Maxwell's equations from U(1) symmetry

In summary, the inhomogeneous pair of Maxwell's equations can be derived from varying the field strength tensor Lagrangian, while the homogeneous pair results from adding a term for coupling to matter. Imposing U(1) gauge invariance leads to the Maxwell's equations, which can be derived from the field tensor Lagrangian. The introduction of a covariant derivative may be confusing, but it is necessary for maintaining the symmetry of the theory. The justification for adding the vector potential and transformation rule is the agreement with experimental results. Non-abelian gauge theories were discovered to be relevant for describing strong and weak nuclear interactions.
  • #1
Thoros
23
1
I understand that one is able to derive the inhomogenuous pair of Maxwell's equations from varying the field strength tensor Lagrangian.

Now implying the U(1) gauge invariance, how is one led to the Maxwell's equations?
 
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  • #2
Thoros said:
I understand that one is able to derive the inhomogenuous pair of Maxwell's equations from varying the field strength tensor Lagrangian [...]

No, the homogenous pair results that way. To get the inhomogenous ones you need to add in a term for coupling to (charged) matter.

[...] Now implying the U(1) gauge invariance, how is one led to the Maxwell's equations?

From a geometric perspective, U(1) is embedded in the field.
 
  • #3
Sorry about that, you are right about the lagrangian.

From a geometric perspective, U(1) is embedded in the field.

Could you give me a few hints on how to do it explicitly or is this already enough to manage with the task of deriving the equations?

Thanks.
 
  • #5
Alright so i reached the point where you get an interaction term in the lagrangian density leading to the inhomogenuous pair of Maxwell's equations.

But to me the intrudiction of a covariant derivative is a little confusing. It seems perfectly reasonable to require that physics stay the same under U(1) symmetry. But adding the vector potential and simply implying an ad hoc transformation rule seems unjustifiable. Also, why do we have to add the elementary charge and planks constant to it? Is this required from dimensional analysis?

And from the Wikipedia article i understand, that the homogenuous pair still only arises from the same old field tensor Lagrangian.

Can anyone clear it up for me?

Thanks.
 
  • #6
Thoros said:
It seems perfectly reasonable to require that physics stay the same under U(1) symmetry. But adding the vector potential and simply implying an ad hoc transformation rule seems unjustifiable.
It is only justified by the fact that we end up with a theory that agrees with experiment. If gauge theories did not agree with experiment, only mathematicians (and not physicists) would care about them.

You cannot derive Maxwell's equations (or any other physical theory) from pure logic. All you can do is find out which theories agree with experiment, and then subsequently notice any cool mathematical features that they might happen to have (such as gauge invariance).

Actually, that's a little too strong. Quantum electrodynamics is an abelian gauge theory, and by 1950 or so it was well established that it agreed with experiment. This success motivated theoretical investigations of nonabelian gauge theories, which ultimately turned out to be relevant for the description of both strong nuclear and weak nuclear interactions (though it took a long time and travel down several wrong roads before the precise connection was understood).
 

1. What are Maxwell's equations from U(1) symmetry?

Maxwell's equations from U(1) symmetry, also known as Maxwell's equations in vacuum, are a set of four partial differential equations that describe the behavior of electric and magnetic fields in space. They were first derived by James Clerk Maxwell in the 19th century and are fundamental to the study of electromagnetism.

2. What is U(1) symmetry?

U(1) symmetry is a mathematical concept that describes the invariance of a physical system under rotations or transformations in a one-dimensional space. In the case of Maxwell's equations, U(1) symmetry refers to the fact that the equations remain unchanged when the electric and magnetic fields are rotated or transformed in a one-dimensional space.

3. How are Maxwell's equations derived from U(1) symmetry?

Maxwell's equations are derived from U(1) symmetry by applying the principle of least action, which states that a physical system will take the path of least resistance to reach a state of equilibrium. In the case of electromagnetism, this leads to the four partial differential equations that make up Maxwell's equations.

4. What are the implications of U(1) symmetry for Maxwell's equations?

The implications of U(1) symmetry for Maxwell's equations are that they provide a unified framework for understanding the behavior of electric and magnetic fields. This symmetry allows for the prediction and explanation of phenomena such as electromagnetic waves, the propagation of light, and the behavior of charged particles in electric and magnetic fields.

5. How have Maxwell's equations from U(1) symmetry impacted science and technology?

Maxwell's equations from U(1) symmetry have had a profound impact on science and technology. They have allowed for the development of technologies such as radio, television, and cell phones, which all rely on the principles of electromagnetism. They have also led to advances in our understanding of the universe, such as the discovery of electromagnetic radiation from distant stars and galaxies.

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