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The Arctic wasteland: a perspective on Arctic pollution

Published online by Cambridge University Press:  27 October 2009

Norman Davis
Affiliation:
Scott Polar Research Institute, University of Cambridge, Lensfield Road, Cambridge CB2 1ER

Abstract

Arctic pollution has become a focus of attention as a result of the admission byRussia of former indiscriminate dumping of radioactive waste in the Kara Sea; thus, radionuclides in the Arctic Basin have become a major cause for concern. Evidence for the bioaccumulation of toxic contaminants such as organochlorines, PCBs, and heavy metals in the Arctic food webwould seem to raise questions about this issue, there being little evidence of significant levels of radionuclide contamination in higher orders of the chain. However, there is growing evidence of a major influx of toxic material into the Arctic Basin, from riverine input and atmospheric deposition, which is transported to biologically active melt fronts. This suggests thatthe serious polluting of the Arctic Basin, combined with bioaccumulation processes, particularly for organochlorines and trace metals, is a major cause for concern. There is, then, a requirement for an overview of current information on Arctic pollutants, with a consideration of source, transport, and accumulation processes, in order to be able to apply some perspective to the situation, to quantify and qualify the problems, and to suggest appropriate actions.

Type
Articles
Copyright
Copyright © Cambridge University Press 1996

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References

Aagaard, K., and Carmack, E.C.. 1989. The role of sea ice andother fresh water in Arctic circulation. Journal of Geophysical Research 94 (C10): 14,48514,498.CrossRefGoogle Scholar
Aarkrog, A., Boelskifte, S., Dahlgaard, H., Duniec, S., Hallstadius, L., Holm, E., and Smith, J.N.. 1987. Technetium 99 and caesium-134 as long distance tracers in Arctic waters. Estuarine, Coastal and Shelf Science 24: 637647.CrossRefGoogle Scholar
Aarkrog, A., Dahlgaard, H., Hallstadius, L., Hansen, H., and Holm, E.. 1983. Radiocaesium from Sellafield effluent in Greenland waters. Nature 304: 4951.CrossRefGoogle Scholar
Ash, J.S. 1994. Cold water legacy: radionuclide contamination in the Barents and Kara seas. Cambridge: University of Cambridge (Global Security Programme Occasional Paper 3).Google Scholar
Baumann, M., and Wefer, G.. 1991. Enhanced deposition of Chernobyl radiocaesium by plankton in the Norwegian Sea: evidence from sediment trap deployments. In: Kershaw, P.J., and Woodhead, D.S. (eds). Radionuclides in the study of marine processes. London and New York: Elsevier Applied Science: 299308.CrossRefGoogle Scholar
Boehm, P., Leblanc, L., Trefry, J., Marajh-Whittemore, P., Brown, J., Schutzberg, A., and Kick, A.. 1990. Monitoring hydrocarbons and trace metals in Beaufort Sea sediments and organisms. Final report tothe US Department of the Interior, Minerals Management Service, Anchorage, Alaska.Google Scholar
Bridgman, H.A., and Bodhaine, B.A.. 1994. On the frequency of long range transport events at Point Barrow, Alaska, 1983–1992. Atmospheric Environment 28 (21): 35373549.CrossRefGoogle Scholar
Chester, R., and Bradshaw, G.F.. 1991. Source control on the distribution of participate trace elements in the North Sea atmosphere. Marine Pollution Bulletin 22: 3036.CrossRefGoogle Scholar
Chester, R., Bradshaw, G.F., Ottley, C.J., Harrison, R.M., Merrett, J.L., Preston, M.R., Rendell, A.R., Kane, M.M., and Jickells, T.D.. 1993. The atmospheric distributions of trace metals, trace organics and nitrogen species over the North Sea. Philosophical Transactions of the Royal Society of London Series A, 343: 543556.Google Scholar
Dahlgaard, H., Aarkrog, A., Hallstadius, L., Holm, E., and Rioseco, J.. 1986. Radiocaesium transport from the Irish Sea via the North Sea and the Norwegian coastal currentto East Greenland. Rapport et procès - verbaux des réunions 186: 7079.Google Scholar
Dahlgaard, H, Chen, Q.J., and Nielsen, S.P.. 1991. Radioactive tracers in the Greenland Sea. In: Kershaw, P.J., and Woodhead, D.S. (eds). Radionuclides in the study of marine processes. London and New York: Elsevier Applied Science: 1222.CrossRefGoogle Scholar
Eaton, R.D.P. 1982. Metallic contaminants of significance to Northwest Territories residents. Yellowknife: Science Advisory Board of the Northwest Territories (Contract report 6).Google Scholar
Eicken, H., and 16 others. 1987. The under-ice water layer. Berichte zur Polarforschung 39: 182189.Google Scholar
Fahrbach, E., Klindt, H., Muus, D., Rohardt, G., and Salameh, P.. 1987. Physical oceanography. Berichte zur Polarforschung 39: 156169.Google Scholar
Farrington, J.A. 1980. An overview of the biogeochemistry of fossil fuel hydrocarbons in the marine environment. In: Petrakis, L., and Weiss, F.T. (eds). Petroleum in the marine environment. Washington, DC: American Chemical Society (Advances in Chemistry Series 185).Google Scholar
Farrington, J.A., and Meyer, P.A.. 1975. Hydrocarbons in the marine environment. In: Eglinton, G. (ed). Environmental chemistry. London: The Chemical Society: I, 109136.Google Scholar
Gardner, B.D., Siegfried, W.R., and Connell, A.D.. 1985. Chlorinated hydrocarbons in seabird eggs from the southern Atlantic and Indian oceans. In: Siegfried, W.R., Condy, P.R., and Laws, R.M. (eds). Antarctic nutrient cycles and food webs. Berlin, Heidelberg, New York, and Tokyo: Springer-Verlag: 647651.CrossRefGoogle Scholar
Gaul, H. In press. Organochlorine compounds in water and sea ice of the European Arctic area. In: Roots, F., and Shearer, R. (eds). Proceedings of the conference of the Comité Arctique International on the global significance of the transport and accumulation of polychlorinated hydrocarbons in the Arctic. New York: Plenum Press.Google Scholar
Gloersen, P., Campbell, W.J., Cavalieri, D.J., Comiso, J.C., Parkinson, C.L., and Zwally, H.J.. 1992. Arctic and Antarctic sea ice, 1978–1987: satellite passive microwave observations and analysis. Washington, DC: National Aeronautical and Space Administration (Scientific and Technical Information Program, NASA SP511).Google Scholar
Gorzelska, K. 1989. Locally generated atmospheric trace metal pollution in Canadian Arctic as reflected by chemistry of snowpack samples from the Mackenzie Delta region. Atmospheric Environment 23 (12): 2729–2727.CrossRefGoogle Scholar
Gradinger, R. 1995. Climate change and biological oceanography of the Arctic Ocean. Philosophical Transactions of the Royal Society of London, Series A 352 (1699): 27772786.Google Scholar
Gran, H.H. 1931. On the conditions for production of plankton in the sea. Rapport et procès - verbaux des réunions 75: 3746.Google Scholar
Hallstadius, L, Aarkrog, A., Dahlgaard, H., Holm, E., Boelskifte, S., Duniec, S., and Persson, B.. 1986. Plutonium and americium in Arctic waters, the North Sea, and Scottish and Irish coastal zones. Journal of Environmental Radioactivity 4: 1130.CrossRefGoogle Scholar
Hansen, C.T., Nielsen, C.O., Dietz, R., and Hansen, M.M.. 1990. Zinc, cadmium, mercury and selenium in minke whales, belugas and narwhals from West Greenland. Polar Biology 10 (7): 529539.CrossRefGoogle Scholar
Hargrave, B.T., Vass, W.P., Erickson, P.E., and Fowler, B.R.. 1989. Distribution of chlorinated hydrocarbon pesticides and PCBs in the Arctic Ocean. Ottawa: Department of Fisheries and Oceans (Canadian Technical Report of Fisheries and Aquatic Sciences).Google Scholar
Hauge, F., Nilsen, T., and Nilsen, K.E.. 1992. Dumping of radioactive waste in the Barents and Kara seas. Oslo: Bellona Foundation (Bellona Working Paper 3:92).Google Scholar
Helle, E., Hyvarinen, H., and Stenman, O.. 1984. PCB and DDT levels in the Baltic and Saimaa seal populations. In: Linden, H., and Stenman, O. (eds). Proceedings from the Symposium on the seals in the Baltic and Eurasian lakes. Part 1: Seals in the Baltic. Savonlinna: Finnish Game and Fisheries Research Institute, Game Division.Google Scholar
Hennig, H.F.-K.O., Eagle, G.A., McQuaid, C.D., and Rickett, L.H.. 1985. Metal concentrations in Antarctic zooplankton species. In: Siegfried, W.R., Condy, P.R., and Laws, R.M. (eds). Antarctic nutrient cycles and food webs. Berlin, Heidelberg, New York, and Tokyo: Springer-Verlag: 656661.CrossRefGoogle Scholar
Hirota, R., Fukuda, Y., Chiba, J., Tajima, S., and Tujiki, M.. 1989. Mercury content of copepods (Crustacea) collected from the Antarctic sea. Proceedings of the NIPR Symposium on Polar Biology 2: 6570.Google Scholar
Holm, E., Aarkrog, A., Ballestra, S., and Dahlgaard, H.. 1986. Origin and isotopic ratios of plutonium in the Barents and Greenland seas. Earth and Planetary Science Letters 79: 2732.CrossRefGoogle Scholar
Honda, K., Yamamoto, Y., and Tatsukawa, R.. 1987. Distribution of heavy metals in Antarctic marine ecosystems. Proceedings of the NIPR Symposium on Polar Biology 1: 184197.Google Scholar
Honjo, S. 1990. Particle fluxes and modern sedimentation in the polar oceans. In: Smith, W.O. (ed). Polar oceanography, part B: chemistry, biology and geology. New York: Academic Press: 687739.CrossRefGoogle Scholar
Honjo, S., Krishfield, R., and Plueddemann, A.. 1990. The Arctic environmental drifting buoy (AEDB). Report of field operations and results August 1987–April 1988. Woods Hole Oceanographic Institution (Technical Report WHOI–90–02).CrossRefGoogle Scholar
Horner, R.A. 1989. Arctic sea ice biota. In: Herman, Y. (ed). The Arctic seas: climatology, oceanography, geology and biology. New York: Van Nostrand Reinhold Company: 123146.CrossRefGoogle Scholar
Iseki, K., Macdonald, R.W., and Carmack, E.. 1987. Distribution of particulate matter in the southeastern Beaufort Sea in late summer. Proceedings of the NIPR Symposium on Polar Biology 1: 3546.Google Scholar
Iversen, T., and Joranger, E.. 1985. Arctic air pollution an large scale atmospheric flows. Atmospheric Enwronment 19 (12): 20992108.CrossRefGoogle Scholar
Jickells, T.D., Davies, T.D., Tranter, M., Landsberger, S., Jarvis, K., and Abrahams, P.. 1992. Trace elements in snow from the Scottish Highlands: sources and dissolved/ particulate distributions. Atmospheric Environment 26 (3): 393401.CrossRefGoogle Scholar
Joiris, C, and Overloop, W.. 1989. PCBs, organochlorine pesticides and mercury in the lower trophic levels of the Indian sector of the Antarctic marine ecosystem. In: Caschetto, S. (ed). Antarctica: Belgian Scientific Research Programme on Antarctica: scientific results of phase 1. Brussels: Science Policy Office of Belgium: 129.Google Scholar
Kalabin, G. 1994. Evaluation of airotechnogenic pollution of ecosystems of Barents region. In: Molnia, B.F., and Taylor, K.B. (eds). Proceedings of the Interagency Arctic Research Policy Committee workshop on Arctic contamination, May 2–7, 1993, Anchorage, Alaska. Arctic Research of the United States 8: 307.Google Scholar
Kalinnikov, V.T. 1994. Mining and metallurgical wastes as a source of Arctic contamination and a remedy for northern environment protection. In: Molnia, B.F., and Taylor, K.B. (eds). Proceedings of the I nteragency Arctic Research Policy Committee workshop on Arctic contamination, May 2–7, 1993, Anchorage, Alaska. Arctic Research of the United States 8: 308.Google Scholar
Kelce, W.R., Stone, C.R., Laws, S., Gray, L.E., Kemppalnen, J.A., and Wilson, E.M.. 1995. Persistent DDT metabolite p.p'DDE is a potent androgen receptor antagonist. Nature 375: 581585.CrossRefGoogle ScholarPubMed
Knap, A.H., and Jickells, T.D.. 1983. Trace metals and organochlorines in the goosebeaked whale. Marine Pollution Bulletin 14: 271274.CrossRefGoogle Scholar
Krasovkaya, T. 1987. Possible routes of transport of atmospheric pollution into the Arctic and patterns of accumulation in snow and ice. Polar Geography and Geology 11: 7680.CrossRefGoogle Scholar
Lange, M.A., and Pfirman, S.L.. 1995. Arctic sea ice contamination: majorcharacteristics and consequences. Unpublished report for the Arctic Centre, Rovaniemi.Google Scholar
Lee, S.H., Kim, K.T., and Kim S.H., S.H.. 1990. Trace metals in the surface waters of Maxwell Bay, King George Island, Antarctica. Korean Journal of Polar Research 1 (2): 1115.Google Scholar
Levy, E.M. 1986. Background levels of petroleum residues in the Canadian Arctic marine environment. Water Science Technology 18: 161169.CrossRefGoogle Scholar
Lukowski, A.B. 1978. DDT and its metabolites in Antarctic krill (Euphausia superba Dana) from South Atlantic. Polskie Archiwum Hydrobiologii 25 (3): 663668.Google Scholar
Lukowski, A.B. 1983. DDT and its metabolites in the tissues and eggs of migrating Antarctic seabirds from the regions of the South Shetland Islands. Polish Polar Research 4 (1–4): 135141.Google Scholar
Mackenzie, A.S. 1984. Applications of biological markers. In: Brooks, J., and Welte, D. (eds). Advances in petroleum geochemistry. New York: Academic Press: I, 115215.CrossRefGoogle Scholar
Matsuda, O., Ishikawa, S., and Kawaguchi, K.. 1987. Seasonal variation of downward flux of participate organic matter under the Antarctic fast ice. Proceedings of the NIPR Symposium on Polar Biology 1: 2334.Google Scholar
Mehlum, F., and Daelemans, F.F.. 1995. PCBs in Arctic seabirds from the Svalbard region. Science of the Total Environment 160/161: 441446.CrossRefGoogle Scholar
Molnia, B.F., and Taylor, K.B. (eds). 1994. Proceedings of the Interagency Arctic Research Policy Committee workshop on Arctic contamination, May 2–7,1993, Anchorage, Alaska. Arctic Research of the United States 8.Google Scholar
Moore, R.M. 1981. Oceanographic distributions of zinc, cadmium, copper, and aluminium in waters of the central Arctic. Geochimica et Cosmochimica Acta 45: 24752482.CrossRefGoogle Scholar
Norheim, G., Skaare, J.U., and Ø., Wiig. 1992. Some heavy metals, essential elements, and chlorinated hydrocarbons in polar bear (Ursus maritimus) at Svalbard. Environmental Pollution 77: 5157.CrossRefGoogle ScholarPubMed
Patterson, C.C., and Settle, D.M.. 1987. Review of data on eolian transport of industrial and natural lead to the lands and seas in remote regions on a global scale. Marine Chemistry 22: 137162.CrossRefGoogle Scholar
Pfirman, S.L., Eicken, H., Bauch, D., and Weeks, W.F.. 1995. The potential transport of pollutants by Arctic sea ice. Science of the Total Environment 159: 23, 129–146.CrossRefGoogle Scholar
Preston, M.A. 1989. Marine pollution. In: Riley, J.P. (ed). Chemical oceanography, Volume 9. New York: Academic Press: 50196.Google Scholar
Preston, M.A., Chester, R., Bradshaw, G.F., and Merrett, J.L. 1992. PAH/lead relationships: a possible tool for the assessment of anthropogenic influence on marine aerosols. Marine Pollution Bulletin 24: 164166.CrossRefGoogle Scholar
Preston, M.R., and Merrett, J.L.. 1991. The distribution and origins of the hydrocarbon fraction of paniculate material in the North Sea atmosphere. Marine Pollution Bulletin 22: 516522.CrossRefGoogle Scholar
Rahm, L., Hakansson, B., Larsen, P., Foyelkvist, E., Bremle, G., and Valderramo, J.. In press. Nutrient and persistent pollutant deposition on the Bothman Bay ice and snow fields. Water Air & Soil Pollution.Google Scholar
Readman, J.W., Preston, M.R., and Mantoura, R.F.C.. 1986. An integrated technique to quantify sewage, oil and PAH pollution in estuarine and coastal environments. Marine Pollution Bulletin 17 (7): 298308.CrossRefGoogle Scholar
Renzoni, A., and Norstrom, R.J.. 1990. Mercury in the hairs of polar bears, Ursus maritimus. PolarRecord 26 (159): 326327.Google Scholar
Schneider, R., Steinhagen-Schneider, G., and Drescher, H-E.. 1985. Organochlorines and heavy metals in seals and birds from the Weddell Sea. In: Siegfried, W.R., Condy, P.R., and Laws, R.M. (eds). Antarctic nutrient cycles and food webs. Berlin, Heidelberg, New York, and Tokyo: Springer-Verlag: 652655.CrossRefGoogle Scholar
Semenova, S.N. (ed). 1990. Antarkticheskiy kril' v ekosistemakh promyslovykh rayanov (biologicheskiye, tekhnologicheskiye i ekonomicheskiye aspekty) [Antarctic krill in the ecosystems of industrial regions (biological, technological and economic aspects)]. Kaliningrad: Atlanticheskiye Naucho-lssledovatel'skiy Institut Rybnogo Khozyaystva i Okeanografii, (AtlantNIRO).Google Scholar
Shiklomanov, I.A., and Skakalsy, B.G.. 1994. Studying water, sediment, and contaminant runoff of Siberian rivers: modern status and prospects. In: Molnia, B.F., and Taylor, K.B. (eds). Proceedings of the Interagency Arctic Research Policy Committee workshop on Arctic contamination, May 2–7, 1993, Anchorage, Alaska. Arctic Research of the United States 8: 295306.Google Scholar
Sladen, W.J.L, Menzie, C.M., and Reichel, W.L. 1966. DDT residues in Adélie penguins and crabeater seals from Antarctica. Nature 210 (5037): 670673.CrossRefGoogle Scholar
Thomas, W. 1986. Accumulation of airborne trace pollutants by Arctic plants and soil. Water Science and Technology: 18 4757.CrossRefGoogle Scholar
Völkening, J., and Heumann, K.G.. 1988. Determination of heavy metals at the pg/g level in Antarctic snow with DPASVand IDMS. Fresenuis' Zeitschrift für Analytische Chemie 331 (2): 174181.CrossRefGoogle Scholar
Wadhams, P. 1994. Sea ice thickness changes and their relation to climate. In: Johannessen, O.M., Meunch, R.D., and Overland, J.E. (eds). The polar oceans and their role in shaping the global environment. Washington, DC: American Geophysical Union (Geophysical Monograph 85): 337361.Google Scholar
Wagemann, R. 1989. Comparison of heavy metals in two groups of ringed seals (Phoca hispida) from the Canadian Arctic. Canadian Journal of Fisheries and Aquatic Sciences 46 (9): 15561563.CrossRefGoogle Scholar
Wania, F., and Mackay, D.. 1993. Global fractionation and cold condensation of low volatility organochlorine compounds in polar regions. Ambio 22: 1018.Google Scholar
Weeks, W.F. 1994. Possible roles of sea ice in the transport of hazardous material. In: Molnia, B.F., and Taylor, K.B. (eds). Proceedings of the Interagency Arctic Research Policy Committee workshop on Arctic contamination, May 2–7, 1993, Anchorage, Alaska. Arctic Research of the United States. 8: 3452.Google Scholar
Weiss, H.V., Chew, K., Guttman, M., and Host, A.. 1974. Mercury in the environments of the North Slope of Alaska. In: Reed, J.C., Sater, J.E., and Gunn, W.W. (eds). The coast and shelf of the Beaufort Sea. Arlington, VA: Arctic Institute of North America: 737746.Google Scholar
Wong, C.S., Cretney, W.J., Macdonald, R.W., and Christensen, P.. 1976. Hydrocarbon levels in the marine environment of the southern Beaufort Sea. Victoria, BC: Department of the Environment, Beaufort Sea Project (Beaufort Sea Technical Report 38).Google Scholar
Yablokov, A.V. 1993. Facts and problems related to radioactive waste disposal in seas adjacent to the territory of the Russian Federation: materials for a report by the government commission on matters related to radioactive waste disposal at sea. Moscow: Office of the President of the Russian Federation.Google Scholar
Yablokov, A.V., and Danilov-Danilyan, L.. 1991. Environmentalissues: state report on the state of the environment in the Russian Federation in 1991. Moscow: International Arctic Sciences Committee.Google Scholar
Yamamoto, Y., Honda, K., Endo, Y., and Tatsukawa, R.. 1990. Sex- and maturity-related heavy metal accumulations in the Antarctic krill (Euphausia superba). Proceedings of the NIPR Symposium on Polar Biology 3: 5763.Google Scholar
Yeats, P.A. 1988. Manganese, nickel, zinc and cadmium distributions at the Fram 3 and Cesar ice camps in the Arctic Ocean. Oceanologica Acta 11 (4): 383388.Google Scholar
Yevseyev, A.V., and Korzun, A.V.. 1985. The chemical composition of an ice cap on Nordaustlandet. Polar Geography and Geology 9: 334338.CrossRefGoogle Scholar