Topological string amplitudes and Seiberg-Witten prepotentials from the counting of dimers in transverse flux

TL;DR

This paper links topological string partition functions on Calabi-Yau manifolds to solutions of $q$-difference equations, demonstrating how dimer models and WKB methods reveal connections to Seiberg-Witten prepotentials in gauge theories.

Contribution

It provides a new perspective on topological string/spectral theory correspondence by relating dimer models and $q$-difference equations to gauge theory prepotentials.

Findings

Dimer counting models topological string partition functions.

Partition functions satisfy $q$-difference equations of integrable systems.

WKB analysis yields explicit formulas for Seiberg-Witten prepotentials.

Abstract

Important illustration to the principle ``partition functions in string theory are $\tau$-functions of integrable equations'' is the fact that the (dual) partition functions of $4d$ $\mathcal{N}=2$ gauge theories solve Painlev\'e equations. In this paper we show a road to self-consistent proof of the recently suggested generalization of this correspondence: partition functions of topological string on local Calabi-Yau manifolds solve $q$-difference equations of non-autonomous dynamics of the ``cluster-algebraic'' integrable systems. We explain in details the ``solutions'' side of the proposal. In the simplest non-trivial example we show how $3d$ box-counting of topological string partition function appears from the counting of dimers on bipartite graph with the discrete gauge field of ``flux'' $q$. This is a new form of topological string/spectral theory type correspondence, since the partition function of dimers can be computed as determinant of the linear $q$-difference Kasteleyn operator. Using WKB method in the ``melting'' $q\to 1$ limit we get a closed integral formula for Seiberg-Witten prepotential of the corresponding $5d$ gauge theory. The ``equations'' side of the correspondence remains the intriguing topic for the further studies.