A genus 2 family with 226 sections

Abstract

Faltings' theorem [Fal83],[Fal91] (formerly the Mordell conjecture [Mo22]) states that a curve of genus greater than one over any number field has only finitely many points. Again a natural question is how many points can such a curve have. Caporaso, Harris, and Mazur [CHM97] have shown that the weak Bombieri-Lang conjecture implies that for any number field F and any integer g 2 there is an absolute upper bound B(F; g) on the number of points on a genus g curve over F. Furthermore, the strong Bombieri-Lang conjecture implies that for each genus g 2, there is an absolute bound C(g) depending on the genus -- but not on the field -- such that over any number field, only finitely many curves of genus g have more than C(g) points. Again we can ask what those two bounds are and, as it turns out, it helps to consider families that come from K3 surfaces. Specifically, we will consider the case g = 2. We use a K3 surface X that is a double cover of P2 ramified over a smooth sextic curve C, so every pencil of lines gives us a family of genus 2 curves. Any line that is tangent to C at 3 points will lift to a pair of curves on X that become sections of the family given by any pencil of lines. In section 3 we will construct an K3 surface (over a number field) and corresponding sextic with 64 such tritangents. Furthermore, there will turn out to be other rational curves in P2 of higher degree that also meet C only at tangent points. By suitably choosing the pencil and performing suitable base changes we find a family of genus 2 curves with 226 sections. This is the current best record, the previous [Elk06] being 150 sections, which remains the record for a family over .