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| Phosphorus(P)is the limiting factor for biomass growth in surface waters. In sandy soils, due to their low sorp- tion capacity and high permeability, leaching processes are special interest (Sawhney 1977). Discharge of wastewater from agricultural and industrial activities contributes to P enrichment in aquatic ecosystems (Camargo et al. 2005). P in the soil solution exists as negatively charged P ion, but it is well known that P is relatively immobile in the soil system (Johnson et al. 1997). However, several recent studies provide clear evidence that P can be leached from soil under suitable conditions (Jalali and Kolahchi 2009; Jalali 2009; Maguire and Sims 2002; Heckrath et al. 1995). Leaching of nutrients including P from sandy soils has been identified as one of the main factors for degrading water quality (Chen et al. 2006). The amount and distri- bution of rainfall and the type and rate of used fertilizer are known as the factors that affect losses of P from sandy soils. P in soil is considered to be distributed among several geochemical forms including soil solution and exchangeable, organic matter phase, Ca-bound phase, Fe¨CAl-bound phase, and residual phases(Hedley et al. 1982a, b). A sequential chemical extraction of P from soils could provide a method- ology for examining soil P that allows for a better understanding of status of P (Linquist et al. 2011). Also, knowledge about P fractionation in soils is important for predicting bioavailability, leachability, and transformations of P between chemical forms in surface water and soils (Sui et al. 1999). The Ca- bound, Fe¨CAl oxide-bound, and organic matter- bound fractions could be considered relatively active depending on the actual physical and chemical prop- erties of soil. Soil amendment is considered as one of the best ways to reduce P leaching from sandy soils. Important factors for P retention are the pres- ence of amorphous aluminum (Al) oxides and iron (Fe) compounds in the soil (Börling et al. 2001; Borggaard et al. 1990). Also, presence of calcium (Ca) in soils decreases the release of P (Hughes and Gilkes 1984). Previous studies have shown that ad- dition of materials containing these elements can reduce P solubility (Kalbasi and Karthikeyan 2004; Dou et al. 2003). There are many methods to control P loss. One of these methods is the addition of nanoparticles (NPs) and natural clay minerals. To assess the risk of eutrophication problems, it is nec- essary to know the leaching behavior of P in the presence of modified and unmodified adsorbents when mixed with soil. Although, several investiga- tions of P leaching from amended soil with compost and inorganic fertilizer (Esteller et al. 2009; Elliot et al. 2002a); piggery waste ash (Kuligowski and Poulsen 2009); CaCl2, CaCO 3, Al(OH) 3, cellulose, and mill mud (Yang et al. 2007); and biosolids (Lu and O¡¯Connor 2001) have been carried out, relative- ly few studies on the P leaching from amended soil with clay minerals and NPs are available. On the other hand, several researchers are concerned that NPs transported in the environment may contami- nate surface and groundwater and pose potential risks to microorganisms, animals, and humans when applied in commercial quantities (Wiesner et al. 2006; Colvin 2003). Therefore, it is essential to understand the release of the NPs from soil column. The objectives of this paper are (1) to assess P leaching fromanamended sandy soil with clay minerals and NPs,(2)to investigate the different P form spresents in soil after P leaching,(3)to evaluate movement of Pin a column experiment using transport model, and (4) to evaluate movement of the NPs from soil column. |
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