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Cockpit opening
38.1 cm (15.0 in) -- 71.1 cm (28.0 in) -- 198.1 cm (78.0 in) My black Galasport
39.4 cm (15.5 in) -- 73.7 cm (29.0 in) -- 203.2 cm (80.0 in) My blue Fox
39.0 cm (15.4 in) -- 74.0 cm (29.1 in) All new Galasports
45.0 cm (17.7 in) -- 78.0 cm (30.7 in) Fluid Donsa
38.1 cm (15.0 in) -- 67.3 cm (26.5 in) -- 188.0 cm (74.0 in) Mirage
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2.390 m (7.84 ft) Dagger CFS
2.540 m (8.33 ft) Habitat 80
3.645 m (11.96 ft) My black Galasport
3.594 m (11.79 ft) My blue Fox
4.000 m (13.123 ft) Mirage
Wausau Whitewater Park 44.957485, -89.633041
√4 = 2
Qiantang River Tidal Bore 30°16′45″N 120°23′15″E / 30.27923°N 120.387382°E
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editPhysical effects of the bomb
editAfter being selected in April 1945, Hiroshima was spared conventional bombing to serve as a pristine target, where the effects of a nuclear bomb on an undamaged city could be observed.[1] While damage could be studied later, the energy yield of the untested Little Boy design could be determined only at the moment of detonation, using instruments dropped by parachute from a plane flying in formation with the one that dropped the bomb. Radio-transmitted data from these instruments indicated a yield of about 15 kilotons.[2]
Comparing this yield to the observed damage produced a rule of thumb called the 5 psi lethal area rule. The number of immediate fatalities will approximately equal the number of people inside the area where the shock wave carries an overpressure of 5 psi or greater.[3] At Hiroshima, that area was 3.5 kilometres (2.2 mi) in diameter.[4]
The damage came from three main effects: blast, fire, and radiation.[5]
Blast
editThe blast from a nuclear bomb is the result of X-ray-heated air (the fireball) sending a shock/pressure wave in all directions at a velocity greater than the speed of sound (aka, the "Mach-Stem"),[6] analogous to thunder generated by lightning. Our knowledge about urban blast destruction is based largely on studies of Little Boy at Hiroshima. Nagasaki buildings suffered similar damage at similar distances, but the Nagasaki bomb detonated 3.2 kilometres (2.0 mi) from the city center over hilly terrain that was partially bare of buildings.[7]
In Hiroshima almost everything within 1.6 kilometres (1.0 mi) of the point directly under the explosion was completely destroyed, except for about 50 heavily reinforced, earthquake-resistant concrete buildings, only the shells of which remained standing. Most were completely gutted, with their windows, doors, sashes, and frames ripped out.[8] The perimeter of severe blast damage approximately followed the 5 psi contour at 1.8 kilometres (1.1 mi).
Later test explosions of nuclear weapons with houses and other test structures nearby confirmed the 5 psi overpressure threshold. Ordinary urban buildings experiencing it will be crushed, toppled, or gutted by the force of air pressure. The picture at right shows the effects of a nuclear-bomb-generated 5 psi pressure wave on a test structure in Nevada in 1953.[9]
A major effect of this kind of structural damage was that it created fuel for fires that were started simultaneously throughout the severe destruction region.
Fire
editThe first effect of the explosion was blinding light, accompanied by radiant heat from the fireball. The Hiroshima fireball was 370 metres (1,200 ft) in diameter, with a surface temperature of 6,000 °C (10,830 °F).[10] Near ground zero, everything flammable burst into flame. One famous, anonymous Hiroshima victim, sitting on stone steps 260 metres (850 ft) from the hypocenter, left only a shadow, having absorbed the fireball heat that permanently bleached the surrounding stone.[11] Simultaneous fires were started throughout the blast-damaged area by fireball heat and by overturned stoves and furnaces, electrical shorts, etc. Twenty minutes after the detonation, these fires had merged into a firestorm, pulling in surface air from all directions to feed an inferno which consumed everything flammable.[12]
The Hiroshima firestorm was roughly 3.2 kilometres (2.0 mi) in diameter, corresponding closely to the severe blast damage zone. (See the USSBS[13] map, right.) Blast-damaged buildings provided fuel for the fire. Structural lumber and furniture were splintered and scattered about. Debris-choked roads obstructed fire fighters. Broken gas pipes fueled the fire, and broken water pipes rendered hydrants useless.[12] At Nagasaki, the fires failed to merge into a single firestorm, and the fire-damaged area was only one fourth as great as at Hiroshmia, due in part to a southwest wind that pushed the fires away from the city.[14]
As the map shows, the Hiroshima firestorm jumped natural firebreaks (river channels), as well as prepared firebreaks. The spread of fire stopped only when it reached the edge of the blast-damaged area, encountering less available fuel.[15]
Accurate casualty figures are impossible to determine, because many victims were cremated by the firestorm, along with all record of their existence. The Manhattan Project report on Hiroshima estimated that 60% of immediate deaths were caused by fire, but with the caveat that "many persons near the center of explosion suffered fatal injuries from more than one of the bomb effects."[16] In particular, many fire victims also received lethal doses of nuclear radiation.
Radiation
editLocal fallout is dust and ash from a bomb crater, contaminated with radioactive fission products. It falls to earth downwind of the crater and can produce, with radiation alone, a lethal area much larger than that from blast and fire. With an air burst, the fission products rise into the stratosphere, where they dissipate and become part of the global environment. Because Little Boy was an air burst 580 metres (1,900 ft) above the ground, there was no bomb crater and no local radioactive fallout.[17]
However, a burst of intense neutron and gamma radiation came directly from the fireball. Its lethal radius was 1.3 kilometres (0.8 mi),[4] covering about half of the firestorm area. An estimated 30% of immediate fatalities were people who received lethal doses of this direct radiation, but died in the firestorm before their radiation injuries would have become apparent. Over 6,000 people survived the blast and fire, but died of radiation injuries.[16] Among injured survivors, 30% had radiation injuries[18] from which they recovered, but with a lifelong increase in cancer risk.[19] To date, no radiation-related evidence of heritable diseases has been observed among the survivors' children.[20][21][22]
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edit- ^ Malik 1985, p. 1.
- ^ Glasstone 1962, p. 629.
- ^ a b Glasstone & Dolan 1977, p. Nuclear Bomb Effects Computer.
- ^ Glasstone & Dolan 1977, p. 1.
- ^ Diacon 1984, p. 18.
- ^ Glasstone & Dolan 1977, pp. 300, 301.
- ^ The Atomic Bombings of Hiroshima and Nagasaki, 1946, p. 14.
- ^ Glasstone & Dolan 1977, p. 179.
- ^ Nuclear Weapon Thermal Effects 1998.
- ^ Human Shadow Etched in Stone.
- ^ a b Glasstone & Dolan 1977, pp. 300–304.
- ^ D'Olier 1946, pp. 22–25.
- ^ Glasstone & Dolan 1977, p. 304.
- ^ The Atomic Bombings of Hiroshima and Nagasaki, 1946, pp. 21–23.
- ^ a b The Atomic Bombings of Hiroshima and Nagasaki, 1946, p. 21.
- ^ Glasstone & Dolan 1977, p. 409 "An air burst, by definition, is one taking place at such a height above the earth that no appreciable quantities of surface material are taken up into the fireball. . . the deposition of early fallout from an air burst will generally not be significant. An air burst, however, may produce some induced radioactive contamination in the general vicinity of ground zero as a result of neutron capture by elements in the soil." p. 36, "at Hiroshima . . . injuries due to fallout were completely absent.".
- ^ Glasstone & Dolan 1977, pp. 545, 546.
- ^ Richardson RR 2009.
- ^ Genetic Effects.
- ^ Izumi BJC 2003.
- ^ Izumi IJC 2003.
References
edit- Abrahamson, James L.; Carew, Paul H. (2002). Vanguard of American Atomic Deterrence. Westport, Connecticut: Praeger. ISBN 978-0-275-97819-8. OCLC 49859889.
- "The Atomic Bombings of Hiroshima and Nagasaki" (PDF). The Manhattan Engineer District. 1946 Jun 29. Retrieved 2013 Nov 6.
{{cite web}}
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and|date=
(help) This report can also be found here and here. - Bernstein, Jeremy (2007). Nuclear Weapons: What You Need to Know. Cambridge University Press. ISBN 978-0-521-88408-2.
- Campbell, Richard H. (2005). The Silverplate Bombers: A History and Registry of the Enola Gay and Other B-29s Configured to Carry Atomic Bombs. Jefferson, North Carolina: McFarland & Company. ISBN 978-0-7864-2139-8. OCLC 58554961.
- Coster-Mullen, John (2012). Atom Bombs: The Top Secret Inside Story of Little Boy and Fat Man. United States: J. Coster-Mullen. OCLC 298514167.
- Diacon, Diane (1984). Residential Housing and Nuclear Attack. London: Croom Helm. p. 18. ISBN 978-0-7099-0868-5.
- D'Olier, Franklin, ed. (1946). United States Strategic Bombing Survey, Summary Report (Pacific War). Washington: United States Government Printing Office. Retrieved 2013 Nov 6.
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(help); Unknown parameter|editorlink=
ignored (|editor-link=
suggested) (help) This report can also be found here. - "Genetic Effects: Question #7". Radiation Effects Research Foundation. Retrieved 2013 Nov 6.
{{cite web}}
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(help) - Glasstone, Samuel (1962). The Effects of Nuclear Weapons, Revised Edition. United States: United States Department of Defense and United States Atomic Energy Commission. ISBN 978-1258793555.
- Glasstone, Samuel; Dolan, Philip J. (1977). The Effects of Nuclear Weapons, Third Edition. United States: United States Department of Defense and United States Department of Energy. ISBN 978-1603220163.
- Gosling, F. G. (1999). The Manhattan Project: Making the Atomic Bomb. Diane Publishing. ISBN 978-0-7881-7880-1.
- Groves, Leslie R. (1962). Now it Can Be Told: the Story of the Manhattan Project. New York: Da Capo Press (1975 reprint). ISBN 978-0-306-70738-4.
- Hansen, Chuck (1995). Volume V: US Nuclear Weapons Histories. Swords of Armageddon: US Nuclear Weapons Development since 1945. Sunnyvale, California: Chukelea Publications. ISBN 978-0-9791915-0-3. OCLC 231585284.
- Hansen, Chuck (1995a). Volume VII: The Development of US Nuclear Weapons. Swords of Armageddon: US Nuclear Weapons Development since 1945. Sunnyvale, California: Chukelea Publications. ISBN 978-0-9791915-7-2. OCLC 231585284.
- Hoddeson, Lillian; Henriksen, Paul W.; Meade, Roger A.; Westfall, Catherine L. (1993). Critical Assembly: A Technical History of Los Alamos During the Oppenheimer Years, 1943–1945. New York: Cambridge University Press. ISBN 978-0-521-44132-2. OCLC 26764320.
- "Human Shadow Etched in Stone". Photographic Display. Hiroshima Peace Memorial Museum. Retrieved 2013 Nov 6.
{{cite web}}
: Check date values in:|accessdate=
(help) - Izumi S, Koyama K, Soda M, Suyama A (2003). "Cancer incidence in children and young adults did not increase relative to parental exposure to atomic bombs". British Journal of Cancer. 89 (9): 1709–13. doi:10.1038/sj.bjc.6601322. PMC 2394417. PMID 14583774.
{{cite journal}}
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ignored (help)CS1 maint: multiple names: authors list (link) - Izumi S, Suyama A, Koyama K (2003). "Radiation-related mortality among offspring of atomic bomb survivors: a half-century of follow-up". International Journal of Cancer. 107 (2): 292–7. doi:10.1002/ijc.11400. PMID 12949810.
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ignored (help)CS1 maint: multiple names: authors list (link) - Jones, Vincent (1985). Manhattan: The Army and the Atomic Bomb (PDF). Washington, D.C.: United States Army Center of Military History. OCLC 10913875. Retrieved 25 August 2013.
- Malik, John S. (1985). "The yields of the Hiroshima and Nagasaki nuclear explosions" (PDF). Los Alamos National Laboratory report number LA-8819. Retrieved 2013 Nov 6.
{{cite web}}
: Check date values in:|accessdate=
(help) - "Nuclear Weapon Thermal Effects". Special Weapons Primer, Weapons of Mass Destruction. Federation of American Scientists. 1998. Retrieved 2013 Nov 5.
{{cite web}}
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(help) - Rhodes, Richard (1986). The Making of the Atomic Bomb. New York: Simon & Schuster. ISBN 978-0-684-81378-3. OCLC 13793436.
- Rhodes, Richard (1995). Dark Sun: The Making of the Hydrogen Bomb. New York: Touchstone. ISBN 978-0-684-82414-7.
- Richardson, David (2009). "Ionizing Radiation and Leukemia Mortality among Japanese Atomic Bomb Survivors, 1950–2000". Radiation Research. 172 (3): 368–382. doi:10.1667/RR1801.1. PMID 12949810.
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ignored (help) - Samuels, David (December 15, 2008). "Atomic John: A truck driver uncovers secrets about the first nuclear bombs". The New Yorker. Retrieved August 30, 2013.
- Serber, Robert; Crease, Robert P. (1998). Peace & War: Reminiscences of a Life on the Frontiers of Science. New York: Columbia University Press. ISBN 9780231105460. OCLC 37631186.
march 1
editOperation Crossroads
edit- This is my first nomination, so I am not sure how to proceed. I count a possible 4 points, since I am not aware of any TFA about nuclear weapons or nuclear weapons tests. At least half the article is my work. The relevant date, which would be worth only 1 point anyway, would be July 1, the 68th anniversary of the first detonation. March 1 is the 60th anniversary of the first Bikini test after Crossroads, and the test that ruined the atoll forever (that date is mentioned in passing in the article). However, I am nominating it for a non-specific date in hopes of speeding up the process.
blurb
editOperation Crossroads was a series of two nuclear weapon tests conducted by the United States at Bikini Atoll in mid-1946. They were the first nuclear detonations after World War II, and the first ever to be publicly announced beforehand and observed by an invited audience, including a large press corps. A fleet of 95 target ships was assembled in Bikini Lagoon and hit with two detonations of Fat Man plutonium implosion-type nuclear weapons, each with a yield of 23 kt (96 TJ). The first test, Able, was an air burst that sank five ships and demonstrated the survivability of ships located more than one kilometer from the explosion. The second test, Baker, was an underwater explosion (pictured), which effectively destroyed the entire target fleet with radioactive contamination. It was the first case of immediate, concentrated radioactive fallout from a nuclear explosion. The fallout from Baker and subsequent Bikini tests still renders Bikini uninhabitable. Glenn Seaborg, the longest-serving chairman of the U.S. Atomic Energy Commission, called Baker "the world's first nuclear disaster." (Full article...)
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investigating and demonstrating the effect of nuclear weapons on naval ships.