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Conservation of Momentum

Conservation of Momentum. Momentum cannot be created or destroyed, only transferred If momentum is CONSTANT: The sum of the momentums of two bodies before they collide is equal to the sum of their momentums after they collide if there are no external forces exerted on them .

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Conservation of Momentum

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  1. Conservation of Momentum • Momentum cannot be created or destroyed, only transferred • If momentum is CONSTANT: The sum of the momentums of two bodies before they collide is equal to the sum of their momentums after they collide if there are no external forces exerted on them. Σpi = Σpf OR p1i + p2i = p1f + p2f OR m1v1i + m2v2i = m1v1f + m2v2f

  2. Collision Types Elastic vs. Inelastic • Inelastic Collisions : the bodies involved in the collision either begin as a single mass before the collision or become a single mass after the collision. Σpi = Σpf is still true, but the masses act as a single entity either before or after the collision.

  3. Inelastic Collisions pi= p1f + p2f OR p1i+ p2i = pf (m1 + m2) vi = m1v1f + m2v2f OR m1v1i+ m2v2i = (m1 + m2) vf

  4. Inelastic collisions • Include situations involving • Recoil • Explosions • coupling train cars and other real life situations where the masses either combine or separate due to a collision.

  5. Elastic Collisions • The bodies involved in the collision remain as separate, unconnected bodies both before and after the collision. Σpi = Σpf p1i+ p2i = p1f + p2f m1v1i + m2v2i = m1v1f + m2v2f

  6. Inelastic Collision Example Step 1. Draw a picture for BEFORE and AFTER the collision Step 2. Write out Table of Knowns for BEFORE and AFTER the collision Step 3. Determine whether the objects are together at the beginning (explosion) or at the end (collide and stick) Step 4. Set up equation and solve for unknown value.

  7. Example: Inelastic Collision • A mineral wagon is moving at a speed of 4 meters per second. It’s mass is 2000 kg. It collides with a car that is not moving whose mass is 4000 kg. The cars stick together. What is the velocity of the two cars after they collide?

  8. Write out TOK

  9. Calculate initial momentum of each

  10. Initial momentums of each How do you find the initial momentum of the SYSTEM ?

  11. Initial System Momentum

  12. Final Momentum • The two bodies collide and stick together (is this elastic or inelastic???? • The masses now act as a SINGLE mass (after the collision)

  13. Inelastic collisions • After the collision the two bodies become one. • The system now has a final momentum that is the result of a single mass and a single final velocity.

  14. Inelastic Collisions • m1+m2= mf = 2,000 kg + 4,000 kg = 6,000 kg • From the Law of conservation of momentum, the sum of the initial momentums equals the sum of the final momentums.

  15. CONSERVATION! • And The sum of the initial momentums is equal to 8,000 kg*m/s. SO the final momentum after the collision is equal to 8,000 kg*m/s INITIAL Momentum = FINAL Momentum

  16. What is the final Velocity? once coupled, the cars slow down but continue to move in the same direction.

  17. Elastic Collision • The mineral wagon above has a mass of 2,000 kg and is moving at 4.0 m/s toward the guard van on a level frictionless track. The guard van is moving at 1.0 m/s toward the mineral wagon and has a mass of 4,000 kg

  18. The train cars collide and do not lock together as a single mass. Find the velocity of the guard van if the mineral wagon is moving at 1.0 m/s to the left after the collision.

  19. What are the given values? Be sure to identify direction!!!

  20. Find initial momentum of each • Find initial momentum of the system (watch the signs!)

  21. The bodies then bounce off of each other and remain as separate bodies after the collision. • Even if they are separate, the total initial momentum of the system must be equal tothe total final momentum of the system. • What is the given velocity of the mineral wagon? In what direction is it going?

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