On the size of the Fourier coefficients of Hilbert cusp forms

Abstract

Let f be a primitive Hilbert cusp form of weight k and level n with Fourier coefficients c f(m). We prove a non-trivial upper bound for almost all Fourier coefficients c f(m) of f. This generalizes the bounds obtained by Luca, Radziwi and Shparlinski. We also prove the existence of infinitely many integral ideals m for which the Fourier coefficients c f(m) have the improved upper bound and further we obtain a refinement of these integral ideals in terms of prime powers. In particular, this enable us to deduce the bound for Fourier coefficients of elliptic cusp forms beyond the `typical size'. Moreover, we prove further improvements of the bound under the assumption of Littlewood's conjecture. Finally, We study a lower bound for the Fourier coefficients at prime powers provided the corresponding Hecke eigen angle is badly approximable.