In the theory of Lorentzian manifolds, spherically symmetric spacetimes admit a family of nested round spheres. In such a spacetime, a particularly important kind of coordinate chart is the Schwarzschild chart, a kind of polar spherical coordinate chart on a static and spherically symmetric spacetime, which is adapted to these nested round spheres. The defining characteristic of Schwarzschild chart is that the radial coordinate possesses a natural geometric interpretation in terms of the surface area and Gaussian curvature of each sphere. However, radial distances and angles are not accurately represented.
These charts have many applications in metric theories of gravitation such as general relativity. They are most often used in static spherically symmetric spacetimes. In the case of general relativity, Birkhoff's theorem states that every isolated spherically symmetric vacuum or electrovacuum solution of the Einstein field equation is static, but this is certainly not true for perfect fluids. The extension of the exterior region of the Schwarzschild vacuum solution inside the event horizon of a spherically symmetric black hole is not static inside the horizon, and the family of (spacelike) nested spheres cannot be extended inside the horizon, so the Schwarzschild chart for this solution necessarily breaks down at the horizon.
g
In a Schwarzschild chart (on a static spherically symmetric spacetime), the line element takes the form
g=-a(r)2dt2+b(r)2dr2+r2\left(d\theta2+\sin2\thetad\phi2\right)=-a(r)2dt2+b(r)2dr2+r2g\Omega
-infty<t<infty,r0<r<r1,0<\theta<\pi,-\pi<\phi<\pi
\Omega=(\theta,\phi)
g\Omega
Depending on context, it may be appropriate to regard a and b as undetermined functions of the radial coordinate (for example, in deriving an exact static spherically symmetric solution of the Einstein field equation). Alternatively, we can plug in specific functions (possibly depending on some parameters) to obtain a Schwarzschild coordinate chart on a specific Lorentzian spacetime.
If this turns out to admit a stress–energy tensor such that the resulting model satisfies the Einstein field equation (say, for a static spherically symmetric perfect fluid obeying suitable energy conditions and other properties expected of reasonable perfect fluid), then, with appropriate tensor fields representing physical quantities such as matter and momentum densities, we have a piece of a possibly larger spacetime; a piece which can be considered a local solution of the Einstein field equation.
With respect to the Schwarzschild chart, the Lie algebra of Killing vector fields is generated by the timelike irrotational Killing vector field
\partialt
\partial\phi
\sin\phi\partial\theta+\cot\theta\cos\phi\partial\phi
\cos\phi\partial\theta-\cot\theta\sin\phi\partial\phi
\vec{X}=\partialt
t=t0
Note the last two fields are rotations of one-another, under the coordinate transformation
\phi\mapsto\phi+\pi/2
In the Schwarzschild chart, the surfaces
t=t0,r=r0
| g| | |
| t=t0,r=r0 |
=
| 2 | |
| r | |
| 0 |
g\Omega=
| 2 | |
| r | |
| 0 |
\left(d\theta2+\sin2\thetad\phi2\right), 0<\theta<\pi, -\pi<\phi<\pi
g\Omega
A=4\pi
| 2 | |
| r | |
| 0 |
K=
| 2 | |
| 1/r | |
| 0 |
\Omega=(\theta,\phi)
\theta
\phi
It may help to add that the four Killing fields given above, considered as abstract vector fields on our Lorentzian manifold, give the truest expression of both the symmetries of a static spherically symmetric spacetime, while the particular trigonometric form which they take in our chart is the truest expression of the meaning of the term Schwarzschild chart. In particular, the three spatial Killing vector fields have exactly the same form as the three nontranslational Killing vector fields in a spherically symmetric chart on E3; that is, they exhibit the notion of arbitrary Euclidean rotation about the origin or spherical symmetry.
However, note well: in general, the Schwarzschild radial coordinate does not accurately represent radial distances, i.e. distances taken along the spacelike geodesic congruence which arise as the integral curves of
\partialr
b(r)dr
\Delta\rho=
| r2 | |
| \int | |
| r1 |
b(r)dr
Similarly, we can regard each sphere as the locus of a spherical cloud of idealized observers, who must (in general) use rocket engines to accelerate radially outward in order to maintain their position. These are static observers, and they have world lines of form
r=r0,\theta=\theta0,\phi=\phi0
In order to compute the proper time interval between two events on the world line of one of these observers, we must integrate
a(r)dt
\Delta\tau=
| t2 | |
| \int | |
| t1 |
a(r)dt
Looking back at the coordinate ranges above, note that the coordinate singularity at
t=t0,r=r0,\theta=0
t=t0,r=r0,\theta=\pi
\phi=0
t=t0
r=0
When we said above that
\partial\phi
\phi
Possibly, of course,
r1>0
r2<infty
To better understand the significance of the Schwarzschild radial coordinate, it may help to embed one of the spatial hyperslices
t=t0
t=0,\theta=\pi/2
g|t=b(r)2dr2+r2d\phi2, r1<r<r2,-\pi<\phi<\pi
f(r)
(z,r,\phi) → (f(r),r\cos\phi,r\sin\phi)
\partialr=(f\prime(r),\cos\phi,\sin\phi), \partial\phi=(0,-r\sin\phi,r\cos\phi)
d\rho2=\left(1+f\prime(r)2\right)dr2+r2d\phi2, r1<r<r2,-\pi<\phi<\pi
f(r)
f\prime(r)=\sqrt{1-b(r)2}
b(r)=f(r)=\sin(r)
This works for surfaces in which true distances between two radially separated points are larger than the difference between their radial coordinates. If the true distances are smaller, we should embed our Riemannian manifold as a spacelike surface in E1,2 instead. For example, we might have
b(r)=f(r)=\sinh(r)
The point is that the defining characteristic of a Schwarzschild chart in terms of the geometric interpretation of the radial coordinate is just what we need to carry out (in principle) this kind of spherically symmetric embedding of the spatial hyperslices.
The line element given above, with f,g regarded as undetermined functions of the Schwarzschild radial coordinate r, is often used as a metric ansatz in deriving static spherically symmetric solutions in general relativity (or other metric theories of gravitation).
As an illustration, we will indicate how to compute the connection and curvature using Cartan's exterior calculus method. First, we read off the line element a coframe field,
\sigma0=-a(r)dt
\sigma1=b(r)dr
\sigma2=rd\theta
\sigma3=r\sin\thetad\phi
ab
r
Second, we compute the exterior derivatives of these cobasis one-forms:
d\sigma0=-a'(r)dr\wedgedt=
| a'(r) | |
| b(r) |
dt\wedge\sigma1
d\sigma1=0
d\sigma2=dr\wedged\theta
d\sigma3=\sin\thetadr\wedged\phi+r\cos\thetad\theta\wedged\phi=-\left(
| \sin\thetad\phi | |
| b(r) |
\wedge\sigma1+\cos\thetad\phi\wedge\sigma2\right)
d\sigma\hat{m}=
| \hat{m}} | |
| -{\omega | |
| \hat{n} |
\wedge\sigma\hat{n}
dt,dr,d\theta,d\phi
If we recall which pairs of indices are symmetric (space-time) and which are antisymmetric (space-space) in
| \hat{m}} | |
| {\omega | |
| \hat{n} |
| 0} | |
| {\omega | |
| 1 |
=
| a' | |
| b |
(r)dt
| 0} | |
| {\omega | |
| 2 |
=0
| 0} | |
| {\omega | |
| 3 |
=0
| 1} | |
| {\omega | |
| 2 |
=-
| d\theta | |
| b(r) |
| 1} | |
| {\omega | |
| 3 |
=-
| \sin\thetad\phi | |
| b(r) |
| 2} | |
| {\omega | |
| 3 |
=-\cos\thetad\phi
Third, we compute the exterior derivatives of the connection one-forms and use Cartan's second structural equation
| \hat{m}} | |
| {\Omega | |
| \hat{n} |
=
| \hat{m}} | |
| d{\omega | |
| \hat{n} |
-
| \hat{m}} | |
| {\omega | |
| \hat{\ell} |
\wedge
| \hat{\ell}} | |
| {\omega | |
| \hat{n} |
| \hat{m}} | |
| {\Omega | |
| \hat{n} |
=
| \hat{m}} | |
| {R | |
| \hat{n |
|\hat{\imath}\hat{\jmath}|}\sigma\hat{\imath}\wedge\sigma\hat{\jmath}
| 0} | |
| {R | |
| 101 |
=
| -a''b+a'b' | |
| ab3 |
(r)
| 0} | |
| {R | |
| 202 |
=
| 1 | |
| r |
| -a' | |
| ab2 |
(r)=
| 0} | |
| {R | |
| 303 |
| 1} | |
| {R | |
| 212 |
=
| 1 | |
| r |
| b' | |
| b3 |
(r)=
| 1} | |
| {R | |
| 313 |
| 2} | |
| {R | |
| 323 |
=
| 1 | |
| r2 |
| b2-1 | |
| b2 |
(r)
Fifth, we can lower indices and organize the components
R\hat{m\hat{n}\hat{i}\hat{j}}
\left[\begin{matrix}R0101&R0102&R0103&R0123&R0131&R0112\ R0201&R0202&R0203&R0223&R0231&R0212\ R0301&R0302&R0303&R0323&R0331&R0312\ R2301&R2302&R2303&R2323&R2331&R2312\ R3101&R3102&R3103&R3123&R3131&R3112\ R1201&R1202&R1203&R1223&R1231&R1212\end{matrix}\right]=\left[\begin{matrix}E&B\ BT&L\end{matrix}\right]
\vec{X}=\vec{e}0=
| 1 | |
| a(r) |
\partialt
E[\vec{X}]11=
| a''b-a'b' | |
| ab3 |
(r), E[\vec{X}]22=E[\vec{X}]33=
| 1 | |
| r |
| a' | |
| ab2 |
(r)
\vec{X}
L[\vec{X}]11=
| 1 | |
| r2 |
| 1-b2 | |
| b2 |
(r), L[\vec{X}]22=L[\vec{X}]33=
| 1 | |
| r |
| -b' | |
| b3 |
(r)
This is all valid for any Lorentzian manifold, but we note that in general relativity, the electrogravitic tensor controls tidal stresses on small objects, as measured by the observers corresponding to our frame, and the magnetogravitic tensor controls any spin-spin forces on spinning objects, as measured by the observers corresponding to our frame.
The dual frame field of our coframe field is
\vec{e}0=
| 1 | |
| a(r) |
\partialt
\vec{e}1=
| 1 | |
| b(r) |
\partialr
\vec{e}2=
| 1 | |
| r |
\partial\theta
\vec{e}3=
| 1 | |
| r\sin\theta |
\partial\phi
| 1 | |
| b(r) |
Some examples of exact solutions which can be obtained in this way include:
It is natural to consider nonstatic but spherically symmetric spacetimes, with a generalized Schwarzschild chart in which the metric takes the form
g=-a(t,r)2dt2+b(t,r)2dr2+r2\left(d\theta2+\sin2\thetad\phi2\right),
-infty<t<infty,r0<r<r1,0<\theta<\pi,-\pi<\phi<\pi
Generalizing in another direction, we can use other coordinate systems on our round two-spheres, to obtain for example a stereographic Schwarzschild chart which is sometimes useful:
g=-a(r)2dt2+b(r)2dr2+
| dx2+dy2 | |
| (1+x2+y2)2 |
, -infty<t,x,y<infty,r1<r<r2
\vec{X}
\partialt
\partialx
\partial/\partialx