Two point charges are on the y axis. A 6.00
The electric potential from each charge is K*q/r, where r is the distance to the charge measured from the origin. Potentials add algebraically. For the first charge, V1 = K*6.0*10^-6/0.0125 and for the second V2 = K*(-2.02*10^-6)/(-0.018). The total potential at the origin is V1 + V2.
Two charges (dipole) of +q = +6.00 μC and −q = −6.00 μC along the y-axis, separated by 3.00 m, as shown in the figure below. Point P is located 4.00 m directly to the right of the positive charge, as shown. The origin is located halfway between the charges. (a) At point P (test point), sketch and label the electric field E+ due to the positive charge +q, and the electric field E - due to the negative charge...
Two charges of ±6.00 µC on the x-axis. the negative charge is at -5 cm and the positive one is at 5 cm. Find the magnitude of the electric field at point P on the y-axis, which is 7.00 cm from each charge.
Two point charges are fixed on the y axis: a negative point charge q1 = -34 μC at y1 = +0.22 m and a positive point charge q2 at y2 = +0.35 m. A third point charge q = +8.3 μC is fixed at the origin. The net electrostatic force exerted on the charge q by the other two charges has a magnitude of 26 N and points in the +y direction. Determine the magnitude of q2. Chapter 18, Problem...
Two point charges are fixed on the y axis: a negative point charge q1 = -28 μC at y1 = +0.21 m and a positive point charge q2 at y2 = +0.38 m. A third point charge q = +8.8 μC is fixed at the origin. The net electrostatic force exerted on the charge q by the other two charges has a magnitude of 29 N and points in the +y direction. Determine the magnitude of q2. Chapter 18, Problem...
Two point charges are fixed on the y axis: a negative point charge q1 = -26 µC at y1 = +0.20 m and a positive point charge q2 at y2 = +0.30 m. A third point charge q = +8.6 µC is fixed at the origin. The net electrostatic force exerted on the charge q by the other two charges has a magnitude of 22 N and points in the +y direction. Determine the magnitude of q2.
Two point charges are fixed on the y axis: a negative point charge q1 = -25 μC at y1 = +0.20 m and a positive point charge q2 at y2 = +0.31 m. A third point charge q = +8.4 μC is fixed at the origin. The net electrostatic force exerted on the charge q by the other two charges has a magnitude of 29 N and points in the +y direction. Determine the magnitude of q2.
Two point charges are fixed on the y axis: a negative point charge q1 = -31 μC at y1 = +0.16 m and a positive point charge q2 at y2 = +0.32 m. A third point charge q = +9.0 μC is fixed at the origin. The net electrostatic force exerted on the charge q by the other two charges has a magnitude of 28 N and points in the +y direction. Determine the magnitude of q2.
Two point charges are fixed on the y axis: a negative point charge q1 = -27 µC at y1 = +0.20 m and a positive point charge q2 at y2 = +0.33 m. A third point charge q = +9.1 µC is fixed at the origin. The net electrostatic force exerted on the charge q by the other two charges has a magnitude of 20 N and points in the +y direction. Determine the magnitude of q2.
Two point charges are fixed on the y axis: a negative point charge q1 = -26 μC at y1 = +0.23 m and a positive point charge q2 at y2 = +0.33 m. A third point charge q = +8.7 μC is fixed at the origin. The net electrostatic force exerted on the charge q by the other two charges has a magnitude of 28 N and points in the +y direction. Determine the magnitude of q2.
Two point charges are fixed on the y axis: a negative point charge q1 = -28 µC at y1 = +0.23 m and a positive point charge q2 at y2 = +0.33 m. A third point charge q = +8.0 µC is fixed at the origin. The net electrostatic force exerted on the charge q by the other two charges has a magnitude of 25 N and points in the +y direction. Determine the magnitude of q2.