A Theorem on GL(n) a la Tchebotarev

Abstract

Let K/F be a finite Galois extension of number fields. It is well known that the Tchebotarev density theorem implies that an irreducible, finitely ramified p-adic representation of the absolute Galois group of K is determined (up to equivalence) by the characteristic polynomials of Frobenius elements Frv at any set of primes v of K of degree 1 over F. Here we prove an analogue for GL(n), namely that a cuspidal automorphic representation π of GL(n, AK) is determined up by the knowledge of its local components at the primes of degree one over F. We prove in fact a stronger theorem, stimulated by a question of Michael Rapoport and Wei Zhang, relaxing to an extent the Galois hypothesis. The method uses, besides the Rankin-Selberg theory of L-functions and the Luo-Rudnick-Sarnak bound for the Hecke roots of π, certain consequences of class field theory via Galois cohomology. In an earlier paper (Ra2) we obtained such a result up to twist equivalence for K/F cyclic of prime degree by using basic Kummer theory. We make use of suitable solvable base changes πM, relative to certain auxiliary succession of abelian extensions E/F, with M being an abelian extension of the compositum EK, and deduce that πM π'M, and then descend this isomorphism to one over K. A key ingredient for progress here is the use of global Tate duality and a local-global result arising from class field theory. In fact we prove the main result for isobaric automorphic representations, which are analogues of semisimple Galois representations. In the last section we introduce a notion of semi-temperedness, which is much weaker than temperedness, but allows for the deduction of the main result without any hypothesis whatsoever on K/F.