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To Prevent Aridization, Combat Salinity*

Published online by Cambridge University Press:  24 August 2009

Victor A. Kovda
Victor A. Kovda
Affiliation:
Professor, Subfaculty of Pedology, Moscow State University, Moscow 177234, USSR; formerly Director, Institute of Agrochemistry and Soil Science of the Academy of Sciences of the USSR; sometime President of the International Society of Soil Science and President of SCOPE.
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With some 8% of the world's land-surface occupied by absolute desert, and up to another 40% estimated to be covered or threatened by less-extreme deserts or semideserts, it is clear that still-increasing desertification imposes one of the most critical situations and hence important considerations for the future of Man and Nature. All the inhabited continents are involved to varying degrees, with Australia (80% desertified) the worst-hit areally. And yet the area of the world that is affected by desertification, soil-degradation, erosion, and/or recurrent droughts, continues to increase at a rate of 5–7 million hectares annually in the face of ever-increasing overall human population. This survey warns again of foreseeable dangers for the future.

Aridization and more advanced desertification of land result from the combined action of natural tendencies and ecological mistakes made by Man in the course of his manifold activities. Most alarmingly, the velocity of what is mainly anthropogenic aridization is commonly measured in terms of a few years or at most a single human generation. But help should come from the maintenance of rain-fed farming in less arid areas, and especially from the widespread establishment of irrigation systems which now involve some 250 millions of hectares. There are, however, very serious problems engendered by continuing irrigation, which is apt to be wasteful of fresh water. To begin with, river-water resources are becoming increasingly limited and artesian waters are too-easily depleted or become brackish. Worse still, with the high rate of evaporation in arid regions, salinization of the surface and the uppermost soil horizon commonly ensues, and gradually penetrates to lower strata in which plants mainly root. Most existing irrigation systems lack the piping or consistent lining of water-bringing canals and the deep (2.5–3 m) horizontal drainage-ducts that are needed to evacuate excessive soluble salts. The ultimate disposal of the salt, moreover, still causes problems when the sea cannot be used or salt-lakes be created for fish and waterfowl. Meanwhile, revegetation is becoming more and more widely practised and some success is attending efforts to develop salt-resistant crops in USA, India, and USSR.

Type
Main Papers
Information
Environmental Conservation , Volume 9 , Issue 4 , Winter 1982 , pp. 323 - 327
Copyright
Copyright © Foundation for Environmental Conservation 1982

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References

REFERENCES

Arnon, I. (1972). Crop Production in Dry Regions, Vol 1: Background and Principles; Vol. 2: Systematic Treatment of the Principal Crops. (Plant Science Monographs, Ed. Polunin, Nicholas.) Leonard Hill: Intertext, London, England, UK: xxii + 650 and xxvi + 683 pp., respectively (both illustr.).Google Scholar
Arnon, I. (1981). Modernization of Agriculture in Developing Countries: Resources, Potentials and Problems. (Environmental Monographs & Symposia), Convener & General Editor Polunin, N..) John Wiley & Sons, Chichester-New York-Brisbane-Toronto: xxiii + 565 pp., illustr.Google Scholar
Biswas, Margaret R. (1978). The UN Conference on Desertification, in retrospect. Environmental Conservation, 5(4), pp. 247–62.Google Scholar
Cloudsley-Thompson, J.L. (1974). The expanding Sahara. Environmental Conservation, 1(1), pp. 513, 7 figs.Google Scholar
Ehrlich, A.H. & Ehrlich, P.R. (1981). Dangers of uninformed optimism. Environmental Conservation, 8(3), pp. 173–5.Google Scholar
Hare, F.K. (1977). Connections between climate and desertification. Environmental Conservation, 4(2), pp. 8190, 5 figs.Google Scholar
Kassas, M. (1972). Ecological consequences of water development projects. Pp. 215–35 and discussion to p. 246 in The Environmental Future (ed. Polunin, Nicholas). Macmillan, London & Basingstoke, England, and Barnes & Noble, New York, USA: xiv + 650 pp., illustr.Google Scholar
Kovda, V.A. (19461947). The Origin of Saline Soils and Their Régime (translated from the Russian, 1971). Academy of Sciences of USSR, Moscow-Leningrad: [not available for checking].Google Scholar
Kovda, V.A. (1980). Land Aridization and Drought Control. Westview Press, 5500 Central Avenue, Boulder, Colorado 80301, USA: xix + 277 pp., illustr.Google Scholar
Mabbutt, J.A. (1978). The impact of desertification as revealed by mapping. Environmental Conservation, 5(1), pp. 4556, 4 figs.Google Scholar
United Nations Conference on Desertification (1977). Desertification: Its Causes and Consequences. Pergamon Press, Oxford, England, UK: v + 488 pp., illustr.Google Scholar
United Nations Environment Programme [cited as UNEP] (1978). Additional Measures, and Means of Financing for the Implementation of the Plan of Action to Combat Desertification. (Note by the Executive Director.) UNEP/GC. 6/9/Add. 1, UNEP, Nairobi, Kenya: ii + 22 pp. (mimeogr.).Google Scholar
Went, F.W. & Babu, V.R. (1978). Plant life and desertification. Environmental Conservation, 5(4), pp. 263–72, 6 Figs.CrossRefGoogle Scholar