A potential difference of `300` volts is applied to a combination of `2.0 muF` and `8.0 muF` capacitors connected in series. The charge on the `2.0 muF` capacitor is

Three capacitors of 2.0, 3.0 and 6.0 muF are connected in series to a 10 V source. The charge on the 3.0 muF capacitor is

Three capacitors 2,3 and 6 muF are connected in series to a 10 V source. The charge on 3muF capacitor is

Two capacitors of 10muF and 20 muF are connected in series with a 30 V battery. The charge on the capacitors will be, respectively

Two capacitors of 10muF and 20 muF are connected in series with a 30 V battery. The charge on the capacitors will be, respectively

The capacitor of capacitance 4 muF and 6 muF are connected in series. A potential difference of 500 volts applied to the outer plates of the two capacitor system. Then the charge on each capacitor is numerically

The capacitor of capacitance 4 muF and 6 muF are connected in series. A potential difference of 500 volts applied to the outer plates of the two capacitor system. Then the charge on each capacitor is numerically

Two capacitors of 10muF and 20muF are connected is series with a 30 V battery. The charge on the capacitors will be respectively

Three capacitors of capacitance 1.0muF,2.0muF" and "5.0muF are connected in series to a 10V source. The potential difference across the 2.0muF capacitor is

Three capacitors of capacitacnce 1.0, 2.0 and 5.0muF are connected in series to a 10 V source. The potential difference across the 2.0muF capacitor is