Three point charges, +6.8 µC, +1.4 µC, and −3.3 µC, lie along the x-axis at 0...

(Question 1 of 3) Three-point charges, +5.7 µC, +1.3 µC, and −3.2 µC, lie along the...

(Question 1 of 3) Three-point charges, +5.7 µC, +1.3 µC, and −3.2 µC, lie along the x-axis at 0 cm, 1.6 cm, and 5.4 cm, respectively. What is the force exerted on q1 by the other two charges? (To the right is positive.) The Coulomb constant is 8.99 × 109 N · m2 /C 2 . Answer in units of N. (Question 2 of 3)What is the force exerted on q2 by the other two charges? (To the right is...

Three point charges, +6.0 μC, +1.8 μC, and −3.0 μC, lie along the x-axis at 0...

Three point charges, +6.0 μC, +1.8 μC, and −3.0 μC, lie along the x-axis at 0 cm, 1.5 cm, and 5.4 cm, respectively. What is the force exerted on q1 by the other two charges? (To the right is positive.) Coulomb constant is 8.99 × 10 N · m /C . Answer in units of N (Part B): What is the force exerted on q2 by the other two charges? (To the right is positive.)Answer in units of N. (Part...

Three point charges are arranged along the x-axis. Charge q1 = +3.75 µC is at the...

Three point charges are arranged along the x-axis. Charge q1 = +3.75 µC is at the origin, and charge q2 = -5.25 µC is at x = 0.300 m. Charge q3 = -9.00 µC. Where is q3 located if the net force on q1 is 6.00 N in the −x-direction?

Three point charges are on the x axis: q1 is at the origin, q2 is at...

Three point charges are on the x axis: q1 is at the origin, q2 is at x = +3.8 m, and q3 is at x = +5.1 m. Find the electrostatic potential energy of this system of charges for the following charge values. (Assume the potential energy is zero when the charges are very far from each other.) (a) q1 = q2 = q3 = +2.7 µC (b) q1 = q2 = +3.3 µC and q3 = -3.3 µC (c)...

Two electrostatic point charges of +55.0 µC and +48.0 µC exert a repulsive force on each...

Two electrostatic point charges of +55.0 µC and +48.0 µC exert a repulsive force on each other of 160 N. What is the distance between the two charges? The value of the Coulomb constant is 8.98755 × 109 N · m2 /C 2 . Answer in units of m.

Three point charges lie along a straight line as shown in the figure, where q1= 35.00...

Three point charges lie along a straight line as shown in the figure, where q1= 35.00 uC, q2= 1.50 µC, and q3=-2.00 µC. The separation distances are d1 = 3.00 cm and d2 = 2.00 cm. Calculate the magnitude of the resultant electric force on q1.

Three point charges lie along a straight line as shown in the figure below, where q1...

Three point charges lie along a straight line as shown in the figure below, where q1 = 5.52 µC, q2 = 1.61 µC, and q3 = -2.14 µC. The separation distances are d1 = 3.00 cm and d2 = 2.00 cm. Calculate the magnitude and direction of the net electric force on each of the charges.

Three point charges are located on the x-axis at the following positions: Q1 = +4.00 μC...

Three point charges are located on the x-axis at the following positions: Q1 = +4.00 μC is at x = 1.00 m, Q2 = +6.00 μC is at x = 0.00, and Q3 = -8.00 μC is at x = -1.00 m. What is the magnitude of the electric force on Q2? (k = 1/4πε0 = 8.99 × 109 N ∙ m2/C2)

Three charges lie along the x-axis. One positive charge, q1 = 25 uC is at x...

Three charges lie along the x-axis. One positive charge, q1 = 25 uC is at x = 0.25 m. Another charge, q2 = -5.0 uC, is located at the origin. A third charge, q3 = -35 uC, is placed so that q2 is in electrostatic equilibrium with q1 and q3. How large must the electrostatic force between q2 and q3 be to balance the force between q1 and q2?

Three point charges are on the x axis: q1 is at the origin, q2 is at...

Three point charges are on the x axis: q1 is at the origin, q2 is at x = +3.4 m, and q3 is at x = +6.5 m. Find the electrostatic potential energy of this system of charges for the following charge values. (Assume the potential energy is zero when the charges are very far from each other.) 1) (a) q1 = q2 = q3 = +4.2 µC 2) (b) q1 = q2 = +4 µC and q3 = -4...