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Potassium (Q/I) relationships as influenced by calcium and magnesium treated as separate ionic species, and by soil submergence

Published online by Cambridge University Press:  27 March 2009

N. S. Pasricha
N. S. Pasricha
Affiliation:
Department of Soils, Punjab Agricultural University, Ludhiana 141004, India
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Summary

The quantity–intensity relationships between gains and losses of exchangeable K of the soil, and the K-intensity in the equilibrium solution, were determined for two soils incubated at 25 ± 1 °C for 0, 2, 4, 6 and 8 weeks under submerged conditions. The Kintensity modified to include the factor (F) by which Mg differs from Ca in its behaviour on the exchange complex, i. e. aK/(Ca + F.Mg), gave significantly lower values of equilibrium activity ratio, , and higher values of linear buffering capacity (LBCK), than when measured by the simple ratio, aK/(aCa + aMg)½. The mean value of the factor, F, was 0·46 for Conlubang sandy loam and 0–49 for Luisiana clay. Submergence up to 2 weeks resulted in an increase in the equilibrium activity ratio, , by 43–3% in Conlubang sandy loam. In Luisiana clay, , increased slightly after an initial decrease. In both soils, the readily exchangeable K, , increased with submergence, more so in Conlubang sandy loam than in Luisiana clay. Linear buffering capacity, LBCk, which is a measure of the rate of release of K to the soil solution, increased markedly with soil submergence.

Type
Research Article
Information
The Journal of Agricultural Science , Volume 104 , Issue 3 , June 1985 , pp. 577 - 581
Copyright
Copyright © Cambridge University Press 1985

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References

Addiscott, T. M. (1970). A note on resolving soil cation exchange capacity into ‘mineral’ and ‘organic’ fractions. Journal of Agricultural Science, Cambridge 75, 365367.CrossRefGoogle Scholar
Beckett, P. H. T. (1964). The immediate Q/Irelations of labile potassium in soils. Journal of Soil Science 15, 923.CrossRefGoogle Scholar
Beckett, P. H. T. (1971). Potassium potentials, a review. Potash Review Subject 5, Suite 30, 141.Google Scholar
Beckett, P. H. T. & Nafady, M. H. M. (1967). Studies on soil potassium. VI. The effect of K-fixation and release on the form of the K:Ca + Mg exchange isotherm. Journal of Soil Science 18, 244262.CrossRefGoogle Scholar
Bray, R. H. (1942). Ionic competition in base-exchange reactions. Journal of the American Chemical Society 64, 954.CrossRefGoogle Scholar
De Datta, S. K. (1981). Principles and Practices of Rice Production. New York: Wiley.Google Scholar
Gapon, E. N. (1933). Theory of exchange adsorption in soils. Journal of General Chemistry, Moscow 3, 144.Google Scholar
Le Roux, J. & Sumner, M. E. (1968). Labile potassium in soils. I. Factors affecting the quantity-intensity (Q/I)parameters. Soil Science 106, 3541.CrossRefGoogle Scholar
Pasricha, N. S. (1983). Cation activity ratios in the soil solution and availability of potassium to rice in a submerged soil. Journal of Agricultural Science, Cambridge 100, 16.CrossRefGoogle Scholar
Patrick, W. H. Jr & Reddy, K. R. (1978). Chemical changes in rice soils. In Soils and Rice, pp. 361–79. International Rice Research Institute, Los Baños, Philippines.Google Scholar
Ponnamperuma, F. N. (1972). The chemistry of submerged soils. Advances in Agronomy 24, 29–96.Google Scholar
Ponnamperuma, F. N., Tianco, E. M. & Loy, T. A. (1966). Ionic strengths of the solutions of flooded soils, and other natural aqueous solutions from specific conductance. Soil Science 102, 408413.CrossRefGoogle Scholar
Salmon, R. C. (1964). Cation-activity ratios in equilibrium soil solutions and the availability of magnesium. Soil Science 98, 213221.CrossRefGoogle Scholar