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When a rubber ball is dropped, the potential energy is converted to kinetic energy upon hitting the ground, causing the ball to compress and then rebound. The elastic properties of the rubber material then allow the ball to quickly return to its original shape, transferring the kinetic energy back into potential energy and causing the ball to bounce back up.
When a rubber ball is dropped from a height, it accelerates downwards due to gravity. As it falls, the ball's potential energy is converted into kinetic energy. Upon impact with the ground, the kinetic energy is transferred back into potential energy through deformation of the rubber material, causing the ball to bounce back up.
The rubber ball moved due to an external force applied to it, such as being thrown, kicked, or rolled. The force caused the ball to accelerate and change its position or direction.
Rubber balls bounce high because rubber is an elastic material that can store and release a lot of energy upon impact. When a rubber ball hits a surface, it deforms and compresses, storing potential energy. As it rebounds, the stored energy is released, propelling the ball back up with force, resulting in a high bounce.
A soccer ball bounces due to the elasticity of the material it is made from, typically rubber. When the ball hits the ground, the rubber compresses and stores energy. This energy is then released, causing the ball to bounce back up in the opposite direction.
Moving a rubber ball across the room requires mechanical energy.
When a rubber ball is dropped, the potential energy is converted to kinetic energy upon hitting the ground, causing the ball to compress and then rebound. The elastic properties of the rubber material then allow the ball to quickly return to its original shape, transferring the kinetic energy back into potential energy and causing the ball to bounce back up.
When a rubber ball is dropped from a height, it accelerates downwards due to gravity. As it falls, the ball's potential energy is converted into kinetic energy. Upon impact with the ground, the kinetic energy is transferred back into potential energy through deformation of the rubber material, causing the ball to bounce back up.
The rubber ball moved due to an external force applied to it, such as being thrown, kicked, or rolled. The force caused the ball to accelerate and change its position or direction.
Rubber balls bounce high because rubber is an elastic material that can store and release a lot of energy upon impact. When a rubber ball hits a surface, it deforms and compresses, storing potential energy. As it rebounds, the stored energy is released, propelling the ball back up with force, resulting in a high bounce.
it has more elasticity and potential energy
bouyancy.
A soccer ball bounces due to the elasticity of the material it is made from, typically rubber. When the ball hits the ground, the rubber compresses and stores energy. This energy is then released, causing the ball to bounce back up in the opposite direction.
A rubber ball rebounds lower over time due to energy loss in the form of heat and deformation when it collides with a surface. This dissipates energy and reduces the ball's ability to return to its original height.
The air molecules inside the ball will contract and lose energy, causing the ball to deflate as the pressure decreases. The rubber material of the ball may also become more rigid and less elastic in the cold temperatures.
A rubber ball bounces on a hard surface due to its elasticity and the conservation of kinetic energy. When the ball hits the surface, it deforms and stores potential energy. As it rebounds, this potential energy is converted back into kinetic energy, propelling the ball upward.
The simple answer to this is that the rubber ball is more 'elastic' than the tennis ball and, assuming they are both dropped from the same height onto the same surface, the tennis ball 'loses' more energy than the rubber ball when it strikes the surface the ball is bouncing off. Of course no energy is truly ever lost but rather it is transferred or converted into other forms, in this case the energy will be converted into thermal energy (as the balls deform upon striking the surface due to friction within the materials), sound (the noise you hear when the ball strikes the surface) and to varying extents energy is transferred to the surface which the balls are striking. This energy 'loss' is the reason why the balls do not return to the height the balls were dropped from originally and the amount of energy 'loss' will vary with the type of ball dropped.