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Georgallas, Alexander

Permanent URI for this collectionhttps://hdl.handle.net/10222/38547

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    Modification of the biophysical water function to predict the change in soil mineral nitrogen concentration resulting from concurrent mineralization and denitrification
    (2012-08) Georgallas, Alex; Dessureault-Rompre, Jacynthe; Zebarth, Bernie J.; Burton, David L.; Drury, Craig F.; Grant, Cynthia A.
    Georgallas, A., Dessureault-Rompre, J., Zebarth, B. J., Burton, D. L., Drury, C. F. and Grant, C. A. 2012. Modification of the biophysical water function to predict the change in soil mineral nitrogen concentration resulting from concurrent mineralization and denitrification. Can. J. Soil Sci. 92: 695-710. Uncertainty in soil N supply is an important limitation in making crop fertilizer N recommendations. This study modified a biophysical water function developed to predict net soil N mineralization, making it possible to consider how both N mineralization and denitrification processes affect the rate of soil mineral N accumulation. Data were from a published experiment measuring changes in soil mineral N concentration in five soils of varying texture (loamy sand to clay loam) incubated for 3 mo with or without addition of red clover residue and at two levels of compaction. The biophysical water function was effective in fitting the relationship between scaled change in the rate of soil mineral N accumulation (Delta SMN) and scaled water-filled pore space (WFPSs) across soils and treatments provided that WFPSs = 1 was set to the water content at which the transition from mineralization to denitrification occurs. The water content at WFPSs = 1 varied with soil type, but not residue addition or compaction treatments, and was closely related to clay content. The k(D), parameter, which controls the denitrification term of the function, was influenced by soil type, whereas legume residue application had no significant effect on the k(D) parameter despite a twofold increase in net N mineralization. The modified biophysical water function holds promise for improving estimates of soil N supply because it can predict changes in Delta SMN in response to N mineralization and denitrification processes across a wide range of soil water contents.