Chain Reactions and Reactors

Overview

Chain Reactions and Reactors explains how neutrons from one fission event can trigger further fission events, and how nuclear reactors control this process safely.

This page deepens ideas from:

• Nuclear Fission
• Nuclear Physics

Definition

A chain reaction is a self-propagating sequence of fission events in which neutrons from earlier fissions cause further fissions.

Why It Matters

Students need this idea to understand:

• why fission can produce enormous energy output
• why not all neutrons are equally useful
• how reactors maintain steady operation without becoming uncontrolled

Key Representations

Chain Reaction Mechanism

When a fissile nucleus undergoes fission, it releases:

• energy
• daughter nuclei
• several neutrons

Example:

$${}_{92}^{235}\text{U}+{}_0^{1}n\to \text{products}+2\text{ to }3{}_0^{1}n+E$$

These neutrons may strike other fissile nuclei and cause more fission.

This repeating process is a chain reaction.

Fission Neutrons

Why they matter:

• without emitted neutrons, the reaction would stop after one event

Possible outcomes of a released neutron:

• it causes another fission
• it is absorbed without causing fission
• it escapes from the fuel
• it is slowed by the moderator
• it is absorbed by control rods

Only some neutrons continue the chain reaction.

Multiplication of Reactions

Simple idea:

• 1 fission causes 2 more
• 2 cause 4 more
• 4 cause 8 more

This can grow rapidly if not controlled.

Criticality Concepts

Subcritical State

Too few neutrons continue the chain reaction.

Result:

• reaction rate decreases
• reactor power falls
• chain reaction may stop

Critical State

Exactly enough neutrons continue.

Result:

• steady reaction rate
• constant power output

Supercritical State

More than enough neutrons continue.

Result:

• reaction rate rises
• power increases

Controlled Reactor Operation

A power reactor aims to remain near the critical state.

This gives:

• stable heat production
• predictable electricity generation
• safer operation

Operators adjust the neutron population using control systems.

Reactor Components and Functions

Fuel

Contains fissile nuclei such as:

• uranium-235
• plutonium-239

It provides nuclei for fission.

Moderator

Purpose:

• slows fast neutrons into slower thermal neutrons

Slow neutrons are more likely to induce fission in some fuels.

Common materials:

• water
• heavy water
• graphite

Important note:

• the moderator does not mainly absorb neutrons

Control Rods

Purpose:

• absorb neutrons to control the reaction rate

If inserted deeper:

• fewer neutrons are available
• power decreases

If withdrawn:

• more neutrons are available
• power increases

Common materials:

• boron
• cadmium

Coolant

Purpose:

• transfers heat away from the reactor core

This heat is then used to generate steam for turbines.

Examples:

• water
• carbon dioxide gas
• liquid sodium

Shielding

Purpose:

• protects workers and surroundings from ionising radiation

Materials include:

• thick concrete
• steel
• lead in some regions

Why Moderators Are Used

Fast neutrons produced by fission may be less effective at causing further fission.

Moderator collisions reduce neutron speed.

Therefore:

• probability of further fission increases
• sustained reaction becomes easier

Why Control Rods Are Used

Without neutron absorption, the reactor may become supercritical.

Control rods allow:

• stable output
• rapid shutdown if needed
• safe response to changing conditions

Why Coolant Is Used

Fission releases large amounts of thermal energy.

Without coolant:

• temperature rises dangerously
• materials may be damaged

Coolant removes energy continuously.

Why Shielding Is Used

Fission products and the reactor core emit radiation.

Shielding reduces exposure to:

• gamma rays
• neutrons
• other ionising radiation

Worked Reasoning Examples

Example 1: Reactor Power Rising Too Fast

What should be done?

Answer:

Insert the control rods further to absorb more neutrons.

Example 2: Why Large Fuel Mass Helps

Answer:

It reduces the fraction of neutrons escaping, increasing the chance of further fission.

Example 3: Why Use a Moderator Instead of Just More Fuel

Answer:

Slow neutrons are more effective for causing fission in certain fuels.

Example 4: Why Coolant Must Circulate

Answer:

It must carry thermal energy away continuously.

Summary

• fission neutrons can trigger further fission
• a chain reaction may be subcritical, critical, or supercritical
• reactors aim for critical operation
• moderator slows neutrons
• control rods absorb neutrons
• coolant removes heat
• shielding reduces radiation exposure

Links

• Nuclear Fission
• Nuclear Physics
• Ionizing Radiation and Safety
• Nuclear Fission Common Exam Traps