Electric Field of a Charged Sphere with a small hole on the surface. Consider a spherical...

A solid, nonconducting sphere of radius R = 6.0cm is charged uniformly with an electrical charge...

A solid, nonconducting sphere of radius R = 6.0cm is charged uniformly with an electrical charge of q = 12µC. it is enclosed by a thin conducting concentric spherical shell of inner radius R, the net charge on the shell is zero. a) find the magnitude of the electrical field E1  inside the sphere (r < R) at the distance r1 = 3.0 cm from the center. b) find the magnitude of the electric field E2 outside the shell at the...

For a charged hollow metal sphere with total charge Q and radius R centered on the...

For a charged hollow metal sphere with total charge Q and radius R centered on the origin: True False  the charge is on the inside surface. True False  the field for r > R will be the same as the field of a point charge, Q, at the origin. True False  the field on the outside is perpendicular to the surface. True False  inside the metal the field is strongest. True False  the field inside the shell is zero. True False  only positive charges can be...

Consider a solid uniformly charged copper sphere with charge Q and radius R. Showing all Steps,...

Consider a solid uniformly charged copper sphere with charge Q and radius R. Showing all Steps, (a) Calculate the potential of the spherical charge inside and outside of the sphere. (b) Calculate the electric field of the spherical charge from the potential in part (a) for the inside and outside regions.

A uniformly charged insulating sphere (R1 = 3.0 cm) is charged to QI = 50 nC....

A uniformly charged insulating sphere (R1 = 3.0 cm) is charged to QI = 50 nC. It is concentric within a charged conducting shell (inner radius R2 = 5.0 cm, outer radius R3 = 5.2 cm) that is charged to QC = 200 nC. The insulating sphere is not connected to the conducting shell, and the conductors are separated by air. (Note: The figure is not to scale.) In which region(s) is the electric field zero, if any? (b) Find...

Consider a charged spherical shell of radius a having a constant surface charge density σ0, rotating...

Consider a charged spherical shell of radius a having a constant surface charge density σ0, rotating about the z-axis with angular frequency ω. (a) Find the electric and magnetic fields outside of the shell. (b) What is the electric pressure on the surface charges? What is the magnetic pressure due to the surface currents? (c) Find the Poynting vector outside of the shell. (d) What is the angular momentum density outside of the shell? What is the total angular momentum...

A thin, uniformly charged spherical shell has a potential of 727 V on its surface. Outside...

A thin, uniformly charged spherical shell has a potential of 727 V on its surface. Outside the sphere, at a radial distance of 20.0 cm from this surface, the potential is 403 V. (1) Calculate the radius of the sphere. (2) Determine the total charge on the sphere (3) What is the electric potential inside the sphere at a radius of 3.0 cm (4) Calculate the magnitude of the electric field at the surface of the sphere. (5) If an...

A small conducting spherical shell with inner radius a and outer radius b is concentric with...

A small conducting spherical shell with inner radius a and outer radius b is concentric with a larger conducting spherical shell with inner radius c and outer radius d. The inner shell has a total charge of -1q and the outer shell has a total charge of +3q. Select True or False for the following statements. True False The radial component of the electric field in the region r > dis given by +2q/(4πε0r2). True False The total charge on...

An uncharged conducting sphere of radius 2b is centered on the origin and has a spherical...

An uncharged conducting sphere of radius 2b is centered on the origin and has a spherical cavity of radius b that is also centered on the origin. 1. If a charge of +q is at the origin, explain why the surfaces at r=2b and r=b each have a net charge of +q and −q, respectively, and not, say, +q/2 and −q/2. 2. Repeat this question for the case where the inner surface of the cavity is not spherical (but the...

A charge is spread out uniformly over a small non-conducting sphere. The small sphere shares a...

A charge is spread out uniformly over a small non-conducting sphere. The small sphere shares a center with a larger spherical shell with an inner radius of 6 ?? and an outer radius of 12 ??. a) Using Gauss’ Law, what is the magnitude of the charge on the nonconducting sphere if the field from the sphere is measured to be 8200 ?/? when 0.5 ?? from the center? b) What is the surface charge density on the inside of...

A surface charge density sigma(theta)=[sigma_o(cos(theta))] is glued to the surface of a spherical shell of radius...

A surface charge density sigma(theta)=[sigma_o(cos(theta))] is glued to the surface of a spherical shell of radius R. There is a vacuum with no charges both inside and outside of the shell. Calculate the electrostatic potential and the electric field both inside and outside the spherical shell. (the "_" is a subscript in sigma_o).