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Topic 7. 2 Radioactive Decay

Topic 7. 2 Radioactive Decay . These notes were typed in association with Physics for use with the IB Diploma Programme by Michael Dickinson For further reading and explanation see: Physics, Tsokos (purple): Ch 6.2 Physics, Giancoli (mountain): Ch 30.

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Topic 7. 2 Radioactive Decay

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  1. Topic 7. 2 Radioactive Decay These notes were typed in association with Physics for use with the IB Diploma Programme by Michael Dickinson For further reading and explanation see: Physics, Tsokos (purple): Ch 6.2 Physics, Giancoli (mountain): Ch 30

  2. 7.2.1 Describe the phenomenon of natural radioactive decay. • Certain isotope’s nuclides are said to be unstable – that is, the strong nuclear force does not bind the nucleus together indefinitely and it eventually breaks apart. • Radioactive decay – the process of these unstable nuclides breaking apart. • These unstable nuclides are said to be radioactive. • Natural radioactive decay (natural transmutation) – the break down and change of radioactive elements to change into a different element.

  3. 7.2.1 Describe the phenomenon of natural radioactive decay. Three types of decay • Alpha decay • Beta decay • Gamma Radiation • During alpha and beta decay, the radioactive nuclide changes into one of a different atomic number. This is therefore a different element. This change is called natural transmutation.

  4. 7.2.1 Describe the phenomenon of natural radioactive decay. Alpha Decay (α) • An unstable nuclide emits an alpha particle to try and become more stable. • Alpha particle – (2protons and 2neutrons) • Nucleus of a helium atom • Alpha decay generally occurs in very large nuclides. (lead) • Larger nucleus means more repulsive Coulomb force acting between the protons, spans the entire nucleus • Strong force only acts between neighboring nucleons. • If coulomb force becomes too big then the strong force is no longer able to hold nucleus together.

  5. 7.2.1 Describe the phenomenon of natural radioactive decay. Let’s look at radium – 222 (atomic number 88) Ra -222 – Parent nucleus • Z = 88 • N = 134 α – alpha particle • Z = 2 • N = 2 Rn – Daughter Nucleus • Z = 86 • N = 134

  6. 7.2.1 Describe the phenomenon of natural radioactive decay. Beta Decay (β) – is an electron • An unstable nuclide emits and beta particle to try and become more stable. • Emits an electron from the nucleus. • Electrons have a mass number of 0 and atomic number -1. • Symbol - ****Draw on board****

  7. 7.2.1 Describe the phenomenon of natural radioactive decay. Beta Decay (β) – is an electron • A neutron in the nucleus changes into a proton, and electron, β, and an almost undetectable particle called an antineutrino. v (with a line) • The elctron and the antineutrino are emitted from the nucleus at very high speed. • Since the number of nucleons remains the same, the mass number does not change. • The number of protons and therefore the atomic number Z, increases by 1

  8. 7.2.1 Describe the phenomenon of natural radioactive decay. Let’s look at Iodine – 131 (atomic number 53) I – 131 – Parent nucleus • Z = 53 • N = 78 Xe – 131 – Daughter Nucleus • Z = 54 • N = 77

  9. 7.2.1 Describe the phenomenon of natural radioactive decay. Gamma Radiation (γ) • After alpha or beta emission, the daughter nucleus is left in an “excited state”. The protons and neutrons reorganize themselves in an attempt to become more stable. • As they do this they lose energy. This energy is emitted from the nucleus as a pulse of gamma radiation • This energy emission is a little like the energy emitted from an atom as an electron drops to a lower energy state. • However, the energy levels oa a nucleus are much wider than that.

  10. 7.2.1 Describe the phenomenon of natural radioactive decay. Gamma Radiation (γ) • Where an atom emits radiation in the order of a few eV, the nucleus emits radiation in the range of a few keV, or a few MeV

  11. 7.2.2 Describe the properties of alpha (α) and beta (β) particles and gamma (γ) radiation. Alpha (α) • Helium nucleus • +2 charge • Mass: 4u(7350 x me • Strong ionizing ablility • Stopped by a sheet of thick paper or card or by the skin. • Travels a few cm in air • Effect in an electric field ***See board*** • Effect in an magnetic field ***See board***

  12. 7.2.2 Describe the properties of alpha (α) and beta (β) particles and gamma (γ) radiation. Beta (β) • High speed electron • -1 charge • Mass: 1/1800u • Weak ionizing ability • Stopped by a few mm of aluminum or other metals. Travels up to a meter in air. • Effect in an electric field ***See board*** • Effect in an magnetic field ***See board***

  13. 7.2.2 Describe the properties of alpha (α) and beta (β) particles and gamma (γ) radiation. Gamma (γ) • Electromagnetic Wave • 0 • Mass: 0u • Very weak ionizing ability • Never completely stopped although reduced by thick concrete or lead. • Effect in an electric field ***See board*** • Effect in an magnetic field ***See board***

  14. 7.2.2 Describe the properties of alpha (α) and beta (β) particles and gamma (γ) radiation. Decay Series • Parent nuclide don’t always decay into a stable daughter nucleus. The daughter nucleus then needs become the parent and decay again, producing another daughter. • This will continue until there is a stable nuclide.

  15. 7.2.3 Describe the ionizing properties of alpha (α) and beta (β) particles and gamma (γ) radiation. 7.2.4 – Outline the biological effects of ionizing radiation. • Ion is a charged atom. Atoms become ionized by gaining or losing electrons. • Ionizing radiations – radiation that has the ability to strip away electrons. • Can damage or destroy cells. • Can alter the chemical information in cells. • Can cause mutations and/or cancer. • The ionization effects of radiation can be used to detect and identify the different forms of radiation.

  16. 7.2.5 Explain why some nuclei are stable while others are unstable.

  17. 7.2.5 Explain why some nuclei are stable while others are unstable. • Two interactions inside the nucleus. • Coulomb, electrostatic force and Strong Nuclear Force. • Very fine balance must be maintained to stay stable. • Neutrons help to increase the nucleus size and keep protons further apart to reduce the coulomb repulsive forces. • There has to be just the right ratio of neutrons to protons. • If it’s not just right the strong force is reduced the nucleus becomes unstable

  18. 7.2.5 Explain why some nuclei are stable while others are unstable. • This graph shows the relationship between neutrons and protons. • Stable nuclides – Z < 20 • Protons and neutrons are about equal • Above 20 the nuclides have more neutrons than protons.

  19. 7.2.5 Explain why some nuclei are stable while others are unstable. • Nuclides above the stability line have too many neutrons • Beta minus (electron emission) • Nuclides below the stability line have too few neutrons • Beta plus (positron emission) • Positron is same mass and size charge as electron only positive. • Larger unstable nuclides decay by alpha emission. • Above Z = 83

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