - Discussion of Results..- II Electroionization CO2 High-Pressure Laser.-
1. Kinetics of Population of Working Levels; Gain of Active Medium of Electroionization CO2 Laser.-
2. Threshold Characteristics, Output Energy, Power, and Efficiency of Laser; Divergence of the Radiation..-
3. Gain Spectrum of Electroionization CO2 Laser.-
4. Relaxation of Upper Laser Level at High Pressures.-
5. Operating Regimes of Electroionization CO2 Lasers.- III High-Pressure Gas Lasers Using Other Working Media.-
1. Electroionization CO Laser.-
2. Laser Operating with Compressed Xenon and Ar:Xe Mixture..-
3. Ultraviolet High-Pressure Laser Using the Mixture Ar:N2.- Conclusion.- Appendix Theory of Current Flow through an Ionized Gas.- Literature Cited.- Experimental Investigation of the Reflection and Absorptionof High-Power Radiation in a Laser Plasma O. N. Krokhin, G. V. Sklizkov, and A. S. Shikanov.- I Reflection of Laser Radiation from a Plasma (Survey of the Literature).-
1. Experimental Conditions Realized in Research on Laser-Plasma Parameters.-
2. Energy Composition of the Reflected Radiation; Anomalous Character of the Interaction of Laser Radiation with a Plasma in a Wide Range of Flux Densities.-
3. Spectral Composition of Reflected and Scattered Radiation.- II Investigation of the Absorption of Laser Radiation in Thin Targets.-
1. Experimental Setup.-
2. Multiframe Schlieren Photography in Ruby-Laser Light; Spatial Resolution.-
3. Determination of the Time of Bleaching of a Thin Target.-
4. Investigation of the Dynamics of Motion of Shock Waves in the Gas Surrounding the Target; Absorbed Energy.-
5. Discussion of Results.- III Reflection of Laser Radiation from a Dense Plasma.-
1. Experimental Setup.-
2. Behavior of the Coefficient of Reflection of Laser Radiation from a Plasma in the Flux-Density Interval 1010-1014 W/cm2.-
3. Dependence of the Reflection Coefficient on the Time; Plasma Probing by Ruby-Laser Radiation.-
4. Oscillations of Reflected Radiation with Time.-
5. Directivity of Reflected Radiation.- IV Generation of Harmonics of the Heating-Radiation Frequency in a Laser Plasma.-
1. Investigation of the Generation of the Second Harmonic of the Heating Radiation in a Laser Plasma; Dependence on the Flux Density; Variation with Time..-
2. Generation of 3/2?0 Line.- V Anisotropy of X Rays from a Laser Plasma.-
l· Procedure of Multichannel Measurement of Continuous X Radiation.-
2. Investigation of the Directivity of the X Rays.-
3. Possibility of Measuring the Electron "Temperature" of a Laser Plasma by the "Absorber" Method.- Literature Cited.- Experimental Study of Cumulative
3. Electric Characteristics of Active Medium.- 3.1. Calculation of the Characteristics of the Discharge Excited by the Electroionization Method.- 3.2. Experimental Investigation of a Nonautonomous Discharge Initiated in a Compressed Gas by an Intense Electron Beam - Discussion of Results..- II Electroionization CO2 High-Pressure Laser.-
1. Kinetics of Population of Working Levels; Gain of Active Medium of Electroionization CO2 Laser.-
2. Threshold Characteristics, Output Energy, Power, and Efficiency of Laser; Divergence of the Radiation..-
3. Gain Spectrum of Electroionization CO2 Laser.-
4. Relaxation of Upper Laser Level at High Pressures.-
5. Operating Regimes of Electroionization CO2 Lasers.- III High-Pressure Gas Lasers Using Other Working Media.-
1. Electroionization CO Laser.-
2. Laser Operating with Compressed Xenon and Ar:Xe Mixture..-
3. Ultraviolet High-Pressure Laser Using the Mixture Ar:N2.- Conclusion.- Appendix Theory of Current Flow through an Ionized Gas.- Literature Cited.- Experimental Investigation of the Reflection and Absorptionof High-Power Radiation in a Laser Plasma O. N. Krokhin, G. V. Sklizkov, and A. S. Shikanov.- I Reflection of Laser Radiation from a Plasma (Survey of the Literature).-
1. Experimental Conditions Realized in Research on Laser-Plasma Parameters.-
2. Energy Composition of the Reflected Radiation; Anomalous Character of the Interaction of Laser Radiation with a Plasma in a Wide Range of Flux Densities.-
3. Spectral Composition of Reflected and Scattered Radiation.- II Investigation of the Absorption of Laser Radiation in Thin Targets.-
1. Experimental Setup.-
2. Multiframe Schlieren Photography in Ruby-Laser Light; Spatial Resolution.-
3. Determination of the Time of Bleaching of a Thin Target.-
4. Investigation of the Dynamics of Motion of Shock Waves in the Gas Surrounding the Target; Absorbed Energy.-
5. Discussion of Results.- III Reflection of Laser Radiation from a Dense Plasma.-
1. Experimental Setup.-
2. Behavior of the Coefficient of Reflection of Laser Radiation from a Plasma in the Flux-Density Interval 1010-1014 W/cm2.-
3. Dependence of the Reflection Coefficient on the Time; Plasma Probing by Ruby-Laser Radiation.-
4. Oscillations of Reflected Radiation with Time.-
5. Directivity of Reflected Radiation.- IV Generation of Harmonics of the Heating-Radiation Frequency in a Laser Plasma.-
1. Investigation of the Generation of the Second Harmonic of the Heating Radiation in a Laser Plasma; Dependence on the Flux Density; Variation with Time..-
2. Generation of 3/2?0 Line.- V Anisotropy of X Rays from a Laser Plasma.-
l· Procedure of Multichannel Measurement of Continuous X Radiation.-
2. Investigation of the Directivity of the X Rays.-
3. Possibility of Measuring the Electron "Temperature" of a Laser Plasma by the "Absorber" Method.- Literature Cited.- Experimental Study of Cumulative
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Bibliographische Angaben
- 2012, 1978., 241 Seiten, Maße: 27,9 cm, Kartoniert (TB), Englisch
- Herausgegeben von Basov, N. G.
- Verlag: Springer
- ISBN-10: 1468416340
- ISBN-13: 9781468416343
Sprache:
Englisch
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