A) Identical positive charges are held in place to make the corners of a regular octagon....

Three identical point charges are located at the corners of an equilateral triangle that is 0.3m...

Three identical point charges are located at the corners of an equilateral triangle that is 0.3m on each side. If each charge is +20μC, than the magnitude of the net force (in N) on one of the charges due to the other two is..

Three equal positive point charges of magnitude Q = 9.00μ C are located at three corners...

Three equal positive point charges of magnitude Q = 9.00μ C are located at three corners of a square of edge length d = 8.1 cm. A negative charge -27.00μ C is placed on the fourth corner. At the position of the negative charge, what is the magnitude of the electric field due to the three positive charges? What is the magnitude of the attractive force on the negative charge?

Identical point charges of +1.2 µC are fixed to three of the four corners of a...

Identical point charges of +1.2 µC are fixed to three of the four corners of a square. What is the magnitude |q| of the negative point charge that must be fixed to the fourth corner, so that the charge at the diagonally opposite corner experiences a net force of zero? |q| = Number _______ Units _____

There are four charges, each with a magnitude of 1.91 μC. Two are positive and two...

There are four charges, each with a magnitude of 1.91 μC. Two are positive and two are negative. The charges are fixed to the corners of a 0.266-m square, one to a corner, in such a way that the net force on any charge is directed toward the center of the square. Calculate the magnitude of the net electrostatic force experienced by any charge.

There are four charges, each with a magnitude of 2.18 µC. Two are positive and two...

There are four charges, each with a magnitude of 2.18 µC. Two are positive and two are negative. The charges are fixed to the corners of a 0.21-m square, one to a corner, in such a way that the net force on any charge is directed toward the center of the square. Find the magnitude of the net electrostatic force experienced by any charge.

Three 6.8 micro coulomb charges are arranged at the corners of a an equilateral triangle with...

Three 6.8 micro coulomb charges are arranged at the corners of a an equilateral triangle with sides of length 0.3 meters. They are held in place initially. The charges have a mass of 10 grams. One side of the triangle is on the horizontal axis. Find : a) size of the force, in Newtons, acting on the charge at the top of the triangle due to the other two charges b) the direction of the force, in degrees, as measured...

Three 5.8 micro coulomb charges are arranged at the corners of a an equilateral triangle with...

Three 5.8 micro coulomb charges are arranged at the corners of a an equilateral triangle with sides of length 0.6 meters. They are held in place initially. The charges have a mass of 10 grams. One side of the triangle is on the horizontal axis. Find the: a) size of the force, in Newtons, acting on the charge at the top of the triangle due to the other two charges, b) the direction of the force, in degrees, as measured...

Three identical charged particles sit at the corners of an equilateral triangle of side length 30...

Three identical charged particles sit at the corners of an equilateral triangle of side length 30 cm. Each particle has a charge of 8.5μc. The charges Q1 and Q2 are positive and Q3 is negative. A.) What are the magnitude and the direction of the net force on charge Q2 is: B.) What is the total electric potential energy of the charge combination is

Three identical 50-kg balls are held at the corners of an equilateral triangle, 30 cm on...

Three identical 50-kg balls are held at the corners of an equilateral triangle, 30 cm on each side. If one of the balls is released, what is the magnitude of its initial acceleration if the only forces acting on it are the gravitational forces due to the other two masses? (​G =​ 6.67 × 10^-11 N · m^2/kg^2)

Three identical very small 50-kg masses are held at the corners of an equilateral triangle, 0,30m...

Three identical very small 50-kg masses are held at the corners of an equilateral triangle, 0,30m on each side. If one of the masses is released, what is its initial magnitude of acceleration if the only forces acting on it are the gravitational forces due to the other two masses? (G=6.67x10^-11 (Nm^2/kg^2))