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Tundra Disturbance Studies, III: Short-term Effects of Aeolian Sand and Dust, Yamal Region, Northwest Siberia

Published online by Cambridge University Press:  24 August 2009

Bruce C. Forbes
Bruce C. Forbes
Affiliation:
Arctic Centre, University of Lapland, PO Box 122, SF-96101 RovaniemiFinland.
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Extract

This paper describes the short-term responses of tundra vegetation and soils to aeolian sand and dust emanating from anthropogenically-bared surfaces in the low-arctic region of northwestern Siberia. Such surfaces, including roads and quarries, are increasing substantially each year as the region undergoes massive gas- and oil-producing development. Data are presented which emphasize the ‘cumulative’ impacts of corridor construction, namely those effects which are measurable laterally, at some distance from the actual surfaces of roads and quarries, four years after their creation. In particular, changes in plant communities are documented, in addition to the chemistry and macronutrient status of mineral soils and dominant vascular plants and mosses, respectively, as affected by road-dust.

Dramatic changes in plant community composition and cover were evident up to 200 m downwind from a ‘typical’ sand quarry. Although a few species appeared to respond favourably to rapid sand deposition, the great majority that were beset with it have declined in status or disappeared altogether. The exceptions were those growth-forms having the ability to keep perennating buds at or above the surface of the deepening sand (e.g. Betula nana, Salix spp., and Polytrichum spp.). The most pronounced decreases recorded were among lichens, hepatics, Sphagnum spp., and pleurocarpous mosses. The decline in Sphagnum spp., which dominate the moss layer and contribute much of the hummock-hollow microtopography, is already having a profound impact on community structure by virtually eliminating surface heterogeneity.

Type
Main Papers
Information
Environmental Conservation , Volume 22 , Issue 4 , Winter 1995 , pp. 335 - 344
Copyright
Copyright © Foundation for Environmental Conservation 1995

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References

Adamson, E., Adamson, H. & Seppelt, R. (1994). Cement dust contamination of Ceratodon purpureus at Casey, East Antarctica: damage and capacity for recovery. Journal of Bryology, 18, pp. 127–37.CrossRefGoogle Scholar
Anon. (1995). Svalbard becomes a hot issue. WWF Arctic Bulletin, Nr 1.95, pp. 18–9.Google Scholar
Andreev, M.P. (1993). [Lichens of Yamal Peninsula] (in Russian). Novitates Systematicae Plantarum Non Vascularum, 21, pp. 127–36.Google Scholar
Auerbach, N.A. (1992). Effects of Road and Dust Disturbance in Minerotrophic and Acidic Tundra Ecosystems, Northern Alaska. MSc thesis, University of Colorado, Boulder, Colorado, USA: xvii + 253 pp., illustr.Google Scholar
Auerbach, N.A., Walker, M.D. & Walker, D.A. (in press). Effects of road dust disturbance on substrate and vegetation properties in arctic tundra. Ecological Applications.Google Scholar
Aulio, K. (1980). Nutrient accumulation in Sphagnum mosses, I: A multivariate summarization of the mineral element composition of 13 species from an ombrotrophic raised bog. Annales Botanici Fennici, 17, pp. 307–14, illustr.Google Scholar
Bailey, R.G. & Hogg, H.C. (1986). A world ecoregions map for resource reporting. Environmental Conservation, 13, pp. 195202, illustr.CrossRefGoogle Scholar
Birse, E.M., Landsberg, S.Y. & Gimingham, C.H. (1957). The effects of burial by sand on dune mosses. British Bryological Society Transactions, 3, pp. 285301.CrossRefGoogle Scholar
Bliss, L.C. & Mateveyeva, N.V. (1992). Circumpolar arctic vegetation. Pp. 5989, illustr., in Arctic Ecosystems in a Changing Climate: an Ecophysiological Perspective (Eds Chapin, F.S. III, Jefferies, R.L., Reynolds, J.F., Shaver, G.R. & Svoboda, J.). Academic Press, New York, NY, USA: xvii + 469 pp., illustr.CrossRefGoogle Scholar
Botch, M.C., Gerasimenko, T.V. & Tolchelnikov, Y.C. (1971). [Mires of the Yamal Peninsula] (in Russian with English summary). Botanicheskii Zhurnal, 56, pp, 1421–35.Google Scholar
Braak, C.J.F. ter (1991). CANOCOTMA FORTRAN Program for Canonical Community Ordination by [Partial] [Detrended] [Canonical] Correspondence Analysis, Principal Components Analysis and Redundancy Analysis (Version 3.11). Agricultural Mathematics Group, Wageningen, The Netherlands: [not available for checking].Google Scholar
Braun-Blanquet, J. (1932). Plant Sociology: the Study of Plant Communities. (1983 reprint translated, revised, and Ed. Fuller, G.D. & Conard, H.S..) Koeltz Scientific Books, Koenigstein, Germany: 439 pp., illustr.Google Scholar
Farmer, A.M. (1993). The effects of dust on vegetation — a review. Environmental Pollution, 79, pp. 6375.CrossRefGoogle ScholarPubMed
Filion, L. & Payette, S. (1989). Subarctic lichen polygons and soil development along a colonization gradient on eolian sands. Arctic and Alpine Research, 21, pp. 175–84.CrossRefGoogle Scholar
Forbes, B.C. (1992 a). Tundra disturbance studies, I: Long-term effects of vehicles on species richness and biomass. Environmental Conservation, 19(2), pp. 4858, illustr.CrossRefGoogle Scholar
Forbes, B.C. (1992 b).Tundra disturbance studies, II: Plant growth forms of human-disturbed ground in the Canadian Far North. Musk-ox, 39, pp. 4655, illustr.Google Scholar
Forbes, B.C. (MS). Early primary succession on anthropogenic surfaces within low-arctic tundra — Yamal Region, northwest Siberia, Russia. [Submitted to] Journal of Biogeography.Google Scholar
Grime, J.P., Rincon, E.R. & Wickerson, B.E. (1990). Bryophytes and plant strategy theory. Botanical Journal of the Linnean Society, 104, pp. 175–86.CrossRefGoogle Scholar
Halonen, O., Tulkki, H. & Derome, J. (1983). Nutrient Analysis Methods. Maantutkimusosasto Vantaa, Finland: 28 pp., illustr.Google Scholar
Hill, M.O. (1979 a). TWINSPAN: A FORTRAN Program for Arranging Multivariate Data in an Ordered Two-way Table by Classification of the Individuals and Attributes. Cornell University, Ithaca, NY, USA: [not available for checking].Google Scholar
Hill, M.O. (1979 b). DECORANA: A FORTRAN Program for Detrended Correspondence Analysis and Reciprocal Averaging. Cornell University, Ithaca, NY, USA: [not available for checking].Google Scholar
Hill, M.O. & Gaugh, H.G. (1980). Detrended correspondence analysis: an improved ordination technique. Vegetatio, 42, pp. 4758, illustr.CrossRefGoogle Scholar
Hippa, H., Koponen, S. & Osmonen, O. (1978). Role of bees (Hym., Apidae) in pollination of the Cloudberry (Rubus chamaemorus L.) in northern Fennoscandia. Reports from the Kevo Subarctic Research Station, 14, pp. 31–7.Google Scholar
Hippa, H., Koponen, S. & Osmonen, O. (1981). Pollen transport and pollinating efficiency of flower visitors to the Cloudberry (Rubus chamaemorus L.) in northern Fennoscandia. Reports from the Kevo Subarctic Research Station, 17, pp. 5866.Google Scholar
Hope, A.S., Fleming, J.B., Stow, D.A. & Aguado, E. (1991). Tussock tundra albedos on the North Slope of Alaska: effects of illumination, vegetation composition, and dust deposition. Journal of Applied Meteorology, 30, pp. 1200–6.2.0.CO;2>CrossRefGoogle Scholar
Ignatov, M.S. & Afonina, O.M. (1992). Check-list of mosses of the former USSR. Arctoa, 1, pp. 186.CrossRefGoogle Scholar
Ilyina, I.S., Lapshina, E.I., Makhno, V.D., Meltzer, L.I. & Romanova, E.A. (1976). Vegetation of the West Siberian Plain — 1:1.500,000 map (in Russian) (Ed. Ilyina, I.S.). GUGC, Moscow, USSR: 4 sheets.Google Scholar
Konstantinova, N.A., Potemkin, A.D. & Schijakov, R.N. (1992). Check-list of the Hepaticae and Anthocerotae of the former USSR. Arctoa, 1, pp. 87127.CrossRefGoogle Scholar
Kooijman, A.M. & Bakker, C. (1995). Species replacement in the bryophyte layer in mires: the role of water type, nutrient supply, and interspecific interactions. Journal of Ecology, 83, pp. 18.CrossRefGoogle Scholar
Kortesharju, J. (1989). The elemental composition and dry weight of Cloudberry (Rubus chamaemorus) rhizomes near a cement works at Kolari, NW Finland. Aquilo Ser. Botanica, 26, pp. 16.Google Scholar
Kortesharju, J., Savonen, K. & Säynätkari, T. (1990). Element contents of raw humus, forest moss, and reindeer lichens, around a cement works in northern Finland. Annales Botanici Fennici, 27, pp. 221–30.Google Scholar
Leach, W. (1931). On the importance of some mosses as pioneers on unstable soils. Journal of Ecology, 19, pp. 98102.CrossRefGoogle Scholar
Li, Y. & Vitt, D.H. (1994). The dynamics of moss establishment: temporal responses to nutrient gradients. Bryologist, 97, pp. 357–64.CrossRefGoogle Scholar
Maarel, E. van der (1979). Transformation of cover-abundance values in phytosociology and its effects on community similarity. Vegetatio, 39, pp. 97114.Google Scholar
Matt, K.J. (1970). Colorimetric determination of phosphorus in soil and plant materials with ascorbic acid. Soil Science, 109, pp. 214–20.Google Scholar
Meinenger, C.A. & Spatt, P.D. (1988). Variations of tardigrade assemblages in dust-impacted arctic mosses. Arctic and Alpine Research, 20, pp. 2430.CrossRefGoogle Scholar
Meltzer, L.I. (1984). [Zonal division of tundra vegetation of the West Siberian plain] (in Russian). Pp. 719, illustr., in Vegetation of Western Siberia and its Mapping (Ed. Belov, A. V.). Akademia Nauk, Novosibirsk, USSR: [not available for checking].Google Scholar
Nelson, F.E. & Anisimov, O.A. (1993). Permafrost zonation in Russia under anthropogenic climatic change. Permafrost and Periglacial Processes, 4, pp. 137–48, illustr.CrossRefGoogle Scholar
Parsons, A., Press, M.C., Wookey, P.A., Welker, J.M., Robinson, C.H., Callaghan, T.V. & Lee, J.A. (1995). Growth responses of Calamagrostis lapponica to simulated environmental change in the Sub-arctic. Oikos, 72, pp. 61–6, illustr.CrossRefGoogle Scholar
Polunin, N. (1936). Plant succession in Norwegian Lapland. Journal of Ecology, 24, pp. 372–91, illustr.CrossRefGoogle Scholar
Polunin, N. (1959). Circumpolar Arctic Flora. Clarendon Press, Oxford, England, UK: xxviii + 514 pp., illustr. practically throughout.Google Scholar
Rebristaya, O.V. (1977). Flora of the Eastern Part of the Bolschezemelskaya Tundra (in Russian). Nauka, Leningrad, USSR: 344 pp., illustr.Google Scholar
Spatt, P.D. & Miller, M.C. (1981). Growth conditions and vitality of Sphagnum in a tundra community along the Alaska pipeline haul road. Arctic, 34, pp. 4854.CrossRefGoogle Scholar
Specter, M. (1994 a). In the defiled Russian Arctic, hope is a US oil company. The New York Times, 27 11 1994, pp. 1 & 22, illustr.Google Scholar
Specter, M. (1994 b). Arctic tribe's hard life unchanged for centuries. The New York Times, 22 11 1994, pp. C1 & C12, illustr.Google Scholar
Sykes, M.T. & Wilson, J.B. (1990). An experimental investigation into the response of New Zealand sand-dune species to different depths of burial by sand. Acta Botanica Neerlandica, 39, pp. 171–81.CrossRefGoogle Scholar
Tamm, C.O. & Trœdsson, T. (1955). An example of the amounts of plant nutrients supplied to the ground in road dust. Oikos, 6, pp. 6170.CrossRefGoogle Scholar
Ter Braak, C.J.F. — see Braak, C.J.F. ter.Google Scholar
van der Maarel, E., see Maarel, E. van der.Google Scholar
Vilchek, G.E. & Bykova, O.Y. (1992). The origin of regional ecological problems within the northern Tyumen Oblast, Russia. Arctic and Alpine Research, 24, pp. 99107, illustr.CrossRefGoogle Scholar
Vitebsky, P. (1990). Gas, environmentalism, and native anxieties in the Soviet Arctic: the case of Yamal Peninsula. Polar Record, 26, pp. 1926, illustr.CrossRefGoogle Scholar
Walker, D.A. & Everett, K.R. (1987). Road dust and its environmental impact on Alaskan taiga and tundra. Arctic and Alpine Research, 19, pp. 479–89, illustr.CrossRefGoogle Scholar
Walker, D.A., Webber, P.J., Walker, M.D., Lederer, N.D., Meehan, R.H. & Nordstrand, E.A. (1986). Use of ecobotanical maps and automated mapping techniques to examine cumulative impacts in the Prudhoe Bay oilfield, Alaska. Environmental Conservation, 13(2), pp. 149–60, illustr.CrossRefGoogle Scholar
Webber, P.J. & Ives, J.D. (1978). Damage and recovery of tundra vegetation. Environmental Conservation, 5(3), pp. 171–82, illustr.CrossRefGoogle Scholar
Yurtsev, B.A. (1994). Floristic division of the Arctic. Journal of Vegetation Science, 5, pp. 765–76, illustr.CrossRefGoogle Scholar
Zar, J.H. (1984). Biostatistical Analysis, 2nd edition. Prentice-Hall, Englewood Cliffs, New Jersey, USA: 718 pp., illustr.Google Scholar
Zobel, D.B. & Antos, J.A. (1986). Survival of prolonged burial by subalpine forest understory plants. American Midland Naturalist, 114, pp. 282–7.CrossRefGoogle Scholar