Energy stored in coil is $$E = \frac{1}{2}L{i^2}$$
where, $$L$$ is self-inductance of coil and $$i$$ is current induced. Here, $$L = 100\,mH = 100 \times {10^{ - 3}}H$$      and $$i = 1\,A$$
$$\therefore E = \frac{1}{2} \times \left( {100 \times {{10}^{ - 3}}} \right) \times {\left( 1 \right)^2} = 0.05\,J$$

$$\eqalign{ & L = 2\,mH,i = {t^2}{e^{ - t}} \cr & E = - L\frac{{di}}{{dt}} = - L\left[ { - {t^2}{e^{ - t}} + 2t{e^{ - t}}} \right] \cr & {\text{when}}\,E = 0, - {e^{ - t}}{t^2} + 2t{e^{ - t}} = 0 \cr & {\text{or,}}\,\,2t\,{e^{ - t}} = {e^{ - t}}{t^2} \cr & \Rightarrow t = 2\,\sec . \cr} $$

$$\eqalign{ & I\left( t \right) = \sqrt {\frac{m}{L}} {v_0}\sin \omega t\,\,{\text{where}}\,\,\omega = \frac{{B\ell }}{{\sqrt {mL} }} \cr & \Rightarrow I = \sqrt {\frac{{mv_0^2}}{{2L}}} \cr} $$

Induced emf produced across $$MNQ$$  will be same as the induced emf produced in straight wire $$MQ.$$
$$\therefore e = Bv\ell = Bv \times 2R\,{\text{with }}Q{\text{ at higher potential}}{\text{.}}$$

For inductor, as we know induced voltage for
$$t = 0\,{\text{to}}\,t = \frac{T}{2},$$
$$V = L\frac{{dI}}{{dt}} = L\frac{d}{{dt}}\left( {\frac{{2{I_0}t}}{T}} \right) = {\text{constant}}$$
For $$t = \frac{T}{2}\,{\text{to}}\,t = T,$$
$$V = L\frac{{dI}}{{dt}} = \left( {\frac{{ - 2{I_0}t}}{T}} \right) = - {\text{constant}}$$
So, answer can be represented with graph (D).

If a wire loop is rotated in a magnetic field, the frequency of change in the direction of the induced emf is twice per revolution.

Energy stored in magnetic field = $$\frac{1}{2}L{i^2}$$
Energy stored in electric field = $$\frac{1}{2}\frac{{{q^2}}}{C}$$
$$\eqalign{ & \therefore \frac{1}{2}L{i^2} = \frac{1}{2}\frac{{{q^2}}}{C} \cr & {\text{Also }}q = {q_0}\cos \omega t{\text{ and }}\omega = \frac{1}{{\sqrt {LC} }} \cr} $$
On solving $$t = \frac{\pi }{4}\sqrt {LC} $$

$$L = \frac{{{\mu _0}{N^2}\pi {r^2}}}{\ell }$$
Length of wire $$ = N\,2\pi r = {\text{constant}}\left( { = C,{\text{suppose}}} \right)$$
$$\eqalign{ & \therefore L = {\mu _0}{\left( {\frac{C}{{2\pi r}}} \right)^2}\frac{{\pi {r^2}}}{\ell } \cr & \therefore L \propto \frac{1}{\ell } \cr} $$
$$\therefore $$ Self inductance will become $$2L.$$

Total number of turns in the solenoid, $$N = 500$$
Current, $$I = 2\,A.$$
Magnetic flux linked with each turn $$ = 4 \times {10^{ - 3}}Wb$$
As, $$\phi = LI\,{\text{or}}\,N\phi = LI$$
$$ \Rightarrow L = \frac{{N\phi }}{1} = \frac{{500 \times 4 \times {{10}^{ - 3}}}}{2}{\text{henry}} = 1\,H.$$

$$\overrightarrow {{F_1}} = \overrightarrow {{F_2}} = 0$$
because of action and reaction pair