Variations on Schanuel's Conjecture for elliptic and quasi-elliptic functions I: the split case
Abstract
It is expected that Schanuel's Conjecture contains all ``reasonable" statements that can be made on the values of the exponential function. In particular it implies the Lindemann-Weierstrass Theorem and the Conjecture on algebraic independence of logarithms of algebraic numbers. Our goal is to state conjectures \`a la Schanuel, which imply conjectures \`a la Lindemann-Weierstrass, for the exponential map of an extension G of an elliptic curve E by the multiplicative group Gm. In the present paper we assume that the extension is split, that is G= Gm× E. In a second paper in preparation we will deal with the non-split case, namely when the extension is not a product. Here we propose the split semi-elliptic Conjecture, which involves the exponential function and the Weierstrass and ζ functions, related with integrals of the first and second kind. In the second paper, our non-split semi-elliptic Conjecture will also involve Serre's functions, related with integrals of the third kind. We expect that our conjectures contain all ``reasonable" statements that can be made on the values of these functions. In the present paper we highlight the geometric origin of the split semi-elliptic Conjecture: it is equivalent to the Grothendieck-Andr\'e generalized period Conjecture applied to the 1-motive M=[u:Z → Gms × En ], which is the Elliptico-Toric Conjecture of the first author. We show that our split semi-elliptic Conjecture implies three theorems of Schneider on elliptic analogs of the Hermite-Lindemann and Gel'fond-Schneider's theorems, as well as a conjecture on the Weierstrass zeta function.
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