From Kinetic Models to Hydrodynamics
Colangeli, Matteo.
From Kinetic Models to Hydrodynamics Some Novel Results / [electronic resource] : by Matteo Colangeli. - X, 96 p. 21 illus., 9 illus. in color. online resource. - SpringerBriefs in Mathematics, 2191-8198 . - SpringerBriefs in Mathematics, .
1. Introduction -- 2. From the Phase Space to the Boltzmann Equation -- 3. Methods of Reduced Description -- 4. Hydrodynamic Spectrum of Simple Fluids -- 5. Hydrodynamic Fluctuations from the Boltzmann Equation -- 6. 13 Moment Grad System -- 7. Conclusions -- References. .
From Kinetic Models to Hydrodynamics serves as an introduction to the asymptotic methods necessary to obtain hydrodynamic equations from a fundamental description using kinetic theory models and the Boltzmann equation. The work is a survey of an active research area, which aims to bridge time and length scales from the particle-like description inherent in Boltzmann equation theory to a fully established “continuum” approach typical of macroscopic laws of physics.The author sheds light on a new method—using invariant manifolds—which addresses a functional equation for the nonequilibrium single-particle distribution function. This method allows one to find exact and thermodynamically consistent expressions for: hydrodynamic modes; transport coefficient expressions for hydrodynamic modes; and transport coefficients of a fluid beyond the traditional hydrodynamic limit. The invariant manifold method paves the way to establish a needed bridge between Boltzmann equation theory and a particle-based theory of hydrodynamics. Finally, the author explores the ambitious and longstanding task of obtaining hydrodynamic constitutive equations from their kinetic counterparts. The work is intended for specialists in kinetic theory—or more generally statistical mechanics—and will provide a bridge between a physical and mathematical approach to solve real-world problems.
9781461463061
10.1007/978-1-4614-6306-1 doi
Mathematics.
Mathematical physics.
Mathematical models.
Physics.
Statistical physics.
Dynamical systems.
Mathematics.
Mathematical Physics.
Mathematical Methods in Physics.
Mathematical Applications in the Physical Sciences.
Theoretical, Mathematical and Computational Physics.
Mathematical Modeling and Industrial Mathematics.
Statistical Physics, Dynamical Systems and Complexity.
QA401-425 QC19.2-20.85
530.15
From Kinetic Models to Hydrodynamics Some Novel Results / [electronic resource] : by Matteo Colangeli. - X, 96 p. 21 illus., 9 illus. in color. online resource. - SpringerBriefs in Mathematics, 2191-8198 . - SpringerBriefs in Mathematics, .
1. Introduction -- 2. From the Phase Space to the Boltzmann Equation -- 3. Methods of Reduced Description -- 4. Hydrodynamic Spectrum of Simple Fluids -- 5. Hydrodynamic Fluctuations from the Boltzmann Equation -- 6. 13 Moment Grad System -- 7. Conclusions -- References. .
From Kinetic Models to Hydrodynamics serves as an introduction to the asymptotic methods necessary to obtain hydrodynamic equations from a fundamental description using kinetic theory models and the Boltzmann equation. The work is a survey of an active research area, which aims to bridge time and length scales from the particle-like description inherent in Boltzmann equation theory to a fully established “continuum” approach typical of macroscopic laws of physics.The author sheds light on a new method—using invariant manifolds—which addresses a functional equation for the nonequilibrium single-particle distribution function. This method allows one to find exact and thermodynamically consistent expressions for: hydrodynamic modes; transport coefficient expressions for hydrodynamic modes; and transport coefficients of a fluid beyond the traditional hydrodynamic limit. The invariant manifold method paves the way to establish a needed bridge between Boltzmann equation theory and a particle-based theory of hydrodynamics. Finally, the author explores the ambitious and longstanding task of obtaining hydrodynamic constitutive equations from their kinetic counterparts. The work is intended for specialists in kinetic theory—or more generally statistical mechanics—and will provide a bridge between a physical and mathematical approach to solve real-world problems.
9781461463061
10.1007/978-1-4614-6306-1 doi
Mathematics.
Mathematical physics.
Mathematical models.
Physics.
Statistical physics.
Dynamical systems.
Mathematics.
Mathematical Physics.
Mathematical Methods in Physics.
Mathematical Applications in the Physical Sciences.
Theoretical, Mathematical and Computational Physics.
Mathematical Modeling and Industrial Mathematics.
Statistical Physics, Dynamical Systems and Complexity.
QA401-425 QC19.2-20.85
530.15