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Conservation of momentum Investigation 11A: Conservation of momentum The law of conservation of momentum is a powerful generalization of Newton’s third law. For an isolated system, the total momentum of all the objects inside is constant. In this investigation, you will explore the conservation of momentum for two carts that are subject to no outside net force. The only catch is that the carts have a compressed spring inserted between them! Is momentum conserved for this system? Part 1: Conservation of momentum for spring-loaded carts 1. Select a mass for each cart. 2. Press [Run] to start the simulation. 3. Run the simulation for different combinations of masses for the two carts. Use your data table to record the mass and velocity for each combination. Questions a. Describe the velocities when the masses of the two carts are equal. b. Describe the velocities when the red cart has more mass than the blue cart. c. Describe the velocities when the blue cart has more mass than the red cart. 1 Table 1: Tabulate the velocities and calculate the momentum and kinetic energy of each cart for masses 5, 10, and 15 kg. Use the results in this table to answer the questions below. m1 v1 p1 Ek1 m2 v2 p2 Ek2 (kg) (m/s) (kg m/s) (J) (kg) (m/s) (kg m/s) (J) 5 5 10 5 15 5 5 10 10 10 15 10 5 15 10 15 15 15 d. Evaluate the data in your table. What quantity can you construct or calculate that is equal and opposite for the two carts after they are released? How is this the most logical conclusion to draw from your data? e. Why are ballistic carts useful in studying the conservation of momentum? Explain. f. What similarities are there in the velocities, momenta, and kinetic energies when the masses of both carts are equal? g. What is the difference in velocity when one mass is twice that of the other? When one mass is three times the other? 2 h. What is the difference in momentum when the masses are equal? When one cart has twice the mass of the other? When one cart has three times the mass of the other? Applying new knowledge 1. Define the law of conservation of momentum in one sentence. 2. Explain the connection between Newton’s third law of action/reaction, and the law of conservation of momentum for a closed, isolated system. 3. An astronaut with a mass of 100 kg throws a wrench with a mass of 2 kg at a velocity of 5 m/s. What is the resulting recoil velocity of the astronaut if both the wrench and astronaut were initially at rest together? 4. Write a multiple-choice question that requires the reader to apply conservation of momentum to a system of two objects. 3