The surface charge density of a large conducting sheet is `17.7 xx 10^(-6)Cm^(-2)`. The electric field intensity just outside the sheet is :

Assertion: The surface charge densities of two spherical conductors of different radii are equal. Then the electric field intensities near their surface are also equal. Reason: Surface charge density is equal to charge per unit area.

Two parallel large thin metal sheets have equal surface charge densities (sigma = 26.4 xx 10^(-12) C//m^(2)) of opposite signs. The electric field between these sheets is

If the linear charge density of a cylinder is 4 mu C m^(-6) ,then electric field intensity at point 3.6 cm from axis is :

We have an isolated conducting spherical shell of radius 10 cm . Some positive charge is given to it so that the resulting electric field has a maximum intensity of 1.8 xx 10^6 NC^-1 . The same amount of negative charge is given to another isolated conducting spherical shell of radius 20 cm . Now, the first shell is placed inside the second so that both are concentric as shown in (Fig. 3.154). . The electric field intensity just inside the outer sphere.

Suppose that earth has a surface charge density of 1 electron / "metre" ^(2) . Calculate earth s potential and electric field just outside earth surface . Radius of earth 6400 km.

A very long uniformly charged cylinder (radius R) has a surface charge density sigma . A very long uniformaly charged line charge( linear charge density lambda ) is placed along the ctlinder axis. If electric field intensity vector outside the cylinder is zerom then :

Two large conducting plates X and Y. each having large surface area A (on one side), are placed parallel to each other as shown in figure (30-E7). The plate X is given a charge Q whereas the other is neutral. Find (a) the surface charge density at the inner surface of the plates X, (b) the electric field at a point to the left of the plates, (c) the electric field at a point in between the plates and (d) the electric field at a point to the right of the plates.

(A ): The surface densities of two spherical conductors of different radii are equal. Then the electric field intensities near their surface are also equal. (R ): Surface density is equal to charge per unit area.

An infinite thin plane sheet of charge density 7.08 xx 10^(-11)(C //m^(2)) is held in air. Find the electric field at a point very close to the sheet.

A uniformly charged non conducting disc with surface charge density 10nC//m^(2) having radius R=3 cm . Then find the value of electric field intensity at a point on the perpendicular bisector at a distance of r=2cm