Presentation is loading. Please wait.

Presentation is loading. Please wait.

Physics 11 Mr. Jean May 7th, 2013.

Similar presentations


Presentation on theme: "Physics 11 Mr. Jean May 7th, 2013."— Presentation transcript:

1 Physics 11 Mr. Jean May 7th, 2013

2 The plan: Video clip of the day Conservation of Momentum Application
1-D collisions

3 Conservation of Momentum:
One of the most powerful laws in physics is the law of momentum conservation. The law of momentum conservation can be stated as follows. For a collision occurring between object 1 and object 2 in an isolated system, the total momentum of the two objects before the collision is equal to the total momentum of the two objects after the collision. That is, the momentum lost by object 1 is equal to the momentum gained by object 2.

4 The above equation is one statement of the law of momentum conservation. In a collision, the momentum change of object 1 is equal to and opposite of the momentum change of object 2. That is, the momentum lost by object 1 is equal to the momentum gained by object 2. In most collisions between two objects, one object slows down and loses momentum while the other object speeds up and gains momentum. If object 1 loses 75 units of momentum, then object 2 gains 75 units of momentum. Yet, the total momentum of the two objects (object 1 plus object 2) is the same before the collision as it is after the collision. The total momentum of the system (the collection of two objects) is conserved

5 Law of Conservation of Momentum:

6 Collisions commonly occur in contact sports (such as football) and racket and bat sports (such as baseball, golf, tennis, etc.). Consider a collision in football between a fullback and a linebacker during a goal-line stand. The fullback plunges across the goal line and collides in midair with the linebacker. The linebacker and fullback hold each other and travel together after the collision. The fullback possesses a momentum of 100 kg*m/s, East before the collision and the linebacker possesses a momentum of 120 kg*m/s, West before the collision. The total momentum of the system before the collision is 20 kg*m/s, West (review the section on adding vectors if necessary). Therefore, the total momentum of the system after the collision must also be 20 kg*m/s, West. The fullback and the linebacker move together as a single unit after the collision with a combined momentum of 20 kg*m/s. Momentum is conserved in the collision.

7 Now suppose that a medicine ball is thrown to a clown who is at rest upon the ice; the clown catches the medicine ball and glides together with the ball across the ice. The momentum of the medicine ball is 80 kg*m/s before the collision. The momentum of the clown is 0 m/s before the collision. The total momentum of the system before the collision is 80 kg*m/s. Therefore, the total momentum of the system after the collision must also be 80 kg*m/s. The clown and the medicine ball move together as a single unit after the collision with a combined momentum of 80 kg*m/s. Momentum is conserved in the collision.

8 One Dimensional Collisions:
In a one dimensional collision both the magnitude and the direction of the momentum must be conserved. For complex momentum situations break all momentums into components and then sum the components. This too will conserve momentum.

9 Collisions: Collisions can be classified according to the energy interaction that takes place: Elastic collision  kinetic energy is conserved Inelastic collision  kinetic energy is not conserved Perfectly inelastic collision  objects stick together and have the same velocity.

10 Example: An old lady driving a 2.5x103 kg H2 Hummer drives into the back of your 1.0x103 kg Mazda RX8. The two cars stick together. What is their velocity after the collision if the old lady was originally travelling at 8.0m/s?

11

12 Example #2: The cue ball collides with the ‘8’ ball. The cue ball has twice as much mass as the ‘8’ ball. The objects do not stay attached. What is the velocity of the ‘8’ ball? Is this collision realistic? (Why or why not?)

13

14 Cannon Recoil: A 2000kg cannon contains a 100kg armour piercing shell. The cannon fires the projectile horizontally with a velocity of 1000m/s. What is the velocity of the cannon after the shot?

15

16 “Loose Cannon”: An unpredictable person or thing, liable to cause damage if not kept in check by others. Also a place to eat in Halifax on Argyle Street.

17 Rifle Recoil: .50 Cal Rifle “Surprising Recoil”

18 Questions to work on: Conservation of Energy: P.287 P.296 P.298 P.308

19 Questions to work on: Conservation of Momentum: P.315 P.317 P.298
25 & 26 P.317 27 to 29 P.298 15 to 16 P.332 38 to 50


Download ppt "Physics 11 Mr. Jean May 7th, 2013."

Similar presentations


Ads by Google