Phosphorus (P) is one of the major

Phosphorus (P) is one of the major nutrients limiting crop
production. One method to raise soil available P to the critical crop
level is by addition of P fertilizer. However, continued long-term
application of fertilizers can lead to P accumulation in surface horizons
greater than that required for optimum plant growth, thus increasing
the potential for P loss to surface waters and eutrophication (McDowell
et al., 2001; Sui et al., 1999). Soil P reserves make an important
contribution to plant P supply. In intensively cultivated and fertilized
soils, P availability has increased, as measured by soil test methods (Sui
et al., 1999; Jalali, 2007). Some agricultural soils can now be classified
as overfertilized due to a steady increase in available P resulting from
application of fertilizer P in the past (Sharpley and Smith, 1989). Many
soils in Iran have received large amounts of P fertilizer and
consequently contained high level of available P (Jalali, 2007).
The release of organically and inorganically bound nutrients like
P, which can then be utilized by plants, is particularly important in
agriculture. For optimal nutrition of crop, the replenishment of a Pdepleted
soil solution is affected predominately by the release of P from
clay minerals and organic matter. Hughes et al. (2000) indicated that
the release rate of adsorbed P directly affects the P supply to plants. In
addition, the release of P may have a significant impact on the surface
and ground water quality. Thus, knowledge of the rate of release of P
from soils is important for long-term planning of crop production
while minimizing the impact on the surface and groundwater quality.
Phosphorus in soil is considered to be distributed among several
geochemical forms that include soil solution and exchangeable phase,
organic matter phase, Ca-bound phase, and Fe-Al- bound phase and
residual phase (Hedley et al., 1982a,b). The degree of P associationwith
different geochemical forms strongly depends upon physico-chemical
properties of different soil types (Tiessen et al., 1984), climate, and
management practices (Motavalli and Miles, 2002). Various P fractions
have remarkable differences in mobility, bioavailability and chemical
behaviors in soil and can be transformed under certain conditions
(Sharpley et al., 2000). Sequential extraction technique is used to define
them in soils both as qualitatively as well as quantitatively. Such
information is potential useful for predicting bioavailability, P leachability
and transformations of P between chemical forms in agricultural and
polluted soils (Hedley et al., 1982a,b; Sui et al., 1999). In contrast to
analysis of total P, redistribution among various fractions is important for
P mobility. The Ca-bound, Fe–Al oxide bound, and organic matter bound
fractions could be considered relatively active depending on the actual
physical and chemical properties of soil.