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NUCLEAR CHEMISTRY

NUCLEAR CHEMISTRY. FYI: Historical Perspective. Henri Becquerel 1896 - Discovers natural radioactivity. FYI: Historical Perspective. Marie Sklodowska, Polish chemist marries Pierre Curie, French physicist Marie died from leukemia caused by her exposure to radiation

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NUCLEAR CHEMISTRY

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  1. NUCLEAR CHEMISTRY

  2. FYI: Historical Perspective • Henri Becquerel • 1896 - Discovers natural radioactivity

  3. FYI: Historical Perspective • Marie Sklodowska, Polish chemist marries Pierre Curie, French physicist • Marie died from leukemia caused by her exposure to radiation • Pierre was killed while crossing the street when he was hit by a vegetable wagon.

  4. FYI: Historical Perspective • Earnest Rutherford • 1899 – Discovers alpha, beta and gamma radiation

  5. Nuclear Reactions • Involve changes in the composition of nuclei • Accompanied by the release of tremendous amounts of energy

  6. Nuclear Fission • The splitting of a heavy nucleus into lighter nuclei

  7. Nuclear Fusion • The combination of light nuclei to produce a heavier nucleus

  8. Nuclides • Different atomic forms of all elements • Most small nuclides have equal # of protons and neutrons • Some nuclides have “magic #’s” of protons and neutrons and are especially stable

  9. The neutron-to-proton ratio determines the stability of the nucleus • For low atomic #’s: • Equal #’s of protons and neutrons • Above atomic #20: • More neutrons than protons

  10. Nuclei whose neutron-to-proton ratio is unstable undergo radioactive decay by emitting 1 or more particles and/or electromagnetic rays:

  11. Nuclei whose neutron-to-proton ratio is unstable undergo radioactive decay by emitting 1 or more particles and/or electromagnetic rays: helium nucleus 4.0026 2+ low electron 0.00055 1- low-med high energy radiation 0 0 high proton, H nucleus 1.0073 1+ low-med neutron 1.0087 0 very high

  12. Comparing penetrating ability…

  13. Alpha Particle Decay • Example 1: Radium-226 transmutates by alpha decay. Write the nuclear equation that represents this process. or

  14. + + Beta Particle Decay • Example 2: Write the nuclear equation for the beta-decay of boron-12. or

  15. Gamma Radiation • Example 3: Write the nuclear equation representing gamma radiation given off by the unstable radionuclide cobalt-60.

  16. Nuclear Fission & Fusion

  17. FISSION: a heavy nucleus splits into 2 lighter nuclei • some elements undergo fission spontaneously • some elements can be induced to undergo fission when bombarded with other particles (e.g. neutrons)

  18. FUSION: 2 nuclei combine to form a heavier nucleus • the sun is a tremendous fusion reaction; the major fusion reaction in the sun is thought to be: • both fission & fusion release large amounts of energy (fusion more than fission)

  19. The Atomic Bomb (FISSION) • when the nucleus of U-235 splits, 2 isotopes are formed, plus neutrons are emitted • these neutrons collide with other U-235 atoms, causing them to undergo fission; they release neutrons, and so on… • The result - CHAIN REACTION!!

  20. FISSION

  21. CHAIN REACTION!!!

  22. The Atomic Bomb (FISSION)

  23. The Atomic Bomb (FISSION)

  24. CRITICAL MASS • The minimum mass of fissionable material that must be used to sustain a chain reaction

  25. One type of bomb… • Little Boy: U-235 (Hiroshima) • Fat Man: Pu-239 (Nagasaki) subcritical mass of U-235 TNT(dynamite) subcritical mass of U-235

  26. Nuclear Reactors (controlled FISSION)

  27. Nuclear Reactors (FISSION) • use subcritical masses of fissionable material • CORE: contains fuel pins made of U-235; interspersed among the pins are control rods • control rods: absorb neutrons • pull rods out of core: fission increases • push rods back into the core: fission decreases • Safety feature: if power is lost, rods will automatically fall into the core and shut the reaction down.

  28. Nuclear Reactors (FISSION) “The energy produced by breaking down the atom is a very poor kind of thing. Anyone who expects a source of power from the transformation of these atoms is talking moonshine.” Ernest Rutherford

  29. Nuclear Reactors (FISSION)

  30. Nuclear Power Plants

  31. Nuclear Power Plants

  32. Nuclear Power Plants

  33. TO GENERATE ELECTRICITY: • Fission heats up water in vessel and heat is carried away. • This heat is used to heat up water in a second system, which turns into steam. • Steam turns turbine of a generator. • Generator makes electricity.

  34. PROS OF NUCLEAR ENERGY: • no air pollution • enormous amt. of energy released • alternative to using our rapidly decreasing fossil fuels

  35. CONS OF NUCLEAR ENERGY • containers for waste products may erode or break • thermal pollution (heated water returned to rivers, etc.) • potential theft of fuel (Pu-239) for use in weapons

  36. Controlled Nuclear FUSION • PROS: • A very abundant supply of energy world wide. • Environmentally clean • No creation of weapon materials • No chance of runaway reactions leading to accidents • CONS: • It doesn’t work; at least not yet…

  37. Nuclear Fusion "Every time you look up at the sky, every one of those points of light is a reminder that fusion power is extractable from hydrogen and other light elements, and it is an everyday reality throughout the Milky Way Galaxy." Carl Sagan, Spitzer Lecture, October 1991

  38. Nuclear Fusion • Obstacles… • HOT – plasma at least 100 million C • High density plasma • Containment of plasma • Confinement time

  39. Rates of Decay & Half Life Radionuclides have different stabilities and decay at different rates.

  40. Integrated Rate Equation where… • A = the amt. of decaying sample remaining at some time, t • Ao= the amt. of sample present at the beginning • k = rate constant; different for each radionuclide • t = time

  41. Integrated Rate Equation OR… where… • N = # of disintegrations per unit of time; relative activity • No= original activity

  42. HALF-LIFE= the amount of time required for half of the original sample to decay

  43. HALF-LIFE= the amount of time required for half of the original sample to decay Daughter Parent

  44. HALF-LIFE • Half-life = the amount of time required for half of the original sample to decay

  45. Example: Cobalt-60 decays with the emission of beta particles and gamma rays, with a half-life of 5.27 years. How much of a 3.42 g of cobalt-60 remains after 30.0 years? How do you solve for A???

  46. Take the ANTILOG (10x) of both sides.

  47. Example: Cobalt-60 decays with the emission of beta particles and gamma rays, with a half-life of 5.27 years. How much of a 3.42 g of cobalt-60 remains after 30.0 years?

  48. Uses of Radionuclides • Radiocarbon dating: the ages of specimens of organic origin can be estimated by measuring the amount of cabon-14 in a sample.

  49. Example: A piece of wood taken from a cave dwelling in New Mexico is found to have a carbon-14 activity (per gram of carbon) only 0.636 times that of wood today. Estimate the age of the wood. (The half-life of carbon-14 is 5730 years.)

  50. Example: A piece of wood taken from a cave dwelling in New Mexico is found to have a carbon-14 activity (per gram of carbon) only 0.636 times that of wood today. Estimate the age of the wood. (The half-life of carbon-14 is 5730 years.) t=3744 yrs = 3740 yrs

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