SASP – Radioactivity Karen Fisher – Helena Romanes School

1. SASP – RadioactivityKaren Fisher – Helena Romanes School 27th May 2010

2. Learning Outcomes • Provide evidence for the structure of atoms • Explain radioactivity in terms of the instability of nuclei • Describe properties of alpha, beta and gamma radiation • State and use units of activity and of radiation dose • Interpret and use nuclear equations, A and Z, isotopes • Teach ‘How Science Works’ skills through radioactivity • Appreciate why teaching should start with macroscopic phenomena before moving to microscopic descriptions and explanations • Use a range of models and examples to illustrate radioactive phenomena.

3. Plan

4. What do we need to know about radioactivity? • In groups, sort statements into topics/year groups • There are some gaps! • How do ideas progress across KS4 & Post-16? • Where do you feel confident/what looks like the biggest challenge? • 10 minutes!

5. What makes teaching radioactivity difficult? Conceptual Difficulties • Too small to see • Abstract ideas Teacher concerns • What is safe? • Handling sources Student perceptions • Radioactivity is bad • Nuclear weapons/pollution

6. Conceptual difficulties Everything is made of atoms Atoms are almost unimaginably small – you can’t see them even with a really good microscope because they are smaller than the wavelength of light. An atom is almost entirely empty space with nearly all it’s mass in a tiny central nucleus. This tiny central nucleus is made up of even smaller bits – these do stuff we can term radioactivity Richard Feynman Stylised lithium atom Electron micrograph of carbon atoms

7. Addressing conceptual difficulties • Research shows mid and lower ability students find the particle model of matter difficult. • So introducing radioactivity in terms of atomic and nuclear structure is unhelpful! • Start from the phenomena you can demonstrate, e.g. effects getting smaller with distance from source or which materials radiation can and can’t penetrate. • Models of microscopic processes can help students develop understanding but may also add to misconceptions – important that students question the model.

8. ‘Radiation is bad’ • Students (and the population in general) perceive radiation as a bad thing: • Undetectable by human senses • Serious consequences • Cancers (time delayed) • Contamination (long lasting) • Unaware of background radiation • Media scares • Secrecy – industrial, military and political interests

9. What do you think of radiation?

10. Addressing fears… • Consider the concepts you use to teach about radioactivity. • Medical Physics; IoP Inside Story site is excellent - http://www.insidestory.iop.org/insidestory_flash1.html • Other uses of radioactivity: industry, archaeology, smoke detectors • Nuclear electricity – how do fission reactors work, might fusion be a future energy source • But students are interested in nuclear weapons, nuclear waste and the stories about weapons proliferation and assassinations with Po-210 that they here in the media

11. Background Radioactivity • Many students are unaware that radiation occurs naturally around us all the time. • The nucleonica site is a useful resource: http://www.nucleonica.net/naturalra.aspx

12. Teacher concerns • What practical work can I do? • How do I handle sources to keep risk to my students and myself to a minimum? • When can students handle sources? • What are the legal requirements? • Where can I get more help?

13. Sources of support • Your school will have a radiation protection supervisor – they will have been on external training and be able to explain safe practice to you. • They will be responsible for checking the sources and ensuring protocols are followed. • An RPS course is not expensive and is only one day – but it does not focus on classroom practice. • www.practicalphysics.org – Atoms and nuclei • IoP Teaching Radioactivity DVD • Teachers TV – Demonstrating Physics: Radioactivity • Several excellent ICT resources & simulations

14. Radiation Dose • Activity of a source is measured in Becquerels (Bq) • Absorbed dose is the amount of energy that cells absorb and is measured in Grays (Gy) • 1 gray = 1 Joule absorbed per kg of tissue • Dose equivalent is a measure of the possible harm from radiation and is measured in Seiverts(Sv) • UK annual average dose is 2.6mSv • Maximum allowable dose for employees is 20mSv • Diagnostic medical radiation gives an average dose of 0.37mSv • A teachers hand receives a 0.01mSv dose during a standard school demonstration

15. Radioactivity - an historical context • History of atoms, ideal example of how scientific idea evolve over time. • In 1896, Henri Becquerel discovered radioactivity when invisible rays from fluorescent salts (potassium uranyl sulfate) were detected by photographic film. • Research carried out my Marie and Pierre Curie, discovery of Polonium and Radium • Six experiments that changed the world

16. Rutherford Scattering • Before radioactivity could be explained the structure of the atom needed to be understood A cosmic onion RSCL clip http://www-outreach.phy.cam.ac.uk/camphy/nucleus/nucleus1_1.htm

19. ‘Nucleons’ (protons and neutrons) are held together by the strong force.

21. Radioactive decay • Radioactivity is a random process – this means the chance of any particular atom decaying is constant with time. • We can’t make predictions for individual atoms. • However, over large numbers of atoms we can identify patterns because of the statistics involved. • This allows us to talk about half-life for a radioactive isotope, which can be modelled in a number of ways; • Dice • Drawing Pins • Coins

22. Data from drawing pins Original data

24. Mathematical model of decay • Each nucleus in an isotope has a certain chance of decaying in a unit of time. • This is called the decay constant (λ) and has units of s-1 • The activity (A) of a sample is a measure of how many atoms decay each second and has units of Becquerels (Bq) also dimensionally s-1 • A = -λN • Half-life and decay constant are related by the equation • t1/2 = ln2/λ

25. Mathematical model of decay Equation of line: N = N0 e-λt

26. Nuclear Stability A nucleus can only be stable if there is a balance between the repulsive (coulombic) force and the attractive (strong) force. http://www.iop.org/activity/education/Teaching_Resources/Teaching%20Advanced%20Physics/page_8325.html

28. More on alpha, beta and gamma • Alpha decay • Beta decay

29. Cloud Chamber Evidence Alpha Particle Tracks