The Explicit Sato-Tate Conjecture and Densities Pertaining to Lehmer-Type Questions (1305.5283v4)
Abstract: Let $f(z)=\sum_{n=1}\infty a(n)qn\in S{\text{new}}_ k (\Gamma_0(N))$ be a newform with squarefree level $N$ that does not have complex multiplication. For a prime $p$, define $\theta_p\in[0,\pi]$ to be the angle for which $a(p)=2p{( k -1)/2}\cos \theta_p $. Let $I\subset[0,\pi]$ be a closed subinterval, and let $d\mu_{ST}=\frac{2}{\pi}\sin2\theta d\theta$ be the Sato-Tate measure of $I$. Assuming that the symmetric power $L$-functions of $f$ satisfy certain analytic properties (all of which follow from Langlands functoriality and the Generalized Riemann Hypothesis), we prove that if $x$ is sufficiently large, then [ \left|#{p\leq x:\theta_p\in I} -\mu_{ST}(I)\int_2x\frac{dt}{\log t}\right|\ll\frac{x{3/4}\log(N k x)}{\log x} ] with an implied constant of $3.34$. By letting $I$ be a short interval centered at $\frac{\pi}{2}$ and counting the primes using a smooth cutoff, we compute a lower bound for the density of positive integers $n$ for which $a(n)\neq0$. In particular, if $\tau$ is the Ramanujan tau function, then under the aforementioned hypotheses, we prove that [ \lim_{x\to\infty}\frac{#{n\leq x:\tau(n)\neq0}}{x}>1-1.54\times10{-13}. ] We also discuss the connection between the density of positive integers $n$ for which $a(n)\neq0$ and the number of representations of $n$ by certain positive-definite, integer-valued quadratic forms.