Nuclear winter

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Nuclear winter is a predicted climatic effect of nuclear war. It has been theorized that severely cold weather and reduced sunlight for a period of months or years could be caused by detonating large numbers of nuclear weapons, especially over flammable targets such as cities, where large amounts of smoke and soot would be ejected into the Earth's stratosphere.

Similar climatic effects can be caused by a comet or asteroid impact,[1][2] also sometimes termed an impact winter, or of a supervolcano eruption, known as a volcanic winter.[3]

Contents

Mechanism

The nuclear winter scenario predicts that the huge fires caused by nuclear explosions (particularly from burning urban areas) would loft massive amounts of dark smoke and aerosol particles from the fires into the upper troposphere / stratosphere. At 10-15 kilometers (6–9 miles) above the Earth's surface, the absorption of sunlight would further heat the smoke, lifting it into the stratosphere where the smoke would persist for years, with no rain to wash it out. This would block out much of the sun's light from reaching the surface, causing surface temperatures to drop drastically.

Consequences

Climatic effects

A study presented at the annual meeting of the American Geophysical Union in December 2006 found that even a small-scale, regional nuclear war could disrupt the global climate for a decade or more. In a regional nuclear conflict scenario where two opposing nations in the subtropics would each use 50 Hiroshima-sized nuclear weapons (about 15 kiloton each) on major populated centers, the researchers estimated as much as five million tons of soot would be released, which would produce a cooling of several degrees over large areas of North America and Eurasia, including most of the grain-growing regions. The cooling would last for years and could be "catastrophic" according to the researchers.[4][5]

Ozone depletion

A 2008 study published in the Proceedings of the National Academy of Science found that a nuclear weapons exchange between Pakistan and India using their current arsenals could create a near- global ozone hole, triggering human health problems and wreaking environmental havoc for at least a decade.[6] The computer-modeling study looked at a nuclear war between the two countries involving 50 Hiroshima-sized nuclear devices on each side, producing massive urban fires and lofting as much as five million metric tons of soot about 50 miles (80 km) into the stratosphere. The soot would absorb enough solar radiation to heat surrounding gases, setting in motion a series of chemical reactions that would break down the stratospheric ozone layer protecting Earth from harmful ultraviolet radiation.

Column ozone losses could exceed 20% globally, 25–45% at mid-latitudes, and 50–70% at northern high latitudes persisting for 5 years, with substantial losses continuing for 5 additional years. Column ozone amounts would remain near or below 220 Dobson units at all latitudes even after three years, constituting an extra-tropical “ozone hole”. Human health ailments like cataracts and skin cancer, as well as damage to plants, animals and ecosystems at mid-latitudes would likely rise sharply as ozone levels decreased and allowed more harmful UV light to reach Earth, according to the PNAS study. This study demonstrates that a small-scale, regional nuclear conflict is capable of triggering ozone losses even larger than losses that were predicted in the 1980s following a full-scale nuclear war. The missing piece back then was that the models at the time could not account for the rise of the smoke plume and consequent heating of the stratosphere.

Recent modeling

Based on new work published in 2007 and 2008 by some of the authors of the original studies, several new theories have been put forth.[7]

A minor nuclear war with each country using 50 Hiroshima-sized atom bombs as airbursts on urban areas could produce climate change unprecedented in recorded human history. A nuclear war between the United States and Russia today could produce nuclear winter, with temperatures plunging below freezing in the summer in major agricultural regions, threatening the food supply for most of the planet. The climatic effects of the smoke from burning cities and industrial areas would last for several years, much longer than previously thought. New climate model simulations, which are said to have the capability of including the entire atmosphere and oceans, show that the smoke would be lofted by solar heating to the upper stratosphere, where it would remain for years.

Compared to climate change for the past millennium, even the smallest exchange modeled would plunge the planet into temperatures colder than the Little Ice Age (the period of history between approximately 1600 A.D. and 1850 A.D.). This would take effect instantly, and agriculture would be severely threatened. Larger amounts of smoke would produce larger climate changes, and for the 150 Tg case produce a true nuclear winter, making agriculture impossible for years. In both cases, new climate model simulations show that the effects would last for more than a decade.

2007 study on global nuclear war

A study published in the Journal of Geophysical Research in July 2007[8], Nuclear winter revisited with a modern climate model and current nuclear arsenals: Still catastrophic consequences[9], used current climate models to look at the consequences of a global nuclear war involving most or all of the world's current nuclear arsenals (which the authors described as being only about a third the size of the world's arsenals twenty years earlier). The authors used a global circulation model, ModelE from the NASA Goddard Institute for Space Studies, which they noted "has been tested extensively in global warming experiments and to examine the effects of volcanic eruptions on climate." The model was used to investigate the effects of a war involving the entire current global nuclear arsenal, projected to release about 150 Tg of smoke into the atmosphere (1 Tg is equal to 1012 grams), as well as a war involving about one third of the current nuclear arsenal, projected to release about 50 Tg of smoke. In the 150 Tg case they found that:

A global average surface cooling of –7°C to –8°C persists for years, and after a decade the cooling is still –4°C (Fig. 2). Considering that the global average cooling at the depth of the last ice age 18,000 yr ago was about –5°C, this would be a climate change unprecedented in speed and amplitude in the history of the human race. The temperature changes are largest over land ... Cooling of more than –20°C occurs over large areas of North America and of more than –30°C over much of Eurasia, including all agricultural regions.

In addition, they found that this cooling caused a weakening of the global hydrological cycle, reducing global precipitation by about 45%. As for the 50 Tg case involving one third of current nuclear arsenals, they said that the simulation "produced climate responses very similar to those for the 150 Tg case, but with about half the amplitude," but that "the time scale of response is about the same." They did not discuss the implications for agriculture in depth, but noted that a 1986 study which assumed no food production for a year projected that "most of the people on the planet would run out of food and starve to death by then" and commented that their own results show that "this period of no food production needs to be extended by many years, making the impacts of nuclear winter even worse than previously thought."

Kuwait wells in the first Gulf War

Following Iraq's invasion of Kuwait, Carl Sagan and other scientists predicted that burning oil wells could cause environmental damage comparable to nuclear winter.[10] Nearly 700 oil wells were set ablaze by the retreating Iraqi army and the fires were not fully extinguished until November 6, 1991, eight months after the end of the war.[11] The fires consumed an estimated six million barrels of oil daily.

According to a 1992 study from Peter Hobbs and Lawrence Radke daily emissions of sulfur dioxide were 57% of that from electric utilities in the United States, emissions of carbon dioxide were 2% of global emissions and emissions of soot were 3400 metric tons per day.[12] However, prewar claims of widescale, long-lasting, and significant global environmental impacts were not borne out and found to be significantly exaggerated by the media and speculators[13] At the peak of the fires, the smoke absorbed 75% to 80% of the sun’s radiation. The particles were never observed to rise above 6 km and when combined with scavenging by clouds gave the smoke a short residency time in the atmosphere and localized its effects.[12] Professor Carl Sagan of the Turco, Toon, Ackerman, Pollack, Sagan (TTAPS) study hypothesized in January 1991 that enough smoke from the fires "might get so high as to disrupt agriculture in much of South Asia...." Sagan later conceded in his book The Demon-Haunted World that this prediction did not turn out to be correct: "it was pitch black at noon and temperatures dropped 4°–6°C over the Persian Gulf, but not much smoke reached stratospheric altitudes and Asia was spared." [14]

A 2007 study noted that modern computer models have been applied to the Kuwait oil fires, finding that individual smoke plumes are not able to loft smoke into the stratosphere, but that smoke from fires covering a large area, like some forest fires[15][16][17][18] or the burning of cities that would be expected to follow a nuclear strike, would loft significant amounts of smoke into the stratosphere.

History

Early work

In 1974, John Hampson suggested that a full-scale nuclear exchange could result in depletion of the ozone shield, possibly subjecting the earth to ultraviolet radiation for a year or more.[19][20] In 1975, the United States National Research Council (NRC) reported on ozone depletion following nuclear war, judging that the effect of dust would probably be slight climatic cooling.[19][21]

1982

In 1981, William J. Moran began discussions and research in the NRC on the dust effects of a large exchange of nuclear warheads. An NRC study panel on the topic met in December 1981 and April 1982.[19]

As part of a study launched in 1980 by Ambio, a journal of the Royal Swedish Academy of Sciences, Paul Crutzen and John Birks circulated a draft paper in early 1982 with the first quantitative evidence of alterations in short-term climate after a nuclear war.[19] In 1982, a special issue of Ambio devoted to the possible environmental consequences of nuclear war included a paper by Crutzen and Birks anticipating the nuclear winter scenario.[22] The paper discussed particulates from large fires, nitrogen oxide, ozone depletion and the effect of nuclear twilight on agriculture. Crutzen and Birks showed that smoke injected into the atmosphere by fires in cities, forests and petroleum reserves could prevent up to 99% of sunlight from reaching the Earth's surface, with major climatic consequences: "The normal dynamic and temperature structure of the atmosphere would therefore change considerably over a large fraction of the Northern Hemisphere, which will probably lead to important changes in land surface temperatures and wind systems."[22] An important implication of their work was that a "first strike" nuclear attack would have severe consequences for the perpetrator.

1983

In 1982, the so-called TTAPS team (R.P. Turco, O.B. Toon, T.P. Ackerman, J.B. Pollack and C.S. Sagan) undertook a computational modeling study of the atmospheric consequences of nuclear war, publishing their results in Science in December 1983.[23] The phrase "nuclear winter" was coined by Turco just prior to publication.[24] In this early work, TTAPS carried out the first estimates of the total smoke and dust emissions that would result from a major nuclear exchange, and determined quantitatively the subsequent effects on the atmospheric radiation balance and temperature structure. To compute dust and smoke impacts, they employed a one-dimensional microphysics/radiative-transfer model of the Earth's lower atmosphere (to the mesopause), which defined only the vertical characteristics of the global climate perturbation.

Around this time, interest in nuclear war environmental effects also arose in the USSR. After becoming aware of the work of the Swedish Academy and, in particular, papers by N.P.Bochkov and E.I.Chazov,[25] Russian atmospheric scientist Georgy Golitsyn applied his research on dust-storms to the situation following a nuclear catastrophe.[26] His suggestion that the atmosphere would be heated and that the surface of the planet would cool appeared in The Herald of the Academy of Sciences in September 1983.[27] Upon learning of the TTAPS scenarios, Vladimir Alexandrov and G. I. Stenchikov soon published a report on the climatic consequences of nuclear war based on simulations with a two-level global circulation model, which produced results consistent with the TTAPS findings.[28]

1986

In 1984 the WMO commissioned Georgy Golitsyn and N. A. Phillips to review the state of the science. They found that studies generally assumed a scenario that half of the world's nuclear weapons would be used, ~5000 Mt, destroying approximately 1,000 cities, and creating large quantities of carbonaceous smoke - 1–2 × 1014 grams being mostly likely, with a range of 0.2 – 6.4 × 1014 grams (NAS; TTAPS assumed 2.25 × 1014). The smoke resulting would be largely opaque to solar radiation but transparent to infra-red, thus cooling by blocking sunlight but not causing warming from enhancing the greenhouse effect. The optical depth of the smoke can be much greater than unity. Forest fires resulting from non-urban targets could increase aerosol production further. Dust from near-surface explosions against hardened targets also contributes; each Mt-equivalent of explosion could release up to 5 million tons of dust, but most would quickly fall out; high altitude dust is estimated at 0.1-1 million tons per Mt-equivalent of explosion. Burning of crude oil could also contribute substantially.

The 1-D radiative-convective models used in these studies produced a range of results, with coolings up to 15-42 °C between 14 and 35 days after the war, with a "baseline" of about 20 °C. Somewhat more sophisticated calculations using 3-D GCMs (Alexandrov and Stenchikov (1983); Covey, Schneider and Thompson (1984); which would be considered primitive by modern standards) produced similar results: temperature drops of between 20 and 40 °C, though with regional variations.

All calculations show large heating (up to 80 °C) at the top of the smoke layer at about 10 km; this implies a substantial modification of the circulation there and the possibility of advection of the cloud into low latitudes and the southern hemisphere.

The report made no attempt to compare the likely human impacts of the post-war cooling to the direct deaths from explosions.

1990

In 1990, in a paper entitled "Climate and Smoke: An Appraisal of Nuclear Winter," TTAPS give a more detailed description of the short- and long-term atmospheric effects of a nuclear war using a three-dimensional model[29]:

First 1 to 3 months:

Following 1 to 3 years:

Scientific debate

The TTAPS study was widely reported and criticized in the media. Later model runs in some cases predicted less severe effects, but continued to support the overall conclusion of significant global cooling.[30][31] Recent studies (2006) substantiate that smoke from urban firestorms in a regional war would lead to long lasting global cooling but in a less dramatic manner than the nuclear winter scenario,[32][33] while a 2007 study of the effects of global nuclear war supported the conclusion that it would lead to full-scale nuclear winter.[8][9]. The concept of "nuclear winter" is based on long-term climate models. Meanwhile, the careful numerical simulation of the initial stage of the process, done by Muzafarov and Utyuzhnikov in 1995 [34], showed the effect of smoke following on a large-scale fire is local rather than global.

The original work by Sagan and others was criticized as a "myth" and "discredited theory" in the 1987 book Nuclear War Survival Skills, a civil defense manual by Cresson Kearny for the Oak Ridge National Laboratory.[35] Kearny said the maximum estimated temperature drop would be only about by 20 degrees Fahrenheit, and that this amount of cooling would last only a few days. He also suggested that a global nuclear war would indeed result in millions of deaths from hunger, but primarily due to cessation of international food supplies, rather than due to climate changes.[35]

Policy implications

In contrast to the obvious direct dangers of nuclear warfare, there is no clear evidence that the indirect dangers of nuclear winter made any substantial difference to policy.

In response to the comment "In the 1980s, you warned about the unprecedented dangers of nuclear weapons and took very daring steps to reverse the arms race," in an interview in 2000, Mikhail Gorbachev said "Models made by Russian and American scientists showed that a nuclear war would result in a nuclear winter that would be extremely destructive to all life on Earth; the knowledge of that was a great stimulus to us, to people of honor and morality, to act in that situation."[36]

See also

References

Footnotes

  1. "Comet Caused Nuclear Winter". Discover. January 2005. http://discovermagazine.com/2005/jan/comet-caused-nuclear-winter. 
  2. A Fiery Death for Dinosaurs?
  3. Supervolcanoes could trigger global freeze
  4. Regional Nuclear War Could Devastate Global Climate, Science Daily, December 11, 2006
  5. The published papers that were first presented at the AGU Meeting.
  6. Mills, M. J.; Toon, O. B.; Turco, R. P.; Kinnison, D. E.; Garcia, R. R. (2008). "Massive global ozone loss predicted following regional nuclear conflict". Proc. Natl. Acad. Sci. U.S.A. 105 (14): 5307. doi:10.1073/pnas.0710058105. PMID 18391218. as PDF
  7. Climatic Consequences of Nuclear Conflict: Department of Environmental Sciences, Rutgers University http://envsci.rutgers.edu/%7Erobock
  8. 8.0 8.1 Abstract on Journal of Geophysical Research website
  9. 9.0 9.1 paper available online from Rutgers University website
  10. Wilmington morning Star January 21’st, 1991
  11. GulfLink Summary of Oil Well fires
  12. 12.0 12.1 Hobbs, Peter V.; Radke, Lawrence F. (May 15, 1992). "Airborne Studies of the Smoke from the Kuwait Oil Fires". Science. 
  13. Hosny Khordagu, Dhari Al-Ajmi (July 1993). "Environmental impact of the Gulf War: An integrated preliminary assessment". Environmental Management 17 (4). 
  14. Sagan, Carl (1996). The demon-haunted world: science as a candle in the dark. New York: Random House. p. 257. ISBN 0-394-53512-X. 
  15. In-situ observations of mid-latitude forest fire plumes deep in the stratosphere
  16. EO Newsroom: New Images - Smoke Soars to Stratospheric Heights
  17. Observations of Boreal Forest Fire Smoke in the Stratosphere
  18. Fromm (2006). "Smoke in the Stratosphere: What Wildfires have Taught Us About Nuclear Winter". Eos Trans. AGU 87 (52 Fall Meet. Suppl.): Abstract U14A–04. http://www.agu.org/cgi-bin/SFgate/SFgate?&listenv=table&multiple=1&range=1&directget=1&application=fm06&database=%2Fdata%2Fepubs%2Fwais%2Findexes%2Ffm06%2Ffm06&maxhits=200&=%22U14A-04%22. 
  19. 19.0 19.1 19.2 19.3 Committee on the Atmospheric Effects of Nuclear Explosions, The Effects on the Atmosphere of a Major Nuclear Exchange, Washington D.C., National Academy Press, 1985
  20. Hampson J. (1974). "Photochemical war on the atmosphere". Nature 250 (5463): 189–91. doi:10.1038/250189a0. http://www.nature.com/nature/journal/v250/n5463/pdf/250189a0.pdf. 
  21. National Research Council, Long-term worldwide effects of multiple nuclear weapons detonations, Washington DC, National Academy of Sciences, 1975, p.38
  22. 22.0 22.1 Crutzen P., Birks J. (1982). "The atmosphere after a nuclear war: Twilight at noon". Ambio 11: 114–25. http://www.jstor.org/pss/4312777?cookieSet=1. 
  23. R. P. Turco, O. B. Toon, T. P. Ackerman, J. B. Pollack, and Carl Sagan (23 December 1983). "Nuclear Winter: Global Consequences of Multiple Nuclear Explosions". Science 222 (4630): 1283–92. doi:10.1126/science.222.4630.1283. PMID 17773320. http://www.sciencemag.org/cgi/content/abstract/222/4630/1283. 
  24. US Military History Companion
  25. Chazov, E.I., Vartanian, M.E. (1983). "Effects on human behaviour". In Peterson, Jeannie. The Aftermath: the human and ecological consequences of nuclear war. New York: Pantheon Books. pp. 155–63. ISBN 0-394-72042-3. 
  26. Vladimir Gubarev (2001). "Tea Drinking in The Academy. Academician G. S. Golitsyn: Agitations Of The Sea And Earth" (in Russian). Science and Life 3. http://www.nkj.ru/archive/articles/5755/. 
  27. Igor Shumeyko, Heavy dust "nuclear winter", 2003-10-08
  28. Alexandrov, V. V. and G. I. Stenchikov (1983): "On the modeling of the climatic consequences of the nuclear war" The Proceeding of Appl. Mathematics, 21 p., The Computing Center of the AS USSR, Moscow.
  29. "Nuclear Winter Theorists Pull Back" The New York Times, January 23, 1990
  30. Nuclear winter: science and politics
  31. Does Anybody Remember The Nuclear Winter?
  32. Toon, O. B., Turco, R. P., Robock, A., Bardeen, C., Oman, L., and Stenchikov, G. L. (2006). "Atmospheric effects and societal consequences of regional scale nuclear conflicts and acts of individual nuclear terrorism". Atmos. Chem. Phys. Discuss. 6: 11745–816. doi:10.5194/acpd-6-11745-2006. http://www.atmos-chem-phys-discuss.net/6/11745/2006/acpd-6-11745-2006.html. 
  33. Robock, A., Oman, L., Stenchikov, G. L., Toon, O. B., Bardeen, C., and Turco, R. P (2007). "Climatic consequences of regional nuclear conflicts". Atmos. Chem. Phys. 7: 2003–12. doi:10.5194/acp-7-2003-2007. http://www.atmos-chem-phys.net/7/2003/2007/acp-7-2003-2007.html. 
  34. Muzafarov I.F., Utyuzhnikov S.V. (1995). "Numerical modeling of convective columns above a large fire in the atmosphere". High Temperature 33 (4): 588–95. http://personalpages.manchester.ac.uk/staff/S.Utyuzhnikov/Papers/MU.pdf. 
  35. 35.0 35.1 Kearny, Cresson (1987). Nuclear War Survival Skills. Cave Junction, OR: Oregon Institute of Science and Medicine. pp. 17–19. ISBN 0-942487-01-X. http://www.oism.org/nwss/. 
  36. Mikhail Gorbachev explains what's rotten in Russia

External links