Is the usual non-abelian gauge field A real or complex?

In summary, the usual non-abelian gauge field A can be either real or complex depending on the theory being studied, and it is significant because it allows for more complex interactions between particles. It is intimately related to gauge symmetry and can be indirectly observed through its interactions with other particles. The gauge field is responsible for mediating interactions and determining the properties of particles, making it a crucial component of our understanding of the physical world.
  • #1
popwolf
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0
If it's complex how could one calculate the 2 points function of A(+) and A? Thanks
 
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  • #2
Gauge fields are real. They are in the adjoint representations of the gauge groups, which are real representations. On a related note, you can show that if you have a collection of fieldstrengths that can only be expressed in the Lagrangian as complex combinations, then you cannot define vector potentials corresponding to these complex fieldstrengths. Therefore, you cannot have gauge fields in a theory if the corresponding fieldstrengths in the theory are complex.
 
  • #3


The usual non-abelian gauge field A is typically complex. This is because the gauge group in non-abelian gauge theories, such as the Standard Model of particle physics, is a non-commutative group. This means that the generators of the gauge group do not commute with each other, and therefore the gauge field must be a complex field in order to properly describe the interactions between particles.

To calculate the 2-point function of A(+) and A, one would use the standard techniques of quantum field theory. This involves performing perturbative calculations using Feynman diagrams, where the complex gauge field is represented as a propagating particle. The 2-point function can then be obtained by summing over all possible Feynman diagrams that contribute to this quantity.

It is important to note that the complex nature of the gauge field does not affect the physical observables in the theory. These observables, such as particle masses and scattering cross-sections, are always real quantities. The complex nature of the gauge field is simply a mathematical tool used to accurately describe the underlying physics of non-abelian gauge theories.
 

1. Is the usual non-abelian gauge field A real or complex?

The usual non-abelian gauge field A can be either real or complex, depending on the specific theory being studied. In some theories, such as quantum chromodynamics (QCD), the gauge field is real and describes the interactions between quarks and gluons. In other theories, such as the electroweak theory, the gauge field is complex and describes the interactions between particles such as electrons and neutrinos.

2. What is the significance of the gauge field being non-abelian?

The term "non-abelian" refers to the fact that the gauge field does not follow the rules of abelian symmetry, which states that the order of operations does not affect the final outcome. This is significant because it allows for more complex and diverse interactions between particles, leading to a richer and more accurate description of the physical world.

3. How is the gauge field related to gauge symmetry?

The gauge field is intimately connected to gauge symmetry, as it is the mathematical object that describes the gauge symmetry transformations. These transformations are used to maintain the same physical properties of a system while changing its underlying mathematical description, making the gauge field an essential component of gauge theories such as the Standard Model.

4. Can the gauge field be observed experimentally?

Yes, the gauge field can be indirectly observed through its interactions with other particles. For example, in particle accelerators, scientists can study the behavior of particles and their interactions, providing evidence for the existence of the gauge field. Additionally, the effects of the gauge field can be observed in various physical phenomena, such as the weak nuclear force and the strong nuclear force.

5. How does the gauge field affect the behavior of particles?

The gauge field is responsible for mediating the interactions between particles, such as the electromagnetic force between charged particles. It also plays a crucial role in determining the properties of particles, such as their mass and charge. Without the gauge field, particles would not be able to interact with each other, and the physical world as we know it would not exist.

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