Induced Electric Fields of metal ring

In summary, the conversation is discussing the calculation of the induced electric field in a metal ring placed between two magnets with a gradually decreasing magnetic field. The magnitude of the electric field is found by using the equation for change in magnetic flux and the area of the ring. The direction of the induced current is determined by the direction of the changing magnetic flux, in this case, clockwise.
  • #1
aznkid310
109
1

Homework Statement



A metal ring 4.50 cm in diameter is placed between the north and south poles of large magnets with the plane of its area perpendicular to the magnetic field. These magnets produce an initial uniform field of 1.12 T between them but are gradually pulled apart, causing this field to remain uniform but decrease steadily at 0.250 T/s.

(a) What is the magnitude of the electric field induced in the ring?

(b) In which direction (clockwise or counterclockwise) does the current flow as viewed by someone on the south pole of the magnet?

Homework Equations



Do i need to do anything with the initial B value?

Change in flux dB/dt = -0.25t?

Or is it dB/dt = 1.12 - 0.25t?

The Attempt at a Solution



a) d[phi]/dt = (dB/dt)*Acos(0) = (-0.250)*(pi(2.25*10^-2)^2) = -3.98*10^-4 Wb

E = (1/2r*pi)*(d[phi]/dt) = -2.8*10^-3 N/C

b) Clockwise?
 
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  • #2
Hi aznkid310,

I don't believe your answer to part b is correct. Can you explain your reasoning for that part?
 
  • #3
induced emf = - (change in magnetic flux)

Since magnetic flux is decreasing, an induced magnetic field opposite to that must be created to counteract this change in flux. Is my reasoning off?

Also, is part (a) correct?
 
  • #4
Your answer to part a looks right to me (except they want the magnitude of the field, so you don't need the negative sign).

aznkid310 said:
induced emf = - (change in magnetic flux)

Since magnetic flux is decreasing, an induced magnetic field opposite to that must be created to counteract this change in flux. Is my reasoning off?

Also, is part (a) correct?

The induced magnetic field will be in the direction to oppose the change. Since the magnetic flux from the magnets is decreasing, the induced magnetic field will be in the same direction as the magnet's field. Does that make sense?
 
  • #5
Ah that makes sense. It would oppose only if the magnetic flux is incresing right?
 
  • #6
It always opposes the change, so if the magnetic flux is increasing, then yes, the induced field will be in the opposite direction as the external flux.
 

Related to Induced Electric Fields of metal ring

What is an induced electric field of a metal ring?

An induced electric field of a metal ring is a type of electric field that is created when a changing magnetic field passes through the ring. This causes the free electrons in the metal to move, generating an electric field around the ring.

How is an induced electric field of a metal ring different from a permanent electric field?

The main difference between an induced electric field and a permanent electric field is that an induced electric field is temporary and only exists when there is a changing magnetic field, while a permanent electric field exists continuously.

What factors affect the strength of the induced electric field in a metal ring?

The strength of the induced electric field in a metal ring is affected by the rate of change of the magnetic field, the radius of the ring, and the material of the ring. A larger rate of change and a smaller radius will result in a stronger induced electric field. Additionally, materials with higher conductivity will have a stronger induced electric field.

Can the direction of the induced electric field be changed?

Yes, the direction of the induced electric field can be changed by changing the direction of the changing magnetic field. This is known as Faraday's law of induction.

What are some real-world applications of induced electric fields of metal rings?

Induced electric fields of metal rings are commonly used in generators to convert mechanical energy into electrical energy. They are also used in transformers to increase or decrease the voltage of an electrical current. Additionally, they are used in some scientific experiments to study the behavior of electric and magnetic fields.

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