Each capacitance shown in is in `muF`. Find the charge on `6 muC`.
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All the capacitances shown in figure are in muF . Find the equivalent capacitance between A and B.

Six capacitors each of capacitance 1 muF are connected as show in . Find the charge flowing in direction 1 as shown in the figure will be .

The capacitance of a capacitor is 3 muF . If a charge of 108muC , exists on it, calculate its potential .

In each capacitance C_(1) is 6.0 muF , and each capacitance C_(2) is 4.0 muF . . The charge on C_(1) nearest to a when V_(ab)=420 V is.

In the given circuit it is known that the capacitor A has a capacitance of 2 muF and carries a charge of 40 muC . Capacitor C has a capacitance of 6 muF and carries a charge of 180 muC . The positive plate of both capacitors has been indicated in the Figure. Capacitance of capacitor B is 3 muF . Calculate charge on B after the switch S is closed.

Several capacitors are connected as shown in. If the charge on the 5 muF capacitor is 120 muC , the potential between points A and D is .

In the circuit shown in figure-3.395, find the charges on capacitors of capacitances 5 mu F and 3 muF , in steady state.

Four capacitors C_(1)=8 muF , C_(2)=2 muf, C_(3)=6 muF , and C_(4)=6, muF are arranged as shown in. Find the charge on all the capacitors in the circuit. .

In the network shown in figure. C_(1)=C_(2)=C_(3)=C_(4)=10muF . Find th equivalent capacitance between the points A and B, what will be the charge on each capacitor?

A capacitor of 5muF capacitance is charged with an initial charge 60muC as shown in figure and connected across a 10V battery. Find the amount of heat produced when switch is closed.