Effective height bounds for odd-degree totally real points on some curves

Abstract: I will give a finite-time algorithm that, on input (g,K,S) with g > 0, K a totally real number field of odd degree, and S a finite set of places of K, outputs the finitely many g-dimensional abelian varieties A/K which are of $\operatorname{GL}_2$-type over K and have good reduction outside S.

The point of this is to effectively compute the S-integral K-points on a Hilbert modular variety, and the point of that is to be able to compute all K-rational points on complete curves inside such varieties.

This gives effective height bounds for rational points on infinitely many curves and (for each curve) over infinitely many number fields. For example one gets effective height points for odd-degree totally real points on $x^6 + 4y^3 = 1$, by using the hypergeometric family associated to the arithmetic triangle group $\Delta(3,6,6)$.

number theory

Audience: researchers in the topic

Harvard number theory seminar