Three particles are placed in the xy plane. A m1 = 65 g particle is located...

Three particles are fixed in positions on the xy plane. Particle A, with a mass of...

Three particles are fixed in positions on the xy plane. Particle A, with a mass of 6.00 g, is located at the origin. Particle B, with a mass of 12.0 g, is located in the second quadrant a distance 0.500 m from the origin at an angle of 30◦ from the x axis. Particle C has a mass of 8.00 g. The net gravitational force acting on particle A due to particles B and C is 2.77 × 10−14 N...

Three particles have the following masses and center of mass coordinates: m1 = 2.50 kg, (0.150...

Three particles have the following masses and center of mass coordinates: m1 = 2.50 kg, (0.150 m, 0.420 m), m2 = 1.50 kg, (0.120 m, -0.350 m), and m3 = 2.00 kg, (-0.410 m, 0.520 m). The coordinate of the center of mass of the particle system is: a. (0.04 m, -0.261 m) b. (0.04 m, -0.261 m) c. (- 0.04 m, -0.261 m) d. (- 0.04 m, 0.261 m)

Three point mass particles are located in a plane: 4.27 kg located at the origin, 7.8995...

Three point mass particles are located in a plane: 4.27 kg located at the origin, 7.8995 kg at [(5.77 cm),(11.54 cm)], and 2.23321 kg at [(12.117 cm),(0 cm)]. How far is the center of mass of the three particles from the origin? Answer in units of cm.

Three uniform spheres are placed in the xy plane as follows: The center of mass of...

Three uniform spheres are placed in the xy plane as follows: The center of mass of an 8.50-kg sphere is located at (2.00, 2.00) m, the center of mass of a 5.00-kg sphere is located at (0, 5.20) m, and the center of mass of a 2.00-kg sphere is located at (3.10, 0) m. Where should a 6.00-kg sphere be placed if the center of mass of the four-sphere system is to be located at the origin? x = m...

A system consists of two particles. The first particle has mass m1 = 2.0 kg and...

A system consists of two particles. The first particle has mass m1 = 2.0 kg and a velocity of (-5.0 i+1.0j) m/s, and the second particle has mass m2 = 1.00 kg and a velocity of (1.0i - 5.0j)    m/s. A:) What is the velocity of the center of mass of this system?   B:) what is the total momentum of this system?

Consider a system of two particles in the xy plane: m1 = 1.95 kg is at...

Consider a system of two particles in the xy plane: m1 = 1.95 kg is at the location r with arrow1 = (1.00î + 2.00?) m and has a velocity of (3.00î + 0.500?) m/s; m2 = 3.15 kg is at r with arrow2 = (?4.00î ? 3.00?) m and has velocity (3.00î ? 2.00?) m/s. (a) Plot these particles on a grid or graph paper. Draw their position vectors and show their velocities. (Include the center of mass of...

A particle with mass m1=2 kg is located at x=0 while a particle with mass m2=128...

A particle with mass m1=2 kg is located at x=0 while a particle with mass m2=128 kg is located at x=200 m along the x axis. Somewhere between them is a point where the gravitational force of m1 acting on a mass m0=1 kg is canceled by the gravitational force of m2 acting on that mass. (a) What is the coordinate x of this point? _______ (b) Find the ratio (in terms of integer numbers) of the magnitude of the...

Consider a system consisting of three particles: m1 = 4 kg, 1 = < 11, -6,...

Consider a system consisting of three particles: m1 = 4 kg, 1 = < 11, -6, 12 > m/s m2 = 2 kg, 2 = < -13, 7, -4 > m/s m3 = 3 kg, 3 = < -29, 34, 19 > m/s (a) What is the total momentum of this system? tot = ______ kg · m/s (b) What is the velocity of the center of mass of this system? cm = ______ m/s (c) What is the total...

Consider a system consisting of three masses on the x axis. Mass m1 = 1.50 kg...

Consider a system consisting of three masses on the x axis. Mass m1 = 1.50 kg is at x1 = 1.50 m ; mass m2 = 2.00 kg is at x2 = 2.30 m ; and mass m3 = 3.20 kg is at x3 = 2.70 m . What is the total gravitational potential energy of this system?

Three identical very dense masses of 6300 kg each are placed on the x axis. One...

Three identical very dense masses of 6300 kg each are placed on the x axis. One mass is at x1 = -210 cm, one is at the origin, and one is at x2 = 320 cm. (the gravitational constant G = 6.67×10−11N⋅m2/kg2 ) a) calculate the gravitational attraction of the object located at x1 on the object sitting at the origin. (magnitude and direction. Take the direction from the origin to the right as POSITIVE) b) Calculate the gravitational attraction...