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Connectedness and combinatorial interplay in the moduli space of line arrangements

Benoît Guerville-Ballé, Juan Viu-Sos

Abstract

This paper aims to undertake an exploration of the behavior of the moduli space of line arrangements while establishing its combinatorial interplay with the incidence structure of the arrangement. In the first part, we investigate combinatorial classes of arrangements whose moduli space is connected. We unify the classes of simple and inductively connected arrangements appearing in the literature. Then, we introduce the notion of arrangements with a rigid pencil form. It ensures the connectedness of the moduli space and is less restrictive that the class of $C_3$ arrangements of simple type. In the last part, we obtain a combinatorial upper bound on the number of connected components of the moduli space. Then, we exhibit examples with an arbitrarily large number of connected components for which this upper bound is sharp.

Connectedness and combinatorial interplay in the moduli space of line arrangements

Abstract

This paper aims to undertake an exploration of the behavior of the moduli space of line arrangements while establishing its combinatorial interplay with the incidence structure of the arrangement. In the first part, we investigate combinatorial classes of arrangements whose moduli space is connected. We unify the classes of simple and inductively connected arrangements appearing in the literature. Then, we introduce the notion of arrangements with a rigid pencil form. It ensures the connectedness of the moduli space and is less restrictive that the class of arrangements of simple type. In the last part, we obtain a combinatorial upper bound on the number of connected components of the moduli space. Then, we exhibit examples with an arbitrarily large number of connected components for which this upper bound is sharp.
Paper Structure (16 sections, 19 theorems, 50 equations, 5 figures)

This paper contains 16 sections, 19 theorems, 50 equations, 5 figures.

Table of Contents

  1. Introduction
  2. Moduli spaces of line arrangements
  3. Line combinatorics and line arrangements
  4. Realization and moduli spaces
  5. Type of an arrangement and naive dimension of the moduli space
  6. Families of arrangements with connected moduli space
  7. Inductively connected arrangement
  8. Nice, simple and generalized simple arrangements
  9. Inductively rigid arrangements
  10. Arrangements with a rigid pencil form
  11. On the number of connected components of $\mathcal{M}(\mathcal{A})$
  12. Perturbations of a combinatorics
  13. Parametrization of the moduli space.
  14. Inductive upper bound
  15. Sharpness of the upper bound
  16. ...and 1 more sections

Key Result

Proposition 2.9

Let $(\mathcal{A},\omega)$ be an ordered arrangement. The following equality holds:

Figures (5)

  • Figure 1: Arrangements in the classes $\mathfrak{X}(4)$ and $\overline{\mathfrak{X}}(4)$.
  • Figure 2: An arrangement with type $\tau(\mathcal{A},\omega)=(0,0,0,0,2,2,1,3)$.
  • Figure 3: An inductively connected arrangement with type $\tau(\mathcal{A},\omega)=(0,0,0,0,2,2,1)$.
  • Figure 4: The arrangement $\mathcal{Y}_2$.
  • Figure 5: An arrangement with rigid pencil form.

Theorems & Definitions (61)

  • Definition 2.1
  • Remark 2.2
  • Example 2.3
  • Definition 2.4
  • Remark 2.5
  • Definition 2.6
  • Example 2.7
  • Remark 2.8
  • Proposition 2.9
  • proof
  • ...and 51 more