English

The $u$-plane integral, mock modularity and enumerative geometry

High Energy Physics - Theory 2022-04-07 v2 Algebraic Geometry Differential Geometry Number Theory

Abstract

We revisit the low-energy effective U(1)U(1) action of topologically twisted N=2\mathcal N=2 SYM theory with gauge group of rank one on a generic oriented smooth 4-manifold XX with nontrivial fundamental group. After including a specific new set of Q\mathcal Q-exact operators to the known action, we express the integrand of the path integral of the low-energy U(1)U(1) theory as an anti-holomorphic derivative. This allows us to use the theory of mock modular forms and indefinite theta functions for the explicit evaluation of correlation functions of the theory, including but not restricted to those that physically reproduce Donaldson invariants, thus facilitating the computations compared to previously used methods. As an explicit check of our results, we compute the path integral for the product ruled surfaces X=Σg×CP1X=\Sigma_g \times \mathbb{CP}^1 for the reduction on either factor and compare the results with existing literature. In the case of reduction on the Riemann surface Σg\Sigma_g, via an equivalent topological A-model on CP1\mathbb{CP}^1, we will be able to express the generating function of genus zero Gromov-Witten invariants of the moduli space of flat rank one connections over Σg\Sigma_g in terms of an indefinite theta function, whence we would be able to make concrete numerical predictions of these enumerative invariants in terms of modular data, thereby allowing us to derive results in enumerative geometry from number theory.

Keywords

Cite

@article{arxiv.2109.04302,
  title  = {The $u$-plane integral, mock modularity and enumerative geometry},
  author = {Johannes Aspman and Elias Furrer and Georgios Korpas and Zhi-Cong Ong and Meng-Chwan Tan},
  journal= {arXiv preprint arXiv:2109.04302},
  year   = {2022}
}

Comments

31 pages + appendices. Minor changes to title, abstract, introduction and section 5 after reviewer comments. To appear in Lett.Math.Phys

R2 v1 2026-06-24T05:49:40.137Z