The One-Dimensional Line Scheme of a Certain Family of Quantum ${\mathbb P}^3$s

TL;DR

This paper computes the line scheme of a family of quantum ${ m P}^3$ algebras, revealing a union of seven elliptic curves and conics, advancing understanding of their geometric structure.

Contribution

It explicitly determines the line scheme of a family of quantum ${ m P}^3$ algebras, identifying its geometric components for the first time.

Findings

Line scheme is the union of seven curves.

Includes a nonplanar elliptic curve in ${ m P}^3$.

Contains four planar elliptic curves and two conics.

Abstract

A quantum ${\mathbb P}^3$ is a noncommutative analogue of a polynomial ring on four variables, and, herein, it is taken to be a regular algebra of global dimension four. It is well known that if a generic quadratic quantum ${\mathbb P}^3$ exists, then it has a point scheme consisting of exactly twenty distinct points and a one-dimensional line scheme. In this article, we compute the line scheme of a family of algebras whose generic member is a candidate for a generic quadratic quantum ${\mathbb P}^3$. We find that, as a closed subscheme of ${\mathbb P}^5$, the line scheme of the generic member is the union of seven curves; namely, a nonplanar elliptic curve in a ${\mathbb P}^3$, four planar elliptic curves and two nonsingular conics.