Contents

Idea

An ordinary gauge field (such as the electromagnetic field or the fields that induce the nuclear force) is a field (in the sense of physics) which is locally represented by a differential 1-form (the “gauge potential”) and whose field strength is locally a differential 2-form. For instance, in the case of the electromagnetic field this differential 2-form is the Faraday tensor.

Roughly speaking, a higher gauge field is similarly a field which is locally represented by differential forms of higher degree.

An explanation as to why an ordinary gauge field has a gauge potential given locally by a differential 1-form $A$ is that the trajectory of a charged particle is a 1-dimensional curve in spacetime $X$, its worldline, hence a smooth function $\gamma \colon \Sigma_1 \to X$, and the canonical way to produce an action functional on the mapping space of such curves is the integration of 1-forms over curves:

This is the parallel transport map or the holonomy map, if $\Sigma_1$ is a closed manifold. The contribution to the Euler-Lagrange equation of the particle obtained from the variation of this action functional is the Lorentz force which is exerted by the background gauge field on the particle.

When one generalizes in this picture from 0-dimensional particles with 1-dimensional worldlines to $p$-dimensional particles (often called “p-branes”) with $(p+1)$-dimensional worldvolumes $\gamma_{p+1} \colon \Sigma_{p+1} \to X$, then one needs, locally, a differential (p+1)-form $A_{p+1}$ on spacetime $X$

The field strength or flux of such a higher gauge field is, accordingly, locally the $(p+2)$-form $F_{p+2}$.

The archetypical example of such a higher gauge field is the (hypothetical) Kalb-Ramond field or B-field (a precursor of the axion field under KK-compactification) to which the charged 1-brane, the “string”, couples. This is locally a differential 2-form $B_2$, and the gauge-coupling term in the action functional for the string is accordingly, locally, of the form

This continues: next one may consider “2-branes”, i.e. membranes, and these will couple to a 3-form gauge field. For instance, the membrane which gives the name to M-theory (the M2-brane) couples to a 3-form field called the supergravity C-field.

But there is an important further aspect to higher gauge fields which makes this simple picture of higher degree differential forms drastically more rich:

Where an ordinary gauge field has gauge transformations $A_1 \mapsto A'_1$ given locally by smooth functions (0-forms) $\lambda_0$ via the de Rham differential $d_{dR}$

so a higher gauge field has higher gauge transformations given locally by $p$-forms $\lambda_p$:

But for $p \gt 0$ then a crucial new effect appears: these gauge transformations, being higher differential forms themselves, have “gauge-of-gauge transformations” between them, given by lower degree forms.

This phenomenon implies that higher gauge fields have a rich global (“topological”) structure, witnessed by the higher analog of their instanton sectors. Namely, while a higher gauge field to which a p-brane may couple is locally given by a $(p+1)$-form $A_{p+1}$, as one moves across coordinate charts this form gauge transforms by a $p$-form, which then itself, as one passes along two charts, transforms by a $(p-1)$-form, and so on.

The global structure for higher gauge fields obtained by carrying out this globalization via higher gauge transformations is the higher analog of that of a fiber bundle with connection on a bundle in higher differential geometry. This is sometimes known as a gerbe or, more generally, a principal infinity-bundle.

In fact the situation that there is just one gauge potential of degree $(p+1)$ with field strength of degree $(p+2)$ is just the simplest case, the “ordinary” case. More abstractly one says that such higher gauge fields are cocycles in ordinary differential cohomology.

More generally it may happen in higher gauge theory that the gauge potential is a formal linear combination of differential forms in various degrees.

The canonical example of this phenomenon is the RR-field in string theory. This has, locally, a gauge potential which is a differential form in every even degree, or every odd degree. If one is careful about the higher gauge transformations in this situation to find the correct global structure (the “instanton sector”) of the higher gauge field, then one finds that this now is a cocycle in a differential generalized cohomology, namely, in what is called differential topological K-theory. This may be understood as a higher and generalized form of the famous Dirac charge quantization condition for the electromagnetic field, see Freed 00. A lot of the fine detail of the anomaly cancellation in type II string theory depends on being careful about the global nature of this K-theoretic higher gauge RR-field (Distler-Freed-Moore 09)

Examples

Among ordinary gauge theories there is

1. “metric” gauge theory:

   1. Maxwell theory,

   2. Yang-Mills theory

2. topological gauge theory:

   • Chern-Simons theory

(as well as mixed cases, such as the ABJM model).

While the fields of these theories are gauge fields of the same kind in all cases (modeled by connections on principal bundles), the nature of these theories is different, not the least because the first class depends on (couples to) a background (pseudo) Riemannian metric (gravity) while the second does not (is a topological field theory).

Moreover, even though Maxwell theory (electromagnetism) may be understood as the special case of Yang-Mills theory for gauge group specialized to the circle group $U(1)$, this makes a crucial difference for the nature of these theories and their higher generalizations.

Some example of higher gauge fields…

1. …of higher Maxwell type:

   the fields appearing in higher-dimensional supergravity theories:

   • Kalb-Ramond field (B-field)

   • RR-field

   • supergravity C-field

2. …of higher Chern-Simons type:

   • AKSZ sigma-models

   • string field

Higher gauge theories of Maxwell type

Consider

• $D = 1 + d \in \mathbb{N}_{\geq 2}$ the spacetime dimension,

• $X^D$ a $D$-dimensional spacetime manifold,

• with Hodge star-operator on differential forms

  $$\star \,\colon\, \Omega^p_{dR}(X^D) \to \Omega^{D-p}_{dR}(X^D)$$

  satisfying (see there)

  $$\star \, \star = - (-1)^{p(D-p)} \,,$$

• $I \,\in\, Set$ an index set of flux species

  (subsuming both electric fluxes and magnetic fluxes, both now allowed of further different species),

• $\big( deg_i \,\in\, \mathbb{N}_{\geq 1} \big)_{i \in I}$ an indexed set of degrees,

• $\vec F \,\equiv\,\big( F^{(i)} \,\in\, \Omega^{deg_i}_{dR}(X^D) \big)_{i \in I}$ an indexed set of flux densities

• $\vec P = \big( P^{(i)} \big)_{i \in I}$ an indexed set of graded-symmetric polynomials in $I$ variables,

• $\vec \mu$ an invertible $I \times I$-matrix

then the corresponding higher Maxwell-type equations on these differential forms/flux densities are, in duality-symmetric form (cf. SS23):

1. the system of Bianchi identity differential equations (cf. at Gauss law)

   (1)$$\mathrm{d}\,\vec F \,=\, \vec P\big( \vec F \big)$$

2. the self-Hodge duality condition

   (2)$$\star \, \vec F \,=\, \vec \mu\big(\vec F\big) \,.$$

The full field content of a higher gauge theory with these flux densities is to involve gauge potentials for these flux densities. A systematic way to get hold of these is to choose a flux quantization law for the given flux densities, defining a (nonabelian) generalized cohomology theory. Then a full higher gauge field is a cocycle in the corresponding (nonabelian) differential cohomology.

Higher gauge theories of Chern-Simons type

See at infinity-Chern-Simons theory

Related entries

• differential nonabelian cohomology

• Wilson surface

• local prequantum field theory

• higher category theory and physics

• adjusted Weil algebra

References

General

Introduction and exposition:

• John Baez, John Huerta, An invitation to higher gauge theory, General Relativity and Gravitation 43 (2011), 2335-2392 (arXiv:1003.4485)

• Luigi Alfonsi, §2 in: Higher geometry in physics, in: Encyclopedia of Mathematical Physics 2nd ed, Elsevier (2024) [arXiv:2312.07308]

• Leron Borsten, Mehran Jalali Farahani, Branislav Jurčo, Hyungrok Kim, Jiří Nárožný, Dominik Rist, Christian Saemann, Martin Wolf, Higher Gauge Theory, in Encyclopedia of Mathematical Physics 2nd ed, Elsevier (2024) [arXiv:2401.05275]

• PhysicsForums-Insights Why higher category theory in physics?

• geometry of physics

• twisted smooth cohomology in string theory

• Examples of prequantum field theories II: Higher gauge fields

For technical introduction to the RR-field as a higher gauge field (for more see at Dirac charge quantization):

• Daniel Freed, Dirac charge quantization and generalized differential cohomology, Surveys in Differential Geometry, Int. Press, Somerville, MA, 2000, pp. 129–194 (arxiv:hep-th/0011220)

• Jacques Distler, Dan Freed, Greg Moore, Orientifold Précis in: Hisham Sati, Urs Schreiber (eds.) Mathematical Foundations of Quantum Field and Perturbative String Theory Proceedings of Symposia in Pure Mathematics, AMS (2011) (arXiv:0906.0795, slides)

Deriving higher gauge symmetries through the variational bicomplex:

• Igor Khavkine, Topology, rigid cosymmetries and linearization instability in higher gauge theories, Annales Henri Poincaré 16 (2015) 255–288, [arXiv:1303.2406, doi:10.1007/s00023-014-0321-9]

The aspect of flux quantization laws:

• Hisham Sati, Urs Schreiber, Flux Quantization on Phase Space [arXiv:2312.12517]

Foundations of higher prequantum field theory:

• Domenico Fiorenza, Chris Rogers, Urs Schreiber, Higher geometric prequantum theory

For foundations of higher gauge theory formalized in homotopy type theory see

• Urs Schreiber, Mike Shulman, Quantum gauge field theory in Cohesive homotopy type theory

On higher gauge theory in condensed matter physics:

• Chenchang Zhu, Tian Lan, Xiao-Gang Wen, Topological non-linear σ-model, higher gauge theory, and a realization of all 3+1D topological orders for boson systems [arXiv:1808.09394]

• J.P. Ang, Abhishodh Prakash, Higher categorical groups and the classification of topological defects and textures, (arXiv:1810.12965)

Specifically on topological phases of matter via higher lattice gauge theory:

• Joe Huxford, The higher lattice gauge theory model for topological phases of matter, PhD thesis, Oxford (2022) [uuid:e789bf29-179b-4b79-9168-605bf8c035ba, pdf]

• Joe Huxford, Steven H. Simon, Excitations in the Higher Lattice Gauge Theory Model for Topological Phases I: Overview [arXiv:2202.08294]

Further on higher lattice gauge theory:

• Juan Orendain, José A. Zapata, Higher homotopy and lattice gauge fields [arXiv:2311.02363]