Two charges pm 10 muC are placed 5.0 mm apart. Determine the electric field at (a) a point P on the axis of the dipole 15 cm away from its centre O on the side of the positive charges, as shown in Fig. (a) and (b) be a point Q, 15 cm away from O on a line passing through O and normal to the axis of the dipole, as shown in Fig (b).

Two charges pm 10 muC are placed 5.0 mm apart. Determine the electric

1.	Two charges pm 10 muC are placed 5.0 mm apart. Determine the electric field at (a) a point P on the axis of the dipole 15 cm away from its centre O on the side of the positive charges, as shown in Fig. (a) and (b) be a point Q, 15 cm away from O on a line passing through O and normal to the axis of the dipole, as shown in Fig (b).
Answer» Solution :Field at P due to charge `+10 muC=(10^(-5))/(4 pi (8.854 xx 10^(-12))) xx (1)/((15-0.25)^(2) xx 10^(-4))` `=4.13 xx 10^(6) NC^(-1)` along BP Field at P due to charge `-10muC=(10^(-5))/(4pi (8.854 xx 10^(-12))) xx (1)/((15+0.25)^(2) xx 10^(-4))` The RESULTANT electric field P due to the two charges at A and B is `= 2.7 xx 10^5 NC^(-1)` along BP. In this EXAMPLE, the ratio OP/OB is quite large (= 60). Thus, we can expect to get approximately the same result as above by directly using the formula for electric field at a far-away point on the axis of a dipole. For a dipole consisting of charges `pm q`, 2a distance apart, the electric field at a distance r from the centre on the axis of the dipole has a MAGNITUDE `E=(2p)/(4pi epsi_(0) r^(3)) " when r" gt gt a` where p=2a q is the magnitude of the dipole moment. The direction of electric field on the dipole axis is always along the direction of the dipole moment vector (i.e., from -q to q). Here, `p =10^(-5) xx 5 xx 10^(-3)= 5 xx 10^(-8)Cm` Therefore`E=(2 xx 5 xx 10^(-8))/(4pi (8.854 xx 10^(-12))) xx (1)/((15)^(2)xx 10^(-6)) =2 .6 xx 10^(5) NC^(-1)` along the dipole moment direction AB, which is close to the result OBTAINED earlier. Field at Q due to charge `+10muC" at B "=(10^(-5))/(4pi (8.851 xx 10^(-12))) xx (1)/([15^(2) +(0.25)^(2) ] xx 10^(-4))` Field at Q due to charge `-10muC" at A"=(10^(-5))/(4pi (8.854 xx 10^(-12))) xx (1)/([15^(2)+(0.25)^(2)] xx 10^(-4))` `=3.99 xx 10^(6) NC^(-1)" along QA"`. Clearly, the components of these two forces with equal magnitudes cancel along the direction OQ but add up along the direction PARALLEL to BA. Therefore, the resultant electric field at due to the two charges at A and B is `=2 xx (0.25)/sqrt(15^(2)+(0.25)^(2)) xx 3.99 xx 10^(6)" along BA="1.33 xx 10^(5) NC^(-1)" along BA"`. As in (a), we can expect to get approximately the same result using the formula for dipole field at a point on the normal to the axis of the dipole. When `r gt gta, E=p/(4pi epsi_(0) r^(3))=(5 xx 10^(-8))/(4 pi (8.854 xx 10^(-12)) xx (1)/((15)^(3) xx 10^(-8)) =1.33 xx 10^(5) NC^(-1)` The direction of electric field in this case in opposite to the direction of the dipole moment vector.

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