Right before it is thrown or right when it bounces
The letter representing the position where the basketball has the greatest energy would be B, which is at the highest point of its trajectory. At this position, the basketball has maximum potential energy due to its height above the ground and minimum kinetic energy as it momentarily stops before falling back down.
the box when it is inclined will have greatest potential energy on the top corners only.
The letter at the bottom of the arc represents the position at which the basketball has the least potential energy. This is because potential energy is lowest at the lowest point of the arc due to the effect of gravity pulling the basketball down.
The potential energy of a swing is greatest at the highest point of its arc. This is where the swing has the most distance from the ground and the most potential to do work if released.
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.
The letter representing the position where the basketball has the greatest energy would be B, which is at the highest point of its trajectory. At this position, the basketball has maximum potential energy due to its height above the ground and minimum kinetic energy as it momentarily stops before falling back down.
the box when it is inclined will have greatest potential energy on the top corners only.
The letter at the bottom of the arc represents the position at which the basketball has the least potential energy. This is because potential energy is lowest at the lowest point of the arc due to the effect of gravity pulling the basketball down.
On a pendulum, the greatest potential energy is at the highest point of the swing on either side, and the greatest kinetic energy is at the bottom of the swing. On a roller coaster, the greatest potential energy is at the top of a hill, and the greatest kinetic energy is at the bottom of the hill.
The acorn has the greatest potential energy at the highest point in its fall, where it is furthest from the ground. As it falls, this potential energy converts into kinetic energy, which is greatest just before it hits the ground. At this moment, the acorn's speed is at its maximum, resulting in the highest kinetic energy.
The potential energy of a swing is greatest at the highest point of its arc. This is where the swing has the most distance from the ground and the most potential to do work if released.
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.
The car that is highest has the most potential energy.
The greatest type of energy at the bottom of a swing's path is kinetic energy, which is the energy of motion. The potential energy at the top of the swing is converted to kinetic energy as the swing reaches the bottom of its arc.
The greatest influence on the potential energy of an object is its mass and height above a reference point, such as the ground. The potential energy increases with an increase in mass and height because there is more gravitational potential energy stored in the object.
Kenetic, potential.
A falling object has the greatest potential energy when it is highest, at the beginning of the fall. It has the greatest kinetic energy when it is at its lowest, at the end of the fall. Without taking friction or air resistance into account, the beginning potential energy is the same as the final kinetic energy. If friction is considered, the beginning potential energy is greater.