Abstract
Runoff from clayey soils often contains abundant particulate phoshorus (PP), part of which may solubilize in surface waters. Monitoring losses of potentially bioavailable forms of PP is expensive, calling for other ways to predict them. Such predictions could be based on soil loss and available soil P indices, e.g., agronomic P status. To study correlations between P pools in runoff versus soil P saturation (by Mehlich 3 extraction; DPSM3) and acetate soil test P (PAc), 15 clayey soils of south Finland were subjected to laboratory rainfall simulation. Runoff from these simulations was analyzed for concentrations of suspended soil (TSS), dissolved molybdate-reactive P (DRP), total P (TP), and, as normalized to soil loss, potentially bioavailable forms of PP: desorbable (anion exchange resin-extractable, AER-PP/TSS) and redox-labile PP (bicarbonate- dithionite-extractable, BD-PP/TSS). Correlation coefficients (r2) between DPSM3 and DRP, AER-PP/ TSS, and BD-PP/TSS equaled 0.92, 0.77, and 0.45, respectively. Runoff P forms were also correlated to soil PAc with r2 values of 0.84, 0.56, and 0.58 for DRP, AER-PP/TSS, and BD-PP/TSS, respectively. Prediction of soil loss-normalized concentrations of potentially bioavailable PP by the agronomic PAc test was considered possible. However, such predictions have a high degree of uncertainty, evidenced by comparison to published field data. Acceptably accurate predictive equations would require a large material as a basis for their construction, and soils should probably also be grouped according to other soil properties that would account for variation in P sorption capacity.;
Highlights
PAc with r2 values of 0.84, 0.56, and 0.58 for dissolved molybdate-reactive P (DRP), AER-particulate phoshorus (PP)/total suspended solids (TSS), and BD-PP/TSS, respectively
Depending on soil characteristics and environmental conditions, a variable part of the runoff PP may become algal-available over time (Logan et al In areas where clayey soils are abundant, particulate phosphorus (PP) is the major form of P in field
We report results of a rainfall simulation study in which we tested the potential of acid ammonium acetate buffer, the agronomic soil test of Finland, and an estimate of soil P saturation, based on extraction using Mehlich-3 solution, for their abilities to predict the concentrations of (i) DRP in runoff and (ii) the content of potentially bioavailable P forms in sediment
Summary
Runoff from clayey soils often contains abundant particulate phoshorus (PP), part of which may solubilize in surface waters. To study correlations between P pools in runoff versus soil P saturation (by Mehlich 3 extraction; DPSM3) and acetate soil test P (PAc), 15 clayey soils of south Finland were subjected to laboratory rainfall simulation Runoff from these simulations was analyzed for concentrations of suspended soil (TSS), dissolved molybdate-reactive P (DRP), total P (TP), and, as normalized to soil loss, potentially bioavailable forms of PP: desorbable (anion exchange resin-extractable, AER-PP/TSS) and redox-labile PP (bicarbonate-dithionite-extractable, BD-PP/TSS). We report results of a rainfall simulation study in which we tested the potential of acid ammonium acetate buffer, the agronomic soil test of Finland, and an estimate of soil P saturation, based on extraction using Mehlich-3 solution, for their abilities to predict the concentrations of (i) DRP in runoff and (ii) the content of potentially bioavailable P forms (i.e., desorbable and redox-sensitive PP/TSS) in sediment.
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