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algebraic geometry

Equations for point configurations to lie on a rational normal curve

arXiv:1711.06286

summary

The paper determines explicit defining equations for the space of ordered point configurations that lie on a rational normal curve, providing determinantal equations for conics and using the Gale transform for twisted cubics, and discusses extensions to higher dimensions.

Abstract

The parameter space of $n$ ordered points in projective $d$-space that lie on a rational normal curve admits a natural compactification by taking the Zariski closure in $(\mathbb{P}^d)^n$. The resulting variety was used to study the birational geometry of the moduli space $\overline{\mathrm{M}}_{0,n}$ of $n$-tuples of points in $\mathbb{P}^1$. In this paper we turn to a more classical question, first asked independently by both Speyer and Sturmfels: what are the defining equations? For conics, namely $d=2$, we find scheme-theoretic equations revealing a determinantal structure and use this to prove some geometric properties; moreover, determining which subsets of these equations suffice set-theoretically is equivalent to a well-studied combinatorial problem. For twisted cubics, $d=3$, we use the Gale transform to produce equations defining the union of two irreducible components, the compactified configuration space we want and the locus of degenerate point configurations, and we explain the challenges involved in eliminating this extra component. For $d \ge 4$ we conjecture a similar situation and prove partial results in this direction.

28 pages. Minor correction. We removed the erroneous Lemma 4.7 in the previous version, but the remaining results are valid

Topics & keywords

#rational normal curves#point configurations#determinantal equations#gale transform#moduli space m0,nrational normal curvedeterminantal structureGale transformcompactified configuration spaceM0,nprojective space