Two capacitors of capacitance `6muF and 12muF` are connected in series with a battery. The voltage across the `6muF` capacitors is 2V. Compute the total battery voltage.

Two capacitors of capacitance of 6 muF and 12 muF are connected in series with a battery. The voltage across the 6 muF capacitor is 2V. Compute the total battery voltage.

Two capacitors of 10muF and 20 muF are connected in series with a 30 V battery. The charge on the capacitors will be, respectively

Two capacitor of capacitance 4.0muF and 6.0muF' are connected in series with a battery of 20 V . Find the energy supplied by the battery .

Three capacitors having capanctances 20muF, 30muF and 40muF are conneceted in series with a 12V battary. Find the charge on each of the capacitors. How much work has been done by the battery in charging the capacitors?

The potential drop across 7muF capacitor is 6V. Then

Three capacitors of capacitances 2 muF , 3mu F and 6muF are connected in series with a 12 V battery. All the connecting wire are disconnected, the three positive plates are connected together and the three negative plates are connected together. Find the charges on the three capacitors after the reconnection.

Two capacitors of capacitances C_(1)=2muF and C_(2)=8muF are connected in series and the resulting combination is connected across a 300V battery. Calculate the charge, potential difference and energy stored in the capacitor separately.

The capacitor of capacitance 4 muF and 6 muF are connected in series. A potential difference of 500 volts applied to the outer plates of the two capacitor system. Then the charge on each capacitor is numerically

Three capacitors 3 muF, 6 muF and 6 muF are connected in series to source of 120 V. The potential difference in volt, across the 3 muF capacitor will be

Three capacitors of capacitances 3 muF, 9muF and 18 muF are connected one in series and another time in parallel. The ratio of equivalent capacitance in the two cases ((C_(s))/(C_(p))) will be