The Komar mass (named after Arthur Komar[1]) of a system is one of several formal concepts of mass that are used in general relativity. The Komar mass can be defined in any stationary spacetime, which is a spacetime in which all the metric components can be written so that they are independent of time. Alternatively, a stationary spacetime can be defined as a spacetime which possesses a timelike Killing vector field.
The following discussion is an expanded and simplified version of the motivational treatment in (Wald, 1984, pg 288).
Consider the Schwarzschild metric. Using the Schwarzschild basis, a frame field for the Schwarzschild metric, one can find that the radial acceleration required to hold a test mass stationary at a Schwarzschild coordinate of r is:
a\hat{r}=
m | |||||||||
|
Because the metric is static, there is a well-defined meaning to "holding a particle stationary".
Interpreting this acceleration as being due to a "gravitational force", we can then compute the integral of normal acceleration multiplied by area to get a "Gauss law" integral of:
4\pim | |||||
|
While this approaches a constant as r approaches infinity, it is not a constant independent of r. We are therefore motivated to introduce a correction factor to make the above integral independent of the radius r of the enclosing shell. For the Schwarzschild metric, this correction factor is just
\sqrt{gtt
To proceed further, we will write down a line element for a static metric.
ds2=gttdt2+quadratic form(dx,dy,dz)
where
gtt
dxdt
Because of the simplifying assumption that some of the metric coefficients are zero, some of our results in this motivational treatment will not be as general as they could be.
In flat space-time, the proper acceleration required to hold station is
du/d\tau
\tau
ab=\nablauub=uc\nablacub
ab=uc\nablacub
where
ub
ubub=-1.
The component of the acceleration vector normal to the surface is
anorm=Nbab
where Nb is a unit vector normal to the surface.
In a Schwarzschild coordinate system, for example, we find that
Nbab=
| ||||||
2gtt\sqrt{grr |
as expected - we have simply re-derived the previous results presented in a frame-field in a coordinate basis.
We define
ainf=\sqrt{gtt
so that in our Schwarzschild example:
Nbainf=m/r2.
We can, if we desire, derive the accelerations
ab
ainf
ab=\nablabZ1 Z1=ln{gtt
ainf=\nablabZ2 Z2=\sqrt{gtt
We will demonstrate that integrating the normal component of the "acceleration at infinity"
ainf
m=-
1 | |
4\pi |
\intANbainf dA
To make this demonstration, we need to express this surface integral as a volume integral. In flat space-time, we would use Stokes theorem and integrate
-\nabla ⋅ ainf
Using the formulas for electromagnetism in curved space-time as a guide, we write instead.
Fab=ainfub-ainfua
where F plays a role similar to the "Faraday tensor", in that
ainf=Fabub
\nablaaFabub
An alternate approach would be to use differential forms, but the approach above is computationally more convenient as well as not requiring the reader to understand differential forms.
A lengthy, but straightforward (with computer algebra) calculation from our assumed line element shows us that
-ub\nablaaFab=\sqrt{gtt
Thus we can write
m=
\sqrt{gtt | |
In any vacuum region of space-time, all components of the Ricci tensor must be zero. This demonstrates that enclosing any amount of vacuum will not change our volume integral. It also means that our volume integral will be constant for any enclosing surface, as long as we enclose all of the gravitating mass inside our surface. Because Stokes theorem guarantees that our surface integral is equal to the above volume integral, our surface integral will also be independent of the enclosing surface as long as the surface encloses all of the gravitating mass.
By using Einstein's Field Equations
u{} | |
G | |
v |
=
u{} | |
R | |
v |
-
1 | |
2 |
R
u{} | |
I | |
v |
=8\pi
u{} | |
T | |
v |
letting u=v and summing, we can show that
R=-8\piT.
This allows us to rewrite our mass formula as a volume integral of the stress–energy tensor.
m=\intV\sqrt{gtt
where
To make the formula for Komar mass work for a general stationary metric, regardless of the choice of coordinates, it must be modified slightly. We will present the applicable result from (Wald, 1984 eq 11.2.10) without a formal proof.
m=\intV\left(2Tab-Tgab\right)ua\xibdV,
where
\xib
\xia\xia=-1
Note that
\xib
\sqrt{gtt
If none of the metric coefficients
gab
\xia=(1,0,0,0).
While it is not necessary to choose coordinates for a stationary space-time such that the metric coefficients are independent of time, it is often convenient.
When we chose such coordinates, the time-like Killing vector for our system
\xia
ua,
\xia=Kua.
m=\intV\left(2T00-Tg00\right)KdV
Because
ua
\xib
a\xi | |
\sqrt{-\xi | |
a} |
Evaluating the "red-shift" factor K based on our knowledge of the components of
\xia
\sqrt{gtt
If we chose our spatial coordinates so that we have a locally Minkowskian metric
gab=ηab
g00=-1,T=-T00+T11+T22+T33
With these coordinate choices, we can write our Komar integral as
m=\intV\sqrt{-\xia\xia}\left(T00+T11+T22+T33\right)dV
While we can't choose a coordinate system to make a curved space-time globally Minkowskian, the above formula provides some insight into the meaning of the Komar mass formula. Essentially, both energy and pressure contribute to the Komar mass. Furthermore, the contribution of local energy and mass to the system mass is multiplied by the local "red shift" factor
K=\sqrt{gtt
We also wish to give the general result for expressing the Komar mass as a surface integral.
The formula for the Komar mass in terms of the metric and its Killing vector is (Wald, 1984, pg 289, formula 11.2.9)
m=-
1 | |
8\pi |
\intS\epsilonabcd\nablac\xid
where
\epsilonabcd
\xid
\xia\xia=-1
The surface integral above is interpreted as the "natural" integral of a two form over a manifold.
As mentioned previously, if none of the metric coefficients
gab
\xia=\left(1,0,0,0\right)