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PHYSICS – Radioactive Decay

PHYSICS – Radioactive Decay. LEARNING OBJECTIVES. Radioactive decay. Radioactive decay. Radioactive decay is a random event –

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PHYSICS – Radioactive Decay

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  1. PHYSICS – Radioactive Decay

  2. LEARNING OBJECTIVES

  3. Radioactive decay

  4. Radioactive decay Radioactive decay is a random event – The unstable nuclei in some materials will break up, or disintegrate. It is impossible to predict exactly which nuclei will decay. This disintegration of the nuclei is called radioactive decay.

  5. Radioactive decay When a nucleus decays it becomes more stable, but the loss of protons and neutrons makes it a different element. The original nucleus is called the parent nucleus.The nucleus formed is known as thedaughter nucleus. Both are called the decay products. Radioactive decay is a random event – The unstable nuclei in some materials will break up, or disintegrate. It is impossible to predict exactly which nuclei will decay. This disintegration of the nuclei is called radioactive decay.

  6. Radioactive decay When a nucleus decays it becomes more stable, but the loss of protons and neutrons makes it a different element. The original nucleus is called the parent nucleus.The nucleus formed is known as thedaughter nucleus. Both are called the decay products. Radioactive decay is a random event – The unstable nuclei in some materials will break up, or disintegrate. It is impossible to predict exactly which nuclei will decay. This disintegration of the nuclei is called radioactive decay. Mass number (nucleon number) = total number of nucleons (protons + neutrons) in the nucleus 4 He 2

  7. Radioactive decay When a nucleus decays it becomes more stable, but the loss of protons and neutrons makes it a different element. The original nucleus is called the parent nucleus.The nucleus formed is known as thedaughter nucleus. Both are called the decay products. Radioactive decay is a random event – The unstable nuclei in some materials will break up, or disintegrate. It is impossible to predict exactly which nuclei will decay. This disintegration of the nuclei is called radioactive decay. Mass number (nucleon number) = total number of nucleons (protons + neutrons) in the nucleus 4 He 2 Atomic number (proton number) also shows the relative charge on the nucleus.

  8. Radioactive decay When a nucleus decays it becomes more stable, but the loss of protons and neutrons makes it a different element. The original nucleus is called the parent nucleus.The nucleus formed is known as thedaughter nucleus. Both are called the decay products. Radioactive decay is a random event – The unstable nuclei in some materials will break up, or disintegrate. It is impossible to predict exactly which nuclei will decay. This disintegration of the nuclei is called radioactive decay. + + Mass number (nucleon number) = total number of nucleons (protons + neutrons) in the nucleus Alpha particle 4 4 He α 2 2 Atomic number (proton number) also shows the relative charge on the nucleus. Four nucleons, relative charge of +2

  9. Radioactive decay When a nucleus decays it becomes more stable, but the loss of protons and neutrons makes it a different element. The original nucleus is called the parent nucleus.The nucleus formed is known as thedaughter nucleus. Both are called the decay products. Radioactive decay is a random event – The unstable nuclei in some materials will break up, or disintegrate. It is impossible to predict exactly which nuclei will decay. This disintegration of the nuclei is called radioactive decay. + + Mass number (nucleon number) = total number of nucleons (protons + neutrons) in the nucleus Beta particle Alpha particle 4 0 4 He α β 2 2 -1 Atomic number (proton number) also shows the relative charge on the nucleus. Four nucleons, relative charge of +2 An electron, charge of -1

  10. Radioactive decay Use equations involving nuclide notation to represent changes in the composition of the nucleus when particles are emitted

  11. Radioactive decay Use equations involving nuclide notation to represent changes in the composition of the nucleus when particles are emitted Let’s have a look at some examples!

  12. Radioactive decay When radium-226 decays, it does so by emitting an alpha particle. This means that the ‘daughter’ nucleus now has 2 protons and 2 neutrons less than it did before. We can write this as a nuclear equation. Use equations involving nuclide notation to represent changes in the composition of the nucleus when particles are emitted Let’s have a look at some examples!

  13. Radioactive decay When radium-226 decays, it does so by emitting an alpha particle. This means that the ‘daughter’ nucleus now has 2 protons and 2 neutrons less than it did before. We can write this as a nuclear equation. Use equations involving nuclide notation to represent changes in the composition of the nucleus when particles are emitted Let’s have a look at some examples! 226 222 4 + Rn Ra α 2 86 88

  14. Radioactive decay When radium-226 decays, it does so by emitting an alpha particle. This means that the ‘daughter’ nucleus now has 2 protons and 2 neutrons less than it did before. We can write this as a nuclear equation. Use equations involving nuclide notation to represent changes in the composition of the nucleus when particles are emitted Let’s have a look at some examples! 226 222 4 + Rn Ra α 2 86 88 A new element, radon, has been formed from the decay of the radium.

  15. Radioactive decay Thorium-232 also undergoes radioactive decay, again with the loss of an alpha particle (helium nucleus). Use equations involving nuclide notation to represent changes in the composition of the nucleus when particles are emitted Let’s have a look at some examples! 232 228 4 + Ra Th α 2 88 90 The element radium has been formed from the decay of the thorium.

  16. Radioactive decay Use equations involving nuclide notation to represent changes in the composition of the nucleus when particles are emitted Both examples involved alpha decay. Let’s now look at an example of beta decay

  17. Radioactive decay In beta decay, a neutron changes into a proton plus an electron. The proton stays in the nucleus and the electron leaves the atom with high energy. The mass number remains unchanged (one neutron lost, one proton gained) but the atomic number increases by one. Use equations involving nuclide notation to represent changes in the composition of the nucleus when particles are emitted Both examples involved alpha decay. Let’s now look at an example of beta decay

  18. Radioactive decay In beta decay, a neutron changes into a proton plus an electron. The proton stays in the nucleus and the electron leaves the atom with high energy. The mass number remains unchanged (one neutron lost, one proton gained) but the atomic number increases by one. Use equations involving nuclide notation to represent changes in the composition of the nucleus when particles are emitted Both examples involved alpha decay. Let’s now look at an example of beta decay 14 14 0 + N C e- -1 7 6

  19. Radioactive decay In beta decay, a neutron changes into a proton plus an electron. The proton stays in the nucleus and the electron leaves the atom with high energy. The mass number remains unchanged (one neutron lost, one proton gained) but the atomic number increases by one. Use equations involving nuclide notation to represent changes in the composition of the nucleus when particles are emitted Both examples involved alpha decay. Let’s now look at an example of beta decay 14 14 0 + N C e- -1 7 6 The element nitrogen has been formed from the betadecay of the carbon.

  20. Radioactive decay In this example of beta decay, iodine-131 emits a beta particle to become xenon. Use equations involving nuclide notation to represent changes in the composition of the nucleus when particles are emitted Both examples involved alpha decay. Let’s now look at an example of beta decay 131 131 0 + Xe I e- -1 54 53 The mass number remains unchanged, and the proton number (atomic number) increases by 1.

  21. Radioactive decay Radioactive decay is a random event – The unstable nuclei in some materials will break up, or disintegrate. It is impossible to predict exactly which nuclei will decay. This disintegration of the nuclei is called radioactive decay. Some types of nucleus are more unstable than others and decay at a faster rate.

  22. Radioactive decay Radioactive decay is a random event – The unstable nuclei in some materials will break up, or disintegrate. It is impossible to predict exactly which nuclei will decay. This disintegration of the nuclei is called radioactive decay. Some types of nucleus are more unstable than others and decay at a faster rate. 10 Days

  23. Radioactive decay Radioactive decay is a random event – The unstable nuclei in some materials will break up, or disintegrate. It is impossible to predict exactly which nuclei will decay. This disintegration of the nuclei is called radioactive decay. Some types of nucleus are more unstable than others and decay at a faster rate. 10 Days 10 Days

  24. Radioactive decay Radioactive decay is a random event – The unstable nuclei in some materials will break up, or disintegrate. It is impossible to predict exactly which nuclei will decay. This disintegration of the nuclei is called radioactive decay. Some types of nucleus are more unstable than others and decay at a faster rate. 10 Days 10 Days One half-life One half-life

  25. Radioactive decay Radioactive decay is a random event – The unstable nuclei in some materials will break up, or disintegrate. It is impossible to predict exactly which nuclei will decay. This disintegration of the nuclei is called radioactive decay. Some types of nucleus are more unstable than others and decay at a faster rate. 10 Days 10 Days One half-life One half-life HALF-LIFE is the TIME TAKEN for HALF of the radioactive atoms now present to DECAY

  26. Radioactive decay Radioactive decay is a random event – The unstable nuclei in some materials will break up, or disintegrate. It is impossible to predict exactly which nuclei will decay. This disintegration of the nuclei is called radioactive decay. Some types of nucleus are more unstable than others and decay at a faster rate.

  27. Radioactive decay Measurements taken with a GM tube. Don’t forget that you might need to subtract figures for background radiation! Radioactive decay is a random event – The unstable nuclei in some materials will break up, or disintegrate. It is impossible to predict exactly which nuclei will decay. This disintegration of the nuclei is called radioactive decay. 70 60 50 40 30 20 10 0 x Nuclei remaining Radioactive decay curve x x x x x 0 10 20 30 40 50 Days

  28. Radioactive decay Measurements taken with a GM tube. Don’t forget that you might need to subtract figures for background radiation! Radioactive decay is a random event – The unstable nuclei in some materials will break up, or disintegrate. It is impossible to predict exactly which nuclei will decay. This disintegration of the nuclei is called radioactive decay. 70 60 50 40 30 20 10 0 x Nuclei remaining Radioactive decay curve x x x x x 0 10 20 30 40 50 Days

  29. Radioactive decay Radioactive decay is a random event – The unstable nuclei in some materials will break up, or disintegrate. It is impossible to predict exactly which nuclei will decay. This disintegration of the nuclei is called radioactive decay. In the early hours of 26 April 1986 one of the four reactors at Chernobyl power station exploded. Because of the long-lived radiation in the region surrounding the former Chernobyl Nuclear Power Plant, the area won't be safe for human habitation for at least 20,000 years.

  30. Radioactive decay Radioactive decay is a random event – The unstable nuclei in some materials will break up, or disintegrate. It is impossible to predict exactly which nuclei will decay. This disintegration of the nuclei is called radioactive decay. In the early hours of 26 April 1986 one of the four reactors at Chernobyl power station exploded. In a radioactive sample, the average number of disintegrations per second is called the activity. The SI unit of activity is the becquerel (Bq). For example, 100Bq = 100 nuclei disintegrating per second. Because of the long-lived radiation in the region surrounding the former Chernobyl Nuclear Power Plant, the area won't be safe for human habitation for at least 20,000 years.

  31. Radioactive decay

  32. Radioactive decay Initial count rate = 600 counts per second.

  33. Radioactive decay Count rate falls to 200 counts per second after 25 minutes

  34. Radioactive decay If the initial count was 600, the half-life is 300 particles, which will be after 16 minutes.

  35. Radioactive decay Initial count = 600, one half life = 300, two half lives = 150

  36. Radioactive decay Initial count = 600, one half life = 300, two half lives = 150 600 25 16 150

  37. Calculate half-life from data or decay curves from which background radiation has not been subtracted Radioactive decay Supplement Every half-minute a teacher records a count rate of a radioactive substance. The background count was 3Bq. Calculate the corrected count rate and draw a graph for these results.

  38. Calculate half-life from data or decay curves from which background radiation has not been subtracted Radioactive decay Supplement Every half-minute a teacher records a count rate of a radioactive substance. The background count was 3Bq. Calculate the corrected count rate and draw a graph for these results.

  39. Calculate half-life from data or decay curves from which background radiation has not been subtracted Radioactive decay Supplement Every half-minute a teacher records a count rate of a radioactive substance. The background count was 3Bq. Calculate the corrected count rate and draw a graph for these results. Corrected count rate in Bq 50 45 40 35 30 25 20 15 10 5 0 x x x x x x x x x x 0 0.5 1.0 1.5 2.0 2.5 3.0 3.5 4.0 4.5 Time in minutes

  40. Calculate half-life from data or decay curves from which background radiation has not been subtracted Radioactive decay Supplement Every half-minute a teacher records a count rate of a radioactive substance. The background count was 3Bq. Calculate the corrected count rate and draw a graph for these results. Use your graph to estimate the half-life of the material Corrected count rate in Bq 50 45 40 35 30 25 20 15 10 5 0 x Original count = 49 x Half of original count = 24.5 x x Half-life = 1 min x x x x x x 0 0.5 1.0 1.5 2.0 2.5 3.0 3.5 4.0 4.5 Time in minutes

  41. Ionising Radiation and Living Things

  42. Ionising Radiation and Living Things Alpha,beta and gamma radiation will enter living cells and collide with molecules – these collisions cause ionisation, damaging or destroying the molecules.

  43. Ionising Radiation and Living Things Alpha,beta and gamma radiation will enter living cells and collide with molecules – these collisions cause ionisation, damaging or destroying the molecules. Lower doses cause non-fatal damage to cells, but can cause them to become cancerous, when they divide uncontrollably.

  44. Ionising Radiation and Living Things Alpha,beta and gamma radiation will enter living cells and collide with molecules – these collisions cause ionisation, damaging or destroying the molecules. Higher doses tend to kill cells completely, causing radiation sickness. Lower doses cause non-fatal damage to cells, but can cause them to become cancerous, when they divide uncontrollably.

  45. Ionising Radiation and Living Things Alpha,beta and gamma radiation will enter living cells and collide with molecules – these collisions cause ionisation, damaging or destroying the molecules. Higher doses tend to kill cells completely, causing radiation sickness. Lower doses cause non-fatal damage to cells, but can cause them to become cancerous, when they divide uncontrollably. The extent of the harmful effects depends upon two things.

  46. Ionising Radiation and Living Things Alpha,beta and gamma radiation will enter living cells and collide with molecules – these collisions cause ionisation, damaging or destroying the molecules. Higher doses tend to kill cells completely, causing radiation sickness. Lower doses cause non-fatal damage to cells, but can cause them to become cancerous, when they divide uncontrollably. The extent of the harmful effects depends upon two things. How much exposure there is to the radiation. The energy and penetration of the radiation emitted – some types are more hazardous than others.

  47. Ionising Radiation and Living Things Alpha radiation cannot penetrate through skin, so outside the body beta and gamma radiation are the most dangerous – but both of these are less ionising than alpha and so cause less damage. α β γ

  48. Ionising Radiation and Living Things α Alpha radiation cannot penetrate through skin, so outside the body beta and gamma radiation are the most dangerous – but both of these are less ionising than alpha and so cause less damage. However,if alpha particles get inside the body (ingested, breathed-in) then they can do much more damage in a very localised area because they are so strongly ionising.

  49. Ionising Radiation and Safety

  50. Ionising Radiation and Safety In the school laboratory • Handle with tongs, avoid skin contact with a source. • Keep source as far away from the body as possible. • Avoid looking directly at the source • Immediately return source to lead-lined box when not required.

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