A body of capacity `4 muF` is charged to `80V` and another body of capacity `6muF` is charged to `30V`. When they are connected the energy lost by `4 muF` capacitor is

A capacitor of capacitance 4muF is charged to 80V and another capacitor of capacitance 6muF is charged to 30V are connected to each other using zero resistance wires such that the positive plate of one capacitor is connected to the positive plate of the other. The energy lost by the 4muF capacitor in the process in X**10^(-4)J . Find the value of X.

A condenser A of capacity 4muF has a charge 20muC and another condenser B of capacity 10muF has a charge 40muC . If they are connected parallel, then

A capacitor A of capacitance 4muF is charged to 30V and another capacitor B of capacirtance muF is charged to 15V . Now, the opositive plate of A is connected to the negative plate of B and negative plate of A to the positive plate of B . find the final charge of each capacitor and loss of electrostatic energy in the process.

4muF capacitor is charged to 150 V and another capacitor of 6muF is charged to 200 V. Then they are connected across each other. Find the potential difference across them. Calculate the heat produced.

Find the charges on 6muF and 4muF capacitors

The charge on capacitor 4muF is

A capacitor 4 muF charged to 50 V is connected to another capacitor of 2 muF charged to 100 V with plates of like charges connected together. The total energy before and after connection in multiples of (10^(-2) J) is

A capacitor of capacity 10muF is subjected to charge by a battery of 10 V. Calculate the energy stored in the capacitor.

A condenser has a capacity 2muF and is charged to a voltage of 50 V. The energy stored is

A parallel plate air condenser of capacity 4muF is charged to a potential of 1000 V. the energy of the condenser is