A ring of charge with radius `0.5m` has `0.002 pi` m gap. If the ribg carries a charge of `+1 C` the electric field at the center is

A semicircular ring of radius 0.5 m is uniformly charged with a total charge of 1.5 xx 10^(-9) coul. The electric potential at the centre of this ring is :

A ring of radius 0.1m is made out of thin metallic wire of area of cross section 10^(-6)m^(2) . The ring has a uniform charge of pi coulombs. Find the change in the radius of the rig when a charge of 10^(-8)C is placed at the center of the ring. Young's modulus of hte metal is 2xx10^(11)Nm^(-2) .

Figure shows a uniformly charged hemisphere of radius R. It has a volume charge density rho . If the electric field at a point 2R, above the its center is E, then what is the electric field at the point 2R below its center?

A thin conducting ring of radius R is given a charge +Q , Fig. The electric field at the center O of the ring due to the charge on the part AKB of the ring is E . The electric field at the center due to the charge on part ACDB of the ring is

Planes x= 2 and y = -3 , respectively , carry charge densities 10 nC //m^(2) . If the line x=0,z=2 carries charge density 10 pi n C //m , calculate the electric field vector at ( 1,1 ,-1) .

A thin spherical shell of metal has a radius of 0.25 m and carries charge of 0.2 micro coulomb. Calculate the electric intensity at 3.0 m from the centre of the shell.

What is the charge per unit area in C//m^2 of an infinite plane sheet of charge if the electric field produced by the sheet of charge has magnitude 3.0 N//C ?

Charge q is uniformly distributed over a thin half ring of radius R . The electric field at the centre of the ring is

A thick shell with inner radius R and outer radius 3R has a uniform charge density sigma c//m^(3) . It has a spherical cavity of radius R as shown in the figure. The electric field at the centre of the cavity is

Consider a uniformly charged ring of radius R. Find the point on the axis where the electric field is maximum.