The charge density on a disk of radius R = 12.6 cm is given by σ...

A thin disk with radius R has a surface charge density varying with σ = Cr....

A thin disk with radius R has a surface charge density varying with σ = Cr. C is a positive constant and r is the distance from the disk center. Find the electrical potential on the axis perpendicular to the center of the disc and at a point P about x away from the center.

2. A circular ring with a radius R of 1 cm carries a charge density of...

2. A circular ring with a radius R of 1 cm carries a charge density of ?L = R sin ? (? is an azimuthal angle) µC/cm. The ring is then placed on the xy plane with its axis the same as the z-axis. Find the electric field intensity E and the electric potential V on point A on z-axis 2 cm from the xy plane.

A spherical conductor has a radius of 14.0 cm and a charge of 58.0 µC. Calculate...

A spherical conductor has a radius of 14.0 cm and a charge of 58.0 µC. Calculate the electric field and the electric potential at the following distances from the center. (a) r = 8.0 cm magnitude direction electric field MN/C ---Select--- inward outward there is no direction electric potential MV ---Select--- inward outward there is no direction (b) r = 30.0 cm magnitude direction electric field MN/C ---Select--- inward outward there is no direction electric potential MV ---Select--- inward outward...

A nonconducting solid sphere of radius 9.10 cm has a uniform volume charge density. The magnitude...

A nonconducting solid sphere of radius 9.10 cm has a uniform volume charge density. The magnitude of the electric field at 18.2 cm from the sphere's center is 1.77  103 N/C. (a) What is the sphere's volume charge density? µC/m3 (b) Find the magnitude of the electric field at a distance of 5.00 cm from the sphere's center.

Consider a rotating disk of radius R with uniform surface charge density σ and angular rotation...

Consider a rotating disk of radius R with uniform surface charge density σ and angular rotation speed ω. (a) show that for an annular strip of radius r, and width dr that the current dI = ωσrdr HINT: see class notes from previous week (b) Show that the magnetic field in the center of the disk is given by B = 1μ0σωR 2

A solid nonconducting sphere of radius R = 5.82 cm has a nonuniform charge distribution of...

A solid nonconducting sphere of radius R = 5.82 cm has a nonuniform charge distribution of volume charge density ρ = (13.3 pC/m3)r/R, where r is radial distance from the sphere's center. (a) What is the sphere's total charge? 8.23e-15 C (b) What is the magnitude E of the electric field at r = 0? (Use any variable or symbol stated above along with the following as necessary: ε0.) E = 0     (c) What is the magnitude E of...

A uniformly charged disk of radius 10 cm carries a uniform charge density of 3nC/m^2 (a)...

A uniformly charged disk of radius 10 cm carries a uniform charge density of 3nC/m^2 (a) Calculate the electric potential (relative to zero at infinity) at a point A, situated on the symmetry axis of the disk that is perpendicular to the disk face, at a distance of 1 mm from the disk. (b) Calculate the electric potential difference ΔV between point A and another point on the same axis at a distance 2 mm from the disk. (c) Compare...

A uniformly charged disk of radius 35.0 cm carries a charge density of 7.30 ✕ 10-3...

A uniformly charged disk of radius 35.0 cm carries a charge density of 7.30 ✕ 10-3 C/m2. Calculate the electric field on the axis of the disk at the following distances from the center of the disk. (a) 5.00 cm (b) 10.0 cm (c) 50.0 cm (d) 200 cm

A uniformly charged disk of radius 35.0 cm carries a charge density of 8.70 ✕ 10-3...

A uniformly charged disk of radius 35.0 cm carries a charge density of 8.70 ✕ 10-3 C/m2. Calculate the electric field on the axis of the disk at the following distances from the center of the disk. (a) 5.00 cm MN/C (b) 10.0 cm MN/C (c) 50.0 cm MN/C (d) 200 cm MN/C

A uniformly charged disk of radius 35.0 cm carries a charge density of 7.10 ✕ 10-3...

A uniformly charged disk of radius 35.0 cm carries a charge density of 7.10 ✕ 10-3 C/m2. Calculate the electric field on the axis of the disk at the following distances from the center of the disk. (a) 5.00 cm MN/C (b) 10.0 cm MN/C (c) 50.0 cm MN/C (d) 200 cm MN/C