A, B C and D are large conduting plates kept parallel each other,A and D are fixed. Plates B and C connected to each other by a rigied conduction rod, can slide over friction less rails as shown,Initially the distence between `T^(1)` ates C and D.If now the rod (along with plates B and C) is slightly moved toward right, the capacitance between the terminals 1 and 2

Four identical conducting plates are placed parallel to each other at equal separations as shown below: Plates A and D are fixed while B and C are connected with the help of a conducting spring of spring constant k. Initially, the spring is in relaxed position and B and C are at rest, now the spring is compressed slightly by displacing B and C and then plates B and C are released to perform SHM. Now the capacitance of the system across PQ [ Mass of each plate is m]

Two large conducting plates are placed parallel to each other nad they carry equal and opposite charges with surface density sigma as shown in figure (30-E6). Find the electric field (a) at the left of the plates, (b) in between the plates and © at the right of the plates.

Two identical conducting very large plates P_1 and P_2 having charges +4Q and +6Q are placed very closed to each other at separation d. The plate area of either face of the plate is A. The potential difference between plates P_1 and P_2 is

Four metallic plates each with a surface area A of one side and placed at a distance d from each other. the plates are connected as shown in the fig. Then the capacitance of the system between a and b is -

All the plates shown in the figure are parallel to each other, the area of each plate is A, and the separation between each pair of facing plates is d. The equivalent capacitance between points A and B is

Four identical metal plates are placed in air parallel to each other with distances d from one another. The area of each plate is equal to A. The arrangement is shown in the figure. Find the capacitance of the system between plates P and R.

Five identical plates of equal area A are placed parallel to each other and at equal distance d from each other as shown in the figure. The effective capacity of the system between the terminals A and B is

X and Y are large, parallel conducting plates close to each other. Each face has an area A . X is given a charge Q . Y is without any charge. Points A,B and C are as shown in the figure.

A, B, C, D, E, and F are conducting plates each of area A , and any two consecutive plates are separated by a distance d , The energy in system after the switch S is closed is .

Four metallic plates arearrranged as shown in the figure. If the distance between each plate then capacitance of the gives system between points A and B is (Given d lt lt A)