1 / 15

To nuke, or not to nuke…that is the question!

The Planet's Future. To nuke, or not to nuke…that is the question!. Is nuclear power a renewable, or a non-renewable energy source?. Comanche Peak Plant. That’s right… I was a genius. Fusion and Fission.

lenore
Télécharger la présentation

To nuke, or not to nuke…that is the question!

An Image/Link below is provided (as is) to download presentation Download Policy: Content on the Website is provided to you AS IS for your information and personal use and may not be sold / licensed / shared on other websites without getting consent from its author. Content is provided to you AS IS for your information and personal use only. Download presentation by click this link. While downloading, if for some reason you are not able to download a presentation, the publisher may have deleted the file from their server. During download, if you can't get a presentation, the file might be deleted by the publisher.

E N D

Presentation Transcript


  1. The Planet's Future To nuke, or not to nuke…that is the question! Is nuclear power a renewable, or a non-renewable energy source? Comanche Peak Plant

  2. That’s right… I was a genius. Fusion and Fission Mattercan be changed into energy. Albert Einstein, one of the greatest scientific minds of the 20th century, discovered the mathematical formula that explains this. It is: E = MC2 Energy equals mass times the speed of light squared.

  3. Atoms and Nuclei • Inside the nucleus Helium Protons andneutrons • Outside the nucleus Electrons = Proton = Neutron = Electron As you can see, there are two neutrons, and two protons in elemental helium in its most familiar form Now we know there are even smaller bodies called quarks that make up nuclear particles.

  4. An atom’s nucleus can be split apart. When this happens, a tremendous amount of energy is released (NUCLEAR energy). Energy released is both thermal and radiant. Fission Nuclear fission requires large nuclei from atoms such as uranium, (fuel) which are then split into two smaller nuclei of roughly equal size. When this occurs, energy is released. • Released slowly and controlled, it can be harnessed to generate electricity. • Released quickly and all at once, it makes a colossal explosion also known as an atomic bomb.

  5. A nuclear power plant like Comanche Peak uses uranium as fuel. Fission • Uranium is an element with a naturally unstable nucleus. • Uranium is mined and processed into pellets. • The pellets are loaded into long rods and then into a fuel assembly • The assemblies are then loaded into the reactor core, where the energy is produced • The uranium atoms are split apart in a controlled chain reaction, giving off both heat & light.

  6. Control rods are used to keep the splitting regulated so it doesn’t get out of control. • The chain reaction gives off thermal energy. • The heat produced is used to boil water in the core of the reactor. • This hot water is piped to another section of the plant, where it heats another set of pipes that are filled with water to make steam. • The steam in this second set of pipes powers a turbine... • The turbine spins the shaft connected to the generator which makes electricity... Blah, blah, blah...

  7. Luckily, the conditions under which an atomic bomb is created are not present in a nuclear reactor. Danger of Reactors • In bombs, almost pure pieces of Uranium-235 or Plutonium are held together with great force. Then, the particles are split in an UNCONTROLLED chain reaction • Fission creates a radioactive material that is very harmful to the environment, if released. Fission energy is now being used commercially in the United States to produce about 20% of the nation's electricity.

  8. The two fissile materials we use that undergo fission spontaneously are 235U and 239Pu Strontium-90 mimics the properties of calcium and is taken up by living organisms and deposited in bones. It has the potential for causing cancer or damaging the rapidly reproducing bone marrow cells. Strontium, cesium, and rubidium are the radioisotopes which should be most closely guarded against release into the environment. They have half-lives of around 30 years, which ensures that they are not only highly radioactive but also be around for hundreds of years.

  9. What do we do with our waste? Highly radioactive waste from spent fuel is vitrified – or melted down with glass paste. • This technique traps the radioactive atoms in a structure that is chemically stable for tens of thousands of years. • The glass is poured into steel containers, which are temporarily stored in ventilation shafts to let the heat escape, since the waste is very hot. • It must be allowed to cool for several decades before deep storage can be considered • Then it must be confined for hundreds of thousands of years (the length of time necessary for its radioactive decay).

  10. Fusion • Fusion involves the “fusing” together of smaller nuclei to make a larger nucleus. The sun uses nuclear fusion of the hydrogen atoms, into the helium atom. This process gives off heat, light, and other radiation. What types of energy do heat, and light represent? Thermal and radiant

  11. Atoms and Nuclei • Inside the nucleus Hydrogen Protons and neutrons • Outside the nucleus Electrons = Proton = Electron As you can see, there are no neutrons in elemental hydrogen in its most familiar form There are some forms of hydrogen, however, that do contain neutrons.

  12. Isotopes Isotopes are elements that contain a different number of neutrons than the most common average of those elements found on Earth. Hydrogen has two isotopes, called Deuterium, and Tritium that are used as a fuel for fusion. These two hydrogen isotopes each contain neutrons, which the average hydrogen atom doesn’t contain…thereby making these heavier atoms than normal. How do you determine atomic mass? Deuterium and Tritium, when found in the compound H2O, make heavy water, because the atoms have a greater mass than average hydrogen.

  13. Deuterium and Tritium: Two Hydrogen Isotopes Since nuclei carry positive charges, they normally repel one another. The higher the temperature, the faster the atoms or nuclei move. When they collide at these high speeds, they overcome the force of repulsion of the positive charges, and the nuclei fuse. In such collisions, energy is released. = neutron So, basically, two isotopes of hydrogen combine to form a helium atom and an extra neutron, and give off energy in the process. = proton

  14. The Future and Problems faced by fusion Scientists have been working very hard on the development of nuclear fusion. They have had a difficult time learning how to control the reaction in a contained space. The temperatures necessary to continue the reaction (over 100 million degrees C…[180,000,000° F]) are difficult to reach and contain. The temperature on the sun’s surface is nearly 10,000° F, and at the core, nearly 27,000,000 ° F due to the energy of fusion. In a lab, scientists have been able to attain temperatures as high as 3.6 billion degrees F…quite a bit hotter than what is needed to sustain reactions, but with difficulty. The Plusses The fuels used in fusion are nearly inexhaustible. Fusion would be a cleaner source of energy, in that the byproducts are not radioactive as with the byproducts of fission.

  15. Cold Fusion Cold fusion is a hypothetical type of nuclear reaction that would occur close to room temperature. For the most part, it has been rejected by the mainstream scientific community because the original experimental results could not be replicated consistently and reliably, and because there is no accepted theoretical model of cold fusion.

More Related