Let $\alpha$ be an irational number. Consider sequence $x_n=\{n^p\alpha\}$, $n\in\mathbb{N}$ (it's the fractional part of $n^p\alpha$), where $p$ is a nonzero real number.
Question. For which values of $p$ the sequence $\{x_n\}_{n\in\mathbb{N}}$ is equidistributed on $[0,1)$? The other qusetion is when $\{x_n\}_{n\in\mathbb{N}}$ is dense on $[0,1)$.
It's known that if $p\in\mathbb{N}$, then it's true (it's a consequence of Weyl's equdsitribution criterion and van der Corput's difference theorem). However, it's not clear how to apply Weyl's criterion in case when $p\notin\mathbb{N}$. I encountered similar problem when I was working
on this question Convergence of the product $\prod_{n=1}^{\infty}\left(1+\frac{x^n}{n^p}\right)\cos\frac{x^n}{n^q}$ (in order to study the behaviour of $\cos\frac{1}{n^q}$, so $\alpha=1/\pi$ in this case).
Update. It would be also intersting to investigate the distbution of $\left\{\frac{x^n}{n^p}\right\}$.
If the result is known, please give a link or reference. Any help would be appreciated.
Best Answer
The following is Theorem 3.4 of 'Uniform Distribution of Sequences' by Kuipers and Niederreiter.
Theorem
Here $\Delta f(n)=f(n+1)-f(n)$ and $\Delta^k = \Delta \circ \Delta^{k-1}$. When $p>0$ is real and not an integer, then we can find $k$ that satisfies conditions of the Theorem. Further, it is easy to see that $p\leq 0$ does not give uniform distribution. Hence, your sequence is uniformly distributed if and only if $p>0$.