1. Submarines and Aircraft Carriers: The Science of Nuclear Power Science Topic: Physics and Social Science

2. Matter and Energy: Energy From the Atom

4. Plot your course to the Arctic Sea! Use Google Earth or Google Maps to determine the distance in miles from Kitsap Naval Base in Washington state to a secret location in the Arctic Sea.

5. How long underwater? Example calculation: – Assume a cruising speed of 20 knots (23 mph) – If you measured 3,750 miles, the time underwater = 3,750/23 = 163 hours Most non-nuclear submarines cannot remain submerged that long! With nuclear power, a submarine is limited only by its food supply.

6. Nuclear power is… A method of generating electricity A means of powering large vessels, such as submarines and aircraft carriers Based on a process involving atomic nuclei: nuclear fission

7. Matter and Energy: Energy From the Atom

8. Fission A loose neutron… …collides with a uranium atom… …destabilizing it. Fission splits the atom into two new elements, releasing energy, gamma rays and additional neutrons.

9. Chain reaction 1.A neutron collides with a uranium atom. 2.The collision releases energy, and three additional neutrons. 3.Each neutron in turn collides with additional uranium atoms.

10. Nuclear Fission and Power Plants

11. Generating Electricity

12. Labels: Condenser Containment structure Control Rods Electric Generator Pressurizer Reactor Vessel Steam Generator Turbine Containment structure Pressurizer Steam Generator Control Rods Reactor Vessel Turbine Electric Generator Condenser See the reactor in action! See the reactor in action!

13. Nuclear reactor safety – explosion? Could a nuclear explosion occur? - critical mass The minimum amount of material needed to sustain an uncontrolled chain reaction, and therefore cause a nuclear explosion. - purity of U-235 Nuclear fuel in a reactor is about 5% U-235. For a weapon, U-235 needs to be about 90% pure. - an explosion cannot occur The purity of U-235 in nuclear fuel is too low to sustain an uncontrolled chain reaction

14. Nuclear reactor safety – waste Why is radioactivity dangerous? - meltdown Overheating of reactor core due to loss of cooling ability or control rod function. - cell damage Radioactivity causes damages cell components and causes mutations. - regular operations As uranium fuel is used, it and its byproducts are highly radioactive. To deal with radioactive waste: Protect workers Store waste safely

15. Exponential decay Negative power relationship Faster decay Slower decay

16. Results of half-life activity What shape are the observed curves? Which of the lines, the class average or the group line, is closest to the theoretical line? Why? What is the difference in the average time for U- 232 and P-238 groups to use up all their candies? What does this difference represent?

17. Radioactive decay Over each half-life… …radioactivity is halved… …then again, and… …again, and…

18. Half-life of top 10 fission products Element Name (symbol)Yield (%) Half-life Caesium (Cs 133)6.82.1 years Iodine (I 135)6.36.6 hours Zirconium (Zr 93)6.31,530,000 years Molybdenum (Mo 99)6.165.9 hours Caesium (Cs 137)6.130.17 years Technetium (Tc 99)6.1211,000 years Strontium (Sr 90)5.828.9 years Iodine (I 131)2.88.0 days Promethium (Pm 147)2.32.6 years CONCLUSION Most fission products have relatively short half-lives (< 90 years). Percent yield is the relative amount of each element resulting from fission of U-235. BONUS FACT Seven fission products have very long half-lives. (Only two of those are shown.)

19. Types of radioactive decay Type of Decay (symbol) CauseParticle EmittedExample Alpha (α)Excess neutrons cause repulsion Helium nucleusUranium-238 to Thorium-234 Beta (β)Excess neutrons cause conversion ElectronHydrogen-3 to Helium-3 Gamma (γ)Nucleus energy too high PhotonCobalt-60 to Nickel-60

20. Penetrating power of decay particles

21. Predicting decay products How does alpha decay affect an isotope? What is the atomic number and atomic weight of helium? What is the new atomic mass and atomic number? Loss of a helium nucleus Loss of protons changes the element. Transmutation = change from one element into another Atomic number = 2 Atomic weight = 2 Subtract 2 protons Subtract 2 neutrons

22. Predict alpha decay – example Problem: an atom of 238 U emits an alpha particle, undergoing alpha decay. What is the product of this process? 3. Look up the periodic table. (In the periodic table, the element with atomic number 90 is thorium.) 2. Subtract values for helium from uranium: Atomic mass = 238 – 4 = 234 Atomic number = 92 – 2 = 90 1. Write the equation: Solution: Answer: The decay product is thorium-234 ( 234 Th)

23. Radioactive decay chain Th RaRn PoPb U Uranium  Thorium  Radium  Radon  Polonium  Lead Check the periodic table to find the atomic numbers for each of the elements. Do you see a pattern? – 1 α particle

24. How long is radioactive waste dangerous? It depends on the half-life of the products of fission and decay A few decades to millions of years It can be made safer if stored properly

25. Matter and Energy: Energy From the Atom

26. The Science of Nuclear Power Example concepts alpha particle chain reaction critical mass nuclear fission gamma rays half-life nuclear decay exponential decay nucleus radioactivity transmutation nuclear reactor

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29. Energy yield of nuclear fuel Fun factoids! – 1 gram of nuclear fuel provides 1.76 million times the energy from a gram of gasoline – If your car was nuclear-powered it could travel 5 billion miles to the gallon Type of Engine Engine Efficiency Energy Yield (1g) Diesel40 – 50%5 x 10 4 J Nuclear30 – 40%9 × 10 10 J

30. At Sea: Submarine Warfare

31. Essential (Guiding) Questions How does a nuclear reactor work? What are the benefits and risks of nuclear power? What are basic terms used in the fields of nuclear power and nuclear physics? How are quantitative data related to radioactivity analyzed? Can you define the key words?

32. Key Vocabulary alpha particle chain reaction critical mass exponential decay gamma rays half-life nuclear decay nuclear fission nuclear reactor nucleus radioactivity transmutation