Momentum collision between the ball and the floor

AI Thread Summary
In the discussion about the momentum collision between a ball and the floor, participants analyze the conservation of momentum during a horizontal throw. The vertical momentum of the ball decreases upon collision, while the behavior of horizontal momentum is debated. Some argue that horizontal momentum remains constant, while others suggest it may decrease due to changes in velocity. Key points include the understanding that momentum is a vector and that changes occur based on the forces acting during the collision. The conversation emphasizes the importance of distinguishing between horizontal and vertical components of motion in analyzing momentum changes.
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Homework Statement


I throw a ball horizontally

During the first collsion between the ball and the floor
Select one:
a. Both horizontal and vertical momentum of the ball are conserved
b. The horizontal momentum of the ball decreases and the vertical momentum decreases
c. The horizontal momentum of the ball decreases and the vertical momentum remains the same
d. The horizontal momentum of the ball remains the same and the vertical momentum increases
e. The horizontal momentum of the ball remains the same and the vertical momentum decreases


Homework Equations


p=mv


The Attempt at a Solution


I know that vertical momentum of a ball decreases but I'm not sure if the horizontal momentum decreases or remains constant.
 
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I know that vertical momentum of a ball decreases but I'm not sure if the horizontal momentum decreases or remains constant.
Please show reasoning.
What makes you think that vertical momentum decreases?
Why doesn't the same argument apply to the horizontal?

Presumably the ball does not gain or lose mass - so something else must change if the momentum is to change. What is it?
Dividing the motion of the ball into horizontal and vertical components - which direction has the change and when?
 
ok well think about it like this. if you drop a ball and it bounces back up its velocity decrease as it goes back up because its distance decreases as it bounces back up. and since momentum=velocity multiply by mass i think momentum decreases.

Now for the case of the horizontal momentum i just don't know. I think the horizontal distance should decrease thus decreasing horizontal velocity thus decreasing horizontal momentum but that part I am not to sure of because something in my head tells me the distance is content but something else in my head tells me the distances decreases like how a series would by a certain amount each time until it reaches a certain distance travelled. that's why i need help to understand the horizontal part.
 
Not bad ... but I don't know what you mean by "distance decreases". Vertical displacement decreases after the bounce sure, then it increases again as it changes direction and horizontal displacement surely increases (you've seen a ball bouncing along right?)

Recall that momentum is a vector.
Looking only at the vertical motion - assume no losses in the collision to make it simple - what is different about the vertical momentum before and after the collision?

Recall Newton's laws - under what circumstances does momentum change?
 
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