How does U(1) guage symmetry lead to Maxwell's equations?

In summary: Can Maxwell's equations be derived from the premise of U(1) gauge symmetry? If so, how?One way to get Maxwell's equations from U(1) symmetry is to use the Lorentz force. Maxwell's equations are invariant under Lorentz transformations and the Lorentz force is a consequence of U(1) symmetry.Do Maxwell's equations imply U(1) symmetry?No, Maxwell's equations are not implied by U(1) symmetry. However, U(1) symmetry is a necessary condition for the validity of Maxwell's equations.
  • #1
cygnet1
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Here are some questions that have been puzzling me about symmetry and charge. Any answers to any of these questions would be very helpful. Thank you.

What does U(1) gauge symmetry mean? Does anyone have a simple explanation?

Can Maxwell's equations be derived from the premise of U(1) gauge symmetry? If so, how?

Do Maxwell's equations imply U(1) symmetry?

Is there an operator to obtain the electric charge of a particle from its quantum state?
 
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  • #2
cygnet1 said:
Here are some questions that have been puzzling me about symmetry and charge. Any answers to any of these questions would be very helpful. Thank you.

What does U(1) gauge symmetry mean? Does anyone have a simple explanation?

Can Maxwell's equations be derived from the premise of U(1) gauge symmetry? If so, how?

Do Maxwell's equations imply U(1) symmetry?

Is there an operator to obtain the electric charge of a particle from its quantum state?

U(1) gauge symmetry means your physics doesn't change if you add a term of the form exp(i*f(x)) (this is a local gauge symmetry, for a global one f(x) is a constant). If one thinks of the simplest terms one can write down in a Lagrangian which are unchanged by such a transformation (and are Lorentz invariant) you get what turns out to be Maxwell's Equations.Also, you could make a trivial operator but charge is always conserved in QM (or rather charge-parity-time reversal is for QFT as well) so it hardly matters.
 
  • #3
cygnet1 said:
What does U(1) gauge symmetry mean? Does anyone have a simple explanation?

In physical terms it means that the partial differential equations are insensitive to boundary values of the potentials. Since the Maxwell equations are founded on U(1) symmetry they give you gauge freedom for the potentials.

Equations which comply to SU(2) symmetry for example, as often used in QM, are sensitive to boundary conditions for potentials.
 

1. What is U(1) gauge symmetry?

U(1) gauge symmetry is a mathematical concept in the field of quantum field theory. It refers to the invariance of the laws of physics under certain transformations, specifically rotations in a complex plane. In simpler terms, it means that the equations describing physical phenomena remain unchanged regardless of how we choose to orient our coordinate system.

2. How does U(1) gauge symmetry relate to electromagnetism?

Maxwell's equations are a set of fundamental equations that describe the behavior of electromagnetic fields. U(1) gauge symmetry is the mathematical framework that underlies these equations. In other words, U(1) gauge symmetry is the fundamental principle that leads to the equations of electromagnetism.

3. Can you explain the connection between U(1) gauge symmetry and the electromagnetic potential?

In U(1) gauge symmetry, the electromagnetic potential is considered a gauge field. This means that it transforms in a specific way under U(1) transformations. By incorporating this transformation into the equations, we can derive Maxwell's equations, which describe the behavior of electromagnetic fields.

4. How does U(1) gauge symmetry account for the existence of electric and magnetic fields?

In U(1) gauge symmetry, the electric and magnetic fields are described as components of the electromagnetic potential. By applying the principles of U(1) gauge symmetry to the electromagnetic potential, we can derive equations that describe the behavior of these fields, including the well-known Maxwell's equations.

5. What are some practical applications of U(1) gauge symmetry and Maxwell's equations?

The principles of U(1) gauge symmetry and Maxwell's equations have numerous practical applications, including the design and functioning of electronic devices, communication systems, and power grids. They also play a crucial role in the development of technologies such as radar, MRI machines, and particle accelerators.

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