Recently, I came across a beautiful paper by Arnol'd and Krylov (_Uniform distribution of points on a sphere..._) that contains the following theorem:
>**Theorem:** Let _A_ and _B_ be two rotations of the sphere $S_2$ and let $x$ be a point of the sphere. If the sequence of points $$x, Ax, Bx, A^2x, ABx, BAx, B^2x, \ldots $$ is dense on the sphere, then it is uniformly distributed.
Here, uniformly distributed means that, if we consider the $2^n$ points produced with exactly $n$ iterations of the rotations, namely
$$
A^nx , A^{n-1}Bx , A^{n-2}BAx , \ldots , B^nx \ , $$ and we count the proportion of them that lie inside a region $\Delta$ (bounded by a piecewise smooth curve), then these ratios converge to the measure of $\Delta$; that is to say:
$$ \lim_{n\to \infty} \frac{\mbox{Number of points among } \{A^nx , \ldots , B^nx \} \mbox{ inside } \Delta}{2^n} = \frac{\mu(\Delta)}{\mu(S_2)}.$$
A quick search has shown to me that there have been many developments of the ideas behind this result, in many different directions.
But I was wondering what is the state of the art concerning the uniform distribution of points under the action of semigroups of isometries in a more general situation.
To be precise,
> **Question:** Is there a similar result for the action of a (finitely generated) semigroup of isometries of a compact Riemannian manifold?
Most of the references I see are too specialized for me and, although they seem very general, I am not able to understand whether they cover the situation I am interested in or not.
**Edit 1**
In the following reference:
Guivarc'h, Y.: *Equirépartition dans les espaces homogènes*, in Théorie Ergodique, LNM 532, Springer, Berlin (1976) pp. 131--142.
the author seems to comment in the introduction that an analogous result to that of Arnol'd-Krylov holds for the sequence of probabilities $p_n = \frac{1}{n} \sum_{k=0}^{n-1} p^k$ on a compact Lie group.
Here, $p$ is a sum of Dirac deltas, its power $p^k$ is made via the convolution product and the equidistribution statement is written in terms of convergence of probabilities.
As the group of isometries of a compact Riemannian manifold is a compact Lie group, I assume that the answer to my question is yes, but I am not sure yet (there are many assumptions on Guivarc'h's note and very few details...).