# Calculating energy changes - with complex examples (KE and dGPE)

I can use the principle of conservation of energy to calculate changes in energy of moving objects.

# Calculating energy changes - with complex examples (KE and dGPE)

I can use the principle of conservation of energy to calculate changes in energy of moving objects.

## Slide deck

## Lesson details

### Key learning points

- Energy cannot be created or destroyed.
- In an ideal situation, no energy is dissipated.
- As an object changes height, change in gravitational potential energy = change in kinetic energy.

### Common misconception

Energy can be lost or created in physical processes.

Always discuss how energy is dissipated to the surroundings when discussing energy transformations, even when dealing with ‘ideal situations’ in which there is no dissipation.

### Keywords

Conservation of energy - The principle of conservation of energy states that the total amount of energy at the end of a process is always the same as the total amount of energy at the beginning.

Dissipate - Friction or air resistance can cause energy to dissipate into the surroundings as heat.

Gravitational potential energy - The energy an object has in its gravitational store is referred to as the object’s gravitational potential energy.

Kinetic energy - The energy an object has in its kinetic store is referred to as the object’s kinetic energy.

### Licence

This content is © Oak National Academy Limited (2024), licensed on Open Government Licence version 3.0 except where otherwise stated. See Oak's terms & conditions (Collection 2).

## Video

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## Worksheet

## Starter quiz

### 6 Questions

$$\Delta GPE$$ -

change in gravitational potential energy

$$m$$ -

mass

$$g$$ -

gravitational field strength

$$\Delta h$$ -

change in height

$$KE$$ -

kinetic energy

$$v$$ -

speed

energy -

joules (J)

mass -

kilograms (kg)

speed -

metres per second (m/s)

gravitational field strength -

newtons per kilogram (N/kg)

height -

metres (m)