Reissner–Nordström metric

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. The analogous solution for a charged, rotating body is given by the Kerr–Newman metric. The metric was discovered between 1916 and 1921 by Hans Reissner,^[1] Hermann Weyl,^[2] Gunnar Nordström^[3] and George Barker Jeffery^[4] independently.^[5]

The metric

In spherical coordinates ${\displaystyle (t,r,\theta ,\phi )}$, the Reissner–Nordström metric (i.e. the line element) is ${\displaystyle d{s}^2=c^{2}d{\tau }^2=(1-\frac{r_{\text{s}}}{r}+\frac{r_{\mathrm{Q}}^2}{r^2})c^{2}d{t}^2-{(1-\frac{r_{\text{s}}}{r}+\frac{r_Q^2}{r^2})}^{-1}d{r}^2-r^{2}d{\theta }^2-r^2{\sin }^2\theta d{\phi }^2,}$

• Where ${\displaystyle c}$ is the speed of light.
• ${\displaystyle \tau }$ is the proper time.
• ${\displaystyle t}$ is the time coordinate (measured by a stationary clock at infinity).
• ${\displaystyle r}$ is the radial coordinate.
• ${\displaystyle (\theta ,\phi )}$ are the spherical angles.
• ${\displaystyle r_{\text{s}}}$ is the Schwarzschild radius of the body given by

${\displaystyle r_{\text{s}}=\frac{2GM}{c^2},}$.

• ${\displaystyle r_Q}$ is a characteristic length scale given by

${\displaystyle r_Q^2=\frac{Q^{2}G}{4\pi {\epsilon }_0{c}^4}.}$

• ${\displaystyle {\epsilon }_0}$ is the electric constant.

The total mass of the central body and its irreducible mass are related by^[6][7] $$\begin{gathered} {\displaystyle M_{\mathrm{i}\mathrm{r}\mathrm{r}}=\frac{c^2}{G}\sqrt{\frac{r_{+}^2}{2}} \\ \to \\ M=\frac{Q^2}{16\pi {\epsilon }_{0}G{M}_{\mathrm{i}\mathrm{r}\mathrm{r}}}+M_{\mathrm{i}\mathrm{r}\mathrm{r}}.} \end{gathered}$$ The difference between ${\displaystyle M}$ and ${\displaystyle M_{\mathrm{i}\mathrm{r}\mathrm{r}}}$ is due to the equivalence of mass and energy, which makes the electric field energy also contribute to the total mass. In the limit that the charge ${\displaystyle Q}$ (or equivalently, the length scale ${\displaystyle r_Q}$) goes to zero, one recovers the Schwarzschild metric. The classical Newtonian theory of gravity may then be recovered in the limit as the ratio ${\displaystyle r_{\text{s}}/r}$ goes to zero. In the limit that both ${\displaystyle r_Q/r}$ and ${\displaystyle r_{\text{s}}/r}$ go to zero, the metric becomes the Minkowski metric for special relativity. In practice, the ratio ${\displaystyle r_{\text{s}}/r}$ is often extremely small. For example, the Schwarzschild radius of the Earth is roughly 9 mm (3/8 inch), whereas a satellite in a geosynchronous orbit has an orbital radius ${\displaystyle r}$ 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 ≪ r_s are similar to the Schwarzschild black hole, they have two horizons: the event horizon and an internal Cauchy horizon.^[8] As with the Schwarzschild metric, the event horizons for the spacetime are located where the metric component ${\displaystyle g_{rr}}$ diverges; that is, where $${\displaystyle 1-\frac{r_{\mathrm{s}}}{r}+\frac{r_{\mathrm{Q}}^2}{r^2}=-\frac{1}{g_{rr}}=0.}$$ This equation has two solutions: $${\displaystyle r_{\pm }=\frac{1}{2}(r_{\mathrm{s}}\pm \sqrt{r_{\mathrm{s}}^2-4r_{\mathrm{Q}}^2}).}$$ 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 cannot exist in nature because if the charge is greater than the mass there can be no physical event horizon (the term under the square root becomes negative).^[9] Objects with a charge greater than their mass can exist in nature, but they can not collapse down to a black hole, and if they could, they would display a naked singularity.^[10] Theories with supersymmetry usually guarantee that such "superextremal" black holes cannot exist. The electromagnetic potential is $${\displaystyle A_{\alpha }=(Q/r,0,0,0).}$$ If magnetic monopoles are included in the theory, then a generalization to include magnetic charge P is obtained by replacing Q² by Q² + P² in the metric and including the term P cos θ dφ in the electromagnetic potential.^{[clarification needed]}

Gravitational time dilation

The gravitational time dilation in the vicinity of the central body is given by $${\displaystyle \gamma =\sqrt{|g^{tt}|}=\sqrt{\frac{r^2}{Q^2+(r-2M)r}},}$$ which relates to the local radial escape velocity of a neutral particle $${\displaystyle v_{\mathrm{e}\mathrm{s}\mathrm{c}}=\frac{\sqrt{{\gamma }^2-1}}{\gamma }.}$$

Christoffel symbols

The Christoffel symbols $$\begin{gathered} {\displaystyle {\mathrm{\Gamma }}_{jk}^i={\displaystyle \sum _{s=0}^3} \\ \frac{g^{is}}{2}(\frac{\partial g_{js}}{\partial x^k}+\frac{\partial g_{sk}}{\partial x^j}-\frac{\partial g_{jk}}{\partial x^s})} \end{gathered}$$ with the indices $$\begin{gathered} {\displaystyle \{0, \\ 1, \\ 2, \\ 3\}\to \{t, \\ r, \\ \theta , \\ \phi \}} \end{gathered}$$ give the nonvanishing expressions $${\displaystyle \begin{array}{rl}{\mathrm{\Gamma }}_{tr}^t& =\frac{Mr-Q^2}{r(Q^2+r^2-2Mr)}\\ {\mathrm{\Gamma }}_{tt}^r& =\frac{(Mr-Q^2)(r^2-2Mr+Q^2)}{r^5}\\ {\mathrm{\Gamma }}_{rr}^r& =\frac{Q^2-Mr}{r(Q^2-2Mr+r^2)}\\ {\mathrm{\Gamma }}_{\theta \theta }^r& =-\frac{r^2-2Mr+Q^2}{r}\\ {\mathrm{\Gamma }}_{\phi \phi }^r& =-\frac{{\sin }^2\theta (r^2-2Mr+Q^2)}{r}\\ {\mathrm{\Gamma }}_{\theta r}^{\theta }& =\frac{1}{r}\\ {\mathrm{\Gamma }}_{\phi \phi }^{\theta }& =-\sin \theta \cos \theta \\ {\mathrm{\Gamma }}_{\phi r}^{\phi }& =\frac{1}{r}\\ {\mathrm{\Gamma }}_{\phi \theta }^{\phi }& =\cot \theta \end{array}}$$ Given the Christoffel symbols, one can compute the geodesics of a test-particle.^[11][12]

Tetrad form

Instead of working in the holonomic basis, one can perform efficient calculations with a tetrad.^[13] Let ${\displaystyle {\mathbf{e}}_I=e_{\mu I}}$ be a set of one-forms with internal Minkowski index ${\displaystyle I\in \{0,1,2,3\}}$, such that ${\displaystyle {\eta }^{IJ}{e}_{\mu I}{e}_{\nu J}=g_{\mu \nu }}$. The Reissner metric can be described by the tetrad

${\displaystyle {\mathbf{e}}_0=G^{1/2}dt}$,

${\displaystyle {\mathbf{e}}_1=G^{-1/2}dr}$,

${\displaystyle {\mathbf{e}}_2=rd\theta }$

${\displaystyle {\mathbf{e}}_3=r\sin \theta d\phi }$

where ${\displaystyle G(r)=1-r_s{r}^{-1}+r_Q^2{r}^{-2}}$. The parallel transport of the tetrad is captured by the connection one-forms ${\displaystyle {\mathit{\omega }}_{IJ}=-{\mathit{\omega }}_{JI}={\omega }_{\mu IJ}=e_I^{\nu }{\mathrm{\nabla }}_{\mu }{e}_{J\nu }}$. These have only 24 independent components compared to the 40 components of ${\displaystyle {\mathrm{\Gamma }}_{\mu \nu }^{\lambda }}$. The connections can be solved for by inspection from Cartan's equation ${\displaystyle d{\mathbf{e}}_I={\mathbf{e}}^J\wedge {\mathit{\omega }}_{IJ}}$, where the left hand side is the exterior derivative of the tetrad, and the right hand side is a wedge product.

${\displaystyle {\mathit{\omega }}_{10}=\frac{1}{2}{\partial }_{r}Gdt}$

${\displaystyle {\mathit{\omega }}_{20}={\mathit{\omega }}_{30}=0}$

${\displaystyle {\mathit{\omega }}_{21}=-G^{1/2}d\theta }$

${\displaystyle {\mathit{\omega }}_{31}=-\sin \theta G^{1/2}d\phi }$

${\displaystyle {\mathit{\omega }}_{32}=-\cos \theta d\phi }$

The Riemann tensor ${\displaystyle {\mathbf{R}}_{IJ}=R_{\mu \nu IJ}}$ can be constructed as a collection of two-forms by the second Cartan equation ${\displaystyle {\mathbf{R}}_{IJ}=d{\mathit{\omega }}_{IJ}+{\mathit{\omega }}_{IK}\wedge {\mathit{\omega }}^K{}_J,}$ which again makes use of the exterior derivative and wedge product. This approach is significantly faster than the traditional computation with ${\displaystyle {\mathrm{\Gamma }}_{\mu \nu }^{\lambda }}$; note that there are only four nonzero ${\displaystyle {\mathit{\omega }}_{IJ}}$ compared with nine nonzero components of ${\displaystyle {\mathrm{\Gamma }}_{\mu \nu }^{\lambda }}$.

Equations of motion

^[14] Because of the spherical symmetry of the metric, the coordinate system can always be aligned in a way that the motion of a test-particle is confined to a plane, so for brevity and without restriction of generality we use θ instead of φ. In dimensionless natural units of G = M = c = K = 1 the motion of an electrically charged particle with the charge q is given by $$\begin{gathered} {\displaystyle {\ddot{x}}^i=-{\displaystyle \sum _{j=0}^3} \\ {\displaystyle \sum _{k=0}^3} \\ {\mathrm{\Gamma }}_{jk}^i \\ {\dot{x}}^j \\ {\dot{x}}^k+q \\ {F}^{ik} \\ {\dot{x}}_k} \end{gathered}$$ which yields $$\begin{gathered} {\displaystyle \ddot{t}=\frac{ \\ 2(Q^2-Mr)}{r(r^2-2Mr+Q^2)}\dot{r}\dot{t}+\frac{qQ}{(r^2-2mr+Q^2)} \\ \dot{r}} \end{gathered}$$ $$\begin{gathered} {\displaystyle \ddot{r}=\frac{(r^2-2Mr+Q^2)(Q^2-Mr) \\ {\dot{t}}^2}{r^5}+\frac{(Mr-Q^2){\dot{r}}^2}{r(r^2-2Mr+Q^2)}+\frac{(r^2-2Mr+Q^2) \\ {\dot{\theta }}^2}{r}+\frac{qQ(r^2-2mr+Q^2)}{r^4} \\ \dot{t}} \end{gathered}$$ $$\begin{gathered} {\displaystyle \ddot{\theta }=-\frac{2 \\ \dot{\theta } \\ \dot{r}}{r}.} \end{gathered}$$ All total derivatives are with respect to proper time ${\displaystyle \dot{a}=\frac{da}{d\tau }}$. Constants of the motion are provided by solutions ${\displaystyle S(t,\dot{t},r,\dot{r},\theta ,\dot{\theta },\phi ,\dot{\phi })}$ to the partial differential equation^[15] $${\displaystyle 0=\dot{t}{\displaystyle \frac{\partial S}{\partial t}}+\dot{r}\frac{\partial S}{\partial r}+\dot{\theta }\frac{\partial S}{\partial \theta }+\ddot{t}\frac{\partial S}{\partial \dot{t}}+\ddot{r}\frac{\partial S}{\partial \dot{r}}+\ddot{\theta }\frac{\partial S}{\partial \dot{\theta }}}$$ after substitution of the second derivatives given above. The metric itself is a solution when written as a differential equation $${\displaystyle S_1=1=(1-\frac{r_s}{r}+\frac{r_{\mathrm{Q}}^2}{r^2})c^2{\dot{t}}^2-{(1-\frac{r_s}{r}+\frac{r_Q^2}{r^2})}^{-1}{\dot{r}}^2-r^2{\dot{\theta }}^2.}$$ The separable equation $${\displaystyle \frac{\partial S}{\partial r}-\frac{2}{r}\dot{\theta }\frac{\partial S}{\partial \dot{\theta }}=0}$$ immediately yields the constant relativistic specific angular momentum $${\displaystyle S_2=L=r^2\dot{\theta };}$$ a third constant obtained from $${\displaystyle \frac{\partial S}{\partial r}-\frac{2(Mr-Q^2)}{r(r^2-2Mr+Q^2)}\dot{t}\frac{\partial S}{\partial \dot{t}}=0}$$ is the specific energy (energy per unit rest mass)^[16] $${\displaystyle S_3=E=\frac{\dot{t}(r^2-2Mr+Q^2)}{r^2}+\frac{qQ}{r}.}$$ Substituting ${\displaystyle S_2}$ and ${\displaystyle S_3}$ into ${\displaystyle S_1}$ yields the radial equation $${\displaystyle c\int d\tau =\int \frac{r^{2}dr}{\sqrt{r^4(E-1)+2M{r}^3-(Q^2+L^2)r^2+2M{L}^{2}r-Q^2{L}^2}}.}$$ Multiplying under the integral sign by ${\displaystyle S_2}$ yields the orbital equation $${\displaystyle c\int L{r}^{2}d\theta =\int \frac{Ldr}{\sqrt{r^4(E-1)+2M{r}^3-(Q^2+L^2)r^2+2M{L}^{2}r-Q^2{L}^2}}.}$$ The total time dilation between the test-particle and an observer at infinity is $$\begin{gathered} {\displaystyle \gamma =\frac{q \\ Q \\ {r}^3+E \\ {r}^4}{r^2 \\ (r^2-2r+Q^2)}.} \end{gathered}$$ The first derivatives ${\displaystyle {\dot{x}}^i}$ and the contravariant components of the local 3-velocity ${\displaystyle v^i}$ are related by $$\begin{gathered} {\displaystyle {\dot{x}}^i=\frac{v^i}{\sqrt{(1-v^2) \\ |g_{ii}|}},} \end{gathered}$$ which gives the initial conditions $${\displaystyle \dot{r}=\frac{v_{\parallel }\sqrt{r^2-2M+Q^2}}{r\sqrt{(1-v^2)}}}$$ $${\displaystyle \dot{\theta }=\frac{v_{\perp }}{r\sqrt{(1-v^2)}}.}$$ The specific orbital energy $${\displaystyle E=\frac{\sqrt{Q^2-2rM+r^2}}{r\sqrt{1-v^2}}+\frac{qQ}{r}}$$ and the specific relative angular momentum $$\begin{gathered} {\displaystyle L=\frac{v_{\perp } \\ r}{\sqrt{1-v^2}}} \end{gathered}$$ of the test-particle are conserved quantities of motion. ${\displaystyle v_{\parallel }}$ and ${\displaystyle v_{\perp }}$ are the radial and transverse components of the local velocity-vector. The local velocity is therefore $${\displaystyle v=\sqrt{v_{\perp }^2+v_{\parallel }^2}=\sqrt{\frac{(E^2-1)r^2-Q^2-r^2+2rM}{E^2{r}^2}}.}$$

Alternative formulation of metric

The metric can be expressed in Kerr–Schild form like this: $${\displaystyle \begin{array}{rl}{g}_{\mu \nu }& ={\eta }_{\mu \nu }+f{k}_{\mu }{k}_{\nu }\\ f& =\frac{G}{r^2}[2Mr-Q^2]\\ \mathbf{k}& =(k_x,k_y,k_z)=(\frac{x}{r},\frac{y}{r},\frac{z}{r})\\ k_0& =1.\end{array}}$$ Notice that k is a unit vector. Here M is the constant mass of the object, Q is the constant charge of the object, and η is the Minkowski tensor.

See also

• Black hole electron

Notes

References

• Adler, R.; Bazin, M.; Schiffer, M. (1965). Introduction to General Relativity. New York: McGraw-Hill Book Company. pp. 395–401. ISBN 978-0-07-000420-7.
• Wald, Robert M. (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.