How to Enrich Uranium

PDF download Download Article
PDF download Download Article

Uranium is used as a power source in nuclear reactors and was used to make the first atomic bomb, dropped on Hiroshima in 1945.[1] Uranium is mined as an ore called pitchblende,[2] and consists of several isotopes of different atomic weights and different levels of radioactivity. To be used in fission reactions, the amount of the 235U isotope must be increased to a level to permit ready fission in a reactor or bomb. This process is called enriching uranium, and there are several ways to do it.

Method 1
Method 1 of 7:

The Basic Enrichment Process

PDF download Download Article
  1. Step 1 Decide what the uranium will be used for.
    Most mined uranium contains only about 0.7 percent 235U, with most of the rest being the comparatively stable isotope 238U.[3] What type of fission reaction the uranium will be used for determines what the level of 235U must be raised to for the uranium to be used effectively.
    • Uranium used in most nuclear power plants needs to be enriched to a level of 3 to 5 percent 235U.[4] [5] (A few nuclear reactors, such as the CANDU reactor in Canada and the Magnox reactor in the United Kingdom, are designed to use unenriched uranium.)
    • Uranium used for atomic bombs and warheads, in contrast, needs to be enriched to 90 percent 235U.
  2. Step 2 Convert the uranium ore to a gas.
    Most of the methods currently in existence for enriching uranium require the ore to be converted to a low-temperature gas. Fluorine gas is normally pumped into an ore conversion plant; the uranium oxide gas reacts with the fluorine to produce uranium hexafluoride (UF6). The gas is then acted on to separate out and gather the 235U isotope.
    Advertisement
  3. Step 3 Enrich the uranium.
    The remaining sections of this article describe the various processes available to enrich uranium. Of these, gaseous diffusion and gas centrifuge are the two most common, but the laser isotope separation process is expected to replace them.[6]
  4. Step 4 Convert the UF6 gas to uranium dioxide (UO2).
    Once enriched, the uranium needs to be converted to a stable solid form for its intended use.
    • Uranium dioxide used as fuel in nuclear reactors is made into centered ceramic pellets encased in metal tubes to make 4m (13.12-foot) long rods
    5. Advertisement
Method 2
Method 2 of 7:

Gaseous Diffusion Process

PDF download Download Article
  1. Step 1 Pump UF6 through pipelines.
  2. Step 2 Force the gas through a porous filter or membrane.
    Because the 235U isotope is lighter than the 238U isotope, UF6 containing the lighter isotope will diffuse through the membrane faster than the heavier isotope.
  3. Step 3 Repeat the diffusion process until enough 235U is collected.
    The repeated diffusion is called a cascade. It may take as many as 1,400 passes through porous membranes to get enough 235U to enrich the uranium sufficiently.
  4. Step 4 Condense the UF6 gas into liquid form.
    Once the gas is sufficiently enriched, it is condensed into a liquid and then stored in containers, where it cools and solidifies for transport to be made into fuel pellets.
    • Because of the number of passes required, this process is energy-intensive and is being phased out. In the United States, only one gaseous diffusion enrichment plant remains, located in Paducah, Kentucky.[7]
    5. Advertisement
Method 3
Method 3 of 7:

Gas Centrifuge Process

PDF download Download Article
  1. Step 1 Assemble a number of high-speed rotating cylinders.
    These cylinders are the centrifuges. The centrifuges are assembled in both series and parallel layouts.
  2. Step 2 Pipe the UF6 gas into the centrifuges.
    The centrifuges use centripetal acceleration to send the heavier 238U-bearing gas to the cylinder wall and the lighter 235U-bearing gas to the center.
  3. Step 3 Extract the separated gases.
  4. Step 4 Reprocess the separated gases in separate centrifuges.
    The 235U-rich gases are sent to a centrifuge where still more 235U is extracted, while the 235U-depleted gas goes to a different centrifuge to extract still more of the remaining 235U. This enables the centrifuge process to extract much more 235U than the gaseous diffusion process can.[8]
    • The gas centrifuge process was first developed in the 1940s, but was not brought into significant use until the 1960s, when its lower energy requirements for producing enriched uranium became important. At present, a gas centrifuge processing plant exists in the United States in Eunice, New Mexico.[9] In contrast, Russia currently has four such plants, Japan and China have two each, while the United Kingdom, the Netherlands, and Germany each have one.
    5. Advertisement
Method 4
Method 4 of 7:

Areodynamic Separation Process

PDF download Download Article
  1. Step 1 Build a series of stationary narrow cylinders.
  2. Step 2 Inject UF6 gas into the cylinders at high speed.
    The gas is blown into the cylinders in such a way that it is induced to spin in cyclonic fashion, producing the same kind of separation between 235U and 238U as is achieved in a rotating centrifuge.
    • One method being developed in South Africa injects the gas into the cylinder on a tangent. It is presently being tested with light isotopes such as those in silicon.
    3. Advertisement
Method 5
Method 5 of 7:

Liquid Thermal Diffusion Process

PDF download Download Article
  1. Step 1 Liquefy the UF6 gas under pressure.
  2. Step 2 Construct a pair of concentric pipes.
    The pipes should be fairly tall, with taller pipes enabling more separation of the 235U and 238U isotopes.
  3. Step 3 Surround the pipes with a jacket of liquid water.
    This will cool the outer pipe.
  4. Step 4 Pump the liquid UF6 between the pipes.
  5. Step 5 Heat the inner pipe with steam.
    The heat will create a convection current in the UF6 that will draw the lighter 235U isotope toward the hotter inner pipe and push the heavier 238U isotope toward the colder outer pipe.
    • This process was investigated in 1940 as part of the Manhattan Project, but was abandoned while still in an early stage of development when the more efficient gaseous diffusion process was developed.[10] [11]
    6. Advertisement
Method 6
Method 6 of 7:

Electromagnetic Isotope Separation Process

PDF download Download Article
  1. Step 1 Ionize the UF6 gas.
  2. Step 2 Pass the gas through a strong magnetic field.
  3. Step 3 Separate the ionized uranium isotopes by the trails they leave when passing through the magnetic field.
    Ions of 235U leave trails that curve differently than those of 238U. These ions can be isolated to enrich uranium.
    • This method was used to process uranium for the atomic bomb dropped on Hiroshima in 1945 and was also the enrichment method Iraq used in its nuclear weapons program of 1992. It requires 10 times more energy than gaseous diffusion, making it impractical for large-scale enrichment programs.
    4. Advertisement
Method 7
Method 7 of 7:

Laser Isotope Separation Process

PDF download Download Article
  1. Step 1 Tune a laser to a specific color.
    The laser light needs to be entirely of a specific wavelength (monochromatic). This wavelength will target only 235U atoms, while leaving the 238U atoms untouched.
  2. Step 2 Shine the laser light on the uranium.
    Unlike the other uranium enrichment processes, you don’t have to use uranium hexafluoride gas, although most of the laser processes do. You can also use an alloy of uranium and iron as the uranium source, which the Atomic Vapor Laser Isotope Separation (AVLIS) process does.
  3. Step 3 Extract the uranium atoms with excited electrons.
    These will be atoms of 235U.
    4. Advertisement

Community Q&A

Search
Add New Question
  • Question
    Is enriching uranium legal?
    Jacob Ropp
    Jacob Ropp
    Community Answer
    In the US it isn't illegal to enrich uranium, but it is illegal to possess enriched uranium.
    Thanks! We're glad this was helpful.
     Thank you for your feedback.
     If wikiHow has helped you, please consider a small contribution to support us in helping more readers like you. We’re committed to providing the world with free how-to resources, and even $1 helps us in our mission. Support wikiHow
    Yes No
    Not Helpful 2 Helpful 22
  • Question
    Thank you. This was very helpful for my 6th grade class project. What can I do if I come into contact with uranium? Will I get cancer?
    Jacob Ropp
    Jacob Ropp
    Community Answer
    There is the possibility of causing damage to your DNA or getting cancer if you come into contact with any radioactive material of sufficient strength. See a doctor if this happens.
    Thanks! We're glad this was helpful.
     Thank you for your feedback.
     If wikiHow has helped you, please consider a small contribution to support us in helping more readers like you. We’re committed to providing the world with free how-to resources, and even $1 helps us in our mission. Support wikiHow
    Yes No
    Not Helpful 4 Helpful 7
  • Question
    Which method would you recommend to set up in my mother's basement, speaking strictly in theoretical terms?
    Jacob Ropp
    Jacob Ropp
    Community Answer
    Laser enriching seems to be the best option, due to the fact that it doesn't require long-term storage of gases.
    Thanks! We're glad this was helpful.
     Thank you for your feedback.
     If wikiHow has helped you, please consider a small contribution to support us in helping more readers like you. We’re committed to providing the world with free how-to resources, and even $1 helps us in our mission. Support wikiHow
    Yes No
    Not Helpful 0 Helpful 21
See more answers
Ask a Question
200 characters left
Include your email address to get a message when this question is answered.
Submit
Advertisement

Tips

  • Some countries re-process spent nuclear fuel to recover its depleted uranium and plutonium created during the fission process. Reprocessed uranium must be stripped of the 232U and 236U isotopes that formed during fission, and if enriched, must be enriched to a higher level than “fresh” uranium because 236U absorbs neutrons and so inhibits the fission process. For this reason, reprocessed uranium must be kept separate from first-time enriched uranium.
    Thanks
    Helpful 0 Not Helpful 0

Tips from our Readers

  • Don't actually try to build a warhead using these instructions. Not only will it not work without millions of dollars worth of equipment, but it's actually illegal to try.
Submit a Tip
All tip submissions are carefully reviewed before being published
Name
Please provide your name and last initial
Submit
Thanks for submitting a tip for review!
Advertisement

Warnings

  • Enriched uranium can ordinarily be reprocessed only once.
    Thanks
    Helpful 3 Not Helpful 2
  • Reprocessed uranium must be kept under heavy shielding, because the 232U it contains decays into elements that emit a lot of gamma radiation.
    Thanks
    Helpful 3 Not Helpful 3
  • Uranium is actually only weakly radioactive; however, when processed into UF6 gas, it becomes a toxic chemical that reacts with water to form corrosive hydrofluoric acid. (This acid is commonly called “etching acid” because of its use to etch glass.)[12] Uranium enrichment plants thus require the same protective measures as chemical plants that work with fluorine, which include keeping UF6 gas under low pressure most of the time and using extra containment levels in areas requiring higher pressure.
    Thanks
    Helpful 2 Not Helpful 3
Advertisement

You Might Also Like

Split an Atom
How to
Split an Atom
Set Up Nuclear Power in "Satisfactory"
How to
Set Up Nuclear Power in "Satisfactory"
Make Gold from MercuryModern Alchemy? Here’s How Nuclear Reactors Make Gold from Mercury
Identify Uranium GlassA Complete Guide to Uranium Glass: Identification, Value, & More
Survive a Nuclear Attack
How to
Survive a Nuclear Attack
Make Nitric Acid
How to
Make Nitric Acid
Make Gunpowder
How to
Make Gunpowder
Melt Copper
How to
Melt Copper
Refine Gold
How to
Refine Gold
Make a Laser
How to
Make a Laser
Make Aerogel
How to
Make Aerogel
Collect Hydrogen
How to
Collect Hydrogen
Extract Gold from a Rock
How to
Extract Gold from a Rock
Melt Aluminum Cans
How to
Melt Aluminum Cans
Advertisement

References

  1. http://www.atomicheritage.org/history/science-behind-atom-bomb
  2. http://www.britannica.com/EBchecked/topic/462007/pitchblende
  3. https://www.orano.group/en/unpacking-nuclear/all-about-uranium
  4. http://www.cnn.com/2013/11/20/world/gallery/uranium-enrichment-explainer/
  5. https://tutorials.nti.org/nuclear-101/uranium-enrichment/
  6. http://www.nrc.gov/materials/fuel-cycle-fac/ur-enrichment.html
  7. http://www.nrc.gov/materials/fuel-cycle-fac/ur-enrichment.html
  8. http://www.nrc.gov/materials/fuel-cycle-fac/ur-enrichment.html
  9. http://www.nrc.gov/materials/fuel-cycle-fac/ur-enrichment.html
  1. http://www.atomicarchive.com/History/mp/p2s6.shtml
  2. http://www.globalsecurity.org/wmd/intro/u-thermal.htm
  3. http://emedicine.medscape.com/article/773304-overview

About This Article

Joseph Quinones
Reviewed by:
Joseph Quinones
Physics Teacher
This article was reviewed by Joseph Quinones. Joseph Quinones is a Physics Teacher working at South Bronx Community Charter High School. Joseph specializes in astronomy and astrophysics and is interested in science education and science outreach, currently practicing ways to make physics accessible to more students with the goal of bringing more students of color into the STEM fields. He has experience working on Astrophysics research projects at the Museum of Natural History (AMNH). Joseph recieved his Bachelor's degree in Physics from Lehman College and his Masters in Physics Education from City College of New York (CCNY). He is also a member of a network called New York City Men Teach. This article has been viewed 85,689 times.
335 votes - 95%
Co-authors: 15
Updated: March 19, 2024
Views: 85,689
Categories: Chemistry
Article SummaryX

To enrich uranium, introduce fluorine gas to convert the ore to uranium hexafluoride. From there, use gaseous diffusion or gas centrifuges to separate the gas so that the desired uranium isotope can be gathered. To use gaseous diffusion, pump uranium hexafluoride through pipelines, then force the gas through a porous filter to separate the desired isotope. To use the gas centrifuge process, assemble several high-speed rotating cylinders and pipe the uranium hexafluoride gas into them to separate and extract the desired uranium isotope. If you want to learn how to enrich uranium through other processes, such as aerodynamic separation or laser isotope separation, keep reading the article!

Did this summary help you?

In other languages
Thanks to all authors for creating a page that has been read 85,689 times.

Reader Success Stories

  • Wyatt Kreps

    Wyatt Kreps

    Jan 6, 2023

    "This helped me with my middle school science fair project. My Siemens Nuclear Centrifuge booted right up after..." more
    Rated this article:
More reader stories Hide reader stories
Share your story

Did this article help you?

Advertisement