− | Past research done on the efficiency of the use of WTR for phosphorus reduction is promising. Laboratory studies have shown that WTRs adsorb large amounts of phosphorus and increase the phosphorus-sorbing capacity of soils. This decreases phosphorus losses in runoff and leaching. Surface application of WTRs showed an 88% reduction in runoff and leachate dissolved phosphorous. <ref name=Agyin/>Agyin-Birikorang et. al. also state that phosphorous sorption by aluminum-based WTRs is practically irreversible. <ref name = Agyin/> Results from another study state that WTR can be used for phosphorous removal in engineered wetlands and it carries the benefits of reuse of a by-product that promotes sustainability. <ref>Babatunde AO, Zhao YQ, Burke AM, Morris MA, Hanrahan JP. Characterization of aluminum-based water treatment residual for potential phosphorus removal in engineered wetlands. Environmental Pollution 157 (2015) 2830-2836. doi: 10.1016/j.envpol.2009.04.016</ref> It is estimated that the phosphorous adsorptive capacity of amended bioretention [[Bioretetion: Filter media|filter media]], which was mixed with 4% of WTR, was 4 times as high as the traditional media under the same conditions. <ref> Wang JJ, Li T, Zhang Y. Water treatment residual as a [[bioretention]] media amendment for phosphorus removal. Huan Jing ke xue: Huanjing kexue 12:35 (2014) 4642-4647. </ref> | + | Past research done on the efficiency of the use of WTR for phosphorus reduction is promising. Laboratory studies have shown that WTRs adsorb large amounts of phosphorus and increase the phosphorus-sorbing capacity of soils. This decreases phosphorus losses in runoff and leaching. Surface application of WTRs showed an 88% reduction in runoff and leachate dissolved phosphorous. <ref name=Agyin/>Agyin-Birikorang et. al. also state that phosphorous sorption by aluminum-based WTRs is practically irreversible. <ref name = Agyin/> Results from another study state that WTR can be used for phosphorous removal in engineered wetlands and it carries the benefits of reuse of a by-product that promotes sustainability. <ref>Babatunde AO, Zhao YQ, Burke AM, Morris MA, Hanrahan JP. Characterization of aluminum-based water treatment residual for potential phosphorus removal in engineered wetlands. Environmental Pollution 157 (2015) 2830-2836. doi: 10.1016/j.envpol.2009.04.016</ref> It is estimated that the phosphorous adsorptive capacity of amended bioretention [[Bioretention: Filter media|filter media]], which was mixed with 4% of WTR, was 4 times as high as the traditional media under the same conditions. <ref> Wang JJ, Li T, Zhang Y. Water treatment residual as a [[bioretention]] media amendment for phosphorus removal. Huan Jing ke xue: Huanjing kexue 12:35 (2014) 4642-4647. </ref> |