Multiplicities of the Betti map associated to a section of an elliptic surface from a differential-geometric perspective

Abstract

For the study of the Mordell-Weil group of an elliptic curve E over a complex function field of a projective curve B, the first author introduced the use of differential-geometric methods arising from K\"ahler metrics on H × C invariant under the action of the semi-direct product SL(2, R) R2. To a properly chosen geometric model π: E B of E as an elliptic surface and a non-torsion holomorphic section σ: B E there is an associated ``verticality'' ησ of σ related to the locally defined Betti map. The first-order linear differential equation satisfied by ησ, expressed in terms of invariant metrics, is made use of to count the zeros of ησ, in the case when the regular locus B0⊂ B of π: E B admits a classifying map f0 into a modular curve for elliptic curves with level-k structure, k 3, explicitly and linearly in terms of the degree of the ramification divisor Rf0 of the classifying map, and the degree of the log-canonical line bundle of B0 in B. Our method highlights deg(Rf0) in the estimates, and recovers the effective estimate obtained by a different method of Ulmer-Urz\'ua on the multiplicities of the Betti map associated to a non-torsion section, noting that the finiteness of zeros of ησ was due to Corvaja-Demeio-Masser-Zannier. The role of Rf0 is natural in the subject given that in the case of an elliptic modular surface there is no non-torsion section by a theorem of Shioda, for which a differential-geometric proof had been given by the first author. Our approach sheds light on the study of non-torsion sections of certain abelian schemes.