A capacity of capacity `C_(1)` is charged up to `V` volt and then connected to an uncharged capacitor of capacity `C_(2)`. Then final potential difference across each will be

A capacitor or capacitance C_(1) is charge to a potential V and then connected in parallel to an uncharged capacitor of capacitance C_(2) . The fianl potential difference across each capacitor will be

A capacitor of capacitance C_(1) is charged to a potential difference V and then connected with an uncharged capacitor of capacitance C_(2) a resistance R. The switch is closed at t = 0. Choose the correct option(s):

A capacitor of capacity C charged to potential "V" and " then connected to an identical uncharged capacitor then loss of energy is

A capacitor of capacity C is charged to a potential difference V and another capacitor of capacity 2C is charged to a potential difference 4V . The charged batteries are disconnected and the two capacitors are connected with reverse polarity (i.e. positive plate of first capacitor is connected to negative plate of second capacitor). The heat produced during the redistribution of charge between the capacitors will be

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.

A 10 muF capacitor is charged to a potential difference of 1000 V . The terminals of the charged capacitor are disconnected from the power supply and connected to the terminals of an uncharged 6 muF capacitor. What is the final potential difference across each capacitor ?

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 capacitor C_(1) is charged to a p.d.V. The charging battery is then removed and the capacitor is connected to an uncharged capacitor C_(2) . The final p.d. across the combination is