A finiteness theorem for specializations of dynatomic polynomials

Abstract

Let t and x be indeterminates, let φ(x)=x2+t∈ Q(t)[x], and for every positive integer n let n(t,x) denote the nth dynatomic polynomial of φ. Let Gn be the Galois group of n over the function field Q(t), and for c∈ Q let Gn,c be the Galois group of the specialized polynomial n(c,x). It follows from Hilbert's irreducibility theorem that for fixed n we have Gn Gn,c for every c outside a thin set En⊂ Q. By earlier work of Morton (for n=3) and the present author (for n=4), it is known that En is infinite if n 4. In contrast, we show here that En is finite if n∈\5,6,7,9\. As an application of this result we show that, for these values of n, the following holds with at most finitely many exceptions: for every c∈ Q, more than 81\% of prime numbers p have the property that the polynomial x2+c does not have a point of period n in the p-adic field Qp.