Uranium in the environment explained

Uranium in the environment is a global health concern, and comes from both natural and man-made sources. Beyond naturally occurring uranium, mining, phosphates in agriculture, weapons manufacturing, and nuclear power are anthropogenic sources of uranium in the environment.[1]

In the natural environment, radioactivity of uranium is generally low, but uranium is a toxic metal that can disrupt normal functioning of the kidney, brain, liver, heart, and numerous other systems.[2] Chemical toxicity can cause public health issues when uranium is present in groundwater, especially if concentrations in food and water are increased by mining activity. The biological half-life (the average time it takes for the human body to eliminate half the amount in the body) for uranium is about 15 days.[3]

Uranium's radioactivity can present health and environmental issues in the case of nuclear waste produced by nuclear power plants or weapons manufacturing.

Uranium is weakly radioactive and remains so because of its long physical half-life (4.468 billion years for uranium-238). The use of depleted uranium (DU) in munitions is controversial because of questions about potential long-term health effects.[4]

Natural occurrence

Uranium is a naturally occurring element found at low levels within all rock, soil, and water. This is the highest-numbered element to be found naturally in significant quantities on Earth. According to the United Nations Scientific Committee on the Effects of Atomic Radiation the normal concentration of uranium in soil is 300 μg/kg to 11.7 mg/kg.[5]

It is considered to be more plentiful than antimony, beryllium, cadmium, gold, mercury, silver, or tungsten and is about as abundant as tin, arsenic or molybdenum. It is found in many minerals including uraninite (the most common uranium ore), autunite, uranophane, torbernite, and coffinite.[6] There are significant concentrations of uranium in some substances, such as phosphate rock deposits, and minerals such as lignite, and monazite sands in uranium-rich ores. (It is recovered commercially from these sources.) Coal fly ash from uranium-bearing coal is particularly rich in uranium, and there have been several proposals to "mine" this waste product for its uranium content.[7] [8] Because some of the ash produced in a coal power plant escapes through the smokestack, the radioactive contamination released by coal power plants in normal operation is actually higher than that of nuclear power plants.[9] [10]

Seawater contains about 3.3 parts per billion (3.3 μg/kg of uranium by weight or 3.3 micrograms per liter).[11]

Sources of uranium

Mining and milling

See main article: Uranium mining. Mining is the largest source of uranium contamination in the environment. Uranium milling creates radioactive waste in the form of tailings, which contain uranium, radium, and polonium. Consequently, uranium mining results in "the unavoidable radioactive contamination of the environment by solid, liquid and gaseous wastes".[12]

Seventy percent of global uranium resources are on or adjacent to traditional lands belonging to Indigenous people, and perceived environmental risks associated with uranium mining have resulted in environmental conflicts involving multiple actors, in which local campaigns have become national or international debates.[13]

Some of these environmental conflicts have limited uranium exploration. Incidents at Ranger Uranium Mine in the Northern Territory of Australia and disputes over Indigenous land rights led to increased opposition to development of the nearby Jabiluka deposits and suspension of that project in the early 2000s. Similarly, environmental damage from Uranium mining on traditional Navajo lands in the southwestern United States resulted in restrictions on additional mining in Navajo lands in 2005.

Occupational hazards

The radiation hazards of uranium mining and milling were not appreciated in the early years, resulting in workers being exposed to high levels of radiation. Inhalation of radon gas caused sharp increases in lung cancers among underground uranium miners employed in the 1940s and 1950s.[14]

Military activity

See also: Depleted uranium.

Military activity is a source of uranium, especially at nuclear or munitions testing sites. Depleted uranium (DU) is a byproduct of uranium enrichment that is used for defensive armor plating and armor-piercing projectiles. Uranium contamination has been found at testing sites in the UK, in Kazakhstan, and in several countries as a result of DU munitions used in the Gulf War and the Yugoslav wars. During a three-week period of conflict in 2003 in Iraq, 1,000 to 2,000 tonnes of DU munitions were used.[15]

Combustion and impact of DU munitions can produce aerosols that disperse uranium metal into the air and water where it can be inhaled or ingested by humans.[16] A United Nations Environment Programme (UNEP) study has expressed concerns about groundwater contamination from these munitions.[17] Studies of DU aerosol exposure suggest that uranium particles would quickly settle out of the air,[18] and thus should not affect populations more than a few kilometres from target areas.

Nuclear energy and waste

The nuclear power industry is also a source of uranium in the environment in the form of radioactive waste or through nuclear accidents such as Three Mile Island or the Chernobyl disaster. Perceived risks of contamination associated with this industry contribute to the anti-nuclear movement.

In 2020, there were over 250,000 metric tons of high-level radioactive waste being stored globally in temporary containers. This waste is produced by nuclear power plants and weapons facilities, and is a serious human health and environmental issue. There are plans to permanently dispose of high-level waste in deep geological repositories, but none of these are operational. Corrosion of aging temporary containers has caused some waste to leak into the environment.[19]

As spent uranium dioxide fuel is very insoluble in water, it is likely to release uranium (and fission products) even more slowly than borosilicate glass when in contact with water.[20]

Health effects

Soluble uranium salts are toxic, though less so than those of other heavy metals such as lead or mercury. The organ which is most affected is the kidney. Soluble uranium salts are readily excreted in the urine, although some accumulation in the kidneys does occur in the case of chronic exposure. The World Health Organization has established a daily "tolerated intake" of soluble uranium salts for the general public of 0.5 μg/kg body weight (or 35 μg for a 70 kg adult): exposure at this level is not thought to lead to any significant kidney damage.[21] [22]

Tiron may be used to remove uranium from the human body, in a form of chelation therapy.[23] Bicarbonate may also be used as uranium (VI) forms complexes with the carbonate ion.

Public health

Uranium mining produces toxic tailings that are radioactive and may contain other toxic elements such as radon. Dust and water leaving tailing sites may carry long-lived radioactive elements that enter water sources and the soil, increase background radiation, and eventually be ingested by humans and animals. A 2013 analysis in a medical journal found that, "The effects of all these sources of contamination on human health will be subtle and widespread, and therefore difficult to detect both clinically and epidemiologically."[24] A 2019 analysis of the global uranium industry said that the industry was shifting mining activities toward the Global South where environmental regulations are typically less stringent; and that people in impacted communities would "surely experience adverse environmental consequences" and public health issues arising from mining activities carried out by powerful multi-national corporations or mining companies based in foreign countries.[25]

Cancer

In 1950, the US Public Health service began a comprehensive study of uranium miners, leading to the first publication of a statistical correlation between cancer and uranium mining, released in 1962.[26] The federal government eventually regulated the standard amount of radon in mines, setting the level at 0.3 WL on January 1, 1969.[27]

Out of 69 present and former uranium milling sites in 12 states, 24 have been abandoned, and are the responsibility of the US Department of Energy.[28] Accidental releases from uranium mills include the 1979 Church Rock uranium mill spill in New Mexico, called the largest accident of nuclear-related waste in US history, and the 1986 Sequoyah Corporation Fuels Release in Oklahoma.[29]

In 1990, Congress passed the Radiation Exposure Compensation Act (RECA), granting reparations for those affected by mining, with amendments passed in 2000 to address criticisms with the original act.

Depleted uranium exposure studies

See also: Depleted uranium. The use of depleted uranium (DU) in munitions is controversial because of questions about potential long-term health effects.[30] Normal functioning of the kidney, brain, liver, heart, and numerous other systems can be affected by uranium exposure, because uranium is a toxic metal. Some people have raised concerns about the use of DU munitions because of its mutagenicity,[31] teratogenicity in mice,[32] [33] neurotoxicity,[34] and its suspected carcinogenic potential. Additional concerns address unexploded DU munitions leeching into groundwater over time.[35]

The toxicity of DU is a point of medical controversy. Multiple studies using cultured cells and laboratory rodents suggest the possibility of leukemogenic, genetic, reproductive, and neurological effects from chronic exposure.[36] A 2005 epidemiology review concluded: "In aggregate the human epidemiological evidence is consistent with increased risk of birth defects in offspring of persons exposed to DU."[37] The World Health Organization states that no risk of reproductive, developmental, or carcinogenic effects have been reported in humans due to DU exposure.[38] [39] This report has been criticized by Dr. Keith Baverstock for not including possible long-term effects.[40]

Birth defects

Most scientific studies have found no link between uranium and birth defects, but some claim statistical correlations between soldiers exposed to DU, and those who were not, concerning reproductive abnormalities.

One study found epidemiological evidence for increased risk of birth defects in the offspring of persons exposed to DU. Several sources have attributed an increased rate of birth defects in the children of Gulf War veterans and in Iraqis to inhalation of depleted uranium.[41] A 2001 study of 15,000 Gulf War combat veterans and 15,000 control veterans found that the Gulf War veterans were 1.8 (fathers) to 2.8 (mothers) times more likely to have children with birth defects.[42] A study of Gulf War Veterans from the UK found a 50% increased risk of malformed pregnancies reported by men over non-Gulf War veterans. The study did not find correlations between Gulf war deployment and other birth defects such as stillbirth, chromosomal malformations, or congenital syndromes. The father's service in the Gulf War was associated with increased rate of miscarriage, but the mother's service was not.[43]

In animals

Uranium causes reproductive defects and other health problems in rodents, frogs and other animals. Uranium was also shown to have cytotoxic, genotoxic and carcinogenic effects in animals.[44] [45] It has been shown in rodents and frogs that water-soluble forms of uranium are teratogenic.[32] [33]

In soil and microbiology

Bacteria and Pseudomonadota, such as Geobacter and Burkholderia fungorum (strain Rifle), can reduce and fix uranium in soil and groundwater.[46] [47] [48] These bacteria change soluble U(VI) into the highly insoluble complex-forming U(IV) ion, hence stopping chemical leaching.

It has been suggested that it is possible to form a reactive barrier by adding something to the soil which will cause the uranium to become fixed. One method of doing this is to use a mineral (apatite)[49] while a second method is to add a food substance such as acetate to the soil. This will enable bacteria to reduce the uranium(VI) to uranium(IV), which is much less soluble. In peat-like soils, the uranium will tend to bind to the humic acids; this tends to fix the uranium in the soil.[50]

Notes and References

  1. Ma . Minghao . Wang . Ruixia . Xu . Lining . Xu . Ming . Liu . Sijin . 2020-12-01 . Emerging health risks and underlying toxicological mechanisms of uranium contamination: Lessons from the past two decades . Environment International . en . 145 . 106107 . 10.1016/j.envint.2020.106107 . 32932066 . 0160-4120. free . 2020EnInt.14506107M .
  2. E. S. Craft . A. W. Abu-Qare . M. M. Flaherty . M. C. Garofolo . H. L. Rincavage . M. B. Abou-Donia . 2004 . Depleted and natural uranium: chemistry and toxicological effects . Journal of Toxicology and Environmental Health Part B: Critical Reviews . 7 . 4 . 297–317 . . 10.1080/10937400490452714 . 15205046 . 2004JTEHB...7..297C . 9357795.
  3. Web site: Georgia State University . Biological Half Lives .
  4. Pattison . John E. . Hugtenburg . Richard P. . Green . Stuart . 2010 . Enhancement of Natural Background Gamma-radiation Dose around Uranium Micro-particles in the Human Body . Journal of the Royal Society Interface . 7 . 45. 603–611 . 10.1098/rsif.2009.0300 . 19776147 . 2842777 .
  5. Book: Sources and effects of ionizing radiation : UNSCEAR 1993 Report to the General Assembly, with Scientific Annexes . United Nations Scientific Committee on the Effects of Atomic Radiation . . 978-92-1-142200-9 . 1993.
  6. Jackson . Robert A. . Montenari . Michael . 2019 . Computer modeling of Zircon (ZrSiO4)—Coffinite (USiO4) solid solutions and lead incorporation: Geological implications . Stratigraphy & Timescales . 4 . 217–227 . 10.1016/bs.sats.2019.08.005 . 9780128175521 . 210256739 .
  7. Maslov . O. D. . Tserenpil . Sh. . Norov . N. . Gustova . M. V. . Filippov . M. F. . Belov . A. G. . Altangerel . M. . Enhbat . N. . Uranium recovery from coal ash dumps of Mongolia . Solid Fuel Chemistry . December 2010 . 44 . 6 . 433–438 . 10.3103/S0361521910060133. 96643462 .
  8. Web site: Monnet . Antoine . Uranium from Coal Ash: An Outlook on Production Capacities . iaea.org . 22 March 2022.
  9. Web site: Hvistendahl . Mara . Coal Ash Is More Radioactive Than Nuclear Waste . Scientific American . 22 March 2022 .
  10. Web site: US EPA . OAR . TENORM: Coal Combustion Residuals . www.epa.gov . 22 March 2022 . 22 April 2015.
  11. Book: Ferronskiĭ . V. I. . Poliakov . V. A. . Isotopes of the Earth's hydrosphere . Springer . Dordrecht . 2012 . 978-94-007-2856-1 . 780164518 .
  12. [Benjamin K. Sovacool]
  13. Graetz . Geordan . 2014-12-01 . Uranium mining and First Peoples: the nuclear renaissance confronts historical legacies . Journal of Cleaner Production . Special Volume: The sustainability agenda of the minerals and energy supply and demand network: an integrative analysis of ecological, ethical, economic, and technological dimensions . en . 84 . 339–347 . 10.1016/j.jclepro.2014.03.055 . 0959-6526.
  14. 10.1001/jama.1989.03430050045024. 262. 5. 629–633. Roscoe. R. J.. K. Steenland . W. E. Halperin . J. J. Beaumont . R. J. Waxweiler . Lung cancer mortality among nonsmoking uranium miners exposed to radon daughters. JAMA. 1989-08-04. 2746814.
  15. Paul Brown, Gulf troops face tests for cancer guardian.co.uk 25 April 2003, Retrieved February 3, 2009
  16. Mitsakou C, Eleftheriadis K, Housiadas C, Lazaridis M Modeling of the dispersion of depleted uranium aerosol. 2003 Apr, Retrieved January 15, 2009
  17. News: UNEP confirms low-level DU contamination . March 22, 2002 . . June 18, 2006 . December 27, 2013 . https://web.archive.org/web/20131227094034/http://www.unep.org/Documents.multilingual/Default.asp?DocumentID=241&ArticleID=3036 . dead .
  18. Web site: Depleted uranium . . dead . https://web.archive.org/web/20060614010814/http://www.deploymentlink.osd.mil/du_library/du_ii/du_ii_tabl1.htm . June 14, 2006 .
  19. Web site: As nuclear waste piles up, scientists seek the best long-term storage solutions . 2023-03-12 . cen.acs.org.
  20. Web site: Crystalline Materials for Actinide Immobilisation. Imperial College Press. London. 2010. B.E.. Burakov. M.I.. Ojovan. W.E.. Lee. 2010-10-16 . dead . https://web.archive.org/web/20120309093650/http://www.icpress.co.uk/engineering/p652.html . 2012-03-09 .
  21. Web site: Focus: Depleted Uranium . . August 28, 2010 . dead . https://web.archive.org/web/20100318003818/http://www.iaea.org/NewsCenter/Features/DU/faq_depleted_uranium.shtml . March 18, 2010 .
  22. Book: HEALTH EFFECTS. Diamond. Gary. Wohlers. David. Plewak. Daneil. Llados. Fernando. Ingerman. Lisa. Wilbur. Sharon. Scinicariello. Franco. Roney. Nickolette. Faroon. Obaid. February 2013. Agency for Toxic Substances and Disease Registry (US).
  23. O.. Braun. C.. Contino. M.H.. Hengé-Napoli. E.. Ansoborlo. B.. Pucci . 1999 . Development of an in vitro test for screening of chelators of uranium . . 27 . 65–68 . 10.1051/analusis:1999108. free .
  24. Dewar . Dale . Harvey . Linda . Vakil . Cathy . 2013 . Uranium mining and health . Canadian Family Physician . 59 . 5 . 469–471 . 0008-350X . 3653646 . 23673579.
  25. Sarkar . Atanu . 2019-12-01 . Nuclear power and uranium mining: current global perspectives and emerging public health risks . Journal of Public Health Policy . en . 40 . 4 . 383–392 . 10.1057/s41271-019-00177-2 . 31292510 . 195879522 . 1745-655X.
  26. Dawson, Susan E, and Gary E Madsen. "Uranium Mine Workers, Atomic Downwinders, and the Radiation Exposure Compensation Act." In Half Lives & Half-Truths: Confronting the Radioactive Legacies of the Cold War, 117-143. Santa Fe: School For Advanced Research, 2007)
  27. Brugge, Doug, Timothy Benally, and Esther Yazzie-Lewis. The Navajo People and Uranium Mining. Albuquerque : University of New Mexico Press, 2006.
  28. http://www.atomictraveler.com/MillDecommissioningData.pdf Decommissioning of U.S. Uranium Production Facilities
  29. Doug Brugge, et al, "The Sequoyah Corporation Fuels Release and the Church Rock Spill", American Journal of Public Health, September 2007, Vol., 97, No. 9, pp. 1595-1600.
  30. News: A. L. Kennedy . July 10, 2003 . Our gift to Iraq . .
  31. Monleau . Marjorie . De Méo . Michel . Paquet . François . Chazel . Valérie . Duménil . Gérard . Donnadieu-Claraz . Marie . 1 January 2006 . Genotoxic and Inflammatory Effects of Depleted Uranium Particles Inhaled by Rats . Toxicological Sciences . 89 . 1 . 287–295 . 10.1093/toxsci/kfj010 . 16221956 . free.
  32. Darryl P. Arfsten, Kenneth R. Still & Glenn D. Ritchie . June 2001 . A review of the effects of uranium and depleted uranium exposure on reproduction and fetal development . . 17 . 5–10 . 180–191 . 10.1191/0748233701th111oa . 12539863 . 2001ToxIH..17..180A . 25310165.
  33. J. L. Domingo . 2001 . Reproductive and developmental toxicity of natural and depleted uranium: a review . Reprod. Toxicol. . 15 . 6 . 603–9 . 10.1016/S0890-6238(01)00181-2 . 11738513. 38317769 .
  34. W. Briner . J. Murray . amp . 2005 . Effects of short-term and long-term depleted uranium exposure on open-field behavior and brain lipid oxidation in rats . . 27 . 1 . 135–44 . 10.1016/j.ntt.2004.09.001 . 15681127.
  35. Sheppard . S.C. . Sheppard . M.I. . Gallerand . M.O. . Sanipelli . B. . 2005 . Derivation of ecotoxicity thresholds for uranium . . 79 . 1 . 55–83 . 10.1016/j.jenvrad.2004.05.015 . 15571876.
  36. Miller AC, McClain D. . A review of depleted uranium biological effects: in vitro and in vivo studies . Rev Environ Health . Jan–Mar 2007 . 22 . 1 . 75–89 . 17508699 . 10.1515/REVEH.2007.22.1.75 . McClain. 25156511 .
  37. Rita Hindin, Doug Brugge . Bindu Panikkar . amp . Teratogenicity of depleted uranium aerosols: A review from an epidemiological perspective . . 4 . 1 . 17 . 2005 . 16124873 . 1242351 . 10.1186/1476-069X-4-17 . free . 2005EnvHe...4...17H .
  38. Web site: Depleted uranium . World Health Organization . dead . https://web.archive.org/web/20120815092349/http://www.who.int/mediacentre/factsheets/fs257/en/ . August 15, 2012 .
  39. Web site: Depleted uranium . World Health Organization . 2011-01-26 . https://web.archive.org/web/20110126230758/http://www.who.int/ionizing_radiation/env/du/en/index.html . 2011-01-26 . dead.
  40. Web site: Depleted Uranium Weapons . Keith Baverstock.
  41. 10.1016/0165-7992(90)90130-C . Q. Y. Hu . S. P. Zhu . amp . Induction of chromosomal aberrations in male mouse germ cells by uranyl fluoride containing enriched uranium . . 244 . 3 . 209–214 . July 1990 . 2366813 .
  42. Kang . Han . Magee . Carol . Mahan . Clare . Lee . Kyung . Murphy . Frances . Jackson . Leila . Matanoski . Genevieve . Pregnancy Outcomes Among U.S. Gulf War Veterans . Annals of Epidemiology . October 2001 . 11 . 7 . 504–511 . 10.1016/S1047-2797(01)00245-9. 11557183 .
  43. Pat. Doyle. Noreen. Maconochie. Graham. Davies. Ian. Maconochie. Margo. Pelerin. Susan. Prior. Samantha. Lewis. Miscarriage, stillbirth and congenital malformation in the offspring of UK veterans of the first Gulf war. International Journal of Epidemiology. 33. 1. 74–86. February 2004. 15075150. 10.1093/ije/dyh049. free. 2006-06-18. 2008-09-05. https://web.archive.org/web/20080905224401/http://ije.oupjournals.org/cgi/content/full/33/1/74. dead.
  44. Lin . Ruey H. . Wu . Lih J. . Lee . Ching H. . Lin-Shiau . Shoei Y. . Cytogenetic toxicity of uranyl nitrate in Chinese hamster ovary cells . Mutation Research/Genetic Toxicology . November 1993 . 319 . 3 . 197–203 . 10.1016/0165-1218(93)90079-S. 7694141 .
  45. A.C.. Miller. C.. Bonait-Pellie. R.F.. Merlot. J.. Michel. M.. Stewart. P.D.. Lison . Leukemic transformation of hematopoietic cells in mice internally exposed to depleted uranium . . 279 . 1–2 . 97–104 . November 2005 . 16283518 . 10.1007/s11010-005-8226-z. 19417920 .
  46. Renshaw . Joanna C. . Butchins . Laura J. C. . Livens . Francis R. . May . Iain . Charnock . John M. . Lloyd . Jonathan R. . Bioreduction of Uranium: Environmental Implications of a Pentavalent Intermediate . Environmental Science & Technology . 1 August 2005 . 39 . 15 . 5657–5660 . 10.1021/es048232b. 16124300 . 2005EnST...39.5657R .
  47. Anderson . Robert T. . Vrionis . Helen A. . Ortiz-Bernad . Irene . Resch . Charles T. . Long . Philip E. . Dayvault . Richard . Karp . Ken . Marutzky . Sam . Metzler . Donald R. . Peacock . Aaron . White . David C. . Lowe . Mary . Lovley . Derek R. . Stimulating the In Situ Activity of Geobacter Species To Remove Uranium from the Groundwater of a Uranium-Contaminated Aquifer . Applied and Environmental Microbiology . October 2003 . 69 . 10 . 5884–5891 . 10.1128/AEM.69.10.5884-5891.2003. 14532040 . 201226 . 2003ApEnM..69.5884A .
  48. Spatial Distribution of an Uranium-Respiring Betaproteobacterium at the Rifle, CO Field Research Site. Koribanics. Nicole M.. 13 April 2015. PLOS ONE. 10.1371/journal.pone.0123378. 25874721. Tuorto. Steven J.. etal. 4395306. 10. 4. e0123378. 2015PLoSO..1023378K. free.
  49. Web site: Remediation of uranium-contaminated water at Fry Canyon, Utah . Christopher C. Fuller, John R. Bargar & James A Davis . November 20, 2003 . Stanford University.
  50. Web site: Geochemistry . dead . https://web.archive.org/web/20041212095102/http://www.magnet.fsu.edu/publications/2000annualreview/pdfs/NHMFL2000AR-Geochemistry.pdf . December 12, 2004 .