Intrinsic enumerative mirror symmetry: Takahashi's log mirror symmetry for $(\mathbb{P}^2,E)$ revisited

TL;DR

This paper revisits Takahashi's conjecture relating rational curve counts in the complement of a cubic in the projective plane to period integrals, demonstrating it as a natural outcome of intrinsic mirror symmetry and extending the approach to higher dimensions.

Contribution

It provides a new proof of Takahashi's conjecture using intrinsic mirror symmetry and introduces a method that generalizes to log Calabi-Yau varieties of any dimension.

Findings

Explicit computation of the period integral matches the product of wall functions.

Wall functions' coefficients correspond to logarithmic Gromov-Witten counts.

Takahashi's conjecture follows naturally from the intrinsic mirror symmetry framework.

Abstract

Let $E$ be a smooth cubic in the projective plane $\mathbb{P}^2$. Nobuyoshi Takahashi formulated a conjecture that expresses counts of rational curves of varying degree in $\mathbb{P}^2\setminus E$ as the Taylor coefficients of a particular period integral of a pencil of affine plane cubics after reparametrizing the pencil using the exponential of a second period integral. The intrinsic mirror construction introduced by Mark Gross and the third author associates to a degeneration of $(\mathbb{P}^2, E)$ a canonical wall structure from which one constructs a family of projective plane cubics that is birational to Takahashi's pencil in its reparametrized form. By computing the period integral of the positive real locus explicitly, we find that it equals the logarithm of the product of all asymptotic wall functions. The coefficients of these asymptotic wall functions are logarithmic Gromov-Witten counts of the central fiber of the degeneration that agree with the algebraic curve counts in $(\mathbb{P}^2,E)$ in question. We conclude that Takahashi's conjecture is a natural consequence of intrinsic mirror symmetry. Our method generalizes to give similar results for log Calabi-Yau varieties of arbitrary dimension.