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Plutonium in the environment

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Title: Plutonium in the environment  
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Plutonium in the environment

Since the mid-20th century, plutonium in the environment has been primarily produced by human activity. The first plants to produce plutonium for use in cold war atomic bombs were at the Hanford nuclear site, in Washington, and Mayak nuclear plant, in Russia. Over a period of four decades, “both released more than 200 million curies of radioactive isotopes into the surrounding environment -- twice the amount expelled in the Chernobyl disaster in each instance”.[1]

The majority of plutonium isotopes are short-lived on a geological timescale,[2] though it has been argued that some natural plutonium, like the long-lived 244Pu isotope, can be found in nature.[3] This isotope has been found in lunar soil,[4] meteorites,[5] and in the Oklo natural reactor.[6] However, one paper on marine sediments for plutonium in marine sediments, atomic bomb fallout is responsible for 66% of the 239Pu and 59% 240Pu found in the English Channel, while nuclear reprocessing is responsible for the majority of the 238Pu and 241Pu present in the Earth's oceans (nuclear weapons testing is only responsible for 6.5 and 16.5% of these isotopes respectively).[7]


  • Plutonium production 1
  • Bomb detonations 2
  • Bomb safety trials 3
  • Atomic batteries 4
    • Space 4.1
    • Nuclear fuel cycle 4.2
    • Chernobyl 4.3
    • Fukushima 4.4
    • Nuclear crime 4.5
  • Environmental chemistry 5
    • Overview 5.1
    • Binding to soil 5.2
    • Microbiological chemistry 5.3
  • Biology 6
  • References 7

Plutonium production

The Hanford site represents two-thirds of the nation's high-level radioactive waste by volume. Nuclear reactors line the riverbank at the Hanford Site along the Columbia River in January 1960.

Richland, Washington was the first city established to support plutonium production at the nearby Hanford nuclear site, to power the American nuclear weapons arsenals. Ozersk, Russia supported plutonium production to power the Soviet nuclear arsenals at the Mayak nuclear plant. These were the first two cities in the world to produce plutonium for use in cold war atomic bombs.[1]

In the 2013 book on a history of these two blighted cities, Plutopia: Nuclear Families, Atomic Cities, and the Great Soviet and American Plutonium Disasters (Oxford), Kate Brown explores the health of affected citizens in both the United States and Russia, and the “slow-motion disasters” that still threaten the environments where the plants are located. According to Brown, the plants at Hanford and Mayak, over a period of four decades, “both released more than 200 million curies of radioactive isotopes into the surrounding environment -- twice the amount expelled in the Chernobyl disaster in each instance”.[1]

Most of this radioactive contamination over the years at Hanford and Mayak were part of normal operations, but unforeseen accidents did occur and plant management kept this secret, as the pollution continued unabated. Even today, as pollution threats to health and the environment persist, the government keeps knowledge about the associated risks from the public.[1]

Bomb detonations

Levels of radioactivity in the trinitite glass from two different samples as measured by gamma spectroscopy on lumps of the glass. The americium content is the current content while all the other isotopes have been back calculated to shortly after the moment of detonation.
Isotropic signatures of the plutonium before and after the detonation.

About 3.5 tons of plutonium have been released into the environment by atomic bomb tests. While this might sound like a large amount it has only resulted in a very small dose to the majority of the humans on the earth. Overall the health effects of

  1. ^ a b c d Robert Lindley (2013). "Kate Brown: Nuclear "Plutopias" the Largest Welfare Program in American History". History News Network. 
  2. ^ "Plutonium" (PDF). Human Health Fact Sheet. Argonne National Laboratory, EVS. August 2005. Retrieved 2009-07-06. 
  3. ^ P.K. Kuroda, Accounts of Chemical Research, 1979, 12(2), 73-78 [2]
  4. ^ KURODA, P.K., MYERS, W.A., "Plutonium-244 Dating III Initial Ratios of Plutonium to Uranium in Lunar Samples." Radioanalyt Chem. 150, 71.
  5. ^ MYERS, W.A., and KURODA, P.K., "Plutonium-244 Dating IV. Initial Ratios of Plutonium to Uranium in the Renazzo, Mokoia and Groznaya Meteorite." J. Radioanalyt. Nucl. Chem. 152, 99.
  6. ^ KURODA, P.K., "Plutonium-244 in the Early Solar System and the Pre-Fermi Natural Reactor (The Shibata Prize Awardee's Lecture)". Geochem. J. 26, 1.
  7. ^ O.F.X. Donard, F. Bruneau, M. Moldovan, H. Garraud, V.N. Epov and D. Boust, Analytica Chimica Acta, 2007, 587, 170-179
  8. ^ Radiochemistry and Nuclear Chemistry, G. Choppin, J-O. Liljenzin and J. Rydberg, 3rd Ed, Butterworth-Heinemann, 2002
  9. ^ P.P. Parekh, T.M. Semkow, M.A. Torres, D.K. Haines, J.M. Cooper, P.M. Rosenberg and M.E. Kitto, Journal of Environmental Radioactivity, 2006, 85, 103-120
  10. ^ Y. Saito-Kokubu, F. Esaka, K. Yasuda, M. Magara, Y. Miyamoto, S. Sakurai, S. Usuda, H. Yamazaki, S. Yoshikawa and S. Nagaoka, Applied Radiation and Isotopes, 2007, 65(4), 465-468
  11. ^ S. Yoshida, Y. Muramatsu, S. Yamazaki and T. Ban-nai, Journal of Environmental Radioactivity, 2007, In Press doi:10.1016/j.jenvrad.2007.01.019
  13. ^ "Resources (martac report)" (PDF). 
  14. ^ "Alan Parkinson - 2000 National Conference - MAPW Australia". Archived from the original on 2008-02-01. 
  15. ^ Clark, David L. (2002-05-29). "Cleanup at Rocky Flats". Los Alamos National Laboratory. Stanford Synchrotron Radiation Lightsource. Retrieved 2009-07-06. 
  17. ^ (Journal of Environmental Radioactivity, 2006, 86, 143-163.)
  18. ^
  19. ^
  20. ^ Bunn, Matthew and Col-Gen. E.P. Maslin (2010). "All Stocks of Weapons-Usable Nuclear Materials Worldwide Must be Protected Against Global Terrorist Threats" (PDF). Belfer Center for Science and International Affairs, Harvard University. Retrieved July 26, 2012. 
  21. ^ "Wise Nc; Germany: Plutonium Soup As A Murder Weapon?". WISE News Communique. 2001-10-05. Retrieved 2009-07-06. 
  23. ^ Journal of Environmental Radioactivity, 2006, 88, 171-188.
  24. ^ Neu, Mary P. (Number 26, 2000). "Siderophore-Mediated Chemistry and Microbial Uptake of Plutonium" (PDF). Chemical Interactions of Actinides in the Environment (Los Alamos Science): 416–417. Retrieved 2009-07-06. 
  25. ^ John SG, Ruggiero CE, Hersman LE, Tung CS, Neu MP (July 2001). "Siderophore mediated plutonium accumulation by Microbacterium flavescens (JG-9)". Environ. Sci. Technol. 35 (14): 2942–8.  
  26. ^ "Bacterial Biotransformations for the In situ Stabilization of Plutonium" (PDF). April 2005. Retrieved 2009-07-06. 
  27. ^ "Pentetate calcium trisodium injection (Ca-DTPA)". Cerner Multum. Archived from the original on September 28, 2007. Retrieved 2009-07-06. 
  28. ^ ORISE: Radiation Emergency Assistance Center/Training Site
  29. ^ "Pentetate zinc trisodium injection (Zn-DTPA)". Cerner Multum. Archived from the original on September 28, 2007. Retrieved 2009-07-06. 


Plutonium that is inhaled by humans lodges in the lungs and is slowly translocated to the lymph nodes. Inhaled plutonium has been shown to lead to lung cancer in experimental animals.

Plutonium ingested by or injected into humans is transported in the transferrin based iron(III) transport system and then is stored in the liver in the iron store (ferritin), after an exposure to plutonium it is important to rapidly inject the subject with a chelating agent such as calcium complex[27] of DTPA.[28][29] This antidote is useful for a single one off exposure such as that which would occur if a glove box worker was to cut their hand with a Pu contaminated object. The calcium complex has faster metal binding kinetics than the zinc complex but if the calcium complex is used for a long time it tends to remove important minerals from the person. The zinc complex is less able to cause these effects.


Mary Neu (at Los Alamos in the USA) has done some work which suggests that bacteria can accumulate plutonium because the iron transport systems used by the bacteria also function as plutonium transport systems.[24][25][26]

Microbiological chemistry

Plutonium is known to bind to soil particles very strongly, see above for a X-ray spectroscopic study of plutonium in soil and concrete. While caesium has very different chemistry to the actinides, it is well known that both caesium and many of the actinides bind strongly to the minerals in soil. Hence it has been possible to use 134Cs labeled soil to study the migration of Pu and Cs is soils. It has been shown that colloidal transport processes control the migration of Cs (and will control the migration of Pu) in the soil at the Waste Isolation Pilot Plant according to R.D. Whicker and S.A. Ibrahim.[23]

Binding to soil

PuO2 formed from neutralizing highly acidic nitric acid solutions tends to form polymeric PuO2 which is resistant to complexation. Plutonium also readily shifts valences between the +3, +4, +5 and +6 states. It is common for some fraction of plutonium in solution to exist in all of these states in equilibrium.

  • PuO2(CO3)1−2
  • PuO2(CO3)2−4
  • PuO2(CO3)3−6

Plutonium like other actinides readily forms a dioxide plutonyl core (PuO2). In the environment, this plutonyl core readily complexes with carbonate as well as other oxygen moieties (OH, NO2, NO3, and SO4−2) to form charged complexes which can be readily mobile with low affinities to soil.


Environmental chemistry

One case exists of a German man who attempted to poison his ex-wife with plutonium stolen from WAK (Wiederaufbereitungsanlage Karlsruhe), a small scale reprocessing plant where he worked. He did not steal a large amount of plutonium, just rags used for wiping surfaces and a small amount of liquid waste. The man was sent to prison for his crime.[21] At least two other people were contaminated by the plutonium. Two flats in Rhineland-Palatinate were also contaminated.[22] These were later cleaned at a cost of two million euro.

There have been 18 incidences of theft or loss of highly enriched uranium (HEU) and plutonium confirmed by the IAEA.[20]

Nuclear crime

The ongoing crisis at this site includes Spent Fuel Pools on the upper floors, exposed to the elements with complex MOX and plutonium products. The Japanese Government Taskforce has asked for submissions to the International Research Institute for Nuclear Decommissioning[18] in regards to the ongoing Contaminated Water Issues.[19]


Because plutonium oxide is very involatile, most of the plutonium in the reactor was not released during the fire. However that which was released can be measured. V.I. Yoschenko et al. reported that grass and forest fires can make the caesium, strontium and plutonium become mobile in the air again.[17]


The XANES experiments done on plutonium in soil, concrete and standards of the different oxidation states.

One example of a site (military not civil) where plutonium entered the soil is Rocky Flats where in the recent past XANES (a X-ray spectroscopy) has been used to determine the chemical nature of the plutonium in the soil.[15] The XANES was used to determine the oxidation state of the plutonium, while EXAFS was used to investigate the structure of the plutonium compound present in the soil and concrete.[16]

Plutonium has been released into the environment in aqueous solution from nuclear reprocessing and uranium enrichment plants. The chemistry of this plutonium is different from that of the metal oxides formed from nuclear bomb detonations.

Nuclear fuel cycle

The US Department of Energy has conducted seawater tests and determined that the graphite casing, which was designed to withstand reentry, is stable and no release of plutonium should occur. Subsequent investigations have found no increase in the natural background radiation in the area. The Apollo 13 accident represents an extreme scenario due to the high re-entry velocities of the craft returning from cislunar space. This accident has served to validate the design of later-generation RTGs as highly safe.

In order to minimise the risk of the radioactive material being released, the fuel is typically stored in individual modular units with their own heat shielding. They are surrounded by a layer of iridium metal and encased in high-strength graphite blocks. These two materials are corrosion and heat-resistant. Surrounding the graphite blocks is an aeroshell, designed to protect the entire assembly against the heat of reentering the Earth's atmosphere. The plutonium fuel is also stored in a ceramic form that is heat-resistant, minimising the risk of vaporization and aerosolization. The ceramic is also highly insoluble.

Chain reactions do not occur inside RTGs, so a nuclear meltdown is impossible. In fact, some RTGs are designed so that fission does not occur at all; rather, forms of radioactive decay which cannot trigger other radioactive decays are used instead. As a result, the fuel in an RTG is consumed much more slowly and much less power is produced. RTGs are still a potential source of radioactive contamination: if the container holding the fuel leaks, the radioactive material will contaminate the environment. The main concern is that if an accident were to occur during launch or a subsequent passage of a spacecraft close to Earth, harmful material could be released into the atmosphere. However, this event is extremely unlikely with current RTG cask designs.

Image of (mostly) thermally isolated, RTG pellet glowing red hot because of incandescence.

Plutonium can also be introduced into the environment via the reentry of artificial satellites containing atomic batteries. There have been several such incidents, the most prominent being the Apollo 13 mission. The Apollo Lunar Surface Experiment Package carried on the Lunar Module re-entered the atmosphere over the South Pacific. Many atomic batteries have been of the Radioisotope thermoelectric generator (RTG) type. The Plutonium-238 used in RTGs has a half-life of 88 years, as opposed to the plutonium-239 used in nuclear weapons and reactors, which has a half-life of 24,100 years.

Diagram of an RTG used on the Cassini probe


Atomic batteries

Other related trials were conducted at Maralinga, South Australia where both normal bomb detonations and "safety trials" have been conducted. While the activity from the fission products has decayed away almost totally (as of 2006) the plutonium remains active.[13][14]

Plutonium has also been released into the environment in safety trials. In these experiments, nuclear bombs have been subjected to simulated accidents or detonated with an abnormal initiation of their chemical explosives. An abnormal implosion will result in a compression of the plutonium pit, which is less uniform and smaller than the designed compression in the device. In these experiments where no or very little nuclear fission occurs, plutonium metal has been scattered around the test sites. While some of these tests have been done underground, other such tests were conducted in open air. A paper on the radioisotopes left on an island by the French nuclear bombs tests of the 20th century has been printed by the International Atomic Energy Agency and a section of this report deals with plutonium contamination resulting from such tests.[12]

The two basic fission weapon designs.

Bomb safety trials

As the 239Pu/240Pu ratio only changed slightly during the Trinity detonation, it has been commented[10] that this isotope ratio for the majority of atomic bombs (in Japan the 239Pu/240Pu ratio in soil is normally in the range 0.17 to 0.19[11]) is very different than from the bomb dropped upon Nagasaki.

Some plutonium can be deposited close to the point of detonation. The glassy trinitite formed by the Trinity bomb has been examined to determine what actinides and other radioisotopes it contained. A recent paper[9] reports the levels of long lived radioisotopes in the trinitite. 152Eu and 154Eu was mainly formed by the neutron activation of the europium in the soil, and the level of radioactivity for these isotopes is highest where the neutron dose to the soil was larger. Some of the 60Co was generated by activation of the cobalt in the soil, but some was also generated by the activation of the cobalt in the steel (100 foot) tower on which the bomb stood. This 60Co from the tower would have been scattered over the site reducing the difference in the soil levels. 133Ba and 241Am were created by the neutron activation of barium and plutonium inside the bomb. The barium was present in the form of the nitrate in the chemical explosives used while the plutonium was the fissile fuel used.


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