Let's consider a rigid system with three particles. Masses of these particles m1 = 3 kgs,...

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?

(a) A light, rigid rod of length ℓ = 1.00 m joins two particles, with masses...

(a) A light, rigid rod of length ℓ = 1.00 m joins two particles, with masses m1 = 4.00 kg and m2 = 3.00 kg, at its ends. The combination rotates in the xy-plane about a pivot through the center of the rod (see figure below). Determine the angular momentum of the system about the origin when the speed of each particle is 4.80 m/s. (Enter the magnitude to at least two decimal places in kg · m2/s.) Two masses...

Mass and coordinates of three particles are given: Mass, M1 = 3 kg, Coordinates: X =...

Mass and coordinates of three particles are given: Mass, M1 = 3 kg, Coordinates: X = 1, Y = 1 Mass, M2 = 2 kg, Coordinates: X = -1, Y = -1 Mass, M3 = 1 kg, Coordinates: X = 0, Y = 1 (a) Find the Moment of Inertia of the three particles about the X-axis (axis of rotation) (b) Find the Center of Mass of the three objects

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)

Consider three particles with masses m1=m , m= 2m and m3= 3m connected by springs with...

Consider three particles with masses m1=m , m= 2m and m3= 3m connected by springs with force constants k1= 2k k2= 3k and k3= 6k These particles can move on a circle of radius R (no gravity forces here, restoring forces come from springs only!), see Fig. 2 for the illustration. Find eigenfrequencies ω of small oscillations in this system.

A rod of length l=1.1m and mass M= 5.5kg joins two particles with masses m1 =4.8kg...

A rod of length l=1.1m and mass M= 5.5kg joins two particles with masses m1 =4.8kg and m2 = 2.8kg, at its ends. The combination rotates in the xy-plane about a pivot through the center of the rod with the linear speed of the masses of v= 3.5 m/s. (Moment of inertia of a uniform rod rotating about its center of mass I= 1 12 M l2 ) angularmomentum a) Calculate the total moment of inertia of the system I...

A rod of length l=2.2m and mass M= 9.7kg joins two particles with masses m1 =12.9kg...

A rod of length l=2.2m and mass M= 9.7kg joins two particles with masses m1 =12.9kg and m2 = 5.0kg, at its ends. The combination rotates in the xy-plane about a pivot through the center of the rod with the linear speed of the masses of v= 12.9 m/s. (Moment of inertia of a uniform rod rotating about its center of mass I= 1 12 M l2 ) a) Calculate the total moment of inertia of the system I =...

A rod of length l=0.8m and mass M= 3.7kg joins two particles with masses m1 =4.5kg...

A rod of length l=0.8m and mass M= 3.7kg joins two particles with masses m1 =4.5kg and m2 = 2.8kg, at its ends. The combination rotates in the xy-plane about a pivot through the center of the rod with the linear speed of the masses of v= 3.5 m/s. (Moment of inertia of a uniform rod rotating about its center of mass I= 1 12 M l2 a) Calculate the total moment of inertia of the system b) What is...

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...

For a system composed of two non-interacting, distinguishable particles of mass m1 and m2 (<<m1) in...

For a system composed of two non-interacting, distinguishable particles of mass m1 and m2 (<<m1) in an 1-D infinite potential well (V=0 for 0<x<a, V=infinite otherwise), 1)Write down the hamiltonian of the system. Obtain the eigenenergies and eigenfunctions of the hamiltonian by solving the Hamiltonian eigenequation? 2) For the second-lowest eigenenergy state, what is the probability to find particle 2 between 0< x < a/4