4.1 Use the following units: kilogram (kg), joule (J), metre (m), metre/second (m/s), metre/second² (m/s²), newton (N), second (s) and watt (W).
This module explores how energy is stored and transferred, the fundamental principle of energy conservation, the concept of efficiency, and the mechanisms of thermal energy transfer.
⚡ 1. Energy Stores and Transfers
🎯 Learning Outcomes (4.2, 4.5)
Describe energy transfers involving the 8 energy stores and 4 transfer pathways.
Describe everyday devices, explaining the transfer of input energy.
Energy is never created or destroyed, but it can be stored in different ways and transferred between stores.
Energy Stores
Chemical – bonds in food, fuels, batteries
Kinetic – moving objects
Gravitational PE – objects at height
Elastic PE – stretched/compressed objects
Thermal – particle energy due to temperature
Magnetic – interacting magnets
Electrostatic – separated charges
Nuclear – energy in atomic nuclei
Energy Transfers
Mechanically – a force does work (pushing, lifting)
Electrically – charges flow through a circuit
By Heating – temperature difference drives energy flow
By Radiation – energy as waves (light, sound)
💡 Example: A Bouncing Ball
Ball held high → Gravitational PE store
Falls: GPE decreases, KE increases (mechanical transfer); some to thermal (air resistance)
Hits ground: KE → Elastic PE + Thermal + Sound
Bounces up: Elastic PE → KE → GPE
💡 Example: Battery-Powered Torch
Battery: Chemical energy store
Switched on: Chemical energy transferred electrically to bulb
Watch how energy transfers between GPE, KE, and Thermal stores as a ball bounces.
GPE0 J
KE0 J
Thermal0 J
Total0 J
🔄 2. Conservation of Energy
🎯 Learning Outcome (4.3)
Use the principle of conservation of energy.
Energy cannot be created or destroyed, only transferred from one store to another, or transformed from one form to another.
The total energy in a closed system remains constant. Energy can change forms, but the sum of all energy stays the same.
🕐 Simulation: Pendulum – GPE & KE Transfer
See how gravitational PE converts to kinetic energy and back. Toggle friction to observe energy dissipation.
GPE0 J
KE0 J
Thermal0 J
Total0 J
📈 3. Efficiency & Sankey Diagrams
🎯 Learning Outcomes (4.4, 4.5)
Know and use: Efficiency = (Useful Energy Output / Total Energy Input) × 100%
Represent energy transfers using Sankey diagrams.
Efficiency = (Useful Energy Output ÷ Total Energy Input) × 100%
No device is 100% efficient; some energy is always dissipated, typically as heat.
🧮 Efficiency Calculator
Sankey Diagram
The widths of the arrows are proportional to the energy amounts.
🌡 4. Thermal Energy Transfer
🎯 Learning Outcomes (4.6–4.8, 4.10)
Describe thermal energy transfer by conduction, convection and radiation.
Explain the role of convection in everyday phenomena.
Explain how emission/absorption relate to surface and temperature.
Explain ways of reducing unwanted energy transfer.
A. Conduction
Conduction transfers thermal energy through a substance without the substance moving. It mainly occurs in solids. Heated particles vibrate more vigorously, passing energy to neighbours. In metals, free electrons also carry energy rapidly.
💡 A metal spoon in hot tea – the handle becomes hot because energy is conducted along the metal.
Good conductors: metals. Poor conductors (insulators): wood, plastic, air.
🔥 Simulation: Conduction Race
Compare how fast heat travels through different materials. Watch the colour change from blue (cold) to red (hot).
0.0s
B. Convection
Convection transfers thermal energy in fluids (liquids and gases) by the movement of the fluid itself. Heated fluid expands, becomes less dense, and rises. Cooler fluid sinks, creating convection currents.
💡 Everyday examples:
Heating water in a kettle – element heats nearby water which rises
Room heaters – warm air rises, cool air replaces it
Sea & land breezes – differential heating of land and sea
C. Radiation
Radiation transfers thermal energy as infrared electromagnetic waves. It doesn’t require a medium and works through a vacuum (e.g., sunlight reaching Earth).