The capacitance between the adjacent plates shown in figure (31-E20 ) is `50 nF` . A charge of `1.0muC `is placed on the middle plate (a )What will be the charge on the outer surface pf the upper plate ? (b ) Find the potential difference developed between the upper and the middle plates .

A charge of 1 muC is given to one plate of a parallel - plate capacitor of capacitance 0.1muF and a charge of 2 muC is given to the other plate . Find the potential difference developed between the plate .

A charge of 20 microCoulomb is placed on the positive plate of on isolated parallel - plate capacitor of capacitance 10 microFarad calculate the potential difference developed between the plates .

A charge of +2.0xx 10 ^-8 C is placed on the positive plate and a charge of -1.0xx10 ^-8 C at negative plate. And capacitance of capacitor is 1.2 xx (10^-3) mu F . Calculate the potential difference developed between the plates.

The plates of a parallel-plate capacior are given equal positive charges .What will be the potential difference between the plates ? What will be the charges on the facing surfaces and on the outer surfaces ?

What is the work done in increasing the charge from Q_(1)" to "Q_(1) +delta_(1)+deltaQ_(1) , if the potential difference between the plates is V?

Consider the situation of the given figure . If 1.0muC is placed on the upper plate , what will be the potential difference between (a ) the upper and middle plates and (b ) the middle and the lower plate? If capacitance of each capacitor is 50 nF.

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.

Figure shows a capacitor made of two circular plates each of radius 12 cm and separated by 5.0 cm. The capacitor is being charged by an external source (not shown in the figure). The charging current is constant and equal to 0.15 A. a. Calculate the capacitance and the rate of change of potential difference between the plates. b. Obtain the displacement current across the plates. c. Is Kirchhoff's first rule (junction rule) valid at each plate of the capacitor ?

Find the capacitances of the capacitance shown In figure .The plate area is A and the separation between the plate is d . Different dielectric slabe in a particular part of the figure area of the same thickness and the entire gap between the plate is filled with the dielectric slabs.

Each of the three plates shown in figure has an area of 200 cm^2 on one side and the gap between the adjacent plates is 0.2 mm. The emf of the battery is 20V. Find the distribution of charge on various surfaces of the plates. What is the equivalent capacitance of the system between the terminal points?