涡量和不可压缩流

内容概要

Vorticity is perhaps the most important facet of turbulent fluid flows. This book is intended to be a comprehensive introduction to the mathematical theory of vorticity and incompressible flow ranging from elementary introductory material to current research topics. Although the contents center on mathematical theory, many parts of the book showcase a modem applied mathematics interaction among rigorous mathematical theory, numerical, asymptotic, and qualitative simplified modeling, and physical phenomena. The interested reader can see many examples of this symbiotic interaction throughout the hook, especially in Chaps. 4-9 and 13. The authors hope that this point of view will be interesting to mathematicians as well as other scientists and engineers with interest in the mathematical theory of incompressible flows.

书籍目录

Preface1 An Introduction to Vortex Dynamics for Incompressible Fluid Flows  1.1 The Euler and the Navier-Stokes Equations  1.2 Symmetry Groups for the Euler and the Navier-Stokes Equations  1.3 Particle Trajectories  1.4 The Vorticity, a Deformation Matrix, and Some Elementary Exact Solutions  1.5 Simple Exact Solutions with Convection, Vortex Stretching, and Diffusion  1.6 Some Remarkable Properties of the Vorticity in Ideal Fluid Flows  1.7 Conserved Quantities in Ideal and Viscous Fluid Flows  1.8 Leray''s Formulation of Incompressible Flows and Hodge''s Decomposition of Vector Fields  1.9 Appendix  Notes for Chapter 1  References for Chapter 12 The Vorfidty-Stream Formulation of the Euier and the Navier. Stokes Equations  2.1 The Vorticity-Stream Formulation for 2D Flows  2.2 A General Method for Constructing Exact Steady Solutions to the 2D Euler Equations  2.3 Some Special 3D Flows with Nontrivial Vortex Dynamics  2.4 The Vorticity-Stream Formulation for 3D Flows  2.5 Formulation of the Euler Equation as an Integrodifferential Equation for the Particle Trajectories  Notes for Chapter 2  References for Chapter 23 Energy Methods for the Euler and the Navier-Stokes Equations  3.1 Energy Methods: Elementary Concepts  3.2 Local-in-Time Existence of Solutions by Means of Energy Methods  3.3 Accumulation of Vorticity and the Existence of Smooth Solutions Globally in Time  3.4 Viscous-Splitting Algorithms for the Navier-Stokes Equation  3.5 Appendix for Chapter 3  Notes for Chapter 3  References for Chapter 34 The Particle-Trajectory Method for Existence and Uniqueness of Solutions to the Euler Equation  4.1 The Local-in-Time Existence of Inviscid Solutions  4.2 Link between Global-in-Time Existence of Smooth Solutions and the Accumulation of Vorticity through Stretching  4.3 Global Existence of 3D Axisymmetric Flows without Swirl  4.4 Higher Regularity  4.5 Appendixes for Chapter 4  Notes for Chapter 4  References for Chapter 45 The Search for Singular Solutions to the 3D Euler Equations  5.1 The Interplay between Mathematical Theory and Numerical Computations in the Search for Singular Solutions  5.2 A Simple 1D Model for the 3D Vorticity Equation  5.3 A 2D Model for Potential Singularity Formation in 3D Euler Equations  5.4 Potential Singularities in 3D Axisymmetric Flows with Swirl  5.5 Do the 3D Euler Solutions Become Singular in Finite Times Notes for Chapter 5  References for Chapter 56 Computational Vortex Methods  6.1 The Random-Vortex Method for Viscous Strained Shear Layers  6.2 2D Inviscid Vortex Methods  6.3 3D Inviscid-Vortex Methods  6.4 Convergence of Inviscid-Vortex Methods  6.5 Computational Performance of the 2D Inviscid-Vortex Method on a Simple Model Problem  6.6 The Random-Vortex Method in Two Dimensions  6.7 Appendix for Chapter 6  Notes for Chapter 6  References for Chapter 67 Simplified Asymptotic Equations for Slender Vortex Filaments  7.1 The Self-Induction Approximation, Hasimoto''s Transform, and the Nonlinear Schrodinger Equation  7.2 Simplified Asymptotic Equations with Self-Stretch for a Single Vortex Filament  7.3 Interacting Parallel Vortex Filaments - Point Vortices in the Plane  7.4 Asymptotic Equations for the Interaction of Nearly Parallel Vortex Filaments  7.5 Mathematical and Applied Mathematical Problems Regarding Asymptotic Vortex Filaments  Notes for Chapter 7  References for Chapter 78 Weak Solutions to the 2D Euler Equations with Initial Vorticlty in L  8.1 Elliptical Vorticies  8.2 Weak L Solutions to the Vorticity Equation  8.3 Vortex Patches  8.4 Appendix for Chapter 8  Notes for Chapter 8  References for Chapter 89 Introduction to Vortex Sheets, Weak Solutions, and Approximate-Solution Sequences for the Euler Equation  9.1 Weak Formulation of the Euler Equation in Primitive-Variable Form  9.2 Classical Vortex Sheets and the Birkhoff-Rott Equation  9.3 The Kelvin-Helmholtz Instability  9.4 Computing Vortex Sheets  9.5 The Development of Oscillations and Concentrations  Notes for Chapter 9  References for Chapter 910 Weak Solutions and Solution Sequences in Two Dimensions  10.1 Approximate-Solution Sequences for the Euler and the Navier-Stokes Equations  10.2 Convergence Results for 2D Sequences with L1 and Lp  Vorticity Control  Notes for Chapter 10  References for Chapter 1011 The 2D Euler Equation: Concentrations and Weak Solutions with Vortex-Sheet Initial Data  11.1 Weak-* and Reduced Defect Measures  11.2 Examples with Concentration  11.3 The Vorticity Maximal Function: Decay Rates and Strong Convergence  11.4 Existence of Weak Solutions with Vortex-Sheet Initial Data of Distinguished Sign  Notes for Chapter 11  References for Chapter 1112 Reduced Hansdorff Dimension, Oscillations, and Measure-Valued Solutions of the Euler Equations in Two and Three Dimensions  12.1 The Reduced Hausdorff Dimension  12.2 Oscillations for Approximate-Solution Sequences without L1 Vorticity Control  12.3 Young Measures and Measure-Valued Solutions of the Euler Equations  12.4 Measure-Valued Solutions with Oscillations and Concentrations  Notes for Chapter 12  References for Chapter 1213 The Vlasov-Poisson Equations ns an Analogy to the Euler Equations for the Study of Weak Solutions  13.1 The Analogy between the 2D Euler Equations and the 1D Vlasov-Poisson Equations  13.2 The Single-Component 1D Vlasov-Poisson Equation  13.3 The Two-Component Vlasov-Poisson System  Note for Chapter 13  References for Chapter 13Index

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