Q 1 :

The figure shows certain wire segments joined together to form a coplanar loop. The loop is placed in a perpendicular magnetic field in the direction going into the plane of the figure. The magnitude of the field increases with time. $I_1$ and $I_2$ are the currents in the segments ab and cd. Then,          [2009]

• $I_1>I_2$

   

• $I_1<I_2$

   

• $I_1$ is in the direction $ba$ and $I_2$ is in the direction $cd$

   

• $I_1$ is in the direction $ab$ and $I_2$ is in the direction $dc$

   

Q 2 :

A small bar magnet is being slowly inserted with constant velocity inside a solenoid as shown in the figure. Which graph  best represents the relationship between emf induced with time?                  [2004]

Q 3 :

A rectangular conducting loop of length 4 cm and width 2 cm is in the $xy$-plane, as shown in the figure. It is being moved away from a thin and long conducting wire along the direction $\frac{\sqrt{3}}{2}\hat{x}+\frac{1}{2}\hat{y}$ with a constant speed $v$. The wire is carrying a steady current $I=10\text{\hspace{0.05em}A}$ in the positive $x$-direction. A current of $10\mu \text{A}$ flows through the loop when it is at a distance $d=4\text{\hspace{0.05em}cm}$ from the wire. If the resistance of the loop is $0.1\Omega$, then the value of $v$ is ______ ${\text{ms}}^{-1}$.

[Given: The permeability of free space ${\mu }_0=4\pi \times {10}^{-7}{\text{\hspace{0.05em}N A}}^{-2}$]                  [2023]

Q 4 :

A series R-C combination is connected to an AC voltage of angular frequency $\omega =500\text{ rad/s}.$ If the impedance of the R-C circuit is $R\sqrt{1.25},$ the time constant (in millisecond) of the circuit is                         [2011]

Q 5 :

A small circular loop of area A and resistance R is fixed on a horizontal $xy$-plane with the center of the loop always on the axis $\hat{n}$ of a long solenoid. The solenoid has $m$ turns per unit length and carries current $I$ counterclockwise as shown in the figure. The magnetic field due to the solenoid is in $\hat{n}$ direction. List-I gives time dependences of $\hat{n}$ in terms of a constant angular frequency $\omega$. List-II gives the torques experienced by the circular loop at time $t=\frac{\pi }{6\omega }.$ Let $\alpha =\frac{A^2{\mu }_0^2{m}^2{I}^2\omega }{2R}.$             [2022]

	List-I		List-II
(I)	$\frac{1}{\sqrt{2}}(\sin \omega t\hat{j}+\cos \omega t\hat{k})$	(P)	$0$
(II)	$\frac{1}{\sqrt{2}}(\sin \omega t\hat{i}+\cos \omega t\hat{j})$	(Q)	$-\frac{\alpha }{4}\hat{i}$
(III)	$\frac{1}{\sqrt{2}}(\sin \omega t\hat{i}+\cos \omega t\hat{k})$	(R)	$\frac{3\alpha }{4}\hat{i}$
(IV)	$\frac{1}{\sqrt{2}}(\cos \omega t\hat{j}+\sin \omega t\hat{k})$	(S)	$\frac{\alpha }{4}\hat{j}$
		(T)	$-\frac{3\alpha }{4}\hat{i}$

Which one of the following options is correct?

• (I) → (Q); (II) → (P); (III) → (S); (IV) → (T)

   

• (I) → (S); (II) → (T); (III) → (Q); (IV) → (P)

   

• (I) → (Q); (II) → (P); (III) → (S); (IV) → (R)

   

• (I) → (T); (II) → (Q); (III) → (P); (IV) → (R)

   

Q 6 :

A current carrying infinitely long wire is kept along the diameter of a circular wire loop, without touching it, the correct statement(s) is(are)         [2012]

• The emf induced in the loop is zero if the current is constant.

   

• The emf induced in the loop is finite if the current is constant.

   

• The emf induced in the loop is zero if the current decreases at a steady rate.

   

• The emf induced in the loop is infinite if the current decreases at a steady rate.