The figure shows four particles, each of mass 30.0 g, that form a square with an...

The figure shows four particles, each of mass 20.0 g, that form a square with an...

The figure shows four particles, each of mass 20.0 g, that form a square with an edge length of d = 0.400 m. If d is reduced to 0.100 m, what is the change in the gravitational potential energy of the four-particle system?

In the figure the four particles form a square of edge length a = 5.60 cm...

In the figure the four particles form a square of edge length a = 5.60 cm and have charges q1 = 6.16 nC, q2 = -21.6 nC, q3 = 21.6 nC, and q4 = -6.16 nC. What is the magnitude of the net electric field produced by the particles at the square's center?

In the figure the four particles form a square of edge length a = 4.10 cm...

In the figure the four particles form a square of edge length a = 4.10 cm and have charges q1 = 8.11 nC, q2 = -21.6 nC, q3 = 21.6 nC, and q4 = -8.11 nC. What is the magnitude of the net electric field produced by the particles at the square's center?

n the figure, a square of edge length 16.0 cm is formed by four spheres of...

n the figure, a square of edge length 16.0 cm is formed by four spheres of masses m1 = 5.10 g, m2 = 2.90 g, m3 = 0.600 g, and m4 = 5.10 g. In unit-vector notation, what is the net gravitational force from them on a central sphere with mass m5 = 2.80 g?

Four identical particles (charge Q=1.6 nC, mass m = 4 g) are placed at corners of...

Four identical particles (charge Q=1.6 nC, mass m = 4 g) are placed at corners of a square of side b = 5.9 cm. What is the electric potential energy of this system? (The electric potential energy is zero when the particles are very far apart.) The particles are now released from rest. What is the speed of each particle when they are very far apart? (You may ignore gravity.)

Four stars, each having a mass M, are situated in a square pattern (each star is...

Four stars, each having a mass M, are situated in a square pattern (each star is at the corner of the square) and are rotating about the system's center of mass. At what speed must they move for the system to maintain its square shape, such that the system does not collapse due to mutual gravitational attraction of the stars? Assume a side length of a for the square, and express your answer in terms of M, G, and a.

In the figure, two particles, each with mass m = 0.86 kg, are fastened to each...

In the figure, two particles, each with mass m = 0.86 kg, are fastened to each other, and to a rotation axis at O, by two thin rods, each with length d = 5.4 cm and mass M = 1.2 kg. The combination rotates around the rotation axis with angular speed ω = 0.33 rad/s. Measured about O, what is the combination's (a) rotational inertia and (b) kinetic energy?

Consider two particles of mass m connected by a spring with rest length L with potential...

Consider two particles of mass m connected by a spring with rest length L with potential energy given by V(x1, x2) = ½ k (x1 – x2 – L)2. Show that the total wavefunction for this system is the product of two terms, one term is the solution for free particle motion of the center of mass for a particle with the total mass and the other term is simple harmonic (vibrational) motion of the relative displacement x1-x2 of the...

2. In the figure, four particles form a square with side a = 3 cm and...

2. In the figure, four particles form a square with side a = 3 cm and have charges q1 = +5 nC, q2 = - 10 nC, q3 = + 10 nC and q4 = - 5 nC. (InC = 10 ° C) Determine the magnitude and direction of the resultant force acting on q2. First you must make the corresponding force diagram.

The figure shows a ball with mass m = 0.450 kg attached to the end of...

The figure shows a ball with mass m = 0.450 kg attached to the end of a thin rod with length L = 0.415 m and negligible mass. The other end of the rod is pivoted so that the ball can move in a vertical circle. The rod is held horizontally as shown and then given enough of a downward push to cause the ball to swing down and around and just reach the vertically upward position, with zero speed...