Consider an infinite line with a total charge of −3Q in a length L that is...

5. Consider a system consisting of an insulating sphere of radius a, with total charge Q...

5. Consider a system consisting of an insulating sphere of radius a, with total charge Q uniformly spread throughout its volume, surrounded by a conducting spherical inner radius b and outer radius c, having a total charge of -3Q. (a) How much charge is on each surface of the spherical conducting shell? (b) Find the electric potential for all r, assuming v=0 at infinity.

A very long non-conducting cylindrical rod of length L and radius a has a total charge...

A very long non-conducting cylindrical rod of length L and radius a has a total charge – 2q uniformly distributed throughout its volume. It is surrounded by a conducting cylindrical shell of length L, inner radius b, and outer radius c. The cylindrical shell has a total charge +q. Determine the electric field for all regions of space and the charge distribution on the shell.

An insulating sphere of radius a has charge density p(r) = P0r^2, where P0 is a...

An insulating sphere of radius a has charge density p(r) = P0r^2, where P0 is a constant with appropriate units. The total charge on the sphere is -3q. Concentric with the insulating sphere is a conducting spherical shell with inner radius b > a and utter radius. The total charge on the shell is +2q. Determine a. the magnitude of the electric field at the following locations: (i) r < a, (ii) a < r < b, (iii) b <...

A hollow non conducting spherical shell A (from r = 2cm to r= 3cm) with a...

A hollow non conducting spherical shell A (from r = 2cm to r= 3cm) with a charge distribution of rho= 2r (c/m^3) is surrounded by a larger concentric spherical neutral conducting shell of radius (r= 4 cm to r = 5cm) . If the inner charge is Q find the electric field in the region between A and B as a function of the distance r. what is the distribution of charges on the inner and outer surfaces of shell...

Consider two neutral, hollow conducting spherical shells. The inner shell will be denoted by S1 and...

Consider two neutral, hollow conducting spherical shells. The inner shell will be denoted by S1 and the outer shell will be denoted by S2. The inner radius of S1 is r1. The outer radius of S1 is r2. The inner radius of S2 is r3 and the outer radius of S2 is r4. S1 and S2 are concentric with S1 contained within S2. S1 has a total charge of Q1 and S2 has a total charge of Q2. Find: a)...

Consider an insulating sphere of radius 5 cm surrounded by a conducting sphere of inner radius...

Consider an insulating sphere of radius 5 cm surrounded by a conducting sphere of inner radius 22 cm and outer radius 25 cm. Furthermore, suppose that the electric field at a point 13 cm from the center is measured to be 1540 N/C radially inward while the electric field at a point 44 cm from the center is 90 N/C radially outward. 1. Find the charge on the insulating sphere. Answer in units of C. 2.Find the net charge on...

An infinitely long solid insulating cylinder of radius a = 4.3 cm is positioned with its...

An infinitely long solid insulating cylinder of radius a = 4.3 cm is positioned with its symmetry axis along the z-axis as shown. The cylinder is uniformly charged with a charge density ρ = 29 μC/m3. Concentric with the cylinder is a cylindrical conducting shell of inner radius b = 10.1 cm, and outer radius c = 12.1 cm. The conducting shell has a linear charge density λ = -0.34μC/m. What is V(P) – V(R), the potential difference between points...

A point charge of 6.0 nC is placed at the center of a hollow spherical conductor...

A point charge of 6.0 nC is placed at the center of a hollow spherical conductor (inner radius =1.0cm, outer radius =2.0cm) which has a net charge of -4.0 nC. Determine the resulting charge density on the inner surface of the conducting sphere.

One of the common uses for a coaxial cable is to transmit radio frequencies. One such...

One of the common uses for a coaxial cable is to transmit radio frequencies. One such coaxial cable of length 33.0 m consists of an inner conducting cylinder with a radius of 1.15 mm and an outer conducting cylinder whose inner radius is 3.25 mm. The charges on the inner and outer cylinders are −7.10 µC and +7.10 µC, respectively. (a) Determine the potential difference between the two cylinders along a path from the inner cylinder to the inside edge...

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...