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In order to be nuclear fuel in an conventional nuclear plant, the isotopes have to be capable of fission and have a critical mass. Of the potential fuels found in nature, only 235U has this capacity, and there is not enough of it in uranium ore to provide for fuel of a simple reactor without enrichment.
The half lives of two uranium isotopes most commonly found in nature are roughly 703,800,000, for 235U, which is 0.720% of what is found, and 4,468,900,000 years for 238U, which is 99.274%. The percentage of 235U is increased to about 4% or 5% for fuel in power plants. This means that even though uranium can have critical mass, it is not especially dangerously radioactive.
Critical mass is achievable because the uranium can produce a chain reaction in which the fission of one atom causes the fission of one or more other atoms. This happens because uranium occasionally undergo spontaneous fission instead of its normal alpha decay, producing neutrons in the process, and the neutrons can cause other atoms to undergo fission. If there is a sufficiently abundant supply of atoms capable of fission, the fission event produces on average more than one other fission event. As this continues, the speed of fission increases and a chain reaction follows, going on until the fuel runs out.
While the original uranium is not especially radioactive, the products of fission are. They cannot support fission, because they do not have sufficient mass, but their half lives are mostly very, very short. Each daughter atom of fission has a high probability of multiple decays during the first seconds of its existence. The isotopes with half lives of seconds or less are mostly gone by the time the fuel rod is removed from the reactor, but they are followed by isotopes with half lives ranging from days to years.
The decay of short term fission products happens so rapidly that even in the absence of fission, the rods need special cooling for several years. As the decay continues, the half lives of the remaining isotopes get longer, until the atoms of isotopes with short half lives are mostly gone, at which point the rods can be removed to longer term storage.
Medium term fission products have half lives of 10 to 90 years, making them very radioactive. Nuclear waste needs centuries of storage just because of these. And long term fission fragments have half lives that range from 211 to 80,000,000 years.
It has been calculated that the time it takes for spent fuel to decay to the level of radioactivity of naturally occurring uranium ore is about 6,000,000 years.
What else can I help you with?
Is uranium recyclable?
This question is not very simple. Uranium used as fuel in nuclear reactors is not all burned completely when it is no longer usable. The rest of uranium can by recycled, but spent fuel processing is extremely difficult and dangerous. Expended fuel is sitting around by the railroad car full for one reason: it is uniformly radioactive, and very highly so. Opening up spent fuel is not for the foolish or the untrained and unequipped. The hazards far outweigh the advantages, and it is far, far "easier" to store spent fuel than to do anything else with it. And that is why spent nuclear fuel storage is an issue now; reprocessing it is almost unspeakably "dirty" work.
Which problem is associated with energy produced by nuclear fission?
1. Some of the waste products from the spent fuel are very radioactive. 2. The plants are expensive to build, and to insure.
What is a radioactive decay of the spent fuel?
Radioactive decay of spent fuel refers to the process where the radioactive isotopes in the fuel break down and release radiation and particles. This decay can continue for thousands of years, making spent fuel a long-term radiation hazard. Proper storage and disposal methods are necessary to prevent environmental and health risks.
Nuclear power is a non-renewable resource How could that change?
It depends what you mean by "renewable". Radioactive materials do not "grow" the way trees grow. There are naturally-occurring radioactive elements. Elements can also be made radioactive by various means that involve atomic collisions, and this may occur in nature or as a result of human direction. It is true that the majority of the fuel used in a reactor eventually becomes "spent". That is, it gets to a point where it stops producing useful power. It is still, however, radioactive. Spent nuclear fuel can be recycled and reused in some cases, depending on the isotope and the form of the fuel. We will probably become more successful in recycling spent fuel as our technology advances. There is no reason to suppose that nuclear fuel could not be effectively infinite, particularly as compared to resources like petroleum and coal. The amount of nuclear fuel require to produce an equivalent amount of electricity to other energy sources is a very small fraction. It is extremely efficient in terms of energy yield per kilogram of raw material.
Why is a nuclear reactor dangerous?
Components in the reactor inside the primary shielding will be radioactive, even after all the fuel has been removed. Provided everything is monitored and assessed properly and health physics advice followed by the operators, there should be no need for anyone to be exposed to dangerous levels during decommissioning.
Does a nuclear generating station make pollution?
No, but the spent fuel must be carefully stored after use because it does contain dangerous radioactivity.
Is uranium recyclable?
This question is not very simple. Uranium used as fuel in nuclear reactors is not all burned completely when it is no longer usable. The rest of uranium can by recycled, but spent fuel processing is extremely difficult and dangerous. Expended fuel is sitting around by the railroad car full for one reason: it is uniformly radioactive, and very highly so. Opening up spent fuel is not for the foolish or the untrained and unequipped. The hazards far outweigh the advantages, and it is far, far "easier" to store spent fuel than to do anything else with it. And that is why spent nuclear fuel storage is an issue now; reprocessing it is almost unspeakably "dirty" work.
Why do spent nuclear fuels generate heat?
Spent nuclear fuel generates heat due to the radioactive decay of the leftover isotopes in the fuel rods. These isotopes emit radiation as they decay, which produces heat energy. The heat generated must be carefully managed to prevent overheating and ensure the safe storage of the spent nuclear fuel.
What form of fuel can be the most dangerous?
nuclear of course!
What are some cautions of nuclear power?
Reactor fuels contain dangerous radioactive fission products after use, so the spent fuel rods must be carefully handled and stored.
Are nuclear spent fuel rods dumped in the ocean?
Dumping nuclear spent fuel rods in the ocean is illegal and poses serious environmental risks. Radioactive materials from spent fuel rods can contaminate marine life, water, and the ecosystem. Safe and secure storage solutions are used to manage nuclear waste.
Is nuclear energy recyclable?
Yes, nuclear energy is a recyclable source of energy. Nuclear fuel can be recycled and reused through a process called nuclear fuel reprocessing, which separates usable material from spent fuel. This helps to reduce nuclear waste and maximize the energy potential of nuclear fuel.
Where does spent nuclear fuel go?
Spent nuclear fuel is typically stored on-site at nuclear power plants in steel and concrete containers called dry casks. Some countries have centralized storage facilities where spent fuel can be safely stored until a permanent disposal solution is developed. Long-term solutions may include deep geological repositories where the fuel is permanently isolated from the environment.
What kind of nuclear waste are produced by nuclear energy?
Radioactive waves
How do scientist collect pure plutonium?
Irradiation of uranium in nuclear reactors, separation from the spent nuclear fuel, refining
What is bad about nuclear waste?
It is highly radioactive (that is the waste contained in the spent fuel)
How long is a spent nuclear fuel rod a danger?
Thousands of years at least
