Mentz114 said:
On the other hand, the stress-energy tensor used in some cosmological models is that of a perfect fluid -
T_{\mu\nu} = pg_{\mu\nu} + \mu u_{\mu}u_{\nu} + \frac{p}{c^2}u_{\mu}u_{\nu}
Could someone, please, explain me, the conflict in the stress-energy tensor units. So for the perfect fluid we have:
T_{\mu\nu} = pg_{\mu\nu} + (\rho + \frac{p}{c^2})u_{\mu}u_{\nu}
But on the other hand
u_{\mu} = g_{\mu\nu}u^{\nu}.
Now, in the comoving frame
u^{\nu} = \frac{dx^{\nu}}{d\tau}
where
d\tau^2 = - ds^2 (-, +, +, + signature).
that follows:
d\tau = \sqrt{-g_{00}}dx^0
(remember, we are in comoving frame). Here the real problem starts. For Schwarzschild solution, g_{00} = - e^{2\nu} and dx^0 = cdt. Then
d\tau = e^{\nu} c dt
This makes
u^{\nu} = \frac{dx^{\nu}}{d\tau} = e^{-\nu} (1, 0, 0, 0)
and
u_{\mu} = g_{\mu\nu}u^{\nu} = - e^{\nu} (1, 0, 0, 0)
Now let us see, the diagonal elements of energy momentum tensor:
T^0_0 = p \delta^0_0 + (\rho +p/c^2)u^0u_0 = p - \rho - p/c^2?
And this makes no sense. Could someone help me, where am I doing wrong? Thanks.
