Powers in orbits of rational functions: cases of an arithmetic dynamical Mordell-Lang conjecture

Abstract

Let K be a finitely generated field of characteristic zero. We study, for fixed m ≥ 2, the rational functions φ defined over K that have a K-orbit containing infinitely many distinct mth powers. For m ≥ 5 we show the only such functions are those of the form cxj((x))m with ∈ K(x), and for m ≤ 4 we show the only additional cases are certain Latt\`es maps and four families of rational functions whose special properties appear not to have been studied before. With additional analysis, we show that the index set \n ≥ 0 : φn(a) ∈ λ(P1(K))\ is a union of finitely many arithmetic progressions, where φn denotes the nth iterate of φ and λ ∈ K(x) is any map M\"obius-conjugate over K to xm. When the index set is infinite, we give bounds on the number and moduli of the arithmetic progressions involved. These results are similar in flavor to the dynamical Mordell-Lang conjecture, and motivate a new conjecture on the intersection of an orbit with the value set of a morphism. A key ingredient in our proofs is a study of the curves ym = φn(x). We describe all φ for which these curves have an irreducible component of genus at most 1, and show that such φ must have two distinct iterates that are equal in K(x)*/K(x)*m.