Einstein Field Equations: Spherical Symmetry Solution

In summary, the conversation discusses the possibility of solving the Einstein Field Equation (EFE) for a spherically symmetric spacetime by writing the components of the Energy-Momentum Tensor (SET) in terms of a single coordinate. It is suggested that this could be achieved by assuming spherical symmetry for the metric and specifying two arbitrary functions for two components of the Einstein tensor, which would determine the remaining components. However, it is noted that this approach may not lead to a unique solution and the minimum number of independent functions required for a unique solution is five. The possibility of eliminating one of the three metric functions by assuming a specific type of coordinate system is also mentioned.
  • #1
PAllen
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[Moderator's Note: Thread spin off due to topic and level change.]

For a spherically symmetric solution, if SET components were written in terms a single one of 4 coordinates, in a way plausible for a radial coordinate, the I believe solving the EFE would require spherical symmetry of the metric up to possible implausible noise terms (producing some Weyl curvature).
 
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  • #2
PAllen said:
if SET components were written in terms a single one of 4 coordinates, in a way plausible for a radial coordinate, then I believe solving the EFE would require spherical symmetry of the metric
You couldn't tell if it were truly a radial coordinate without knowing the metric. Plenty of functions of one variable might look "plausible for a radial coordinate" without actually requiring spherical symmetry (one obvious alternative is just axial symmetry, i.e., cylindrical instead of spherical).

PAllen said:
up to possible implausible noise terms (producing some Weyl curvature).
You seem to be implying that perfect spherical symmetry rules out Weyl curvature. That's obviously false since Schwarzschild spacetime has nonzero Weyl curvature.
 
  • #3
PeterDonis said:
You couldn't tell if it were truly a radial coordinate without knowing the metric. Plenty of functions of one variable might look "plausible for a radial coordinate" without actually requiring spherical symmetry (one obvious alternative is just axial symmetry, i.e., cylindrical instead of spherical).
That could be ruled out by coordinate conditions, not metric conditions per se. Though, I see, that they would only have effect when resolving the metric.
PeterDonis said:
You seem to be implying that perfect spherical symmetry rules out Weyl curvature. That's obviously false since Schwarzschild spacetime has nonzero Weyl curvature.
I guess I wasn’t clear. What I meant was that a metric that produces asymmetric Weyl curvature while producing spherically symmetric Ricci curvature would be allowed by the EFE. My suspicion is that this would happen due extra metric terms that look artificial and could be readily removed.

[edit: I wonder if imposing spherical symmetry via coordinate definition on both the Weyl tensor and the Ricci tensor (or Einstein tensor), would force spherical symmetry on the metric]
 
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  • #4
It occurs to me, on review of material in Synge, 1960, that on the assumption of spherical symmetry, one can specify two arbitrary functions for just two components of the Einstein tensor (rr and tt), and all other components of the Einstein tensor and the metric follow. Thus, if you simply assume spherical symmetry for the spacetime, you can just pick two functions for two components of the SET, and derive everything else. They can even be time dependent functions.
 
  • #5
PAllen said:
if you simply assume spherical symmetry for the spacetime, you can just pick two functions for two components of the SET, and derive everything else.
Not in the general case, no. The most general spherically symmetric Einstein tensor (and hence SET) has three independent diagonal components, not two; the tangential components have to be equal, but they do not have to be the same as the radial one. In order to get the number of independent diagonal components down to two, you need to assume something like a perfect fluid (isotropy of pressure).

Also, as has already been noted, just specifying these three independent functions for the three independent diagonal components of the SET does not specify a unique solution. I believe the minimum number of independent functions required for a unique solution is five: two metric functions (how exactly they appear in the metric can vary, but a common way of specifying them is to specify ##g_{tt}## and the "mass function" ##m##, which makes ##g_{rr}## take the form ##1 / (1 - 2m / r)## in Schwarzschild coordinates) and the three SET functions described above (which can be thought of as energy density, radial pressure, and tangential pressure). These functions are related by three differential equations, arising from the Einstein Field Equation, but those equations do not, I believe, reduce the freedom to specify functions any further in the general case (i.e., nothing else specified by spherical symmetry, no specification of perfect fluid, etc.).

I believe MTW has a discussion of this but I can't find it at present.
 
  • #6
PeterDonis said:
Not in the general case, no. The most general spherically symmetric Einstein tensor (and hence SET) has three independent diagonal components, not two; the tangential components have to be equal, but they do not have to be the same as the radial one. In order to get the number of independent diagonal components down to two, you need to assume something like a perfect fluid (isotropy of pressure).

Also, as has already been noted, just specifying these three independent functions for the three independent diagonal components of the SET does not specify a unique solution. I believe the minimum number of independent functions required for a unique solution is five: two metric functions (how exactly they appear in the metric can vary, but a common way of specifying them is to specify ##g_{tt}## and the "mass function" ##m##, which makes ##g_{rr}## take the form ##1 / (1 - 2m / r)## in Schwarzschild coordinates) and the three SET functions described above (which can be thought of as energy density, radial pressure, and tangential pressure). These functions are related by three differential equations, arising from the Einstein Field Equation, but those equations do not, I believe, reduce the freedom to specify functions any further in the general case (i.e., nothing else specified by spherical symmetry, no specification of perfect fluid, etc.).

I believe MTW has a discussion of this but I can't find it at present.
You can eliminate one of the three metric functions by assuming a specific type of coordinate system. This does not reduce the generality of physics representable. Synge then derives explicit equations relating the two remaining metric functions to just two components of the Einstein tensor. Either can be determined from the other. He also derives the rest of the Einstein tensor from the two chosen arbitrarily. All of these functions may allow time as well as radial coordinate. This is one area where I find MTW seriously deficient. Not only does it discuss spherical symmetry with less completeness than Synge, it has no general discussion of axial symmetry at all. Wald, on the other hand, has the same material on axial symmetry as Synge, expressed in more modern formalism.
 
  • #7
PAllen said:
You can eliminate one of the three metric functions by assuming a specific type of coordinate system.
Yes, I know, that's why I said you only have two independent functions in the metric. You have three in the SET (actually possibly four, see below on the nonzero off diagonal term).

PAllen said:
Synge then derives explicit equations relating the two remaining metric functions to just two components of the Einstein tensor.
I'm not familiar with Synge's derivation, but as I've already said, I'm not sure how there could be only two independent components of the Einstein tensor, since tangential and radial pressures do not have to be the same.

Also, now I come to think of it, if ##dm / dt## is nonzero, I'm not even sure the Einstein tensor has to be diagonal. The basic metric ansatz would be something like:

$$
ds^2 = - J(r, t) dt^2 + \frac{dr^2}{1 - \frac{2 m(r, t)}{r}} + r^2 d\Omega^2
$$

Plugging this into Maxima gives a nonzero off diagonal component ##G_{tr} = G_{rt}## for the Einstein tensor.
 
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  • #8
PeterDonis said:
Yes, I know, that's why I said you only have two independent functions in the metric. You have three in the SET.I'm not familiar with Synge's derivation, but as I've already said, I'm not sure how there could be only two independent components of the Einstein tensor, since tangential and radial pressures do not have to be the same.

Also, now I come to think of it, if ##dm / dt## is nonzero, I'm not even sure the Einstein tensor has to be diagonal. The basic metric ansatz would be something like:

$$
ds^2 = - J(r, t) dt^2 + \frac{dr^2}{1 - \frac{2 m(r, t)}{r}} + r^2 d\Omega^2
$$

Plugging this into Maxima gives a nonzero off diagonal component ##G_{tr} = G_{rt}## for the Einstein tensor.
The key is that these components are not independent. Synge derives formulas for the off diagonal components of the Einstein tensor in terms of just two of the diagonal components. There is also a possible theta,theta and phi,phi component of the Einstein tensor( these are equal to each other) that is derivable from the rr and tt components. So it remains true that you can choose just these two SET components, assume spherical symmetry, and derive everything else.

I thought, at some point, you had acquired a copy of Synge. The relevant pages are 270 to 274. I would be loathe to present 4 pages of terse derivation here.

[edit: you really do want to read from page 270, even though the main derivation is on 273, because he introduces a very odd notation for partial derivatives, used just in this section; the motivation is to save some ink]
 
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  • #9
PAllen said:
I thought, at some point, you had acquired a copy of Synge.
I think I have one somewhere, but it's not handy at the moment. If I can find it I'll take a look.
 
  • #10
PAllen said:
Synge derives formulas for the off diagonal components of the Einstein tensor in terms of just two of the diagonal components. There is also a possible theta,theta and phi,phi component of the Einstein tensor( these are equal to each other) that is derivable from the rr and tt components.
Is Synge using the covariant divergence equations? I had not taken those into account in my earlier posts, but yes, those are additional constraints that can reduce the number of independent functions.
 
  • #11
PeterDonis said:
Is Synge using the covariant divergence equations? I had not taken those into account in my earlier posts, but yes, those are additional constraints that can reduce the number of independent functions.
Yes, he uses the covariant divergence equations to get the tangential components in term of all the others (that is theta,theta in terms of rr, tt, and rt). Before this he uses clever integrations to invert rr and tt Einstein tensor components in terms of metric functions (that is, getting the two metric functions in terms of these Einstein components). Then these inversions are used to get the off diagonal Einstein components in terms the diagonal components. Altogether very slick IMO.
 

FAQ: Einstein Field Equations: Spherical Symmetry Solution

What are the Einstein Field Equations?

The Einstein Field Equations are a set of ten equations in general relativity that describe the relationship between the curvature of spacetime and the distribution of matter and energy within it. They were developed by Albert Einstein in 1915.

What is "spherical symmetry" in the context of Einstein Field Equations?

Spherical symmetry is a property of a physical system in which the distribution of matter and energy is symmetric around a central point, like a sphere. In the context of Einstein Field Equations, it means that the equations can be solved for a system that has this type of symmetry.

Why is the "spherical symmetry solution" important?

The spherical symmetry solution is important because it allows for the calculation of the gravitational field around a spherically symmetric object, such as a planet or star. This solution is also used in the study of black holes and cosmology.

How is the "spherical symmetry solution" derived?

The spherical symmetry solution is derived by inserting the assumption of spherical symmetry into the Einstein Field Equations and solving for the resulting equations. This solution was first derived by Karl Schwarzschild in 1916 and is known as the Schwarzschild metric.

What are some real-world applications of the "spherical symmetry solution"?

The spherical symmetry solution has many real-world applications, including in the study of gravitational waves, black holes, and the structure of the universe. It is also used in the development of accurate models for planetary motion and in the prediction of the behavior of stars and galaxies.

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