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Trampling and Fire in a Subtropical Dry Sclerophyll Forest

Published online by Cambridge University Press:  24 August 2009

N.C. Thyer
Affiliation:
The School of Australian Environmental Studies, Griffith University, Nathan, Brisbane, Queensland 4111, Australia.

Extract

Experimental trampling was carried out in recently-burned and unburned areas of a dry sclerophyll forest. Percentage cover was greatly reduced by burning and trampling. Plant numbers were relatively unaffected by burning, and trampling had approximately the same effect on plant numbers in recently-burned and unburned areas.

The reduction of cover and plant numbers to 50% of their original value by fewer than 16 passages was near to that predicted on the basis of the low primary productivity of the ground-flora, and suggests that this type of vegetation is quite vulnerable to trampling.

Type
Main Papers
Copyright
Copyright © Foundation for Environmental Conservation 1986

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References

Bates, G.H. (1938). Life-forms of pasture plants in relation to treading. Journal of Ecology, 26, pp. 452–5.CrossRefGoogle Scholar
Bates, G.H. (1956). Track-making by man and domestic animals. Journal of Animal Ecology, 20, pp. 21–8.Google Scholar
Beardsly, W.G. & Wagar, J.A. (1971). Vegetation management on a forested recreation site. Journal of Forestry, 69, pp. 728–31.Google Scholar
Birk, E.M. (1979 a). Litter Accession, Accumulation and Disappearance in an Australian Eucalypt Forest. M.Phil, thesis, Griffith University, Queensland, Australia: 155 pp., illustr.Google Scholar
Birk, E.M. (1979 b). Disappearance of overstorey and understorey litter in an open eucalypt forest. Australian Journal of Ecology, 4, pp. 207–22.CrossRefGoogle Scholar
Bulow-Olsen, A., Just, J. & Liddle, M.J. (1982). Growth and flowering history of Xanthorrhoea johnsonii Lee (Liliaceae) in Toohey Forest, Queensland. Botanical Journal of the Linnean Society, 84, pp. 192207.CrossRefGoogle Scholar
Cieslinski, T.J. & Wagar, J.A. (1970). Predicting the Durability of Forest Recreation Sites in Northern Utah: Preliminary Results. U.S.D.A. Forest Service Research, Note INT. 117, Ogden, Utah, USA: 7 pp.CrossRefGoogle Scholar
Dawson, J.O., Hinze, P.N. & Gordon, J.C. (1974). Hiking-trail impact on Iowa stream valley forest preserves. Iowa State University Journal of Research, 48, pp. 329–37.Google Scholar
Dell'Agnola, G. (1971). Human settlement, a factor degrading humic substance and forest soils. Monti e Boschi, 22, pp. 311.Google Scholar
Dotzenko, A.D., Papamichos, N.T. & Romine, D.S. (1967). Effect of recreational use on soil moisture conditions in Rocky Mountain National Park. Journal of Soil and Water Conservation, 22, pp. 196–7.Google Scholar
Falinski, J.B. (1975). Die Reaktion der Waldbodenvegetation auf Trittwirkung im licht experimenteller Forschungen. Phytocoenologia, 2, pp. 451–65.Google Scholar
Foin, T.C., Garton, E.O., Bowen, C.W., Everingham, J.M. & Schultz, R.O. (1977). Quantitative studies of visitor impacts on environments of Yosemite National Park, California, and their implications for park management policy. Journal of Environmental Management, 5, pp. 122.Google Scholar
Gill, A.M. (1981). Adaptive responses of Australian vascular plant species to fires. Pp. 243–72 in Fire and the Australian Biota (Eds Gill, A.M., Groves, R.M. & Noble, I.R.). Australian Academy of Science, Canberra, Australia: 582 pp., illustr.Google Scholar
Humphries, F.R. & Craig, F.G. (1981). Effects of fire on soil chemical, structural and hydrological properties. Pp. 177202 in Fire and the Australian Biota (Eds Gill, A.M., Groves, R.M. & Noble, I.R.). Australian Academy of Science, Canberra, Australia: 582 pp., illustr.Google Scholar
Kay, A.M. & Liddle, M. J. (1984). Tourist Impact on Reef Corals. (Report to the Great Barrier Reef Marine Park Authority.) School of Australian Evironmental Studies, Griffith University, Brisbane, Queensland, Australia: 188 pp., illustr.Google Scholar
Kellomaki, S. (1973). Ground cover response to trampling in a spruce stand of Myrtillus type. Silva Fennica, 7, pp. 96113.Google Scholar
Kellomaki, S. (1977). Deterioration of forest ground-cover during tampling. Silva Fennica, 11, pp. 153–61.CrossRefGoogle Scholar
Kellomaki, S. & Saastamoinen, V.L. (1975). Trampling tolerance of forest vegetation. Acta Forestalia Fennica (Helsinki), 147, 22 pp.Google Scholar
Krebs, C.J. (1978). Ecology: The Experimental Analysis of Distribution and Abundance. Harper & Row, New York, NY, USA: 678 pp., illustr.Google Scholar
Liddle, M.J. (1975). A theoretical relationship between the primary productivity of vegetation and its ability to tolerate trampling. Biological Conservation, 8, pp. 251–5.CrossRefGoogle Scholar
Liddle, M.J. (1984). A classification of the interactions between animals and plants with particular reference to human trampling. Pp. 113–28 in The Ecological Basis of Interactions Between Organisms (Eds Liddle, M.J. & Tothil, J.C.). (A.E.S. Monograph 1/84.) The School of Australian Environmental Studies, Griffith University, Brisbane, Queensland, Australia: 128 pp.Google Scholar
Liddle, M.J. & Chitty, L.D. (1981). The nutrient-budget of horse tracks on an English lowland heath. Journal of Applied Ecology, 18, pp. 841–8.CrossRefGoogle Scholar
Liddle, M.J. & Greig-Smith, P. (1975). A survey of tracks and paths in a sand-dune ecosystem, I: Soils. Journal of Applied Ecology, 12, pp. 893908.CrossRefGoogle Scholar
Liddle, M.J. & Kay, A.M. (MS), Resistance, tolerance and resilience of trampled corals on the Great Barrier Reef.Google Scholar
Manning, R.E. (1979). Impacts of recreation on riparian soils and vegetation. Water Resources Bulletin, 15, pp. 3043.CrossRefGoogle Scholar
Staff, I.A. (1970). Regeneration in shoots of Xanthorrhoea australis after injury. Phytomorphology, 20, pp. 68.Google Scholar
Taylor, U.M. (1971). Soil conditions as they affect plant establishment, root development and yield. In Compaction of Agricultural Soils (Eds Barnes, K.K. et al. ). American Society of Agriculture Engineers, Michigan, USA: 471 pp., illustr.Google Scholar
Weaver, T. & Dale, D. (1978). Trampling effects of hikers, motor cycles and horses in meadows and forests. Journal of Applied Ecology, 15, pp. 451–7.CrossRefGoogle Scholar