Phosphate-induced clay dispersion as related to aggregate size and composition in hapludoxs

Although phosphate sorption is a well-understood phenomenon in soils, less is known of its effect on electrophoretic mobility (EM), isoelectric point (IEP), and clay particle dispersion in Oxisols. High phosphate sorption and high stability of aggregates are characteristic of Oxisols. Phosphate sorb ed as inner-sphere complexes brings negative charge to the surface of parti cles, affecting Ehl, IEP, and clay particle dispersion. The objectives of t his research were to determine the effect of residual sorbed P (after one s orption-desorption cycle in 0.015 M NaCl) on EM, IEP, and clay particle dis persion in aggregates of Oxisols with different organic matter contents and hematite/ goethite ratios. Aggregates of 1 to 2 and 0.1 to 0.2 mm were fra ctionated from samples of A and B horizons of two Oxisols, both with 165 g kg(-1) Fe2O3, that differ in their organic matter and hematite and goethite contents. Phosphate sorption decreased EM and IEP of B horizon aggregates. It also decreased the amount of dispersed clay, as the IEP decreased to va lues closer to the pH of the soil suspension, decreasing net positive charg e. Then, P sorption increased dispersed clay as the IEP became lower than t he pH of suspension. The effect was slightly higher on aggregates with high er hematite/goethite ratio. The changes on those parameters were mostly not ed for B horizon samples, where phosphate sorption had a major effect on ch arge balance because of their lower organic matter content. Small aggregate s had less dispersed clay than large aggregates.