Fijación de potasio y competencia con amonio en una arcilla expansiva

Danilo López-Hernández; Miguel  Mahia; William Meléndez; Ana López-Contreras

doi:10.51372/bioagro333.9

Authors

Danilo López-Hernández Instituto de Zoología y Ecología Tropical. Universidad Central de Venezuela. Centro de Ecología Aplicada, Apdo. 47058, Caracas 1041A, Venezuela. https://orcid.org/0000-0002-7787-3577
Miguel Mahia Instituto de Ciencias de la Tierra. Universidad Central de Venezuela, facultad de Ciencias, avenida Los Ilustres, Los Chaguaramos, Caracas, Venezuela. Apartado postal 3895
William Meléndez Instituto de Zoología y Ecología Tropical. Universidad Central de Venezuela. Centro de Ecología Aplicada, Apdo. 47058, Caracas 1041A, Venezuela.
Ana López-Contreras Instituto de Zoología y Ecología Tropical. Universidad Central de Venezuela. Centro de Ecología Aplicada, Apdo. 47058, Caracas 1041A, Venezuela.

DOI:

https://doi.org/10.51372/bioagro333.9

Keywords:

2:1 clays, K requirements, ion competition

Abstract

In Venezuela there are large areas of soils with the dominance of 2.1 clays with a strong capacity to retain potassium and ammonium ions in the interlaminar clay complex. As the ion K⁺ and NH₄⁺ have the same oxidation state (valence), as well as a similar ionic radius, both ions can compete in these expansive clays for fixed adsorption sites, and one of them may decrease the binding capacity of the other. Studies carried out on a clay located in Valles del Tuy, Miranda State, indicate the predominance of montmorillonite (bentonite) with a high capacity to fix potassium (Kf), since 54.5 % of K originally added to the soil it was fixed in the interlaminar soil complex. Kf dropped drastically when similar doses of K and ammonium salts (2.0 meq·100 g^-1 of NH₄Cl and KCl) were simultaneously added to the clay, while at higher doses of NH₄Cl in the experimental medium, Kf reached very low values (6 %). These results may indicate that in this kind of soil, a moderately low application of ammonia fertilization may favor the fixation of potassium, which can remain protected from losses due to leaching, therefore, acting as a potential reserve for future plant use.

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References

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Potassium fixation and ammonium competition on an expansive clay

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