Matrix splitting: Difference between revisions

In general relativity, the Weyl metrics (named after the German-American mathematician Hermann Weyl) refer to the class of static and axisymmetric solutions to Einstein's field equation. Three members in the renowned Kerr-Newman family solutions, namely the Schwarzschild, nonextremal Reissner-Nordström and extremal Reissner-Nordström metrics, can be identified as Weyl-type metrics.

Standard Weyl metrics

The Weyl class of solutions has the generic form^[1][2]

${\displaystyle (1)d{s}^2=-e^{2\psi (\rho ,z)}d{t}^2+e^{2\gamma (\rho ,z)-2\psi (\rho ,z)}(d{\rho }^2+d{z}^2)+e^{-2\psi (\rho ,z)}{\rho }^{2}d{\varphi }^2,}$

where ${\displaystyle \psi (\rho ,z)}$ and ${\displaystyle \gamma (\rho ,z)}$ are two metric potentials dependent on Weyl's canonical coordinates ${\displaystyle \{\rho ,z\}}$. The coordinate system ${\displaystyle \{t,\rho ,z,\varphi \}}$ serves best for symmetries of Weyl's spacetime (with two Killing vector fields being ${\displaystyle {\xi }^t={\partial }_t}$ and ${\displaystyle {\xi }^{\varphi }={\partial }_{\varphi }}$) and often acts like cylindrical coordinates,^[1] but is incomplete when describing a black hole as ${\displaystyle \{\rho ,z\}}$ only cover the horizon and its exteriors.

Hence, to determine a static axisymmetric solution corresponding to a specific stress-energy tensor ${\displaystyle T_{ab}}$, we just need to substitute the Weyl metric Eq(1) into Einstein's equation (with c=G=1):

${\displaystyle (2)R_{ab}-\frac{1}{2}R{g}_{ab}=8\pi T_{ab},}$

and work out the two functions ${\displaystyle \psi (\rho ,z)}$ and ${\displaystyle \gamma (\rho ,z)}$.

Reduced field equations for electrovac Weyl solutions

One of the best investigated and most useful Weyl solutions is the electrovac case, where ${\displaystyle T_{ab}}$ comes from the existence of (Weyl-type) electromagnetic field (without matter and current flows). As we know, given the electromagnetic four-potential ${\displaystyle A_a}$, the anti-symmetric electromagnetic field ${\displaystyle F_{ab}}$ and the trace-free stress-energy tensor ${\displaystyle T_{ab}}$ ${\displaystyle (T=g^{ab}{T}_{ab}=0)}$ will be respectively determined by

${\displaystyle (3)F_{ab}=A_{b;a}-A_{a;b}=A_{b,a}-A_{a,b}}$
${\displaystyle (4)T_{ab}=\frac{1}{4\pi }(F_{ac}{F}_b^c-\frac{1}{4}{g}_{ab}{F}_{cd}{F}^{cd}),}$

which respects the source-free covariant Maxwell equations:

${\displaystyle (5.a)(F^{ab}{)}_{;b}=0,F_{[ab;c]}=0.}$

Eq(5.a) can be simplified to:

${\displaystyle (5.b)(\sqrt{-g}{F}^{ab}{)}_{,b}=0,F_{[ab,c]}=0}$

in the calculations as ${\displaystyle {\mathrm{\Gamma }}_{bc}^a={\mathrm{\Gamma }}_{cb}^a}$. Also, since ${\displaystyle R=-8\pi T=0}$ for electrovacuum, Eq(2) reduces to

${\displaystyle (6)R_{ab}=8\pi T_{ab}.}$

Now, suppose the Weyl-type axisymmetric electrostatic potential is ${\displaystyle A_a=\mathrm{\Phi }(\rho ,z)[dt{]}_a}$ (the component ${\displaystyle \mathrm{\Phi }}$ is actually the electromagnetic scalar potential), and together with the Weyl metric Eq(1), Eqs(3)(4)(5)(6) imply that

${\displaystyle (7.a){\mathrm{\nabla }}^2\psi =(\mathrm{\nabla }\psi {)}^2+{\gamma }_{,\rho \rho }+{\gamma }_{,zz}}$
${\displaystyle (7.b){\mathrm{\nabla }}^2\psi =e^{-2\psi }(\mathrm{\nabla }\mathrm{\Phi }{)}^2}$
${\displaystyle (7.c)\frac{1}{\rho }{\gamma }_{,\rho }={\psi }_{,\rho }^2-{\psi }_{,z}^2-e^{-2\psi }({\mathrm{\Phi }}_{,\rho }^2-{\mathrm{\Phi }}_{,z}^2)}$
${\displaystyle (7.d)\frac{1}{\rho }{\gamma }_{,z}=2{\psi }_{,\rho }{\psi }_{,z}-2e^{-2\psi }{\mathrm{\Phi }}_{,\rho }{\mathrm{\Phi }}_{,z}}$
${\displaystyle (7.e){\mathrm{\nabla }}^2\mathrm{\Phi }=2\mathrm{\nabla }\psi \mathrm{\nabla }\mathrm{\Phi },}$

where ${\displaystyle R=0}$ yields Eq(7.a), ${\displaystyle R_{tt}=8\pi T_{tt}}$ or ${\displaystyle R_{\phi \phi }=8\pi T_{\phi \phi }}$ yields Eq(7.b), ${\displaystyle R_{\rho \rho }=8\pi T_{\rho \rho }}$ or ${\displaystyle R_{zz}=8\pi T_{zz}}$ yields Eq(7.c), ${\displaystyle R_{\rho z}=8\pi T_{\rho z}}$ yields Eq(7.d), and Eq(5.b) yields Eq(7.e). Here ${\displaystyle {\mathrm{\nabla }}^2={\partial }_{\rho \rho }+\frac{1}{\rho }{\partial }_{\rho }+{\partial }_{zz}}$ and ${\displaystyle \mathrm{\nabla }={\partial }_{\rho }{\hat{e}}_{\rho }+{\partial }_z{\hat{e}}_z}$ are respectively the Laplace and gradient operators. Moreover, if we suppose ${\displaystyle \psi =\psi (\mathrm{\Phi })}$ in the sense of matter-geometry interplay and assume asymptotic flatness, we will find that Eqs(7.a-e) implies a characteristic relation that

${\displaystyle (7.f)e^{\psi }={\mathrm{\Phi }}^2-2C\mathrm{\Phi }+1.}$

Specifically in the simplest vacuum case with ${\displaystyle \mathrm{\Phi }=0}$ and ${\displaystyle T_{ab}=0}$, Eqs(7.a-7.e) reduce to^[3]

${\displaystyle (8.a){\gamma }_{,\rho \rho }+{\gamma }_{,zz}=-(\mathrm{\nabla }\psi {)}^2}$
${\displaystyle (8.b){\mathrm{\nabla }}^2\psi =0}$
${\displaystyle (8.c){\gamma }_{,\rho }=\rho ({\psi }_{,\rho }^2-{\psi }_{,z}^2)}$
${\displaystyle (8.d){\gamma }_{,z}=2\rho {\psi }_{,\rho }{\psi }_{,z}.}$

We can firstly obtain ${\displaystyle \psi (\rho ,z)}$ by solving Eq(8.b), and then integrate Eq(8.c) and Eq(8.d) for ${\displaystyle \gamma (\rho ,z)}$. Practically, Eq(8.a) arising from ${\displaystyle R=0}$ just works as a consistency relation or integrability condition.

Unlike the nonlinear Poisson's equation Eq(7.b), Eq(8.a) is the linear Laplace equation; that is to say, superposition of given vacuum solutions to Eq(8.a) is still a solution. This fact has a widely application, such as to analytically distort a Schwarzschild black hole.

Newtonian analogue of metric potential Ψ(ρ,z)

In Weyl's metric Eq(1), ${\displaystyle e^{\pm 2\psi }={\displaystyle \sum _{n=0}^{\mathrm{\infty }}}\frac{(\pm 2\psi {)}^n}{n!}}$; thus in the approximation for weak field limit ${\displaystyle \psi \to 0}$, one has

${\displaystyle (9)g_{tt}=-(1+2\psi )-\mathcal{𝒪}({\psi }^2),g_{\varphi \varphi }=1-2\psi +\mathcal{𝒪}({\psi }^2),}$

and therefore

${\displaystyle (10)d{s}^2\approx -(1+2\psi (\rho ,z))d{t}^2+(1-2\psi (\rho ,z))[e^{2\gamma }(d{\rho }^2+d{z}^2)+{\rho }^{2}d{\varphi }^2].}$

This is pretty analogous to the well-known approximate metric for static and weak gravitational fields generated by low-mass celestial bodies like the Sun and Earth,^[4]

${\displaystyle (11)d{s}^2=-(1+2{\mathrm{\Phi }}_N(\rho ,z))d{t}^2+(1-2{\mathrm{\Phi }}_N(\rho ,z))[d{\rho }^2+d{z}^2+{\rho }^{2}d{\varphi }^2].}$

where ${\displaystyle {\mathrm{\Phi }}_N(\rho ,z)}$ is the usual Newtonian potential satisfying Poisson's equation ${\displaystyle {\displaystyle \underset{L}{\overset{2}{\mathrm{\nabla }}}}{\mathrm{\Phi }}_N=4\pi {\varrho }_N}$, just like Eq(3.a) or Eq(4.a) for the Weyl metric potential ${\displaystyle \psi (\rho ,z)}$. The similarities between ${\displaystyle \psi (\rho ,z)}$ and ${\displaystyle {\mathrm{\Phi }}_N(\rho ,z)}$ inspire people to find out the Newtonian analogue of ${\displaystyle \psi (\rho ,z)}$ when studying Weyl class of solutions; that is, to reproduce ${\displaystyle \psi (\rho ,z)}$ nonrelativistically by certain type of Newtonian sources. The Newtonian analogue of ${\displaystyle \psi (\rho ,z)}$ proves quite helpful in specifying particular Weyl-type solutions and extending existing Weyl-type solutions.^[1]

Schwarzschild solution

The Weyl potentials generating Schwarzschild's metric as solutions to the vacuum equations Eq(8) are given by^[1][2][3]

${\displaystyle (12){\psi }_{SS}=\frac{1}{2}\ln \frac{L-M}{L+M},{\gamma }_{SS}=\frac{1}{2}\ln \frac{L^2-M^2}{l_{+}{l}_{-}},}$

where

${\displaystyle (13)L=\frac{1}{2}(l_{+}+l_{-}),l_{+}=\sqrt{{\rho }^2+(z+M{)}^2},l_{-}=\sqrt{{\rho }^2+(z-M{)}^2}.}$

From the perspective of Newtonian analogue, ${\displaystyle {\psi }_{SS}}$ equals the gravitational potential produced by a rod of mass ${\displaystyle M}$ and length ${\displaystyle 2M}$ placed symmetrically on the ${\displaystyle z}$-axis; that is, by a line mass of uniform density ${\displaystyle \sigma =1/2}$ embedded the interval ${\displaystyle z\in [-M,M]}$. (Note: Based on this analogue, important extensions of the Schwarzschild metric have been developed, as discussed in ref.^[1])

Given ${\displaystyle {\psi }_{SS}}$ and ${\displaystyle {\gamma }_{SS}}$, Weyl's metric Eq(\ref{Weyl metric in canonical coordinates}) becomes

${\displaystyle (14)d{s}^2=-\frac{L-M}{L+M}d{t}^2+\frac{(L+M{)}^2}{l_{+}{l}_{-}}(d{\rho }^2+d{z}^2)+\frac{L+M}{L-M}{\rho }^{2}d{\varphi }^2,}$

and after substituting the following mutually consistent relations

${\displaystyle (15)L+M=r,l_{+}+l_{-}=2M\cos \theta ,z=(r-M)\cos \theta ,}$
${\displaystyle \rho =\sqrt{r^2-2Mr}\sin \theta ,l_{+}{l}_{-}=(r-M{)}^2-M^2{\cos }^{}\theta ,}$

one can obtain the common form of Schwarzschild metric in the usual ${\displaystyle \{t,r,\theta ,\varphi \}}$ coordinates,

${\displaystyle (16)d{s}^2=-(1-\frac{2M}{r})d{t}^2+(1-\frac{2M}{r}{)}^{-1}d{r}^2+r^{2}d{\theta }^2+r^2{\sin }^2\theta d{\varphi }^2.}$

The metric Eq(14) cannot be directly transformed into Eq(16) by performing the standard cylindrical-spherical transformation ${\displaystyle (t,\rho ,z,\varphi )=(t,r\sin \theta ,r\cos \theta ,\varphi )}$, because ${\displaystyle \{t,r,\theta ,\varphi \}}$ is complete while ${\displaystyle (t,\rho ,z,\varphi )}$ is incomplete. This is why we call ${\displaystyle \{t,\rho ,z,\varphi \}}$ in Eq(1) as Weyl's canonical coordinates rather than cylindrical coordinates, although they have a lot in common; for example, the Laplacian ${\displaystyle {\mathrm{\nabla }}^2:={\partial }_{\rho \rho }+\frac{1}{\rho }{\partial }_{\rho }+{\partial }_{zz}}$ in Eq(7) is exactly the two-dimensional geometric Laplacian in cylindrical coordinates.

Nonextremal Reissner-Nordström solution

The Weyl potentials generating the nonextremal Reissner-Nordström solution (${\displaystyle M>\left|Q\right|}$) as solutions to Eqs(7} are given by^[1][2][3]

${\displaystyle (17){\psi }_{RN}=\frac{1}{2}\ln \frac{L^2-(M^2-Q^2)}{(L+M{)}^2},{\gamma }_{RN}=\frac{1}{2}\ln \frac{L^2-(M^2-Q^2)}{l_{+}{l}_{-}},}$

where

${\displaystyle (18)L=\frac{1}{2}(l_{+}+l_{-}),l_{+}=\sqrt{{\rho }^2+(z+\sqrt{M^2-Q^2}{)}^2},l_{-}=\sqrt{{\rho }^2+(z-\sqrt{M^2-Q^2}{)}^2}.}$

Thus, given ${\displaystyle {\psi }_{RN}}$ and ${\displaystyle {\gamma }_{RN}}$, Weyl's metric becomes

${\displaystyle (19)d{s}^2=-\frac{L^2-(M^2-Q^2)}{(L+M{)}^2}d{t}^2+\frac{(L+M{)}^2}{l_{+}{l}_{-}}(d{\rho }^2+d{z}^2)+\frac{(L+M{)}^2}{L^2-(M^2-Q^2)}{\rho }^{2}d{\varphi }^2,}$

and employing the following transformations

${\displaystyle (20)L+M=r,l_{+}+l_{-}=2\sqrt{M^2-Q^2}\cos \theta ,z=(r-M)\cos \theta ,}$
${\displaystyle \rho =\sqrt{r^2-2Mr+Q^2}\sin \theta ,l_{+}{l}_{-}=(r-M{)}^2-(M^2-Q^2){\cos }^{}\theta ,}$

one can obtain the common form of non-extremal Reissner-Nordström metric in the usual ${\displaystyle \{t,r,\theta ,\varphi \}}$ coordinates,

${\displaystyle (21)d{s}^2=-(1-\frac{2M}{r}+\frac{Q^2}{r^2})d{t}^2+(1-\frac{2M}{r}+\frac{Q^2}{r^2}{)}^{-1}d{r}^2+r^{2}d{\theta }^2+r^2{\sin }^2\theta d{\varphi }^2.}$

Extremal Reissner-Nordström solution

The potentials generating the extremal Reissner-Nordström solution (${\displaystyle M=\left|Q\right|}$) as solutions to Eqs(7} are given by^[3] (Note: We treat the extremal solution separately because it is much more than the degenerate state of the nonextremal counterpart.)

${\displaystyle (22){\psi }_{ERN}=\frac{1}{2}\ln \frac{L^2}{(L+M{)}^2},{\gamma }_{ERN}=0,\text{with}L=\sqrt{{\rho }^2+z^2}.}$

Thus, the extremal Reissner-Nordström metric reads

${\displaystyle (23)d{s}^2=-\frac{L^2}{(L+M{)}^2}d{t}^2+\frac{(L+M{)}^2}{L^2}(d{\rho }^2+d{z}^2+{\rho }^{2}d{\varphi }^2),}$

and by substituting

${\displaystyle (24)L+M=r,z=L\cos \theta ,\rho =L\sin \theta ,}$

we obtain the extremal Reissner-Nordström metric in the usual ${\displaystyle \{t,r,\theta ,\varphi \}}$ coordinates,

${\displaystyle (25)d{s}^2=-(1-\frac{M}{r}{)}^{2}d{t}^2+(1-\frac{M}{r}{)}^{-2}d{r}^2+r^{2}d{\theta }^2+r^2{\sin }^2\theta d{\varphi }^2.}$

Mathematically, the extremal Reissner-Nordström can be obtained by taking the limit ${\displaystyle Q\to M}$ of the corresponding nonextremal equation, and in the meantime we need to use the L'Hospital rule sometimes.

Remarks: Weyl's metrics Eq(1) with the vanishing potential ${\displaystyle \gamma (\rho ,z)}$ (like the extremal Reissner-Nordström metric) constitute a special subclass which have only one metric potential ${\displaystyle \psi (\rho ,z)}$ to be identified. Extending this subclass by canceling the restriction of axisymmetry, one obtains another useful class of solutions (still using Weyl's coordinates), namely the conformastatic metrics,^[5][6]

${\displaystyle (26)d{s}^2=-e^{2\lambda (\rho ,z,\varphi )}d{t}^2+e^{-2\lambda (\rho ,z,\varphi )}(d{\rho }^2+d{z}^2+{\rho }^{2}d{\varphi }^2),}$

where we use ${\displaystyle \lambda }$ in Eq(22) as the single metric function in place of ${\displaystyle \psi }$ in Eq(1) to emphasize that they are different by axial symmetry (${\displaystyle \varphi }$-dependence).

Weyl vacuum solutions in spherical coordinates

Weyl's metric can also be expressed in spherical coordinates that

${\displaystyle (27)d{s}^2=-e^{2\psi (r,\theta )}d{t}^2+e^{2\gamma (r,\theta )-2\psi (r,\theta )}(d{r}^2+r^{2}d{\theta }^2)+e^{-2\psi (r,\theta )}{\rho }^{2}d{\varphi }^2,}$

which equals Eq(1) via the coordinate transformation ${\displaystyle (t,\rho ,z,\varphi )\mapsto (t,r\sin \theta ,r\cos \theta ,\varphi )}$ (Note: As shown by Eqs(15)(21)(24), this transformation is not always applicable.) In the vacuum case, Eq(8.b) for ${\displaystyle \psi (r,\theta )}$ becomes

${\displaystyle (28)r^2{\psi }_{,rr}+2r{\psi }_{,r}+{\psi }_{,\theta \theta }+\cot \theta \cdot {\psi }_{,\theta }=0.}$

The asymptotically flat solutions to Eq(28) is^[1]

${\displaystyle (29)\psi (r,\theta )=-{\displaystyle \sum _{n=0}^{\mathrm{\infty }}}{a}_n\frac{P_n(\cos \theta )}{r^{n+1}},}$

where ${\displaystyle P_n(\cos \theta )}$ represent Legendre polynomials, and ${\displaystyle a_n}$ are multipole coefficients. The other metric potential ${\displaystyle \gamma (r,\theta )}$is given by^[1]

${\displaystyle (30)\gamma (r,\theta )=-{\displaystyle \sum _{l=0}^{\mathrm{\infty }}}{\displaystyle \sum _{m=0}^{\mathrm{\infty }}}{a}_l{a}_m}$ ${\displaystyle \frac{(l+1)(m+1)}{l+m+2}}$ ${\displaystyle \frac{P_l{P}_m-P_{l+1}{P}_{m+1}}{r^{l+m+2}}.}$

See also

• Schwarzschild metric
• Reissner–Nordström metric
• Distorted Schwarzschild metric

References

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