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Learning Outcomes Historical outline of radioactivity: work of Becquerel (discovery of radiation from uranium salts); Marie and Pierre Curie (discovery of polonium and radium). Widespread occurrence of radioactivity.
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Antoine Henri Becquerel In 1896, while investigating uranium salts, Becquerel accidentally discovered radioactivity. Becquerel found that the photographic plates were fully exposed when in contact with radioactive salt.
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Marie Curie developed a theory of radioactivity techniques for isolating radioactive isotopes, and discovered two new elements, Polonium and Radium
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Natural Radiation comes from Sources in the earth that contain radioactive isotopes. Sources from space in the form of cosmic rays Sources in the atmosphere, particularly from Radon gas that is released from the Earth's crust. About 15% of background radiation comes from medical X-rays and nuclear medicine. About 3% of background radiation comes from other man-made sources such as: nuclear testing, power plants, and smoke detectors.
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Pierre Curie Pierre discovered nuclear energy, by identifying the continuous emission of heat from Radium particles. He also investigated the radiation emissions of radioactive substances, which lead to the discovery of Alpha, Beta and Gamma radiation.
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Learning Outcomes Alpha, beta and gamma radiation (nature and penetrating ability).One example each of: an α-emitter, e.g. 241 Am a β-emitter, e.g. 14 C a γ-emitter, e.g. 60 Co.
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Radioactivity Is the spontaneous breaking up of unstable nuclei with the emission of one or more types of radiation There are three types alpha, beta and gamma
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Alpha particle
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Alpha Made of 2 protons + 2 neutrons Helium nucleus From unstable nuclei Low penetration; stopped by a sheet of paper Americum-241 [used in smoke detectors] emits alpha particles
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Alpha particle
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Smoke detector
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Beta Electrons Formed when a neutron decays into a proton and an electron Penetrate 5mm of aluminum Carbon-14 used in carbon-dating emits beta particles
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Neutron decay
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Carbon 14
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Learning Outcomes Uses of radioisotopes (three examples). 14 C age determination (calculations not required). 60 Co for cancer treatment. Food irradiation.
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The animation below shows the decay of a radioactive sample of Carbon-14 to stable Nitrogen by the emission of beta particles.
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Carbon-14 decays to nitrogen-14
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Take in Carbon-14 The percentage of carbon-14 in all of these living things is the same as the percentage of carbon- 14 in the atmosphere.
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Death The carbon-14 within every once-living thing will someday turn back into nitrogen-14
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Carbon-14 detection
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Gamma High energy electromagnetic radiation Not deflected by magnetic or electric fields Only stopped by several cms of lead. Cobalt-60 [used to treat cancer] emits gamma rays
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Gamma Rays
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Learning Outcomes Demonstration of properties –detection and penetrating power
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Penetration
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Penetration 2
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Learning Outcomes Distinction between chemical reaction and nuclear reaction (simple equations required –confine examples to alpha and beta emissions).
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Nuclear reactions Emission of radioactive radiation In a nuclear reaction the nucleus forms a new element,
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Loss of an alpha particle Radium-226 Radon-222 + alpha particle 226 88 Ra 222 86 Rn + 4 2 He Mass decreases by 4 [226 222] Atomic number decreases by 2 [88 86]
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Beta loss Carbon-14 nitrogen-14 + beta 14 6 C 14 7 N + 0 -1 e Mass number stays the same Atomic number increases by 1
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Learning Outcomes Radioisotopes. Half-life (non-mathematical treatment). Uses of radioisotopes (three examples).
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Radioisotopes A Radioisotope (radionuclide) is an atom with an unstable nucleus.
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Transmutation Change of one element into another Rutherford confirmed the artificial transmutation of nitrogen. Alpha particles were allowed to pass through nitrogen gas; when one struck a nitrogen nucleus, a hydrogen nucleus was ejected, and an oxygen nucleus formed.
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Half life Time taken for half of the nuclei in any given sample to decay
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uses Medical—.gamma rays kill cancerous cells and sterilises equipment Archaeological—after a living thing dies the amount of C-14 decreases. Used to determine the age of a plant/animal Food—gamma rays kill disease causing organisms
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