A charge distribution with spherical symmetry has density
\rho_{v}=\begin{cases}\frac{\rho_{o}r}{R}, & 0\leq r\leq R \\0, & r\gt R\end{cases}
Determine E everywhere.
Question 4.9: A charge distribution with spherical symmetry has density ρv...
The charge distribution is similar to that in Figure 4.16. Since symmetry exists, we can apply Gauss’s law to find E.
\varepsilon _{o}\oint_{S}E\cdot dS=Q_{enc}=\int_{v}\rho_{v}dv
(a) For r \lt R
\varepsilon _{o}E_{r}4\pi r^{2}=Q_{enc}=\int_{0}^{r}\int_{0}^{\pi}\int_{0}^{2\pi}\rho_{v}r^{2}\sin\theta d\phi d\theta dr
=\int_{0}^{r}4\pi r^{2}\frac{\rho _{o}r}{R}dr= \frac{\rho _{o}\pi r^{4}}{R}
or
E=\frac{\rho _{o}r^{2}}{4\varepsilon _{o} R}a_{r}
(b) For r\gt R
\varepsilon _{o}E_{r}4\pi r^{2}=Q_{enc}=\int_{0}^{r}\int_{0}^{\pi}\int_{0}^{2\pi}\rho_{v}r^{2}\sin\theta d\phi d\theta dr
=\int_{0}^{R}\frac{\rho _{o}r}{R}4\pi r^{2}dr+\int_{R}^{r}0\cdot4\pi r^{2}dr= \pi\rho _{o}R^{3}
or
E=\frac{\rho _{o}R^{3}}{4\varepsilon _{o} r^{2}}a_{r}
Related Answered Questions
Let
Q_{1}=-4\mu C, Q_{2}=5\mu C[/latex...
The D field has already been found in Section 4.6D...
Consider the system of charges as shown in Figure ...
Ignoring the coulombic force between particles, th...
(a) Consider the system as shown in Figure 4.9. Ag...
Let D=D_{Q}+D_{L}, where D_{...
\rho _{v}=\nabla\cdot D=\frac{\partial D_{z...
Let the potential at any point be
V=V_{Q}+V...
V=\sum\limits_{k=1}^{2}\frac{p_{k}\cdot r_{...