(B) Area of the square loop $A = 25 \, cm^2 = 25 \times 10^{-4} \, m^2$. Side length $l = \sqrt{A} = 5 \, cm = 0.05 \, m$. Velocity $v = \frac{l}{t} =

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(B) Area of the square loop $A = 25 \, cm^2 = 25 \times 10^{-4} \, m^2$. Side length $l = \sqrt{A} = 5 \, cm = 0.05 \, m$. Velocity $v = \frac{l}{t} = \frac{0.05 \, m}{1 \, s} = 0.05 \, m/s$. Induced electromotive force $(EMF)$ $e = B l v$. Induced current $I = \frac{e}{R} = \frac{B l v}{R}$. Substituting the values: $I = \frac{40 \times 0.05 \times 0.05}{10} = 0.01 \, A$. The magnetic force on the conductor is $F = B I l$. $F = 40 \times 0.01 \times 0.05 = 0.02 \, N$. Work done $W = F \times l = 0.02 \, N \times 0.05 \, m = 1 \times 10^{-3} \, J$.

Class 12 Physics Electromagnetic Induction Motional EMI (Induced Parameter)

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$A$ square loop of area $25 \, cm^2$ has a resistance of $10 \, \Omega$. The loop is placed in a uniform magnetic field of magnitude $40 \, T$. The plane of the loop is perpendicular to the magnetic field. The work done in pulling the loop out of the magnetic field slowly and uniformly in $1 \, s$ will be:

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A
$2.5 \times 10^{-3} \, J$
B
$1.0 \times 10^{-3} \, J$
C
$1.0 \times 10^{-4} \, J$
D
$5 \times 10^{-3} \, J$

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Electromagnetic Induction

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Motional EMI (Induced Parameter)

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$A$ conducting rod of length $L = 0.1 \, m$ is moving with a uniform speed $v = 0.2 \, m/s$ on conducting rails in a magnetic field $B = 0.5 \, T$ as shown. On one side,the end of the rails is connected to a capacitor of capacitance $C = 20 \, \mu F$. Then the charges on the capacitor plates $A$ and $B$ are:

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$A$ thin wire of length $2\,m$ is placed perpendicular to the $x-y$ plane. It is moved with velocity $\overrightarrow v = (2\hat i + 3\hat j + \hat k)\,m/s$ through a region of magnetic induction $\overrightarrow B = (\hat i + 2\hat j)\,Wb/m^2$. The potential difference induced between the ends of the wire is......$V$.

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$A$ uniform magnetic field exists in a region given by $\vec B = 3\hat i + 4\hat j + 2\hat k \, T$. $A$ conducting rod of length $5\,m$ is placed along the $y$-axis and is moved along the $x$-axis with a constant speed of $1\,m/s$. The $emf$ induced in the rod will be......$V$.

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$A$ conducting rod is moving in a uniform magnetic field as shown in the diagram. Which end is at a lower potential?

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Initially,a rectangular coil with its length vertical is moving out with a constant velocity $v$ in a constant magnetic field $B$ towards the right. Now,the same coil is rotated through $90^{\circ}$ in the same plane in the same magnetic field $B$,and the coil is moving with the same velocity $v$. The magnitude of the induced e.m.f. is now

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$A$ uniform magnetic field exists in a region given by $\vec B = 3\hat i + 4\hat j + 2\hat k \, T$. $A$ conducting rod of length $5\,m$ is placed along the $y$-axis and is moved along the $x$-axis with a constant speed of $1\,m/s$. The $emf$ induced in the rod will be......$V$.

$A$ conducting rod is moving in a uniform magnetic field as shown in the diagram. Which end is at a lower potential?

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