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The Ecological Dimension of Nuclear War*

Published online by Cambridge University Press:  24 August 2009

Arthur H. Westing
Affiliation:
International Peace Research Institute, Fuglehauggata 11, N-0260 Oslo 2, Norway(PR10); also Adjunct Professor of Ecology, Hampshire College, Amherst, Massachusetts, USA.

Extract

This paper examines the widespread environmental effects, sensu stricto, that would result from a large-scale nuclear war and the resultant ecological impacts. Singled out for analysis are the effects of wildfires, radioactive fallout, enhanced ultraviolet radiation, loss of atmospheric oxygen, gain in atmospheric carbon dioxide, and reductions in sunlight and temperature; also of combinations and ramifications of these adverse phenomena.

Type
Main Papers
Copyright
Copyright © Foundation for Environmental Conservation 1987

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References

ACDA (1978). Assessment of Frequently Neglected Effects in Nuclear Attacks. US Arms Control & Disarmament Agency (ACDA), Civil Defense Study Report No. 5, Washington, DC, USA: 21 +7 pp.Google Scholar
Alcalay, G.H. (1980). Aftermath of Bikini. Ecologist (London), 10, pp. 346–51.Google Scholar
Aleksandrov, V.V. & Stenchikov, G.L. (1983). On the Modelling of the Climatic Consequences of … Nuclear War. USSR Academy of Sciences Computing Centre, Moscow, USSR: 21 pp.Google Scholar
Altman, P.L. & Dittmer, D.S. (19721974). Biology Data Book, 2nd edn.Federation of American Scientists for Experimental Biology, Bethesda, Maryland, USA: xvii + 2123 pp., illustr.Google Scholar
Barton, I.J. & Paltridge, G.W. (1984). ‘Twilight at noon’ overstated. Ambio (Stockholm), 13, pp. 59–51.Google Scholar
Bates, C.G. & Roeser, J. Jun. (1928). Light intensities required for growth of coniferous seedlings. American Journal of Botany, 15, pp. 185–94.Google Scholar
Behar, A., Cohen-Boulakia, F., Sene, M. & Boudet, R. (1987). What if a nuclear warhead explodes over a one gigawatt nuclear power reactor in France? Medicine & War (London), 3, pp. 510.CrossRefGoogle Scholar
Benarie, M. (1986). Volcanoes, weather, wine and winter (nuclear). Science of the Total Environment (Amsterdam), 50, pp. 191–6.CrossRefGoogle Scholar
Bensen, D.W. & Sparrow, A.H. (Eds) (1971). Survival of Food Crops and Livestock in the Event of Nuclear War. US Atomic Energy Commission Symposium Series No. 24, Washington, DC, USA: xi + 745 pp., illustr.Google Scholar
Bergström, S. et al. ,* (1987). Effects of Nuclear War on Health and Health Services, Rev. edn. World Health Organization Publication No. A40/11, Geneva, Switzerland: 27 + 130 pp.Google Scholar
Bergthorsson, P. (1985). Sensitivity of Icelandic agriculture to climatic variations. Climatic Change (Dordrecht), 7, pp. 111–27.CrossRefGoogle Scholar
Brinkman, A.W. & McGregor, J. (1983). Solar radiation in dense Saharan aerosol in northern Nigeria. Quarterly Journal of the Royal Meteorological Society (Bracknell, England), 109, pp. 831–47.CrossRefGoogle Scholar
Broecker, W.S. (1970). Man's oxygen reserves. Science, 168, pp. 1537–8.CrossRefGoogle ScholarPubMed
Brooks, J.W., Evans, E.I., Ham, W.T. Jun. & Reid, J.D. (1952). Influence of external body radiation on mortality from thermal burns. Annals of Surgery (Philadelphia), 136, pp. 533–45.Google ScholarPubMed
Caldwell, M.M. (1981). Plant response to solar ultraviolet radiation. Pp. 170–97 in Encyclopedia of Plant Physiology, new ser. Springer-Verlag (New York), vol. 12A, chap. 6 (pp. 170–97).Google Scholar
Calkins, J. & Thordardottir, T. (1980). Ecological significance of solar UV radiation on aquatic organisms. Nature (London), 283, pp. 563–6.CrossRefGoogle Scholar
Carrier, G.F. et al. * (1985). Effects on the Atmosphere of a Major Nuclear Exchange. National Academy Press, Washington, DC, USA: ix + 193 pp., illustr.Google Scholar
Catchpole, A.J.W. & Faurer, M.-A. (1983). Summer sea-ice severity in Hudson Strait, 1751–1870. Climatic Change (Dordrecht), 5, pp. 115–39.Google Scholar
Cess, R.D., Potter, G.L., Ghan, S.J. & Gates, W.L. (1985). Climatic effects of large injections of atmospheric smoke and dust: A study of climate feedback mechanisms with one- and three-dimensional climate models. Journal of Geophysical Research (Washington), 90(D7), pp. 12937–50.CrossRefGoogle Scholar
Chazov, Y.I., Ilyin, L.A. & Guskova, A.K. (1984). Nuclear War: The Medical and Biological Consequences: Soviet Physicisans' Viewpoint. Novosti Press Agency Publishing House, Moscow, USSR: 239 pp., illustr.Google Scholar
Clark, W.C. et al. * (1982). Carbon dioxide question: perspectives for 1982. Pp. 344 in Carbon Dioxide Review 1982 (Ed. Clark, W.C.), Clarendon Press, Oxford, England, UK: 469 pp.Google Scholar
Cogley, J.G. (1985). Hypsometry of the continents. Zeitschrift für Geomorphologie (West Berlin), new ser., 53 (suppl.), pp. 148.Google Scholar
Committee for the Compilation of Materials on Damage Caused by the Atomic Bombs in Hiroshima and Nagasaki [cited as Committee] (1981). Hiroshima and Nagasaki: The Physical, Medical, and Social Effects of the Atomic Bombings (transl. from the Japanese by Ishikawa, E. & Swain, D.L.). Basic Books, New York, NY, USA: xiv + 706 pp., illustr.Google Scholar
Cotton, W.R. (1985). Atmospheric convection and nuclear winter. American Scientist (New Haven), 73, pp. 275–80.Google Scholar
Covey, C., Schneider, S.H. & Thompson, S.L. (1984). Global atmospheric effects of massive smoke injections from a nuclear war: Results from general circulation model simulations. Nature (London), 308, pp. 21–5.CrossRefGoogle Scholar
Covey, C., Thompson, S.L. & Schneider, S.H. (1985). ‘Nuclear winter’: A diagnosis of atmospheric general circulation model simulations. Journal of Geophysical Research (Washington), 90 (D3), pp. 5615–28.Google Scholar
Crutzen, P.J., Galbally, I.E. & Brühl, C. (1984). Atmospheric effects from post-nuclear fires. Climatic Change (Dordrecht), 6, pp. 323–64.Google Scholar
Daugherty, W., Levi, B. & Hippel, F.V. (19851986). Consequences of ‘limited’ nuclear attacks on the United States, International Security (Cambridge, Mass.), 10(4), pp. 345.Google Scholar
Din, A.M. & Diezi, J. (1984). Nuclear War Effects in Switzerland. Physicians for Social Responsibility, Basel, Switzerland: 43 pp. + 33 figs.Google Scholar
Ehrlich, P.R. et al. * (1983). Long-term biological consequences of nuclear war. Science, 222, pp. 1293–300.CrossRefGoogle ScholarPubMed
Ehrlich, R. (1986). We should not overstate the effects of nuclear war. International Journal on World Peace (New York), 3(3):3143. Cf. International Journal on World Peace 3(3):43–6.Google Scholar
Faber, M. et al. * (1979). Ultraviolet Radiation. Geneva, Switzerland: World Health Organization Environmental Health Criteria No. 14, 110 pp., illustr.Google Scholar
Fetter, S.A. & Tsipis, K. (1981). Catastrophic releases of radioactivity. Scientific American (New York), 244(4), pp. 33–9, 146.CrossRefGoogle Scholar
Flavin, C. (1987). Reassessing Nuclear Power: The Fallout from Chernobyl. Worldwatch Institute Paper No. 75, Washington, DC, USA: 91 pp.Google Scholar
Fryxell, P.A. (1957). Mode of reproduction of higher plants. Botanical Review (Chicago), 23, pp. 135233.CrossRefGoogle Scholar
GAO (1986). Nuclear Winter: Uncertainties Surrounding the Long-term Effects of Nuclear War. US General Accounting Office Report No. GAO/NSIAD-86–62, Washington, DC, USA: 55 pp.Google Scholar
Gerstl, S.A.W., Zardecki, A. & Wiser, H.L. (1981). Biologically damaging radiation amplified by ozone depletions. Nature (London), 294, pp. 352–4.CrossRefGoogle Scholar
Glasstone, S. & Dolan, P.J. (1977). Effects of Nuclear Weapons, 3rd edn.US Departments of Defense & Energy, Washington, DC, USA: 653 pp. + slide-rule, illustr.Google Scholar
Golding, B.W., Goldsmith, P., Machin, N.A. & Slingo, A. (1986). Importance of local mesoscale factors in any assessment of nuclear winter. Nature (London), 319, pp. 301–3.CrossRefGoogle Scholar
Greene, O., Percival, I. & Ridge, I. (1985). Nuclear Winter: The Evidence and the Risks. Polity Press, Cambridge, England, UK: 216 pp., illustr.Google Scholar
Gromyko, A. A. et al. * (1984). Global Consequences of Nuclear War and the Developing Countries. Committee of Soviet Scientists for Peace, Against the Nuclear Threat, Moscow, USSR: 42 pp.Google Scholar
Gunter, G. & Hildebrand, H.H. (1951). Destruction of fishes and other organisms on the south Texas coast by the cold wave of January 28-February 3, 1951. Ecology, 32, pp. 731–6.Google Scholar
Hain, P.P. (1987). Interactions of insects, trees and air pollutants. Tree Physiology (Victoria, Canada), 3, pp. 93102.Google Scholar
Hare, F.K. et al. * (1985). Nuclear Winter and Associated Effects: A Canadian Appraisal of the Environmental Impact of Nuclear War. Royal Society of Canada, Ottawa, Ontario, Canada: 382 pp.Google Scholar
Harwell, M.A. (1984). Nuclear Winter: The Human and Environmental Consequences of Nuclear War. Springer-Verlag, New York, NY, USA: xix + 179 pp., illustr.Google Scholar
Hecht, A.D. et al. * (1985). Interagency Research Report for Assessing Climatic Effects of Nuclear War. US Office of Science Technology & Policy, Washington, DC, USA: 49 + 2 + 5 pp.Google Scholar
Hensel, H., Brück, K. & Raths, P. (1973). Homeothermic organisms. Pp. 503732 in Temperature and Life (Eds Precht, H. et al. *). Springer-Verlag, West Berlin, West Germany: 779 pp.Google Scholar
Hippel, F. von & Cochran, T.B. (1986). Chernobyl: the emerging story: estimating long-term health effects. Bulletin of the Atomic Scientists (Chicago), 43(7), pp. 1824.Google Scholar
Hobbs, P.V. (1985). ‘Nuclear winter’ calculations. Science, 228, p. 648.Google Scholar
Hohenemser, C., Deicher, M., Ernst, A., Hofsäss, H., Lindner, G. & Recknagel, E. (1986). Chernobyl: an early report. Environment (Washington), 28(5), pp. 613 & 3043.Google Scholar
Holdsworth, G. (1986). Evidence fora link between atmospheric thermonuclear detonations and nitric acid. Nature (London), 324, pp. 551–3.Google Scholar
Holland, H.D. (1978). Chemistry of the Atmosphere and Oceans. John Wiley, New York, NY, USA: 351 pp.Google Scholar
Hoyt, J.B. (1958). Cold summer of 1816. Annals of the Association of American Geographers (Washington), 48, pp. 118–31.Google Scholar
Hutchinson, T.C. (1967). Comparative studies of the ability of species to withstand prolonged periods of darkness. Journal of Ecology, 55, pp. 291–9.Google Scholar
Johnson, G. (1980). Paradise lost. Bulletin of the Atomic Scientists (Chicago), 36(10), pp. 24–9.CrossRefGoogle Scholar
Jokiel, P.L. (1980). Solar ultraviolet radiation and coral reef epi-fauna. Science, 207, pp. 1069–71.Google Scholar
Jones, G.N. (1951). On the number of species of plants. Scientific Monthly (Washington), 72, pp. 289–94 & 312.Google Scholar
Katz, A.M. (1982). Life After Nuclear War: The Economic and Social Impacts of Nuclear Attacks on the United States. Bal-linger, Cambridge, Massachusetts, USA: xxvii + 423 pp., illustr.Google Scholar
Keeling, C.D., Bacastow, R.B. & Whorf, T.P. (1982). Measurements of the concentration of carbon dioxide at Mauna Loa Observatory, Hawaii. Pp. 377–85 in Carbon Dioxide Review 1982 (Ed. Clark, W.C.). Clarendon Press, Oxford, England, UK: 469 pp.Google Scholar
Korstian, C.F. (1921). Effect of a late spring frost upon forest vegetation in the Wasatch Mountains of Utah. Ecology, 2(1), pp. 4752.CrossRefGoogle Scholar
Kruger, C.H. Jun et al. *, (1982). Causes and Effects of Stratospheric Ozone Reduction: An Update. National Academy Press, Washington, DC, USA: xi + 339 pp., illustr.Google Scholar
Larsson, T. (1981). Environmental effects of nuclear war. Pp. 134–50 in War and Environment (Ed. Barnaby, W.). Royal Ministry of Agriculture, Environmental Advisory Council, Stockholm, Sweden: 154 pp.Google Scholar
Laudien, H. (1973). Poikilothermic organisms: animals: activity, behavior, etc. Pp. 441–69 in Temperature and Life (Eds Precht, H. et al. *.) Springer-Verlag, West Berlin, West Germany: 779 pp.Google Scholar
Lee, R.E. Jun., Chen, C.-P. & Denlinger, D.L. (1987). Rapid cold-hardening process in insects. Science (Washington), 238, pp. 1415–7.Google Scholar
Lyons, J.M. (1973). Chilling injury in plants. Annual Review of Plant Physiology (Palo Alto, California), 24, pp. 445–66.Google Scholar
MacDonald, L. (1984). Wound in the world. Asiaweek (Hongkong), 10(28), pp. 32–8 & 43–9.Google Scholar
McNaughton, S.J., Ruess, R.W. & Coughenour, M.B. (1986). Ecological consequences of nuclear war. Nature (London), 321, pp. 483–7.CrossRefGoogle Scholar
Malingreau, J.P., Stephens, G. & Fellows, L. (1985). Remote sensing of forest fires: Kalimantan and North Borneo in 1982–83. Ambio (Stockholm), 14, pp. 314–21.Google Scholar
Malone, R.C., Auer, L.H., Glatzmaier, G.A., Wood, M.C. & Toon, O.B. (1986). Nuclear winter: three-dimensional simulations including interactive transport, scavenging, and solar heating of smoke. Journal of Geophysical Research (Washington), 91(D1), pp. 1039–53.Google Scholar
Manley, G. (1974). Central England temperatures: monthly means 1659 to 1973. Quarterly Journal of the Royal Meteorological Society (Bracknell England, UK: 100, pp. 389405.Google Scholar
Milne, D.H. & McKay, C.P. (1982). Response of marine plankton communities to a global atmospheric darkening. Pp. 297303 in Geological Implications of Impacts of Large Asteroids and Comets on the Earth. Geological Society of America, Special Paper No. 190, Boulder, Colorado, USA: 528 pp. (Eds Silver, L.T. & Schultz, P.H.).Google Scholar
Mitchell, B.R. (1981). European Historical Statistics 1750–1975, 2nd edn.Macmillan, London, England, UK: 868 pp.Google Scholar
Neftel, A., Moor, E., Oeschger, H. & Stauffer, B. (1985). Evidence from polar ice-cores for the increase in atmospheric CO2 in the past two centuries. Nature (London), 315, pp. 45–7.Google Scholar
Nier, A.O.C. et al. * (1975). Long-term Worldwide Effects of Multiple Nuclear-weapons Detonations. U.S. National Academy of Sciences, Washington, DC, USA: 213 pp., illustr.Google Scholar
Paltridge, G.W. & Hunt, G.E. (1984). Three-dimensional climate models in perspective. Ambio (Stockholm), 13, pp. 387–8.Google Scholar
Park, C. (1978). Nitric oxide production by Tunguska meteor. Acta Astronautica (Elmsford, NY), 5, pp. 523–42.Google Scholar
Parker, J. (1963). Cold resistance in woody plants. Botanical Review (Chicago), 29, pp. 123201.Google Scholar
Pearman, G.I., Etheridge, D., Silva, F. De & Fraser, P.J. (1986). Evidence of changing concentrations of atmospheric CO2, N2O and CH4 from air bubbles in Antarctic ice. Nature (London), 320, pp. 248–50.CrossRefGoogle Scholar
Penner, J.E. (1986). Uncertainties in the smoke source term for ‘nuclear winter’ studies. Nature (London), 324, pp. 222–6.CrossRefGoogle Scholar
Petersen, R.C. Jun., Landner, L. & Blanck, H. (1986). Assessment of the impact of the Chernobyl reactor accident on the biota of Swedish streams and lakes. Ambio (Stockholm), 15, pp. 327–31.Google Scholar
Peterson, J.T. & Drury, L.D. (1967). Reduced values of solar radiation with occurrence of dense smoke over the Canadian tundra. Geographical Bulletin (Ottawa), 9, pp. 269–71.Google Scholar
Pittock, A.B. et al. * (19851986). Environmental Consequences of Nuclear War, I: Physical and Atmospheric Effects, II: Ecological and Agricultural Effects. John Wiley & Sons, Chichester, England, UK: xi + 359 + 523 pp., illustr.Google Scholar
Post, J.D. (1974). Study in meteorological and trade cycle history: The economic crisis following the Napoleonic wars. Journal of Economic History (New York), 34, pp. 315–49.Google Scholar
Precht, H. (1973). Poikilothermic organisms: Animals: Limiting temperatures of life functions. Pp. 400–40 in Temperature and Life (Eds Precht, H. et al. *) Springer-Verlag, West Berlin, West Germany: 779 pp.Google Scholar
Ramberg, B. (1984). Nuclear Power Plants as Weapons for the Enemy: An Unrecognized Peril, 2nd edn.University of California Press, Berkeley, California, USA: xxxv + 193 pp., illustr.Google Scholar
Rasmussen, K.L., Clausen, H.B. & Risbo, T. (1984). Nitrate in the Greenland ice-sheet in the years following the 1908 Tunguska event. Icarus (New York), 58, pp. 101–8.Google Scholar
Rathjens, G.W. & Siegel, R.H. (19841985). Nuclear winter: Strategic significance. Issues in Science & Technology (Washington), 1(2), pp. 123–8.Google Scholar
Rathjens, G.W. & Siegel, R.H. (1985). Review of ‘The cold and the dark’ by P.R. Ehrlich et al. * Survival (London), 27, pp. 43–4.Google Scholar
Raven, P.H. (1976). Ethics and attitudes. Pp. 155–79 in Conservation of Threatened Plants (Eds Simmons, J.B. et al. *). Plenum Press, New York, NY, USA: xvi + 336 pp., illustr.CrossRefGoogle Scholar
Raven, P.H., Evert, R.F. & Curtis, H. (1981). Biology of Plants, 3rd edn.Worth, New York, NY, USA: 686 pp.Google Scholar
Regal, P.J. (1982). Pollination by wind and animals: Ecology of geographic patterns. Annual Review of Ecology & Systematics (Palo Alto, California), 13, pp. 497524.Google Scholar
Robock, A. (1984). Snow and ice feedbacks prolong effects of nuclear winter. Nature (London), 310, pp. 667–70.Google Scholar
Rotblat, J. (1981). Nuclear Radiation in Warfare. Taylor & Francis, London, England, UK: xvii + 149 pp., illustr.Google Scholar
Sakai, A. & Otsuka, K. (1970). Freezing resistance of alpine plants. Ecology, 51, pp. 665–71.Google Scholar
Sakai, A. & Weiser, C.J. (1973). Freezing resistance of trees in North America with reference to tree regions. Ecology, 54, pp. 118–26.Google Scholar
Schneider, S.H. (1987). Climate modeling. Scientific American, 256(5), pp. 7281 & 120.Google Scholar
Schultz, V. & Whicker, F.W. (1985). Ionizing radiation and nuclear war. Review of deliberations on ecological impacts. Critical Reviews in Environmental Control (Boca Raton, Florida), 15, pp. 417–27.Google Scholar
Sear, C.B., Kelly, P.M., Jones, P.O. & Goddess, C.M. (1987). Global surface-temperature responses to major volcanic eruptions. Nature (London), 330, pp. 365–7.CrossRefGoogle Scholar
Seitz, R. (1986). Siberian fire as ‘nuclear winter’ guide. Nature (London), 323, pp. 116–7.Google Scholar
Sharfman, P. et al. * (1979). Effects of Nuclear War. US Congress Office of Technology Assessment Publ. No. OTA-NS-89, Washington, DC, USA: vii + 151 pp., illustr.Google Scholar
Shetler, S.G. & Skog, L.E. (1978). Provisional Checklist of Species for Flora North America, rev. edn. Missouri Botanical Garden, St Louis, Missouri, USA: 199 pp.Google Scholar
Shinn, E.A. (1976). Coral reef recovery in Florida and the Persian Gulf. Environmental Geology (New York), 1, pp. 241–54.Google Scholar
Shirley, H.L. (1929). Influence of light intensity and light quality upon the growth of plants. American Journal of Botany, 16, pp. 354–90 + pis XXVIII–XXXII.Google Scholar
Shostakovitch, V.B. (1925). Forest conflagrations in Siberia: with special reference to the fires of 1915. Journal of Forestry (Washington), 23, pp. 365–71.Google Scholar
Singer, S.F. (1984). Is the ‘nuclear winter’ real? Nature (London), 310, p. 625.CrossRefGoogle Scholar
Singer, S.F. (1985). On a ‘nuclear winter’. Science, 227, p. 356.Google Scholar
Small, R.D. & Bush, B.W. (1985). Smoke production from multiple nuclear explosions in nonurban areas. Science, 229, pp. 465–9.Google Scholar
Smith, J.V. (1985). Review of ‘The cold and the dark’ by P.R. Ehrlich et al. Bulletin of the Atomic Scientists (Chicago), 41( 1), pp. 4951.Google Scholar
Solomon, F. & Marston, R.Q. (Eds) (1986). Medical Implications of Nuclear War. National Academy Press, Washington, DC, USA: xviii + 619 pp., illustr.Google Scholar
Stenchikov, G. (1985). Climatic consequences of nuclear war. Pp. 5382 in The Night After…: Scientists' Warning (Ed. Velikhov, Y.), Mir, Moscow, USSR: 165 pp.Google Scholar
Stommel, H., & Stommel, E. (1979). Year without a summer. Scientific American, 240(6), pp. 176–86 & 202.Google Scholar
Stothers, R.B. (1984). Great Tambora eruption in 1815 and its aftermath. Science, 224, pp. 1191–8.CrossRefGoogle ScholarPubMed
Svirezhev, Y.M. et al. * (1985). Ecological and Demographic Consequences of Nuclear War. USSR Academy of Sciences Computer Center, Moscow, USSR: iv + 267 pp., illustr.Google Scholar
Teller, E. (1984). Widespread after-effects of nuclear war. Nature (London), 310, pp. 21–4.Google Scholar
Teramura, A.M. (1983). Effects of ultraviolet-B radiation on the growth and yield of crop plants. Physiologia Plantarum (Copenhagen), 58, pp. 415–27.Google Scholar
Thompson, S.L. (1985). Global interactive transport simulations of nuclear war smoke. Nature (London), 317, pp. 35–9.Google Scholar
Thompson, S.L. & Schneider, S.H. (19851986). Nuclear winter reappraised. Foreign Affairs (New York), 64, pp. 9811005; 65, pp. 163–78.Google Scholar
Thunborg, A.I. et al. * (1981). Comprehensive Study on Nuclear Weapons. UN Centre for Disarmament Study Series No. 1, New York, NY, USA: vii + 172 pp., illustr.Google Scholar
Toumey, J.W. & Korstian, C.F. (1947). Foundations of Silviculture upon an Ecological Basis, 2nd edn, rev. John Wiley, New York, NY, USA: xxi + 468 pp., illustr.Google Scholar
Tukey, J.W. et al. * (1979). Protection Against Depletion of Stratospheric Ozone by Chlorofluorocarbons. National Academy of Sciences, Washington, DC, USA: xvii + 392 pp., illustr.Google Scholar
Turco, R.P., Toon, O.B., Park, C., Whitten, R.C., Pollack, J.B. & Noerdlinger, P. (1981). Tunguska meteor fall of 1908: Effects on stratospheric ozone. Science, 214, pp. 1923, illustr.Google Scholar
Turco, R.P., Toon, O.B., Park, C., Whitten, R.C., Pollack, J.B. & Noerdlinger, P. (1982). Analysis of the physical, chemical, optical, and historical impacts of the 1908 Tunguska meteor fall. Icarus (New York), 50, pp. 152.Google Scholar
Turco, R.P., Toon, O.B., Ackerman, T.P., Pollack, J.B. & Sagan, C. (1983). Nuclear winter: Global consequences of multiple nuclear explosions. Science, 222, pp. 1283–92.Google Scholar
Velikhov, Y. (Ed.). (1985). The Night After…: Scientists' Warning. Mir, Moscow, USSR: xviii + 165 pp., illustr.Google Scholar
Warren, S.G. & Wiscombe, W.J. (1985). Dirty snow after nuclear war. Nature (London), 313, pp. 467–70.Google Scholar
Watts, J.A. (1982). Carbon dioxide question: Data sampler. Pp. 431–69 in Carbon Dioxide Review 1982 (Ed. Clark, W.C.) Clarendon Press, Oxford, England, UK: 469 pp.Google Scholar
Weinberger, C.W. (19851986). Potential Effects of Nuclear War on the Climate. US Department of Defense, Washington, DC, USA: 17 + 5 pp.Google Scholar
Westing, A.H. (1977). Weapons of Mass Destruction and the Environment. Taylor & Francis, London, England, UK: xi + 95pp.Google Scholar
Westing, A.H. (1978). Neutron bombs and the environment. Ambio (Stockholm), 7, pp. 93–7.Google Scholar
Westing, A.H. (1980). Warfare in a Fragile World: Military Impact on the Human Environment. Taylor & Francis, London, England, UK: xiv + 249 pp.Google Scholar
Westing, A.H. (1981). Environmental impact of nuclear warfare. Environmental Conservation, 8, pp. 269–73.Google Scholar
Westing, A.H. (1982). Environmental consequences of nuclear warfare. Environmental Conservation, 9(3), pp. 269–72.Google Scholar
Westing, A.H. (1985 a). Nuclear winter: a bibliography. SIPRI Yearbook, London, 1985, pp. 126–9.Google Scholar
Westing, A.H. (1985 b). Review of ‘Nuclear winter’ by M.A. Harwell. Environment, 27(4), pp. 28–9.Google Scholar
Westing, A.H. (1986). Review of ‘Environmental consequences of nuclear war’ by A.B. Pittock et al. * Environmental Conservation, 13, pp. 281–2.Google Scholar
Wexler, H. (1950). Great smoke pall: September 24–30, 1950. Weatherwise (Philadelphia), 3, pp. 129–34 & 142.Google Scholar
Woodwell, G.M. (1970). Effects of pollution on the structure and physiology of ecosystems. Science, 168, pp. 429–33.Google Scholar
Worrest, R.C. (1983). Impact of solar ultraviolet-B radiation (290–320 nm) upon marine microalgae. Physiologia Plantarum (Copenhagen), 58, pp. 2834.Google Scholar
Worrest, R.C., Thomson, B.E. & Dyke, H. Van (1981 a). Impact of UV-B radiation upon estuarine microcosms. Photochemistry & Photobiology (London), 33, pp. 861–7.Google Scholar
Worrest, R.C., Wolniakowski, K.U., Scott, J.D., Brooker, D.L., Thomson, B.E. & Dyke, H. Van (1981 b). Sensitivity of marine phytoplankton to UV-B radiation: impact upon a model ecosystem. Photochemistry & Photobiology (London), 33, pp. 223–7.CrossRefGoogle Scholar