Hostname: page-component-78c5997874-v9fdk Total loading time: 0 Render date: 2024-11-10T06:35:19.054Z Has data issue: false hasContentIssue false

Environmental Problems Associated with Arctic Development Especially in Alaska

Published online by Cambridge University Press:  24 August 2009

George C. West
Affiliation:
Professor of Zoophysiology and Acting Director, Institute of Arctic Biology, University of Alaska, Fairbanks, Alaska 99701, U.S.A.

Extract

Rapid development for the exploration and extraction of mineral and petroleum resources in the cold-dominated arctic tundra and subarctic taiga regions of the world has resulted in a series of unexpected potential impacts on the environment, wildlife, and human health and safety.

Surface transportation, especially over low wet-tundra areas in summer, causes long-term changes in vegetation through reduction of insulation to the underlying permafrost. The number of passes over the same track, ground pressure of the vehicle, and speed of travel, affect the degree of degradation. For permanent roads, gravel removed from adjacent stream-beds or hillsides and laid directly on the tundra mat, has provided the most suitable road-bed. These roads, and the removal of gravel, however cause aesthetic and practical problems such as spreading of dust, impoundment of water, behavioural barricading of animals, alteration of river channels, and siltation of streams.

Anadromous fishes constitute a major food resource; alteration of stream channels or siltation of rivers can affect their movement and reproductive success. Oil-spills in aquatic systems, especially in rivers, are harder to control and clean up than terrestrial ones. Recovery of ponds in which oil has been spilled takes several years. The oil-rich outer-continental shelves in the Beaufort, Chukchi, and Bering Seas, now under exploration for oil, are especially sensitive, as they are highly productive and contain unique populations of marine mammals and birds.

Human habitation of the Arctic requires transport of food, fuel, and construction materials for lodging, and disposal of refuse and human wastes which, due to the permafrost-underlain vegetative mat, is difficult in arctic areas. Heating by fossil fuels results in ice-fogs in winter and accumulation of atmospheric pollutants at ground-level during thermal inversions at all seasons.

Perhaps the greatest impact on arctic ecosystems is simply the increased intervention of the human population. Where native people were previously only sparsely settled or nomadic in the tundra, and on coasts where they tended to congregate, now the economic need for resources has resulted in increased pressure overall which will result in decreasing habitats for wildlife, destruction of wilderness areas, and increased access to humans for further exploration and recreation.

Type
Main Papers
Copyright
Copyright © Foundation for Environmental Conservation 1976

Access options

Get access to the full version of this content by using one of the access options below. (Log in options will check for institutional or personal access. Content may require purchase if you do not have access.)

References

Agosti, J. & Agosti, I. (1973). The oxidation of certain Prudhoe Bay hydrocarbons by microorganisms indigenous to a natural oil-seep at Umiat, Alaska. Pp. 80–5 in Proc. Symp. on Impact of Oil Resource Development in Northern Plant Communities. Occas. Publ. Northern Life No. 1, Inst. Arctic Biol., Univ. Alaska, Fairbanks: ii + 95 pp., illustr.Google Scholar
Benson, C. S. (1970). Ice fog: low-temperature air pollution. U.S. Army Cold Regions Research and Engineering Laboratory, Hanover, New Hampshire, Research Report 121, 116 pp.Google Scholar
Benson, C. S., Holmgren, B., Timmer, R., Weller, G. & Parrish, S. (1975). Observations on the seasonal snow cover and radiation climate at Prudhoe Bay, Alaska, during 1972. Pp. 1350 in Ecological Investigations of the Tundra Biome in the Prudhoe Bay Region, Alaska (Ed. Brown, J.). Biol. Pap. Univ. Alaska, Special Report No. 2: xv + 215pp., illustr.Google Scholar
Bliss, L. C. (1970). A biologist explains why we must plan now to protect the Arctic. Science Forum, 15, pp. 38.Google Scholar
Bliss, L. C. & Peterson, E. B. (1973). The Ecological Impact of Northern Petroleum Development. Fifth International Congress ‘Arctic Oil and Gas: Problems and Possibilities’, Le Havre, May 1973: 26 pp.Google Scholar
Britton, M. E. (1973). Arctic Alaska Tundra. Arctic Inst. N. Amer. Tech. Paper 25, 224 pp.Google Scholar
Brown, J. (Ed.) (1975). Ecological and Limnological Reconnaissance from Prudhoe Bay into the Brooks Range, Alaska, Summer 1975. Report of the RATE Program, U.S. Army Cold Regions Research and Engineering Laboratory, Hanover, New Hampshire: 65 pp.Google Scholar
Brown, J., Rickard, W. & Vietor, D. (1969). The effect of disturbance on permafrost terrain. USA CRREL Special Report 138, 13 pp.Google Scholar
Brown, J. & West, G. C. (1970). Tundra Biome Research in Alaska: the Structure and Function of Cold-dominated Ecosystems. U.S. International Biological Program, Tundra Biome Report 70–1, The Biome Center, University of Alaska, Fairbanks, Alaska: 148 pp.Google Scholar
Brown, J., Bunnell, F., Miller, P., MacLeans, F. Jr, & Tieszen, L. L. (Eds), (in prep.). An Arctic Ecosystem: The Coastal Tundra of Northern Alaska.Google Scholar
Burns, J. J. (1970). Remarks on the distribution and natural history of pagophilic pinnipeds in the Bering and Chukchi Seas. J. Mamm., 51, pp. 445–54.CrossRefGoogle Scholar
Burt, G. R. (1970). Summer Travel in the Tundra with Low Ground-pressure vehicles. Inst. Arctic Env. Engin., Univ. Alaska, College, Alaska: 9 pp.Google Scholar
Campbell, W. B., Harris, R. W. & Benoit, R. E. (1973). Response of Alaskan tundra microflora to a crude-oil spill. Pp. 5362 in Proc. Symp. on Impact of Oil Resource Development in Northern Plant Communities. Occas. Publ. Northern Life No. 1, Inst. Arctic Biol., Univ. Alaska, Fairbanks: ii + 95 pp., illustr.Google Scholar
Chapin, F. S. & Chapin, M. C. (in prep.). Manipulation of Reproductive Strategy to Achieve Revegetation by a Native Tundra Species.Google Scholar
Child, K. N. (1972). A specific problem: the reaction of Reindeer and Caribou to pipelines. Pp. 14–9 in Proc. 1st International Reindeer Caribou Symp. (Ed. Luick, J. et al. ). Biol. Pap. Univ. Alaska, Special Report No. 1: xiii + 551, illustr.Google Scholar
Child, K. N. (1973). The Reactions of Barren-ground Caribou (Rangifer tarandus granti) to Simulated Pipeline and Pipeline-crossing Structures at Prudhoe Bay, Alaska. Alaska Coop. Wildl. Res. Unit. Completion Report, 51 pp.Google Scholar
Deneke, F. J., McCown, B. H., Coyne, P. L, Rickard, W. E. & Brown, J. (1975). Biological aspects of terrestrial oil-spills. USA CRREL Research Report 346, 66 pp.Google Scholar
Ferry, B. W., Baddeley, M. S. & Hawksworth, D. W. (1973). Air Pollution and Lichens. Athlone Press, London: x + 389 pp., illustr.Google Scholar
Geist, V. (1971). Is big game harassment harmful? Oilweek, 23, pp. 12–3.Google Scholar
Hjeljord, O. (1973). Studien av revegetasjonsforlop i gamle traktorspor på Svalbard. Norsk Polarinst. Årbok, 1971, pp. 3142.Google Scholar
Holty, J. G. (1973). Air quality in a subarctic community, Fairbanks, Alaska. Arctic, 26, pp. 292302.Google Scholar
Hok, J. R. (1969). A Reconnaissance of Tractor Trails and Related Phenomena on the North Slope of Alaska. U.S. Department of the Interior, Bureau of Land Management Report, 66 pp.Google Scholar
Irving, L., Mcroy, C. P. & Burns, J. J. (1970). Birds observed during a cruise in the ice-covered Bering Sea in March 1968. Condor, 72, pp. 110–12.CrossRefGoogle Scholar
Ives, J. D. & Barry, R. G. (Eds) (1975). Arctic and Alpine Environments. London, Methuen: xviii + 999 pp., illustr.Google Scholar
Johnson, L. & VanCleve, K. (1975). Revegetation in arctic and subarctic North America—a literature review. USA CRREL Technical Note, 72 pp.Google Scholar
Klein, D. R. (1971). Reaction of reindeer to obstructions and disturbances. Science, 173, pp. 393–8.CrossRefGoogle ScholarPubMed
Klein, D. R. (1972). Problems in conservation of mammals in the North. Biol. Conserv., 4, pp. 97101.CrossRefGoogle Scholar
Klein, D. R. (1973). The impact of oil development in the northern environment. Proc. 3rd Interpetroleum Congress, Rome, Petrolio e ambiente, pp. 109–21.Google Scholar
Klein, D. R. (1974). The reaction of some northern mammals to aircraft disturbance. XI International Cong. Game Biol., Stockholm 1973, SNV 13E, pp. 377–83.Google Scholar
Mccown, D. D. & Deneke, F. J. (1973). Plant germination and seedling growth as affected by the presence of crude petroleum. Pp. 4451 in Proc. Symp. on Impact of Oil Resource Development in Northern Plant Communities. Occas. Publ. Northern Life No. 1, Inst. Arctic Biol., Univ. Alaska, Fairbanks: ii + 95 pp., illustr.Google Scholar
McRoy, C. P. (1966). The Standing Stock and Ecology of Eelgrass (Zostera marina, L.) in Izembek Lagoon, Alaska. Unpublished M.S. thesis, Univ. Washington, Seattle, 138pp.Google Scholar
McRoy, C. P. (1969). Eelgrass under arctic winter ice. Nature (London), 224, pp. 818–9.Google Scholar
McRoy, C. P. (1970). Standing stocks and other features of Eelgrass (Zostera marina) populations on the coast of Alaska. j. Fish. Res. Bd. Canada, 27, pp. 275–92.CrossRefGoogle Scholar
McRoy, C. P., Stoker, S. W. & Hall, G. E. (1971). Winter observations of mammals and birds, St. Matthew Island. Arctic, 24, pp. 63–4.CrossRefGoogle Scholar
McRoy, C. P. & Goering, J. J. (1974). The influence of ice on the primary productivity of the Bering Sea. Pp. 403–21 in Oceanography of the Bering Sea (Ed. Hood, D. W. & Kelley, E. J.). Occas. Publ. No. 2, Institute of Marine Science, Univ. of Alaska, Fairbanks: xxi + 622 pp., illustr.Google Scholar
Miller, F. L. (1974). A new era—are migratory Barren-ground Caribou and petroleum exploitation compatible? Trans. 31st Northeast Fish and Wildlife Conf., pp. 4555.Google Scholar
Mitchell, W. W. 1973. Adaptations of species and varieties of grasses for potential use in Alaska. Pp. 26 in Proc. Symp. on Impact of Oil Resource Development in Northern Plant Communities. Occas. Publ. Northern Life No. 1, Inst. Arctic Biol., Univ. Alaska, Fairbanks: ii + 95 pp., illustr.Google Scholar
Moore, J. J. (Ed.) (in prep.). Tundra and Related Habitats. ‘Cambridge University Press.’Google Scholar
Norton, D. W., Ailes, I. W. & Curatolo, J. A. (1975). Ecological relationships of the inland tundra avifauna near Prudhoe Bay, Alaska. Pp. 125–33 in Ecological Investigations of the Tundra Biome in the Prudhoe Bay Region, Alaska (Ed. Brown, J.). Biol. Pap. Univ. Alaska, Special Report No. 2: xv + 215 pp., illustr.Google Scholar
Pegau, R. E. (1970). Effect of reindeer trampling and grazing on lichens. J. Range. Mgmt, 23, pp. 95–7.CrossRefGoogle Scholar
Polunin, N. (1948). Botany of the Canadian Eastern Arctic, Part III: Vegetation and Ecology. Nat. Mus. Canada Bull. 104, vii + 304 pp., illustr.Google Scholar
Polunin, N. (1970 a). ‘Tundra’. Pp. 957–9 in The Encyclopedia of the Biological Sciences (2nd edn, Ed. Gray, P.). Van Nostrand Reinhold, New York, etc.: xxv + 1,027 pp., illustr.Google Scholar
Polunin, N. (1970 b). ‘Arctic flora’ and ‘Arctic vegetation’. Pp. 5360 in The Encyclopedia of the Biological Sciences (2nd edn, Ed. Gray, P.). Van Nostrand Reinhold, New York, etc.: xxv + 1,027 pp., illustr.Google Scholar
Polunin, N. (1974). Polar biomes. Pp. 655–7 in appropriate volume of Encyclopaedia Britannica (15th edn).Google Scholar
Scarborough, A. & Flanagan, P. W. (1973). Observations on the effects of mechanical disturbance and oil on soil microbial populations. Pp. 6371 in Proc. Symp. on Impact of Oil Resource Development in Northern Plant Communities. Occas. Publ. Northern Life No. 1, Inst. Arctic Biol. Univ., Alaska, Fairbanks: ii + 95 pp., illustr.Google Scholar
Schofield, E. & Hamilton, W. L. (1970). Probable damage to tundra biota through sulphur dioxide destruction of lichens. Biol. Conserv., 2, pp. 278–80.Google Scholar
Slavin, S. V. (1972). The Soviet North—Present Development and Prospects [transi, from Russian]. Progress Publ., Moscow: 192 pp.Google Scholar
Tilsworth, T. (1972). Sludge Production and Disposal for Small Cold-climate Biotreatment Plants. Institute of Water Resources, Univ. Alaska, Report 32, 43 pp.Google Scholar
Tilsworth, T. & Damron, F. J. (1974). Industrial waste-water treatment in arctic Alaska. Pp. 227–36 in Proceedings, Water—1974 (Ed. Bennett, G. F.). Am. Inst. Chem. Eng. Symp. Series: 393 pp.Google Scholar
USDI (1972). Final environmental impact statement, proposed Trans-Alaska Pipeline. US Dept of the Int., 6 volumes.Google Scholar
Vancleve, K. (1973). Revegetation of disturbed tundra and taiga surfaces by introduced and native plant species. Pp. 7–11 in Proc. Symp. on Impact of Oil Resource Development in Northern Plant Communities. Occas. Publ. Northern Life No. 1, Inst. Arctic Biol., Univ. Alaska, Fairbanks: ii + 95 pp., illustr.Google Scholar
Weeden, R. B. (1971). Oil and wildlife: a biologist's view. Trans. 36th N. Amer. Wildl. & Nat. Res. Conf., pp. 242–58.Google Scholar
Weeden, R. B. (1973). Wildlife Management and Alaska Land-use Decisions. Institute of Social, Economic & Government Research, Univ. Alaska, Occas. Pap. 8, 51 pp.Google Scholar
Weeden, R. B. & Klein, D. R. (1971). Wildlife and oil: a survey of critical issues in Alaska. Polar Record, 15, pp. 479–94.CrossRefGoogle Scholar
Weller, G. E. (1969). Ice-fog Studies in Alaska: A Survey of Past, Present and Proposed Research. Geophysical Inst. UAG R 207, Univ. Alaska: 48 pp.Google Scholar
White, R. G., Thompson, B. R., Skogland, T., Person, S. J., Russell, D. E., Holleman, D. E. & Luick, J. R. (1975). Ecology of Caribou at Prudhoe Bay, Alaska. Pp. 151–87 in Ecological Investigations of the Tundra Biome in the Prudhoe Bay Region, Alaska (Ed. Brown, J.). Biol. Pap. Univ. Alaska, Special Report No. 2: xv + 215 pp., illustr.Google Scholar
Winchester, J. W., Zoller, W. H., Duce, R. A. & Benson, C. S. (1967). Lead and halogens in pollution aerosols and snow from Fairbanks, Alaska. Atmosphere Environment, Pergamon Press, 1, pp. 105–19.Google Scholar
Zhigunov, P. S. (Ed.) (1961). Reindeer Husbandry. Translated from the Russian by Israel Program for Scientific Translations, Jerusalem, 1968: iv + 348 pp., illustr.Google Scholar