The ball will bounce back to a height less than its original drop height of 50 cm due to energy loss during each bounce. The exact height the ball will bounce to depends on the ball's elasticity and the surface it bounces on.
The higher the ball is dropped from, the higher it will bounce due to increased potential energy converting to kinetic energy upon impact with the ground. However, it will not bounce at the same height it was dropped from due to energy losses from factors such as air resistance and deformation upon impact.
The higher the ball is dropped from, the higher it will bounce back. This is due to potential energy converting to kinetic energy upon impact with the ground, propelling the ball higher when dropped from greater heights. Ultimately, the bounce height depends on factors like gravity, air resistance, and the material of the ball.
After each bounce, the ball reaches half of the height from which it was dropped. Since the ball was initially dropped from 10 feet, on the first bounce it will reach 5 feet, on the second bounce it will reach 2.5 feet, on the third bounce it will reach 1.25 feet, and on the fourth bounce it will reach 0.625 feet.
When a ball is bounced, some of the initial energy is used to deform the ball upon impact with the ground. This deformation causes some of the energy to be converted into other forms, such as heat and sound, resulting in a lower bounce height compared to the height it was dropped from.
On the third bounce, the ball will bounce to a height of 35% of the previous bounce height (35% of 35% of 125m). Therefore, the ball will bounce to a height of (35/100) x (35/100) x 125m = 15.63m on the third bounce.
The higher the ball is dropped from, the higher it will bounce due to increased potential energy converting to kinetic energy upon impact with the ground. However, it will not bounce at the same height it was dropped from due to energy losses from factors such as air resistance and deformation upon impact.
The higher the ball is dropped from, the higher it will bounce back. This is due to potential energy converting to kinetic energy upon impact with the ground, propelling the ball higher when dropped from greater heights. Ultimately, the bounce height depends on factors like gravity, air resistance, and the material of the ball.
After each bounce, the ball reaches half of the height from which it was dropped. Since the ball was initially dropped from 10 feet, on the first bounce it will reach 5 feet, on the second bounce it will reach 2.5 feet, on the third bounce it will reach 1.25 feet, and on the fourth bounce it will reach 0.625 feet.
Who has dropped the ball? The referee?! If the referee drops the ball after he interrupted the game the ball is in play when the ball touches the ground. It isn't allowed to score a goal directly from a dropped ball, two players have to touch the ball before the goal counts.
When a ball is bounced, some of the initial energy is used to deform the ball upon impact with the ground. This deformation causes some of the energy to be converted into other forms, such as heat and sound, resulting in a lower bounce height compared to the height it was dropped from.
On the third bounce, the ball will bounce to a height of 35% of the previous bounce height (35% of 35% of 125m). Therefore, the ball will bounce to a height of (35/100) x (35/100) x 125m = 15.63m on the third bounce.
Increasing the height from which a ball is dropped will result in a higher bounce because the ball gains more potential energy as it falls from a greater height. This increase in potential energy translates to a greater kinetic energy upon impact with the ground, leading to a higher bounce.
Gravity affects the bounce of a basketball by pulling it back towards the ground as soon as it leaves the surface. When the basketball is dropped or thrown, it accelerates towards the ground due to gravity, causing it to bounce off the surface. The height of the bounce is determined by the force with which the basketball hits the ground and the elasticity of the ball.
When a tennis ball is dropped to the ground, it loses some of its energy upon impact, which is converted into other forms of energy such as heat and sound. This loss of energy causes the ball to bounce back to a lower height than its original position. Additionally, factors like air resistance and the elasticity of the ball also contribute to the decrease in bounce height.
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Still accelerating til it hits earth. ====================================== The height from which she dropped the ball is irrelevant. In any case, the ball was most likely moving at the greatest speed just as it hit the ground. The answer to the question is: zero.
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