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Momentum is conserved for all collisions as long as external forces don’t interfere. In the absence of outside influences, the total amount of momentum in a system is conserved. The momentum of the cue ball is transferred to other pool balls.
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Momentum is conserved for all collisions as long as external forces don’t interfere.
In the absence of outside influences, the total amount of momentum in a system is conserved. The momentum of the cue ball is transferred to other pool balls. The momentum of the pool ball (or balls) after the collision must be equal to the momentum of the cue ball before the collision p before = p after LAW OF CONSERVATION OF MOMENTUM
8.5 Law of Conservation and Collisions Motion of the other balls Whenever objects collide in the absence of external forces, the net momentum of the objects before the collision equals the net momentum of the objects after the collision. Motion of the cue ball
8.4Conservation of Momentum The momentum before firing is zero. After firing, the net momentum is still zero because the momentum of the cannon is equal and opposite to the momentum of the cannonball. Velocity cannon to left is negative Velocity of cannonball to right is positive (momentums cancel each other out!)
8.5 Two Types of Collisions • Elastic Collision: When objects collide without sticking together • Inelastic Collision: When objects collide and deform or stick together.
Changes in Velocity Conserve Momentum A. Elastic collisions with equal massed objects show no change in speed to conserve momentum • http://www.walter-fendt.de/ph14e/ncradle.htm • http://www.walter-fendt.de/ph14e/collision.htm B. Elastic collisions with inequally massed objects show changes in speed to conserve momentum • Larger mass collides with smaller mass—smaller mass object’s speed is greater than the larger mass object • Smaller mass object collides with larger mass object—larger mass object’s speed is much less than the smaller mass object • http://www.walter-fendt.de/ph14e/collision.htm C. Addition of mass in inelastic collisions causes the speed of the combined masses to decrease in order for momentum to be conserved
8.5 Examples of Elastic Collisions when the objects have identical masses • A moving ball strikes a ball at rest. Note: purple vector arrow represents velocity: speed and direction
8.5 Examples of Elastic Collisions when the objects have identical masses • A moving ball strikes a ball at rest. Momentum of the first ball was transferred to the second; velocity is identical
8.5 Examples of Elastic Collisions when the objects have identical masses b. Two moving balls collide head-on.
8.5 Examples of Elastic Collisions when the objects have identical masses b. Two moving balls collide head-on. The momentum of each ball was transferred to the other; each kept same speed in opposite direction
8.5 Examples of Elastic Collisions when the objects have identical masses c. Two balls moving in the same direction at different speeds collide.
8.5 Examples of Elastic Collisions when the objects have identical masses c. Two balls moving in the same direction at different speeds collide. The momentum of the first was transferred to the second and the momentum of the second was transferred to the first. Speeds to conserve momentum.
Start with less mass, end up with more mass Notice how speed changes to conserve momentum (more mass, less speed—inverse relationship!) 8.5 Inelastic Collisions
Example of an elastic collision with objects same speed but different masses What happens to the speed of the smaller car after the elastic collision with the more massive truck? Notice that the car has a positive velocity and the truck a negative velocity. What is the total momentum in this system?
Example of an elastic collision with objects same speed but different masses What happens to the speed of the smaller car after the elastic collision with the more massive truck? (the car’s speed increases to conserve momentum) Notice that the car has a positive velocity and the truck a negative velocity. What is the total momentum in this system? (-40,000 kg x m/s [20,000 - 60,000 kg x m/s)
Calculating conservation of momentum • Equation for elastic collisions m1v1 + m2v2 = m1v1 + m2v2 • Equation for inelastic collision m1v1 + m2v2 = (m1 + m2)v2 Before collision After collision Before collision After collision