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Chapter 8
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What is momentum? Momentum can be defined as inertia in motion. Another way to think of it is to consider how hard it is to stop something that is moving.
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What is the formula? The formula is Momentum = mass x velocity or M=mv. M = momentum m = mass v = velocity The units are kg-m/s
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Examples? An example of momentum is seen when we consider a bike and a freight train moving at the same speed. Which one is harder to stop? Why?
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What is impulse? A change in momentum is brought about by applying a force for a certain time interval. We call this an impulse, thus Impulse = Force x time.
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Impulse = change in momentum
Setting impulse equal to change in momentum gives us: Ft = mv A large momentum can be achieved by applying a large force, applying a force over a long time or both.
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How can collisions be safer?
To avoid being injured, we like to extend the time of contact when we encounter large momentums.
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Why airbags? Examples include using airbags, making cars with padded dashboards, bending our knees when we jump from large heights, etc.
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Bouncing Bouncing requires more impulse since an object must be quickly stopped and then it must be “thrown” back upward.
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Bouncing hurts more If an object falls and bounces off your head instead of breaking when it hits, it will hurt more.
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Total momentum doesn’t change
The momentum of all closed systems remains the same even though individual parts may undergo a change.
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Equal and opposite An example is a rifle bullet system. The bullet undergoes a large change in momentum, but so does the gun and it is equal and opposite. This is recoil
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Conservation of Momentum
The net momentum hasn’t changed and thus we say it has been conserved. One of the central laws in physics is the Law of conservation of momentum.
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Total momentum doesn’t change
In the absence of an external force the momentum of a system remains unchanged.
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Momentum is conserved When moving objects collide in the absence of external forces net momentum (before) = net momentum (after)
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Elastic Collisions When objects collide without being permanently deformed and without generating heat, the collision is said to be an elastic collision. Colliding objects bounce perfectly in elastic collisions.
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Inelastic Collisions Whenever colliding objects become tangled or couple together, they are said to undergo an inelastic collision.
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Types of collisions Most collisions in the everyday world are inelastic. Even when billiard balls collide on a pool table, they don’t bounce off with the same impact as they had before impact.
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But they do slow down. Why?
Heat and sound are generated when the billiard balls collide and “steal” some of the momentum, thus they eventually slow down.
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Even fireworks? Yes even fireworks
Even the fragments that are produced by a firecracker follow the rules of vector addition. The vector sum after explosion equals that of before explosion.
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