The higher the height the ball is dropped from, the higher the height it will bounce to.
After the 5th bounce, it peaks at 0.168 meter. Nice problem.
Gravity pulls it back to earth. The gravitational pull isn't strong enough to keep the ball from bouncing but it can limit the height.
1 metre
Since no energy was lost, we can conclude that it was an elastic collision.
When the ball is at a low temperature, the molecules are not flexible and bounce only to a small height. On the other hand, if the ball is warm or at a higher temperature, it will bounce longer heights.
the height from which it was dropped
After the 5th bounce, it peaks at 0.168 meter. Nice problem.
89
Gravity pulls it back to earth. The gravitational pull isn't strong enough to keep the ball from bouncing but it can limit the height.
75%
1 metre
Since no energy was lost, we can conclude that it was an elastic collision.
When the ball is at a low temperature, the molecules are not flexible and bounce only to a small height. On the other hand, if the ball is warm or at a higher temperature, it will bounce longer heights.
Yes, assuming the ball has elasticity and you haven't exceeded the height where the ball, when dropped, reaches terminal velocity.
The factors that affect the bounce of a dropped ball include...... the height from which it is dropped; the force applied to it, if any, when dropped; the acceleration of gravity, which is different depending upon what planet you're on ; the elasticity of the ball; the density of the atmosphere, which affects "air resistance"; and the rigidity and elasticity of the surface on which the ball bounces.
Yes. Under ideal circumstances - no air resistance, elastic collision (i.e., perfect bounce), the ball should bounce back to the same height from which it was dropped, due to conservation of energy. In practice, some energy is always lost, both due to air resistance and to a non-perfect bounce.
I think it is like 6 or something like that.