6. A thin shell of sphere of of charge Q = 10C with radius Ro =...

10. A shell of solid metal sphere of outer radius Ro = 2m and inner radius...

10. A shell of solid metal sphere of outer radius Ro = 2m and inner radius of R1 = 1m has a charge of Q1 = 4C placed on it. After the charge is placed on the sphere, a charge of Q2 = 6C is then placed at the center of the sphere. Find the electric field everywhere in the sphere. What are the charges on the inside of the sphere, and outside the sphere.

A solid conducting sphere with radius R is concentric with a very thin insulating shell of...

A solid conducting sphere with radius R is concentric with a very thin insulating shell of radius 2R. Sphere carries charge Q on its surface. Same amount of charge is present on the surface of shell also. Charge is distributed uniformly over the insulating shell. Find the electric Öeld for the regions: (i) 0 < r < R, (ii) R < r < 2R, and (iii) r > 2R.

A thin spherical shell has a radius a and charge +Q that is distributed uniformly overr...

A thin spherical shell has a radius a and charge +Q that is distributed uniformly overr it. There is also a second spherical shell of radius b that is concentric with the first shell and has charge +Q2 uniformly distributed over it. b> a. Find the magnitude and direction of electric field in the regions (a) R<a (b)a<R<b (c)R>b (d) electric potential for the region R>b (e) electric potential for the region a<R<b (f)electric potential for the region R<a

8. A solid metal sphere of radius Ro = 2m has a charge of Q1 =...

8. A solid metal sphere of radius Ro = 2m has a charge of Q1 = 4C. Find the electric field every where.

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...

(8c23p69) A thin, metallic, spherical shell of radius a = 7.0 cm has a charge qa...

(8c23p69) A thin, metallic, spherical shell of radius a = 7.0 cm has a charge qa = 5.00×10-6 C. Concentric with it is another thin, metallic, spherical shell of radius b = 18.90 cm and charge qb = 5.00×10-6 C. Find the electric field at radial points r where r = 0.0 cm. Find the electric field at radial points r where r = 13.0 cm. Find the electric field at radial points r where r = 28.4 cm. Discuss...

A thin aluminum sphere of radius 25 cm has a charge of Q=150 nC uniformly distributed...

A thin aluminum sphere of radius 25 cm has a charge of Q=150 nC uniformly distributed on its surface. a) Assuming that the center of the sphere is at r=0, find expressions for the electric field for all regions of interest (r<R, and R>r), and make a plot of the electric field strength as a function of r. b) Find expressions for the electric potential for all regions of interest, and plot the electric potential as a function of r....

A thin-walled metal spherical shell of radius a = 8 m has a charge qa =...

A thin-walled metal spherical shell of radius a = 8 m has a charge qa = 23 C. Concentric with it is a thin-walled metal spherical shell of radius b = 7a and charge qb = 27 C. Find the electric field at points a distance r from the common center, where (a) r = 2.4 m, (b) r = 16 m, and (c) r = 84.0 m.

A thin-walled metal spherical shell of radius a = 36 m has a charge qa =...

A thin-walled metal spherical shell of radius a = 36 m has a charge qa = 11 C. Concentric with it is a thin-walled metal spherical shell of radius b = 5a and charge qb = 33 C. Find the electric field at points a distance r from the common center, where (a) r = 10.8 m, (b) r = 72 m, and (c) r = 270.0 m.

An amount of charge Q is distributed uniformly inside a spherical shell of inner radius a...

An amount of charge Q is distributed uniformly inside a spherical shell of inner radius a and outer radius b. Use Gauss's Law to calculate the electric field at a distance r from the center of the shell. Consider the cases r<a, a<r<b, and r<b.