Answer to Question #188707 in Physics for Hinata

(a) Let "q_1=3\\ \\mu C", "q_2=-2\\ nC" and "q_3=12\\ \\mu C".Then, we can find the net force on a −2nC charge as follows:

"F_{net}=\\dfrac{8.99\\cdot10^9\\ \\dfrac{Nm^2}{C^2}}{(0.5\\ m)^2}(|(-2\\cdot10^{-9}\\ C)\\cdot12\\cdot10^{-6}\\ C|-|3\\cdot10^{-6}\\ C\\cdot(-2\\cdot10^{-9}\\ C)|)=6.47\\cdot10^{-4}\\ N."

The sign plus means that the net force directed to the right.

(b) Let "q_1=-2\\ nC", "q_2=3\\ \\mu C" and "q_3=12\\ \\mu C".Then, we can find the net force on a −2nC charge as follows:

"F_{net}=8.99\\cdot10^9\\ \\dfrac{Nm^2}{C^2}\\cdot(\\dfrac{|(-2\\cdot10^{-9}\\ C)\\cdot3\\cdot10^{-6}\\ C|}{(0.5\\ m)^2}+\\dfrac{|(-2\\cdot10^{-9}\\ C)\\cdot12\\cdot10^{-6}\\ C|}{(1.5\\ m)^2})=3.12\\cdot10^{-4}\\ N."

The sign plus means that the net force directed to the right.

(c) Let "q_1=3\\ \\mu C", "q_2=12\\ \\mu C" and "q_3=-2\\ nC". Let's first find the "x"- and "y"-components of the electric force:

"F_{13,x}=-8.99\\cdot10^9\\ \\dfrac{Nm^2}{C^2}\\cdot\\dfrac{|3\\cdot10^{-6}\\ C\\cdot(-2\\cdot10^{-9}\\ C)|}{(\\sqrt{(1\\ m)^2+(0.5\\ m)^2})^2}\\cdot\\dfrac{0.5\\ m}{\\sqrt{(1\\ m)^2+(0.5\\ m)^2}}=-1.93\\cdot10^{-5}\\ N,"

"F_{13,y}=-8.99\\cdot10^9\\ \\dfrac{Nm^2}{C^2}\\cdot\\dfrac{|3\\cdot10^{-6}\\ C\\cdot(-2\\cdot10^{-9}\\ C)|}{(\\sqrt{(1\\ m)^2+(0.5\\ m)^2})^2}\\cdot\\dfrac{1.0\\ m}{\\sqrt{(1\\ m)^2+(0.5\\ m)^2}}=-3.86\\cdot10^{-5}\\ N,"

"F_{23,y}=-8.99\\cdot10^9\\ \\dfrac{Nm^2}{C^2}\\cdot\\dfrac{|12\\cdot10^{-6}\\ C\\cdot(-2\\cdot10^{-9}\\ C)|}{(0.5\\ m)^2}=-8.63\\cdot10^{-4}\\ N,"

We can find the net electric force on "q_3" from the Pythagorean theorem:

We can find the direction of the net electric force from the geometry:

The net electric force on charge "q_3"directed "91.2^{\\circ}" below "x"-axis.