Advances in Theoretical and Mathematical Physics

Volume 27 (2023)

Number 3

Modular bootstrap for D4-D2-D0 indices on compact Calabi–Yau threefolds

Pages: 683 – 744

DOI: https://dx.doi.org/10.4310/ATMP.2023.v27.n3.a2

Authors

Sergei Alexandrov (Laboratoire Charles Coulomb, Université de Montpellier, France)

Nava Gaddam (Institute for Theoretical Physics, and Center for Extreme Matter and Emergent Phenomena, Utrecht University, Utrecht, The Netherlands)

Jan Manschot (School of Mathematics, Trinity College, Dublin, Ireland)

Boris Pioline (Laboratoire de Physique Théorique et Hautes Energies, CNRS-Sorbonne Université, Paris, France)

Abstract

We investigate the modularity constraints on the generating series $h_r(\tau)$ of BPS indices counting D4-D2-D0 bound states with fixed D4-brane charge $r$ in type IIA string theory compactified on complete intersection Calabi–Yau threefolds with $b_2 = 1$. For unit D4-brane, $h_1$ transforms as a (vector-valued) modular form under the action of $SL(2,\mathbb{Z})$ and thus is completely determined by its polar terms. We propose an Ansatz for these terms in terms of rank‑1 Donaldson–Thomas invariants, which incorporates contributions from a single $\mathrm{D}6 \textrm{-} \overline{\mathrm{D}6}$ pair. Using an explicit overcomplete basis of the relevant space of weakly holomorphic modular forms (valid for any $r$), we find that for $10$ of the $13$ allowed threefolds, the Ansatz leads to a solution for $h_1$ with integer Fourier coefficients, thereby predicting an infinite series of DT invariants. For $r \gt 1$, $h_r$ is mock modular and determined by its polar part together with its shadow. Restricting to $r = 2$, we use the generating series of Hurwitz class numbers to construct a series $h^{(\mathrm{an})}_2$ with exactly the same modular anomaly as $h_2$, so that the difference $h_2 - h^{(\mathrm{an})}_2$ is an ordinary modular form fixed by its polar terms. For lack of a satisfactory Ansatz, we leave the determination of these polar terms as an open problem.

Published 6 June 2024