The interior Schwarzschild metric is framed in a spherical coordinate system with the body's centre located at the origin, plus the time coordinate. Its line element is^[2][3]

${\displaystyle c^{2}{d\tau }^{2}=-{\frac {1}{4}}\left(3{\sqrt {1-{\frac {r_{s}}{r_{g}}}}}-{\sqrt {1-{\frac {r^{2}r_{s}}{r_{g}^{3}}}}}\right)^{2}c^{2}dt^{2}+\left(1-{\frac {r^{2}r_{s}}{r_{g}^{3}}}\right)^{-1}dr^{2}+r^{2}\left(d\theta ^{2}+\sin ^{2}\theta \,d\varphi ^{2}\right),}$ 

where

• ${\displaystyle \tau }$  is the proper time (time measured by a clock moving along the same world line with the test particle).
• ${\displaystyle c}$  is the speed of light.
• ${\displaystyle t}$  is the time coordinate (measured by a stationary clock located infinitely far from the spherical body).
• ${\displaystyle r}$  is the Schwarzschild radial coordinate. Each surface of constant ${\displaystyle t}$  and ${\displaystyle r}$  has the geometry of a sphere with measurable (proper) circumference ${\displaystyle 2\pi r}$  and area ${\displaystyle 4\pi r^{2}}$  (as by the usual formulas), but the warping of space means the proper distance from each shell to the center of the body is greater than ${\displaystyle r}$ .
• ${\displaystyle \theta }$  is the colatitude (angle from north, in units of radians).
• ${\displaystyle \varphi }$  is the longitude (also in radians).
• ${\displaystyle r_{s}}$  is the Schwarzschild radius of the body, which is related to its mass ${\displaystyle M}$  by ${\displaystyle r_{s}=2GM/c^{2}}$ , where ${\displaystyle G}$  is the gravitational constant. (For ordinary stars and planets, this is much less than their proper radius.)
• ${\displaystyle r_{g}}$  is the value of the ${\displaystyle r}$ -coordinate at the body's surface. (This is less than its proper (measurable interior) radius, although for the Earth the difference is only about 1.4 millimetres.)

This solution is valid for ${\displaystyle r\leq r_{g}}$ . For a complete metric of the sphere's gravitational field, the interior Schwarzschild metric has to be matched with the exterior one,

${\displaystyle -c^{2}{d\tau }^{2}=\left(1-{\frac {r_{s}}{r}}\right)c^{2}dt^{2}-\left(1-{\frac {r_{s}}{r}}\right)^{-1}dr^{2}-r^{2}\left(d\theta ^{2}+\sin ^{2}\theta \,d\varphi ^{2}\right),}$ 

at the surface. It can easily be seen that the two have the same value at the surface, i.e., at ${\displaystyle r=r_{g}}$ .

Other formulations edit

Defining a parameter ${\displaystyle {\mathcal {R}}^{2}=r_{g}^{3}/r_{s}}$ , we get

${\displaystyle -c^{2}{d\tau }^{2}=-{\frac {1}{4}}\left(3{\sqrt {1-{\frac {r_{g}^{2}}{{\mathcal {R}}^{2}}}}}-{\sqrt {1-{\frac {r^{2}}{{\mathcal {R}}^{2}}}}}\right)^{2}c^{2}dt^{2}+\left(1-{\frac {r^{2}}{{\mathcal {R}}^{2}}}\right)^{-1}dr^{2}+r^{2}\left(d\theta ^{2}+\sin ^{2}\theta \,d\varphi ^{2}\right).}$ 

We can also define an alternative radial coordinate ${\displaystyle \eta =\arcsin {\frac {r}{\mathcal {R}}}}$  and a corresponding parameter ${\displaystyle \eta _{g}=\arcsin {\frac {r_{g}}{\mathcal {R}}}=\arcsin {\sqrt {\frac {r_{s}}{r_{g}}}}}$ , yielding^[4]

${\displaystyle c^{2}{d\tau }^{2}=\left({\frac {3\cos \eta _{g}-\cos \eta }{2}}\right)^{2}c^{2}dt^{2}-{\frac {dr^{2}}{\cos ^{2}\eta }}-r^{2}\left(d\theta ^{2}+\sin ^{2}\theta \,d\varphi ^{2}\right).}$ 

Volume edit

With ${\displaystyle g_{rr}=(1-r_{s}r^{2}/r_{g}^{3})^{-1}}$  and the area ${\displaystyle A=4\pi r^{2}}$ 

the integral for the proper volume is

${\displaystyle V=\int _{0}^{r_{g}}A{\sqrt {g_{rr}}}\,{\rm {d}}r=2\pi \left({\frac {r_{g}^{9/2}\arcsin {\sqrt {\frac {r_{s}}{r_{g}}}}}{r_{s}^{3/2}}}-{\frac {r_{g}^{4}{\sqrt {1-{\frac {r_{s}}{r_{g}}}}}}{r_{s}}}\right)}$ 

which is larger than the volume of a euclidean reference shell.

Density edit

The fluid has a constant density by definition. It is given by

${\displaystyle \rho ={\frac {M}{{\frac {4\pi }{3}}r_{g}^{3}}}={\frac {3}{\kappa {\mathcal {R}}^{2}}},}$ 

where ${\displaystyle \kappa =8\pi G/c^{2}}$  is the Einstein gravitational constant.^[3][5] It may be counterintuitive that the density is the mass divided by the volume of a sphere with radius ${\displaystyle r_{g}}$ , which seems to disregard that this is less than the proper radius, and that space inside the body is curved so that the volume formula for a "flat" sphere shouldn't hold at all. However, ${\displaystyle M}$  is the mass measured from the outside, for example by observing a test particle orbiting the gravitating body (the "Kepler mass"), which in general relativity is not necessarily equal to the proper mass. This mass difference exactly cancels out the difference of the volumes.

Pressure and stability edit

The pressure of the incompressible fluid can be found by calculating the Einstein tensor ${\displaystyle G_{\mu \nu }}$  from the metric. The Einstein tensor is diagonal (i.e., all off-diagonal elements are zero), meaning there are no shear stresses, and has equal values for the three spatial diagonal components, meaning pressure is isotropic. Its value is

${\displaystyle p=\rho c^{2}{\frac {\cos \eta -\cos \eta _{g}}{3\cos \eta _{g}-\cos \eta }}.}$ 

As expected, the pressure is zero at the surface of the sphere and increases towards the centre. It becomes infinite at the centre if ${\displaystyle \cos \eta _{g}=1/3}$ , which corresponds to ${\displaystyle r_{s}={\frac {8}{9}}r_{g}}$  or ${\displaystyle \eta _{g}\approx 70.5^{\circ }}$ , which is true for a body that is extremely dense or large. Such a body suffers gravitational collapse into a black hole. As this is a time dependent process, the Schwarzschild solution does not hold any longer.^[2][3]

Redshift edit

Gravitational redshift for radiation from the sphere's surface (for example, light from a star) is

${\displaystyle z={\frac {1}{\cos \eta _{g}}}-1.}$ 

From the stability condition ${\displaystyle \cos \eta _{g}>1/3}$  follows ${\displaystyle z<2}$ .^[3]

The spatial curvature of the interior Schwarzschild metric can be visualized by taking a slice (1) with constant time and (2) through the sphere's equator, i.e. ${\displaystyle t=const.,\theta =\pi /2}$ . This two-dimensional slice can be embedded in a three-dimensional Euclidean space and then takes the shape of a spherical cap with radius ${\displaystyle {\mathcal {R}}}$  and half opening angle ${\displaystyle \eta _{g}}$ . Its Gaussian curvature ${\displaystyle K}$  is proportional to the fluid's density and equals ${\displaystyle {\mathcal {R}}^{-2}=r_{s}/r_{g}^{3}=\rho \kappa /3}$ . As the exterior metric can be embedded in the same way (yielding Flamm's paraboloid), a slice of the complete solution can be drawn like this:^[5][6]

In this graphic, the blue circular arc represents the interior metric, and the black parabolic arcs with the equation ${\displaystyle w=2{\sqrt {r_{s}(r-r_{s})}}}$  represent the exterior metric, or Flamm's paraboloid. The ${\displaystyle \eta }$ -coordinate is the angle measured from the centre of the cap, that is, from "above" the slice. The proper radius of the sphere – intuitively, the length of a measuring rod spanning from its centre to a point on its surface – is half the length of the circular arc, or ${\displaystyle \eta _{g}{\mathcal {R}}}$ .

This is a purely geometric visualization and does not imply a physical "fourth spatial dimension" into which space would be curved. (Intrinsic curvature does not imply extrinsic curvature.)

Here are the relevant parameters for some astronomical objects, disregarding rotation and inhomogeneities such as deviation from the spherical shape and variation in density.

The interior Schwarzschild solution was the first static spherically symmetric perfect fluid solution that was found. It was published on 24 February 1916, only three months after Einstein's field equations and one month after Schwarzschild's exterior solution.^[1][2]