A uniform surface charge density of 36.6 nC/m² covers the entire xy- plane. Consider a spherical surface centered on the origin (radius = 4.19 cm). Find the electric flux through this surface.
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- Consider a thin, spherical shell of radius 14.5 cm with a total charge of 29.9 µC distributed uniformly on its surface. (a) Find the electric field 10.0 cm from the center of the charge distribution. (b) Find the electric field 24.5 cm from the center of the charge distribution.A uniformly charged conducting sphere of 1.7 m diameter has a surface charge density of 8.7 µC/m². (a) Find the net charge on the sphere. (b) What is the total electric flux leaving the surface of the sphere? (a) Number (b) Number i Units UnitsPlease answer for only the incorrect one
- A sphere shell of radius R, centered on the origin, has a uniform surface charge density /sigma and no charge in its interior. What is the magnitude of the electric field outside the sphere, at the distance r from the center, where r > R?A point charge is located at the origin. Centered along the x axis is a cylindrical closed surface of radius 10 cm with one end surface located at x = 2 m and the other end surface located at x = 2.5 m. If the magnitude of the electric flux through the surface at x = 2 m is 4 N . m2 /C, what is the magnitude of the electric flux through the surface at x = 2.5 m? Select one: a. 1.8 N . m2 /C b. 2.56 N . m2 /C c. 1.0 N . m2 /C d. 4.0 N . m2 /C e. 5.0 N . m2 /CA cylinder has a volume of 5.2 cm^3 and a charge density of 6.1 μC/cm^3, and is enclosed in a spherical surface with a radius of 17.5 cm. What is the total charge on the cylinder? What is the total electric flux through the surface of the sphere?