What Causes Increased Horizontal Velocity After a Perfect Bounce?

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In a physics lab on rebound dynamics, it was noted that a perfect bounce can result in a horizontal velocity greater than the initial velocity due to the interaction with the surface. The ball's spin and friction during the collision contribute to this increase in forward momentum. While a perfectly elastic bounce should theoretically maintain the same speed, the presence of friction allows rotational velocity to convert into linear motion, enhancing speed. In cases of less than perfect bounces, the increase in linear speed from rotation may not compensate for any loss due to inelasticity. Understanding these dynamics is crucial for analyzing the behavior of bouncing objects.
sonya
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ok my physics class jst did a lab on studying rebound and last question in the report says:

An extrapolation of the data to a perfect bounce (ie. one that reaches to the height of the launch point) results in a bounce distance that is more than twice the horizontal distance of the point of impact from the launch point. Since the fall of the ball from the launch point is only half the trajectory of such a perfect bounce, this means that the horizontal velocity after the bounce is greater than it was before the bounce.

What is a possible reason for this??

i am stuck on this last question...ne help would be much appreciated!
 
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The ball is spinning. Friction with the floor during the collision gives it a forward momentum.
 
but wouldn't that happen with ne bounce then...not jst the "perfect" one?
 
With a "perfect bounce" (perfectly elastic), ignoring friction, the ball will come back up to the same height with the same speed. With less than a perfect bounce, it would have lower speed.

With friction, the rotational velocity can be converted to linear motion. If the bounce is "perfect", that can result in greater linear speed that initially. If the bounce is not perfectly elastic, that might not happen. The increase in linear speed due to the rotation might not make up for the reduction due to the inelastic bounce.
 
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