Types of Radiation (WJEC GCSE Physics): Revision Note
Exam code: 3420
Types of Radiation
When an unstable nucleus decays, it emits radiation
The different types of radiation that can be emitted are:
Alpha (α) particles
Beta (β-) particles
Gamma (γ) radiation
These changes are spontaneous and random
Alpha Particles
The symbol for alpha is α
An alpha particle is the same as a helium nucleus
This is because it consists of two neutrons and two protons
Beta Particles
The symbol for beta is β−
Beta particles are high-energy electrons
They are produced in nuclei when a neutron changes into a proton and an electron
Gamma Rays
The symbol for gamma is γ
Gamma rays are electromagnetic waves
They have the highest energy of the different types of electromagnetic waves
Alpha, Beta & Gamma Radiation
Alpha particles, beta particles and gamma waves can be emitted from unstable nuclei
Properties of Alpha, Beta & Gamma
Alpha (α), beta (β) and gamma (γ) radiation can be identified by their:
Nature (what type of particle or radiation they are)
Ionising ability (how easily they ionise other atoms)
Penetrating power (how far can they travel before they are stopped completely)
Alpha, beta and gamma penetrate materials in different ways
This means they are stopped, or reduced, by different materials
Penetrating Power of Alpha, Beta and Gamma
Alpha, beta and gamma are different in how they penetrate materials. Alpha is the least penetrating, and gamma is the most penetrating
Alpha is stopped by paper, whereas beta and gamma pass through it
Beta is stopped by a few millimetres of aluminium
Gamma rays can pass through aluminium but are only partially stopped by thick lead
Summary of the properties of nuclear radiation
Particle | Nature | Range in air | Penetrating power | Ionising ability |
|---|---|---|---|---|
Alpha (α) | helium nucleus (2 protons, 2 neutrons) | a few cm | low; stopped by a thin sheet of paper | high |
Beta (β) | high-energy electron | a few 10s of cm | moderate; stopped by a few mm of aluminium foil or Perspex | moderate |
Gamma (γ) | electromagnetic wave | infinite | high; reduced by a few cm of lead | low |
Examiner Tips and Tricks
It is important to note that beta particles are only stopped by aluminium if it is a few mm thick. They can pass though aluminium which is thinner than this. This concept often comes up in exam questions.
Dangers of Nuclear Radiation
All types of ionising radiation pose a danger if mishandled as they can damage living cells and tissues and can even cause cancer
Effect of Radiation on a Human Cell
Ionising radiation can cause damage to DNA. Sometimes the cell can successfully repair the DNA, but incorrect repairs can cause a mutation
Highly ionising types of radiation are more dangerous inside the body (if a radioactive source is somehow ingested)
Alpha sources are the most ionising, so they are likely to cause the most harm to living cells inside the body
Gamma sources are the least ionising (about 20 times lower than alpha particles), so they are likely to cause the least harm to living cells inside the body
Highly penetrating types of radiation are more dangerous outside the body
Gamma sources are the most penetrating, so they are able to pass through the skin and reach living cells in the body
Alpha sources are least penetrating, so they would be absorbed by the air before even reaching the skin
Nuclear Waste
Nuclear waste must be treated appropriately, depending on the type of radiation it emits
Alpha-emitting nuclear waste is easily stored in plastic or metal canisters
Beta-emitting nuclear waste is stored inside metal canisters and concrete silos
Gamma-emitting nuclear waste requires storage inside lead-lined, thick concrete silos
Radioactive waste of all types tends to emit dangerous levels of radiation for many years, so it must be stored securely for a very long time
Typically, waste with the highest levels of radioactivity must be buried underground in secure, geologically stable locations
Dealing with Radioactive Waste
Depending on the type of radiation emitted, nuclear waste is treated in different ways
Worked Example
A student has an unknown radioactive source. They are trying to work out which type of ionising radiation is being emitted.
They measure the count rate, using a Geiger-Muller tube, when the source is placed behind different materials. Their results are recorded in a table.
| no material between source and detector | thin sheet of paper between source and detector | 5 mm aluminium foil between source and detector | 5mm lead plate between source and detector |
|---|---|---|---|---|
Count-rate | 4320 | 4218 | 256 | 34 |
Which type(s) of ionising radiation is/are emitted by the source?
A. Alpha particles
B. Beta particles
C. Gamma rays
D. Alpha, beta and gamma radiation
Answer: B
The answer is not A or D because the radiation passed through the paper almost unchanged
This means it is not alpha as alpha is stopped by a thin sheet of paper
The answer is not C because the aluminium decreased the count rate significantly
This means it is not gamma as gamma penetrates aluminium
Therefore, the source must be beta particles
Examiner Tips and Tricks
Remembering the type of particle, penetration and ionising power for alpha, beta and gamma radiation is very important for your exam! Often the exam question will give some clues and you will have to choose which type of radiation it could be based off these.
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