Abstract

Abstract Potassium (K + ) directly released from primary K‐bearing minerals can contribute to plant nutrition. The objective of this research was to assess short‐term K + release and fixation on a range of intensively cropped calcareous soils. Potassium sorption and desorption properties and the contributions of exchangeable‐K + (EK) and nonexchangeable‐K + (NEK) pools to K + dynamics of the soil‐solution system was measured using a modified quantity‐to‐intensity (Q : I) experiment. Release and fixation of K + were varied among soils. The relation between the change in the amount of NEK during the experiment and the initial constrain was linear, and soil ability for K + release and fixation (β) for all soils varied from 0.041 to 0.183, indicating that 4% to 18% of added K + converted to NEK when fixation occurred. The equilibrium potential buffering capacity (PBC) for K + derived from Q : I experiments had significant correlation (r = 0.75, p < 0.01) with β, indicating that PBC depends not only on exchange properties but also on release and fixation properties. The depleted soils showed higher β value than the other soils, indicating much of the added K + was converted to NEK in case of positive constraint. The range of the amount of EK which was not in exchange equilibrium with Ca (E min ) in the experimental conditions was large and varied from 0.68 to 9.00 mmol kg –1 . On average, E min amounted to 64% of EK. This fraction of EK may not be available to the plant. The parameters obtained from these short‐term K + release and fixation experiments can be used in plant nutrition.