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Preface; Reviewers; Contents; 1 The Theoretical Basis of the Low-Temperature Plasma; 1.1 The Basic Approaches to the Description of Plasma; 1.1.1 The Plasma Relations for the Full Thermodynamic Equilibrium; 1.1.2 The Model of Local Thermodynamic Equilibrium in Plasma; 1.1.3 The Model of Partial Local Thermodynamic Equilibrium in Plasma; 1.2 Model of Equilibrium Plasma; 1.2.1 The Energy Balance Equation; 1.2.2 The Momentum Equations of the Plasma Flow; 1.2.3 The Continuity Equation of the Plasma Flow; 1.2.4 The Maxwell's Equations.
1.2.5 The Equations of Equilibrium Plasma Model in a Cylindrical Coordinate System1.3 The Two-Temperature Model of Nonequilibrium Plasma; 1.3.1 The Violation of Ionization Equilibrium in Plasma. Equation of Ionization Equilibrium; 1.4 The Two-Speed Plasma Model; 1.5 Gas Dynamic Models of Plasma Turbulence; 1.5.1 The Reynolds-Averaged Navier-Stokes Equations; 1.5.2 The Main Gas Dynamic Model of Turbulence; 1.6 Models of Light Emission and Absorption in Plasma; 1.6.1 Radiation in the Continuous Spectrum; 1.6.1.1 Bremsstrahlung (ff) Radiation; 1.6.1.2 Recombination (fb) Radiation.
1.6.2 Absorption in the Continuum1.6.2.1 The Bremsstrahlung (ff) Absorption; 1.6.3 Radiation in the Spectral Lines; 1.6.3.1 The Spectral Lines Outline; 1.6.4 The Absorption in Spectral Lines; References; 2 Classical Theory of the Particle Scattering; 2.1 Classical Consideration of the Particle Scattering; 2.2 Determination of Cross Sections for Plasma Particles Interaction; 2.2.1 Coulomb Scattering: The Cross Section of the Interaction of Charged Particles; 2.2.2 Ramseur Effect and the Resonance Scattering of the Electrons by Atoms.
2.2.3 The Cross Sections for the Interaction of Molecule-Molecule, Atom-Atom2.2.4 The Cross Sections for the Interaction of the Atom-Ion; References; 3 Quantum Mechanical Theory of the Particle Scattering; 3.1 The Schrödinger Equation; 3.2 Solution of the Schrödinger Equation for the Elastic Interactions; 3.3 Determination of the Phase Shift; 3.4 Born Approximation for Calculating the Amplitudes of the Scattered Waves; 3.5 Determination of Differential and Total Cross Sections of Elastic Interactions; References.
4 Determination of the Composition, Thermodynamic Properties, and Transport Coefficients on the Basis of the Mean Free Path4.1 The Plasma Composition; 4.2 Thermodynamic Properties of the Plasma; 4.3 Transport Coefficients of the Plasma; 4.3.1 Determination of the Electrical Conductivity and Thermal Conductivity; 4.3.2 Determination of the Viscosity, the Ambipolar Diffusion Coefficient, and Integrated Emission; 4.4 The Coefficients of Triple Recombination and Impact Ionization; 4.5 The Frequency of Particle Collisions, the Current Density, and Heating Capacity of Plasma; References.
1.2.5 The Equations of Equilibrium Plasma Model in a Cylindrical Coordinate System1.3 The Two-Temperature Model of Nonequilibrium Plasma; 1.3.1 The Violation of Ionization Equilibrium in Plasma. Equation of Ionization Equilibrium; 1.4 The Two-Speed Plasma Model; 1.5 Gas Dynamic Models of Plasma Turbulence; 1.5.1 The Reynolds-Averaged Navier-Stokes Equations; 1.5.2 The Main Gas Dynamic Model of Turbulence; 1.6 Models of Light Emission and Absorption in Plasma; 1.6.1 Radiation in the Continuous Spectrum; 1.6.1.1 Bremsstrahlung (ff) Radiation; 1.6.1.2 Recombination (fb) Radiation.
1.6.2 Absorption in the Continuum1.6.2.1 The Bremsstrahlung (ff) Absorption; 1.6.3 Radiation in the Spectral Lines; 1.6.3.1 The Spectral Lines Outline; 1.6.4 The Absorption in Spectral Lines; References; 2 Classical Theory of the Particle Scattering; 2.1 Classical Consideration of the Particle Scattering; 2.2 Determination of Cross Sections for Plasma Particles Interaction; 2.2.1 Coulomb Scattering: The Cross Section of the Interaction of Charged Particles; 2.2.2 Ramseur Effect and the Resonance Scattering of the Electrons by Atoms.
2.2.3 The Cross Sections for the Interaction of Molecule-Molecule, Atom-Atom2.2.4 The Cross Sections for the Interaction of the Atom-Ion; References; 3 Quantum Mechanical Theory of the Particle Scattering; 3.1 The Schrödinger Equation; 3.2 Solution of the Schrödinger Equation for the Elastic Interactions; 3.3 Determination of the Phase Shift; 3.4 Born Approximation for Calculating the Amplitudes of the Scattered Waves; 3.5 Determination of Differential and Total Cross Sections of Elastic Interactions; References.
4 Determination of the Composition, Thermodynamic Properties, and Transport Coefficients on the Basis of the Mean Free Path4.1 The Plasma Composition; 4.2 Thermodynamic Properties of the Plasma; 4.3 Transport Coefficients of the Plasma; 4.3.1 Determination of the Electrical Conductivity and Thermal Conductivity; 4.3.2 Determination of the Viscosity, the Ambipolar Diffusion Coefficient, and Integrated Emission; 4.4 The Coefficients of Triple Recombination and Impact Ionization; 4.5 The Frequency of Particle Collisions, the Current Density, and Heating Capacity of Plasma; References.