Kinetic energy
It will decrease if the object moves upward; decrease if the object moves downward.
As the ball falls, its potential energy will decrease while its kinetic energy will increase. This is because potential energy is converted to kinetic energy as the ball falls due to the force of gravity acting on it.
When something falls or is dropped, its potential energy decreases because it is being converted into kinetic energy due to gravity. As the object moves closer to the Earth's surface, gravitational force is doing work on it, causing a reduction in potential energy and an increase in kinetic energy.
When you toss a ball upward, your body applies kinetic energy to the ball, giving it potential energy as it rises. As the ball falls back down, its potential energy is converted back into kinetic energy, leading to a decrease in potential energy and an increase in kinetic energy until it reaches the ground.
If an object falls twice as far, it acquires twice as much potential energy due to the increase in height. The increase in potential energy is directly proportional to the distance the object falls.
It will decrease if the object moves upward; decrease if the object moves downward.
As the ball falls, its potential energy will decrease while its kinetic energy will increase. This is because potential energy is converted to kinetic energy as the ball falls due to the force of gravity acting on it.
Kinetic energy increases and gravitational potential energy decreases.
When something falls or is dropped, its potential energy decreases because it is being converted into kinetic energy due to gravity. As the object moves closer to the Earth's surface, gravitational force is doing work on it, causing a reduction in potential energy and an increase in kinetic energy.
When you toss a ball upward, your body applies kinetic energy to the ball, giving it potential energy as it rises. As the ball falls back down, its potential energy is converted back into kinetic energy, leading to a decrease in potential energy and an increase in kinetic energy until it reaches the ground.
If an object falls twice as far, it acquires twice as much potential energy due to the increase in height. The increase in potential energy is directly proportional to the distance the object falls.
As the diver falls, their kinetic energy increases due to their gain in speed. This increase in kinetic energy correlates with a decrease in potential energy as the diver descends towards the ground. The total energy of the diver (kinetic + potential) remains constant if we ignore air resistance and other external forces.
As an object falls, its potential energy (PE) decreases due to the force of gravity pulling it downward. This decrease in PE is accompanied by an increase in kinetic energy (KE) as the object gains speed from its downward motion. Thus, energy is converted from PE to KE as the object falls.
As an object falls, its potential energy decreases and is converted into kinetic energy. This leads to an increase in the object's kinetic energy as its speed and velocity increase due to the pull of gravity.
As the stone falls, its potential energy decreases due to the decrease in height above the ground. At the same time, its kinetic energy increases as it gains speed while falling. The total mechanical energy (sum of potential and kinetic energy) of the stone remains constant in the absence of external forces like air resistance.
As a coin falls to the ground, it loses potential energy due to a decrease in height and gains kinetic energy, which is the energy of motion. This kinetic energy increases as the coin's speed increases during its fall.
The mechanical energy of a coconut falling from a tree decreases. As the coconut falls, its potential energy (due to its height) is transformed into kinetic energy (due to its motion). Therefore, the total mechanical energy (potential energy + kinetic energy) decreases as the coconut falls.