I have a question which I believe to be pretty basic.
Let $\Gamma$ be some convex body, bounded inside a $L_2$ sphere of radius 1 $B(0,1)$.
Is it true that the surface area of $\Gamma$ is smaller than the surface area of the sphere?
I'm guessing that the answer involves finding a continuous deformation from $\Gamma$ to the sphere for which the area is monotonous, but I'm incapable of finding it
The nearest-point projection from the sphere to the convex set decreases distances.
This is a consequence of the standard inequalities on the "intrinsic volumes" (or "quermaß integrals", the two are synonymous up to a constant) of convex sets: for every $i$, the $i$-th intrinsic volume $V_i(K)$ of a convex set is monotone in $K$, and for a $d$-dimensional convex set, $V_{d-1}(K)$ is twice the $(d-1)$-dimensional surface area of $K$ (while $V_d(K)$ is the $d$-dimensional volume; the quick definition in general is that $V_i(K)$ is the coefficient of $r^{d-i}$ in the polynomial giving the volume of the distance $r$ ball $K+B(0,r)$ around $K$, divided by the volume of $B(0,1)$ in dimension $d-i$).
See, for example, J. R. Sangwine-Yager's chapter "Mixed Volumes" (specifically §3) in the Handbook of Convex Geometry (vol. A), edited by Gruber & Wills (North-Holland 1993).
Yes, this is a general fact. If $K_1\subset K_2$ are convex, then the surface area of $K_1$ is at most that of $K_2$.
