Revision 132bb547-a976-4008-bf50-1a26db5a1a25

Gravitation Page 276 Exercise 11.3 solution indicated that 

$$\nabla_\gamma \nabla _\delta e_\beta
=e_{\mu}\Gamma^\mu_{\beta\delta,\gamma} +(e_\nu\Gamma^\nu_{\mu\gamma}) \Gamma^\mu_{\beta\delta}$$

However, using to "Chain rule for gradient" i.e. Eq 10.22 
$$\nabla_\gamma \nabla _\delta e_\beta
=\nabla_{\gamma}(e_{\mu}\Gamma^\mu_{\beta\delta,\gamma})
=e_{\mu} \Gamma^\mu_{\beta\delta;\gamma} +(e_{\nu;\gamma}) \Gamma^\mu_{\beta\delta}$$

where according to equation 10.19, 
$$\Gamma^\mu_{\beta\delta;\gamma} $$ did have indices and have to be corrected. 

Yet the answer somehow indicated that
$$\Gamma^\mu_{\beta\delta;\gamma}=\Gamma^\mu_{\beta\delta,\gamma} $$.


Why $\Gamma^\mu_{\beta\delta;\gamma} =\Gamma^\mu_{\beta\delta,\gamma}$? Was there some identity? How to show that $\Gamma^\mu_{\beta\delta;\gamma} =\Gamma^\mu_{\beta\delta,\gamma}$?