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Do elephants over-utilize mopane woodlands in northern Botswana?

Published online by Cambridge University Press:  10 July 2009

Raphael Ben-Shahar
Affiliation:
Department of Zoology, University of Oxford, South Parks Road, Oxford 0X1 3PS

Abstract

Evidence from southern African semi-arid savannas suggests that high elephant densities in nature reserves cause the over-utilization of woodlands. Northern Botswana, with its prolific elephant population, is expected to follow such a pattern unless the densities of elephants which could be sustained by indigenous woodlands are determined and maintained at carrying capacity. Above ground biomass production was estimated for mopane (Colophospermum mopane) woodlands, a principal food source for elephants, which grows over much of northern Botswana. Densities of trees and shrubs, dimensions of plants and elephant densities were recorded within stratified plots situated according to a regional rainfall gradient. Mean estimates of above ground biomass (foliage and twigs) were 9.41 and 7.83 t ha−1 for shrubs and trees respectively. A logistic model described the maximum levels of biomass removal from plants before over-utilization of mopane occurred. Variables incorporated in the model included above ground biomass of mopane shrubs and trees, growth rates of plants and expected off-take by elephants. The model predicted a complete biomass regain within 10 y if no elephant browsing occurs. Intensive elephant browsing in woodlands containing 15 elephants km−2, however, can suppress biomass production if growth rates of plants fall below 70% of the maximum annual rate. Nonetheless, there was no substantial evidence to suggest that elephants will reduce the biomass of mopane woodlands in northern Botswana below a sustainable level if their numbers are allowed to increase considerably beyond the current estimate.

Type
Research Article
Copyright
Copyright © Cambridge University Press 1996

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References

LITERATURE CITED

Barnes, R. F. W. 1983a. The elephant problem in Ruaha National Park, Tanzania. Biological Conservation 26:127148.CrossRefGoogle Scholar
Barnes, R. F. W. 1983b. Effects of browsing on woodlands in a Tanzanian national Park: measurements, models, and management. Journal of Applied Ecology 20:123126.CrossRefGoogle Scholar
Ben-Shahar, R. 1993. Patterns of elephant damage to vegetation in northern Botswana. Biological Conservation 65:249256.CrossRefGoogle Scholar
Ben-Shahar, R. 1996. Woodland dynamics under the influence of elephants and fire in northern Botswana. Vegetatio (in Press).CrossRefGoogle Scholar
Bhalotra, Y. P. R. 1987. Climate of Botswana. Part II: elements of climate. Meteorological Services, MWTC, Gaborone.Google Scholar
Calef, G. W. 1988. Maximum rate of increase in the African Elephant. African Journal of Ecology 26:323327.CrossRefGoogle Scholar
Caughley, G. 1976. The elephant problem – an alternative hypothesis. East African Wildlife Journal 14:265283.CrossRefGoogle Scholar
Child, G. 1968. An ecological survey of northeastern Botswana. FAO Publication No. TA2563, Rome.Google Scholar
Coates-Palgrave, K. 1983. Trees of southern Africa. Struik, Cape-Town.Google Scholar
Craig, C. G. 1989. A simple model of tree-elephant equilibrium. Elephant management in Zimbabwe. Department of National Parks and Wild Life Management, Harare.Google Scholar
Craig, C. G. 1990. Present population and distribution of elephants in Botswana. The future of Botswana's elephants Proceedings of the Kalahari Conservation Society. Gaborone.Google Scholar
DeAngelis, D. L. & Waterhouse, J. C. 1987. Equilibrium and nonequilibrium concepts in ecological models. Ecological Monographs 57:121.CrossRefGoogle Scholar
Dent, M. C., Schulze, R. E., Wills, H. M. M. & Lynch, S. D. 1987. Spatial and temporal analysis of the recent drought in the summer rainfall of southern Africa. Water of South Africa 13:3742.Google Scholar
DeVilliers, P. A., Pietersen, E. W., Hugo, T. A., Meissner, H. H. & Kok, O. B. 1991. Methods of sampling food consumption by free-ranging elephant. South African Journal of Wildlife Research 21:2327.Google Scholar
Dublin, H. T., Sinclair, A. R. E. & McGlade, J. 1990. Elephants and fire as causes of multiple stable states in the Serengeti-Mara woodlands. Journal of Animal Ecology 59:11471164.CrossRefGoogle Scholar
DWNP 1993. Elephant census in northern Botswana. Department of Wildlife and National Park, Gaborone. (Unpubl. Mimogr.)Google Scholar
Dye, P. J. & Walker, B. H. 1980. Vegetation-environment relations on acidic soils of Zimbabwe, Rhodesia. Journal of Ecology 68:589606.CrossRefGoogle Scholar
Fowler, N. 1986. The role of competition in plant communities in arid and semiarid regions. Annual Review of Ecology and Systematics 17:89110.CrossRefGoogle Scholar
Gertenbach, W. P. D. 1980. Rainfall patterns in the Kruger National Park. Koedoe 23:3543.CrossRefGoogle Scholar
Guy, P. 1981. Changes in the biomass and productivity of woodlands in the Sengwa Wildlife Research Area, Zimbabwe. Journal of Applied Ecology 18:507519.CrossRefGoogle Scholar
Guy, P. 1989. The influence of elephants and fire on a Brachystegia-Julbernardia woodland in Zimbabwe. Journal of Tropical Ecology 5:215226.CrossRefGoogle Scholar
Hutchins, D. G., Hutton, S. M. & Jones, C. R. 1976. The geology of the Okavango Delta. Proceedings of the Symposium on the Okavango Delta and its Future Utilization. Botswana Society, National Museum, Gaborone.Google Scholar
Jachmann, H. 1991. Evaluation of four survey methods for estimating elephant densities. African Journal of Ecology 29:188195.CrossRefGoogle Scholar
Laws, R. M., Parker, I. S. C. & Johnstone, R. C. B. 1975. Elephants and their habitats. Clarendon Press, Oxford.Google Scholar
Lewis, D. M. 1991. Observations of tree growth, woodland structure and elephant damage on Colophospermum mopane in Luangwa Valley, Zambia. African Journal of Ecology 29:207221.CrossRefGoogle Scholar
McLanahan, T. R. 1986. Quick population survey method using faecal droppings and a steady state assumption. African Journal of Ecology 24:3739.CrossRefGoogle Scholar
Melton, D. A. 1985. The status of elephants in northern Botswana. Biological Conservation 31:317333.CrossRefGoogle Scholar
Rutherford, M. C. 1984. Relative allocation and seasonal phasing of growth of woody plants components in a South African savanna. Progress in Biometeorology 3:200221.Google Scholar
SAS 1988. SAS/STAT User's Guide, Release 6.02 Edition. SAS Institute Inc., Cary, North Carolina.Google Scholar
Scholes, R. J. & Walker, B. H. 1993. An African savanna: synthesis of the Nylsveley study. University Press, Cambridge.CrossRefGoogle Scholar
Schonau, A. P. G. & Purnell, R. C. 1987. A different approach to site evaluation and some preliminary results. South African Journal of Forestry 14:1925.CrossRefGoogle Scholar
Smithers, R. H. N. 1983. The mammals of the southern African subregion. University of Pretoria Press, Pretoria.Google Scholar
Van Wyk, P. & Fairall, N. 1969. The influence of the African elephant on the vegetation of the Kruger National Park. Koedoe 9:5795.Google Scholar
Wijngaarden, W. van 1985. Elephants-trees-grass-grazers: relationships between climate, soil, vegetation and large herbivores in a semi-arid savanna ecosystem (Tsavo, Kenya). ITC Publication No. 4. Wageningen.Google Scholar
Zuccini, W. & Himstra, L. A. V. 1983. A note on the relationship between annual rainfall and tree-ring indices for 1 site in South Africa. Water South Africa 9:155158.Google Scholar