Reissner–Nordström metric

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In physics and astronomy, the Reissner–Nordström metric is a static solution to the Einstein-Maxwell field equations, which corresponds to the gravitational field of a charged, non-rotating, spherically symmetric body of mass M.

1 The metric
2 Charged black holes
3 See also
4 Notes
5 References
6 External links

The metric

Discovered by Hans Reissner and Gunnar Nordström, their metric can be written as

$c^2 {d \tau}^{2} = \left( 1 - {\color{OliveGreen}\frac{r_{s}}{r}} %2B {\color{Red}\frac{r_{Q}^{2}}{r^{2}}} \right) c^{2} dt^{2} - \frac{dr^{2}}{1 - {\color{OliveGreen}\frac{r_{s}}{r}} %2B {\color{Red}\frac{r_{Q}^{2}}{r^{2}}}} - r^{2} d\Omega^{2}$

where

τ is the proper time (time measured by a clock moving with the particle) in seconds,

c is the speed of light in meters per second,

t is the time coordinate (measured by a stationary clock at infinity) in seconds,

r is the radial coordinate (circumference of a circle centered on the star divided by 2π) in meters,

Ω is the solid angle,

$\,d \Omega^2 = d \theta^2 %2B \sin^2 \theta d \phi^2$

r_s is the Schwarzschild radius (in meters) of the massive body, which is related to its mass M by

$r_{s} = \frac{2GM}{c^{2}}$

where G is the gravitational constant, and

r_Q is a length-scale corresponding to the electric charge Q of the mass

$r_{Q}^{2} = \frac{Q^{2}G}{4\pi\epsilon_{0} c^{4}}$

where 1/4πε₀ is Coulomb's force constant.^[1]

The colors have been added in order to highlight the extensions to Minkowski spacetime. In the limit that the charge Q (or equivalently, the length-scale r_Q) goes to zero, one recovers the Schwarzschild metric. To do this, you just remove term in $\,\color{Red}\text{red}$ . The classical Newtonian theory of gravity may then be recovered in the limit as the ratio r_s/r goes to zero. To do this, you just remove term in $\,\color{OliveGreen}\text{green}$ . In that limit, the metric returns to the Minkowski metric for special relativity

$c^{2} d\tau^{2} = c^{2} dt^{2} - dr^{2} - r^{2} d\Omega^{2}.\,$

In practice, the ratio r_s/r is almost always extremely small. For example, the Schwarzschild radius r_s of the Earth is roughly 9 mm (³⁄₈ inch), whereas a satellite in a geosynchronous orbit has a radius r that is roughly four billion times larger, at 42,164 km (26,200 miles). Even at the surface of the Earth, the corrections to Newtonian gravity are only one part in a billion. The ratio only becomes large close to black holes and other ultra-dense objects such as neutron stars.

Charged black holes

Although charged black holes with $r_{Q} \ll r_{s}$ are similar to the Schwarzschild black hole, they have two horizons: the event horizon and an internal Cauchy horizon. As usual, the event horizons for the spacetime are located where $g^{rr}$ diverges:

$(g^{rr})^{-1}= 1 - \frac{r_{s}}{r} %2B \frac{r_{Q}^{2}}{r^{2}} = \frac{1}{r^2}(r^2 - r_sr %2B r_Q^2) = 0.$

The second factor r ² − r_s r + r_Q² is a quadratic in r and we find its zeros by using the quadratic formula:

$r_\pm = \frac{1}{2}\left(r_{s} \pm \sqrt{r_{s}^2 - 4r_{Q}^2}\right).$

These concentric event horizons become degenerate for $2r_{Q}=r_{s}$ which corresponds to an extremal black hole. Black holes with $2r_{Q}>r_{s}$ are believed not to exist in nature because they would contain a naked singularity; their appearance would contradict Roger Penrose's cosmic censorship hypothesis which is generally believed to be true. Theories with supersymmetry usually guarantee that such "superextremal" black holes can't exist.

The electromagnetic potential is

$A^{\alpha} = \left(\frac{Q}{r}, 0, 0, 0\right).$

If magnetic monopoles are included into the theory, then a generalization to include magnetic charge $P$ is obtained by replacing $Q^2$ by $Q^2 %2B P^2$ in the metric and including the term $P \cos \theta d \phi$ in the electromagnetic potential.

Notes

^ Landau 1975.

References

Reissner, H (1916). "Über die Eigengravitation des elektrischen Feldes nach der Einsteinschen Theorie". Annalen der Physik 50: 106–120. Bibcode 1916AnP...355..106R. doi:10.1002/andp.19163550905.
Nordström, G (1918). "On the Energy of the Gravitational Field in Einstein's Theory". Verhandl. Koninkl. Ned. Akad. Wetenschap., Afdel. Natuurk., Amsterdam 26: 1201–1208.
Adler, R; Bazin M, and Schiffer M (1965). Introduction to General Relativity. New York: McGraw-Hill Book Company. pp. 395–401. ISBN 978-0-07-000420-7.
Wald, RM (1984). General Relativity. Chicago: The University of Chicago Press. pp. 158, 312–324. ISBN 978-0-226-87032-8.

External links

spacetime diagrams including Finkelstein diagram and Penrose diagram, by Andrew J. S. Hamilton
"Particle Moving Around Two Extreme Black Holes" by Enrique Zeleny, The Wolfram Demonstrations Project.

Black holes

Types	Schwarzschild Rotating Charged Virtual

Size	Micro Extremal (Electron) Stellar Intermediate-mass Supermassive Quasar Active galactic nucleus Blazar

Formation	Stellar evolution Collapse Neutron star (Related links) Compact star Quark Exotic Tolman–Oppenheimer–Volkoff limit White dwarf (Related links) Supernova (Related links) Hypernova Gamma-ray burst

Properties	Thermodynamics Schwarzschild radius M-sigma relation Event horizon Quasi-periodic oscillation Photon sphere Ergosphere Hawking radiation Penrose process Bondi accretion Spaghettification Gravitational lens

Models	Gravitational singularity (Penrose–Hawking singularity theorems) Primordial black hole Gravastar Dark star Dark energy star Black star Magnetospheric eternally collapsing object Fuzzball White hole Naked singularity Ring singularity Immirzi parameter Membrane paradigm Kugelblitz Wormhole Quasistar

Issues	No-hair theorem Information paradox Cosmic censorship Alternative models Holographic principle Black hole complementarity

Metrics	Schwarzschild Kerr Reissner–Nordström Kerr–Newman

Related	List of black holes Timeline of black hole physics Rossi X-ray Timing Explorer Hypercompact stellar system