A coil of area and turns is rotating with angular velocity in a uniform magnetic field about an axis perpendicular to . Magnetic flux and induced emf across it, at an instant when is parallel to the plane of the coil, are:
- A
- B
- C
- D
A coil of area and turns is rotating with angular velocity in a uniform magnetic field about an axis perpendicular to . Magnetic flux and induced emf across it, at an instant when is parallel to the plane of the coil, are:
Correct answer:C
Standard Method
Given: A coil of area and turns rotates with angular velocity in a uniform magnetic field . The magnetic field is parallel to the plane of the coil at the required instant.
Find: Magnetic flux and induced emf at that instant.
Magnetic flux through the coil is
where is the angle between and the normal to the plane of the coil.
When is parallel to the plane of the coil, it is perpendicular to the normal. Hence,
and therefore
For a rotating coil, Faraday's law gives
If
then
At the instant when , the rate of change of flux is maximum, so
Therefore, the magnetic flux is and the induced emf is . Hence, the correct option is C.
Discrepancy noted: The answer key and the solution mark option D, but the worked solution clearly concludes and , which matches option C.
Using Coil Orientation
Given: is parallel to the plane of the coil.
Find: The values of and .
The important orientation fact is that magnetic flux depends on the component of along the area vector. When the field lies in the plane of the coil, the field has zero component along the normal.
So,
However, the coil is rotating, so this zero flux is changing instantaneously at the maximum rate. Therefore the induced emf is maximum:
Thus the required pair is and , so the correct option is C.
Taking the angle with the plane of the coil instead of with the normal. Flux uses the angle between and the area vector, not the plane itself. When is parallel to the plane, the angle with the normal is , so use .
Assuming zero flux means zero emf. That is incorrect because emf depends on the rate of change of flux, not the flux value alone. At this orientation, the flux is zero but changing most rapidly, so the emf is maximum.
Ignoring the factor in Faraday's law. For a coil of turns, the induced emf is . Omitting gives the wrong magnitude.
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