000			06361cam a2200553Ki 4500
001			9781003041962
003			FlBoTFG
005			20220531132538.0
006			m d
007			cr cnu---unuuu
008			200222s2020 enk o 000 0 eng d
040			_aOCoLC-P _beng _cOCoLC-P
020			_a9781000066173 _q(electronic bk.)
020			_a1000066177 _q(electronic bk.)
020			_a9781003041962 _q(electronic bk.)
020			_a1003041965 _q(electronic bk.)
020			_a9781000066197 _q(electronic bk. : Mobipocket)
020			_a1000066193 _q(electronic bk. : Mobipocket)
020			_a9781000066210 _q(electronic bk. : EPUB)
020			_a1000066215 _q(electronic bk. : EPUB)
035			_a(OCoLC)1140789079
035			_a(OCoLC-P)1140789079
050		4	_aTA1695.5
072		7	_aTEC _x019000 _2bisacsh
072		7	_aSCI _x013050 _2bisacsh
072		7	_aSCI _x055000 _2bisacsh
072		7	_aTTBL _2bicssc
082	0	4	_a621.36/6 _223
100	1		_aApollonov, Victor V.
245	1	0	_aHigh Energy Ecologically Safe HF/DF Lasers _h[electronic resource] : _bPhysics of Self Initiated Volume Discharge Based HF/DF Lasers / _cVictor V. Apollonov, Sergey Yu. Kazantsev.
260			_aMilton : _bCRC Press LLC, _c2020.
300			_a1 online resource (226 pages)
505	0		_aCover -- Half Title -- Title Page -- Copyright Page -- Dedication -- Table of Contents -- Introduction -- 1. High-energy HF (DF) Lasers with Non-chain Chemical Reaction (Literature Review) -- 1.1. Chemical HF(DF) lasers. (The Principle of Operation and General Characteristics) -- 1.2. HF (DF) Lasers with the Initiation of Non-chain Chemical Reaction by Electric Discharge -- 1.3. The Problem of Increasing the Energy Characteristics of Non-chain HF Lasers -- 1.4. Search for Methods for SSVD formation in the Working Mixtures of HF(DF) Laser
505	8		_a1.5. P-P Non-chain HF (DF) Lasers with a High Pulse Repetition Rate -- 2. Self-initiated Volume Discharge in Working Environments of Non-chain HF(DF) Lasers -- 2.1. SIVD in Highly Electronegative Gases (Methods of Preparation and Basic Properties) -- 2.1.1. Description of Experimental Facilities and Experimental Techniques -- 2.1.2. General Characteristics of SIVD -- 2.1.3 Effect of UV Illumination on SSVD Characteristics -- 2.1.4. Investigation of the Stability of SIVD in SF[sub(6)] and Mixtures Based on it -- 2.1.5. Dynamics of the Formation of SIVD
505	8		_a2.1.6 Factors Affecting the Spatial Homogeneity of SIVD in SF[sub(6)] Mixtures with Hydrocarbons -- 2.1.7. Influence of the Inhomogeneity of the Electric Field in the Gap on the Stability of SIVD -- 2.2. Numerical Simulation of the SIVD in SF[sub(6)]-based gas Mixtures -- 2.2.1 Calculation of the Characteristics of SIVD in the Working Mixtures of HF Laser -- 2.2.2. Modelling of the Channel Structure of SIVD in SF[sub(6)] and mixtures based on it -- 2.3. Qualitative Analysis of the Mechanisms for Limiting the Current Density in the Diffuse Channel in SF[sub(6)]
505	8		_a3. Effect of Limiting Current Density in the Diffusion Channel -- 3.1. Study of the Characteristics of a single Diffuse Channel in SF[sub(6)] and Mixtures Based on it -- 3.1.1 Description of Experimental Installations and Experimental Techniques -- 3.1.2. Investigation of the Characteristics of a Single Diffuse Channel Unlimited by External Walls -- 3.1.3. Investigation of the Characteristics of the Diffuse Channel Bounded by External Walls -- 3.1.4. Numerical Simulation of Limited SSVD -- 3.1.5. Analysis of the Results
505	8		_a3.2. Characteristics of the SSVD Under Conditions of Strong Population of Vibrationally Excited States of SF[sub(6)] Molecules -- 3.2.1. Experimental Setup and Experimental Methods -- 3.2.2. Determination of CO[sub(2)] Laser Energy Absorbed in the Discharge Gap -- 3.2.3. Investigation of the effect of CO[sub(2)] Laser Radiation on the Combustion Voltage of SSVD in SF and Mixtures based on it -- 3.2.4. The Role of the Electron Attachment Process to Vibrationally Excited SF[sub(6)] Molecules in the Effect of Limiting the Current Density -- 3.2.5. Analysis of the Results
500			_a4. Mechanisms of Development of Plasma Instabilities of Self- initiated Volume Discharge in Working Mixtures of Non-chain HF(DF) Lasers
520			_aThis book explores new principles of Self-Initiating Volume Discharge for creating high-energy non-chain HF(DF) lasers, as well as the creation of highly efficient lasers with output energy and radiation power in the spectral region of 2.6-5 m. Today, sources of high-power lasing in this spectral region are in demand in various fields of science and technology including remote sensing of the atmosphere, medicine, biological imaging, precision machining and other special applications. These applications require efficient laser sources with high pulse energy, pulsed and average power, which makes the development of physical fundamentals of high-power laser creation and laser complexes of crucial importance. High-Energy Ecologically Safe HF/DF Lasers: Physics of Self-Initiated Volume Discharge-Based HF/DF Lasers examines the conditions of formation of SSVD, gas composition and the mode of energy input into the gas on the efficiency and radiation energy of non-chain HF(DF) lasers. Key Features: Shares research results on SSVD in mixtures of non-chain HF(DF) lasers Studies the stability and dynamics of the development of SSVD Discusses the effect of the gas composition and geometry of the discharge gap (DG) on its characteristics Proposes recommendations for gas composition and for the method of obtaining SSVD in non-chain HF(DF) lasers Develops simple and reliable wide-aperture non-chain HF(DF) lasers and investigates their characteristics Investigates the possibilities of expanding the lasing spectrum of non-chain HF(DF) lasers
588			_aOCLC-licensed vendor bibliographic record.
650		7	_aTECHNOLOGY / Lasers _2bisacsh
650		7	_aSCIENCE / Chemistry / Physical & Theoretical _2bisacsh
650		7	_aSCIENCE / Physics _2bisacsh
650		0	_aHigh power lasers.
650		0	_aPhysics.
700	1		_aKazantsev, Sergey Yu.
856	4	0	_3Taylor & Francis _uhttps://www.taylorfrancis.com/books/9781003041962
856	4	2	_3OCLC metadata license agreement _uhttp://www.oclc.org/content/dam/oclc/forms/terms/vbrl-201703.pdf
999			_c73788 _d73788