Contents

Idea

In physics, specifically in field theory, a gauge field is a type of field in gauge theory. In the standard model of particle physics, gauge fields are the force fields whose quanta are bosons, in contrast to matter-fields whose quanta are fermions.

The eponymous property of gauge fields is that they are identified only up to equivalences called gauge transformations.

The archetypical example of a gauge field is the electromagnetic field in (classically) electromagnetism and (quantumly) in quantum electrodynamics.

The most widely considered kind of gauge field, often the one understood by default, is a non-abelian generalization of electromagnetism, generally called the Yang-Mills field, of which specific instances are the gluon-field in quantum chromodynamics carrying the strong nuclear force, and a similar field carrying the weak nuclear force.

Mathematically, field configurations of such “ordinary” gauge fields are:

• locally identified with Lie algebra-valued differential forms, whose curvature 2-form (just the de Rham differential in the abelian case) is to be understood as the flux density that the gauge fields imprints on spacetime,

• globally identified with connections on principal bundles, whose structure group is then called the gauge group of the field.

The eponymous gauge transformations between gauge fields are thereby identified with isomorphisms between these connections.

The isomorphism class of the underlying principal bundles, hence its class in nonabelian cohomology, reflects the “topological charge” carried by the gauge field, attributed to solitonic field configurations such as Abrikosov vortices, magnetic monopoles and instantons.

(To some extent also the gravitational field behaves like a gauge field with structure/gauge group a Poincaré group, but a further soldering-constraint makes gravity be described more specifically by Cartan connections which are often not counted under “gauge fields” – see at first-order formulation of gravity for more on this.)

Much technology in variational calculus for Lagrangian field theory and subsequent quantization-procedures has been and is being developed already for handling gauge fields with their gauge transformations just locally – common machinery is known as “BRST-BV-formalism” or variants thereof.

Comparatively less attention has traditionally been paid to the global aspects of gauge fields (for instance available BRST-BV formalism does not really reflect or handle them). But realizing that connections on $U(1)$-principal bundles globally describing the electromagnetic field are equivalently 2-cocycles in ordinary differential cohomology, and that connections on general principal bundles may still be understood as cocycles in nonabelian differential cohomology, it is helpful to understand the global nature of gauge fields generally as reflected by notions of cohomology:

This cohomological perspective is particularly apt for generalizations of gauge fields such as to (hypothetical) higher gauge fields. For instance, the RR-fields of type II supergravity/type II string theory have famously been conjectured to be cocycles in (twisted equivariant differential) topological K-theory instead of ordinary cohomology.

Related concepts

• gauge theory

• gauge transformation

• gauge fixing

• gauge invariance

• higher gauge field

References

For the time being see the references at gauge theory.