Are sines of primes dense in $[-1,1]?$

Let $P$ be the set of all prime numbers. Is $\sin(P)$ dense is $[-1,1]?$ How could we approach such a problem?

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+1 Cool question. What have you tried? –  draks ... Feb 15 '12 at 22:40
On distributional principles it sure seems true. Very cool question. –  Brian B Feb 15 '12 at 22:53
@draks Well, I know the proof that $\sin(\mathbb N)$ is dense. Actually, I just remembered it from my first course in analysis and thought about this problem. The proof of the case with $\mathbb N$ doesn't seem to generalize, and it would be strange if it did I think. But I have simply no idea how to find another approach. –  user23211 Feb 15 '12 at 22:57
I don't know the $\sin(\mathbb{N})$ proof (can you provide a link?), but would it help to think of $\mathbb{N}$ as sum of all primes, semi-primes, k-almost primes? –  draks ... Feb 15 '12 at 23:09
@draks There's a question about it on this site. There's a link to a paper with a proof there but I can't access it from my house so I'm not sure what's in it. –  user23211 Feb 15 '12 at 23:12

The sequence of all multiples of an irrational $\alpha$ by successive prime numbers, $2 \alpha$, $3 \alpha$, $5 \alpha$, $7 \alpha$, $11 \alpha$, ... is equidistributed modulo 1. This is a famous theorem of analytic number theory, proved by I. M. Vinogradov in 1935.
With $\alpha = \frac{1}{2 \pi}$, this implies that $P$ is equidistributed modulo $2 \pi$. Using this, and the continuity of the sine function, I think it is straightforward to show that $\sin(P)$ is dense in $[-1,1]$ (although not equidistributed).
Also, the distribution of $sin(P)$ can be derived from the fact of the equidistribution of $P$ modulo $2\pi$. –  Michael Lugo Feb 16 '12 at 5:37
How about $P^{it}$? Is this dense over the unit circle? –  draks ... Jul 16 '12 at 14:40
@draks The phase of $P^{it}$ varies extremely slowly for any fixed $t$, so there's no question that it is dense on the unit circle. One only needs $\frac{p_{n+1}}{p_n} \to 1$, which is slightly stronger than Bertrand's postulate and weaker than the Prime Number Theorem. –  Erick Wong Jan 6 '13 at 7:40