Plates of a parallel plate capacitor, having a potential difference 100 V applied across them, carry a surface charge density of `"50 nC cm"^(-2)`. Spacing between the plates is

The plates of a parallel plate capacitor are 5mm apart and 2m^2 in area. The plates are in vacuum. A potential difference of 10000 V is applied across the capacitor. Compute The electric field in the space between them.

The plates of a parallel plate capacitor are charged to a potential difference of 117 V and then connected across a resistor. The potential difference across the capacitor decreases exponentially with to time.After 1s the potential difference between the plates is 39 V, then after 2s from the start, the potential difference (in V) between the plates is

The plates of a parallel plate capacitor are charged to a potential difference of 117 V and then connected across a resistor. The potential difference across the capacitor decreases exponentially with to time.After 1s the potential difference between the plates is 39 V, then after 2s from the start, the potential difference (in V) between the plates is

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 parallel plate capacitor are 5mm apart and 2m^2 in area. The plates are in vacuum. A potential difference of 10000 V is applied across the capacitor. Compute The charge on each plate

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.