Three charges `q_(1)=1 mu c,q_(2)=2 mu c` and `q_(3)=-3 mu c` and four surfaces `S_(1),S_(2),S_(3)` and `S_(4)` are shown. The flux emerging through surface `S_(2)` in `N-m^(2)//C` is-

Three charges q_1 = 1 mu C, q_2 = -2 mu C, and q_3 = -1 mu C are placed at A (0,0,0), B(-1 , 2,3,) and C (2 , -1, 1) . Find the potential of the system of three charges at P( 1, - 2, -1) .

In, the charges on C_(1),C_(2) , and C_(3) , are Q_(1), Q_(2) , and Q_(3) , respectively. .

Four capacitors C_(1)(=1 muF),C_(2)(=2muF),C_(3)(=3muF) and C_(4)(=4 muF) are connected in a network as shown in the diagram. The emf of the battery is E = 12 V and its internal resistance is negligible. The keys S_(1) and S_(2) can be independetly put on or off. Indicate the charge on the capacitors by q_(1),q_(2),q_(3) and q_(4) respectively and the potential drops across them by V_(1),V_(2),V_(3) and V_(4) respectively. Initially key S_(2) is closed. Then the key S_(1) is now closed. Then the charges on the capacitors are.

Four capacitors C_(1)(=1 muF),C_(2)(=2muF),C_(3)(=3muF) and C_(4)(=4 muF) are connected in a network as shown in the diagram. The emf of the battery is E = 12 V and its internal resistance is negligible. The keys S_(1) and S_(2) can be independetly put on or off. Indicate the charge on the capacitors by q_(1),q_(2),q_(3) and q_(4) respectively and the potential drops across them by V_(1),V_(2),V_(3) and V_(4) respectively. Initially key S_(2) is open. The key S_(1) is closed and teh capacitors are charged. If now key S_(2) be closed, the charge that will flow across this key is.

Charges q_(1) , q_(2) and q_(3) are placed on capacitors of capacitance C_(1) , C_(2) and C_(3) , respectively, arranged in series as shown. Switch S is there closed. What are the final charges q'_(1) , q'_(2) and q'_(3) on the capacitors? Given q_(1)=30muC , q_(2)=muC , q_(3)=10muC , C_(1)=10muF , C_(2)=20muF , C_(3)=30muF and epsilon=12"volt"

Two capacitros of capacity 6 mu F are charged to 100 V and 50 V separately and connected as shown. Now all the three switches S_(1), S_(2) and S_(3) are closed. Suppose q_(1), q_(2) and q_(3) be the magnitudes of charge flown from switches S_(1), S_(2) and S_(3) after they closed. Then

Four capacitors C_(1)(=1 muF),C_(2)(=2muF),C_(3)(=3muF) and C_(4)(=4 muF) are connected in a network as shown in the diagram. The emf of the battery is E = 12 V and its internal resistance is negligible. The keys S_(1) and S_(2) can be independetly put on or off. Indicate the charge on the capacitors by q_(1),q_(2),q_(3) and q_(4) respectively and the potential drops across them by V_(1),V_(2),V_(3) and V_(4) respectively. Initially both the keys are open. Then the key S_(1) is closed. Then the charges on the capacitors are.

Two point charges q_(1) = 4 mu C and q_(2) = 9 mu C are placed 20 cm apart. The electric field due to them will be zero on the line joining them at distamce of

In the figure shown sphere S_(1),S_(2) and S_(3) have radii R,(R)/(2)and (R)/(4) respectively C_(1),C_(2) and C_(3) are centers of the three spheres lying in a plane Angle angleC_(1)C_(2)C_(3) is right angle. Sphere S_(3) has a uniformly spread volume charge density 4rho. the remaining pat of S_(2) has uniform charge density of 2rho and the left over part of S_(1) has a uniform charge density of rho . (a) Find electric field at a point A at a distance (R)/(8) from C_(3) on the line, C_(2)C_(3) (see figure) (b). Find electric field at point B at a distance (R)/(4) from C_(2) on the line C_(3)C_(2) (See figure)

Three capacitors C _(1) =2 mu F, C _(2) 6 mu F and C _(3) = 12 mu F are connected as shown in figure. Find the ratio of the charges on capacitors C _(1), C _(2) and C _(3) respectively :