http://ex-skf.blogspot.com/2012/01/uc-davis-researcher-sea-water-can.html
Japan used seawater to cool nuclear fuel at the stricken Fukushima-Daiichi nuclear plant after the tsunami in March 2011 -- and that was probably the best action to take at the time, says Professor Alexandra Navrotsky of the University of California, Davis.
But Navrotsky and others have since discovered a new way in which seawater can corrode nuclear fuel, forming uranium compounds that could potentially travel long distances, either in solution or as very small particles. The research team published its work Jan. 23 in the journal Proceedings of the National Academy of Sciences.
“This is a phenomenon that has not been considered before,” said Alexandra Navrotsky, distinguished professor of ceramic, earth and environmental materials chemistry. “We don’t know how much this will increase the rate of corrosion, but it is something that will have to be considered in future.”Japan used seawater to avoid a much more serious accident at the Fukushima-Daiichi plant, and Navrotsky said, to her knowledge, there is no evidence of long-distance uranium contamination from the plant.
Japan used seawater to cool nuclear fuel at the stricken Fukushima-Daiichi nuclear plant after the tsunami in March 2011 -- and that was probably the best action to take at the time, says Professor Alexandra Navrotsky of the University of California, Davis.
But Navrotsky and others have since discovered a new way in which seawater can corrode nuclear fuel, forming uranium compounds that could potentially travel long distances, either in solution or as very small particles. The research team published its work Jan. 23 in the journal Proceedings of the National Academy of Sciences.
“This is a phenomenon that has not been considered before,” said Alexandra Navrotsky, distinguished professor of ceramic, earth and environmental materials chemistry. “We don’t know how much this will increase the rate of corrosion, but it is something that will have to be considered in future.”Japan used seawater to avoid a much more serious accident at the Fukushima-Daiichi plant, and Navrotsky said, to her knowledge, there is no evidence of long-distance uranium contamination from the plant.
Uranium in nuclear fuel rods is in a chemical form that is “pretty insoluble” in water, Navrotsky said, unless the uranium is oxidized to uranium-VI — a process that can be facilitated when radiation converts water into peroxide, a powerful oxidizing agent.
Peter Burns, professor of civil engineering and geological sciences at the University of Notre Dame and a co-author of the new paper, had previously made spherical uranium peroxide clusters, rather like carbon “buckyballs,” that can dissolve or exist as solids.
In the new paper, the researchers show that in the presence of alkali metal ions such as sodium — for example, in seawater — these clusters are stable enough to persist in solution or as small particles even when the oxidizing agent is removed.
In other words, these clusters could form on the surface of a fuel rod exposed to seawater and then be transported away, surviving in the environment for months or years before reverting to more common forms of uranium, without peroxide, and settling to the bottom of the ocean. There is no data yet on how fast these uranium peroxide clusters will break down in the environment, Navrotsky said.
Navrotsky and Burns worked with the following co-authors: postdoctoral researcher Christopher Armstrong and project scientist Tatiana Shvareva, UC Davis; May Nyman, Sandia National Laboratory, Albuquerque, N.M.; and Ginger Sigmon, University of Notre Dame. The U.S. Department of Energy supported the project.
Professor Navrotsky says as far as she knows there is no evidence of long-distance uranium contamination from Fukushima I Nuke Plant. I don't think the Japanese government is specifically looking for uranium anywhere outside the plant. They are not even looking for strontium. That doesn't mean it doesn't exist.
The abstract of the paper at PNAS (Proceedings of the National Academy of Sciences of the United States of America):
Uranyl peroxide enhanced nuclear fuel corrosion in seawater
Christopher R. Armstrong, May Nyman, Tatiana Shvareva, Ginger E. Sigmon, Peter C. Burns, and Alexandra Navrotsky
Abstract
The Fukushima-Daiichi nuclear accident brought together compromised irradiated fuel and large amounts of seawater in a high radiation field. Based on newly acquired thermochemical data for a series of uranyl peroxide compounds containing charge-balancing alkali cations, here we show that nanoscale cage clusters containing as many as 60 uranyl ions, bonded through peroxide and hydroxide bridges, are likely to form in solution or as precipitates under such conditions. These species will enhance the corrosion of the damaged fuel and, being thermodynamically stable and kinetically persistent in the absence of peroxide, they can potentially transport uranium over long distances.
Frozen water blamed for leaks at Fukushima plant
ReplyDeleteTokyo Electric Power Company has found water leaks in 14 locations at the Fukushima Daiichi nuclear plant.
The utility says the leaks apparently occurred after frozen water ruptured the pipes and the leaked water did not contain any radioactive materials.
Tokyo Electric said about 40 liters of water leaked from a cooling system for a spent fuel pool at the No.4 reactor on Sunday, but the flow stopped when workers closed the valve.
The company said the leak forced the system to stop for one hour and 40 minutes, but the pool's temperature did not rise.
Tokyo Electric said 7 tons of water had leaked from the No.6 reactor.
The temperature fell to minus 8 degrees Celsius on Sunday morning near the damaged plant.
Ruptured pipes caused 3 water leaks on the previous day.
Tokyo Electric official Junichi Matsumoto admitted that the utility failed to take sufficient steps to prevent frozen pipes. He said it will take quick action to protect the pipes from the cold weather.
Sunday, January 29, 2012 23:42 +0900 (JST)
http://enenews.com/tepco-frozen-water-ruptures-pipes-at-fukushima-plant-cooling-system-stops-at-spent-fuel-pool-no-4
http://mdn.mainichi.jp/mdnnews/news/20120128p2a00m0na013000c.html
ReplyDeleteJapan's plutonium stockpile builds as nuke fuel cycle policy hits dead end
Japan's stockpile of plutonium had reached 45 metric tons by the end of 2010, inviting suspicion from the international community about what Japan intended to do with the fissile material. As a result, much hope has been pinned on a MOX fuel reactor being built in northern Japan to eventually consume that excess plutonium.
MOX fuel is a mix of plutonium and different uranium oxides produced as waste by conventional reactors, and the Japanese government had hopes that plants that can burn it -- like one now under construction by the firm J-Power in Oma, Aomori Prefecture -- would become the foundations of a new nuclear fuel cycle. That cycle, which would see the spent fuel from conventional nuclear plants used again in MOX-burning plants, has yet to come close to fruition. Meanwhile, reprocessing of spent fuel into plutonium has continued apace, making the entire program a symbol of policy inconsistency.
First of all, the only example of a functioning "full MOX" reactor -- one that burns MOX fuel exclusively -- has been an experimental reactor in France. Furthermore, a MOX fuel reactor core tends to have a smaller margin for error during shutdowns than a uranium-burning core. As such, MOX fuel reactor maker Hitachi-GE Nuclear Energy has said it has increased the capacity of safety valves that bleed off reactor vessel pressure during an emergency by 5 percent and developed high-efficiency control rods -- measures that will allow improvements to existing light boiling water reactors.
"Reactors must be tested and meet minimum standards before they can be used, which requires a certain amount of development funds," explains a Hitachi-GE Nuclear Energy official.
Another MOX option is so-called "pluthermal" reactors, which burn some of the reprocessed fuel. However, the only countries in the world still pursuing the technology are France and Japan.
"Resource-wise, pluthermal reactors have nearly no merit," says former Kyoto University Research Reactor Institute lecturer Keiji Kobayashi.
Furthermore, spent MOX fuel contains many elements that can't be dissolved in the nitric acid used during fuel reprocessing. Disposing of the waste adds to the technology's costs, while a practical disposal method has yet to be developed.
Meanwhile, the chances of directly disposing of plutonium by burying it underground in Japan are just about zero. As such, if "full MOX" reactors don't get up and running, there will be no way for the country to consume the plutonium. On the other hand, if these reactors do go on line, Japan will end up with increasing amounts of spent MOX fuel it has no way of dealing with. In the background of this dilemma is the possible cancelation of the MOX-fueled Monju fast-breeder reactor in Fukui Prefecture.
All in all, Japan's nuclear fuel cycle policy has gone down a blind alley, and shows no signs of finding its way out.
Japan's nuclear problems have no end it would appear.
http://mdn.mainichi.jp/mdnnews/news/20120128p2a00m0na013000c.html