If potential difference across `3muF` is 4V, then total energy stored in all capacitors is

The energy stored in 4 muF capacitors is

Two capacitors of capacitances 20 .0pF and 50.0pF are connected in series with a 6.00V bettery . Find (a )the potential difference across each capacitor and (b) the energy stored in each capacitor .

Find the total energy stored in the capacitors in the given network.

A capacitance C , a resistance R and an emf (epsilon) are connected in series at t=0.What is the maximum value of (a) the potential difference across the resistor, (b) the current in the circuit,(c )the potential difference across the capacitor, (d) the energy stored in the capacitor ,(e)the power delivered by the battery and (f) the power converted int heat.

Find total energy stored in capacitors given in the circuit

The total electrostatic energy stored in both the capacitor is

The potential drop across 7muF capacitor is 6V. Then

Three uncharged capacitors are connected across a battery as shown. It is known that the energy stored in all the capacitors is same. Which of the following is not correct?

Three capacitors having capacitances of 8.4 muF, 8.4 muF and 4.2 muF are connected in series across a 36 potential difference. (a) What is the charge on 4.2muF capacitor? (b) What is the total energy stored in all three capacitors? (c) The capacitors are disconnected from the potential difference without allowing them to discharge. They are then reconnected in parallel with each other, with the positively charged plates connected together. What is the voltage across each capacitor in the parallel combination? (d) What is the total energy now stored in the capacitors?

A 8uF capacitor C_1 is charged to V_0 = 120 V . The charging battery is then removed and the capacitor is connected in parallel to an uncharged + 4muF capacitor C_2 . (a) what is the potential difference V across the combination? (b) what is the stored energy before and after the switch S is closed?