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Error terms for the motives of discriminant complements and a Cayley-Bacharach theorem

Ishan Banerjee

Abstract

In this paper we prove under some simplifying hypotheses questions of Picoco and Levinson-Ullery on Cayley-Bacharach sets. Our results imply that, under suitable hypotheses Cayley-Bacharach sets lie on curves of low degree. We then use these results to estimate error terms to the normalized motive of the space of smooth degree $d$ hypersurfaces in $\mathbb{P}^n$as $d$ grows to infinity. The error term can be expressed in terms of a certain `sum over points' on plane cubic curves and the associated Hodge structure can be expressed in terms of the cohomology of the moduli space of elliptic curves. We also prove convergence of the motive of degree $d$ hypersurfaces in $\mathbb{P}^n$ as $n$ grows to infinity as well as other results on discriminant complements of high dimensional varieties.

Error terms for the motives of discriminant complements and a Cayley-Bacharach theorem

Abstract

In this paper we prove under some simplifying hypotheses questions of Picoco and Levinson-Ullery on Cayley-Bacharach sets. Our results imply that, under suitable hypotheses Cayley-Bacharach sets lie on curves of low degree. We then use these results to estimate error terms to the normalized motive of the space of smooth degree hypersurfaces in as grows to infinity. The error term can be expressed in terms of a certain `sum over points' on plane cubic curves and the associated Hodge structure can be expressed in terms of the cohomology of the moduli space of elliptic curves. We also prove convergence of the motive of degree hypersurfaces in as grows to infinity as well as other results on discriminant complements of high dimensional varieties.
Paper Structure (16 sections, 40 theorems, 195 equations)

This paper contains 16 sections, 40 theorems, 195 equations.

Table of Contents

  1. Introduction
  2. Grothendieck ring of varieties
  3. A note on brackets
  4. Meta problems for convergence
  5. Statement of results on convergence
  6. Motivation for our results on convergence
  7. Homological stability
  8. Arithmetic statistics
  9. Cayley-Bacharach sets
  10. Results on Cayley-Bacharach sets
  11. Acknowledgements
  12. Cayley-Bacharach subsets lie on curves
  13. Preparatory lemmas
  14. Proof of Theorem \ref{['mainrate']}
  15. Proof of Theorem \ref{['maindim']}
  16. ...and 1 more sections

Key Result

Theorem 1.6

Let $X, \mathcal{L}, m(d)$ be as above. Then there exists $C> 0$ such that for all $d \gg 0$, up to dimension $- m(d)(\dim X) + C$.

Theorems & Definitions (91)

  • Remark 1
  • Theorem 1.6
  • Remark 2
  • Theorem 1.7
  • Corollary 1.8
  • Theorem 1.9
  • Remark 3
  • Definition 1.10
  • Proposition 1.11
  • proof
  • ...and 81 more