The Schwarzchild metric is the most general spherically symmetric, vacuum solution of the Einstein field equations.
I was wondering if there was a simple argument to explain why the Schwarzchild metric is diagonal in the spherical coordinate system, i.e. of the form
$$ds^2 = dt^2 + \cdots d\theta^2 + \cdots d\phi^2 + \cdots dr^2.$$
This Wikipedia article gives a really simple explanation which seems false.
(When you write the transformation law for $ g_{\mu 4} $, it should be understood: $$ g'_{\mu 4} (x') = \frac{\partial x^\alpha}{\partial x'^\mu}\frac{\partial x^\beta}{\partial x'^4}g_{\alpha\beta}(x)= -g_{\mu 4}(x) ,$$ while at the same time the invariance tells you that $$ g'_{\mu 4}(x') = g_{\mu 4}(x') .$$ This leads to the conclusion that $$ g_{\mu 4}(x') = -g_{\mu 4}(x) ,$$ but I fail to see how to go further in the reasoning without any aditionnal assumption.)
Other derivations either start from the diagonal form or are much more complicated.
It's probably a dumb question, but I fail to see a simple argument.
