I am reposting [this question][1] from math.stackexchange where it has not yet generated an answer I had been looking for. 

- The volume of an $n$-dimensional ball of radius $R$ is given by the classical formula
$$V_n(R)=\frac{\pi^{n/2}R^n}{\Gamma(n/2+1)}.$$ 
It is not difficult to see that the "dimensionless" ratio $V_n(R)/R^n$ attains its maximal value when $n=5$.

- The "dimensionless" ratio $S_n(R)/R^n$ where $S_n(R)$ is the $n$-dimensional volume of an $n$-sphere attains its maximum when $n=7$.

**Question.** Is there a purely geometric explanation of why the maximal values in each case are attained at these particular values of the dimension?

[EDIT. Thanks to all for the answers and comments.]







  [1]: https://math.stackexchange.com/questions/15656/volumes-of-n-balls-what-is-so-special-about-n-5