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RADIOACTIVE DECAY NCCS 1.1.4

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1 RADIOACTIVE DECAY NCCS 1.1.4
UNIT 1 ATOMIC STRUCTURE RADIOACTIVE DECAY NCCS 1.1.4

2 Radioactive Decay Radioactive decay is the spontaneous disintegration of a nucleus into a slightly lighter nucleus, accompanied by emission of particles, electromagnetic radiation, or both. Nuclear radiation is particles or electromagnetic radiation emitted from the nucleus during radioactive decay. An unstable nucleus that undergoes radioactive decay is a radioactive nuclide. All of the nuclides beyond atomic number 83 are unstable and thus radioactive. Protons and neutrons are called nucleons. An atom is referred to as a nuclide.

3 Radioactive Nuclide Emissions
A nuclide’s type and rate of decay depend on the nucleon content and energy level of the nucleus. Below are some examples of the type of radioactive decay that can occur.

4 Types of Radioactive Decay
Alpha Emission An alpha particle (α) is two protons and two neutrons bound together and is emitted from the nucleus during some kinds of radioactive decay. Alpha emission is restricted almost entirely to very heavy nuclei.

5 Types of Radioactive Decay, continued
Beta Emission A beta particle (β) is an electron emitted from the nucleus during some kinds of radioactive decay. To decrease the number of neutrons, a neutron can be converted into a proton and an electron. The atomic number increases by one and the mass number stays the same.

6 Types of Radioactive Decay, continued
Positron Emission A positron is a particle that has the same mass as an electron, but has a positive charge, and is emitted from the nucleus during some kinds of radioactive decay. To decrease the number of protons, a proton can be converted into a neutron by emitting a positron. The atomic number decreases by one and the mass number stays the same. SUPPLEMENTAL INFORMATION

7 Types of Radioactive Decay, continued
Electron Capture In electron capture, an inner orbital electron is captured by the nucleus of its own atom. To increase the number of neutrons, an inner orbital electron combines with a proton to form a neutron. The atomic number decreases by one and the mass number stays the same. SUPPLEMENTAL INFORMATION

8 Types of Radioactive Decay, continued
Gamma Emission Gamma rays () are high-energy electromagnetic waves emitted from a nucleus as it changes from an excited state to a ground energy state.

9 Comparing Alpha, Beta and Gamma Particles

10 NUCLEAR REACTION PROBLEM
What type of particle is emitted? Identify the product that balances the following nuclear reaction.

11 Nuclear Reactions, continued
This is an alpha emission type of reaction mass number: 212 − 4 = atomic number: 84 − 2 = 82 2. The nuclide has a mass number of 208 and an atomic number of 82, 3. The balanced nuclear equation is

12 Half-Life Half-life, t1/2, is the time required for half the atoms of a radioactive nuclide to decay. Each radioactive nuclide has its own half-life. More-stable nuclides decay slowly and have longer half-lives.

13 Potassium-40 Half-Life

14 Rate of Decay

15 Half-Life, continued Given: original mass of phosphorus-32 = 4.0 mg
Sample Problem B Phosphorus-32 has a half-life of 14.3 days. How many milligrams of phosphorus-32 remain after 57.2 days if you start with 4.0 mg of the isotope? Sample Problem B Solution Given: original mass of phosphorus-32 = 4.0 mg half-life of phosphorus-32 = 14.3 days time elapsed = 57.2 days Unknown: mass of phosphorus-32 remaining after 57.2 days

16 Half-Life, continued Solution: Step 1: find number of half lives
Step 2:find amount of phosphorus remaining after time has lapsed Step 1: days = 4 half lives 14.3 days Step 2: 4 mg x ½ x ½ x ½ x ½ = .25 mg OR 4 mg (1/2) 4 = .25 mg FORMULA: (original amount of substance) x (1/2 life) (number of ½ lifes)

17 FISSION Fission is a reaction when the nucleus of an atom, having captured a neutron, splits into two or more nuclei, and in so doing, releases a significant amount of energy as well as more neutrons. These neutrons then go on to split more nuclei and a chain reaction takes place.

18 FUSION Fusion is a process where nuclei collide and join together to form a heavier atom, usually deuterium and tritium. When this happens a considerable amount of energy gets released at extremely high temperatures: nearly 150 million degrees Celsius. At extreme temperatures, electrons are separated from nuclei and a gas becomes a plasma—a hot, electrically charged gas.

19 FISSION VS FUSION SUPPLEMENTAL INFORMATION Definition
Fission is the splitting of a large atom into two or more smaller ones. Fusion is the fusing of two or more lighter atoms into a larger one. Natural occurrence of the process Fission reaction does not normally occur in nature. Fusion occurs in stars, such as the sun. Byproducts of the reaction Fission produces many highly radioactive particles. Few radioactive particles are produced by fusion reaction, but if a fission "trigger" is used, radioactive particles will result from that. Conditions Critical mass of the substance and high-speed neutrons are required. High density, high temperature environment is required. Energy Requirement Takes little energy to split two atoms in a fission reaction. Extremely high energy is required to bring two or more protons close enough that nuclear forces overcome their electrostatic repulsion. Energy Released The energy released by fission is a million times greater than that released in chemical reactions, but lower than the energy released by nuclear fusion. The energy released by fusion is three to four times greater than the energy released by fission. Nuclear weapon One class of nuclear weapon is a fission bomb, also known as an atomic bomb or atom bomb. One class of nuclear weapon is the hydrogen bomb, which uses a fission reaction to "trigger" a fusion reaction. Energy production Fission is used in nuclear power plants. Fusion is an experimental technology for producing power. Fuel Uranium is the primary fuel used in power plants. Hydrogen isotopes (Deuterium and Tritium) are the primary fuel used in experimental fusion power plants. SUPPLEMENTAL INFORMATION

20 Mass Stability The difference between the mass of an atom and the sum of the masses of its protons, neutrons, and electrons is called the mass defect. Nuclear Binding Energy According to Albert Einstein’s equation E = mc2, mass can be converted to energy, and energy to mass. This is the nuclear binding energy, the energy released when a nucleus is formed from nucleons. The nuclear binding energy is a measure of the stability of a nucleus. The binding energy per nucleon is the binding energy of the nucleus divided by the number of nucleons it contains Elements with intermediate atomic masses have the greatest binding energies per nucleon and are therefore the most stable. The elements with an atomic number of 82 or less have stable isotopes SUPPLEMENTAL INFORMATION

21 Band of Stability Alpha particle The graph has a plot of stable elements, this part is called band of stability. At the higher end of the band of stability lies alpha decay, below is positron emission or electron capture, above is beta emissions and elements beyond the atomic mass of 83 are unstable radioactive elements. SUPPLEMENTAL INFORMATION

22 SUPPLEMENTAL INFORMATION
Alpha particle Alpha decay is located at the top of the plotted line, because the alpha decay decreases the mass number of the element in order to keep the isotope stable. This is done by using the element helium (He). An unstable isotope's protons are decreased by 2 and its neutrons are decreased by 4, and because the isotope was originally unstable before it went through alpha decay, the elements are still considered unstable. SUPPLEMENTAL INFORMATION

23 Beta decay accepts protons so it changes the amount of protons and neutrons. the number of protons increase while neutrons decrease. To make things easier to understand think of the ratio of the isotope: there are too many neutrons compared to the number of protons therefore it is above the band of stability. SUPPLEMENTAL INFORMATION

24 Positron emission and electron capture is when the isotope gains more neutrons. Positron emission and electron capture are below the band of stability because the ratio of the isotope has more protons than neutrons, think of it as there are too few protons for the amount of neutrons and that is why it is below the band of stability. SUPPLEMENTAL INFORMATION

25 The band of stability can be explained by the relationship between the nuclear force and the electrostatic forces between protons. Stable nuclei tend to have even numbers of nucleons. This is referred to as the even-odd rule According to the nuclear shell model, nucleons exist in different energy levels, or shells, in the nucleus. The numbers of nucleons that represent completed nuclear energy levels—2, 8, 20, 28, 50, 82, and 126—are called magic numbers. SUPPLEMENTAL INFORMATION

26 EVEN ODD RULE AND MAGIC NUMBERS
Nuclides containing odd numbers of both protons and neutrons are the least stable means more radioactive. Nuclides containing even numbers of both protons and neutrons are most stable means less radioactive. Nuclides contain odd numbers of protons and even numbers of neutrons are less stable than nuclides containing even numbers of protons and odd numbers of neutrons. In general, nuclear stability is greater for nuclides containing even numbers of protons and neutrons or both SUPPLEMENTAL INFORMATION

27 MAGIC NUMBERS Magic numbers are natural occurrences in isotopes and are stable. Below is a list of numbers of protons and neutrons; isotopes that have these numbers occurring in either the proton or neutron are stable. In some cases there the isotopes can consist of magic numbers for both protons and neutrons; these would be called double magic numbers. But the double numbers only occur for isotopes that are heavier, because the repulsion of the forces between the protons.   The magic numbers: proton: 2, 8, 20, 28, 50, 82, 114 neutron: 2, 8, 20, 28, 50, 82, 126, 184 Also, there is the concept that isotopes consisting a combination of even-even, even-odd, odd-even, and odd-odd are all stable. There are more nuclides that have a combination of even-even than odd-odd. (See chart.) SUPPLEMENTAL INFORMATION

28 Half-Lives of Some Radioactive Isotopes
SUPPLEMENTAL INFORMATION

29 Decay Series A decay series is a series of radioactive nuclides produced by successive radioactive decay until a stable nuclide is reached. The heaviest nuclide of each decay series is called the parent nuclide. The nuclides produced by the decay of the parent nuclides are called daughter nuclides. SUPPLEMENTAL INFORMATION

30 Uranium-238 Decay SUPPLEMENTAL INFORMATION

31 Artificial Transmutations
Artificial radioactive nuclides are radioactive nuclides not found naturally on Earth. They are made by artificial transmutations, bombardment of nuclei with charged and uncharged particles. Transuranium elements are elements with more than 92 protons in their nuclei. Artificial transmutations are used to produce the transuranium elements. SUPPLEMENTAL INFORMATION

32 Radiation Exposure Nuclear radiation can transfer the energy from nuclear decay to the electrons of atoms or molecules and cause ionization. The roentgen (R) is a unit used to measure nuclear radiation exposure; it is equal to the amount of gamma and X ray radiation that produces 2  109 ion pairs when it passes through 1 cm3 of dry air. A rem is a unit used to measure the dose of any type of ionizing radiation that factors in the effect that the radiation has on human tissue. SUPPLEMENTAL INFORMATION


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