Two capacitors A and B with capacitors `3 muF and 2 muF` are charged to a potential difference of 100 V and 180 V respectively. One plate of two capacitors are connected as shown. Now switch S is closed so as to connect a cell of 100 V to the free plates of two capacitors.
(a) Find charge on the two capacitors after the switch is closed.
(b) Calculate heat generated in the circuit

Two capacitors A and B with capacities 3 muF and 2 muF are charged to a potential differece of 100 V and 180 V , respectively. The plates ot the capacitors are connected as shown in, with one wire free from each capacitor. The upper plate of A is positive and that of B is negative An uncharged 2muF capacitor C with lead wires falls on the free ends to complete the circuit. i. Calculate the final charge on the three capacitors, ii. Find the amount of electrostatic energy stored in the system before and after the completion of the circuit. .

Two capacitors A and B with capacities 3 muF and 2 muF are charged to a potential differece of 100 V and 180 V , respectively. The plates ot the capacitors are connected as shown in, with one wire free from each capacitor. The upper plate of A is positive and that of B is negative An uncharged 2muF capacitor C with lead wires falls on the free ends to complete the circuit. i. Calculate the final charge on the three capacitors, ii. Find the amount of electrostatic energy stored in the system before and after the completion of the circuit. .

Two capacitors A and B with capacities 3muF and 2muF are charged to a potential difference of 100 V and 180V , respectively. The plates of the capacitors are connected as show in figure with one wire of each capacitor free. The upper plate of A is positive and that of B is negastive. An uncharged 2muF capcitor C with lead wires falls on the free ends to complete the circuit. Calculate a. the final charge on the three capacitors. b. the amount of electrostatic energy stored in the system before and after completion of the circuit.

Two capacitors A and B with capacities 3muF and 2muF are charged to a potential difference of 100 V and 180V , respectively. The plates of the capacitors are connected as show in figure with one wire of each capacitor free. The upper plate of A is positive and that of B is negastive. An uncharged 2muF capcitor C with lead wires falls on the free ends to complete the circuit. Calculate a. the final charge on the three capacitors. b. the amount of electrostatic energy stored in the system before and after completion of the circuit.

Two capacitors of capacitances 3 muF and 6 muF , are charged to potentials 2V and 5V respectively. These two charged capacitors are connected in series. Find the potential across each of the two capacitors now.

Two capacitors of 2muF and 3muF are charged to 150 V and 120 V , respectively. The plates of capacitor are connected as shown in the figure. An uncharged capacitor of capacity 1.5muF falls to the free end of the wire. Then

Two capacitors of 2muF and 3muF are charged to 150 V and 120 V , respectively. The plates of capacitor are connected as shown in the figure. An uncharged capacitor of capacity 1.5muF falls to the free end of the wire. Then

Two capacitors of 2muF and 3muF are charged to 150 V and 120 V , respectively. The plates of capacitor are connected as shown in the figure. An uncharged capacitor of capacity 1.5muF falls to the free end of the wire. Then