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Desalinization of a salt-affected soil in plots of various sizes under two modes of water application

Published online by Cambridge University Press:  27 March 2009

I. S. Dahiya
Affiliation:
Department of Soils, Haryana Agricultural University, Hissar, Haryana, India
K. S. Grewal
Affiliation:
Department of Soils, Haryana Agricultural University, Hissar, Haryana, India
R. Anlauf
Affiliation:
Institutfilr Bodenkunde der Universitat Hannover, Herrenhduserstrasse 2, D-3000 Hannover 21, Federal Republic of Germany
J. Richter
Affiliation:
Institutfilr Bodenkunde der Universitat Hannover, Herrenhduserstrasse 2, D-3000 Hannover 21, Federal Republic of Germany

Summary

Leaching in a salt-affected, permeable, sandy loam soil was evaluated under continuous and intermittent ponding conditions in 2 × 2 m (S1), 4 × 4 m (S2) and 6 × 6 m (S3) plots. The soil contained large amounts of soluble salts throughout the profile to the water table, chiefly chlorides and sulphates of sodium, calcium and magnesium. The leaching curves did not differ significantly between Slf Sa and S3 plots under continuous ponding but did under intermittent ponding. The leaching efficiency decreased sharply with increased plot size. The leaching efficiency in Sj plots was significantly greater with intermittent than with continuous ponding, but the reverse was true in S3 plots. The displacement of the resident soil solution in S1 plots under intermittent ponding was nearly piston-like. With increased plot size, it tended to deviate from this behaviour. The leaching curves from S3 plots (this size being reasonable in farmers' fields) were compared with those obtained from numerical solution of a simplified steady-state salt transport model. The model also included a source term, solubility rate constant, for the slightly soluble salts present in the experimental soil. The pore water velocity was estimated from field capacity and time-averaged infiltration rate. The effective dispersion coefficient and solubility rate constant were estimated by a least-squares minimization technique. A reasonably good agreement was obtained between simulated and experimental leaching curves. For practical purposes, this simple model may be adequate to predict leaching in salt-affected soils similar to the one under consideration.

Type
Research Article
Copyright
Copyright © Cambridge University Press 1985

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References

Addiscott, T. M. (1977). A simple computer model for leaching in structured soils. Journal of Soil Science 28, 554563.CrossRefGoogle Scholar
Amoozegab-Fard, A., Warrick, A. W. & Fulleb, W. H. (1983). A simplified model for solute movement through soils. Soil Science Society of America Journal 47, 10471049.Google Scholar
Bresler, E., Mcneal, B. L. & Caster, D. L. (1982). Saline and Sodic Soils: Principles-Dynamics-Modeling. Berlin, Heidelberg, New York: Springer-Verlag.Google Scholar
Dahiya, I. S. (1978). Salt-affected soils in India. III. How to live with them. Agriculture and Agro-Industries Journal, Bombay 11 (8), 1726. 11 (9), 17–24, 11 (10), 17–23.Google Scholar
Dahiya, I. S. & Abrol, I. P. (1973). Dynamics of calcium-sodium exchange under unsaturated flow conditions. Communications in Soil Science and Plant Analysis 4, 443453.Google Scholar
Dahiya, I. S. & Abrol, I. P. (1974). The redistribution of surface salts by transient and steady infiltration of water into dry soils. Journal of Indian Society of Soil Science 22, 209216.Google Scholar
Dahiya, I. S., Abrol, I. P. & Hajrasuliha, S. (1980). Modeling transport of reactive solutes in saline-sodic soils rich in soluble carbonates. Agricultural Water Management 3, 316.Google Scholar
Dahiya, I. S. & Dahiya, S. S. (1977). Salt-affected soils in India. I. Their origin, occurrence and characteristics. Agriculture and Agro-Industries Journal, Bombay 10(1), 1116.Google Scholar
Dahiya, I. S., Malik, R. S. & Richter, J. (1983). Testing of simple leaching models in a field soil. International Journal of Tropical Agriculture 1, 193202.Google Scholar
Dahiya, I. S., Malik, R. S. & Singh, M. (1981). Field studies on leaching behaviour of a highly saline-sodic soil under two modes of water application in the presence of crops. Journal of Agricultural Science, Cambridge 97, 383389.Google Scholar
Dahiya, I. S., Malik, R. S. & Singh, M. (1982). Reclaiming a saline-sodic, sandy loam soil under rice production. Agricultural Water Management 5, 6172.CrossRefGoogle Scholar
Dahiya, I. S., Richter, J. & Malik, R. S. (1984). Soil spatial variability: a review. International Journal of Tropical Agriculture 2, 1102.Google Scholar
Dahiya, I. S., Singh, M., Richter, J. & Singh, M. (1984). Leaching of soluble salt during infiltration and redistribution. Irrigation Science 5, 1524.Google Scholar
Dahiya, I. S., Singh, M., Singh, M. & Hajrasuliha, S. (1980). Simultaneous transport of surface applied salts and water through unsaturated soils as affected by infiltration, redistribution and evaporation. Soil Science Society of America Journal 44, 223228.CrossRefGoogle Scholar
Elgabaly, M. M. (1971). Reclamation and Management of Salt Affected Soils. Regional Seminar on Methods of Amelioration of Saline and Alkali Soils, Bagdad. F.A.O. Irrigation and Drainage Paper no. 7, pp. [5059.Google Scholar
Evans, N. H. (1974). Finding knowledge gaps: the key of salinity control solutions. In Salinity in Water Resources (ed. Flack, J. E. and Howe, C. W.). Boulder, Colorado: Merriman.Google Scholar
Frissel, M. L., Poelstra, P. & Reinigeii, P. (1970). Chromatographic transport through soils. III. A simulation method for the evaluation of the apparent diffusion coefficient in undisturbed soils with tritiated water. Plant and Soil 33, 161176.Google Scholar
Khosla, B. K., Gupta, R. K. & Abrol, I. P. (1979). Salt leaching and the effect of gypsum application in a saline-sodic soil. Agricultural Water Management 2, 193202.CrossRefGoogle Scholar
Kirda, C., Nielsen, D. R. & Biggar, J. W. (1974). The combined effect of infiltration and redistribution on leaching. Soil Science 117, 323330.Google Scholar
Leffelaar, P. A. & Sharma, R. P. (1977). Leaching of a highly saline-sodic soil. Journal of Hydrology 32, 203218.Google Scholar
Miller, R. J., Biggar, J. W. & Nielsen, D. R. (1965). Chloride displacement in Panoche clay loam in relation to water movement and distribution. Water Resources Research 1, 6373.CrossRefGoogle Scholar
Oster, J. D., Willardson, L. S. & Hoffman, G. J. (1972). Sprinkling and ponding techniques for reclaiming saline soils. Transactions of American Society of Agricultural Engineers 15, 11151117.CrossRefGoogle Scholar
Pal, R. & Poonia, S. R. (1982). Predictive approaches for solute transport in soils. Journal of Scientific and Industrial Research, New Delhi 41, 117130.Google Scholar
Richards, L. A. (1954). Diagnosis and Improvement of Saline and Alkali Soils. United States Department of Agriculture Handbook no. 60.Google Scholar
Richter, J., Scharpf, H. C. & Wehrmann, J. (1978). Simulation der winterlichen Nitratverlagerung in Boden. Plant and Soil 49, 381393.CrossRefGoogle Scholar
Rose, D. A. & Passioura, J. B. (1971). The analysis of experiments on hydrodynamic dispersion. Soil Science 111, 252257.CrossRefGoogle Scholar
Smiles, D. E., Perroux, K. M., Zegelin, S. J. & Raats, P. A. C. (1981). Hydrodynamic dispersion during constant rate absorption of water by soil. Soil Science Society of America Journal 45, 453458.Google Scholar
Smiles, D. E., Philip, J. R., Knight, J. H. & Elrick, D. E. (1978). Hydrodynamic dispersion during absorption of water by soil. Soil Science Society of America Journal 42, 229236.Google Scholar
Talsma, T. (1967). Leaching of the tile-drained saline soils. Australian Journal of Soil Research 5, 3746.CrossRefGoogle Scholar
Wild, A. & Babiker, I. A. (1976). The asymmetric leaching pattern of nitrate and chloride in a loamy sand under field conditions. Journal of Soil Science 27, 460466.CrossRefGoogle Scholar