Problem 3: the infinite cylinder An insulating cylinder that is infinitely long has radius R and...
An infinitely long insulating cylinder of radius R has a volume charge density that varies with the radius as p po (a-where po a and b are positive constants and ris the distance from the axis of the cylinder. Use Gauss's law to determine the magnitude of the electric field at radial distances (a) r< R and (b)r>R
An infinitely long insulating cylinder of radius R has a volume charge density that varies with the radius as given by the following expression where po. a, and bare positive constants and ris the distance from the axis of the cylinder Use Gauss's law to determine the magnitude of the electric field at r R. (Use the following as necessary: E0. Po. a, b, r, and R 2πεο 2.03b c) c) 2. R 3.b e) Po
A long cylinder or aluminum or radius R meters is charged so that it has a uniform charge per unit length on its surface or (a) Find the electric fields at distances r (from the center of the cylinder) that lie inside and outside the cylinder. (Enter the radial component of the electric field. Use any variable or symbol stated above along with the following as necessary: inside outside E (b) Plot electric field magnitude as a function of distanoe...
mall portion of an infinitely long cylinder is shown. The radius of the cylinder is R = 4 m and the charge is uniformly distributed throughout the cylinder with a volume charge density of ρ = 0.6 nC/m^3. Gauss's law to find the magnitude of the electric field at a distance r 18 m from the center of the cylinder as shown. Your answer should be in units of N/C. Use Submit Answer Tries /2
An infinitely long solid insulating cylinder of radius a = 5.5 cm is positioned with its symmetry axis along the z-axis as shown. The cylinder is uniformly charged with a charge density rho = 25 mu C/m^3. Concentric with the cylinder is a cylindrical conducting shell of inner radius b = 14.4 cm, and outer radius c = 17.4 cm. The conducting shell has a linear charge density lambda = -0.42 mu C/m. 1) What is E_y(R), the y-component of...
Problem 8 A positive charge is uniformly distributed through an insulating sphere of radius R. The point P that is located a distance r from the center of the sphere. (i) Determine the electric field when the point P is inside the sphere (r < R). (ii) Determine the electric field when the point P is outside the sphere (r > R). (iii) Plot the magnitude of the electric field as a function of r.
Problem 8 A positive charge is uniformly distributed through an insulating sphere of radius R. The point P that is located a distance r from the center of the sphere. (i) Determine the electric field when the point P is inside the sphere (r < R). (i) Determine the electric field when the point P is outside the sphere (r> R). (iii) Plot the magnitude of the electric field as a function of r.
: An infinitly long insulating cylinder of radious R has a volume charge density that varies with the radious as 0 ( ) r a b , where a and b are positive constants and r is the distance from the axis of the cylinder.use Gausses law to determine the magnitude of the electric field at radial distances a) r < R b) r > R
Consider an infinitely long straight cylinder of radius R and uniform positive charge density ρ. (a) Find the field inside the cylinder a distance r < R from the center. (b) Find the field outside the cylinder a distance r > R from the center. (c) Sketch a plot of E vs r over the range 0 ≤ r ≤ 2R.
Problem #4: An infinitely long hollow cylinder has inner radius r = 0.2m and outer radius r = 0.4m has ρ,-23r nCm3 inside the cylinder. U D in the regions r0.2m, 0.2m0.4m and r> 0.4 m. se Gauss s law to find the electric flux density vector