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Magnetic Flux
Faraday's Law & Lenz Law
Motional emf
Self - Inductance
Mutual Inductance
LR circuit
Eddy Current
Q. No.
In the circuit shown in the adjoining figure, the switch was kept at the position \('1'\) for a long time. The switch \(K\) is suddenly (and smoothly) shifted to position \('2'.\)
The current through the cell, just after the shift, is:
1. \(\dfrac{V_0}{2R}\) 2. \(\dfrac{V_0}{R}\)
3. \(\dfrac{3V_0}{4R}\) 4. zero
Subtopic:  LR circuit |
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Faraday's law of electromagnetic induction is used in the operation of:
1. metal detectors
2. jet engines
3. electromagnets
4. LEDs
Subtopic:  Faraday's Law & Lenz Law |
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A circular wire of radius \(R\) is placed in a uniform magnetic field \(B,\) which acts into the plane as shown. The wire is given a half-turn about a diameter. The resistance per unit length of the wire is \(\lambda.\) The total charge flowing through the wire is:
                              

 
1. \(\dfrac{2BR}{\lambda}\) 2. \(\dfrac{BR}{\lambda}\)
3. \(\dfrac{BR}{2\lambda}\) 4. zero
Subtopic:  Motional emf |
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A triangular wire frame, in the form of an equilateral triangle \(PQR\) moves with a uniform velocity into a region where there is a uniform magnetic field \(B\). The edge \(PQ\) is parallel to the boundary of the region and the velocity \(v\) is perpendicular to it. The emf(\(E\)) induced within the frame is plotted as a function of time \(t,\) starting from when the frame enters the magnetic field. \(E\) is given by:
1. \(Bv^2t\) 2. \(2Bv^2t\)
3. \(\dfrac{\sqrt3}{2}Bv^2t\) 4. \(\dfrac{2}{\sqrt3}Bv^2t\)
Subtopic:  Motional emf |
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The current through the inductor in the figure is initially zero. The initial rate of change of the current \(i\) through the inductor (i.e. \(\dfrac{di}{dt}\)) is:
           
 
1. zero 2. \(-\dfrac{I_{0} R}{L}\)
3. \(\dfrac{I_{0} R}{L}\) 4. \(\dfrac{I_{0} R}{2L}\)
Subtopic:  LR circuit |
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A parallel plate capacitor is being charged by means of a constant current \(i.\) The plates are circular (of radius \(R)\) and are separated by a distance \(d.\) The magnetic field between the plates, at a distance \(\dfrac{R}{2}\) from the central axis is:
1. zero 2. \(\dfrac{\mu_{0} i}{2 \pi \left(\dfrac{R}{2}\right)}\)
3. \(\dfrac{1}{4}\dfrac{\mu_{0} i}{2 \pi R}\) 4. \(\dfrac{1}{2}\dfrac{\mu_0 i}{2\pi R}\)
Subtopic:  Magnetic Flux |
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The two long, parallel wires shown in the diagram carry equal and opposite currents \(i\). The currents change linearly with time: \(\dfrac{di} {dt}\) = a constant = \(K\). The small circuit is situated midway between the wires and has an area \(A\). The emf induced in the small circuit is: 
1. zero 2. \(\dfrac{\mu_{0} A K}{2 \pi l}\)
3. \(\dfrac{\mu_{0} A K}{ \pi l}\) 4. \(\dfrac{2 \mu_{0} A K}{\pi l}\)
Subtopic:  Magnetic Flux |
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Given below are two statements: 
Assertion (A): Faraday's law of electromagnetic induction is a consequence of Biot-Savart's law.
Reason (R): Currents cause magnetic fields and interact with magnetic flux.
 
1. (A) is True but (R) is False.
2. (A) is False but (R) is True.
3. Both (A) and (R) are True and (R) is the correct explanation of (A).
4. Both (A) and (R) are True but (R) is not the correct explanation of (A).
Subtopic:  Faraday's Law & Lenz Law |
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A rod \(PQ\) of length \(L\) moves in a uniform magnetic field \(B\) with a velocity \(v,\) perpendicular to its own length. The magnetic field \(B\) acts in the plane of motion, making an angle \(\theta\) with the rod. The motional emf, \(V_P-V_Q\) is:
                 
1. zero
2. \(BLv\cos\theta\)
3. \(BLv\sin\theta\)
4. \(BLv\)
Subtopic:  Motional emf |
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A square wire loop of resistance \(0.5\) \(\Omega\)/m, having a side \(10\) cm and made of \(100\) turns is suddenly flipped in a magnetic field \(B,\) which is perpendicular to the plane of the loop. A charge of \(2\times10^{-4} \) C passes through the loop. The magnetic field \(B\) has the magnitude of: 
1. \(2\times10^{-6} \) T
2. \(4\times10^{-6} \) T
3. \(2\times10^{-3} \) T
4. \(4\times10^{-3} \) T
Subtopic:  Magnetic Flux |
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Select Chapter Topics:
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Magnetic Flux
Faraday's Law & Lenz Law
Motional emf
Self - Inductance
Mutual Inductance
LR circuit
Eddy Current
Q. No.

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