What is the physical meaning behind the energy of an electric field?

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SUMMARY

The discussion centers on the intrinsic energy of an electric field, represented by the equation U_e = ∫(1/2)εE² dτ. Participants explore the motivation for assigning energy to electric fields, emphasizing that electromagnetic waves transfer energy and that the energy resides in the electric (E) and magnetic (B) fields during transfer. The conversation also highlights practical applications, such as the energy stored in magnetic fields in MRI systems and the challenges of safely dissipating this energy during magnet quenching.

PREREQUISITES
  • Understanding of electric fields and potentials
  • Familiarity with the equation U_e = ∫(1/2)εE² dτ
  • Knowledge of electromagnetic wave behavior
  • Basic principles of energy storage in magnetic fields
NEXT STEPS
  • Study the derivation of U_e = ∫(1/2)εE² dτ in detail
  • Learn about the energy density in electric fields and its applications
  • Research the role of electric fields in electromagnetic wave propagation
  • Investigate the energy management techniques in MRI systems
USEFUL FOR

Physicists, electrical engineers, and students studying electromagnetism or energy transfer in electric fields will benefit from this discussion.

Tac-Tics
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I understand the notion that an electric field admits an electric potential field, giving the energy per unit charge at each point in space. But I don't understand what is meant when someone says the field itself has energy.

Can anyone explain the motivation behind assigning an energy to an electric field? How can this energy be transformed to other forms of energy? What experiments make use of this idea?
 
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A really, really good motivator is that it's a lot easier to deal with scalar quantities such as potential energy over electric fields when calculating things such as forces.
 
Feldoh said:
A really, really good motivator is that it's a lot easier to deal with scalar quantities such as potential energy over electric fields when calculating things such as forces.

Again, I'm not talking about the electric potential of the field. I'm talking about the intrinsic energy of the field, given by the equation:

<br /> U_e=\int_{\tau}\frac{1}{2}\epsilon E^2 d\tau<br />

So another way to phrase my question is where does this equation come from?
 
Tac-Tics said:
Can anyone explain the motivation behind assigning an energy to an electric field? How can this energy be transformed to other forms of energy? What experiments make use of this idea?

For one thing, electromagnetic waves transfer energy. If the energy doesn't reside in the E and B fields while it's in the process of being transferred, where is it?
 
Tac-Tics said:
Can anyone explain the motivation behind assigning an energy to an electric field? How can this energy be transformed to other forms of energy? What experiments make use of this idea?
My favorite derivation is here: http://farside.ph.utexas.edu/teaching/em/lectures/node89.html

As far as what experiments make use of the idea, it is well known in MRI that there is a huge amount of energy stored in the magnetic field. When a magnet quenches one of the primary challenges is to dissapate all of that energy safely. Luckily, you can dump a lot of energy into liquid nitrogen as long as you can vent the nitrogen somewhere where it will not asphyxiate people.
 
Since the post above contains the math (which I am going to have to ponder) I will present another more nonmathematical view that helps me understand your question.

If an electric field exists it can imply that a charged object exists somewhere that produced that field. If you tried to bring another object with the same charge into that field and move it closer and closer to the charge that created that field, it would require that you do work against that field. You would have to use a force to drag that new charge closer to the original charge. So by this reasoning an electric field automatically implies for me an imbalance. Imbalances of any type intrisically have potential energy in my world.

Now that equation looks very much like the energy density little u in some texts (energy per unit volume) that exists in a uniform electric field like between the plates of a capacitor. u = 1/2*epsilon*E^2. But since you are not necessarily looking at a uniform E field it would require summing up (the integral sign) with respect to the position within that electric field since it is not necessarily uniform. You have prodded me to look at the math in the post above a little closer as it is difficult for me to put the math with the idea sometimes. And maybe I am way off in my nonmathematical explanation or it needs to be cleaned up.
 

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