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Effects of grass fallow treatments in restoring fertility of Buganda clay loam in South Uganda

Published online by Cambridge University Press:  27 March 2009

D. Stephens
D. Stephens
Affiliation:
Kawanda Research Station, Department of Agriculture, Uganda
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Extract

Between 1924 and 1934 Uganda, in common with many other African territories, tested arable rotations incorporating legumo green manures to maintain soil fertility (Martin, 1944; Uganda Dept., 1931–32) and it was concluded that the green manures failed to maintain fertility and were not worth the trouble involved. The Uganda Department of Agriculture accordingly changed its official rotations to modified forms of the indigenous shifting cultivation, namely 3 years of elephant grass rest alternating with 3 years of cropping. This same failure of green manures, combined with the apparent lack of correlation between crop yields and soil nutrient contents and the obvious deterioration of soil structure under crops, led Martin (1944) to the view that it was the physical not chemical condition of the soil which was important. Using his wet sieving technique he showed that, provided soils contained enough clay, all grass increased the water-stable crumbs over ½ mm diameter in the top soil and that 3 years under elephant grass was about optimal for restoring crumb structure.

Type
Research Article
Information
The Journal of Agricultural Science , Volume 68 , Issue 3 , June 1967 , pp. 391 - 403
Copyright
Copyright © Cambridge University Press 1967

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References

Birch, H. F. (1958). The effect of soil drying on humus decomposition and nitrogon availability. Pl. Soil 10 931.CrossRefGoogle Scholar
Birch, H. F. (1960). Nitrification in soils after different periods of dryness. Pl. Soil 12, 8196.CrossRefGoogle Scholar
Bridger, G. L., Boylan, D. R. & Markey, J. W. (1953). Colorimetric determination of phosphorus pentoxide in fertilizers using a standard calibration plot. Analyt. Chem. 25, 336–8.CrossRefGoogle Scholar
Butters, B. & Chenery, E. M. (1959). A rapid method for the determination of total sulphur in soils and plants. Analyst 84, 239–45.CrossRefGoogle Scholar
Chenery, E. M. (1954). Minor elements in Uganda soils. Proa. 2nd Int. Afr. Soil Conf. 3, 1157–63.Google Scholar
D'hoore, J. L. (1961). Soils map of Africa, 1:5,000,000. Scientific Council for Africa South of Sahara.Google Scholar
Farbrother, H. G. & Harrisson, L. E. (1957). On an electrical resistance technique for the study of soil moisture problems in the field. Emp. Cott. Or. Rev. 34, 122.Google Scholar
Griffith, G. AP. (1951). Factors influencing nitrate accumulation in Uganda soil. Emp. J. exp. Agric. 19, 112.Google Scholar
Harbop, J. F. (1962). Soils. Atlas of Uganda, 22. Department of Lands and Surveys, Uganda.Google Scholar
Hosegood, P. H. (undated). Field and Laboratory Techniques Currently Employed in the Physics Division, E.A.A.F.R.O. Cyclostyled report.Google Scholar
Manning, H. L. & Griffith, G. AP. (1949). Fertilizer studies on Uganda soils. E. Afr. agric. J. 15, 8797.Google Scholar
Martin, W. S. (1944). Grass covers in their relation to soil structure. Emp. J. exp. Agric. 12, 2132.Google Scholar
Martin, W. S. (1944). Soil structure. E. Afr. agric. J. 9, 189–95.Google Scholar
Mills, W. R. (1954). A review of recent trials with fertilizers in Uganda. Proc. 2nd Int. Afr. Soil Conf. 3, 1133–42.Google Scholar
Pereira, H. C. (1955). The assessment of structure in tropical soils. J. agric. Sci., Camb. 45, 401–10.CrossRefGoogle Scholar
Pereira, H. C., Chenery, E. M. & Mills, W. R. (1954). The transient effects of grasses on the structure of tropical soils. Emp. J. exp. Agric. 22, 148–60.Google Scholar
Radwanski, S. A. (1960). The soils and land use of Buganda. Research Memoir Department of Agriculture, Uganda, series 1, no. 4.Google Scholar
Robinson, J. B. D., Alien, M. De V. & Gaooka, P. (1959). The determination of soil nitrates with a brucine reagent. Analyst 84, 635–40.CrossRefGoogle Scholar
Uganda Department of Agriculture Annual Reports 19541958.Google Scholar
Uganda Department of Agriculture Annual Reports 19311932.Google Scholar
Uganda Department of Agriculture (19501954). Record of Investigations, nos. 1–4.Google Scholar
Williams, C. H. (1960). The use of lanthanum chloride to prevent interferences in the flame photometric determination of exchangeable calcium in soils. Analyt. Chim. Acta 22, 163–71.CrossRefGoogle Scholar
Yofé, J. & Finkelstein, R. (1958). Elimination of anionic interference in flame photometric determination of calcium in the presence of phosphate and sulphate. Analyt. Chim. Acta 19, 166–73.CrossRefGoogle Scholar