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Chapter 24 Nuclear Reactions and Their Applications.

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Presentation on theme: "Chapter 24 Nuclear Reactions and Their Applications."— Presentation transcript:

1 Chapter 24 Nuclear Reactions and Their Applications

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3 The behavior of three types of radioactive emissions in an electric field

4 Total ATotal Z Reactants = Total ATotal Z Products
Types of Radioactive Decay: Balancing Nuclear Equations Total ATotal Z Reactants = Total ATotal Z Products Alpha decay - A decreases by 4 and Z decreases by 2. Every element heavier than Pb undergoes a decay. Beta decay - ejection of a b particle from the nucleus from the conversion of a neutron into a proton and the expulsion of 0-1b. The product nuclide will have the same Z but will be one atomic number higher. Positron decay - a positron (01b) is the antiparticle of an electron. A proton in the nucleus is converted into a neutron with the expulsion of the positron. Z remains the same but the atomic number decreases. Electron capture - a nuclear proton is converted into a neutron by the capture of an electron. Z remains the same but the atomic number decreases. Gamma emission - energy release; no change in Z or A.

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6 Sample Problem 1 Writing Equations for Nuclear Reactions PROBLEM: Write balanced equations for the following nuclear reactions: (a) Naturally occurring thorium-232 undergoes a decay. (b) Chlorine-36 undergoes electron capture.

7 Nuclear Stability and Mode of Decay
Very few stable nuclides exist with N/Z < 1. The N/Z ratio of stable nuclides gradually increases a Z increases. All nuclides with Z > 83 are unstable. Elements with an even Z usually have a larger number of stable nuclides than elements with an odd Z. Well over half the stable nuclides have both even N and even Z. Predicting the Mode of Decay Neutron-rich nuclides undergo b decay. Neutron-poor nuclides undergo positron decay or electron capture. Heavy nuclides undergo a decay.

8 A plot of neutrons vs. protons for the stable nuclides

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10 Sample Problem 2 Predicting Nuclear Stability PROBLEM: Which of the following nuclides would you predict to be stable and which radioactive? Explain. (a) 1810Ne (b) 3216S (c) Th (d) Ba

11 Sample Problem 3 Predicting the Mode of Nuclear Decay PROBLEM: Predict the nature of the nuclear change(s) each of the following radioactive nuclides is likely to undergo: (a) 125B (b) U (c) 7433As (d) La

12 The 238U decay series

13 Decay rate (A) = DN/Dt SI unit of decay is the becquerel (Bq) = 1d/s.
curie (Ci) = number of nuclei disinegrating each second in 1g of radium-226 = 3.70x1010d/s Nuclear decay is a first-order rate process. Large k means a short half-life and vice versa.

14 Decrease in the number of 14C nuclei over time

15 Sample Problem 4 Finding the Number of Radioactive Nuclei PROBLEM: Strontium-90 is a radioactive by-product of nuclear reactors that behaves biologically like calcium, the element above it in Group 2A(2). When 90Sr is ingested by mammals, it is found in their milk and eventually in the bones of those drinking the milk. If a sample of 90Sr has an activity of 1.2x1012 d/s, what are the activity and the fraction of nuclei that have decayed after 59 yr (t1/2 of 90Sr = 29 yr)

16 Radiocarbon dating for determining the age of artifacts

17 Sample Problem 5 Applying Radiocarbon Dating PROBLEM: The charred bones of a sloth in a cave in Chile represent the earliest evidence of human presence in the southern tip of South America. A sample of the bone has a specific activity of 5.22 disintegrations per minute per gram of carbon (d/min*g). If the ratio of 12C:14C in living organisms results in a specific activity of 15.3 d/min*g, how old are the bones? (t1/2 of 14C = 5730 yr)

18 The linear accelerator operated by Stanford University, California
A linear accelerator The linear accelerator operated by Stanford University, California Copyright © The McGraw-Hill Companies, Inc. Permission required for reproduction or display.

19 The cyclotron accelerator

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21 Penetrating power of radioactive emissions
Nuclear changes cause chemical changes in surrounding matter by excitation and ionization. Penetrating power is inversely related to the mass and charge of the emission.

22 Copyright © The McGraw-Hill Companies, Inc
Copyright © The McGraw-Hill Companies, Inc. Permission required for reproduction or display.

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25 asymmetric scan indicates disease
The use of radio- isotopes to image the thyroid gland asymmetric scan indicates disease normal PET and brain activity normal Alzheimer’s

26 The increased shelf life of irradiated food

27 The Interconversion of Mass and Energy
E = mc2 The mass of the nucleus is less than the combined masses of its nucleons. The mass decrease that occurs when nucleons are united into a nucleus is called the mass defect. DE = Dmc2 Dm = DE / c2 The mass defect (Dm) can be used to calculate the nuclear binding energy in MeV. 1 amu = 931.5x106 eV = 931.5MeV

28 Sample Problem 6 Calculating the Binding Energy per Nucleon PROBLEM: Iron-56 is an extremely stable nuclide. Compute the binding energy per nucleon for 56Fe and compare it with that for 12C (mass of 56Fe atom = amu; mass of 1H atom = amu; mass of neutron = amu).

29 The variation in binding energy per nucleon

30 Induced fission of 235U

31 A chain reaction of 235U

32 Diagram of an atomic bomb

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34 The tokamak design for magnetic containment of a fusion plasma

35 Detection of radioactivity by an ionization counter

36 Vials of a scintillation “cocktail” emitting light

37 Element synthesis in the life cycle of a star
Figure B24.3 Element synthesis in the life cycle of a star

38 A view of Supernova 1987A


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