On the denominators of the Taylor coefficients of G-functions

Abstract

Let Σ\n=0∞ a\n zn∈ Q[[z]] be a G-function, and, for any n0, let δ\n 1 denote the least integer such that δ\n a\0, δ\n a\1, ..., δ\n a\n are all algebraic integers. By definition of a G-function, there exists some constant c 1 such that δ\n cn+1 for all n 0. In practice, it is observed that δ\n always divides D\bns Cn+1 where D\n=lcm\1,2, ..., n\, b, C are positive integers and s 0 is an integer. We prove that this observation holds for any G-function provided the following conjecture is assumed: Let K be a number field, and L∈ K[z,d d z] be a G-operator; then the generic radius of solvability R\v(L) is equal to 1, for all finite places v of K except a finite number. The proof makes use of very precise estimates in the theory of p-adic differential equations, in particular the Christol-Dwork Theorem. Our result becomes unconditional when L is a geometric differential operator, a special type of G-operators for which the conjecture is known to be true. The famous Bombieri-Dwork Conjecture asserts that any G-operator is of geometric type, hence it implies the above conjecture.