I have a question on a non-typical "area" variation question. Let (M,dA) be a 2 dimensional manifold and f be a smooth function. Let $\Gamma$ be a compact 2- dimensional submanifold in M whose boundary is $\gamma(s)$. Consider the integral
$\int_{\Gamma} fdA$
I want to compute a variation where $\gamma \rightarrow \gamma + \delta\gamma$ (that is I only perturn the boundary of the region). Let V be the vector field of the variation and $F_t$ be the map from $\Gamma\times I$ to $M$ giving the variation. If you directly try to apply the usual computations you get something like
$\int_{\Gamma} V(f)dA + \int_{\gamma} f (V*)ds - \int_{\Gamma} fH<N,V>dA$
where V* is the dual form associated to the vector field V, H is mean curvature and N is the normal direction. In this case I have several puzzlements. Since the ambient manifold is also 2-dim this means N is non-zero only in the boundary so the last term cancels. Now I would like to write everything in terms of $\delta\gamma$. However $V$ equals to $\delta\gamma$ only on the boundary. So I could not figure out what to do with the first term. Is this computation correct and if so what would one do with the first term to express in terms of $\delta\gamma$. In variational problems one in the final sets an equality which must hold for all variations. And V is a vector field localized on some nbd of the boundary curve we can find a sequence variations where the first terms goes to zero so it does not contribute.
Another approach would be to somehow calculate "area under the curve" of $\delta\gamma(\theta)$ with density f, but that is only makes sense where I can write the curve in polar coordinates as ($\theta$, $r(\theta)$)
Thanks