Calculating Mass in a Momentum Conservation Problem

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In a momentum conservation problem involving two runners colliding and coming to a complete stop, the key concept is that momentum is conserved. Since both runners have equal speeds but opposite directions, their initial momenta must cancel each other out for the total momentum to equal zero. This means that the masses of both runners must be equal for them to stop completely upon collision. Therefore, if one runner has a mass of 168 kg, the second runner must also have a mass of 168 kg. Momentum conservation confirms that equal masses and opposite velocities result in a complete stop after the collision.
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Homework Statement


A runner has a mass of 168 Kg and is traveling North at 5 meters per second. Another runner is traveling South at 5 meters per second. They collide and come to a complete stop. What is the mass of the second runner



Homework Equations



I do not have an equation.


The Attempt at a Solution



I have stayed up all night trying searching on the Web to find out anything.
 
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Hint: What's conserved in any collision?
 
Yes, it is momentum, I believe.

I read that if two objects crash into each other, then they bounce off each other - and that is not a complete stop.
However, it seems that the mass of both objects would need to be equal, as long as the velocity is equal.

Is that right?
 
I think that's right. If one was 200lbs then that one would blow through the other guy and not stop at the point of collision like i think the question is saying.
 
sean-820 said:
I think that's right. If one was 200lbs then that one would blow through the other guy and not stop at the point of collision like i think the question is saying.


Unless the other guy was also 200 lbs, right?
 
javas1 said:
Yes, it is momentum, I believe.
Right.

I read that if two objects crash into each other, then they bounce off each other - and that is not a complete stop.
They may or may not bounce off, but no matter what, momentum will be conserved. Here you are told that they come to a stop, so you know they don't bounce off.
However, it seems that the mass of both objects would need to be equal, as long as the velocity is equal.

Is that right?
Yes, exactly right. Since they come to a complete stop, you know that the total momentum is zero. That can only be true if their initial momenta are equal and opposite. Since they have the same speed, the only way they can have the same momentum is if they have the same mass.
 
Doc Al said:
Right.


They may or may not bounce off, but no matter what, momentum will be conserved. Here you are told that they come to a stop, so you know they don't bounce off.

Yes, exactly right. Since they come to a complete stop, you know that the total momentum is zero. That can only be true if their initial momenta are equal and opposite. Since they have the same speed, the only way they can have the same momentum is if they have the same mass.

That's perfect. Thanks!
 

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