Let $(M,g)$ be a compact Riemannian manfold with $dim M=n$. This gives us a unique sympletic
structure $(TM, \omega)$ and a unique volum form $\Omega=\omega^{n}$ on $TM$.
For every $r>0$, let $D_{r}(M)$ be the open Disc bundle on $M$, with radius $r$. Namely $D_{r}(M)$
is the subset of $TM$ which contains all vectors with length $<r$.
Define:
${C(r)=(\text{sympletic capacity of $D_{r}(M)$}})^{2n}$
$V(r)$=The Volum of $D_{r}(M)$ with respect to $\Omega$
Question:
Does $\lim_{r\to \infty} C(r)/V(r)$ exist? And what is its geometric interpretation?
Note that the symplectic capacity of a sympletic manifold $N$of dimension 2n defined as follows:
$\sup\; \{r \mid \text{there is a symplectic embedding from $B_{r}(0)\subset \mathbb{R}^{2n}$ to $N$}\}$.
By $B_{r}(0)$ I mean the disc around the origin with radius $r$.