| Description | | - Authored by a leading researcher in the field
- Brings together ideas from PDE theory, General Relativity and Astrophysics
- Valuable resource for advanced undergraduates, graduates and researchers in fields such as numerical relativity and cosmology which are currently very active
| | A graduate level text on a subject which brings together several areas of mathematics and physics: partial differential equations, differential geometry and general relativity. It explains the basics of the theory of partial differential equations in a form accessible to physicists and the basics of general relativity in a form accessible to mathematicians. In recent years the theory of partial
differential equations has come to play an ever more important role in research on general relativity. This is partly due to the growth of the field of numerical relativity, stimulated in turn by work on gravitational wave detection, but also due to an increased interest in general relativity among pure mathematicians working in the areas of partial differential equations and Riemannian geometry,
who have realized the exceptional richness of the interactions between geometry and analysis which arise. This book provides the background for those wishing to learn about these topics. It treats key themes in general relativity including matter models and symmetry classes and gives an introduction to relevant aspects of the most important classes of partial differential equations, including
ordinary differential equations, and material on functional analysis. These elements are brought together to discuss a variety of important examples in the field of mathematical relativity, including asymptotically flat spacetimes, which are used to describe isolated systems, and spatially compact spacetimes, which are of importance in cosmology. |
Readership: Graduates and researchers in Applied Mathematics, Physics, Cosmology and Numerical Relativity
| Contents |
1.
Introduction
2.
General relativity
3.
Matter models
4.
Symmetry classes
5.
Ordinary differential equations
6.
Functional Analysis
7.
Elliptic Equations
8.
Hyperbolic Equations
9.
The Cauchy problem for the Einstein equations
10.
Global results
11.
The Einstein-Vlasov Equation
12.
The Einstein-scalar field system
|
| Authors, editors,
and contributors |
Alan Rendall, Max Planck Institute for Gravitational Physic, (Albert Einstein Institute)
|
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limitation price, format, extent, number of illustrations,
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