No, the skateboard on the floor would have more potential energy due to its higher mass and distance from the ground. Potential energy is determined by an object's position and height above the reference point, so in this case, the skateboard would have more potential energy.
The skateboard on the floor has more potential energy because it is higher up compared to the sock on the dresser. The potential energy of an object is determined by its position relative to the ground, with higher objects having more potential energy.
When a ball drops to the floor, the potential energy it had due to its height is converted into kinetic energy as it falls. Upon impact with the floor, some of this energy is absorbed by both the ball and the floor, resulting in sound and heat energy.
Yes, an object can have potential energy when it is at rest, such as gravitational potential energy or elastic potential energy. Kinetic energy, which is energy of motion, requires the object to be moving.
The book gains potential energy when you pick it up off the floor. This potential energy is stored in the book's position above the ground and can be converted into kinetic energy if the book is dropped.
The gravitational potential energy of the cat relative to the floor depends on the height of the cat above the floor. The formula to calculate gravitational potential energy is GPE = mgh, where m is the mass of the cat, g is the acceleration due to gravity (9.8 m/s^2), and h is the height of the cat above the floor. The higher the cat is from the floor, the greater its gravitational potential energy will be.
Pushing a ball along the floor involves the input of kinetic energy as you apply force to the ball to make it move. The ball itself possesses potential energy based on its position relative to the ground, but the act of pushing it converts some of that potential energy into kinetic energy as it starts moving.
The one that is at the greatest height above the floor level.
When a ball is dropped to the floor, potential energy is converted into kinetic energy as the ball moves downward due to gravity. Upon impact with the floor, some of the kinetic energy is converted into sound energy and thermal energy due to the collision and friction with the floor surface.
As the ball falls toward the floor, its potential energy decreases due to gravity pulling it downward while its kinetic energy increases as it gains speed. This exchange between potential and kinetic energy follows the principle of conservation of mechanical energy.
When a basketball bounces, the potential energy is converted into kinetic energy as it falls downward. This kinetic energy then allows the ball to compress upon impact with the floor, storing elastic potential energy. This potential energy is then converted back into kinetic energy as the ball rebounds back up.
When a falling bag hits the floor, the potential energy of the bag due to its height above the ground is converted into kinetic energy as it falls. Upon impact with the floor, some of this kinetic energy is dissipated as sound and heat energy.