Sato-Tate theorem for families and low-lying zeros of automorphic L-functions

Abstract

We consider certain families of automorphic representations over number fields arising from the principle of functoriality of Langlands. Let G be a reductive group over a number field F which admits discrete series representations at infinity. Let LG= G Gal( F/F) be the associated L-group and r:L G GL(d,C) a continuous homomorphism which is irreducible and does not factor through Gal( F/F). The families under consideration consist of discrete automorphic representations of G(AF) of given weight and level and we let either the weight or the level grow to infinity. We establish a quantitative Plancherel and a quantitative Sato-Tate equidistribution theorem for the Satake parameters of these families. This generalizes earlier results in the subject, notably of Sarnak [Progr. Math. 70 (1987), 321--331.] and Serre [J. Amer. Math. Soc. 10 (1997), no. 1, 75--102.]. As an application we study the distribution of the low-lying zeros of the associated family of L-functions L(s,π,r), assuming from the principle of functoriality that these L-functions are automorphic. We find that the distribution of the 1-level densities coincides with the distribution of the 1-level densities of eigenvalues of one of the Unitary, Symplectic and Orthogonal ensembles, in accordance with the Katz-Sarnak heuristics. We provide a criterion based on the Frobenius--Schur indicator to determine this Symmetry type. If r is not isomorphic to its dual r then the Symmetry type is Unitary. Otherwise there is a bilinear form on Cd which realizes the isomorphism between r and r. If the bilinear form is symmetric (resp. alternating) then r is real (resp. quaternionic) and the Symmetry type is Symplectic (resp. Orthogonal).