Answer:
a. [tex]6.032\times10^{-6}C/m^2[/tex]
b.[tex]6.816\times10^5N/C[/tex]
Explanation:
#Apply surface charge density, electric field, and Gauss law to solve:
a. Surface charge density is defined as charge per area denoted as [tex]\sigma[/tex]
[tex]\sigma=\frac{Q}{4\pi r_{out}^2}[/tex], and the strength of the electric field outside the sphere [tex]E=\frac{\sigma _{new}}{\epsilon _o}[/tex]
Using Gauss Law, total electric flux out of a closed surface is equal to the total charge enclosed divided by the permittivity.
[tex]\phi=\frac{Q_{enclosed}}{\epsilon_o}\\\\\sigma=\frac{Q}{4\pi r_{out}^2}\\\\\sigma=\frac{0.370\times 10^{-6}}{4\pi \times (0.295m)^2}\\\\=3.383\times10^{-7}C/m^2[/tex] #surface charge outside sphere.
[tex]\sigma_{new}=\sigma_{s}-\sigma\\\\\sigma_{new}=6.37\times10^{-6}C/m^2-3.383\times10^{-7}C/m^2\\\\\sigma_{new}=6.032\times10^{-6}C/m^2[/tex]
Hence, the new charge density on the outside of the sphere is [tex]6.032\times10^{-6}C/m^2[/tex]
b. The strength of the electric field just outside the sphere is calculated as:
From a above, we know the new surface charge to be [tex]6.032\times10^{-6}C/m^2[/tex],
[tex]E=\frac{\sigma _{new}}{\epsilon _o}\\\\=\frac{6.032\times10^{-6}C/m^2}{\epsilon _o}\\\\\epsilon _o=8.85\times10^{-12}C^2/N.m^2\\\\E=\frac{6.032\times10^{-6}C/m^2}{8.85\times10^{-12}C^2/N.m^2}\\\\E=6.816\times10^5N/C[/tex]
Hence, the strength of the electric field just outside the sphere is [tex]6.816\times10^5N/C[/tex]
