An Invitation to Higher Gauge Theory

TL;DR

This paper introduces higher gauge theory using 2-connections on 2-bundles, exploring various examples of gauge 2-groups, and connecting these structures to string theory, topological gravity, and supergravity.

Contribution

It provides an accessible overview of higher gauge theory with explicit examples of gauge 2-groups and their applications in physics and geometry.

Findings

U(1) gerbes relate to string theory and multisymplectic geometry.

Poincaré 2-group leads to a spin foam model for Minkowski spacetime.

Tangent 2-group serves as a gauge 2-group in 4d BF theory.

Abstract

In this easy introduction to higher gauge theory, we describe parallel transport for particles and strings in terms of 2-connections on 2-bundles. Just as ordinary gauge theory involves a gauge group, this generalization involves a gauge '2-group'. We focus on 6 examples. First, every abelian Lie group gives a Lie 2-group; the case of U(1) yields the theory of U(1) gerbes, which play an important role in string theory and multisymplectic geometry. Second, every group representation gives a Lie 2-group; the representation of the Lorentz group on 4d Minkowski spacetime gives the Poincar\'e 2-group, which leads to a spin foam model for Minkowski spacetime. Third, taking the adjoint representation of any Lie group on its own Lie algebra gives a 'tangent 2-group', which serves as a gauge 2-group in 4d BF theory, which has topological gravity as a special case. Fourth, every Lie group has an 'inner automorphism 2-group', which serves as the gauge group in 4d BF theory with cosmological constant term. Fifth, every Lie group has an 'automorphism 2-group', which plays an important role in the theory of nonabelian gerbes. And sixth, every compact simple Lie group gives a 'string 2-group'. We also touch upon higher structures such as the 'gravity 3-group' and the Lie 3-superalgebra that governs 11-dimensional supergravity.