A conductor of capacitance `0.5muF` has been charged to 100volts. It is now connected to uncharged conductor of capacitance `0.2muF`. The loss in potential energy is nearly

A condenser of of capacity 2 muF is charged to a potential of 100V. It is now connected to an uncharged condenser of capacity 3muF . The common potential will be

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

A capacitor of capacitor of capacitance 2.0muF is charge to a potential diffrence of 12V It is then connected of uncharged capacitor of capacitance 4.0muF as shown in figure . Find (a ) the charge on each of the two capacitors after the connection, (b ) the electrostatic energy stored in each of the two capacitors.

A capacitor of capacitor of capacitance 2.0muF is charge to a potential diffrence of 12V It is then connected of uncharged capacitor of capacitance 4.0muF as shown in figure . Find (a ) the charge on each of the two capacitors after the connection, (b ) the electrostatic energy stored in each of the two capacitors.

An isolated capacitor of unknown capacitance has been charged to potential V_(0) . This capacitor is then connected to an uncharged capacitor of capacity C . If common potential is V(ltV_(0) , find unknow capacitance.

An isolated capacitor of unknown capacitance has been charged to potential V_(0) . This capacitor is then connected to an uncharged capacitor of capacity C. If common potential is V(ltV_(0)) , find unknown capacitance.