Calculating Radioactive Decay (OCR Gateway GCSE Physics)

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Calculating Radioactive Decay (HT only)

  • To calculate the half-life of a sample, the procedure is:
    • Measure the initial activity, A0, of the sample
    • Determine the half-life of this original activity
    • Measure how the activity changes with time

  • The time taken for the activity to decrease to half its original value is the half-life
  • Half-life can be shown clearly on a graph

Half-life Graph, downloadable IGCSE & GCSE Physics revision notes

The diagram shows how the activity of a radioactive sample changes over time. Each time the original activity halves, another half-life has passed

  • The time it takes for the activity of the sample to decrease from 100 % to 50 % is the half-life
  • It is the same length of time as it would take to decrease from 50 % activity to 25 % activity
  • The half-life is constant for a particular isotope

Worked example

The radioisotope technetium is used extensively in medicine. The graph below shows how the activity of a sample varies with time.Worked Example - Half Life Curve, downloadable AS & A Level Physics revision notesDetermine the half-life of this material.

Step 1: Draw lines on the graph to determine the time it takes for technetium to drop to half of its original activity

Worked Example - Half Life Curve Ans a, downloadable AS & A Level Physics revision notes

Step 2: Read the half-life from the graph

    • In the diagram above the initial activity, A0, is 8 × 107 Bq
    • The time taken to decrease to 4 × 107 Bq, or ½ A0, is 6 hours
    • The time taken to decrease to 2 × 107 Bq is 6 more hours
    • The time taken to decrease to 1 × 107 Bq is 6 more hours
    • Therefore, the half-life of this isotope is 6 hours

Worked example

A particular radioactive sample contains 2 million un-decayed atoms. After a year, there is only 500 000 atoms left un-decayed.

What is the half-life of this material?

Step 1: Calculate how many times the number of un-decayed atoms has halved

    • There were 2 000 000 atoms to start with
    • 1 000 000 atoms would remain after 1 half-life
    • 500 000 atoms would remain after 2 half-lives
    • Therefore, the sample has undergone 2 half-lives

Step 2: Divide the time period by the number of half-lives

    • The time period is a year
    • The number of half-lives is 2

1 space year space rightwards arrow with 1 space half space life on top space 6 space months space rightwards arrow with 2 space half space lives on top space 3 space months

    • 1 year divided by 4 (22) is a quarter of a year or 3 months
    • Therefore, the half-life of the sample is 3 months

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Joanna

Author: Joanna

Expertise: Physics

Joanna obtained her undergraduate degree in Natural Sciences from Cambridge University and completed her MSc in Education at Loughborough University. After a decade of teaching and leading the physics department in a high-performing academic school, Joanna now mentors new teachers and is currently studying part-time for her PhD at Leicester University. Her passions are helping students and learning about cool physics, so creating brilliant resources to help with exam preparation is her dream job!