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Removal of chemical oxygen demand and dissolved nutrients by a sunken lawn infiltration system during intermittent storm events

rebecca.killalea@canberra.edu.au on 15 Mar 2022
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Author(s)
Hou, L., Yang, H., & Li, M.
Year
2013
Title
Removal of chemical oxygen demand and dissolved nutrients by a sunken lawn infiltration system during intermittent storm events
Source
Water Science and Technology
DOI
10.2166/wst.2013.728
Volume
69
Issue
2
Pages
398-406
ISSN/ISBN
0273-1223,1996-9732
Abstract

Urban surface water runoff typically contains high but varying amounts of organic matter and nutrients that require removal before reuse. Infiltration systems such as sunken lawns can improve water quality. However, there is currently insufficient information describing the treatment efficiency of lawn-based infiltration systems. In this study, novel sunken lawn infiltration systems (SLISs) were designed and their pollutant removal effectiveness was assessed. The results revealed that SLISs with Poa pratensis and Lolium perenne effectively removed most chemical oxygen demand (CODCr) and dissolved nutrients. Average CODCr, total nitrogen (TN), ammonium–nitrogen (NH4 þ-N) and total phosphorus (TP) concentrations were reduced by 78.93, 66.64, 71.86 and 75.83%, respectively, and the corresponding effluent concentrations met the standard for urban miscellaneous water consumption in China. The NH4 þ-N in the synthetic runoff was shown to be removed by adsorption during the stormwater dosing and nitrification during subsequent dry days, as well as through uptake by plants. Phosphorus was mainly removed by adsorption and chemical precipitation. The NH4 þ-N and phosphorus Langmuir isotherm model fitted the clay loam soil adsorption process better than the Freundlich model. Overall, these results indicate that an SLIS provides an alternative means of removing runoff pollutants owing to its efficiency, easy operation and maintenance.

Evidence

Cause Effect Response measure type Habitat Country Modified
Plants (riparian)
Sunken lawn infiltration systems planted with two species (Poa pratensis and Lolium perenne)
Water quality - oxygen (Decrease)
The effluent from the two planted systems had a higher removal efficiency of Chemical oxygen demand (COD) than the soil only treatment system. The removal efficiency of Poa pratensis was 81.74+/-6.00%, Lolium perenne was 76.13+/- 7.97% and soil only was 59.93+-2.2%.
 Mean difference Artificial China 16-Mar-2022
Plants (riparian)
Sunken lawn infiltration systems planted with two species (Poa pratensis and Lolium perenne)
Water quality - nutrients (nitrogen) (Decrease)
The effluent from the two planted systems had a higher removal efficiency of nitrogen than the soil only treatment system. The removal efficiency of Poa pratensis was 74.04+/-17.67%, Lolium perenne was 59.24+/-15.84% and soil only was 20.56+-14.74%. The nitrogen removal was suggested to be due to nitrification and denitrification.
 Mean difference Artificial China 16-Mar-2022
Plants (riparian)
Sunken lawn infiltration systems planted with two species (Poa pratensis and Lolium perenne)
Water quality - nutrients (phosphorus) (Decrease)
The effluent from the two planted systems had a higher removal efficiency of total phosphorus (TP) than the soil only treatment system. The removal efficiency of Poa pratensis was 80.12+/-9.45%, Lolium perenne was 71.54+/-13.83% and soil only was 50.17+-18.95%.
Mean difference Artificial China 16-Mar-2022