Gregory V. Vereshchagin, Alexey G. Aksenov (Moscow Russian Academy of Sciences)
Relativistic Kinetic Theory
Gregory V. Vereshchagin, Alexey G. Aksenov (Moscow Russian Academy of Sciences)
Relativistic Kinetic Theory
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This book presents fundamentals, equations, and methods of solutions of relativistic kinetic theory, with applications in astrophysics and cosmology.
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This book presents fundamentals, equations, and methods of solutions of relativistic kinetic theory, with applications in astrophysics and cosmology.
Produktdetails
- Produktdetails
- Verlag: Cambridge University Press
- Seitenzahl: 344
- Erscheinungstermin: 31. Januar 2017
- Englisch
- Abmessung: 260mm x 183mm x 23mm
- Gewicht: 824g
- ISBN-13: 9781107048225
- ISBN-10: 1107048222
- Artikelnr.: 46984572
- Verlag: Cambridge University Press
- Seitenzahl: 344
- Erscheinungstermin: 31. Januar 2017
- Englisch
- Abmessung: 260mm x 183mm x 23mm
- Gewicht: 824g
- ISBN-13: 9781107048225
- ISBN-10: 1107048222
- Artikelnr.: 46984572
Gregory V. Vereshchagin is Professor at the International Center for Relativistic Astrophysics Network (ICRANet), Pescara, Italy. He graduated from Belarusian State University and received a PhD in Theoretical Physics from the National Academy of Sciences, Belarus. He also holds a PhD degree in Relativistic Astrophysics from Sapienza University, Rome, and was awarded the NATO-CNR fellowship. Author of more than 30 refereed papers, his research interests include cosmological singularity and inflation, loop quantum cosmology, the role of neutrino in cosmology, thermalization of relativistic plasma, and photospheric emission from relativistic outflows.
Preface
Acknowledgements
Acronyms and definitions
Introduction
Part I. Theoretical Foundations: 1. Basic concepts
2. Kinetic equation
3. Averaging
4. Conservation laws and equilibrium
5. Relativistic BBGKY hierarchy
6. Basic parameters in gases and plasmas
Part II. Numerical Methods: 7. The basics of computational physics
8. Direct integration of Boltzmann equations
9. Multidimensional hydrodynamics
Part III. Applications: 10. Wave dispersion in relativistic plasma
11. Thermalization in relativistic plasma
12. Kinetics of particles in strong fields
13. Compton scattering in astrophysics and cosmology
14. Self-gravitating systems
15. Neutrinos, gravitational collapse and supernovae
Appendices
Bibliography
Index.
Acknowledgements
Acronyms and definitions
Introduction
Part I. Theoretical Foundations: 1. Basic concepts
2. Kinetic equation
3. Averaging
4. Conservation laws and equilibrium
5. Relativistic BBGKY hierarchy
6. Basic parameters in gases and plasmas
Part II. Numerical Methods: 7. The basics of computational physics
8. Direct integration of Boltzmann equations
9. Multidimensional hydrodynamics
Part III. Applications: 10. Wave dispersion in relativistic plasma
11. Thermalization in relativistic plasma
12. Kinetics of particles in strong fields
13. Compton scattering in astrophysics and cosmology
14. Self-gravitating systems
15. Neutrinos, gravitational collapse and supernovae
Appendices
Bibliography
Index.
Preface
Acknowledgements
Acronyms and definitions
Introduction
Part I. Theoretical Foundations: 1. Basic concepts
2. Kinetic equation
3. Averaging
4. Conservation laws and equilibrium
5. Relativistic BBGKY hierarchy
6. Basic parameters in gases and plasmas
Part II. Numerical Methods: 7. The basics of computational physics
8. Direct integration of Boltzmann equations
9. Multidimensional hydrodynamics
Part III. Applications: 10. Wave dispersion in relativistic plasma
11. Thermalization in relativistic plasma
12. Kinetics of particles in strong fields
13. Compton scattering in astrophysics and cosmology
14. Self-gravitating systems
15. Neutrinos, gravitational collapse and supernovae
Appendices
Bibliography
Index.
Acknowledgements
Acronyms and definitions
Introduction
Part I. Theoretical Foundations: 1. Basic concepts
2. Kinetic equation
3. Averaging
4. Conservation laws and equilibrium
5. Relativistic BBGKY hierarchy
6. Basic parameters in gases and plasmas
Part II. Numerical Methods: 7. The basics of computational physics
8. Direct integration of Boltzmann equations
9. Multidimensional hydrodynamics
Part III. Applications: 10. Wave dispersion in relativistic plasma
11. Thermalization in relativistic plasma
12. Kinetics of particles in strong fields
13. Compton scattering in astrophysics and cosmology
14. Self-gravitating systems
15. Neutrinos, gravitational collapse and supernovae
Appendices
Bibliography
Index.