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Field Theory Gauge symmetry is a Book I topic in the Quantum Collection. Gauge symmetry in quantum field theory is a fundamental principle stating that certain transformations of the fields leave the physical predictions of a theory unchanged. These symmetries determine the form of interactions and require the existence of gauge fields that mediate forces. Gauge symmetry: local transformations of fields requiring compensating gauge fields to preserve invariance Gauge symmetry in quantum field theory is a fundamental principle stating that certain transformations of the fields leave the physical predictions of a theory unchanged. These symmetries determine the form of interactions and require the existence of gauge fields that mediate forces. A symmetry transformation changes the fields without affecting observable quantities.

Global and local symmetry

A symmetry transformation changes the fields without affecting observable quantities.

A global symmetry uses the same transformation everywhere: $ψ (x) \to e^{i α} ψ (x)$

A local symmetry allows the transformation parameter to vary with space-time: $ψ (x) \to e^{i α (x)} ψ (x)$

Local symmetry is much more restrictive and leads directly to interactions.^[1]

Emergence of gauge fields

A naive local transformation introduces extra terms in derivatives: $\partial_{μ} ψ (x) \to (\partial_{μ} + i \partial_{μ} α (x)) ψ (x)$

To restore invariance, a gauge field $A_{μ} (x)$ is introduced and the derivative is replaced by the covariant derivative: $D_{μ} = \partial_{μ} + i g A_{μ}$

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-'''Gauge symmetry in quantum field theory''' is a fundamental principle stating that certain transformations of the fields leave the physical predictions of a theory unchanged.<ref name="weinberg">Weinberg, S. ''The Quantum Theory of Fields'' (1995).</ref> These symmetries determine the form of interactions and require the existence of gauge fields that mediate forces.
+'''Field Theory Gauge symmetry''' is a Book I topic in the Quantum Collection. Gauge symmetry in quantum field theory is a fundamental principle stating that certain transformations of the fields leave the physical predictions of a theory unchanged. These symmetries determine the form of interactions and require the existence of gauge fields that mediate forces. Gauge symmetry: local transformations of fields requiring compensating gauge fields to preserve invariance Gauge symmetry in quantum field theory is a fundamental principle stating that certain transformations of the fields leave the physical predictions of a theory unchanged. These symmetries determine the form of interactions and require the existence of gauge fields that mediate forces. A symmetry transformation changes the fields without affecting observable quantities.</div>
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-<div style="font-size:90%;">Gauge symmetry: local transformations of fields requiring compensating gauge fields to preserve invariance</div>
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Physics:Quantum Field Theory Gauge symmetry: Difference between revisions

Revision as of 08:16, 20 May 2026

Global and local symmetry

Emergence of gauge fields

Gauge invariance

Example: Quantum electrodynamics

Non-Abelian gauge theories

Field strength tensor

Physical interpretation

Conceptual importance

See also

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