Momentum

42 T-Unit Transport T-Unit Transport T-Unit Transport T-Unit Transport T-Unit Transport Physics Lines Momentum Inertia in Motion Presentation designed by DBHS physics department

Mass Velocity Momentum Definition of Momentum • Momentum is the product of mass and velocity. Presentation designed by DBHS physics department

4 x 4 Momentum Depends on Velocity • An object must be moving in order to have momentum. • Consider the truck at rest. • Consider the skate boarder. He has momentum. Presentation designed by DBHS physics department

4 x 4 Momentum Depends on Mass • Larger objects traveling at the same velocity as smaller objects will have greater momentum. Presentation designed by DBHS physics department

STOP 235 The Nature of Momentum • Momentum is a vector quantity. • It has magnitude (how big). • It has direction (right(+) or left(-)). • Direction is denoted by sign (+ or -). Positive Momentum Negative Momentum Presentation designed by DBHS physics department

Calculating Momentum • As mentioned before, momentum is the product of mass and velocity. Presentation designed by DBHS physics department

Practice Problem 1 • Calculate the momentum of the tank if its velocity is to the right. Presentation designed by DBHS physics department

Practice Problem 2 • Calculate the momentum of the tank if its velocity is to the left. Presentation designed by DBHS physics department

F = ma Rails Collisions • The collisions that we will study will involve two objects. • Each object possesses its own momentum. • Collisions are broken down into two categories: • Elastic (Objects Separate) • Inelastic (Objects Stick Together) Presentation designed by DBHS physics department

Momentum – Elastic Collisions • Elastic Collision – a collision in which the colliding bodies do not stick together. • The equation used for elastic collisions is as follows. Presentation designed by DBHS physics department

Physics Rules, Inc. Momentum – Inelastic Collisions • Inelastic Collision – a collision in which the colliding bodies stick together. • The equation used for elastic collisions is as follows. Presentation designed by DBHS physics department

DB Elastic Collisions • The total momentum of the system remains constant. • Elastic collision, objects move off with separate velocities. • This means that they can bounce. • Or they can be projected from rest (like a cannon). Presentation designed by DBHS physics department

Laser Momentum • Identify the number and types of collisions in the animation below. Presentation designed by DBHS physics department

The Bolt Momentum • Identify the number and types of collisions in the animation below. Presentation designed by DBHS physics department

The Law of Conservation of Momentum In a closed and isolated system, the total momentum of all the objects present remains constant. Presentation designed by DBHS physics department

Elastic Collision Equation Before After Subsripts: I: Initial (Before) F: Final (After) Initial Momentum Object 1 Initial Momentum Object 2 Final Momentum Object 1 Final Momentum Object 2 Presentation designed by DBHS physics department

2.0kg 1.0kg 2.0kg 1.0kg v2F = ? v1F = -6.0m/s v1I = 8.0m/s v2I = -3.0m/s After Before Sample Problem (Elastic) What is the initial momentum of the blue ball? What is the final momentum of the red ball? What is the final velocity of the red ball? What is the final momentum of the blue ball? What is the initial momentum of the red ball? Presentation designed by DBHS physics department

Air Track 0.3kg 0.8kg Practice Problem 3 (Elastic) • Two air track cars collide and bounce. • The red car is initially traveling at a velocity of 0.50m/s to the right while the yellow car is traveling at a velocity of 1.5m/s to the left. • After the collision the red car is moving 2.0m/s to the left with the yellow car following, but not touching. What is the final momentum of the red car? What is the final momentum of the yellow car? What is the initial momentum of the red car? What is the initial momentum of the yellow car? Collide What is the final velocity of the yellow car? mred = 0.3kg myellow = 0.8kg Presentation designed by DBHS physics department

Sample Problem (Elastic) • This problem will demonstrate the “cannon type” scenario. • The cannon and cannonball are initially at rest. • The ball then is fired at a velocity of 150m/s. What is the initial momentum of the cannon? What is the velocity of the cannon immediately after firing? What is the initial momentum of the cannonball? What is the final momentum of the cannonball? What is the momentum of the cannon immediately after firing? Fire! mcannon = 300kg mball = 10kg Presentation designed by DBHS physics department

Before After Practice Problem 4 (Elastic) • A gun (m = 1.5kg), initially at rest, is fired sending its bullet (m = 0.1kg) at a velocity of . What is the initial momentum of the gun and bullet? What is the total momentum of the system before firing? What is the total momentum of the system after firing? What is the final momentum of the bullet? What is the final momentum of the gun? What is the final velocity of the gun? Presentation designed by DBHS physics department

S N N S Inelastic Collisions • The Law of Conservation of Momentum: that the total momentum of the system remains constant, no matter what the collision. • In an inelastic collision, objects stick together. • This means that they have the same final velocity (vF). Collide v2 v1 vF vF Presentation designed by DBHS physics department

Inelastic Collision Equation • The inelastic collision equation takes into account the momentum of each object before and after the collision. • Because the objects are combined after the collision, and they have the same final velocity (vF). Presentation designed by DBHS physics department

Inelastic Collision Equation Before After Initial MomentumObject 1 Initial MomentumObject 2 Final Combined Momentum Objects 1 & 2 Presentation designed by DBHS physics department

Pysix Lines P P L L Pysix Lines Sample Problem (Inelastic) The big rig backs up with an initial velocity of 2.0m/s and collides with the trailer, which is initially at rest. What is the initial momentum of the trailer? What is the initial momentum of the truck? What is the final velocity of the truck and trailer combo? What is the combined mass of the truck and trailer? mTruck = 2000.0kg mTrailer = 3000.0kg After Before Presentation designed by DBHS physics department

H C C H N S S N S N N S Practice Problem 5 (Inelastic) • Happy Penguin (m = 7.0kg) slides across the ice on a magnet with a velocity of 3.0m/s. • Cool Penguin (m = 8.0kg) comes up from behind with a velocity of 5.0m/s. He, also having a magnet, will collide and stick. What is the final velocity of the penguin pair? What is the combined mass of the two penguins? What is the initial momentum of Cool Penguin? What is the final momentum of Happy Penguin? Collide ICE Presentation designed by DBHS physics department

Momentum • While climbing a cliff, a super model (m = 51.0 kg) slips and falls. • She falls for 2s before she is rescued by Super Doctor Physics (m = 63.0 kg, v = 27.85 m/s). • What was their velocity immediately after the collision? Presentation designed by DBHS physics department

Impulse (Dmv) • When objects collide, their velocities change. This means that their individual momentums will also change. • Impulse simply defines the change in momentum for an individual object (denoted by Dmv). Presentation designed by DBHS physics department

Impulse (Dmv) • There are two ways to calculate impulse: • You can subtract initial momentum from final momentum. • Or you can take the product of force and time. • The units for impulse are in Ns, which is equal to kgm/s Presentation designed by DBHS physics department

Sample Problem 1 (Impulse) • A golf ball, initially at rest, is struck by a golf club. • The golf ball (m = 0.1kg) rolls away with a velocity of 35m/s. What is the initial momentum of the ball? What is the final momentum of the ball? What is the impulse on the ball? Swing Presentation designed by DBHS physics department

Practice Problem 6 (Impulse) • A soccer ball (m = 0.4kg) approaches a player with a velocity of 13m/s (left). The player kicks the ball giving it a new velocity of 20m/s (right). What is the initial momentum of the soccer ball? What is the final momentum of the soccer ball? What is the impulse felt by the soccer ball? Kick Presentation designed by DBHS physics department

Sample Problem 2 (Impulse) • A baseball is struck by a bat with a force of 3000N for a duration of 0.05s. What is the change in momentum of the baseball? Hit or Presentation designed by DBHS physics department

Practice Problem 7 (Impulse) • A tennis ball is struck with a force of 400N for a time of 0.15s. What is the impulse felt by the tennis ball? Hit Presentation designed by DBHS physics department

Physics Express Summary • All problems surrounding momentum are based on the following principles: • Momentum depends on both mass and velocity. • Momentum is conserved, regardless of collision. • Collision type determines the equation used. • Impulse is simply change in momentum. Trains are stupid cuz they can’t do Physics! Presentation designed by DBHS physics department

Momentum

Momentum

Presentation Transcript

Momentum and changing momentum

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momentum

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Momentum and Momentum Conservation

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Momentum and Momentum Conservation

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MOMENTUM!

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Momentum!!!

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