![]() Although it may become necessary, this solution is hardly simple or permanent. One suggestion has been to encase such plants in concrete for 100 years or more. Third, obsolete generating plants also present a problem to future generations, for they contain much radioactive material. The radioactivity from spent nuclear fuel and from the products of nuclear fission will remain lethal for thousands of years the safe disposal of these materials is a problem that has not yet been solved. Second, many of the products of nuclear fission are themselves radioactive. This problem has been a continuing concern since the accident at the Three-Mile Island nuclear plant in March 1979 - a concern that has increased in the wake of the disaster at the Chernobyl reactor in the former Soviet Union in April 1986, where radioactive fallout spread within days across the globe. First is the everpresent danger that leaks, accidents, or acts of sabotage will release radioactive materials from the reactor into the environment. Nuclear reactors using fissionable materials pose several serious risks to the environment. Several breeder reactors are now functioning in Europe. Thus, a so-called breeder reactor can produce its own supply of fissionable material. ![]() These neutrons can then be used to breed more plutonium-239 from uranium-238. Plutonium-239 also undergoes fission, with the production of more energy and more neutrons. This isotope undergoes beta emission to generate neptunium-239, which, in turn, undergoes another beta emission to produce plutonium-239: However, if uranium-238 is bombarded with neutrons (from uranium-235, for example), it absorbs a neutron and is transformed into uranium-239. The much more abundant uranium-238 does not undergo fission and therefore cannot be used as a fuel for nuclear reactors. Uranium-235 (natural abundance 0.71%) is very scarce and difficult to separate from uranium-238 (natural abundance 99.28%). About 5600 tons (5.1 X 10 6 kg) of coal are required to produce the same amount of electricity in a conventional power plant. A typical nuclear power plant in operation today uses about 2 kg uranium-235 to generate 1000 megawatts of electricity. Energy generation can be regulated by inserting control rods between the fuel rods in the reactor to absorb excess neutrons, thereby controlling the rate of the chain reaction. The steam then drives a turbine to produce electricity. In nuclear power plants, the energy released by the controlled fission of uranium-235 is collected in the reactor and used to produce steam in a heat exchanger. Each fission results in two (or more) neutrons that can react with other uranium atoms so that the number of nuclear fissions occurring soon reaches an enormous number. ![]() In fact, this reaction is the source of energy in the atomic bomb.įIGURE 4.6 Diagram of a nuclear fission chain reaction. Under proper conditions, the fission of a few nuclei of uranium-235 sets in motion a chain reaction (Figure 4.6) that can proceed with explosive violence if not controlled. The brackets around U indicate that it has a highly unstable nucleus. In turn, these atoms split apart, releasing more energy and more neutrons. Some of these neutrons are absorbed by other atoms of uranium-235. When a nucleus of uranium-235 undergoes fission, it splits into two smaller atoms and, at the same time, releases neutrons ( n) and energy. Nuclear power plants currently in use depend primarily on the fission of uranium-235 and plutonium-239. Only a few nuclei are known to undergo fission. In nuclear fission a large nucleus is split into two medium-sized nuclei. The source moves along a circular track, rotating the radioactive beam around the patient, so that only the tumor receives continuous radiation. Industry fall into two categories: fission reactions and fusion reactions.įIGURE 4.5 Cancer treatment with cobalt-60. The nuclear reactions presently used or studied by the nuclear power Of effort and expense has gone into developing nuclear reactors as a source The first nuclear reactor to achieveĬontrolled nuclear disintegration was built in the early 1940s by Enrico FermiĪnd his colleagues at the University of Chicago. A fifth characteristic of nuclear reactions is that Nuclear decay that form the basis for the use of radioisotopes in the healthĪnd biological sciences. In the previous section we listed four characteristics of radioactivity and
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