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2016 | Buch

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Navier–Stokes Equations

An Introduction with Applications

verfasst von: Grzegorz Łukaszewicz, Piotr Kalita

Verlag: Springer International Publishing

Buchreihe : Advances in Mechanics and Mathematics

Enthalten in: Springer Professional "Wirtschaft+Technik" , Springer Professional "Technik" , Springer Professional "Wirtschaft"

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Über dieses Buch

This volume is devoted to the study of the Navier–Stokes equations, providing a comprehensive reference for a range of applications: from advanced undergraduate students to engineers and professional mathematicians involved in research on fluid mechanics, dynamical systems, and mathematical modeling. Equipped with only a basic knowledge of calculus, functional analysis, and partial differential equations, the reader is introduced to the concept and applications of the Navier–Stokes equations through a series of fully self-contained chapters. Including lively illustrations that complement and elucidate the text, and a collection of exercises at the end of each chapter, this book is an indispensable, accessible, classroom-tested tool for teaching and understanding the Navier–Stokes equations.
Incompressible Navier–Stokes equations describe the dynamic motion (flow) of incompressible fluid, the unknowns being the velocity and pressure as functions of location (space) and time variables. A solution to these equations predicts the behavior of the fluid, assuming knowledge of its initial and boundary states. These equations are one of the most important models of mathematical physics: although they have been a subject of vivid research for more than 150 years, there are still many open problems due to the nature of nonlinearity present in the equations. The nonlinear convective term present in the equations leads to phenomena such as eddy flows and turbulence. In particular, the question of solution regularity for three-dimensional problem was appointed by Clay Institute as one of the Millennium Problems, the key problems in modern mathematics. The problem remains challenging and fascinating for mathematicians, and the applications of the Navier–Stokes equations range from aerodynamics (drag and lift forces), to the design of watercraft and hydroelectric power plants, to medical applications such as modeling the flow of blood in the circulatory system.

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Inhaltsverzeichnis

Frontmatter

1. Introduction and Summary

Abstract

This chapter provides, for the convenience of the reader, an overview of the whole book, first of its structure and then of the content of the individual chapters.

Grzegorz Łukaszewicz, Piotr Kalita

2. Equations of Classical Hydrodynamics

Abstract

In this chapter we give an overview of the equations of classical hydrodynamics. We provide their derivation, comment on the stress tensor, and thermodynamics, finally we present some elementary properties and also some exact solutions of the Navier–Stokes equations.

Grzegorz Łukaszewicz, Piotr Kalita

3. Mathematical Preliminaries

Abstract

In this chapter we introduce the basic preliminary mathematical tools to study the Navier–Stokes equations, including results from linear and nonlinear functional analysis as well as the theory of function spaces. We present, in particular, some of the most frequently used in the sequel embedding theorems and differential inequalities.

Grzegorz Łukaszewicz, Piotr Kalita

4. Stationary Solutions of the Navier–Stokes Equations

Abstract

In this chapter we introduce some basic notions from the theory of the Navier–Stokes equations: the function spaces H, V, and V ′, the Stokes operator A with its domain D(A) in H, and the bilinear form B. We apply the Galerkin method and fixed point theorems to prove the existence of solutions of the nonlinear stationary problem, and we consider problems of uniqueness and regularity of solutions.

Grzegorz Łukaszewicz, Piotr Kalita

5. Stationary Solutions of the Navier–Stokes Equations with Friction

Abstract

In this chapter we consider the three-dimensional stationary Navier–Stokes equations with multivalued friction law boundary conditions on a part of the domain boundary. We formulate two existence theorems for the formulated problem. The first one uses the Kakutani–Fan–Glicksberg fixed point theorem, and the second one, with the relaxed assumptions, is based on the cut-off argument.

Grzegorz Łukaszewicz, Piotr Kalita

6. Stationary Flows in Narrow Films and the Reynolds Equation

Abstract

In this chapter we study a typical problem from the theory of lubrication, namely, the Stokes flow in a thin three-dimensional domain \(\varOmega ^{\varepsilon }\), \(\varepsilon> 0\). We assume the Fourier boundary condition (only the friction part) at the top surface and a nonlinear Tresca interface condition at the bottom one.

Grzegorz Łukaszewicz, Piotr Kalita

7. Autonomous Two-Dimensional Navier–Stokes Equations

Abstract

This chapter contains some basic facts about solutions of nonstationary Navier–Stokes equations

Grzegorz Łukaszewicz, Piotr Kalita

8. Invariant Measures and Statistical Solutions

Abstract

In this chapter we prove the existence of invariant measures associated with two-dimensional autonomous Navier–Stokes equations. Then we introduce the notion of a stationary statistical solution and prove that every invariant measure is also such a solution.

Grzegorz Łukaszewicz, Piotr Kalita

9. Global Attractors and a Lubrication Problem

Abstract

We start this chapter from necessary background on the theory of fractal dimension. Next, we formulate and study a problem which models the two-dimensional boundary driven shear flow in lubrication theory. After the derivation of the energy dissipation rate estimate and a version of Lieb–Thirring inequality we provide an estimate from above on the global attractor fractal dimension.

Grzegorz Łukaszewicz, Piotr Kalita

10. Exponential Attractors in Contact Problems

Abstract

In this chapter we consider two examples of contact problems. First, we study the problem of time asymptotics for a class of two-dimensional turbulent boundary driven flows subject to the Tresca friction law which naturally appears in lubrication theory. Then we analyze the problem with the generalized Tresca law, where the friction coefficient can depend on the tangential slip rate.

Grzegorz Łukaszewicz, Piotr Kalita

11. Non-autonomous Navier–Stokes Equations and Pullback Attractors

Abstract

In this chapter we study the time asymptotics of solutions to the two-dimensional Navier–Stokes equations. In the first two sections we prove two properties of the equations in a bounded domain, concerning the existence of determining modes and nodes. Then we study the equations in an unbounded domain, in the framework of the theory of infinite dimensional non-autonomous dynamical systems and pullback attractors.

Grzegorz Łukaszewicz, Piotr Kalita

12. Pullback Attractors and Statistical Solutions

Abstract

This chapter is devoted to constructions of invariant measures and statistical solutions for non-autonomous Navier–Stokes equations in bounded and certain unbounded domains in \(\mathbb{R}^{2}\).After introducing some basic notions and results concerning attractors in the context of the Navier–Stokes equations, we construct the family of probability measures \(\{\mu _{t}\}_{t\in \mathbb{R}}\) and prove the relations \(\mu _{t}(E) =\mu _{\tau }(U(t,\tau )^{-1}E)\) for \(t,\tau \in \mathbb{R}\), t ≥ τ and Borel sets E in H. Then we prove the Liouville and energy equations. Finally, we consider statistical solutions of the Navier–Stokes equations supported on the pullback attractor.

Grzegorz Łukaszewicz, Piotr Kalita

13. Pullback Attractors and Shear Flows

Abstract

In this chapter we consider the problem of existence and finite dimensionality of the pullback attractor for a class of two-dimensional turbulent boundary driven flows which naturally appear in lubrication theory. We generalize here the results from Chap. 9 to the non-autonomous problem.

Grzegorz Łukaszewicz, Piotr Kalita

14. Trajectory Attractors and Feedback Boundary Control in Contact Problems

Abstract

In this chapter we consider two-dimensional nonstationary incompressible Navier–Stokes shear flows with nonmonotone and multivalued leak boundary conditions on a part of the boundary of the flow domain. Our considerations are motivated by feedback control problems for fluid flows in domains with semipermeable walls and membranes and by the theory of lubrication. Our aim is to prove the existence of global in time solutions of the considered problem which is governed by a partial differential inclusion, and then to prove the existence of a trajectory attractor and a weak global attractor for the associated multivalued semiflow.

Grzegorz Łukaszewicz, Piotr Kalita

15. Evolutionary Systems and the Navier–Stokes Equations

Abstract

This chapter is devoted to the study of three-dimensional nonstationary Navier–Stokes equations with the multivalued frictional boundary condition. We use the formalism of evolutionary systems to prove the existence of weak global attractor for the studied problem.

Grzegorz Łukaszewicz, Piotr Kalita

16. Attractors for Multivalued Processes in Contact Problems

Abstract

In this chapter we consider further non-autonomous and multivalued evolution problems, this time in the frame of the theory of pullback attractors for multivalued processes.

Grzegorz Łukaszewicz, Piotr Kalita

Backmatter

Titel: Navier–Stokes Equations
verfasst von: Grzegorz Łukaszewicz
Piotr Kalita
Copyright-Jahr: 2016
Verlag: Springer International Publishing
Electronic ISBN: 978-3-319-27760-8
Print ISBN: 978-3-319-27758-5
DOI: https://doi.org/10.1007/978-3-319-27760-8

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