Nuclear weapon yield: Wikis


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From Wikipedia, the free encyclopedia

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The explosive yield of a nuclear weapon is the amount of energy that is discharged when a nuclear weapon is detonated, expressed usually in the equivalent mass of trinitrotoluene (TNT), either in kilotons (thousands of tons of TNT) or megatons (millions of tons of TNT), but sometimes also in terajoules (1 kiloton of TNT = 4.184 TJ). Because the precise amount of energy released by TNT is and was subject to measurement uncertainties, especially at the dawn of the nuclear age, the accepted convention is that one kt of TNT is simply defined to be 1012 calories equivalent, this being very roughly equal to the energy yield of 1,000 tons of TNT.


Examples of nuclear weapon yields

In order of increasing yield (most yield figures are approximate):

Bomb Yield Notes
Davy Crockett 0.01–1 0.042–4.2 variable yield tactical nuclear weapon—mass only 23 kg (51 lb), lightest ever deployed by the United States (same warhead as Special Atomic Demolition Munition and GAR-11 Nuclear Falcon missile)
Hiroshima's "Little Boy" gravity bomb 12–15 50–63 gun type uranium-235 fission bomb (the first of the two nuclear weapons that have been used in warfare)
Nagasaki's "Fat Man" gravity bomb 20–22 84–92 implosion type Plutonium-239 fission bomb (the second of the two nuclear weapons used in warfare)
W76 warhead 100 420 Twelve of these may be in a MIRVed Trident II missile; treaty limited to eight
B61 nuclear bomb various
  • Mod 7—up to 350 kilotonnes of TNT (1,500 TJ)
  • Mod 10—four yield options
    • 0.3 kilotonnes of TNT (1.3 TJ)
    • 1.5 kilotonnes of TNT (6.3 TJ)
    • 60 kilotonnes of TNT (250 TJ)
    • 170 kilotonnes of TNT (710 TJ)
  • Mod 11—undisclosed yield
W87 warhead 300 1,300 Ten of these were in a MIRVed LG-118A Peacekeeper.
W88 warhead 475 1,990 Twelve of these may be in a Trident II missile (treaty limited to eight)
Ivy King device 500 2,100 second most powerful pure fission bomb, 60 kg uranium, implosion type
Orange Herald 700 2,900 most powerful pure fission bomb, UK
B83 nuclear bomb variable up to 1.2 megatonnes of TNT (5.0 PJ); most powerful US weapon in active service
B53 nuclear bomb 9,000 38,000 most powerful US warhead; no longer in active service, but 50 are retained as part of the "Hedge" portion of the Enduring Stockpile; similar to the W-53 warhead that has been used in the Titan II Missile; decommissioned in 1987
Castle Bravo device 15,000 63,000 most powerful US test
EC17/Mk-17, the EC24/Mk-24, and the B41 (Mk-41) various most powerful US weapons ever: 25 megatonnes of TNT (100 PJ); the Mk-17 was also the largest by size and mass: about 20 short tons (18,000 kg); the Mk-41 had a mass of 4800 kg; gravity bombs carried by B-36 bomber (retired by 1957)
The entire Operation Castle nuclear test series 48,200 202,000 the highest-yielding test series conducted by the US
Tsar Bomba device 50,000 210,000 USSR, most powerful nuclear weapon ever detonated, mass of 27 short tons (24,000 kg), in its "full" form (i.e. with a depleted uranium tamper instead of one made of lead) it would have been 100 megatonnes of TNT (420 PJ).
All nuclear testing 510,000 2,100,000 total energy expended during all nuclear testing.[1]
Comparative fireball radii for a selection of nuclear weapons. Note that full blast effects would extend many times beyond the fireball itself.
Logarithmic scatterplot comparing the yield (in kilotons) and weight (in kilograms) of all nuclear weapons developed by the United States.

As a comparison, the blast yield of the GBU-43 Massive Ordnance Air Blast bomb is 0.011 kt, and that of the Oklahoma City bombing, using a truck-based fertilizer bomb, was 0.002 kt. Most artificial non-nuclear explosions are considerably smaller than even what are considered to be very small nuclear weapons.


Yield limits

The yield-to-weight ratio is the amount of weapon yield compared to the mass of the weapon. The theoretical maximum yield-to-weight ratio for fusion weapons is 6 megatons of TNT per metric ton (25 TJ/kg).[1] The practical achievable limit is somewhat lower, and tends to be lower for smaller, lighter weapons, of the sort that are emphasized in today's' arsenals, designed for efficient MIRV use, or delivery by cruise missile systems. The 25 MT yield option reported for the Mk-41 would give it a yield-to-weight ratio of 5.2 megatons of TNT per metric ton. While this would require a far greater efficiency than any other U.S. weapon (at least 40% efficiency in a fusion fuel of lithium deuteride), this was apparently attainable. In 1963 DOE declassified statements that the U.S. had the technological capability of deploying a 35 MT warhead on the Titan II, or a 50-60 MT gravity bomb on B-52s. Neither weapon was pursued, but either would require yield-to-weight ratios superior to a 25 MT Mk-41. For current smaller US weapons, yield is 600 to 2200 kilotons of TNT per metric ton. By comparison, for the very small tactical devices such as the Davy Crockett it was 0.4 to 40 kilotons of TNT per metric ton. For historical comparison, for Little Boy the yield was only 4 kilotons of TNT per metric ton, and for the largest Tsar Bomba yield was 2 megatons of TNT per metric ton (deliberately reduced from about twice as much). The largest pure-fission bomb ever constructed had a 500 kiloton yield, which is probably in the range of the upper limit on such designs. Fusion boosting could likely raise the efficiency of such a weapon significantly, but eventually all fission-based weapons have an upper yield limit due to the difficulties of dealing with large critical masses. However there is no known upper yield limit for a fusion bomb. Because the maximum theoretical yield-to-weight ratio is about 6 megatons of TNT per metric ton, and the maximum achieved ratio was apparently 5.2 megatons of TNT per metric ton, there is a practical limit on air delivery of the weapon. Note that most later generation weopons have eliminated the very heavy casing once thought needed for the nuclear reactions to occur efficiently - this greatly increases the achievable yield-to-weight ratio. For example, the Mk-36 bomb as built had a yield-to-weight ratio of 1.25 megatons of TNT per metric ton. If the 12,000 pound casing of the Mk-36 was reduced by 2/3s, the yield-to-weight ratio would have been 2.3 megatons of TNT per metric ton which is about the same as the later generation, much lighter 9 megaton Mk/B-53 bomb. Delivery size limites can be estimated to acertain limits to delivery of extremely high yield weapons. If the full 250 metric ton payload of the Antonov An-225 could be used, a 1.3 gigaton bomb could be delivered. Likewise the maximum limit of a missile-delivered weapon is determined by the missile payload capacity. The large Russian SS-18 ICBM has a payload capacity of 7200 kg, so the calculated maximum delivered yield would be 37.4 megatons of TNT and a Saturn V scale missile could deliver over 120 tons with a yield of about 700 megatons. Again, it is helpful for understanding to emphasize that large single warheads are seldom a part of today's arsenals, since smaller MIRV warheads are far more destructive for a given total yield or payload capacity. This effect, which results from the fact that destructive power of a single warhead scales approximately as the 2/3 power of its yield, more than makes up for the lessened yield/weight efficiency encountered if ballistic missile warheads are scaled-down from the maximal size that could be carried by a single-warhead missile.

Milestone nuclear explosions

The following list is of milestone nuclear explosions. In addition to the atomic bombings of Hiroshima and Nagasaki, the first nuclear test of a given weapon type for a country is included, and tests which were otherwise notable (such as the largest test ever). All yields (explosive power) are given in their estimated energy equivalents in kilotons of TNT (see megaton). Putative tests have not been included.

Date Name Yield (kT) Country Significance
1945-07-16 Trinity 19 United States USA First fission device test, first plutonium implosion detonation
1945-08-06 Little Boy 15 United States USA Bombing of Hiroshima, Japan, first detonation of an enriched uranium gun-type device, first use of a nuclear device in military combat
1945-08-09 Fat Man 21 United States USA Bombing of Nagasaki, Japan, last use of a nuclear device in military combat
1949-08-29 RDS-1 22 Soviet Union USSR First fission weapon test by the USSR
1952-10-03 Hurricane 25 United Kingdom UK First fission weapon test by the UK
1952-11-01 Ivy Mike 10,400 United States USA First cryogenic fusion fuel "staged" thermonuclear weapon, primarily a test device and not weaponized
1953-08-12 Joe 4 400 Soviet Union USSR First fusion weapon test by the USSR (not "staged")
1954-03-01 Castle Bravo 15,000 United States USA First dry fusion fuel "staged" thermonuclear weapon; fallout accident
1955-11-22 RDS-37 1,600 Soviet Union USSR First "staged" thermonuclear weapon test by the USSR (deployable)
1957-11-08 Grapple X 1,800 United Kingdom UK First (successful) "staged" thermonuclear weapon test by the UK
1960-02-13 Gerboise Bleue 70 France France First fission weapon test by France
1961-10-31 Tsar Bomba 57,000 Soviet Union USSR Largest thermonuclear weapon ever tested—scaled down from its initial 100 Mt design by 50%
1964-10-16 596 22 People's Republic of China PR China First fission weapon test by the People's Republic of China
1967-06-17 Test No. 6 3,300 People's Republic of China PR China First "staged" thermonuclear weapon test by the People's Republic of China
1968-08-24 Canopus 2,600 France France First "staged" thermonuclear test by France
1974-05-18 Smiling Buddha 12 India India First fission nuclear explosive test by India
1998-05-11 Pokhran-II 60[2] India India First potential fusion/boosted weapon test by India; first deployable fission weapon test by India
1998-05-28 Chagai-I 36-40 [3] Pakistan Pakistan First fission weapon test by Pakistan
2006-10-09 2006 North Korean nuclear test ~1 North Korea North Korea First fission plutonium-based device tested by North Korea; likely resulted as a fizzle
2009-05-25 2009 North Korean nuclear test 5-15 North Korea North Korea First successful fission device tested by North Korea

"Staging" refers to whether it was a "true" hydrogen bomb of the so-called Teller-Ulam configuration or simply a form of a boosted fission weapon. For a more complete list of nuclear test series, see List of nuclear tests. Some exact yield estimates, such as that of the Tsar Bomba and the tests by India and Pakistan in 1998, are somewhat contested among specialists.

Calculating yields and controversy

Yields of nuclear explosions can be very hard to calculate, even using numbers as rough as in the kiloton or megaton range (much less down to the resolution of individual terajoules). Even under very controlled conditions, precise yields can be very hard to determine, and for less controlled conditions the margins of error can be quite large. Yields can be calculated in a number of ways, including calculations based on blast size, blast brightness, seismographic data, and the strength of the shock wave. Enrico Fermi famously made a (very) rough calculation of the yield of the Trinity test by dropping small pieces of paper in the air and measuring at how far they were moved by the shock wave of the explosion.

Picture of the blast used by G.I. Taylor to estimate the yield of the device detonated during the Trinity test

A good approximation of the yield of the Trinity test device was obtained from simple dimensional analysis by the British physicist G. I. Taylor. Taylor noted that the radius R of the blast should initially depend only on the energy E of the explosion, the time t after the detonation, and the density ρ of the air. The only number having dimensions of length that can be constructed from these quantities is:

R=c\left( {\frac{{E{t}}^{2}}{\rho}} \right)^{\frac {1} {5}}

Using the picture of the Trinity test shown here (which had been publicly released by the U.S. government and published in Life magazine), Taylor estimated that at t = 0.025 s the blast radius was 140 metres. Taking ρ to be 1 kg/m³ and solving for E, he obtained that the yield was about 22 kilotons of TNT (90 TJ). This very simple argument agrees within 10% with the official value of the bomb's yield, 20 kilotons of TNT (84 TJ), which at the time that Taylor published his result was considered highly-classified information. (See G. I. Taylor, Proc. Roy. Soc. London A201, pp. 159, 175 (1950).)

Where this data is not available, as in a number of cases, precise yields have been in dispute, especially when they are tied to questions of politics. The weapons used in the atomic bombings of Hiroshima and Nagasaki, for example, were highly individual and very idiosyncratic designs, and gauging their yield retrospectively has been quite difficult. The Hiroshima bomb, "Little Boy", is estimated to have been between 12 and 18 kilotonnes of TNT (50 and 75 TJ) (a 20% margin of error), while the Nagasaki bomb, "Fat Man", is estimated to be between 18 and 23 kilotonnes of TNT (75 and 96 TJ) (a 10% margin of error). Such apparently small changes in values can be important when trying to use the data from these bombings as reflective of how other bombs would behave in combat, and also result in differing assessments of how many "Hiroshima bombs" other weapons are equivalent to (for example, the Ivy Mike hydrogen bomb was equivalent to either 867 or 578 Hiroshima weapons — a rhetorically quite substantial difference — depending on whether one uses the high or low figure for the calculation). Other disputed yields have included the massive Tsar Bomba, whose yield was claimed between being "only" 50 megatonnes of TNT (210 PJ) or at a maximum of 57 megatonnes of TNT (240 PJ) by differing political figures, either as a way for hyping the power of the bomb or as an attempt to undercut it.

See also


  1. ^ The B-41 Bomb
  2. ^
  3. ^ Pakistan Nuclear Weapons. Federation of American Scientists. December 11, 2002

External links


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