It has been experimentally observed that the electric field in a large region of earth's atmosphere is directed vertically down. At an altitude of 300 m, the electric field `60 Vm^(-1)`. At an altitude of 200 m, the field is 100 V m^(-1), the field is `100 Vm^(-1)`. Calculate the net amount of charge contained in the cube of 100 m edge, located between 200 and 300 m altitude.

If the electric field intensity in a fair weather atmosphere is 100 V/m, then total charge on the earth's surface is (radius of the earth is 6400 km)

There exists an electric field of 1 NC^(-1) along Y direction. The flux passing through the square of 1 m placed in xy- plane inside the electric field is

If the field near the earth's surface is 300V m^(-1) directed downwards , what is the surface density of change on the surface of the earth?

Electric field inside the capcitor is 100 V/m and dielectric constant =5.5. What is the polarization ?

The sunlight reaching the earth has maximum electric field of 810V (m^-1) . What is the maximum magnetic field in this light?

The sunlight reaching the earth has maximum electric field of 810V (m^-1) . What is the maximum magnetic field in this light?

The electric field in a region is radially outward with magnitude E=Ar . Find the charge contained in a sphere of radius a centred at the origin. Take A=100 V m^(-2) and a=20.0 cm .

The electric field in aregion is radially ourward with magnitude E=Ar . Find the charge contained in a sphere of radius a centred at the origin. Take A=100 V m^(-2) and a=20.0 cm .

A particle moves in a circle of diamater 1.0 cm under the action of magnetic field of 0.40 T, An electric field of 200 V m^(-1) makes the path straight. Find the charges/mass ratio of the particle.

A large charged metal sheet is placed in a uniform electric field, perpendicular to the electric field lines. After placing the sheet into the field, the electric field on the left side of the sheet is E_1 = 5 xx 10^5 Vm^(-1) and on the right it is E_2 = 3 xx 10^5 V m^(-1) . The sheet experiences a net electric force of 0.08 N. Find the area of one face of the sheet. Assume the external field to remain constant after introducing the large sheet. Use (1/(4piepsilon_0)) = 9 xx 10^(9) Nm^(2)C^(-2)