[" 1.A potential difference of "250" volt is applied across the "],[" plates of a capacitor of "10pF" .Calculate the change on "],[" the plates of the capacitar."]

A potential difference of 250 Volt is applied across the plate of a capacitor of 10 pF. Calculate the charge on the plates of the capacitor.

The plates of a parallel-plate capacitor in vacuum are 5.00 mm apart and 2.00 m^2 in area. A potential difference of 10,000 V is applied across the capacitor. Compute (a) the capacitance (b) the charge on each plate, and (c) the magnitude of the electric field in the space between them.

The plates of a parallel-plate capacitor in vacuum are 5.00 mm apart and 2.00 m^2 in area. A potential difference of 10,000 V is applied across the capacitor. Compute (a) the capacitance (b) the charge on each plate, and (c) the magnitude of the electric field in the space between them.

The plates of a parellel plate capacitor in vacuum are 5mm apart and 1.5m^2 in area. A potential difference of 10kV is applied across the capacitor. Calculate: I) the capacitance, II) the charge on each plate, III) magnitude of the intensity of electric field between the paltes

A parallel capacitor has capacitance 20muF . A potential difference of 220 V is applied across it. Calculate the charge on the plates and energy stored in the capacitor. If a dieletric slab of dielectric constant 5 is introduced between its plates, calculate the new value of potential difference and the energy stored.

A potential difference of 20 volts develops between the plates of the capacitor when 2xx10^(12) electrons are transferred from one plate of the capacitor to the other. What should be the capacitance of capacitor?

A capacitor is charged steadily from a DC source. Correct variation of potential difference across the plates of capacitor with charge on the plates of capacitor is