Kinetic

Gravitational Potential

Elastic potential

Thermal

Sound

Heating

Kinetically

Mechanically

Electrically

Waves

Energy is transferred from the kinetic energy store of the ball to its gravitational potential energy store. Energy is also transferred from the kinetic energy store to the thermal energy store of the ball and the air as work is done by air resistance to slow it down.

Energy is transferred from the gravitational potential energy store of the ball to its kinetic energy store. Energy is also transferred from the gravitational potential energy store to the thermal energy store of the ball and the air as work is done by air resistance to slow it down.

Energy is transferred from the kinetic energy store of the ball to its gravitational potential energy store. Energy is also transferred from the thermal energy store of the ball to the thermal energy store of the air as work is done by air resistance to slow it down.

Energy is transferred from the gravitational potential energy store of the ball to its kinetic energy store. Energy is also transferred from the thermal energy store of the ball to the thermal energy store of the air as work is done by air resistance to slow it down.

A 10 kg mass with a speed of 5 m/s.

A 5 kg mass with a speed of 10 m/s.

A 2 kg mass with a speed of 20 m/s.

A 0.1 kg mass with a speed of 100 m/s.

A 3 kg mass, 5 m above the ground on Earth (g = 9.8 N/kg)

A 4 kg mass, 4 m above the ground on Venus (g = 8.9 N/kg)

A 10 kg mass, 5 m above the ground on Mars (g = 3.4 N/kg)

A 9 kg mass, 11 m above the ground on the Moon (g = 1.6 N/kg)

0.1 J

1.0 J

10.0 J

100.0 J

power = work done x time

time = power x work done

work done = power x time

work done = power / time