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If a collision occurs in an isolated system, then the total amount of momentum possessed by the two objects (when added together) is conserved. The amount before the collision is the same as the amount after the collision. (See Know the Law - The Law of Momentum Conservation section.)
In this question, the momentum is represented by a vector that has a magnitude and a direction. The direction is quite obvious: the arrows point rightward, so a + value can be assigned to each object's momentum (+ for rightward). As for magnitude, the on-screen ruler can be used to measure the length of the vector. The length represents the amount or value or magnitude. The total amount of momentum for objects A and B before the collision will be the same as the total amount after the collision. The momentum of object B must make up the difference between object A's momentum and the total amount. Use the grid marks on the vectors to help you pick the appropriate choice from among the possibilities.
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The Law of Momentum Conservation:
If a collision occurs between object 1 and object 2 in an isolated system, then the momentum change of object 1 is equal in magnitude and opposite in direction to the momentum change of object 2. In equation form
m1 • ∆v1 = - m2 • ∆v2
The total momentum of the system before the collision (p1 + p2) is the same as the total momentum of the system of two objects after the collision (p1' + p2'). That is
p1 + p2 = p1' + p2'
Total system momentum is said to be conserved for any collision occurring in an isolated system.
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The diagram shows momentum vectors for objects A and B before and after the collision. The length of the vector arrow represents the amount of momentum the object possesses. There are grid marks on the vector that can be used to measure its length. Once measured, you would be wise to write it down on some scratch paper. You'll need most your active mind for processing; don't waste space for memory purposes.
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Momentum as a Vector:
Momentum is a vector and it has a direction. The direction of an object's momentum is in the same direction that the object is moving.
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