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Chapter 9

Chapter 9. Linear Momentum and Collisions (Cont.). Outline. Conservation of linear momentum Collisions Elastic collisions (1D) Inelastic collisions (1D) Elastic collisions in 2D Examples. Conservation of Linear Momentum.

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Chapter 9

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  1. Chapter 9 Linear Momentum and Collisions (Cont.) Dr. Jie Zou PHY 1151G Department of Physics

  2. Outline • Conservation of linear momentum • Collisions • Elastic collisions (1D) • Inelastic collisions (1D) • Elastic collisions in 2D • Examples Dr. Jie Zou PHY 1151G Department of Physics

  3. Conservation of Linear Momentum • Conservation of momentum for a system of objects: If the net external force acting on a system is zero, its net (total) momentum is conserved. That is, • It is important to note that this statement applies only to the net momentum of a system, not to the momentum of each individual object. • Internal and external forces: • Internal forces: forces acting between objects within the system. • External forces: forces applied from outside the system. Dr. Jie Zou PHY 1151G Department of Physics

  4. Example 1 • Two groups of canoeists meet in the middle of a lake. After a brief visit, a person in canoe 1 pushes on canoe 2 with a force of 46 N to separate the canoes. If the mass of canoe 1 and its occupants is 130 kg, and the mass of canoe 2 and its occupants is 250 kg, find the momentum of each canoe after 1.20 s of pushing (neglect water resistance). Dr. Jie Zou PHY 1151G Department of Physics

  5. Example 2 • When a bullet is fired from a rifle, the forces present in the horizontal direction are internal forces. • The total momentum of the rifle-bullet system in the horizontal direction is conserved. • The momentum of the system of the rifle and the bullet before firing is zero. After firing, the net momentum of the system is still zero. Dr. Jie Zou PHY 1151G Department of Physics

  6. Collisions • Collisions: By a collision we mean a situation in which two objects strike one another, and in which the net external force is either zero or negligibly small. • During a collision, the total momentum of a system is conserved. • The system’s kinetic energy is not necessarily conserved. Dr. Jie Zou PHY 1151G Department of Physics

  7. Inelastic and Elastic Collisions • Elastic collisions: after a collision, the final kinetic energy of the system is equal to the initial kinetic energy, Kf = Ki. • Inelastic collisions: collisions in which the kinetic energy is not conserved, Kf Ki. • Completely inelastic collisions: When objects stick together after colliding, the collision is completely inelastic. Dr. Jie Zou PHY 1151G Department of Physics

  8. Example: Completely Inelastic Collisions • Example (Ballistic pendulum): In a ballistic pendulum, an object of mass m is fired with an initial speed v0 at the bob of a pendulum. The bob has a mass M, and it suspended by a rod of negligible mass. After the collision, the object and the bob stick together and swing through an arc, eventually gaining a height h. Find the height h in terms of m, M, v0 and g. Dr. Jie Zou PHY 1151G Department of Physics

  9. Example: Elastic Collisions • Consider a head-on collisions of two carts on an air track. The carts are provided with bumpers that give an elastic bounce when the carts collide. Let’s suppose that initially cart 1 is moving to the right with a speed v0 toward cart 2, which is at rest. If the masses of the carts are m1 and m2, respectively, what will be the speed of cart 1 and cart 2 after the collisions? Dr. Jie Zou PHY 1151G Department of Physics

  10. Results for Elastic Collisions • In the previous example, both momentum and kinetic energy of the system are conserved: • Momentum conservation: m1v0 = m1v1,f + m2v2, f • Kinetic energy conservation: (1/2)m1v02 = (1/2)m1v1,f2 + (1/2)m2v2,f2 • Algebra yields the following results: Dr. Jie Zou PHY 1151G Department of Physics

  11. Elastic collisions in 2D • An example: Consider the collision of two 7.00-kg curling stones. One stone is at rest initially, the other approaches with a speed v1,i = 1.50 m/s. The collision is not head-on, and after the collision, stone 1 moves with a speed of v1,f= 0.610 m/s in a direction 66.0 away from the initial line of motion. What is the speed and direction of stone 2? • Answer: v2,f = 1.37 m/s in a direction of 24.0 Dr. Jie Zou PHY 1151G Department of Physics

  12. Homework • See online homework assignment at www.masteringphysics.com • Hand-written homework assignment: • Chapter 9, Page 291, Problems: #33 Dr. Jie Zou PHY 1151G Department of Physics

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