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(C) The motional electromotive force $(EMF)$ induced in a small element $dy$ of the wire moving with velocity $\vec{V} = V_0 \hat{i}$ in a magnetic fi

Vedclass · Accepted Answer

$1, 2, 4$

Vedclass · Answer

(C) The motional electromotive force $(EMF)$ induced in a small element $dy$ of the wire moving with velocity $\vec{V} = V_0 \hat{i}$ in a magnetic field $\vec{B} = B(y) \hat{k}$ is given by $d\phi = |(\vec{V} 	imes \vec{B}) \cdot d\vec{l}|$. Since $\vec{V} = V_0 \hat{i}$ and $\vec{B} = B(y) \hat{k}$,the cross product $\vec{V} 	imes \vec{B} = V_0 B(y) (\hat{i} 	imes \hat{k}) = -V_0 B(y) \hat{j}$.The potential difference between the ends of the wire is $\Delta \phi = \int_0^L V_0 B(y) dy$.Substituting $B(y) = B_0 \left(1 + \left(\frac{y}{L}ight)^\betaight)$:$\Delta \phi = \int_0^L V_0 B_0 \left(1 + \frac{y^\beta}{L^\beta}ight) dy = V_0 B_0 \left[ y + \frac{y^{\beta+1}}{L^\beta (\beta+1)} ight]_0^L = V_0 B_0 \left( L + \frac{L}{\beta+1} ight) = V_0 B_0 L \left( 1 + \frac{1}{\beta+1} ight)$.$(1)$ The integral depends only on the range of $y$ (from $0$ to $L$). Thus,replacing the wire with any shape that spans the same $y$-range results in the same $\Delta \phi$. Statement $(1)$ is correct.$(2)$ Since $\Delta \phi = V_0 B_0 L \left( \frac{\beta+2}{\beta+1} ight)$,it is proportional to $L$ (the projection on the $y$-axis). Statement $(2)$ is correct.$(3)$ For $\beta = 0$,$\Delta \phi = V_0 B_0 L (1 + 1) = 2 V_0 B_0 L$. Statement $(3)$ is incorrect.$(4)$ For $\beta = 2$,$\Delta \phi = V_0 B_0 L (1 + 1/3) = \frac{4}{3} V_0 B_0 L$. Statement $(4)$ is correct.Therefore,the correct statements are $(1), (2),$ and $(4)$.

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