https://wikimd.org/index.php?action=history&feed=atom&title=Nuclear_fuel_cycleNuclear fuel cycle - Revision history2026-04-26T05:41:01ZRevision history for this page on the wikiMediaWiki 1.44.2https://wikimd.org/index.php?title=Nuclear_fuel_cycle&diff=5642845&oldid=prevPrab: CSV import2024-04-22T03:04:12Z<p>CSV import</p>
<p><b>New page</b></p><div>[[File:The_Nuclear_Fuel_Cycle_(44021369082)_(cropped).jpg|The Nuclear Fuel Cycle (44021369082) (cropped)|thumb]] [[File:Spent_Fuel_Storage_(25865854820).png|Spent Fuel Storage (25865854820)|thumb|left]] [[Image:Uranium_ore_square.jpg|Uranium ore square|thumb|left]] [[Image:Yellowcake.jpg|Yellowcake|thumb]] [[Image:UF6_square.jpg|UF6 square|thumb]] [[Image:Nuclear_fuel_pellets.jpeg|Nuclear fuel pellets|thumb]] '''Nuclear fuel cycle''' refers to the series of processes involved in the production and use of [[nuclear fuel]] for generating power. This cycle encompasses the mining and milling of [[uranium]], its conversion into a fuel form, its use in a [[nuclear reactor]], and the subsequent handling of the spent fuel, including its storage, reprocessing, and waste disposal. The nuclear fuel cycle is a critical component of the [[nuclear power]] industry, ensuring the efficient and safe use of nuclear material for energy production.<br />
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== Overview ==<br />
The nuclear fuel cycle starts with the extraction of [[uranium]] from the ground. Uranium is a common element found in the Earth's crust, but it requires processing to be used as fuel. Once extracted, uranium ore is milled to produce [[uranium oxide]] concentrate, which is then refined and converted into uranium hexafluoride ([[UF6]]). This compound can be enriched to increase the concentration of [[Uranium-235|U-235]], the isotope necessary for sustaining a nuclear chain reaction.<br />
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Following enrichment, the UF6 is converted into [[uranium dioxide]] (UO2), which is then fabricated into fuel pellets. These pellets are loaded into metal tubes to form fuel rods, which are assembled into fuel assemblies for use in a nuclear reactor. Within the reactor, the U-235 atoms undergo [[fission]], releasing a significant amount of heat. This heat is used to generate steam, which drives turbines to produce electricity.<br />
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After several years in the reactor, the fuel becomes "spent," meaning it no longer contains enough U-235 to sustain an efficient chain reaction. Spent nuclear fuel is highly radioactive and generates heat, necessitating careful handling and management. It can be stored in cooling pools at reactor sites or in dry cask storage facilities while awaiting final disposal or reprocessing.<br />
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== Reprocessing and Recycling ==<br />
Some countries opt to reprocess spent nuclear fuel to recover [[plutonium]] and unused uranium, which can be recycled into new fuel. This process reduces the volume of high-level waste and makes better use of the original uranium resource. Reprocessed material can be fabricated into mixed oxide (MOX) fuel, which is used in some types of reactors. However, reprocessing is expensive and raises proliferation concerns due to the potential misuse of plutonium.<br />
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== Waste Disposal ==<br />
The final stage of the nuclear fuel cycle involves the disposal of nuclear waste. This includes low-level waste (such as contaminated tools and clothing), intermediate-level waste (such as reactor components), and high-level waste (primarily spent fuel). High-level waste requires isolation from the biosphere for thousands of years due to its long-lived radioactivity. Geological disposal in deep underground repositories is the most widely accepted method for disposing of high-level waste, although no such facility is currently in operation for high-level waste from the commercial nuclear fuel cycle.<br />
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== Challenges and Future Directions ==<br />
The nuclear fuel cycle faces several challenges, including concerns about nuclear proliferation, the high cost of nuclear power, and public opposition to nuclear waste disposal. Advances in reactor technology and fuel cycle management could address some of these issues. For example, [[Generation IV reactors]] promise higher efficiency and reduced waste production. Additionally, new fuel cycle technologies, such as thorium-based fuel or partitioning and transmutation, could further reduce waste and mitigate proliferation risks.<br />
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[[Category:Nuclear technology]]<br />
[[Category:Nuclear materials]]<br />
[[Category:Energy conversion]]<br />
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