IB ESS - Nuclear energy | Free Notes

How nuclear power works

Big idea: Nuclear fission releases enormous amounts of energy from small amounts of fuel, providing low-carbon baseload electricity.

The fission process

Fuel: Usually uranium-235 or plutonium-239
Fission: Neutrons split heavy nuclei, releasing energy and more neutrons
Chain reaction: Released neutrons split more nuclei; controlled by moderators and control rods
Heat generation: Energy heats water to steam, which drives turbines
Energy density: 1 kg uranium = ~20,000 kg coal equivalent

Types of nuclear power

Conventional fission reactors: Current technology; uses enriched uranium
Breeder reactors: Create more fuel than they consume; can use thorium
Fusion (future): Fusing light nuclei (hydrogen); no commercial plants yet
Small modular reactors (SMRs): Emerging technology; smaller, potentially safer

Nuclear power produces no direct CO₂ emissions during operation, making it attractive for climate mitigation — but waste and safety remain concerns.

Exam tip: Nuclear is often classified separately from both fossil fuels and renewables. Understand why — its non-renewable (finite uranium) but low-carbon.

Advantages and disadvantages

Big idea: Nuclear power is controversial — it offers low-carbon baseload electricity but raises concerns about safety, waste, cost, and proliferation.

Advantages

Low carbon emissions: No CO₂ during operation; lifecycle emissions similar to renewables
High energy density: Small fuel volume produces large amounts of electricity
Reliable baseload: Runs continuously regardless of weather; ~90% capacity factor
Small land footprint: Much less land than solar or wind for same output
Long operating life: Plants can run 40-60+ years

Disadvantages

Radioactive waste: High-level waste remains dangerous for thousands of years; no permanent disposal solution
Safety risks: Accidents (Chernobyl, Fukushima) can have catastrophic consequences
High costs: Expensive to build; often over budget and delayed
Proliferation: Technology and materials can potentially be used for weapons
Uranium mining: Causes environmental damage similar to other mining
Decommissioning: Costly and complex process at end of plant life

Nuclear accidents are rare but severe. The debate often comes down to comparing small probability × high consequence risks against certain, ongoing climate change impacts.

Exam tip: Nuclear power divides people across the EVS spectrum. Technocentrists often support it; many ecocentrists oppose it. Be ready to explain both perspectives.

How nuclear power works

Big idea: Nuclear fission releases enormous amounts of energy from small amounts of fuel, providing low-carbon baseload electricity.

The fission process

Fuel: Usually uranium-235 or plutonium-239
Fission: Neutrons split heavy nuclei, releasing energy and more neutrons
Chain reaction: Released neutrons split more nuclei; controlled by moderators and control rods
Heat generation: Energy heats water to steam, which drives turbines
Energy density: 1 kg uranium = ~20,000 kg coal equivalent

Types of nuclear power

Conventional fission reactors: Current technology; uses enriched uranium
Breeder reactors: Create more fuel than they consume; can use thorium
Fusion (future): Fusing light nuclei (hydrogen); no commercial plants yet
Small modular reactors (SMRs): Emerging technology; smaller, potentially safer

Nuclear power produces no direct CO₂ emissions during operation, making it attractive for climate mitigation — but waste and safety remain concerns.

Exam tip: Nuclear is often classified separately from both fossil fuels and renewables. Understand why — its non-renewable (finite uranium) but low-carbon.

Advantages and disadvantages

Big idea: Nuclear power is controversial — it offers low-carbon baseload electricity but raises concerns about safety, waste, cost, and proliferation.

Advantages

Low carbon emissions: No CO₂ during operation; lifecycle emissions similar to renewables
High energy density: Small fuel volume produces large amounts of electricity
Reliable baseload: Runs continuously regardless of weather; ~90% capacity factor
Small land footprint: Much less land than solar or wind for same output
Long operating life: Plants can run 40-60+ years

Disadvantages

Radioactive waste: High-level waste remains dangerous for thousands of years; no permanent disposal solution
Safety risks: Accidents (Chernobyl, Fukushima) can have catastrophic consequences
High costs: Expensive to build; often over budget and delayed
Proliferation: Technology and materials can potentially be used for weapons
Uranium mining: Causes environmental damage similar to other mining
Decommissioning: Costly and complex process at end of plant life

Nuclear accidents are rare but severe. The debate often comes down to comparing small probability × high consequence risks against certain, ongoing climate change impacts.

Exam tip: Nuclear power divides people across the EVS spectrum. Technocentrists often support it; many ecocentrists oppose it. Be ready to explain both perspectives.

Nuclear energy

Study like the top scorers do

How nuclear power works

The fission process

Types of nuclear power

Advantages and disadvantages

Advantages

Disadvantages

Related ESS Topics

IB Exam Questions on Nuclear energy

How Nuclear energy Appears in IB Exams

Make these notes count

Nuclear energy

Study like the top scorers do

How nuclear power works

The fission process

Types of nuclear power

Advantages and disadvantages

Advantages

Disadvantages

Related ESS Topics

IB Exam Questions on Nuclear energy

How Nuclear energy Appears in IB Exams

Make these notes count