Turing jump: Difference between revisions

Revision as of 05:32, 31 January 2014

In general relativity, a spacetime is said to be static if it admits a global, non-vanishing, timelike Killing vector field $K$ which is irrotational, i.e., whose orthogonal distribution is involutive. (Note that the leaves of the associated foliation are necessarily space-like hypersurfaces.) Thus, a static spacetime is a stationary spacetime satisfying this additional integrability condition. These spacetimes form one of the simplest classes of Lorentzian manifolds.

Locally, every static spacetime looks like a standard static spacetime which is a Lorentzian warped product R $\times$ S with a metric of the form $g[(t,x)]=-\beta (x)dt^{2}+g_{S}[x]$ , where R is the real line, $g_{S}$ is a (positive definite) metric and $\beta$ is a positive function on the Riemannian manifold S.

In such a local coordinate representation the Killing field $K$ may be identified with $\partial _{t}$ and S, the manifold of $K$ -trajectories, may be regarded as the instantaneous 3-space of stationary observers. If $\lambda$ is the square of the norm of the Killing vector field, $\lambda =g(K,K)$ , both $\lambda$ and $g_{S}$ are independent of time (in fact $\lambda =-\beta (x)$ ). It is from the latter fact that a static spacetime obtains its name, as the geometry of the space-like slice S does not change over time.

Examples of static spacetimes

The (exterior) Schwarzschild solution
de Sitter space (the portion of it covered by the static patch).
Reissner-Nordström space
The Weyl solution, a static axisymmetric solution of the Einstein vacuum field equations $R_{\mu \nu }=0$ discovered by Hermann Weyl

External links

Concepts of General Relativity - A first principles demonstration of the metric in static spacetime

M. Sanchez, On the geometry of static space-times, preprint, 2004.

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+{{Expert-subject|Physics|date=November 2008}}
+In [[general relativity]], a [[spacetime]] is said to be '''static''' if it admits a global, non-vanishing, [[timelike]] [[Killing vector field]] <math>K</math> which is '''irrotational''', ''i.e.'', whose [[orthogonal distribution]] is [[involutive]]. (Note that the leaves of the associated [[foliation]] are necessarily space-like [[hypersurface]]s.) Thus, a static spacetime is a [[stationary spacetime]] satisfying this additional integrability condition. These spacetimes form one of the simplest classes of [[Lorentzian manifold]]s.
+Locally, every static spacetime looks like a '''standard static spacetime''' which is a Lorentzian warped product ''R'' <math>\times</math> ''S'' with a metric of the form
+<math>g[(t,x)] = -\beta(x) dt^{2} + g_{S}[x]</math>,
+where ''R'' is the real line, <math>g_{S}</math> is a (positive definite) metric and <math>\beta</math> is a positive function on the [[Riemannian manifold]] ''S''.
+In such a local coordinate representation the [[Killing vector field|Killing field]] <math>K</math> may be identified with <math>\partial_t</math> and ''S'', the manifold of <math>K</math>-''trajectories'', may be regarded as the instantaneous 3-space of stationary observers. If <math>\lambda</math> is the square of the norm of the Killing vector field, <math>\lambda = g(K,K)</math>, both <math>\lambda</math> and <math>g_S</math> are independent of time (in fact <math>\lambda = - \beta(x)</math>). It is from the latter fact that a static spacetime obtains its name, as the geometry of the space-like slice ''S'' does not change over time.
+==Examples of static spacetimes==
+#The (exterior) [[Schwarzschild solution]]
+#[[de Sitter space]] (the portion of it covered by the [[De Sitter space#Static coordinates|static patch]]).
+#[[Reissner-Nordström]] space
+#The [[Weyl solution]], a static axisymmetric solution of the Einstein vacuum field equations <math>R_{\mu\nu} = 0</math> discovered by [[Hermann Weyl]]
+==External links==
+* [http://www.rqgravity.net/GeneralRelativity#StationaryObservers Concepts of General Relativity ] - A first principles demonstration of the metric in static spacetime
+* [http://arxiv.org/abs/math/0406332v2 M. Sanchez, On the geometry of static space-times, preprint, 2004.]
+{{relativity-stub}}
+[[Category:Lorentzian manifolds]]

Turing jump: Difference between revisions

Revision as of 05:32, 31 January 2014

Examples of static spacetimes

External links

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