A `10 muF` capacitor is charged to a potential difference of `50 V` and is connected to another uncharged capacitor in parallel. Now the common potential difference becomes `20` volt. The capacitance of second capacitor is

A 100 mu F capacitor is charged to a potential difference of 24 V . It is connected to an uncharged capacitor of capacitance 20 mu F What will be the new potential difference across the 100 mu F capacitor?

A 100 mu F capacitor is charged to a potential difference of 24 V . It is connected to an uncharged capacitor of capacitance 20 mu F What will be the new potential difference across the 100 mu F capacitor?

A 20muF capacitor is charged to a potential of 20V and is then connected to an uncharged 10muF capacitor. Find out the common potential and the ratio of the energies stored in the two capacitors.

A capacitor of capacitance of 2muF is charged to a potential difference of 200V , after disconnecting from the battery, it is connected in parallel with another uncharged capacitor. The final common potential is 20V then the capacitance of second capacitor is :

A condenser of capacitance 10 muF has been charged to 100V . It is now connected to another uncharged condenser in parallel. The common potential becomes 40 V . The capacitance of another condenser is

A condenser of capacitance 10 muF has been charged to 100V . It is now connected to another uncharged condenser in parallel. The common potential becomes 40 V . The capacitance of another condenser is