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∙ 11y agoWhen you drop a ball to the floor, the potential energy stored in the ball due to its height is converted to kinetic energy as it accelerates towards the ground. Upon impact with the floor, some of this kinetic energy is dissipated as sound and heat energy, causing the ball to rebound to a lower height.
When a ball is dropped, it has gravitational potential energy that is converted to kinetic energy as it falls due to gravity. This kinetic energy increases as the ball gains speed during the fall.
The height you drop the ball from will affect the bounce height this is because as the drop height increases so does the bounce height it is all to do with energy transfers. Also the waste energy is the sound and heat energy hope this helps.
When a ball is dropped from different heights, potential energy is converted into kinetic energy as it falls. The higher the drop height, the greater the potential energy at the start, resulting in a faster speed and more kinetic energy at impact. The energy transformation follows the law of conservation of energy, where the total energy remains constant but is converted between potential and kinetic forms.
The drop height of the ball directly affects the height of its bounce. A higher drop height results in a higher bounce, as the potential energy transferred to the ball upon impact is greater, causing it to rebound higher. Conversely, a lower drop height will result in a lower bounce.
When a golf ball is dropped, it gains potential energy due to gravity. As it hits the pavement, this potential energy is converted into kinetic energy, causing the ball to bounce back up. The elasticity of the ball and the pavement determine how high it will bounce.
When a ball is dropped, it has gravitational potential energy that is converted to kinetic energy as it falls due to gravity. This kinetic energy increases as the ball gains speed during the fall.
The height you drop the ball from will affect the bounce height this is because as the drop height increases so does the bounce height it is all to do with energy transfers. Also the waste energy is the sound and heat energy hope this helps.
Because with each bounce it loses energy.
When a ball is dropped from different heights, potential energy is converted into kinetic energy as it falls. The higher the drop height, the greater the potential energy at the start, resulting in a faster speed and more kinetic energy at impact. The energy transformation follows the law of conservation of energy, where the total energy remains constant but is converted between potential and kinetic forms.
The drop height of the ball directly affects the height of its bounce. A higher drop height results in a higher bounce, as the potential energy transferred to the ball upon impact is greater, causing it to rebound higher. Conversely, a lower drop height will result in a lower bounce.
When a golf ball is dropped, it gains potential energy due to gravity. As it hits the pavement, this potential energy is converted into kinetic energy, causing the ball to bounce back up. The elasticity of the ball and the pavement determine how high it will bounce.
The higher the height at which the ball is dropped from, the higher the ball bounces. Look at it in terms of energy. Initially, before the ball is dropped, the ball's potential energy, E is given by E = mgh, where m is the mass of the ball, g is the gravitational acceleration and h is the height of the ball. When the ball is dropped, the potential energy is converted to kinetic energy, and at the point of impact, , i.e. when the ball is level with the ground, and h = 0, the kinetic energy is E, given by E = 0.5mv2, where v is the velocity of the ball. The ball hits the ground, and rises again - its kinetic energy is being converted back to potential energy. The ground absorbs some of the energy upon impact, but most of the energy stays with the ball. So the kinetic energy is converted to potential energy, and once all of the kinetic energy is converted, the ball reaches its maximum height. Clearly, a higher kinetic energy corresponds to a higher bounce height. 0.5mv2 = mgh The amount of energy that the ground absorbs does not change much with the height of the ball as well.As the drop-height increases, the bounce-height too will increase, but not always in direct proportion. The efficiency will decrease as the drop height is increased.
because gold is heavy? and the concrete is too solid/dense to harness the kinetic energy from the fall of the gold ball because when it meets with the concrete the energy is turned into potential energy
Yes, a ball's bounce is affected by the height from which it is dropped. The higher the drop height, the higher the ball will bounce due to the increase in potential energy transferred into kinetic energy during the bounce.
If this happens you can get a free drop under the rule that you can not harm any living animals.
When the ball hits the floor, it gets deformed, and the force of the ball compressing stores potential energy in the ball. This potential energy is released, causing the ball to bounce back up. This bounce-back force is a combination of the stored potential energy and the elasticity of the ball material.
Assuming this took place on the field, the fan is considered an outside agent (OA) and the restart is a drop ball where it was touched.