On integral points on isotrivial elliptic curves over function field

Abstract

Let k be a finite field and L be the function field of a curve C/k of genus g≥ 1. In the first part of this note, we show that the number of separable S-integral points on a constant elliptic curve E/L is bounded solely in terms of g, the size of S and the rank of the Mordell-Weil group E(L). In the second part, we assume that L is the function field of a hyperelliptic curve CA:s2=A(t), where A(t) is a square-free k-polynomial of odd degree. If ∞ is the place of L associated to the point at infinity of CA, then we prove that the set of separable \∞\-points can be bounded solely in terms of g and does not seem to depend on the Mordell-Weil group E(L). This is done by bounding the number of separable integral points over k(t) on elliptic curves of the form EA:A(t)y2=f(x), where f(x) is a polynomial over k. Additionally, we show that, under an extra condition on A(t), the existence of a separable integral point of "small" height on the elliptic curve EA/k(t) determines the isomorphism class of the elliptic curve y2=f(x).