Two condensers, one of capacity `C` and the other of capacity `C//2` are connected to a `V` volt battery, as shown.

The work done in charging fully both the condensers is

Two capacitors C_1 and C_2 of capacitances C/2 and C/4 are connected to a V volt battery, as shown in figure. The ratio of energy slored in capacitors C_1 and C_2 is

Two condensers of capacities 4mF and 6mF are connected to two cells as shown. Then

Three condensers each of capacity C microfarad are connected in series. An exactly similar set is connected in parallel to the first one. The effective capacity of the combination is 4 muF . Then, the value of C in microfard is

Three condensers of same capacity connected in series has effective capacity 2mF. If they are connected in parallel and charged using a battery of emf 12V, the total energy stored in the combination is

The plate separation in a parallel plate condenser and plate area is A. If it is charged to V volt battery is diconnected then the work done increasing the plate separation to 2d will be

In the circuit, all capacitor are identical, each of capacity 2muF and they are infinite in number. If AB is connected to a battery of 10V then the charge drawn from the battery is :

A condenser of capacity 16 mF charged to a potential of 20 V is connected to a condenser of capacity C charged to a potential of 10 V as shown in the figure. If the common potential is 14 V. the capacity C is equal to

Two condensers of capacity 0.3 muF and 0.6muF respectively are connected in series. The combination is connected across a potential of 6 volts. The ratio of energies stored by the condensers will be

A condenser of capacity 1 mu F and a resistance 0.5 mega-ohm are connected in series with a DC supply of 2 V. The time constant of circuit is

A network of four capacitors of capacity equal to C_(1) = C, C_(2) = 2C, C_(3) = 3C and C_(4) = 4C are connected to a battery as shown in the figure. The ratio of the charges on C_(2) an C_(4) is