In the theory of Lorentzian manifolds, spherically symmetric spacetimes admit a family of nested round spheres. There are several different types of coordinate chart which are adapted to this family of nested spheres; the best known is the Schwarzschild chart, but the isotropic chart is also often useful.The defining characteristic of an isotropic chart is that its radial coordinate (which is different from the radial coordinate of a Schwarzschild chart) is defined so that light cones appear round. This means that (except in the trivial case of a locally flat manifold), the angular isotropic coordinates do not faithfully represent distances within the nested spheres, nor does the radial coordinate faithfully represent radial distances. On the other hand, angles in the constant time hyperslices are represented without distortion, hence the name of the chart.
Isotropic charts are most often applied to static spherically symmetric spacetimes in metric theories of gravitation such as general relativity, but they can also be used in modeling a spherically pulsating fluid ball, for example. For isolated spherically symmetric solutions of the Einstein field equation, at large distances, the isotropic and Schwarzschild charts become increasingly similar to the usual polar spherical chart on Minkowski spacetime.
In an isotropic chart (on a static spherically symmetric spacetime), the metric (aka line element) takes the form
g=-a(r)2dt2+b(r)2\left(dr2+r2\left(d\theta2+\sin(\theta)2d\varphi2\right)\right),
-infty<t<infty,r0<r<r1,0<\theta<\pi,-\pi<\varphi<\pi
Depending on context, it may be appropriate to regard
a,b
The Lie algebra of Killing vector fields of a spherically symmetric static spacetime takes the same form in the isotropic chart as in the Schwarzschild chart. Namely, this algebra is generated by the timelike irrotational Killing vector field
\partialt
\partial\varphi
\sin(\varphi)\partial\theta+\cot(\theta)\cos(\varphi)\partial\varphi
\cos(\varphi)\partial\theta-\cot(\theta)\sin(\varphi)\partial\varphi
\vec{X}=\partialt
t=t0
Unlike the Schwarzschild chart, the isotropic chart is not well suited for constructing embedding diagrams of these hyperslices.
The surfaces
t=t0,r=r0
| g| | |
| t=t0,r=r0 |
=
| 2 | |
| b(r | |
| 0) |
| 2g | |
| r | |
| \Omega |
=
| 2 | |
| b(r | |
| 0) |
| 2 | |
| r | |
| 0 |
\left(d\theta2+\sin(\theta)2d\varphi2\right), 0<\theta<\pi,-\pi<\varphi<\pi
\Omega=(\theta,\varphi)
g\Omega
b(r0)r
r
The loci
\varphi=-\pi,\pi
Just as for the Schwarzschild chart, the range of the radial coordinate may be limited if the metric or its inverse blows up for some value(s) of this coordinate.
The line element given above, with f,g, regarded as undetermined functions of the isotropic 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 sketch 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=b(r)rd\theta
\sigma3=b(r)r\sin(\theta)d\varphi
a,b
r
| 0} | |
| {\omega | |
| 1 |
=
| f'dt | |
| g |
| 1} | |
| {\omega | |
| 2 |
=-\left(1+
| rb' | |
| b |
\right)d\theta
| 1} | |
| {\omega | |
| 3 |
=-\left(1+
| rb' | |
| b |
\right)\sin(\theta)d\varphi
| 2} | |
| {\omega | |
| 3 |
=-\cos(\theta)d\varphi