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Do now!

Do now!. In pairs can you discuss what we learnt about momentum at the end of last lesson? You have 2 minutes. Last lesson. Momentum. http://www.youtube.com/watch?v=qGacupc5-tE&feature=related. http://www.youtube.com/watch?v=PggkC3iX578. YouTube - Spectacular 100mph Train Crash Test.

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Do now!

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  1. Do now! In pairs can you discuss what we learnt about momentum at the end of last lesson? You have 2 minutes.

  2. Last lesson Momentum http://www.youtube.com/watch?v=qGacupc5-tE&feature=related http://www.youtube.com/watch?v=PggkC3iX578 YouTube - Spectacular 100mph Train Crash Test

  3. Momentum • Momentum is a useful quantity to consider when thinking about "unstoppability". It is also useful when considering collisions and explosions. It is defined as Momentum (kg.m/s) = Mass (kg) x Velocity (m./s) p = mv

  4. An easy example • A lorry has a mass of 10 000 kg and a velocity of 3 m.s-1. What is its momentum? Momentum = Mass x velocity = 10 000 x 3 = 30 000 kg.m.s-1.

  5. The Law of conservation of momentum “in an isolated system, momentum remains constant”.

  6. momentum before = momentum after • In other words, in a collision between two objects, momentum is conserved (total momentum stays the same). i.e. Total momentum before the collision = Total momentum after Momentum is not energy!

  7. A harder example! • A car of mass 1000 kg travelling at 5 m/s hits a stationary truck of mass 2000 kg. After the collision they stick together. What is their joint velocity after the collision?

  8. A harder example! Before 2000kg 1000kg 5 m/s Momentum before = 1000x5 + 2000x0 = 5000 kg.m/s Combined mass = 3000 kg After V m/s Momentum after = 3000v

  9. A harder example The law of conservation of momentum tells us that momentum before equals momentum after, so Momentum before = momentum after 5000 = 3000v V = 5000/3000 = 1.67 m/s

  10. Momentum is a vector • Momentum is a vector, so if velocities are in opposite directions we must take this into account in our calculations

  11. An even harder example! Snoopy (mass 10kg) running at 4.5 m/s jumps onto a skateboard of mass 4 kg travelling in the opposite direction at 7 m/s. What is the velocity of Snoopy and skateboard after Snoopy has jumped on? I love physics

  12. Because they are in opposite directions, we make one velocity negative An even harder example! 10kg -4.5 m/s 4kg 7 m/s Momentum before = 10 x -4.5 + 4 x 7 = -45 + 28 = -17 14kg v m/s Momentum after = 14v

  13. An even harder example! Momentum before = Momentum after -17 = 14v V = -17/14 = -1.21 m/s The negative sign tells us that the velocity is from left to right (we choose this as our “negative direction”)

  14. “Explosions” - recoil

  15. Let’s try some questions!

  16. Let’s follow Mr Porter

  17. Impulse Ft = mv – mu The quantity Ft is called the impulse, and of course mv – mu is the change in momentum (v = final velocity and u = initial velocity) Impulse = Change in momentum

  18. Impulse Ft = mv – mu F = Δp/Δt

  19. Units Impulse is measured in N.s (Ft) or kg.m.s-1 (mv – mu)

  20. 5 m/s Impulse -3 m/s Note; For a ball bouncing off a wall, don’t forget the initial and final velocity are in different directions, so you will have to make one of them negative. In this case mv – mu = -3m -5m = -8m

  21. Example • Szymon punches Eerik in the face. If Eerik’s head (mass 10 kg) was initially at rest and moves away from Szymon’s fist at 3 m/s, what impulse was delivered to Eerik’s head? If the fist was in contact with the face for 0.2 seconds, what was the force of the punch?

  22. Example • Szymon punches Eerik in the face. If Eerik’s head (mass 10 kg) was initially at rest and moves away from Szymon’s fist at 3 m/s, what impulse was delivered to Eerik’s head? If the fist was in contact with the face for 0.2 seconds, what was the force of the punch? • m = 10kg, t = 0.2, u = 0, v = 3

  23. Example • Szymon punches Eerik in the face. If Eerik’s head (mass 10 kg) was initially at rest and moves away from Szymon’s fist at 3 m/s, what impulse was delivered to Eerik’s head? If the fist was in contact with the face for 0.2 seconds, what was the force of the punch? • m = 10kg, t = 0.2, u = 0, v = 3 • Impulse = Ft = mv - mu

  24. Example Szymon punches Eerik in the face. If Eerik’s head (mass 10 kg) was initially at rest and moves away from Szymon’s fist at 3 m/s, what impulse was delivered to Eerik’s head? If the fist was in contact with the face for 0.2 seconds, what was the force of the punch? m = 10kg, t = 0.2, u = 0, v = 3 Impulse = Ft = mv – mu = 10x3 – 10x0 = 30 Ns

  25. Example Szymon punches Eerik in the face. If Eerik’s head (mass 10 kg) was initially at rest and moves away from Szymon’s fist at 3 m/s, what impulse was delivered to Eerik’s head? If the fist was in contact with the face for 0.2 seconds, what was the force of the punch? m = 10kg, t = 0.2, u = 0, v = 3 Impulse = Ft = mv – mu = 10x3 – 10x0 = 30 Ns Impulse = Ft = 30 Fx0.2 = 30 F = 30/0.2 = 150 N

  26. Another example • A tennis ball (0.3 kg) hits a racquet at 3 m/s and rebounds in the opposite direction at 6 m/s. What impulse is given to the ball?

  27. Another example • A tennis ball (0.3 kg) hits a racquet at 3 m/s and rebounds in the opposite direction at 6 m/s. What impulse is given to the ball? 3 m/s -6 m/s

  28. Another example • A tennis ball (0.3 kg) hits a racquet at 3 m/s and rebounds in the opposite direction at 6 m/s. What impulse is given to the ball? • Impulse = mv – mu = = 0.3x-6 – 0.3x3 = -2.7kg.m.s-1 3 m/s -6 m/s

  29. Now let’s try some fun questions! But first let’s watch this! http://www.youtube.com/watch?v=bKLrj3UFqQI

  30. TICKET TO EXIT

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