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Pattern in a derived savanna in Nigeria

Published online by Cambridge University Press:  10 July 2009

P. Greig-Smith
P. Greig-Smith
Affiliation:
School of Plant Biology, University College of North Wales
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Abstract

All woody growth was enumerated in three transects, each 960 m x 20 m, in derived savanna in the Olokemeji Forest Reserve in south-west Nigeria. The data for species density, species basal area and stem girth classes were analysed by nested-block analysis of variance and covariance. The use of ‘total covariance’, the sum of all covariances at a block size, contributes to understanding of the pattern present.

Three scales of pattern were evident. Patchiness at 160–320 m is interpreted as a response to soil differences or to the pattern of previous farming, which may itself have been determined by soil differences. Patchiness at 20–40 m is attributable to varying intensity of burning. At the smallest scale, of 10 m, there is evidence of regularity of distribution resulting from interference between individuals, possibly due to competition for water.

Keywords

competitionfireinterferencepatternNigeriasavannatotal covariance
Type
Research Article
Information
Journal of Tropical Ecology , Volume 7 , Issue 4 , November 1991 , pp. 491 - 502
Copyright
Copyright © Cambridge University Press 1991

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References

LITERATURE CITED

Charley, J. L. & West, N. F. 1975. Plant-induced soil chemical patterns in some shrub-dominated semidesert ecosystems of Utah. Journal of Ecology 63:945963.CrossRefGoogle Scholar
Greig-Sahth, P. 1961. Data on pattern within plant communities. 1. The analysis of pattern. Journal of Ecology 49:695702.CrossRefGoogle Scholar
Greic-Smith, P. 1979. Pattern in vegetation. Journal of Ecology 67:755779.CrossRefGoogle Scholar
Greic-Smith, P. 1983. Quantitative plant ecology (3rd edition). Blackwell Scientific Publications, Oxford359 pp.Google Scholar
Gutierrez, J. R. & Fuentes, E. R. 1979. Evidence for intraspecific competition in the Acacia craven (Leguminosae) savanna of Chile. Oecologia Plantarum 14:151158.Google Scholar
Hopkins, B.. 1954. A new method for determining the type of distribution of plant individuals. Annals of Botany 18:213217.CrossRefGoogle Scholar
Hopkins, B. 1962. Vegetation of the Olokemeji Forest Reserve, Nigeria. I. General features of the reserve and the research sites. Journal of Ecology 50:559598.CrossRefGoogle Scholar
Hopkins, B. 1965a. Forest and savanna. Hcincmann, London. 100 pp.Google Scholar
Hopkins, B. 1965b. Observations on savanna burning in the Olokemeji Forest Reserve, Nigeria. Journal of Applied Ecology 2:367381.CrossRefGoogle Scholar
Hopkins, B. 1965c. Vegetation of the Olokemeji Forest Reserve, Nigeria. II. The climate with special reference to its seasonal changes. Journal of Ecology 53:109138.CrossRefGoogle Scholar
Hopkins, B. 1965d. Vegetation of the Olokemeji Forest Reserve, Nigeria. III. The microclimates with special reference to their seasonal changes. Journal of Ecology 53:125138.CrossRefGoogle Scholar
Hopkins, B. 1966. Vegetation of the Olokemeji Forest Reserve, Nigeria. IV. The litter and soil with special reference to their seasonal changes. Journal of Ecology 54:687703.CrossRefGoogle Scholar
Hutchinson, J. & Dalziel, J. M. 19541972. The flora of west tropical Africa (2nd edition, revised by Keay, R. W. J. & Hepper, F. N.). Crown Agents for Overseas Governments and Administrations, London.Google Scholar
Keay, R. W. J., Onochie, C. F. A. & Stanfield, D. P. 19601964. Nigerian trees. Federal Department of Forest Research, Ibadan. 329 + 495 pp.Google Scholar
Kershaw, K. A. 1960. The detection of pattern and association. Journal of Ecology 48:233242.CrossRefGoogle Scholar
Kershaw, K. A. 1961. Association and co-variance analysis of plant communities. Journal of Ecology 49:643654.CrossRefGoogle Scholar
Mead, R. 1974. A test for spatial pattern at several scales using data from a grid of contiguous quadrats. Biometrics 30:295307.CrossRefGoogle Scholar
Noy-Meir, I. & Anderson, D. J. 1971. Multiple pattern analysis, or multiscale ordination; towards a vegetation hologram? Pp. 207231 in Patil, G. P., Pielou, E. C. & Waters, W. E. (eds). Statistical ecology. Vol. 3 Many species populations, ecosystems and systems analysis. Pennsylvania Stale University Press, University Park, Pa.Google Scholar
Phillips, D. A. & Macmahon, J. A. 1981. Competition and spacing patterns in desert shrubs. Journal of Ecology 69:97115.CrossRefGoogle Scholar
Pielou, E. C. 1959. The use of point-to-plant distances in the study of the pattern of plant populations. Journal of Ecology 47:607613.CrossRefGoogle Scholar
Smith, T. M. & Goodman, P. S. 1986. The effect of competition on the structure and dynamics of Acacia savannas in southern Africa. Journal of Ecology 74:10311044.CrossRefGoogle Scholar
Smith, T. M. & Walker, B. H. 1983. The role of competition in the spacing of savanna trees. Proceedings of the Grassland Society of Southern Africa. 18:159164.CrossRefGoogle Scholar
Walter, H. 1962. Die Wasserversorgung der Wustenpflanzen. Scientia, Bologna (1962): 17.Google Scholar
Zinke, P. J. 1962. The pattern of influence of individual forest trees on soil properties. Ecology 43:130133.CrossRefGoogle Scholar