Fission & Fusion - Interactive Learning Module

🎓 Module Overview

This module explores the powerful nuclear processes of fission and fusion. Through interactive simulations, you'll discover how these reactions release vast amounts of energy, the principles behind nuclear power, and the energy source of stars.

Use the navigation bar above to jump between sections. Each section includes interactive simulations — click the Play buttons to watch them in action!

⚡ Energy from Nuclear Reactions

🎯 Learning Outcome 7.17:

Know that nuclear reactions, including fission, fusion and radioactive decay, can be a source of energy.

⚡ Where Does Nuclear Energy Come From?

Inside every atom there is a nucleus held together by incredibly powerful forces. When a nucleus is split apart (fission) or when small nuclei are joined together (fusion), some of that binding energy is released. Even radioactive decay (when an unstable nucleus emits particles on its own) releases energy.

The key idea is simple: nuclear reactions release far more energy than chemical reactions like burning fuels. Let's see just how much more!

🔥 How Powerful Is Nuclear Energy?

Click the buttons below to compare the energy from one single nuclear reaction to everyday things you already know about:

💡 Key Takeaway

A tiny piece of nuclear fuel the size of your fingertip contains as much energy as roughly 1 tonne (1,000 kg) of coal. That's why nuclear reactions are so powerful — a small amount of fuel produces an enormous amount of energy!

💥 Nuclear Fission

🎯 Learning Outcomes 7.18 & 7.19:

7.18: Understand how a nucleus of U-235 can be split by collision with a neutron, releasing energy as kinetic energy of the fission products.
7.19: Know that the fission of U-235 produces two radioactive daughter nuclei and a small number of neutrons.

Nuclear fission occurs when a heavy nucleus like Uranium-235 absorbs a neutron, becomes unstable, and splits into two smaller daughter nuclei (e.g., Krypton and Barium), releasing 2–3 additional neutrons and a large amount of kinetic energy.

💡 Fission Reaction:

n + ²³⁵U → ⁹²Kr + ¹⁴¹Ba + 3n + Energy (~200 MeV)

Ready

Watch a neutron strike U-235, causing it to wobble and split into Krypton + Barium + 3 neutrons + energy.

🔗 Chain Reactions

🎯 Learning Outcome 7.20:

Describe how a chain reaction can be set up if the neutrons produced by one fission strike other U-235 nuclei.

A chain reaction occurs when neutrons released from one fission event cause further fissions in nearby U-235 nuclei. If at least one neutron per fission causes another fission, the reaction is self-sustaining.

Controlled: Used in nuclear power reactors, where the rate is carefully managed.
Uncontrolled: Occurs in nuclear weapons, with an explosive release of energy.

Fissions: 0 Neutrons: 1 Atoms left: 0

Click Start to fire an initial neutron. Watch it trigger a cascading chain reaction through the uranium fuel.

🏭 Nuclear Reactor Control

🎯 Learning Outcomes 7.21 & 7.22:

7.21: Describe the role played by the control rods and moderator in the fission process.
7.22: Understand the role of shielding around a nuclear reactor.

Control rods (made of boron or cadmium) absorb neutrons to regulate the fission rate. Moderators (e.g., water, graphite) slow neutrons to increase fission probability. Shielding (thick concrete and steel) protects people from radiation.

Control Rod Depth: 50% Critical

Drag the slider to insert or withdraw control rods. Watch how it affects power output, neutron flux, and reactor status.

⭐ Nuclear Fusion

🎯 Learning Outcomes 7.24, 7.25 & 7.26:

7.24: Describe nuclear fusion as the creation of larger nuclei from smaller nuclei, with a loss of mass and release of energy.
7.25: Know that fusion is the energy source for stars.
7.26: Explain why fusion doesn't happen at low temperatures due to electrostatic repulsion of protons.

Nuclear fusion combines light nuclei (like Deuterium and Tritium) to form a heavier nucleus (Helium-4), releasing even more energy per unit mass than fission. This is the process that powers the Sun and all stars.

💡 Fusion Reaction (D-T):

²H + ³H → ⁴He + n + Energy (~17.6 MeV)

⚡ Fusion Simulation

Ready

Deuterium and Tritium nuclei overcome electrostatic repulsion at extreme temperatures to fuse into Helium-4 + a neutron.

🌡️ Coulomb Barrier & Temperature

Fusion requires extreme temperatures (millions of °C) so nuclei have enough kinetic energy to overcome their electrostatic repulsion. Adjust the temperature below to see the effect.

Temperature: 10 million K

At low temperatures nuclei bounce off each other. Increase the temperature to give them enough kinetic energy to fuse!

⚖️ Fission vs. Fusion

🎯 Learning Outcome 7.23:

Explain the difference between nuclear fusion and nuclear fission.

Feature	Fission	Fusion
Process	Splitting a heavy nucleus	Combining light nuclei
Fuel	Uranium-235, Plutonium-239	Deuterium, Tritium (hydrogen isotopes)
Energy / Reaction	~200 MeV	~17.6 MeV (but far more per kg of fuel)
Conditions	Neutron bombardment + critical mass	Millions of °C temperature + immense pressure
Byproducts	Long-lived radioactive waste	Helium + neutrons (minimal long-lived waste)
In nature	Extremely rare (e.g., Oklo reactor)	Powers all stars
Technology	Established (nuclear power plants)	Experimental (ITER, NIF)

📈 Binding Energy per Nucleon

This curve explains why both fission (of heavy nuclei) and fusion (of light nuclei) release energy. Elements near Iron-56 sit at the peak — any reaction that moves nuclei toward iron releases energy.

Hover over the curve to see specific elements. Fusion moves up-left → peak; Fission moves up-right → peak. Both release energy!

⚛ Fission and Fusion