Two balls, each having a charge of + 6.00 micro Coulombs, are separated by a distance...

Charge 1 of +3 micro-coulombs is placed at the origin, charge 2 of +21 micro-coulombs is...

Charge 1 of +3 micro-coulombs is placed at the origin, charge 2 of +21 micro-coulombs is placed at x = +0.31 m, y = -0.64 m, charge 3 of -3 micro-coulombs is placed at x = -0.27 m, y = 0 m. What is the magnitude of the total electric force on charge 1 in Newtons?

Two charges are placed on the y axis. One charge of +3.5 micro-coulombs is placed at...

Two charges are placed on the y axis. One charge of +3.5 micro-coulombs is placed at y +3.9 m, and another charge of +10.7 micro-coulombs is placed at y = -4.8 m. If a third charge of -6 micro-coulombs is placed between them, where on the y axis (i.e. y = ______) is the total for electric force on this charge equal to zero? Answer in meters.

Charge 1 of +3 micro-coulombs is placed at the origin, charge 2 of +16 micro-coulombs is...

Charge 1 of +3 micro-coulombs is placed at the origin, charge 2 of +16 micro-coulombs is placed at x = +0.29 m, y = -0.56 m, charge 3 of -4 micro-coulombs is placed at x = -0.53 m, y = 0 m. Measured counter-clockwise in degrees, what is the angle of the total electric force vector on charge 1?

Charge 1 with a mass of 4 grams and a charge of +8 micro-coulombs is initially...

Charge 1 with a mass of 4 grams and a charge of +8 micro-coulombs is initially resting on a horizontal surface with friction. Charge 2 of +18 micro-coulombs is held in place 23 cm directly above charge 1. A third charge of -6 micro-coulombs is initially placed far from charge 1 directly to the left of charge 1. It is slowly brought closer to charge 1, at what distance will it begin to move charge 1 and overcome friction if...

Balls are attached to the ends of two strings, each of length 0.400 m. Each ball...

Balls are attached to the ends of two strings, each of length 0.400 m. Each ball is given a charge of - 3.00 micro-coulombs, and the strings swing upward so that in equilibrium they are separated by an angle of =40.0 . Determine the mass of each ball.

a point charge of 5 micro coulombs is placed at the origin and a second point...

a point charge of 5 micro coulombs is placed at the origin and a second point charge of -3 micro coulombs is placed at x=0.370m. where along the x axis can a third charge be placed so that the net force on it is zero? for this part I got 1.64m which was marked corrected but the second part asks, what if both charges are positive?

Four identical particles, each having charge q=28 micro coulomb , are fixed at the corners of...

Four identical particles, each having charge q=28 micro coulomb , are fixed at the corners of a square of side L=25cm . A fifth point charge Q=-28 micro coulomb lies a distance z=7cm along the line perpendicular to the plane of the square and passing through the center of the square as shown in Figure 3. Calculate the force exerted by the other four charges on -Q ?

Two Styrofoam balls have the same charge. Each ball has an excess of N = 108...

Two Styrofoam balls have the same charge. Each ball has an excess of N = 108 protons. The balls are initially separated by a distance, d = 1.9 m. The Coulomb constant is k = 8.988 × 109 N m2/C2. Part (a) Write an expression for the charge on one of the balls, Q, in terms of the charge on a proton e and the number of excess protons Part (b) What is the magnitude of the force between the...

Two tiny conducting spheres are identical and  carry charges of 3.94 micro-Coulomb and -2.39 micro-Coulomb.They are separated...

Two tiny conducting spheres are identical and  carry charges of 3.94 micro-Coulomb and -2.39 micro-Coulomb.They are separated by a distance of  5.89 cm.The spheres are brought into contact and then separated back to the original distance. Determine the magnitude of the force that each sphere now experiences, and state whether the force is attractive or repulsive.

Two small spheres, A and B, are separated by a distance of 1.5 m as shown...

Two small spheres, A and B, are separated by a distance of 1.5 m as shown below. Sphere A has a charge of 3 μC and Sphere B has a charge of -6 μC. (The prefix \"μ\" means \"micro\" which is a \"millionth.\" So, 1 microCoulomb = one-millionth of a Coulomb = 10-6 C.) Sphere C, is now moved to a new position that is directly above Sphere A. The distance between A and C is still half the distance...