Yes the force and the energy affect the bounciness of the ball.
If the ball is released from 1 meter above the ground, it will fall with certain force and energy.
Now let say we drop the same ball from a height of 10m then we have increased its potential energy so this time striking the surface with more force and energy and higher the ball will bounce in this case.
The ball has its "bounciness" built in. The amount of energy transferred on a bounce (or series of bounces) simply "explores" what the ball already has.
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∙ 14y agoYes, the force and energy applied to a ball can affect its bounciness. A higher force or energy can cause the ball to bounce higher and with more intensity. Conversely, a lower force or energy will result in less bounce.
The greater the bounciness of a golf ball, the more energy it retains upon impact with the club. This results in higher initial velocity and longer distance traveled. Golf balls with higher elasticity or compression will generally travel farther than those with lower bounciness.
The source of energy for a ball to move is typically the force that is applied to it, such as someone kicking or throwing it. This force creates kinetic energy in the ball, allowing it to move.
A contact force that could affect the ball when a pitcher throws it is friction between the pitcher's fingers and the ball, which helps create spin and movement on the pitch. A non-contact force that could affect the ball is air resistance, which can slow down the ball's speed and alter its trajectory.
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.
The steepness of the ramp and the weight of the ball would affect the amount of force needed to move the ball up the ramp. A steeper ramp or a heavier ball would require more force to overcome gravity and friction.
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Yes.
The greater the bounciness of a golf ball, the more energy it retains upon impact with the club. This results in higher initial velocity and longer distance traveled. Golf balls with higher elasticity or compression will generally travel farther than those with lower bounciness.
The source of energy for a ball to move is typically the force that is applied to it, such as someone kicking or throwing it. This force creates kinetic energy in the ball, allowing it to move.
The contact force will keep the ball moving but as the ball goes farther the ball slows down that's were the non contact force comes in it makes the ball not in contact
A contact force that could affect the ball when a pitcher throws it is friction between the pitcher's fingers and the ball, which helps create spin and movement on the pitch. A non-contact force that could affect the ball is air resistance, which can slow down the ball's speed and alter its trajectory.
The steepness of the ramp and the weight of the ball would affect the amount of force needed to move the ball up the ramp. A steeper ramp or a heavier ball would require more force to overcome gravity and friction.
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.
The force of a ball allows the ballplayer to transfer energy from their body to the ball, enabling it to be thrown, hit, or caught. The force also determines the speed and direction of the ball's movement.
If the path of the ball curves or bends unexpectedly, or if it slows down or speeds up in an unusual way, these are indications that another force is acting on the ball in addition to the kicking force. This additional force could be caused by friction with the air, spin on the ball, or gravity affecting the trajectory.
Yes, work is done when you throw a ball. When you exert force on the ball to throw it, you are transferring energy to the ball, thus doing work on it. This work results in the ball gaining kinetic energy as it moves.
In physics, work is defined as the transfer of energy to an object by applying a force through a distance. When dropping a ball, gravity is the force acting on the ball, but no energy is transferred by an external force so technically dropping a ball is not considered as doing work in the physics sense.