Depleted uranium (DU; also referred to in the past as Q-metal, depletalloy or D-38) is uranium with a lower content of the fissile isotope U-235 than natural uranium. (Natural uranium is about 99.27% U-238, 0.72% U-235—the fissile isotope, and 0.0055% U-234). Uses of DU take advantage of its very high density of 19.1 g/cm3 (68.4% denser than lead). Civilian uses include counterweights in aircraft, radiation shielding in medical radiation therapy and industrial radiography equipment and containers used to transport radioactive materials. Military uses include defensive armor plating and armor-piercing projectiles.
Most depleted uranium arises as a byproduct of the production of enriched uranium for use in nuclear reactors and in the manufacture of nuclear weapons.
Enrichment processes generate uranium with a higher-than-natural
concentration of lower-mass uranium isotopes (in particular U-235, which
is the uranium isotope supporting the fission chain reaction)
with the bulk of the feed ending up as depleted uranium, in some cases
with mass fractions of U-235 and U-234 less than a third of those in
natural uranium.[2] U-238 has a much longer halflife than the lighter isotopes, and DU therefore emits less alpha radiation
than the same mass of natural uranium: the US Defense Department states
DU used in US munitions has 60% the radioactivity of natural uranium.[3]
Since the U-235 content of nuclear reactor fuel is reduced by fission, uranium recovered by nuclear reprocessing
from spent nuclear reactor fuel made from natural uranium will have a
lower-than-natural U-235 concentration. Such ‘reactor-depleted’ material
will have different isotopic ratios from enrichment byproduct DU, and
can be distinguished from it by the presence of U-236.[4] Trace transuranics (another indicator of the use of reprocessed material) have been reported to be present in some US tank armour.[3]
The use of DU in munitions is controversial because of questions about potential long-term health effects.[5][6] Normal functioning of the kidney, brain, liver, heart, and numerous other systems can be affected by uranium exposure, because uranium is a toxic metal.[7] It is weakly radioactive and remains so because of its long radioactive half-life (4.468 billion years for uranium-238, 700 million years for uranium-235). 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.[8] The aerosol or spallation frangible
powder produced during impact and combustion of depleted uranium
munitions can potentially contaminate wide areas around the impact
sites, leading to possible inhalation by human beings.[9]
The actual level of acute and chronic toxicity of DU is also a point of medical controversy. Several studies using cultured cells and laboratory rodents suggest the possibility of leukemogenic, genetic, reproductive, and neurological effects from chronic exposure.[5] 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."[10] However, the World Health Organization,
the directing and coordinating authority for health within the United
Nations which is responsible for setting health research norms and
standards, providing technical support to countries and monitoring and
assessing health trends, states that no risk of reproductive, developmental, or carcinogenic effects have been reported in humans due to DU exposure.[11][12] This report has been criticized for not including possible long term effects of DU on the human body.[13]
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