Nuclear Chemistry Nuclear Reactions involve an atom’s nucleus !!!!
Radioactive Decay Spontaneous breakdown of an atom’s nucleus Breakdown results in a lighter nucleus Emits electromagnetic radiation Nuclear radiation—radiation emitted from nucleus Radioactive nuclide– nucleus that goes through radioactive decay, unstable. (Ex. Uranium Ask where are our nuclear power plants in NC? Nucleii beyond 83—unstable, radioactive
Types of Radioactive Decay Alpha particle (α) Consists of 2 protons, 2 neutrons emitted during decay Helium nucleus ( 24He )—how particle represented Can be stopped by paper, low energy Atomic number goes down 2, atomic mass goes down 4. Equation: 84210 Po 82206 Pb + 24 He Beta particle (β) Electron given off during radioactive decay Can be stopped by lead or glass Increase in atomic # Equation: 614 C 714 N + -10 β Gamma Rays Has the most energy, only stopped by lead Ex. X-Rays Alpha particles are heavy—stopped by paper. Beta particles are lighter—more penetrating power Gamma particles—go through anything (ex. X-ray)---have to wear lead apron.
Example 1: Nuclear equation when an alpha particle emitted by 21084Po
Example 2:Nuclear equation when a beta particle emitted by 21082Pb
Practice: Alpha Decay Be-9 U-238 Eu-154 Beta Decay Th-234 K-43
Half-Life Time period required for half of a radioactive nuclide to decay. Vary depending on the nuclide, unique for each nuclide. Ex. 146C has a half-life of 5715. Therefore, if we have 10g of 146C, in 5715 years we will have 5g.
Exponential From Google images
Decay series
AE = AO * 0.5 t/t(1/2) Half-Life Equation AE = Substance amount A0 = Initial substance amount t = time elapsed t1/2 = half-life
Example 1: Plutonium-239 has a half life of 24,110 years Example 1: Plutonium-239 has a half life of 24,110 years. We have 100g of this substance. How many grams will we have after 96,440 years? 6.25g
More on Nuclear Chemistry
Nuclear Fission Nuclear reaction where nuclei are SPLIT Nucleus is broken down into a more stable nucleus. HUGE amount of energy is released Critical mass = minimum number of nuclei that can provide enough neutrons to maintain chain reaction. Nuclear reactors = controlled fission reactions. **Can induce a nuclear chain reaction!!! Neutrons bombard atom, nucleus splits—produces more neutrons that can then attack other atoms—chain reaction! Reaction continues until all nuclei are split. Happens with Uranium 235 **Type of reaction used in nuclear power plants!!!
Uranium-235 used HUGE, HUGE, HUGE amount of water is used to cool the reactors !!!!!
Nuclear Reactors Location where controlled fission reactions occur Fuel rods in the core contain enriched uranium Steam generation steam turbine electric generator Control rods take in neutrons so fission is controlled Production of radioactive waste A TON of water is used to cool the reactors
Nuclear Fusion Nuclei having a light mass are joined. Combination of light nuclei Creates heavy nucleus Results in larger, stable nucleus. MORE energy released than in nuclear fission !!! Hard to control Initiated by fission reaction (fission bomb) ---- H bomb **Type of reaction happening in the sun and stars. -fuel: hydrogen atom Fission reaction used to start a fusion reaction in H bomb.
Atomic bomb--
cu H bomb Fusion reaction generated from a fission reaction
Applications to Nuclear Radiation Radioactive Dating Age determination of artifact based on presence of radioactive nuclide Medical Purposes Cancer treatments Radioactive tracers Food Processing Meat exposed to radiation Kills microorganisms
Prompt We talked about nuclear energy today. Do you support or disagree with this type of green energy? Support your answer. How could we harness the nuclear energy in the sun? Discuss how we might use nuclear fusion to benefit us.