Gauge theory and the division algebras

TL;DR

This paper introduces a unified formulation of instanton equations across dimensions 2, 4, and 8, linking them to division algebras and moment map frameworks, and explores their geometric and topological implications.

Contribution

It presents a novel perspective connecting gauge equations with division algebras and moment maps, extending to curved spaces with specific holonomy constraints.

Findings

Unified formulation of instanton equations in dimensions 2, 4, and 8.

Moduli spaces described as symplectic quotients: Kaehler, hyperkaehler, and octonionic Kaehler.

Constraints on manifolds for curved space extensions based on holonomy and geometric structure.

Abstract

We present a novel formulation of the instanton equations in 8-dimensional Yang-Mills theory. This formulation reveals these equations as the last member of a series of gauge-theoretical equations associated with the real division algebras, including flatness in dimension 2 and (anti-)self-duality in 4. Using this formulation we prove that (in flat space) these equations can be understood in terms of moment maps on the space of connections and the moduli space of solutions is obtained via a generalised symplectic quotient: a Kaehler quotient in dimension 2, a hyperkaehler quotient in dimension 4 and an octonionic Kaehler quotient in dimension 8. One can extend these equations to curved space: whereas the 2-dimensional equations make sense on any surface, and the 4-dimensional equations make sense on an arbitrary oriented manifold, the 8-dimensional equations only make sense for manifolds whose holonomy is contained in Spin(7). The interpretation of the equations in terms of moment maps further constraints the manifolds: the surface must be orientable, the 4-manifold must be hyperkaehler and the 8-manifold must be flat.