Book contents
- Frontmatter
- Contents
- Preface
- 1 Preliminaries
- 2 Spacetimes admitting Killing fields
- 3 Circular spacetimes
- 4 The Kerr metric
- 5 Electrovac spacetimes with Killing fields
- 6 Stationary black holes
- 7 The four laws of black hole physics
- 8 Integrability and divergence identities
- 9 Uniqueness theorems for nonrotating holes
- 10 Uniqueness theorems for rotating holes
- 11 Scalar mappings
- 12 Self–gravitating harmonic mappings
- References
- Index
2 - Spacetimes admitting Killing fields
Published online by Cambridge University Press: 13 March 2010
- Frontmatter
- Contents
- Preface
- 1 Preliminaries
- 2 Spacetimes admitting Killing fields
- 3 Circular spacetimes
- 4 The Kerr metric
- 5 Electrovac spacetimes with Killing fields
- 6 Stationary black holes
- 7 The four laws of black hole physics
- 8 Integrability and divergence identities
- 9 Uniqueness theorems for nonrotating holes
- 10 Uniqueness theorems for rotating holes
- 11 Scalar mappings
- 12 Self–gravitating harmonic mappings
- References
- Index
Summary
Einstein's field equations form a set of nonlinear, coupled partial differential equations. In spite of this, it is still sometimes possible to find exact solutions in a systematic way by considering space-times with symmetries. Since the laws of general relativity are covariant with respect to diffeomorphisms, the corresponding reduction of the field equations must be performed in a coordinate–independent way. This is achieved by using the concept of Killing vector fields. The existence of Killing fields reflects the symmetries of a spacetime in a coordinate–invariant manner.
A spacetime (M, g) admitting a Killing field gives rise to an invariantly defined 3–manifold Σ. However, Σ is only a hypersurface of (M, g) if it is orthogonal to the Killing trajectories. In general, Σ must be considered to be a quotient space M/G rather than a subspace of M. (Here G is the 1–dimensional group generated by the Killing field.) The projection formalism for M/G was developed by Geroch (1971, 1972a), based on earlier work by Ehlers (see also Kramer et al. 1980). The invariant quantities which play a leading role are the twist and the norm of the Killing field.
In the first section of this chapter we compile some basic properties of Killing fields. The twist, the norm and the Ricci 1–form assigned to a Killing field are introduced in the second section. Using these quantities, we then give the complete set of reduction formulae for the Ricci tensor.
In the third section we apply these formulae to vacuum space-times. In particular, we introduce the vacuum Ernst potential and derive the entire set of field equations from a variational principle.
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- Black Hole Uniqueness Theorems , pp. 6 - 30Publisher: Cambridge University PressPrint publication year: 1996