Two insulated metallic spheres of `3mu F` and `5 muF` capacitances are charged to `300 V` and `500 V` respectively. The energy loss, when they are connected by a wire is

Two insulated spherical conductors of capacities 1muF and 2muF are charged to 100 V and 200 V respectively. The conductors are then brought in contact. The charges on the sphere after contact are

Two insulated metal spheres of raddi 10 cm and 15 cm charged to a potential of 150 V and 100 V respectively, are connected by means of a metallic wire. What is the charge on the first sphere?

The radii of two insulated metal spheres are 5 cm and 10 cm. They are charged up to potential of 10 esu and 15 esu, respectively. If the two shperes are connected with one another, what will be the loss of energy?

Two capacitors of capacitances 5muF" and "10muF are charged to 16V and 10V respectively. Find what will be the common potential when they are connected in parallel to each other.

Two spheres of radii 3 cm and 5 cm are charged to potentials 3000 and 4500 v respectively. They are then connected by a thin metallic wire. Calculate the loss of electric energy in this process. What happens to this energy?

Two spheres of radii 3 cm and 5 cm are changed to potnetials 3000 and 4500 V respectively. They are then connected bya thin metallic wire. Calculate the loss of electric energy in this process. What happens to this energy?

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