Two capacitors of capacitance `C_(1) = 2 muF` and `C_(2) = 8 mu F` are connected in series and the resulting combination is connected across 300 volts. Calculate the charge, potential difference and energy stored in the capacitor separately.

Two capacitors of capacitances C_(1)=2muF and C_(2)=8muF are connected in series and the resulting combination is connected across a 300V battery. Calculate the charge, potential difference and energy stored in the capacitor separately.

Two capacitors of capacitances C_(1)=2muF and C_(2)=8muF are connected in series and the resulting combination is connected across a 300V battery. Calculate the charge, potential difference and energy stored in the capacitor separately.

Three capacitors of 10,15 and 30 muF are connected in series and on this combination a potential difference of 60 V is applied. Calculate the charge, potential difference and energy stored on each capacitor.

Two capacitors of capacities 1 mu F and C mu F are connected in series and the combination is charged to a potential difference of 120 V. If the charge on the combination is 80 mu C, the energy stored in the capacitor of capacity C in mu J is

Two capacitors of capacitance C_(1) and C_(2) are connected in parallel and a charge Q is delivered to the combination. The two are then disconnected and reconnected in series. What are the new potential differences and charge on the capacitors?

Two capacitors of capacites 1 mu F and C mu F are connected in series and the combination is charged to a potential difference of 120 V . If the charge on the combination is 80 muC , the energy stored in the capacitor C in micro joules is :

Two capacitors of capacitances 20muF and 60muF are connected in series. IF the potential difference between the two ends of the combination is 40 volt, calculate the terminal potential difference pf each capacitor.