Benford's Law for Coefficients of Newforms

Abstract: Let $f(z)=\sum_{n=1}^\infty \lambda_f(n)e^{2\pi i n z}\in S_{k}^{new}(\Gamma_0(N))$ be a normalized Hecke eigenform of even weight $k\geq2$ on $\Gamma_0(N)$ without complex multiplication. Let $\mathbb{P}$ denote the set of all primes. We prove that the sequence ${\lambda_f(p)}{p\in\mathbb{P}}$ does not satisfy Benford's Law in any base $b\geq2$. However, given a base $b\geq2$ and a string of digits $S$ in base $b$, the set [ A{\lambda_f}(b,S):={\text{$p$ prime : the first digits of $\lambda_f(p)$ in base $b$ are given by $S$}} ] has logarithmic density equal to $\log_b(1+S^{-1})$. Thus ${\lambda_f(p)}_{p\in\mathbb{P}}$ follows Benford's Law with respect to logarithmic density. Both results rely on the now-proven Sato-Tate Conjecture.