English

Noncommutative linear systems and noncommutative elliptic curves

Algebraic Geometry 2022-11-23 v1 Quantum Algebra Rings and Algebras

Abstract

In this paper we introduce a noncommutative analogue of the notion of linear system, which we call a helix L:=(Li)iZ\underline{\mathcal{L}} := (\mathcal{L}_{i})_{i \in \mathbb{Z}} in an abelian category C{\sf C} over a quadratic Z\mathbb{Z}-indexed algebra AA. We show that, under natural hypotheses, a helix induces a morphism of noncommutative spaces from ProjEnd(L){\sf Proj }\operatorname{End}(\underline{\mathcal{L}}) to ProjA{\sf Proj }A. We construct examples of helices of vector bundles on elliptic curves generalizing the elliptic helices of line bundles constructed by Bondal-Polishchuk, where AA is the quadratic part of B:=End(L)B:= \operatorname{End}(\underline{\mathcal{L}}). In this case, we identify BB as the quotient of the Koszul algebra AA by a normal family of regular elements of degree 3, and show that ProjB{\sf Proj }B is a noncommutative elliptic curve in the sense of Polishchuk. One interprets this as embedding the noncommutative elliptic curve as a cubic divisor in some noncommutative projective plane, hence generalizing some well-known results of Artin-Tate-Van den Bergh.

Keywords

Cite

@article{arxiv.2211.12465,
  title  = {Noncommutative linear systems and noncommutative elliptic curves},
  author = {Daniel Chan and Adam Nyman},
  journal= {arXiv preprint arXiv:2211.12465},
  year   = {2022}
}

Comments

37 pages

R2 v1 2026-06-28T06:36:51.734Z