Geometry of Logarithmic Topological Recursion: Dilaton Equations, Free Energies and Variational Formulas

TL;DR

This paper extends topological recursion to spectral curves with logarithmic singularities, deriving dilaton equations and variational formulas, and applies these to compute free energies in complex geometric and physical models.

Contribution

It introduces a new framework for defining free energies in logarithmic topological recursion, enabling calculations where standard methods fail.

Findings

Reproduces Nekrasov--Shatashvili partition function components

Derives dilaton equations for logarithmic topological recursion

Calculates all-genus free energies for mirror curves of strip geometries

Abstract

One of the most important applications of topological recursion concerns spectral curves for which the functions $(x,y)$ defining the spectral curve are allowed to have logarithmic singularities. This occurs for instance for Seiberg-Witten curves and mirror curves computing Gromov--Witten invariants of toric Calabi--Yau threefolds. A recently introduced extension of topological recursion, the so-called logarithmic topological recursion, exhibits the correct behavior under certain limits of those spectral curves. In this article, we derive the dilaton equations in the setting of logarithmic topological recursion, as well as variational formulas, and provide a definition of the free energies in situations where standard topological recursion was known to fail. We present examples in which the new definition of the free energies \textit{directly} (without any computation) reproduces the full perturbative part of the Nekrasov--Shatashvili partition function of 4d $\mathcal{N}=2$ pure supersymmetric gauge theory, as well as the all-genus free energies of mirror curves of strip geometries, including in particular the topological vertex and the resolved conifold.