English

On spin structures and orientations for gauge-theoretic moduli spaces

Differential Geometry 2021-01-26 v3 Algebraic Geometry Algebraic Topology

Abstract

Let XX be a compact manifold, GG a Lie group, PXP \to X a principal GG-bundle, and BP\mathcal{B}_P the infinite-dimensional moduli space of connections on PP modulo gauge. For a real elliptic operator EE_\bullet we previously studied orientations on the real determinant line bundle over BP\mathcal{B}_P. These are used to construct orientations in the usual sense on smooth gauge theory moduli spaces, and have been extensively studied since the work of Donaldson. Here we consider complex elliptic operators FF_\bullet and introduce the idea of spin structures, square roots of the complex determinant line bundle of FF_\bullet. These may be used to construct spin structures in the usual sense on smooth complex gauge theory moduli spaces. We study the existence and classification of such spin structures. Our main result identifies spin structures on XX with orientations on X×S1X \times S^1. Thus, if PXP \to X and QX×S1Q \to X \times S^1 are principal GG-bundles with QX×{1}PQ|_{X\times\{1\}} \cong P, we relate spin structures on (BP,F)(\mathcal{B}_P,F_\bullet) to orientations on (BQ,E)(\mathcal{B}_Q,E_\bullet) for a certain class of operators FF_\bullet on XX and EE_\bullet on X×S1X\times S^1. Combined with arXiv:1811.02405, we obtain canonical spin structures for positive Diracians on spin 6-manifolds and gauge groups G=U(m),SU(m)G=U(m), SU(m). In a sequel arXiv:2001.00113 we apply this to define canonical orientation data for all Calabi-Yau 3-folds XX over the complex numbers, as in Kontsevich-Soibelman arXiv:0811.2435, solving a long-standing problem in Donaldson-Thomas theory.

Keywords

Cite

@article{arxiv.1908.03524,
  title  = {On spin structures and orientations for gauge-theoretic moduli spaces},
  author = {Dominic Joyce and Markus Upmeier},
  journal= {arXiv preprint arXiv:1908.03524},
  year   = {2021}
}

Comments

53 pages. (v3) final version, to appear in Advances in Mathematics

R2 v1 2026-06-23T10:43:54.896Z