Induced EMF through variable-resistance-wire due to Faraday's Law

In summary, the conversation discusses Faraday's Law of Induction and the effects of resistance on the induced electric field and emf in a circular loop of wire. While the emf is independent of resistance, self-induction must be taken into account when resistance is low. The induction motor is a clear example where self-induction cannot be ignored.
  • #1
DocZaius
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11
Hello,

While considering Faraday's Law of Induction, I tried to think of a situation which would expose some difficulties I have with the notion that there is an induced EMF without clear regions of relatively high and low voltage (as in a battery). Here is what I thought would get me started:

Consider a circular loop of wire. The top half is made of wire twice as resistant as the bottom half. A uniform magnetic field changes with time through the surface bounded by the loop. Is the (induced) electric field at a point at the top of the loop equal to the electric field at a point diametrically opposed (and therefore in a part of the loop half as resistant)?

Faraday's Law seems to make a statement about the EMF induced around the whole loop, but not how it would vary within that loop due to changes in resistance. Or does it?

edit: Remove a mistaken consideration.

Thanks for any help!
 
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  • #2
It doesn't. The emf is independent of the resistance of the loop, and you could perfectly well talk about the emf around an imaginary path in a vacuum - which also has the value dphi/dt. The cross-section and material of the conductor determine the current that flows as a result. This must be the same all round the loop, even if the top half has a different resistance from the bottom half. Their combined resistance (in series), together with the emf, determines the current.

[I've ignored self-inductive effects, that is emfs arising from changing magnetic flux due to changing current in the loop itself. These emfs DO depend, for obvious but indirect reasons, on the resistance of the loop.]
 
  • #3
So to put some figures to it (ignoring self inductive effects): Let's say the top half of the loop has resistance 2R and the bottom half has resistance R. If the induced EMF is V, then is it safe to say that the current around the loop will be constant throughout and equal to (V/3R)?
 
  • #4
Yes.
 
  • #5
Philip Wood said:
It doesn't. The emf is independent of the resistance of the loop, and you could perfectly well talk about the emf around an imaginary path in a vacuum - which also has the value dphi/dt. The cross-section and material of the conductor determine the current that flows as a result. This must be the same all round the loop, even if the top half has a different resistance from the bottom half. Their combined resistance (in series), together with the emf, determines the current.

[I've ignored self-inductive effects, that is emfs arising from changing magnetic flux due to changing current in the loop itself. These emfs DO depend, for obvious but indirect reasons, on the resistance of the loop.]

Actually the emf does indeed vary with resistance. A low resistance loop results in lower emf than a high R loop. I posted equations a few years ago detailing this. I'll find it and repost. When current exists in the loop it has a magnetic flux that opposes the external flux per law of Lenz.

With high R, the emf is independent of the R value as long as the induced current;s magnetic flux is too small to oppose the external flux. But with low R values, voltages varies with R due to cancellation of external flux by the internal flux.

Dr. Walter Lewin at MIT has a lecture note regarding a loop with 2 different R values. The emf along the high R section is higher. I'll dig that up as well. Cheers.

Claude
 
  • #7
Cabraham: the effect to which you are drawing attention is none other than the self-induction which I mentioned in the second paragraph of my original post.
 
  • #8
Philip Wood said:
Cabraham: the effect to which you are drawing attention is none other than the self-induction which I mentioned in the second paragraph of my original post.

But when the loop R is low, self-induction cannot be ignored. Your mention in the 2nd paragraph is valid only with the condition that R is a high value.

A classic example is the induction motor. The R value of the squirrel cage rotor is extremely low. Without considering self-induction, the induction motor cannot be discussed. One cannot completely explain induction motor behavior w/o self-induction.

Ignoring self-induction and only considering mutual induction is only conditionally valid. The squirrel cage induction motor is a clear case of where self-induction cannot be ignored.

That is all I'm saying. I agree with you that if the R value is high enough so that self-induction is very small relative to mutual induction, then the value of R can vary with negligible influence on induced emf.

Claude
 
  • #9
We are completely in agreement. I didn't mean to imply in my original post that it was always fine to ignore self-induction, just that I had done so in my first paragraph! But re-reading the post, I understand that this could have been misleading.
 

1. What is induced EMF?

Induced EMF (electromotive force) is the voltage or potential difference that is generated in a circuit due to a changing magnetic field. It is a result of Faraday's Law, which states that a changing magnetic field induces an electric field.

2. How is induced EMF produced through variable-resistance-wire?

In a variable-resistance-wire, the resistance of the wire changes as it experiences a changing magnetic field. This change in resistance creates a current in the wire, which in turn generates an induced EMF. This is known as electromagnetic induction.

3. What is Faraday's Law and how does it relate to induced EMF?

Faraday's Law is a fundamental law of electromagnetism that states that a changing magnetic field will induce an electric field. This electric field, in turn, produces an induced EMF in a conductor. Faraday's Law is the basis for understanding how generators and transformers work.

4. What are some real-life applications of induced EMF through variable-resistance-wire?

Induced EMF through variable-resistance-wire is used in various devices, such as generators, transformers, and electric motors. It is also utilized in technologies like wireless charging and electromagnetic braking systems. Furthermore, it plays a crucial role in the functioning of electronic sensors and detectors.

5. How can we calculate the induced EMF in a variable-resistance-wire?

The induced EMF in a variable-resistance-wire can be calculated using Faraday's Law, which states that the induced EMF is equal to the rate of change of magnetic flux through the wire. This can be expressed as E = -N(dΦ/dt), where E is the induced EMF, N is the number of turns in the wire, and dΦ/dt is the change in magnetic flux over time.

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