Radioactivity

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    Created by
    Connor McKeown

    Cards (102)

    • What is the structure of an atom?
      An atom consists of a positively charged nucleus surrounded by negatively charged electrons.
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    • What are the components of the nucleus of an atom?
      The nucleus is made of positive protons and neutral neutrons.
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    • How do electrons orbit the nucleus?
      Electrons orbit the nucleus at different fixed distances.
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    • How does the size of the nuclear radius compare to the size of the atom?
      The nuclear radius is much smaller than the radius of the atom.
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    • Where does most of the mass of an atom lie?
      Almost all the mass of the atom lies in the nucleus.
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    • What are the relative masses and charges of subatomic particles?
      • Proton: Relative Mass = 1, Relative Charge = +1
      • Neutron: Relative Mass = 1, Relative Charge = 0
      • Electron: Relative Mass = 0.0005, Relative Charge = -1
      • Positron: Relative Mass = 0.0005, Relative Charge = +1
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    • What is the approximate size of an atom?
      The size of an atom is approximately \(0.1 \text{ nanometers}\) or \(10^{-10} \text{ meters}\).
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    • What defines isotopes of an element?
      Isotopes are atoms of the same element with the same number of protons but different numbers of neutrons.
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    • What is an example of isotopes of carbon?

      Carbon-12, Carbon-13, and Carbon-14 are examples of isotopes of carbon.
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    • What do the symbols \(X\), \(A\), \(Z\), and \(N\) represent in isotopes?
      • \(X\): Symbol of the element
      • \(A\): Mass number (number of protons and neutrons)
      • \(Z\): Proton number
      • \(N\): Charge of the atom
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    • How does the charge of a neutral atom relate to its protons and electrons?
      A neutral atom has the same number of electrons and protons, resulting in no overall charge.
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    • What happens when electrons change orbits in an atom?
      When electrons move to a higher orbit, the atom absorbs EM radiation; when they fall to a lower orbit, the atom emits EM radiation.
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    • What can happen if an electron gains enough energy?
      If an electron gains enough energy, it can leave the atom and form an ion.
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    • What is the nature of radioactive decay?
      Decay occurs in a random process.
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    • What are the different forms of radioactive decay?
      • Alpha decay: Helium nucleus, highly ionising, weakly penetrating
      • Beta Minus decay: Electron, medium ionising, medium penetration
      • Beta Plus decay: Positron, medium ionising, medium penetration
      • Gamma decay: Electromagnetic radiation, low ionising, highly penetrating
      • Neutron decay
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    • What is background radiation?
      Background radiation is weak radiation that can be detected from natural or external sources.
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    • What are some examples of background radiation?
      • Cosmic rays
      • Radiation from underground rocks
      • Nuclear fallout
      • Medical rays
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    • How is radioactivity measured?
      • Photographic film: Darkens with radiation exposure
      • Geiger-Muller Tube: Detects radiation and produces clicks based on radiation frequency
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    • Who proposed that everything was made of atoms in 1800?
      Dalton proposed that everything was made of atoms in 1800.
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    • What did JJ Thomson discover in 1897?
      JJ Thomson discovered the electron in 1897.
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    • What was the Plum Pudding Model?
      • Proposed by JJ Thomson
      • Atoms consist of a positive "pudding" with negative electrons dispersed throughout
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    • What did Rutherford realize about the atom in 1911?
      Rutherford realized that most of the atom was empty space.
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    • What experiment did Geiger and Marsden conduct?
      Geiger and Marsden conducted the Gold Foil Experiment.
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    • What were the findings of the Gold Foil Experiment?
      • Most particles went straight through, indicating empty space
      • Some alpha particles were slightly deflected, indicating a positive nucleus
      • Few alpha particles were deflected by >90°, indicating that the nucleus contains most of the mass
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    • What model did Bohr produce in 1913?
      Bohr produced the final model of the atom in 1913.
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    • What is Beta-Minus Decay?
      • A neutron becomes a proton
      • An electron is released
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    • What is Beta-Plus Decay?
      • A proton becomes a neutron
      • A positron is released
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    • What does the equation \(Z_X^A \rightarrow Z'_Y^{A'} + \text{decay particle}\) represent?
      This equation represents a general decay process in nuclear reactions.
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    • What is Alpha decay?
      • An alpha particle is equivalent to a helium nucleus
      • The equation is \(Z_X^A \rightarrow Z-2_Y^{A-4} + \alpha\)
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    • What is Beta decay?
      • A beta particle is an electron emitted from the nucleus
      • The equation is \(Z_X^A \rightarrow Y_{Z+1}^A + e^{-} + \bar{\nu}_e\)
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    • What is Gamma decay?
      • A gamma ray is electromagnetic radiation
      • The equation is \(Z_X^A \rightarrow Z'_Y^{A'} + \gamma\)
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    • What happens to nuclei after decay?
      Nuclei after decay often have excess energy, which they release as gamma radiation during nuclear arrangement.
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    • What is activity in the context of radioactivity?
      Activity is the number of decays in a sample per second.
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    • How does activity change over time?
      Activity decreases exponentially over time.
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    • What are the units of activity?
      The units of activity are Becquerel (Bq).
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    • What is half-life in the context of radioactivity?
      • The half-life of an isotope is the time taken for half the nuclei in a sample to decay
      • It is also the time taken for the activity of a sample to decay by half
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    • Why can't the decay of a single nucleus be predicted?
      The decay of a single nucleus cannot be predicted, but the half-life allows for predictions about a large number of nuclei.
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    • How do you calculate net decline of radioactive nuclei after X half-lives?
      • Work out the ratio of net decline:
      • \( \text{net decline} = \frac{\text{initial number} - \text{number after X half-lives}}{\text{initial number}} \)
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    • If there were initially 80 nuclei with a half-life of 15 minutes, what is the net decline after 3 half-lives?
      The net decline is \( \frac{80 - 10}{80} = \frac{7}{8} \) or 87.5%.
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    • What are some uses of radioactivity?
      • Smoke alarms: Americium as an alpha emitter
      • Irradiating food: Gamma rays kill bacteria
      • Sterilisation of equipment: Gamma radiation kills microbes
      • Tracing and gauging thickness: Beta radiation measures thickness
      • Diagnosis and treatment of cancer: Gamma emitters reveal tumors and treat cancer
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