Fizzle (nuclear explosion)

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If two pieces of subcritical material are not brought together fast enough, nuclear predetonation (fizzle) can occur, whereby a very small explosion will blow the bulk of the material apart with much less energy released than a proper nuclear explosion. Nuclear predetonation.svg
If two pieces of subcritical material are not brought together fast enough, nuclear predetonation (fizzle) can occur, whereby a very small explosion will blow the bulk of the material apart with much less energy released than a proper nuclear explosion.

A fizzle occurs when the detonation of a device for creating a nuclear explosion (such as a nuclear weapon) grossly fails to meet its expected yield. The bombs still detonate, but the detonation is much less than anticipated. The cause(s) for the failure can be linked to improper design, poor construction, or lack of expertise. [1] [2] All countries that have had a nuclear weapons testing program have experienced some fizzles. [3] A fizzle can spread radioactive material throughout the surrounding area, involve a partial fission reaction of the fissile material, or both. [4] For practical purposes, a fizzle can still have considerable explosive yield when compared to conventional weapons.

Contents

In multistage fission-fusion weapons, full yield of the fission primary that fails to initiate fusion ignition in the fusion secondary (or produces only a small degree of fusion) is also considered a "fizzle", as the weapon failed to reach its design yield despite the fission primary working correctly. Such fizzles can have very high yields, as in the case of Castle Koon, where the secondary stage of a device with a 1 megaton design fizzled, but its primary still generated a yield of 100 kilotons, and even the fizzled secondary still contributed another 10 kilotons, for a total yield of 110 kT.

Fusion boosting

If a deuterium-tritium mixture is placed at the center of the device to be compressed and heated by the fission explosion, a fission yield of 250 tons is sufficient to cause D-T fusion releasing high-energy fusion neutrons which will then fission much of the remaining fission fuel. This is known as a boosted fission weapon. [5] If a fission device designed for boosting is tested without the boost gas, a yield in the sub-kiloton range may indicate a successful test that the device's implosion and primary fission stages are working as designed, though this does not test the boosting process itself.

Nuclear fission tests considered to be fizzles

Tower for the Upshot-Knothole Ruth test. The explosion failed even to demolish the testing tower, only somewhat damaging it. (1953) RUTH test tower 1953-03-31.jpg
Tower for the Upshot–Knothole Ruth test. The explosion failed even to demolish the testing tower, only somewhat damaging it. (1953)
Buster Able
Considered to be the first known failure of any nuclear device. [6]
Upshot–Knothole Ruth
Testing a uranium hydride bomb. The test failed to declassify the site (erase evidence) as it left the bottom third of the 300-foot (91 m) shot tower still standing. [7]
Upshot–Knothole Ray
Similar test conducted the following month. Allegedly a shorter 100-foot (30 m) tower was chosen, to ensure that the tower would be completely destroyed. [7]
North Korean nuclear test in 2006
Russia claimed to have measured 5–15 kt yield, whereas the United States, France, and South Korea measured less than 1 kt yield. [8] This North Korean debut test was weaker than all other countries' initial tests by a factor of 20, [9] and the smallest initial test in history. [10]

Nuclear fusion tests that fizzled

Castle Koon
A thermonuclear device whose fusion secondary did not successfully ignite, with only low-level fusion burning taking place.
Short Granite
Dropped by the United Kingdom over Malden Island in the Pacific on May 15, 1957, during Operation Grapple 1, this bomb had an expected yield of over 1 megaton, but only exploded with a force of a quarter of the anticipated yield. [3] The test was still considered successful, as thermonuclear ignition occurred and contributed substantially to the bomb's yield. Another bomb dropped during Grapple 1, Purple Granite, was hoped to give an improved yield over Short Granite, but the yield was even lower.

Terrorist concerns

One month after the September 11, 2001 attacks, a CIA informant known as "Dragonfire" reported that al-Qaeda had smuggled a low-yield nuclear weapon into New York City. [11] Although the report was found to be false, concerns were expressed that even a "fizzle bomb" capable of yielding a fraction of the known 10-kiloton weapons could cause "horrific" consequences. A detonation in New York City would mean thousands of civilian casualties. [2] [12]

The nuclear weapon which detonates in Tom Clancy's The Sum of all Fears results in a fizzle, caused by tritium poisoning, which causes the secondary core to fail to ignite.

See also

Related Research Articles

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<span class="mw-page-title-main">Operation Ivy</span> Series of 1950s US nuclear tests

Operation Ivy was the eighth series of American nuclear tests, coming after Tumbler-Snapper and before Upshot–Knothole. The two explosions were staged in late 1952 at Enewetak Atoll in the Pacific Proving Ground in the Marshall Islands.

<span class="mw-page-title-main">Operation Castle</span> Series of 1950s US nuclear tests

Operation Castle was a United States series of high-yield (high-energy) nuclear tests by Joint Task Force 7 (JTF-7) at Bikini Atoll beginning in March 1954. It followed Operation Upshot–Knothole and preceded Operation Teapot.

<span class="mw-page-title-main">Operation Greenhouse</span> Series of 1950s US nuclear tests

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<span class="mw-page-title-main">Operation Upshot–Knothole</span> Series of 1950s US nuclear tests

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Red Snow was a British thermonuclear weapon, based on the US W28 design used in the B28 thermonuclear bomb and AGM-28 Hound Dog missile. The US W28 had yields of 70, 350, 1,100 and 1,450 kilotonnes of TNT and while Red Snow yields are still classified, declassified British documents indicate the existence of "kiloton Red Snow" and "megaton Red Snow" variants of the weapon, suggesting similar yield options, while other sources have suggested a yield of approximately 1 megatonne of TNT (4.2 PJ).

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

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<span class="mw-page-title-main">Boosted fission weapon</span> Type of nuclear weapon

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<span class="mw-page-title-main">Upshot-Knothole Grable</span> 1953 nuclear artillery test at the Nevada Test Site, United States

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<span class="mw-page-title-main">Operation Redwing</span> Series of 1950s US nuclear tests

Operation Redwing was a United States series of 17 nuclear test detonations from May to July 1956. They were conducted at Bikini and Enewetak atolls by Joint Task Force 7 (JTF7). The entire operation followed Project 56 and preceded Project 57. The primary intention was to test new, second-generation thermonuclear weapons. Also tested were fission devices intended to be used as primaries for thermonuclear weapons, and small tactical weapons for air defense. Redwing demonstrated the first United States airdrop of a deliverable hydrogen bomb during test Cherokee. Because the yields for many tests at Operation Castle in 1954 were dramatically higher than predictions, Redwing was conducted using an "energy budget": There were limits to the total amount of energy released, and the amount of fission yield was also strictly controlled. Fission, primarily "fast" fission of the natural uranium tamper surrounding the fusion capsule, greatly increases the yield of thermonuclear devices, and constitutes the great majority of the fallout, as nuclear fusion is a relatively clean reaction.

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<span class="mw-page-title-main">Uranium hydride bomb</span> Type of atomic bomb

The uranium hydride bomb was a variant design of the atomic bomb first suggested by Robert Oppenheimer in 1939 and advocated and tested by Edward Teller. It used deuterium, an isotope of hydrogen, as a neutron moderator in a uranium-deuterium ceramic compact. Unlike all other fission-bomb types, the concept relies on a chain reaction of slow nuclear fission. Bomb efficiency was harmed by the slowing of neutrons since the latter delays the reaction, as delineated by Rob Serber in his 1992 extension of the original Los Alamos Primer.

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References

  1. Staff Writer. "NBC Weapons: North Korean Fizzle Bomb." Strategy Page. Retrieved on 2008-05-04.
  2. 1 2 Earl Lane. "Nuclear Experts Assess the Threat of a "Backyard Bomb”." American Association for the Advancement of Science. Retrieved on 2008-05-04. Archived May 13, 2008, at the Wayback Machine
  3. 1 2 Meirion Jones." A short history of fizzles." BBC News. Retrieved on 2008-05-04.
  4. Theodore E. Liolios." The Effects of Nuclear Terrorism: Fizzles." (PDF) European Program on Science and International Security. Retrieved on 2008-05-04.
  5. http://nuclearweaponarchive.org/News/DoSuitcaseNukesExist.html Nuclear Weapon Archive, Carey Sublette: Are Suitcase Bombs Possible?
  6. Carey Sublette. "Operation Buster-Jangle 1951." Nuclear Weapon Archive. Retrieved on 2008-05-04.
  7. 1 2 Carey Sublette. "Operation Upshot-Knothole 1953 - Nevada Proving Ground." Nuclear Weapon Archive. Retrieved on 2008-05-04.
  8. Penny Spiller." N Korea test - failure or fake?." BBC News. Retrieved on 2008-05-04.
  9. Todd Crowell." A deadly kind of fizzle." Asia Times Online. Retrieved on 2008-05-04.
  10. Staff Writer. "Special report -The fizzle heard around the world." Nature.com. Retrieved on 2008-05-04.
  11. Nicholas D. Kristof. "An American Hiroshima." The New York Times. Published August 11, 2004. Retrieved on 2008-05-04.
  12. Michael A. Levi" How Likely is a Nuclear Terrorist Attack on the United States? Archived 2008-05-02 at the Wayback Machine ." Council on Foreign Relations . Retrieved on 2008-05-04.
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