Please use this identifier to cite or link to this item: https://hdl.handle.net/20.500.14279/1200
Title: Physicochemical properties related to long-term phosphorus retention by drinking-water treatment residuals
Authors: Harris, Willie G. 
O'Connor, George A. 
Obreza, Thomas A. 
Elliott, Herschel A. 
Makris, Konstantinos C. 
Major Field of Science: Natural Sciences
Field Category: Earth and Related Environmental Sciences
Keywords: Drinking-water treatment residuals (WTR);Nonhazardous materials;Phosphorus sorption;Specific surface area (SSA)
Issue Date: 1-Jun-2005
Source: Environmental Science & Technology, 2005, Volume 39, Issue 11, Pages 4280-4289
Volume: 39
Issue: 11
Start page: 4280
End page: 4289
Journal: Environmental Science & Technology 
Abstract: Drinking-water treatment residuals (WTRs) are nonhazardous materials that can be obtained free-of-charge from drinking-water treatment plants to reduce soluble phosphorus (P) concentrations in poorly P sorbing soils. Phosphorus sorption capacities of WTRs can vary 1-2 orders of magnitude, on the basis of short-term equilibration times (up to 7 d), but studies dealing with long-term (weeks to months) P retention by WTRs are lacking. Properties that most affect long-term P sorption capacities are pertinent to the efficacy of WTRs as amendments to stabilize P in soils. This research addressed the long-term (up to 80 d) P sorption/desorption characteristics and kinetics for seven WTRs, including the influence of specific surface area (SSA), porosity, and total C content on the overall magnitude of P sorption by seven WTRs. The data confirm a strong but variable affinity for P by WTRs. Aluminum-based WTRs tended to have higher P sorption capacity than Fe-based WTRs. Phosphorus sorption with time was biphasic in nature for most samples and best fit to a second-order rate model. The P sorption rate dependency was strongly correlated with a hysteretic P desorption, consistent with kinetic limitations on P desorption from micropores. Oxalate-extractable Al + Fe concentrations of the WTRs did not effectively explain long-term (80 d) P sorption capacities of the WTRs. Micropore (CO 2-based) SSAs were greater than BET-N2 SSAs for most WTRs, except those with the lowest (<80 g kg-1) total C content. There was a significant negative linear correlation between the total C content and the CO2/N2 SSA ratio. The data suggest that C in WTRs increases microporosity, but reduces P sorption per unit pore volume or surface area. Hence, variability in C content confounds direct relations among SSA, porosity, and P sorption. Total C, N2-based SSA, and CO 2-based SSAs explained 82% of the variability in the long-term P sorption capacities of the WTRs. Prediction of long-term P sorption capacities for different WTRs may be achieved by taking into account the three proposed variables.
URI: https://hdl.handle.net/20.500.14279/1200
ISSN: 15205851
DOI: 10.1021/es0480769
Rights: © American Chemical Society
Type: Article
Affiliation : University of Texas 
University of Florida 
Pennsylvania State University 
Publication Type: Peer Reviewed
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