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Seawater Uranium

August 24, 2012

About two years ago, I published an article (Seawater Uranium, July 15, 2010) about the possibility of economically extracting uranium from seawater. As the world's carbon footprint increases at an alarming rate, it appears that nuclear energy might be the most environmentally friendly energy source we have. The main caveat here is that we need to prevent nuclear accidents, which have been far too many; and, we need a way to safely store radioactive waste.

There is still innovation happening in nuclear technology, some of which you might have missed if "Bill Gates" is not a key phrase that you track. Bill Gates, who invested $35 million in TerraPower, the nuclear power start-up investigating traveling wave reactors, was in the news recently for another nuclear initiative. He's working with South Korea on development of a sodium-cooled fast reactor. Such reactors can use the spent fuel rods from conventional nuclear reactors, thereby eliminating much of our waste problems.[1]

Conventional nuclear reactors operate as pressurized water reactors, boiling water reactors, or supercritical water reactors. Conventional nuclear reactors need to use enriched uranium as fuel, and this fuel is consumed over the course of a few years, leading to our current radioactive waste storage crisis. Traveling wave reactors can use depleted uranium as a fuel, once they are started, and no further fuel is required for many decades.

All these reactors require uranium as a fuel, and this is mined just like other minerals. Unfortunately, estimates of available mined uranium show that there's only enough for about a century's operation of the present reactor base.[2] Four billion metric tons of uranium are estimated to be dissolved in seawater,[3] which is hundreds of times the quantity as mine reserves. However, the oceans have a lot of water, so the uranium concentration is just three parts per billion. Extraction by strictly chemical means is not possible. The uranium is dissolved with many other metals, and the total salt concentration is about 3.5%.

Before Fukushima, the Japanese were especially concerned with maintaining their supply of uranium for nuclear power. At that time, about thirty percent of Japan's electrical power came from nuclear reactors. In 2003, Japanese scientists developed chemically-coated plastic fibers that were woven into a mat and placed into the sea. The test mat harvested a kilogram of uranium from seawater that was extracted by an acid rinse.[4]

In continuing work, the Japanese Atomic Energy Commission developed a synthetic polymer fiber that adsorbs uranium. A thirty day exposure of fibers of this polymer to flowing seawater in 2010 resulted in a yield of 1.5 grams of yellowcake uranium per kilogram of fiber.[3] This idea of trapping uranium in treated fibers is being pursued by many others, and their research was recently presented at a symposium at the 244th National Meeting & Exposition of the American Chemical Society, August 19-23, 2012, Philadelphia, Pennsylvania.

Abstracts of all twenty-five symposium presentations can be found at reference 5.[5] Fundamental studies are always welcome, and the symposium included the presentation, "Influence Of Temperature On Uranium Adsorption From Seawater," by Jungseung Kim of Oak Ridge National Laboratory.[5] I list a few of the other titles, below:
• Electrospun Chitin Nanofibers For Uranyl Absorbant Materials, Chris S. Griggs, The University of Alabama.

• Extraction Of Uranium With Regenerated Chitin From The Dissolution Of Shrimp Shells In Ionic Liquid, Robin D. Rogers, The University of Alabama.

• Amidoxime-Grafted Mesoporous Carbon And Porous Organic Gel Sorbents For Extraction Of Uranium From Seawater, Suree Brown, University of Tennessee.

• Isolating Trace Seawater Uranium With Polymer Functionalized Porous Carbon, Yanfeng Yue, Oak Ridge National Laboratory.

• Funcitonalized Carbon Materials As Uranium Adsorbents, Richard Mayes, Oak Ridge National Laboratory.

• Synthesis, Development, And Testing Of Uranium Adsorbent Materials, Yatsandra Oyola, Oak Ridge National Laboratory.

The list above includes an anticipated mix of material choices, but one material stands out. Chitin? Chitin is a polymeric protein found in the exoskeletons of crab, lobster, shrimp, and insects. It's a tough material, it can be made into very fine fibers by electrospinning, so it's a useful substrate for uranium extraction.[4]

Structural unit of chitin

Structural unit of chitin.

(Structural diagram by
D. Schanz, via
Wikimedia Commons)


Serendipity is often a part of scientific research. In this case, Robin Rogers of the University of Alabama found himself working with the US Gulf Coast seafood industry after the dual onslaught of Hurricane Katrina and the Deepwater Horizon oil spill. During this time, he found that there was a ready supply of seafood shell available. These were actually an industrial waste that the seafood industry had to pay to dispose, so they were happy to be rid of it.[4] The uranium is bound by a poly-acrylamidoxime coating, and it's extracted using an ionic liquid.[4]

Another approach combining surface absorbants on a fully synthetic, high-surface-area polyethylene fiber, is being developed by Oak Ridge National Laboratory. The material, called HiCap, is claimed by Chris Janke, one of the ORNL inventors, to "extract five to seven times more uranium at uptake rates seven times faster than the world's best adsorbents."[6] The fibers have a non-circular cross section that provides a high surface area. After sea water exposure to entrap uranium, the aborbant is leeched away using acid to recover the uranium. Seawater tests have shown a uranium capacity of 3.94 grams of uranium per kilogram of adsorbent, which is about five times greater than the present record.[6]

How economical can such extraction be? Erich Schneider of the U.S. Department of Energy made a presentation at the ACS Symposium that compared uranium mining and seawater extraction. The best seawater techniques to date would bring the cost to about $300 per pound of uranium, which is about five times the price for mined uranium (see figure). Schneider explained that the seawater techniques are an economic safety net, since they assure that uranium will be available as fuel after you build your ten billion dollar nuclear power plant.[7]

Uranium spot market price

Monthly uranium spot prices, via Via Wikimedia Commons)


References:

  1. Bill Gates to Develop New Nuclear Reactor with Korea, englishnews@chosun.com, August 20, 2012.
  2. Uranium resources sufficient to meet projected nuclear energy requirements long into the future, Nuclear Energy Agency Press release, June 3, 2008.
  3. Sally Adee and Anne-Marie Corley, "Uranium From Seawater," IEEE Spectrum Online, June, 2010.
  4. Uranium from seawater idea boosted with shrimp shells, BBC, August 22, 2012.
  5. Advances in decades-old dream of mining seawater for uranium, American Chemical Society Press Release, August 21, 2012.
  6. ORNL technology moves scientists closer to extracting uranium from seawater, Oak Ridge National Laboratory Press Release, August 21, 2012.
  7. Advances in decades-old dream of mining seawater for uranium, American Chemical Society Press Release, August 21, 2012.

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Linked Keywords: Carbon footprint; nuclear energy; nuclear accident; radioactive waste; Bill Gates; TerraPower<; traveling wave reactor; South Korea; sodium-cooled fast reactor; >spent fuel rod; light water reactor; conventional nuclear reactor; pressurized water reactor; boiling water reactor; supercritical water reactor; enriched uranium; Nuclear Waste Policy Act; radioactive waste storage crisis; depleted uranium; uranium; uranium mining; metric ton; seawater; ocean; water; parts per billion; chemical; metal; salt; Fukushima Daiichi nuclear disaster; Fukushima; Japanese; nuclear power in Japan; nuclear power; electrical power; plastic; fiber; kilogram; acid; Japanese Atomic Energy Commission; synthetic polymer fiber; yellowcake uranium; symposium; 244th National Meeting & Exposition of the American Chemical Society; abstract; pure research; fundamental study; Oak Ridge National Laboratory; The University of Alabama; University of Tennessee; chitin; protein; exoskeleton; crab; lobster; shrimp; insect; tough; material; electrospinning; Wikimedia Commons; serendipity; scientific method; scientific research; Robin Rogers; US Gulf Coast; seafood industry; Hurricane Katrina; Deepwater Horizon oil spill; industrial waste; poly-acrylamidoxime; poly-acrylamid; oxime; ionic liquid; polyethylene; Chris Janke; cross section; economics; U.S. Department of Energy; pound; uranium market; price for mined uranium.




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