# Gravitational energy

**Gravitational energy** is the potential energy held by an object because of its high position compared to a lower position. In other words, it is energy associated with gravity or gravitational force. For example, a pen being held above a table has a higher **gravitational potential** than a pen sitting on the table. Gravitational potential energy is mechanical energy minus kinetic energy. It has a scalar quantity measured in Joules (J).

An object gets gravitational potential energy when it moves uphill. The energy used up when moving up the hill is changed into gravitational potential energy. When the object comes back down again, the gravitational potential energy is turned back into kinetic energy (movement). That is why riding a bike up a steep hill is very hard, but when you are coming back down, you will not need to pedal at all - you are being powered by the gravitational potential energy that you stored when you rode up the hill. Another way gravitational potential energy helps us is by keeping earth and the other planets in orbit in our solar system around the Sun.

## Formula and example[change | change source]

The mathematical formula for the gravitational potential energy:

Gravitational potential energy =

Where:

*m*is the*mass of the object*,*g*is the gravitational acceleration of the object , and*h*is the*height above a chosen point*.

Most scientists and students use these measurement unit:

- The value
*m*is in kilograms. - The value
*h*is in metres. - The value
*g*is a physical constant with the value of 9.81 metres per second squared. This is known as the gravitational constant. - The value of the gravitational potential energy that is calculated using values in the above units is called the Joule (J).

For example, an object with a mass of 1.5 kilograms that is 2.5 metres above the ground would have a gravitational potential energy value of:

joules.