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(B) Let $j$ be the current density. Since the current $I$ spreads over a hemispherical surface,$j 	imes 2 \pi r^2 = I$,which gives $j = \frac{I}{2 \p

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$\frac{\rho I}{\pi a}-\frac{\rho I}{\pi(a+b)}$

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(B) Let $j$ be the current density. Since the current $I$ spreads over a hemispherical surface,$j 	imes 2 \pi r^2 = I$,which gives $j = \frac{I}{2 \pi r^2}$. Using Ohm's law,the electric field is $E = ho j = \frac{ho I}{2 \pi r^2}$. The potential difference due to current $I$ entering at $A$ between points $B$ and $C$ is $\Delta V_{BC, A} = V_B - V_C = \int_{r_B}^{r_C} E dr = \int_{a}^{a+b} \frac{ho I}{2 \pi r^2} dr = \frac{ho I}{2 \pi} \left[ -\frac{1}{r} ight]_{a}^{a+b} = \frac{ho I}{2 \pi} \left( \frac{1}{a} - \frac{1}{a+b} ight)$. Similarly,for current $I$ leaving at $D$,the potential difference $\Delta V_{BC, D}$ is also $\frac{ho I}{2 \pi} \left( \frac{1}{a} - \frac{1}{a+b} ight)$. By the superposition principle,the total potential difference is $\Delta V = \Delta V_{BC, A} + \Delta V_{BC, D} = 2 	imes \frac{ho I}{2 \pi} \left( \frac{1}{a} - \frac{1}{a+b} ight) = \frac{ho I}{\pi a} - \frac{ho I}{\pi(a+b)}$.

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