Equilateral dimension: Difference between revisions

Latest revision as of 08:59, 22 November 2013

In general relativity, the Vaidya metric describes the non-empty external spacetime of a spherically symmetric and nonrotating star which is either emitting or absorbing null dusts. It is named after the Indian physicist Prahalad Chunnilal Vaidya and constitutes a simplest non-static generalization of the non-radiative Schwarzschild solution to Einstein's field equation, and therefore is also called the "radiating(/shining) Schwarzschild metric".

From Schwarzschild to Vaidya metrics

The Schwarzschild metric as the static and spherically symmetric solution to Einstein's equation reads

$(1) d s^{2} = - (1 - \frac{2 M}{r}) d t^{2} + (1 - \frac{2 M}{r})^{- 1} d r^{2} + r^{2} (d θ^{2} + \sin^{2} θ d ϕ^{2}) .$

To remove the coordinate singularity of this metric at $r = 2 M$ , one could switch to the Eddington-Finkelstein coordinates. Thus, introduce the "retarded(/outgoing)" null coordinate $u$ by

$(2) t = u + r + 2 M \ln (\frac{r}{2 M} - 1) \Rightarrow d t = d u + (1 - \frac{2 M}{r})^{- 1} d r,$

and Eq(1) could be transformed into the "retarded(/outgoing) Schwarzschild metric"

$(3) d s^{2} = - (1 - \frac{2 M}{r}) d u^{2} - 2 d u d r + r^{2} (d θ^{2} + \sin^{2} θ d ϕ^{2});$

or, we could instead employ the "advanced(/ingoing)" null coordinate $v$ by

$(4) t = v - r - 2 M \ln (\frac{r}{2 M} - 1) \Rightarrow d t = d v - (1 - \frac{2 M}{r})^{- 1} d r,$

so Eq(1) becomes the "advanced(/ingoing) Schwarzschild metric"

$(5) d s^{2} = - (1 - \frac{2 M}{r}) d v^{2} + 2 d v d r + r^{2} (d θ^{2} + \sin^{2} θ d ϕ^{2}) .$

Eq(3) and Eq(5), as static and spherically symmetric solutions, are valid for both ordinary celestial objects with finite radii and singular objects such as black holes. It turns out that, it is still physically reasonable if one extends the mass parameter $M$ in Eqs(3) and Eq(5) from a constant to functions of the corresponding null coordinate, $M (u)$ and $M (v)$ respectively, thus

$(6) d s^{2} = - (1 - \frac{2 M (u)}{r}) d u^{2} - 2 d u d r + r^{2} (d θ^{2} + \sin^{2} θ d ϕ^{2}),$

$(7) d s^{2} = - (1 - \frac{2 M (v)}{r}) d v^{2} + 2 d v d r + r^{2} (d θ^{2} + \sin^{2} θ d ϕ^{2}) .$

The extended metrics Eq(6) and Eq(7) are respectively the "retarded(/outgoing)" and "advanced(/ingoing)" Vaidya metrics.^[1]^[2] It is also interesting and sometimes useful to recast the Vaidya metrics Eqs(6)(7) into the form

$(8) d s^{2} = \frac{2 M (u)}{r} d u^{2} + d s^{2} (flat) = \frac{2 M (v)}{r} d v^{2} + d s^{2} (flat),$

where $d s^{2} (flat) = - d u^{2} - 2 d u d r + r^{2} (d θ^{2} + \sin^{2} θ d ϕ^{2}) = - d v^{2} + 2 d v d r + r^{2} (d θ^{2} + \sin^{2} θ d ϕ^{2}) = - d t^{2} + d r^{2} + r^{2} (d θ^{2} + \sin^{2} θ d ϕ^{2})$ represents the metric of flat spacetime.

Outgoing Vaidya with pure Emitting field

As for the "retarded(/outgoing)" Vaidya metric Eq(6),^[1]^[2]^[3]^[4]^[5] the Ricci tensor has only one nonzero component

$(9) R_{u u} = - 2 \frac{M (u)_{, u}}{r^{2}},$

while the Ricci curvature scalar vanishes, $R = g^{a b} R_{a b} = 0$ . Thus, according to the trace-free Einstein equation $G_{a b} = R_{a b} = 8 π T_{a b}$ , the stress-energy tensor $T_{a b}$ satisfies

$(10) T_{a b} = - \frac{M (u)_{, u}}{4 π r^{2}} l_{a} l_{b}, l_{a} d x^{a} = - d u,$

where $l_{a} = - \partial_{a} u$ and $l^{a} = g^{a b} l_{b}$ are null (co)vectors (c.f. Box A below). Thus, $T_{a b}$ is a "pure radiation field",^[1]^[2] which has an energy density of $- \frac{M (u)_{, u}}{4 π r^{2}}$ . According to the null energy conditions

$(11) T_{a b} k^{a} k^{b} \geq 0,$

we have $M (u)_{, u} < 0$ and thus the central body is emitting radiations.

Following the calculations using Newman-Penrose (NP) formalism in Box A, the outgoing Vaidya spacetime Eq(6) is of Petrov-type D, and the nonzero components of the Weyl-NP and Ricci-NP scalars are

$(12) Ψ_{2} = - \frac{M (u)}{r^{3}} Φ_{22} = - \frac{M (u)_{, u}}{r^{2}} .$

It is notable that, the Vaidya field is a pure radiation field rather than electromagnetic fields. The emitted particles or energy-matter flows have zero rest mass and thus are generally called "null dusts", typically such as photons and neutrinos, but cannot be electromagnetic waves because the Maxwell-NP equations are not satisfied. By the way, the outgoing and ingoing null expansion rates for the line element Eq(6) are respectively

$(13) θ_{(ℓ)} = - (ρ + \bar{ρ}) = \frac{2}{r}, θ_{(n)} = μ + \bar{μ} = \frac{- r + 2 M (u)}{r^{2}} .$

Box A: Analyses of Vaidya metric in an "outgoing" null tetrad

Suppose $F : = 1 - \frac{2 M (u)}{r}$ , then the Lagrangian for null radial geodesics $(L = 0, \dot{θ} = 0, \dot{ϕ} = 0)$ of the "retarded(/outgoing)" Vaidya spacetime Eq(6) is

$L = 0 = - F {\dot{u}}^{2} + 2 \dot{u} \dot{r},$

where dot means derivative with respect to some parameter $λ$ . This Lagrangian has two solutions,

$\dot{u} = 0 and \dot{r} = \frac{F}{2} \dot{u} .$

According to the definition of $u$ in Eq(2), one could find that when $t$ increases, the areal radius $r$ would increase as well for the solution $\dot{u} = 0$ , while $r$ would decrease for the solution $\dot{r} = \frac{F}{2} \dot{u}$ . Thus, $\dot{u} = 0$ should be recognized as an outgoing solution while $\dot{r} = \frac{F}{2} \dot{u}$ serves as an ingoing solution. Now, we can construct a complex null tetrad which is adapted to the outgoing null radial geodesics and employ the Newman-Penrose formalism for perform a full analysis of the outgoing Vaidya spacetime. Such an outgoing adapted tetrad can be set up as

$l^{a} = (0, 1, 0, 0), n^{a} = (1, - \frac{F}{2}, 0, 0), m^{a} = \frac{1}{\sqrt{2} r} (0, 0, 1, i \csc θ),$

and the dual basis covectors are therefore

$l_{a} = (- 1, 0, 0, 0), n_{a} = (- \frac{F}{2}, - 1, 0, 0), m_{a} = \frac{r}{\sqrt{2}} (0, 0, 1, \sin θ) .$

In this null tetrad, the spin coefficients are

$κ = σ = τ = 0, ν = λ = π = 0, ε = 0$
$ρ = - \frac{1}{r}, μ = \frac{- r + 2 M (u)}{2 r^{2}}, α = - β = \frac{- \sqrt{2} \cot θ}{4 r}, γ = \frac{M (u)}{2 r^{2}} .$

The Weyl-NP and Ricci-NP scalars are given by

$Ψ_{0} = Ψ_{1} = Ψ_{3} = Ψ_{4} = 0, Ψ_{2} = - \frac{M (u)}{r^{3}},$

$Φ_{00} = Φ_{10} = Φ_{20} = Φ_{11} = Φ_{12} = Λ = 0, Φ_{22} = - \frac{M (u)_{, u}}{r^{2}},$

Since the only nonvanishing Weyl-NP scalar is $Ψ_{2}$ , the "retarded(/outgoing)" Vaidya spacetime is of Petrov-type D. Also, there exists a radiation field as $Φ_{22} \neq 0$ .

Box B: Analyses of Schwarzschild metric in an "outgoing" null tetrad

For the "retarded(/outgoing)" Schwarzschild metric Eq(3), let $G : = 1 - \frac{2 M}{r}$ , and then the Lagrangian for null radial geodesics will have an outgoing solution $\dot{u} = 0$ and an ingoing solution $\dot{r} = - \frac{G}{2} \dot{u}$ . Similar to Box A, now set up the adapted outgoing tetrad by

$l^{a} = (0, 1, 0, 0), n^{a} = (1, - \frac{G}{2}, 0, 0), m^{a} = \frac{1}{\sqrt{2} r} (0, 0, 1, i \csc θ),$

$l_{a} = (- 1, 0, 0, 0), n_{a} = (- \frac{G}{2}, - 1, 0, 0), m_{a} = \frac{r}{\sqrt{2}} (0, 0, 1, \sin θ) .$

so the spin coefficients are

$κ = σ = τ = 0, ν = λ = π = 0, ε = 0$
$ρ = - \frac{1}{r}, μ = \frac{- r + 2 M}{2 r^{2}}, α = - β = \frac{- \sqrt{2} \cot θ}{4 r}, γ = \frac{M}{2 r^{2}},$

and the Weyl-NP and Ricci-NP scalars are given by

$Ψ_{0} = Ψ_{1} = Ψ_{3} = Ψ_{4} = 0, Ψ_{2} = - \frac{M}{r^{3}},$

$Φ_{00} = Φ_{10} = Φ_{20} = Φ_{11} = Φ_{12} = Φ_{22} = Λ = 0 .$

The "retarded(/outgoing)" Schwarzschild spacetime is of Petrov-type D with $Ψ_{2}$ being the only nonvanishing Weyl-NP scalar.

Ingoing Vaidya with pure Absorbing field

As for the "advanced/ingoing" Vaidya metric Eq(7),^[1]^[2]^[6] the Ricci tensors again have one nonzero component

$(14) R_{v v} = 2 \frac{M (v)_{, v}}{r^{2}},$

and therefore $R = 0$ and the stress-energy tensor is

$(15) T_{a b} = \frac{M (v)_{, v}}{4 π r^{2}} n_{a} n_{b}, n_{a} d x^{a} = - d v .$

This is a pure radiation field with energy density $\frac{M (v)_{, v}}{4 π r^{2}}$ , and once again it follows from the null energy condition Eq(11) that $M (v)_{, v} > 0$ , so the central object is absorbing null dusts. As calculated in Box C, the nonzero Weyl-NP and Ricci-NP components of the "advanced/ingoing" Vaidya metric Eq(7) are

$(16) Ψ_{2} = - \frac{M (v)}{r^{3}} Φ_{00} = \frac{M (v)_{, v}}{r^{2}} .$

Also, the outgoing and ingoing null expansion rates for the line element Eq(7) are respectively

$(17) θ_{(ℓ)} = - (ρ + \bar{ρ}) = \frac{r - 2 M (v)}{r^{2}}, θ_{(n)} = μ + \bar{μ} = - \frac{2}{r} .$

The advanced/ingoing Vaidya solution Eq(7) is especially useful in black-hole physics as it's one of the few existing exact dynamical solutions. For example, it is often employed to investigate the differences between different definitions of the dynamical black-hole boundaries, such as the classical event horizon and the quasilocal trapping horizon; and as shown by Eq(17), the evolutionary hypersurface $r = 2 M (v)$ is always a marginally outer trapped horizon ( $θ_{(ℓ)} = 0, θ_{(n)} < 0$ ).

Box C: Analyses of Vaidya metric in an "ingoing" null tetrad

Suppose $\tilde{F} : = 1 - \frac{2 M (v)}{r}$ , then the Lagrangian for null radial geodesics of the "advanced(/ingoing)" Vaidya spacetime Eq(7) is

$L = - \tilde{F} {\dot{v}}^{2} + 2 \dot{v} \dot{r},$

which has an ingoing solution $\dot{v} = 0$ and an outgoing solution $\dot{r} = \frac{\tilde{F}}{2} \dot{v}$ in accordance with the definition of $v$ in Eq(4). Now, we can construct a complex null tetrad which is adapted to the ingoing null radial geodesics and employ the Newman-Penrose formalism for perform a full analysis of the Vaidya spacetime. Such an ingoing adapted tetrad can be set up as

$l^{a} = (1, \frac{\tilde{F}}{2}, 0, 0), n^{a} = (0, - 1, 0, 0), m^{a} = \frac{1}{\sqrt{2} r} (0, 0, 1, i \csc θ),$

and the dual basis covectors are therefore

$l_{a} = (- \frac{\tilde{F}}{2}, 1, 0, 0), n_{a} = (- 1, 0, 0, 0), m_{a} = \frac{r}{\sqrt{2}} (0, 0, 1, \sin θ) .$

In this null tetrad, the spin coefficients are

$κ = σ = τ = 0, ν = λ = π = 0, γ = 0$
$ρ = \frac{- r + 2 M (v)}{2 r^{2}}, μ = - \frac{1}{r}, α = - β = \frac{- \sqrt{2} \cot θ}{4 r}, ε = \frac{M (v)}{2 r^{2}} .$

The Weyl-NP and Ricci-NP scalars are given by

$Ψ_{0} = Ψ_{1} = Ψ_{3} = Ψ_{4} = 0, Ψ_{2} = - \frac{M (v)}{r^{3}},$

$Φ_{10} = Φ_{20} = Φ_{11} = Φ_{12} = Φ_{22} = Λ = 0, Φ_{00} = \frac{M (v)_{, v}}{r^{2}} .$

Since the only nonvanishing Weyl-NP scalar is $Ψ_{2}$ , the "advanced(/ingoing)" Vaidya spacetime is of Petrov-type D, and there exists an radiation field encoded into $Φ_{00}$ .

Box D: Analyses of Schwarzschild metric in an "ingoing" null tetrad

For the "advanced(/ingoing)" Schwarzschild metric Eq(5), still let $G : = 1 - \frac{2 M}{r}$ , and then the Lagrangian for the null radial geodesics will have an ingoing solution $\dot{v} = 0$ and an outgoing solution $\dot{r} = \frac{G}{2} \dot{v}$ . Similar to Box C, now set up the adapted ingoing tetrad by

$l^{a} = (1, \frac{G}{2}, 0, 0), n^{a} = (0, - 1, 0, 0), m^{a} = \frac{1}{\sqrt{2} r} (0, 0, 1, i \csc θ),$

$l_{a} = (- \frac{G}{2}, 1, 0, 0), n_{a} = (- 1, 0, 0, 0), m_{a} = \frac{r}{\sqrt{2}} (0, 0, 1, \sin θ) .$

so the spin coefficients are

$κ = σ = τ = 0, ν = λ = π = 0, γ = 0$
$ρ = \frac{- r + 2 M}{2 r^{2}}, μ = - \frac{1}{r}, α = - β = \frac{- \sqrt{2} \cot θ}{4 r}, ε = \frac{M}{2 r^{2}},$

and the Weyl-NP and Ricci-NP scalars are given by

$Ψ_{0} = Ψ_{1} = Ψ_{3} = Ψ_{4} = 0, Ψ_{2} = - \frac{M}{r^{3}},$

$Φ_{00} = Φ_{10} = Φ_{20} = Φ_{11} = Φ_{12} = Φ_{22} = Λ = 0 .$

The "advanced(/ingoing)" Schwarzschild spacetime is of Petrov-type D with $Ψ_{2}$ being the only nonvanishing Weyl-NP scalar.

Comparison with the Schwarzschild metric

As a natural and simplest extension of the Schwazschild metric, the Vaidya metric still has a lot in common with it:

Both metrics are of Petrov-type D with $Ψ_{2}$ being the only nonvanishing Weyl-NP scalar (as calculated in Boxes A and B).

However, there are three clear differences between the Schwarzschild and Vaidia metric:

First of all, the mass parameter $M$ for Schwarzschild is a constant, while for Vaidya $M (u)$ is a u-dependent function.
Schwarzschild is a solution to the vacuum Einstein equation $R_{a b} = 0$ , while Vaidya is solution is to the trace-free Einstein equation $R_{a b} = 8 π T_{a b}$ with a nontrivial pure radiation energy field. As a result, all Ricci-NP scalars for Schwarzschild are vanishing, while we have $Φ_{00} = \frac{M (u)_{, u}}{r^{2}}$ for Vaidya.
Schwarzschild has 4 independent Killing vector fields, including a timelike one, and thus is a static metric, while Vaidya has only 3 independent Killing vector fields regarding the spherical symmetry, and consequently is nonstatic. Consequently, the Schwarzschild metric belongs to Weyl's class of solutions while the Vaidya metric is not.

Extension of the Vaidya metric

Kinnersley metric

While the Vaidya metric is an extension of the Schwarzschild metric to include a pure radiation field, the Kinnersley metric constitutes a further extension of the Vaidya metric.

Vaidya-Bonner metric

Since the radiated or absorbed matter might be electrically non-neutral, the outgoing and ingoing Vaidya metrics Eqs(6)(7) can be naturally extended to include varying electric charges,

$(18) d s^{2} = - (1 - \frac{2 M (u)}{r} + \frac{Q (u)}{r^{2}}) d u^{2} - 2 d u d r + r^{2} (d θ^{2} + \sin^{2} θ d ϕ^{2}),$

$(19) d s^{2} = - (1 - \frac{2 M (v)}{r} + \frac{Q (v)}{r^{2}}) d v^{2} + 2 d v d r + r^{2} (d θ^{2} + \sin^{2} θ d ϕ^{2}) .$

Eqs(18)(19) are called the Vaidya-Bonner metrics, and apparently, they can also be regarded as extensions of the Reissner-Nordström metric, as opposed to the corresponce between Vaidya and Schwarzschild metrics.

References

43 year old Petroleum Engineer Harry from Deep River, usually spends time with hobbies and interests like renting movies, property developers in singapore new condominium and vehicle racing. Constantly enjoys going to destinations like Camino Real de Tierra Adentro.

↑ ^1.0 ^1.1 ^1.2 ^1.3 Eric Poisson. A Relativist's Toolkit: The Mathematics of Black-Hole Mechanics. Cambridge: Cambridge University Press, 2004. Section 4.3.5 and Section 5.1.8. Cite error: Invalid <ref> tag; name "Vaidya-1" defined multiple times with different content
↑ ^2.0 ^2.1 ^2.2 ^2.3 Jeremy Bransom Griffiths, Jiri Podolsky. Exact Space-Times in Einstein's General Relativity. Cambridge: Cambridge University Press, 2009. Section 9.5.
↑ Thanu Padmanabhan. Gravitation: Foundations and Frontiers. Cambridge: Cambridge University Press, 2010. Section 7.3.
↑ Pankaj S Joshi. Global Aspects in Gravitation and Cosmology. Oxford: Oxford University Press, 1996. Section 3.5.
↑ Pankaj S Joshi. Gravitational Collapse and Spacetime Singularities. Cambridge: Cambridge University Press, 2007. Section 2.7.6.
↑ Valeri Pavlovich Frolov, Igor Dmitrievich Novikov. Black Hole Physics: Basic Concepts and New Developments. Berlin: Springer, 1998. Section 5.7.

[Vaidya-1-1] 1.0 ^1.1 ^1.2 ^1.3 Eric Poisson. A Relativist's Toolkit: The Mathematics of Black-Hole Mechanics. Cambridge: Cambridge University Press, 2004. Section 4.3.5 and Section 5.1.8. Cite error: Invalid <ref> tag; name "Vaidya-1" defined multiple times with different content

[Vaidya-2-2] 2.0 ^2.1 ^2.2 ^2.3 Jeremy Bransom Griffiths, Jiri Podolsky. Exact Space-Times in Einstein's General Relativity. Cambridge: Cambridge University Press, 2009. Section 9.5.

[Vaidya-3-3] Thanu Padmanabhan. Gravitation: Foundations and Frontiers. Cambridge: Cambridge University Press, 2010. Section 7.3.

[Vaidya-4-4] Pankaj S Joshi. Global Aspects in Gravitation and Cosmology. Oxford: Oxford University Press, 1996. Section 3.5.

[Vaidya-5-5] Pankaj S Joshi. Gravitational Collapse and Spacetime Singularities. Cambridge: Cambridge University Press, 2007. Section 2.7.6.

[Vaidya-6-6] Valeri Pavlovich Frolov, Igor Dmitrievich Novikov. Black Hole Physics: Basic Concepts and New Developments. Berlin: Springer, 1998. Section 5.7.

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Equilateral dimension: Difference between revisions

Latest revision as of 08:59, 22 November 2013

Contents

From Schwarzschild to Vaidya metrics

Outgoing Vaidya with pure Emitting field

Ingoing Vaidya with pure Absorbing field

Comparison with the Schwarzschild metric

Extension of the Vaidya metric

Kinnersley metric

Vaidya-Bonner metric

See also

References

Navigation menu

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+In [[general relativity]], the '''Vaidya metric''' describes the non-empty external spacetime of a spherically symmetric and nonrotating star which is either emitting or absorbing [[Null dust solution|null dusts]]. It is named after the Indian physicist [[Prahalad Chunnilal Vaidya]] and constitutes a simplest non-static generalization of the non-radiative [[Schwarzschild metric|Schwarzschild solution]] to [[Einstein's field equation]], and therefore is also called the "radiating(/shining) Schwarzschild metric".
+== From Schwarzschild to Vaidya metrics ==
+The Schwarzschild metric as the static and spherically symmetric solution to Einstein's equation reads
+<math>(1)\quad ds^2=-\Big( 1-\frac{2M}{r} \Big) dt^2+\Big( 1-\frac{2M}{r} \Big)^{-1}dr^2+r^2(d\theta^2+\sin^2\theta\,d\phi^2)\;.</math>
+To remove the coordinate singularity of this metric at <math>r=2M</math>, one could switch to the [[Eddington-Finkelstein coordinates]]. Thus, introduce the "retarded(/outgoing)" null coordinate <math>u</math> by
+<math>(2)\quad t=u+r+2M\ln\Big(\frac{r}{2M}-1\Big)\qquad\Rightarrow\quad dt=du+\Big( 1-\frac{2M}{r} \Big)^{-1}dr\;,</math>
+and Eq(1) could be transformed into the "retarded(/outgoing) Schwarzschild metric"
+<math>(3)\quad ds^2=-\Big( 1-\frac{2M}{r} \Big) du^2-2dudr+r^2(d\theta^2+\sin^2\theta\,d\phi^2)\;;</math>
+or, we could instead employ the "advanced(/ingoing)" null coordinate <math>v</math> by
+<math>(4)\quad t=v-r-2M\ln\Big(\frac{r}{2M}-1\Big)\qquad\Rightarrow\quad dt=dv-\Big( 1-\frac{2M}{r} \Big)^{-1}dr\;,</math>
+so Eq(1) becomes the "advanced(/ingoing) Schwarzschild metric"
+<math>(5)\quad ds^2=-\Big( 1-\frac{2M}{r} \Big) dv^2+2dvdr+r^2(d\theta^2+\sin^2\theta\,d\phi^2)\;.</math>
+Eq(3) and Eq(5), as static and spherically symmetric solutions, are valid for both ordinary celestial objects with finite radii and singular objects such as [[black holes]]. It turns out that, it is still physically reasonable if one extends the mass parameter <math>M</math> in Eqs(3) and Eq(5) from a constant to functions of the corresponding null coordinate, <math>M(u)</math> and <math>M(v)</math> respectively, thus
+<math>(6)\quad ds^2=-\Big( 1-\frac{2M(u)}{r} \Big) du^2-2dudr+r^2(d\theta^2+\sin^2\theta\,d\phi^2)\;,</math>
+<math>(7)\quad ds^2=-\Big( 1-\frac{2M(v)}{r} \Big) dv^2+2dvdr+r^2(d\theta^2+\sin^2\theta\,d\phi^2)\;.</math>
+The extended metrics Eq(6) and Eq(7) are respectively the "retarded(/outgoing)" and "advanced(/ingoing)" Vaidya metrics.<ref name=Vaidya-1>Eric Poisson. ''A Relativist's Toolkit: The Mathematics of Black-Hole Mechanics''. Cambridge: Cambridge University Press, 2004. Section 4.3.5 and Section 5.1.8.</ref><ref name=Vaidya-2>Jeremy Bransom Griffiths, Jiri Podolsky. ''Exact Space-Times in Einstein's General Relativity''. Cambridge: Cambridge University Press, 2009. Section 9.5.</ref> It is also interesting and sometimes useful to recast the Vaidya metrics Eqs(6)(7) into the form
+<math>(8)\quad ds^2 =\frac{2M(u)}{r}du^2 +ds^2(\text{flat})=\frac{2M(v)}{r}dv^2 +ds^2(\text{flat})\,,</math>
+where <math>ds^2(\text{flat})=- du^2-2dudr+r^2 (d\theta^2+\sin^2\theta\, d\phi^2  )=- dv^2+2dvdr+r^2 (d\theta^2+\sin^2\theta\, d\phi^2  )=-dt^2+dr^2+r^2 (d\theta^2+\sin^2\theta\, d\phi^2 )</math> represents the metric of [[flat spacetime]].
+==Outgoing Vaidya with pure Emitting field==
+As for the "retarded(/outgoing)" Vaidya metric Eq(6),<ref name=Vaidya-1>Eric Poisson. ''A Relativist's Toolkit: The Mathematics of Black-Hole Mechanics.'' Cambridge: Cambridge University Press, 2004. Section 4.3.5 and Section 5.1.8.</ref><ref name=Vaidya-2>Jeremy Bransom Griffiths, Jiri Podolsky. ''Exact Space-Times in Einstein's General Relativity''. Cambridge: Cambridge University Press, 2009. Section 9.5.</ref><ref name=Vaidya-3>Thanu Padmanabhan. ''Gravitation: Foundations and Frontiers''. Cambridge: Cambridge University Press, 2010. Section 7.3.</ref><ref name=Vaidya-4>Pankaj S Joshi. ''Global Aspects in Gravitation and Cosmology''. Oxford: Oxford University Press, 1996. Section 3.5.</ref><ref name=Vaidya-5>Pankaj S Joshi. ''Gravitational Collapse and Spacetime Singularities''. Cambridge: Cambridge University Press, 2007. Section 2.7.6.</ref> the [[Ricci tensor]] has only one nonzero component
+<math>(9)\quad R_{uu}=-2\frac{M(u)_{,\,u}}{r^2}\,,</math>
+while the [[Ricci curvature scalar]] vanishes, <math>R=g^{ab} R_{ab}=0</math>. Thus, according to the trace-free Einstein equation <math>G_{ab}=R_{ab}=8\pi T_{ab}</math>, the [[stress-energy tensor]] <math>T_{ab}</math> satisfies
+<math>(10)\quad T_{ab}=-\frac{M(u)_{,\,u}}{4\pi r^2} l_a l_b\;,\qquad l_a dx^a=-du\;,</math>
+where <math>l_a=-\partial_au</math> and <math>l^a=g^{ab}l_b</math> are null (co)vectors (c.f. Box A below). Thus, <math>T_{ab}</math> is a "pure radiation field",<ref name=Vaidya-1>Eric Poisson. ''A Relativist's Toolkit: The Mathematics of Black-Hole Mechanics.'' Cambridge: Cambridge University Press, 2004. Section 4.3.5 and Section 5.1.8.</ref><ref name=Vaidya-2>Jeremy Bransom Griffiths, Jiri Podolsky. ''Exact Space-Times in Einstein's General Relativity''. Cambridge: Cambridge University Press, 2009. Section 9.5.</ref> which has an energy density of <math>-\frac{M(u)_{,\,u}}{4\pi r^2}</math>. According to the null [[energy conditions]]
+<math>(11)\quad T_{ab}k^ak^b\geq 0\;,</math>
+we have <math>M(u)_{,\,u}<0</math> and thus the central body is emitting radiations.
+Following the calculations using [[Newman-Penrose formalism|Newman-Penrose (NP) formalism]] in Box A, the outgoing Vaidya spacetime Eq(6) is of [[Petrov Type|Petrov-type D]], and the nonzero components of the [[Weyl scalar|Weyl-NP]] and [[Ricci scalars (Newman-Penrose formalism)|Ricci-NP]] scalars are
+<math>(12)\quad \Psi_2=-\frac{M(u)}{r^3}\qquad \Phi_{22}=-\frac{M(u)_{\,,\,u}}{r^2}\;.</math>
+It is notable that, the Vaidya field is a pure radiation field rather than [[electromagnetic field]]s. The emitted particles or energy-matter flows have zero [[rest mass]] and thus are generally called "null dusts", typically such as photons and [[neutrinos]], but cannot be electromagnetic waves because the Maxwell-NP equations are not satisfied. By the way, the outgoing and ingoing null expansion rates for the [[line element]] Eq(6) are respectively
+<math>(13)\quad \theta_{(\ell)}=-(\rho+\bar\rho)=\frac{2}{r}\,,\quad \theta_{(n)}=\mu+\bar\mu=\frac{-r+2M(u)}{r^2}\;.</math>
+<div style="clear:both;width:65%;" class="NavFrame collapsed">
+<div class="NavHead" style="background-color:#FFFFFF; text-align:left; font-size:larger;">Box A: Analyses of Vaidya metric in an "outgoing" null tetrad </div>
+<div class="NavContent" style="text-align:left;">
+Suppose <math>F:=1-\frac{2M(u)}{r}  </math>, then the Lagrangian for null radial [[Geodesics in general relativity|geodesics]] <math>(L=0, \dot\theta=0, \dot\phi=0)</math> of the "retarded(/outgoing)" Vaidya spacetime Eq(6) is
+<math>L=0=-F\dot{u}^2+2\dot{u}\dot{r}\,,</math>
+where dot means derivative with respect to some parameter <math>\lambda</math>. This Lagrangian has two solutions,
+<math>\dot{u}=0\quad\text{and}\quad \dot{r}=\frac{F}{2}\dot{u}\;.</math>
+According to the definition of <math>u</math> in Eq(2), one could find that when <math>t</math> increases, the areal radius <math>r</math> would increase as well for the solution <math>\dot{u}=0</math>, while <math>r</math> would decrease for the solution <math>\dot{r}=\frac{F}{2}\dot{u}</math>. Thus, <math>\dot{u}=0</math> should be recognized as an outgoing solution while <math>\dot{r}=\frac{F}{2}\dot{u}</math> serves as an ingoing solution. Now, we can [[Construction of a complex null tetrad|construct a complex null tetrad]] which is adapted to the outgoing null radial geodesics and employ the [[Newman-Penrose formalism]] for perform a full analysis of the outgoing Vaidya spacetime. Such an outgoing adapted tetrad can be set up as
+<math>l^a=(0,1,0,0)\,,\quad n^a=(1,-\frac{F}{2},0,0)\,,\quad m^a=\frac{1}{\sqrt{2}\,r}(0,0,1,i\,\csc\theta)\,,</math>
+and the dual basis covectors are therefore
+<math>l_a=(-1,0,0,0)\,,\quad n_a=(-\frac{F}{2},-1,0,0)\,,\quad m_a=\frac{r}{\sqrt{2}}(0,0,1,\sin\theta)\,.</math>
+In this null tetrad, the spin coefficients are
+<math>\kappa=\sigma=\tau=0\,,\quad \nu=\lambda=\pi=0\,,\quad \varepsilon=0 </math><br />
+<math>\rho=-\frac{1}{r}\,,\quad \mu=\frac{-r+2M(u)}{2r^2}\,,\quad \alpha=-\beta=\frac{-\sqrt{2}\cot\theta}{4r}\,,\quad \gamma=\frac{M(u)}{2r^2}\,.</math>
+The [[Weyl scalar|Weyl-NP]] and [[Ricci scalars (Newman-Penrose formalism)|Ricci-NP]] scalars are given by
+<math>\Psi_0=\Psi_1=\Psi_3=\Psi_4=0\,,\quad \Psi_2=-\frac{M(u)}{r^3}\,,</math>
+<math>\Phi_{00}=\Phi_{10}=\Phi_{20}=\Phi_{11}=\Phi_{12}=\Lambda=0\,,\quad \Phi_{22}=-\frac{M(u)_{\,,\,u}}{r^2}\,,</math>
+Since the only nonvanishing Weyl-NP scalar is <math>\Psi_2</math>, the "retarded(/outgoing)" Vaidya spacetime is of [[Petrov Type|Petrov-type D]]. Also, there exists a radiation field as <math>\Phi_{22}\neq 0</math>.
+</div>
+</div>
+<div style="clear:both;width:65%;" class="NavFrame collapsed">
+<div class="NavHead" style="background-color:#FFFFFF; text-align:left; font-size:larger;">Box B: Analyses of Schwarzschild metric in an "outgoing" null tetrad </div>
+<div class="NavContent" style="text-align:left;">
+For the "retarded(/outgoing)" Schwarzschild metric Eq(3), let <math>G:=1-\frac{2M}{r}  </math>, and then the Lagrangian for null radial [[Geodesics in general relativity|geodesics]] will have an outgoing solution <math>\dot{u}=0</math> and an ingoing solution <math>\dot{r}=-\frac{G}{2}\dot{u}</math>. Similar to Box A, now set up the adapted outgoing tetrad by
+<math>l^a=(0,1,0,0)\,,\quad n^a=(1,-\frac{G}{2},0,0)\,,\quad m^a=\frac{1}{\sqrt{2}\,r}(0,0,1,i\,\csc\theta)\,,</math>
+<math>l_a=(-1,0,0,0)\,,\quad n_a=(-\frac{G}{2},-1,0,0)\,,\quad m_a=\frac{r}{\sqrt{2}}(0,0,1,\sin\theta)\,.</math>
+so the spin coefficients are
+<math>\kappa=\sigma=\tau=0\,,\quad \nu=\lambda=\pi=0\,,\quad \varepsilon=0 </math><br />
+<math>\rho=-\frac{1}{r}\,,\quad \mu=\frac{-r+2M}{2r^2}\,,\quad \alpha=-\beta=\frac{-\sqrt{2}\cot\theta}{4r}\,,\quad \gamma=\frac{M}{2r^2}\,,</math>
+and the [[Weyl scalar|Weyl-NP]] and [[Ricci scalars (Newman-Penrose formalism)|Ricci-NP]] scalars are given by
+<math>\Psi_0=\Psi_1=\Psi_3=\Psi_4=0\,,\quad \Psi_2=-\frac{M}{r^3}\,,</math>
+<math>\Phi_{00}=\Phi_{10}=\Phi_{20}=\Phi_{11}=\Phi_{12}=\Phi_{22}=\Lambda=0  \,.</math>
+The "retarded(/outgoing)" Schwarzschild spacetime is of [[Petrov Type|Petrov-type D]] with <math>\Psi_2</math> being the only nonvanishing Weyl-NP scalar.
+</div>
+</div>
+==Ingoing Vaidya with pure Absorbing field==
+As for the "advanced/ingoing" Vaidya metric Eq(7),<ref name=Vaidya-1>Eric Poisson. ''A Relativist's Toolkit: The Mathematics of Black-Hole Mechanics.'' Cambridge: Cambridge University Press, 2004. Section 4.3.5 and Section 5.1.8.</ref><ref name=Vaidya-2>Jeremy Bransom Griffiths, Jiri Podolsky. ''Exact Space-Times in Einstein's General Relativity''. Cambridge: Cambridge University Press, 2009. Section 9.5.</ref><ref name=Vaidya-6>Valeri Pavlovich Frolov, Igor Dmitrievich Novikov. ''Black Hole Physics: Basic Concepts and New Developments''. Berlin: Springer, 1998. Section 5.7.</ref> the Ricci tensors again have one nonzero component
+<math>(14)\quad R_{vv}=2\frac{M(v)_{,\,v}}{r^2}\,,</math>
+and therefore <math>R=0</math> and the stress-energy tensor is
+<math>(15)\quad T_{ab} =\frac{M(v)_{,\,v}}{4\pi r^2}\,n_a n_b \;,\qquad n_a dx^a=-dv\;.</math>
+This is a pure radiation field with energy density <math>\frac{M(v)_{,\,v}}{4\pi r^2}</math>, and once again it follows from the null energy condition Eq(11) that <math>M(v)_{,\,v}>0</math>, so the central object is absorbing null dusts. As calculated in Box C, the nonzero Weyl-NP and Ricci-NP components of the "advanced/ingoing" Vaidya metric Eq(7) are
+<math>(16)\quad \Psi_2=-\frac{M(v)}{r^3}\qquad \Phi_{00}=\frac{M(v)_{\,,\,v}}{r^2}\;.</math>
+Also, the outgoing and ingoing null expansion rates for the line element Eq(7) are respectively
+<math>(17)\quad  \theta_{(\ell)}=-(\rho+\bar\rho)=\frac{r-2M(v)}{r^2}\,,\quad \theta_{(n)}=\mu+\bar\mu=-\frac{2}{r}\;.</math>
+The advanced/ingoing Vaidya solution Eq(7) is especially useful in black-hole physics as it's one of the few existing exact dynamical solutions. For example, it is often employed to investigate the differences between different definitions of the dynamical black-hole boundaries, such as the classical [[event horizon]] and the quasilocal trapping horizon; and as shown by Eq(17), the evolutionary hypersurface <math>r=2M(v)</math> is always a marginally outer trapped horizon (<math>\theta_{(\ell)}=0\;, \theta_{(n)}<0</math>).
+<div style="clear:both;width:65%;" class="NavFrame collapsed">
+<div class="NavHead" style="background-color:#FFFFFF; text-align:left; font-size:larger;">Box C: Analyses of Vaidya metric in an "ingoing" null tetrad </div>
+<div class="NavContent" style="text-align:left;">
+Suppose <math>\tilde{F}:=1-\frac{2M(v)}{r}  </math>, then the Lagrangian for null radial [[Geodesics in general relativity|geodesics]] of the "advanced(/ingoing)" Vaidya spacetime Eq(7) is
+<math>L=-\tilde{F}\dot{v}^2+2\dot{v}\dot{r}\,,</math>
+which has an ingoing solution <math>\dot{v}=0</math> and an outgoing solution <math>\dot{r}=\frac{\tilde{F}}{2}\dot{v}</math> in accordance with the definition of <math>v</math> in Eq(4). Now, we can [[Construction of a complex null tetrad|construct a complex null tetrad]] which is adapted to the ingoing null radial geodesics and employ the [[Newman-Penrose formalism]] for perform a full analysis of the Vaidya spacetime. Such an ingoing adapted tetrad can be set up as
+<math>l^a=(1,\frac{\tilde{F}}{2},0,0)\,,\quad n^a=(0,-1,0,0)\,,\quad m^a=\frac{1}{\sqrt{2}\,r}(0,0,1,i\,\csc\theta)\,,</math>
+and the dual basis covectors are therefore
+<math>l_a=(-\frac{\tilde{F}}{2},1,0,0)\,,\quad n_a=(-1,0,0,0)\,,\quad m_a=\frac{r}{\sqrt{2}}(0,0,1,\sin\theta)\,.</math>
+In this null tetrad, the spin coefficients are
+<math>\kappa=\sigma=\tau=0\,,\quad \nu=\lambda=\pi=0\,,\quad \gamma=0 </math><br />
+<math>\rho=\frac{-r+2M(v)}{2r^2}\,,\quad \mu=-\frac{1}{r}\,,\quad \alpha=-\beta=\frac{-\sqrt{2}\cot\theta}{4r}\,,\quad \varepsilon=\frac{M(v)}{2r^2}\,.</math>
+The [[Weyl scalar|Weyl-NP]] and [[Ricci scalars (Newman-Penrose formalism)|Ricci-NP]] scalars are given by
+<math>\Psi_0=\Psi_1=\Psi_3=\Psi_4=0\,,\quad \Psi_2=-\frac{M(v)}{r^3}\,,</math>
+<math>\Phi_{10}=\Phi_{20}=\Phi_{11}=\Phi_{12}=\Phi_{22}=\Lambda=0\,,\quad \Phi_{00}=\frac{M(v)_{\,,\,v}}{r^2}\;.</math>
+Since the only nonvanishing Weyl-NP scalar is <math>\Psi_2</math>, the "advanced(/ingoing)" Vaidya spacetime is of [[Petrov Type|Petrov-type D]], and there exists an radiation field encoded into <math>\Phi_{00}</math>.
+</div>
+</div>
+<div style="clear:both;width:65%;" class="NavFrame collapsed">
+<div class="NavHead" style="background-color:#FFFFFF; text-align:left; font-size:larger;">Box D: Analyses of Schwarzschild metric in an "ingoing" null tetrad </div>
+<div class="NavContent" style="text-align:left;">
+For the "advanced(/ingoing)" Schwarzschild metric Eq(5), still let <math>G:=1-\frac{2M}{r}  </math>, and then the Lagrangian for the null radial [[Geodesics in general relativity|geodesics]] will have an ingoing solution <math>\dot{v}=0</math> and an outgoing solution <math>\dot{r}=\frac{G}{2}\dot{v}</math>. Similar to Box C, now set up the adapted ingoing tetrad by
+<math>l^a=(1,\frac{G}{2},0,0)\,,\quad n^a=(0,-1,0,0)\,,\quad m^a=\frac{1}{\sqrt{2}\,r}(0,0,1,i\,\csc\theta)\,,</math>
+<math>l_a=(-\frac{G}{2},1,0,0)\,,\quad n_a=(-1,0,0,0)\,,\quad m_a=\frac{r}{\sqrt{2}}(0,0,1,\sin\theta)\,.</math>
+so the spin coefficients are
+<math>\kappa=\sigma=\tau=0\,,\quad \nu=\lambda=\pi=0\,,\quad \gamma=0 </math><br />
+<math>\rho=\frac{-r+2M}{2r^2}\,,\quad \mu=-\frac{1}{r}\,,\quad \alpha=-\beta=\frac{-\sqrt{2}\cot\theta}{4r}\,,\quad \varepsilon=\frac{M}{2r^2}\,,</math>
+and the [[Weyl scalar|Weyl-NP]] and [[Ricci scalars (Newman-Penrose formalism)|Ricci-NP]] scalars are given by
+<math>\Psi_0=\Psi_1=\Psi_3=\Psi_4=0\,,\quad \Psi_2=-\frac{M}{r^3}\,,</math>
+<math>\Phi_{00}=\Phi_{10}=\Phi_{20}=\Phi_{11}=\Phi_{12}=\Phi_{22}=\Lambda=0  \,.</math>
+The "advanced(/ingoing)" Schwarzschild spacetime is of [[Petrov Type|Petrov-type D]] with <math>\Psi_2</math> being the only nonvanishing Weyl-NP scalar.
+</div>
+</div>
+==Comparison with the Schwarzschild metric==
+As a natural and simplest extension of the Schwazschild metric, the Vaidya metric still has a lot in common with it:
+* Both metrics are of [[Petrov Type|Petrov-type D]] with <math>\Psi_2</math> being the only nonvanishing [[Weyl scalar|Weyl-NP scalar]] (as calculated in Boxes A and B).
+However, there are three clear differences between the [[Schwarzschild metric|Schwarzschild]] and Vaidia metric:
+* First of all, the mass parameter <math>M</math> for Schwarzschild is a constant, while for Vaidya <math>M(u)</math> is a u-dependent function.
+* Schwarzschild is a solution to the vacuum Einstein equation <math>R_{ab}=0</math>, while Vaidya is solution is to the trace-free Einstein equation <math>R_{ab}=8\pi T_{ab}</math> with a nontrivial pure radiation energy field. As a result, all Ricci-NP scalars for Schwarzschild are vanishing, while we have <math>\Phi_{00}=\frac{M(u)_{\,,\,u}}{r^2}</math> for Vaidya.
+* Schwarzschild has 4 independent [[Killing vector field]]s, including a timelike one, and thus is a static metric, while Vaidya has only 3 independent Killing vector fields regarding the spherical symmetry, and consequently is nonstatic. Consequently, the Schwarzschild metric belongs to [[Weyl metrics|Weyl's class of solutions]] while the Vaidya metric is not.
+==Extension of the Vaidya metric==
+===Kinnersley metric===
+While the Vaidya metric is an extension of the Schwarzschild metric to include a pure radiation field, the [[Kinnersley metric]] constitutes a further extension of the Vaidya metric.
+===Vaidya-Bonner metric===
+Since the radiated or absorbed matter might be electrically non-neutral, the outgoing and ingoing Vaidya metrics Eqs(6)(7) can be naturally extended to include varying electric charges,
+<math>(18)\quad ds^2=-\Big( 1-\frac{2M(u)}{r}+\frac{Q(u)}{r^2} \Big) du^2-2dudr+r^2(d\theta^2+\sin^2\theta\,d\phi^2)\;,</math>
+<math>(19)\quad ds^2=-\Big( 1-\frac{2M(v)}{r}+\frac{Q(v)}{r^2} \Big) dv^2+2dvdr+r^2(d\theta^2+\sin^2\theta\,d\phi^2)\;.</math>
+Eqs(18)(19) are called the Vaidya-Bonner metrics, and apparently, they can also be regarded as extensions of the [[Reissner-Nordström metric]], as opposed to the corresponce between Vaidya and Schwarzschild metrics.
+== See also ==
+*[[Schwarzschild metric]]
+*[[Null dust solution]]
+==References==
+{{reflist}}
+[[Category:Exact solutions in general relativity]]
+[[Category:Black holes]]
+[[Category:Astrophysics]]

Equilateral dimension: Difference between revisions

Latest revision as of 08:59, 22 November 2013

From Schwarzschild to Vaidya metrics

Outgoing Vaidya with pure Emitting field

Ingoing Vaidya with pure Absorbing field

Comparison with the Schwarzschild metric

Extension of the Vaidya metric

Kinnersley metric

Vaidya-Bonner metric

See also

References

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