Non-Abelian gauge theory is a class of quantum field theories in which the underlying gauge symmetry group is non-commutative, meaning that the order of symmetry transformations matters.^[1] These theories generalize Abelian gauge theories such as quantum electrodynamics and form the foundation of the strong and weak interactions.

Non-Abelian gauge symmetry: interacting gauge fields arising from non-commuting symmetry generators

In Abelian gauge theories, such as ${\displaystyle U(1)}$, the group elements commute: ${\displaystyle T_a{T}_b=T_b{T}_a}$

In contrast, non-Abelian groups such as ${\displaystyle SU(N)}$ satisfy: ${\displaystyle [T_a,T_b]=i{f}_{abc}{T}_c}$

where ${\displaystyle f_{abc}}$ are the structure constants of the group.^[2]

This non-commutativity leads to fundamentally new physical features.

To maintain local gauge invariance, one introduces multiple gauge fields ${\displaystyle A_{\mu }^a(x)}$, one for each generator of the symmetry group.

The covariant derivative becomes: ${\displaystyle D_{\mu }={\partial }_{\mu }+ig{A}_{\mu }^a{T}_a}$

where:

• ${\displaystyle T_a}$ are the generators
• ${\displaystyle g}$ is the coupling constant

This structure ensures invariance under local transformations of the non-Abelian group.^[3]

The field strength tensor generalizes to: ${\displaystyle F_{\mu \nu }^a={\partial }_{\mu }{A}_{\nu }^a-{\partial }_{\nu }{A}_{\mu }^a+g{f}_{abc}{A}_{\mu }^b{A}_{\nu }^c}$

The additional term: ${\displaystyle g{f}_{abc}{A}_{\mu }^b{A}_{\nu }^c}$

arises from the non-commuting nature of the group and leads to self-interactions of the gauge fields.^[1]

Unlike Abelian theories, non-Abelian gauge fields carry the charge associated with the symmetry.

This means that:

• gauge bosons can interact with each other
• the theory is inherently nonlinear

These self-interactions are essential for understanding the behavior of the strong and weak forces.

Important non-Abelian gauge groups include:

• ${\displaystyle SU(3)}$ → quantum chromodynamics (QCD)
• ${\displaystyle SU(2)}$ → weak interaction

These groups describe the internal symmetries of fundamental particles and determine how they interact.

Non-Abelian gauge theories are often called Yang–Mills theories, after Yang and Mills who first formulated them.^[4]

The Yang–Mills Lagrangian is: ${\displaystyle {ℒ}=-\frac{1}{4}{F}_{\mu \nu }^a{F}^{\mu \nu a}}$

This describes the dynamics of the gauge fields and their interactions.

Non-Abelian gauge theories exhibit rich physical phenomena:

• confinement in QCD
• asymptotic freedom at high energies
• spontaneous symmetry breaking (in extended models)

These features distinguish them from simpler Abelian theories.

Non-Abelian gauge theories form the backbone of modern particle physics. They explain:

• the structure of strong and weak interactions
• the behavior of gauge bosons
• the organization of the Standard Model

They represent a profound generalization of the gauge principle.

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1. Physics:Quantum basics

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67. Physics:Quantum Time evolution

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