JMedley
Sep20-11, 06:23 AM
I have started with the space-time metric in a weak gravitational field (with the assumption of low velocity):
ds^2=-(1+2\phi)dt^2+(1-2\phi)(dx^2+dy^2+dz^2)
Where \phi<<1 is the gravitational potential. Using the standard form for the Christoffel symbols have found:
\Gamma^0_{00}=\phi_{,0}, \Gamma^0_{0i}=\Gamma^0_{i0}=\phi_{,i}, \Gamma^0_{ij}=\delta_{ij}\phi_{,0}
\Gamma^i_{00}=\phi^{,i}, \Gamma^i_{0j}=\Gamma^i_{j0}=-\delta^i_j\phi_{,0}, \Gamma^i_{jk}=\delta_{jk}\phi^{,i}-\delta^i_j\phi_{,k}-\delta^i_k\phi_{,j}
Then combining derivatives of these to first order (ignoring products of Christoffel symbols) using:
R^\alpha_{\beta\mu\nu}=\Gamma^\alpha_{\beta\nu,\mu } - \Gamma^\alpha_{\beta\mu,\nu}
to get:
R^0_{i0j}=\delta_{ij}\phi_{00}-\phi_{ij}, R^i_{0j0}=\phi^{,i}_{,j}+\delta^i_j\phi_{,00}
R^i_{0jk}=-\delta^i_k\phi_{,0j}+\delta^i_j\phi_{0k}, R^i_{kj0}=\delta^i_j\phi_{0k} - \delta_{jk}\phi^{,i}_{,0}
R^i_{kjl}=-\delta^i_l\phi_{,jk}+\delta_{kl}\phi^{,i}_{,j}+ {\delta^i_j}\phi_{,kl}-\delta_{jk}\phi^{,i}_{,l}
(Where greek indices run from 0 to 3 and latin indices run from 1 to 3, and commas denote coordinate partial differentiation). And here is where I run into problems.. When I try to use R_{\alpha\beta}=R^\sigma_{\alpha\sigma\beta} to contract these down to find the Ricci tensor. For example I get:
R_{00}=R^\sigma_{0\sigma 0}=\phi^{,i}_{,i}+\phi_{,00}
Which doesn't agree with the text I'm using which gives R_{00}=\nabla^2\phi +3\phi_{,00}
Can anybody spot where I'm going wrong? Many Thanks for any help.
Jack M
ds^2=-(1+2\phi)dt^2+(1-2\phi)(dx^2+dy^2+dz^2)
Where \phi<<1 is the gravitational potential. Using the standard form for the Christoffel symbols have found:
\Gamma^0_{00}=\phi_{,0}, \Gamma^0_{0i}=\Gamma^0_{i0}=\phi_{,i}, \Gamma^0_{ij}=\delta_{ij}\phi_{,0}
\Gamma^i_{00}=\phi^{,i}, \Gamma^i_{0j}=\Gamma^i_{j0}=-\delta^i_j\phi_{,0}, \Gamma^i_{jk}=\delta_{jk}\phi^{,i}-\delta^i_j\phi_{,k}-\delta^i_k\phi_{,j}
Then combining derivatives of these to first order (ignoring products of Christoffel symbols) using:
R^\alpha_{\beta\mu\nu}=\Gamma^\alpha_{\beta\nu,\mu } - \Gamma^\alpha_{\beta\mu,\nu}
to get:
R^0_{i0j}=\delta_{ij}\phi_{00}-\phi_{ij}, R^i_{0j0}=\phi^{,i}_{,j}+\delta^i_j\phi_{,00}
R^i_{0jk}=-\delta^i_k\phi_{,0j}+\delta^i_j\phi_{0k}, R^i_{kj0}=\delta^i_j\phi_{0k} - \delta_{jk}\phi^{,i}_{,0}
R^i_{kjl}=-\delta^i_l\phi_{,jk}+\delta_{kl}\phi^{,i}_{,j}+ {\delta^i_j}\phi_{,kl}-\delta_{jk}\phi^{,i}_{,l}
(Where greek indices run from 0 to 3 and latin indices run from 1 to 3, and commas denote coordinate partial differentiation). And here is where I run into problems.. When I try to use R_{\alpha\beta}=R^\sigma_{\alpha\sigma\beta} to contract these down to find the Ricci tensor. For example I get:
R_{00}=R^\sigma_{0\sigma 0}=\phi^{,i}_{,i}+\phi_{,00}
Which doesn't agree with the text I'm using which gives R_{00}=\nabla^2\phi +3\phi_{,00}
Can anybody spot where I'm going wrong? Many Thanks for any help.
Jack M