Radiological warfare

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United States Navy Seabees donning NBC suits during a CBRN defense drill in 2008 Seabees assigned to U.S. Naval Mobile Construction Battalion 1 participate in a chemical, biological and radiological warfare drill Oct 081028-N-OA833-001.jpg
United States Navy Seabees donning NBC suits during a CBRN defense drill in 2008

Radiological warfare is any form of warfare involving deliberate radiation poisoning or contamination of an area with radiological sources.

Contents

Radiological weapons are normally classified as weapons of mass destruction (WMDs), [1] although radiological weapons can also be specific in whom they target, such as the radiation poisoning of Alexander Litvinenko by the Russian FSB, using radioactive polonium-210. [2]

Numerous countries have expressed an interest in radiological weapons programs, several have actively pursued them, and three have performed radiological weapons tests. [3]

Salted nuclear weapons

A salted bomb is a nuclear weapon that is equipped with a large quantity of radiologically inert salting material. The radiological warfare agents are produced through neutron capture by the salting materials of the neutron radiation emitted by the nuclear weapon. This avoids the problems of having to stockpile the highly radioactive material, as it is produced when the bomb explodes. [4] The result is a more intense fallout than from regular nuclear weapons and can render an area uninhabitable for a long period.

The cobalt bomb is an example of a radiological warfare weapon, where cobalt-59 is converted to cobalt-60 by neutron capture. Initially, gamma radiation of the nuclear fission products from an equivalent sized "clean" fission-fusion-fission bomb (assuming the amount of radioactive dust particles generated are equal) are much more intense than cobalt-60: 15,000 times more intense at 1 hour; 35 times more intense at 1 week; 5 times more intense at 1 month; and about equal at 6 months. Thereafter fission drops off rapidly so that cobalt-60 fallout is 8 times more intense than fission at 1 year and 150 times more intense at 5 years. The very long-lived isotopes produced by fission would overtake the cobalt-60 again after about 75 years. [5]

Other salted bomb variants that do not use cobalt have also been theorized. [6] [7] For example, salting with sodium-23, that transmutes to sodium-24, which because of its 15-hour half-life results in intense radiation. [8] [9]

Surface-burst nuclear weapons

An air burst is preferred if the effects of thermal radiation and blast wave is to be maximized for an area (i.e. area covered by direct line of sight and sufficient luminosity to cause burning, and formation of mach stem respectively). Both fission and fusion weapons will irradiate the detonation site with neutron radiation, causing neutron activation of the material there. Fission bombs will also contribute with the bomb-material residue. Air will not form isotopes useful for radiological warfare when neutron-activated. By detonating them at or near the surface instead, the ground will be vaporized, become radioactive, and when it cools down and condenses into particles cause significant fallout. [10]

Dirty bombs

A far lower-tech radiological weapon than those discussed above is a "dirty bomb" or radiological dispersal device, whose purpose is to disperse radioactive dust over an area. The release of radioactive material may involve no special "weapon" or side forces like a blast explosion and include no direct killing of people from its radiation source, but rather could make whole areas or structures unusable or unfavorable for the support of human life. The radioactive material may be dispersed slowly over a large area, and it can be difficult for the victims to initially know that such a radiological attack is being carried out, especially if detectors for radioactivity are not installed beforehand. [11]

Radiological warfare with dirty bombs could be used for nuclear terrorism, spreading or intensifying fear. In relation to these weapons, nation states can also spread rumor, disinformation and fear. [12] [13] [14]

In July 2023, both Ukraine and Russia blamed each other for preparing to bomb the Zaporizhzhia nuclear power plant in Ukraine, in order to use the nuclear reactors as dirty bombs. [15] [16]

See also

Further reading

Related Research Articles

<span class="mw-page-title-main">Little Boy</span> Atomic bomb dropped on Hiroshima

Little Boy was the name of the type of atomic bomb used in the bombing of the Japanese city of Hiroshima on 6 August 1945 during World War II, making it the first nuclear weapon used in warfare. The bomb was dropped by the Boeing B-29 Superfortress Enola Gay piloted by Colonel Paul W. Tibbets Jr., commander of the 509th Composite Group, and Captain Robert A. Lewis. It exploded with an energy of approximately 15 kilotons of TNT (63 TJ) and caused widespread death and destruction throughout the city. The Hiroshima bombing was the second nuclear explosion in history, after the Trinity nuclear test.

<span class="mw-page-title-main">Nuclear weapon</span>

A nuclear weapon is an explosive device that derives its destructive force from nuclear reactions, either fission or a combination of fission and fusion reactions, producing a nuclear explosion. Both bomb types release large quantities of energy from relatively small amounts of matter.

A neutron bomb, officially defined as a type of enhanced radiation weapon (ERW), is a low-yield thermonuclear weapon designed to maximize lethal neutron radiation in the immediate vicinity of the blast while minimizing the physical power of the blast itself. The neutron release generated by a nuclear fusion reaction is intentionally allowed to escape the weapon, rather than being absorbed by its other components. The neutron burst, which is used as the primary destructive action of the warhead, is able to penetrate enemy armor more effectively than a conventional warhead, thus making it more lethal as a tactical weapon.

<span class="mw-page-title-main">Nuclear fallout</span> Residual radioactive material following a nuclear blast

Nuclear fallout is the residual radioactive material propelled into the upper atmosphere following a nuclear blast, so called because it "falls out" of the sky after the explosion and the shock wave has passed. It commonly refers to the radioactive dust and ash created when a nuclear weapon explodes. The amount and spread of fallout is a product of the size of the weapon and the altitude at which it is detonated. Fallout may get entrained with the products of a pyrocumulus cloud and fall as black rain. This radioactive dust, usually consisting of fission products mixed with bystanding atoms that are neutron-activated by exposure, is a form of radioactive contamination.

A dirty bomb or radiological dispersal device is a radiological weapon that combines radioactive material with conventional explosives. The purpose of the weapon is to contaminate the area around the dispersal agent/conventional explosion with radioactive material, serving primarily as an area denial device against civilians. It is not to be confused with a nuclear explosion, such as a fission bomb, which produces blast effects far in excess of what is achievable by the use of conventional explosives. Unlike the cloud of radiation from a typical fission bomb, a dirty bomb's radiation can be dispersed only within a few hundred meters or a few miles of the explosion.

A cobalt bomb is a type of "salted bomb": a nuclear weapon designed to produce enhanced amounts of radioactive fallout, intended to contaminate a large area with radioactive material, potentially for the purpose of radiological warfare, mutual assured destruction or as doomsday devices.

<span class="mw-page-title-main">Nuclear technology</span> Technology that involves the reactions of atomic nuclei

Nuclear technology is technology that involves the nuclear reactions of atomic nuclei. Among the notable nuclear technologies are nuclear reactors, nuclear medicine and nuclear weapons. It is also used, among other things, in smoke detectors and gun sights.

<span class="mw-page-title-main">Nuclear weapon design</span> Process by which nuclear WMDs are designed and produced

Nuclear weapon designs are physical, chemical, and engineering arrangements that cause the physics package of a nuclear weapon to detonate. There are three existing basic design types:

<span class="mw-page-title-main">Operation Crossroads</span> 1946 nuclear weapon tests at Bikini Atoll

Operation Crossroads was a pair of nuclear weapon tests conducted by the United States at Bikini Atoll in mid-1946. They were the first nuclear weapon tests since Trinity on July 16, 1945, and the first detonations of nuclear devices since the atomic bombing of Nagasaki on August 9, 1945. The purpose of the tests was to investigate the effect of nuclear weapons on warships.

<span class="mw-page-title-main">Effects of nuclear explosions</span> Type and severity of damage caused by nuclear weapons

The effects of a nuclear explosion on its immediate vicinity are typically much more destructive and multifaceted than those caused by conventional explosives. In most cases, the energy released from a nuclear weapon detonated within the lower atmosphere can be approximately divided into four basic categories:

<span class="mw-page-title-main">Mushroom cloud</span> Cloud of debris and smoke from a large explosion

A mushroom cloud is a distinctive mushroom-shaped flammagenitus cloud of debris, smoke, and usually condensed water vapor resulting from a large explosion. The effect is most commonly associated with a nuclear explosion, but any sufficiently energetic detonation or deflagration will produce the same effect. They can be caused by powerful conventional weapons, like thermobaric weapons such as the ATBIP and GBU-43/B MOAB. Some volcanic eruptions and impact events can produce natural mushroom clouds.

<span class="mw-page-title-main">Nuclear and radiation accidents and incidents</span> Severe disruptive events involving fissile or fusile materials

A nuclear and radiation accident is defined by the International Atomic Energy Agency (IAEA) as "an event that has led to significant consequences to people, the environment or the facility. Examples include lethal effects to individuals, large radioactivity release to the environment, reactor core melt." The prime example of a "major nuclear accident" is one in which a reactor core is damaged and significant amounts of radioactive isotopes are released, such as in the Chernobyl disaster in 1986 and Fukushima nuclear disaster in 2011.

<span class="mw-page-title-main">Nuclear fission product</span> Atoms or particles produced by nuclear fission

Nuclear fission products are the atomic fragments left after a large atomic nucleus undergoes nuclear fission. Typically, a large nucleus like that of uranium fissions by splitting into two smaller nuclei, along with a few neutrons, the release of heat energy, and gamma rays. The two smaller nuclei are the fission products..

<span class="mw-page-title-main">Castle Bravo</span> 1954 U.S. thermonuclear weapon test in the Marshall Islands

Castle Bravo was the first in a series of high-yield thermonuclear weapon design tests conducted by the United States at Bikini Atoll, Marshall Islands, as part of Operation Castle. Detonated on March 1, 1954, the device remains the most powerful nuclear device ever detonated by the United States and the first lithium deuteride-fueled thermonuclear weapon tested using the Teller-Ulam design. Castle Bravo's yield was 15 megatonnes of TNT (63 PJ), 2.5 times the predicted 6 megatonnes of TNT (25 PJ), due to unforeseen additional reactions involving lithium-7, which led to radioactive contamination in the surrounding area.

<span class="mw-page-title-main">Samuel T. Cohen</span> American physicist (1921–2010)

Samuel Theodore Cohen was an American physicist who is generally credited as the father of the neutron bomb.

<span class="mw-page-title-main">Neutron activation</span> Induction of radioactivity by neutron radiation

Neutron activation is the process in which neutron radiation induces radioactivity in materials, and occurs when atomic nuclei capture free neutrons, becoming heavier and entering excited states. The excited nucleus decays immediately by emitting gamma rays, or particles such as beta particles, alpha particles, fission products, and neutrons. Thus, the process of neutron capture, even after any intermediate decay, often results in the formation of an unstable activation product. Such radioactive nuclei can exhibit half-lives ranging from small fractions of a second to many years.

<span class="mw-page-title-main">Isotopes of iodine</span> Nuclides with atomic number of 53 but with different mass numbers

There are 37 known isotopes of iodine (53I) from 108I to 144I; all undergo radioactive decay except 127I, which is stable. Iodine is thus a monoisotopic element.

<span class="mw-page-title-main">Cobalt-60</span> Radioactive isotope of cobalt

Cobalt-60 (60Co) is a synthetic radioactive isotope of cobalt with a half-life of 5.2714 years. It is produced artificially in nuclear reactors. Deliberate industrial production depends on neutron activation of bulk samples of the monoisotopic and mononuclidic cobalt isotope 59
Co
. Measurable quantities are also produced as a by-product of typical nuclear power plant operation and may be detected externally when leaks occur. In the latter case the incidentally produced 60
Co
 is largely the result of multiple stages of neutron activation of iron isotopes in the reactor's steel structures via the creation of its 59
Co
 precursor. The simplest case of the latter would result from the activation of 58
Fe
. 60
Co
 undergoes beta decay to the stable isotope nickel-60. The activated cobalt nucleus emits two gamma rays with energies of 1.17 and 1.33 MeV, hence the overall equation of the nuclear reaction is: 59
27Co
 + n → 60
27Co
60
28Ni
 + e + 2 γ

<span class="mw-page-title-main">Strontium-90</span> Radioactive isotope of strontium

Strontium-90 is a radioactive isotope of strontium produced by nuclear fission, with a half-life of 28.8 years. It undergoes β decay into yttrium-90, with a decay energy of 0.546 MeV. Strontium-90 has applications in medicine and industry and is an isotope of concern in fallout from nuclear weapons, nuclear weapons testing, and nuclear accidents.

A salted bomb is a nuclear weapon designed to function as a radiological weapon by producing larger quantities of radioactive fallout than unsalted nuclear arms. This fallout can render a large area uninhabitable. The term is derived both from the means of their manufacture, which involves the incorporation of additional elements to a standard atomic weapon, and from the expression "to salt the earth", meaning to render an area uninhabitable for generations. The idea originated with Hungarian-American physicist Leo Szilard, in February 1950. His intent was not to propose that such a weapon be built, but to show that nuclear weapon technology would soon reach the point where it could end human life on Earth.

References

  1. Safire, William (1998-04-19). "On Language; Weapons of Mass Destruction". The New York Times. Retrieved 2019-06-25.
  2. Addley, Esther; Harding, Luke (2016-01-21). "Key findings: who killed Alexander Litvinenko, how and why". The Guardian. ISSN   0261-3077 . Retrieved 2019-07-02.
  3. Meyer, Samuel; Bidgood, Sarah; Potter, William C. (2020-10-01). "Death Dust: The Little-Known Story of U.S. and Soviet Pursuit of Radiological Weapons". International Security. 45 (2): 51–94. doi: 10.1162/isec_a_00391 . ISSN   0162-2889.
  4. Glasstone, Samuel (1962). The Effects of Nuclear Weapons. U.S. Department of Defense, U.S. Atomic Energy Commission. pp. 464–465. 9.111 Even if a radioisotope with suitable properties and which could be readily manufactured were selected as a radiological warfare agent, the problems of production, handling, and delivery of the weapon emitting intense gamma radiation would not be easily solved. In addition, stockpiling the radioactive material would present a difficulty. ... 9.112 Instead of preparing and stockpiling the contaminating agent in advance, with its attendant difficulties, the radioactive substances are produced by fission at the time of the explosion. Radiological warfare has thus become an automatic extension of the offensive use of nuclear weapons of high fission yield.
  5. Sublette, Carey. "Nuclear Weapons Frequently Asked Questions (Section 1)" . Retrieved 25 July 2014.
  6. Glasstone, Samuel (1962). The Effects of Nuclear Weapons. U.S. Department of Defense, U.S. Atomic Energy Commission. pp. 464–465. 9.110 ... To be effective, a radiological warfare agent should emit gamma radiations and it should have a half-life of a few weeks or months. Radioisotopes of long half-life give off their radiations too slowly to be effective unless large quantities are used, and those of short half-life decay too rapidly to provide an extended hazard.
  7. Sublette, Carey (May 1, 1998). "Types of Nuclear Weapons Cobalt Bombs and Other Salted Bombs". Nuclear Weapons Archive Frequently Asked Questions. Archived from the original on September 28, 2019. Retrieved October 23, 2021.
  8. "Science: fy for Doomsday" . Time . November 24, 1961. Archived from the original on March 14, 2016.
  9. Clark, W. H. (1961). "Chemical and Thermonuclear Explosives". Bulletin of the Atomic Scientists . 17 (9): 356–360. Bibcode:1961BuAtS..17i.356C. doi:10.1080/00963402.1961.11454268.
  10. Glasstone, Samuel (1962). The Effects of Nuclear Weapons. U.S. Department of Defense, U.S. Atomic Energy Commission. pp. 28–47, 109–116, 414, 465. (page 465) 9.112 ... The explosion of such devices at low altitudes can cause radioactive contamination over large areas that are beyond the range of physical damage. Consequently, they are, in effect, weapons of radiological warfare.
  11. Lynn E. Davis; Tom LaTourette; David E. Mosher; Lois M. Davis; David R. Howell (2003). Individual Preparedness and Response to Chemical, Radiological, Nuclear, and Biological Terrorist Attacks (Report). RAND Corporation. pp. 30–31.
  12. Earl P. Stevenson; E. Gordon Arneson; Eric G. Ball; Jacob L. Devers; Willis A. Gibbons; Fredrick Osborn; Arthur W. Page (30 June 1950). Report of the Secretary of Defense's Ad Hoc Committee on Chemical, Biological and Radiological Warfare (PDF) (Report). p. 18,22. (page 18:) With respect to its advantages, the Committee has learned ... that RW (radiological warfare), as a new weapon about which most people are poorly informed, is potentiaily valuable for harassment through rumor. (page 22:) Each of these modes of warfare has an unusually high anxiety-causing potential.
  13. Lendon, Brad (2022-10-25). "What is a dirty bomb and why is Russia talking about it?". CNN.
  14. Roth, Andrew (2022-10-27). "Vladimir Putin says 'dirty bomb' claims to Nato were made on his orders". The Guardian .
  15. Sinclair, Harriet (2023-07-07). "Ukraine war - live updates: Zaporizhzhia nuclear plant could become 'dirty bomb', Ukraine warns". Yahoo! News .
  16. Edwards, Christian (2023-07-05). "Ukraine warns Russia might attack the Zaporizhzhia nuclear power plant. How worried should we be?". CNN .
  17. Fall In, Fallout: When The Us Military (Almost) Brought Radiological Weapons To The Battlefield. Al Mauroni, September 22, 2020; Modern War Institute at West Point.
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