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Aluminum-Based Water Treatment Residual Use in a Constructed Wetland for Capturing Urban Runoff Phosphorus: Column Study

Author:
Ippolito, J. A.
Source:
Water, air, and soil pollution 2015 v.226 no.10 pp. 334
ISSN:
0049-6979
Subject:
Festuca rubra subsp. rubra, aluminum, constructed wetlands, infiltration rate, iron, leaching, nutrient content, nutrient uptake, phosphorus, plant establishment, pollution control, sand, urban runoff, water treatment, watersheds, Idaho
Abstract:
Aluminum-based water treatment residuals (Al-WTRs) have a strong affinity to sorb P. In a proof-of-concept greenhouse column study, Al-WTR was surface-applied at rates equivalent to 0, 62, 124, and 248 Mg ha⁻¹ to 15 cm of soil on top of 46 cm of sand; Al-WTR rates were estimated to capture 0, 10, 20, and 40 years of P from an urban watershed entering an engineered wetland in Boise, ID, USA. Creeping red fescue (Festuca rubra) was established in all columns; one set of columns received no Al-WTR or plants. After plant establishment, once per week over a 12-week period, ∼1.0 pore volumes of ∼0.20 mg P L⁻¹ were added to each column. Infiltration rates were measured, leachate was collected and analyzed for soluble P, and fescue yield, P concentration, and uptake were determined. After plant harvest, the sand, soil, and the Al-WTR layer were collected and analyzed for Olsen P; amorphous Al, Fe, and P; P storage capacity (PSC); and soluble + Al + Fe-bound, occluded, and Ca-bound P phases. Infiltration rate increased only due to the presence of plants. Leached P decreased (50 %) with plants present; Al-WTR further reduced soluble P leaching losses (60 %). Fescue yield, P concentration, and uptake increased with increasing Al-WTR rate, due to Al-WTR sorbing and potentially making P more plant available; Olsen-extractable P increased with increasing Al-WTR rate, supporting this contention. The PSC was reduced with the 62 Mg ha⁻¹ Al-WTR rate but maintained with greater Al-WTR rates. The 124 and 248 Mg ha⁻¹ Al-WTR rates also contained greater P associated with the soluble + Al + Fe and occluded phases which should be stable over the long term (e.g., decadal). It was recommended to apply Al-WTR near the 124 and 248 Mg ha⁻¹ rates in the future to capture urban runoff soluble P in the Boise, ID, engineered wetland.
Agid:
61563
Handle:
10113/61563