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Rarefied gas dynamics : fundamentals for research and practice / Felix Sharipov
Resource type: Ressourcentyp: Buch (Online)Book (Online)Language: English Publisher: Weinheim, Germany : Wiley-VCH, 2015Description: 1 online resourceISBN:- 9783527685530
- 9783527413263
- 533.52 23
- 533/.2
- QC168
Contents:
Summary: Intro -- Related Titles -- Title Page -- Copyright -- Table of Contents -- Preface -- List of Symbols -- List of Acronyms -- Chapter 1: Molecular Description -- 1.1 Mechanics of Continuous Media and Its Restriction -- 1.2 Macroscopic State Variables -- 1.3 Dilute Gas -- 1.4 Intermolecular Potential -- 1.5 Deflection Angle -- 1.6 Differential Cross Section -- 1.7 Total Cross Section -- 1.8 Equivalent Free Path -- 1.9 Rarefaction Parameter and Knudsen Number -- Exercises -- Chapter 2: Velocity Distribution Function -- 2.1 Definition of Distribution Function -- 2.2 Moments of Distribution Function -- 2.3 Entropy and Its Flow Vector -- 2.4 Global Maxwellian -- 2.5 Local Maxwellian -- Exercises -- Chapter 3: Boltzmann Equation -- 3.1 Assumptions to Derive the Boltzmann Equation -- 3.2 General Form of the Boltzmann Equation -- 3.3 Conservation Laws -- 3.4 Entropy Production due to Intermolecular Collisions -- 3.5 Intermolecular Collisions Frequency -- Exercises -- Chapter 4: Gas-Surface Interaction -- 4.1 General form of Boundary Condition for Impermeable Surface -- 4.2 Diffuse-Specular Kernel -- 4.3 Cercignani-Lampis Kernel -- 4.4 Accommodation Coefficients -- 4.5 General form of Boundary Condition for Permeable Surface -- 4.6 Entropy Production due to Gas-Surface Interaction -- Exercises -- Chapter 5: Linear Theory -- 5.1 Small Perturbation of Equilibrium -- 5.2 Linearization Near Global Maxwellian -- 5.3 Linearization Near Local Maxwellian -- 5.4 Properties of the Linearized Collision Operator -- 5.5 Linearization of Boundary Condition -- 5.6 Series Expansion -- 5.7 Reciprocal Relations -- Exercises -- Chapter 6: Transport Coefficients -- 6.1 Constitutive Equations -- 6.2 Viscosity -- 6.3 Thermal Conductivity -- 6.4 Numerical Results -- Exercises -- Chapter 7: Model Equations -- 7.1 BGK Equation -- 7.2 S-Model -- 7.3 Ellipsoidal Model.PPN: PPN: 1657546861Package identifier: Produktsigel: ZDB-26-MYL | ZDB-30-PAD | ZDB-30-PQE
Related Titles; Title Page; Copyright; Table of Contents; Preface; List of Symbols; List of Acronyms; Chapter 1: Molecular Description; 1.1 Mechanics of Continuous Media and Its Restriction; 1.2 Macroscopic State Variables; 1.3 Dilute Gas; 1.4 Intermolecular Potential; 1.5 Deflection Angle; 1.6 Differential Cross Section; 1.7 Total Cross Section; 1.8 Equivalent Free Path; 1.9 Rarefaction Parameter and Knudsen Number; Exercises; Chapter 2: Velocity Distribution Function; 2.1 Definition of Distribution Function; 2.2 Moments of Distribution Function; 2.3 Entropy and Its Flow Vector
2.4 Global Maxwellian2.5 Local Maxwellian; Exercises; Chapter 3: Boltzmann Equation; 3.1 Assumptions to Derive the Boltzmann Equation; 3.2 General Form of the Boltzmann Equation; 3.3 Conservation Laws; 3.4 Entropy Production due to Intermolecular Collisions; 3.5 Intermolecular Collisions Frequency; Exercises; Chapter 4: Gas-Surface Interaction; 4.1 General form of Boundary Condition for Impermeable Surface; 4.2 Diffuse-Specular Kernel; 4.3 Cercignani-Lampis Kernel; 4.4 Accommodation Coefficients; 4.5 General form of Boundary Condition for Permeable Surface
4.6 Entropy Production due to Gas-Surface InteractionExercises; Chapter 5: Linear Theory; 5.1 Small Perturbation of Equilibrium; 5.2 Linearization Near Global Maxwellian; 5.3 Linearization Near Local Maxwellian; 5.4 Properties of the Linearized Collision Operator; 5.5 Linearization of Boundary Condition; 5.6 Series Expansion; 5.7 Reciprocal Relations; Exercises; Chapter 6: Transport Coefficients; 6.1 Constitutive Equations; 6.2 Viscosity; 6.3 Thermal Conductivity; 6.4 Numerical Results; Exercises; Chapter 7: Model Equations; 7.1 BGK Equation; 7.2 S-Model; 7.3 Ellipsoidal Model
7.4 Dimensionless Form of Model EquationsExercises; Chapter 8: Direct Simulation Monte Carlo Method; 8.1 Main Ideas; 8.2 Generation of Specific Distribution Function; 8.3 Simulation of Gas-Surface Interaction; 8.4 Intermolecular Interaction; 8.5 Calculation of Post-Collision Velocities; 8.6 Calculation of Macroscopic Quantities; 8.7 Statistical Scatter; Exercises; Chapter 9: Discrete Velocity Method; 9.1 Main Ideas; 9.2 Velocity Discretization; 9.3 Iterative Procedure; 9.4 Finite Difference Schemes; Exercises; Chapter 10: Velocity Slip and Temperature Jump Phenomena; 10.1 General Remarks
10.2 Viscous Velocity Slip10.3 Thermal Velocity Slip; 10.4 Reciprocal Relation; 10.5 Temperature Jump; Exercises; Chapter 11: One-Dimensional Planar Flows; 11.1 Planar Couette Flow; 11.2 Planar Heat Transfer; 11.3 Planar Poiseuille and Thermal Creep Flows; Exercises; Chapter 12: One-Dimensional Axisymmetrical Flows; 12.1 Cylindrical Couette Flow; 12.2 Heat Transfer between Two Cylinders; 12.3 Cylindrical Poiseuille and Thermal Creep Flows; Exercises; Chapter 13: Two-Dimensional Planar Flows; 13.1 Flows Through a Long Rectangular Channel; 13.2 Flows Through Slits and Short Channels
13.3 End Correction for Channel
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