Decay Equations (Oxford AQA IGCSE Physics)

Revision Note

Author

Caroline Carroll

Expertise

Physics Subject Lead

Decay Equations

The process of radioactive decay can be shown as a decay equation
A decay equation is similar to a chemical reaction equation
- The particles present before the decay are shown before the arrow
- The particles produced in the decay are shown after the arrow
During decay equations, the sum of the mass and atomic numbers before the reaction must be equal to the sum of the mass and atomic numbers after the reaction

Decay equations involving alpha particles

Remember that an alpha particle is a helium nucleus
- It is made of 2 protons and 2 neutrons
When the alpha particle is emitted from the unstable nucleus, the mass number and atomic number of the nucleus changes
- The mass number decreases by 4
  - The mass of the nucleus decreases
- The atomic number decreases by 2
  - The charge of the nucleus decreases by 2
  - This is because protons have a charge of +1 each
A new element is formed
This can be shown by the general decay equation:
${}_{Z}^{A}X \to {}_{Z - 2}^{A - 4}Y + {}_{2}^{4}{He}$

For example, the following equation shows Polonium-212 undergoing alpha decay
- It emits an alpha particle causing its mass and charge to decrease
- It forms lead-208 and an alpha particle
- An alpha particle can also be written as ${}_{2}^{4}α$

${}_{84}^{212}{Po} \to {}_{82}^{208}{Pb} + {}_{2}^{4}{He}$

Worked Example

A nucleus with 84 protons and 126 neutrons undergoes alpha decay. It forms lead, which has the element symbol Pb.

Which of the isotopes of lead below is the correct one formed during the decay?

A	B	C	D
${}_{82}^{206}{Pb}$	${}_{82}^{208}{Pb}$	${}_{84}^{210}{Pb}$	${}_{86}^{214}{Pb}$

Answer: A

Step 1: Calculate the mass number of the original nucleus

The mass number is equal to the number of protons plus the number of neutrons
The original nucleus has 84 protons and 126 neutrons

84 + 126 = 210

The mass number of the original nucleus is 210

Step 2: Calculate the new atomic number

The alpha particle emitted is made of two protons and two neutrons
Protons have an atomic number of 1, and neutrons have an atomic number of 0
Removing two protons and two neutrons will reduce the atomic number by 2

84 – 2 = 82

The new nucleus has an atomic number of 82

Step 3: Calculate the new mass number

Protons and neutrons both have a mass number of 1
Removing two protons and two neutrons will reduce the mass number by 4

210 – 4 = 206

The new nucleus has a mass number of 206

Exam Tip

It is easy to forget that an alpha particle is a helium nucleus. The two are interchangeable, so don’t be surprised to see either used in the exam.

Decay equations involving beta particles

Remember that a beta particle is a high-speed electron
It has a mass number of 0
Therefore, the mass number of the decaying nuclei remains the same
- Therefore the mass of the nuclei remains the same
Electrons have an atomic number of -1
- This means that the new nuclei will increase its atomic number by 1 in order to maintain the overall atomic number before and after the decay
- Therefore the charge of the nuclei increases
This can be shown by the general decay equation:
${}_{Z}^{A}X \to {}_{Z + 1}^{A}Y + {}_{- 1}^{0}e$
The following equation shows carbon-14 undergoing beta decay
- The carbon nucleus emits a beta particle causing the charge of the nucleus to increase but the mass remains the same
- It forms nitrogen-14 and a beta particle
- Beta particles can also be written as ${}_{- 1}^{0}β$
${}_{6}^{14}C \to {}_{7}^{14}N + {}_{- 1}^{0}e$

Worked Example

A nucleus with 11 protons and 13 neutrons undergoes beta decay. It forms magnesium, which has the element symbol Mg.

A	B	C	D
${}_{9}^{20}{Mg}$	${}_{10}^{24}{Mg}$	${}_{11}^{23}{Mg}$	${}_{12}^{24}{Mg}$

Which is the correct isotope of magnesium formed during the decay?

Answer: D

Step 1: Calculate the mass number of the original nucleus

The mass number is equal to the number of protons plus the number of neutrons
The original nucleus has 11 protons and 13 neutrons

11 + 13 = 24

The mass number of the original nucleus is 24

Step 2: Calculate the new atomic number

During beta decay a neutron changes into a proton and an electron
The electron is emitted as a beta particle
The neutron has an atomic number of 0 and the proton has an atomic number of 1
So the atomic number increases by 1

11 + 1 = 12

The new nucleus has an atomic number of 12

Step 3: Calculate the new mass number

Protons and neutrons both have a mass number of 1
Changing a neutron to a proton will not affect the mass number
The new nucleus has a mass number of 24 (the same as before)

Exam Tip

You are not expected to know the names of the elements produced during radioactive decays, but you do need to be able to calculate the mass and atomic numbers by making sure they are balanced on either side of the reaction.

You've read 0 of your 0 free revision notes

Get unlimited access

to absolutely everything:

Downloadable PDFs
Unlimited Revision Notes
Topic Questions
Past Papers
Model Answers
Videos (Maths and Science)

Join the 100,000+ Students that ❤️ Save My Exams

the (exam) results speak for themselves:

Next topic

Did this page help you?

Decay Equations (Oxford AQA IGCSE Physics)

Revision Note

Decay Equations

Decay equations involving alpha particles

Worked Example

Exam Tip

Decay equations involving beta particles

Worked Example

Exam Tip

You've read 0 of your 0 free revision notes

Get unlimited access

Join the 100,000+ Students that ❤️ Save My Exams

Author: Caroline Carroll