English

Elliptic KZB connections via universal vector extensions

Algebraic Geometry 2025-06-18 v2 Number Theory

Abstract

Using the formalism of bar complexes and their relative versions, we give a new, purely algebraic, construction of the so-called universal elliptic KZB connection in arbitrary level. We compute explicit analytic formulae, and we compare our results with previous approaches to elliptic KZB equations and multiple elliptic polylogarithms in the literature. Our approach is based on a number of results concerning logarithmic differential forms on universal vector extensions of elliptic curves. Let SS be a scheme of characteristic zero, ESE \to S be an elliptic curve, f:ESf:E^{\natural} \to S be its universal vector extension, and π:EE\pi:E^{\natural} \to E be the natural projection. Given a finite subset of torsion sections ZE(S)Z\subset E(S), we study the dg-algebra over OS\mathcal{O}_S of relative logarithmic differentials A=fΩE/S(logπ1Z)\mathcal{A} = f_*\Omega^{\bullet}_{E^{\natural}/S}(\log \pi^{-1}Z). In particular, we prove that the residue exact sequence in degree one splits canonically, and we derive the formality of A\mathcal{A}. When SS is smooth over a field kk of characteristic zero, we also prove that sections of A1\mathcal{A}^1 admit canonical lifts to absolute logarithmic differentials in fΩE/k1(logπ1Z)f_*\Omega^1_{E^{\natural}/k}(\log \pi^{-1}Z), which extends a well known property for regular differentials given by the `crystalline nature' of universal vector extensions.

Keywords

Cite

@article{arxiv.2301.12560,
  title  = {Elliptic KZB connections via universal vector extensions},
  author = {Tiago J. Fonseca and Nils Matthes},
  journal= {arXiv preprint arXiv:2301.12560},
  year   = {2025}
}

Comments

New introduction. Comments still welcome

R2 v1 2026-06-28T08:25:41.540Z