Two point charges `q_(1) and q_(2)`, of magnitude `+10^(–8) C and –10^(–8)C`, respectively, are placed 0.1 m apart. Calculate the electric fields at points A, B and C shown in Fig. 1.14.

Two point charges +10^(-7) C and -10^(-7)C are placed at A and B 20 cm apart as shown in the figure. Calculate the electric field at C, 20 cm apart from both A and B.

Two charges +5mu C and +10 mu C are placed 20 cm apart. The net electric field at the mid-point between the two charges is

Two point charges q_(A)= 3mu C and q_(B) = - 3muC are located 20cm apart in vacuum. What is the electric field at the mid point of the line joining the two charges.

Two point charges q_(A) = 3 mu C and q_(B) = -3 muC are located 20 cm apart in vaccum (a) what is the electric field at the mid point O of the line AB joining the two charges ? (b) If a negative test charge of magnitude 1.5xx10^(-9) C is placed at the point, what is the force experienced by the test charge ?

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

Three large identical conducting parallel plates carrying charge +Q , -Q, and +2Q , respectively, are placed as shown in figure. If E_A, E_b, and E_C refer to the magnitudes of the electric field at points A, B, and C, respectively. Then

Two point charges Q_1 = 400 muC and Q_2 = 100 muC are kept fixed, 60 cm apart in vacuum. Find intensity of the electric field at midpoint of the line joining Q_1 and Q_2 .

Two charges q_(1) and q_(2) are placed at (0,0,d) and (0,0,-d) respectively. Find locus of points where the potential is zero.

Two point charges +8q and -2q are located at x=0 and x=L respectively. The location of a point on the x axis at which the net electric field due to these two point charges is zero is

The positions of two point charges q_(1) and q_(2) are vecr_(1) and vecr_(2) , respectively. Find the position of the point where the net field is zero due to thses charges.