Performance Evaluation of a Full‐Scale Constructed Wetland for Treating Stormwater Runoff

Li, Yi Cheng; Zhang, Dong Qing; Wang, Mo

doi:10.1002/clen.201600740

Cited by 25 publications

(15 citation statements)

References 37 publications

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“…Unlike traditional constructed wetlands, FTWs float and so can adjust to water level fluctuations (Headley and Tanner 2007;Lane et al 2016). FTWs have been used and evaluated for treatment of urban stormwater (Borne et al 2013;Li et al 2017;Winston et al 2013), overflows from combined sewage systems (Shen et al 2018;Van de Moortel 2008), acid mine drainage (Smith and Kalin 2000), agricultural runoff, and other waste waters (Chen et al 2016;Stewart et al 2008). Benefits associated with FTWs include improved water quality, reduced shoreline erosion, and provision of wildlife habitat (Borne et al 2015;Lynch et al 2015;.…”

Section: Responsible Editor: Yi-ping Chenmentioning

confidence: 99%

Assessing nitrogen and phosphorus removal potential of five plant species in floating treatment wetlands receiving simulated nursery runoff

Spangler

Sample

Fox

et al. 2019

Environ Sci Pollut Res

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The feasibility of using floating treatment wetlands (FTWs) to treat runoff typical of commercial nurseries was investigated using two 8-week trials with replicated mesocosms. Plants were supported by Beemat rafts. Five monoculture treatments of Agrostis alba (red top), Canna × generalis 'Firebird' (canna lily), Carex stricta (tussock sedge), Iris ensata 'Rising Sun' (Japanese water iris), Panicum virgatum (switchgrass), two mixed species treatments, and an unplanted control were assessed. These plant species are used for ornamental, wetland, and biofuel purposes. Nitrogen (N) and phosphorus (P) removals were evaluated after a 7-day hydraulic retention time (HRT). N removal (sum of ammonium-N, nitrate-N, and nitrite-N) from FTW treatments ranged from 0.255 to 0.738 g•m −2 •d −1 (38.9 to 82.4% removal) and 0.147 to 0.656 g•m −2 •d −1 (12.9 to 59.6% removal) for trials 1 and 2, respectively. P removal (phosphate-P) ranged from 0.052 to 0.128 g•m −2 •d −1 (26.1 to 64.7% removal) for trial 1, and 0.074 to 0.194 g•m −2 •d −1 (26.8 to 63.2% removal) for trial 2. Panicum virgatum removed more N and P than any other FTW treatment and the control in both trials. Results show that species selection and timing of FTW harvest impact the rate and mass of nutrient remediation. FTWs can effectively remove N and P from runoff from commercial nurseries.

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Section: Responsible Editor: Yi-ping Chenmentioning

confidence: 99%

Assessing nitrogen and phosphorus removal potential of five plant species in floating treatment wetlands receiving simulated nursery runoff

Spangler

Sample

Fox

et al. 2019

Environ Sci Pollut Res

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“…Due to their flexibility of scale, BCs' positive life-cycle benefits can be effectively integrated into dense urban areas [32][33][34]. BCs have been widely applied in urban areas through strong support from local governments, such as in the Sponge City program [35].…”

Section: Study Sitementioning

confidence: 99%

Assessing Hydrological Effects of Bioretention Cells for Urban Stormwater Runoff in Response to Climatic Changes

Wang

Zhang

Lou

et al. 2019

Water

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An investigation into the effectiveness of bioretention cells (BCs) under potential climatic changes was conducted using representative concentration pathways. A case study of Guangzhou showed changes in peak runoff in climate change scenarios, with obvious growth in RCP8.5 and slight growth in RCP2.6. The performance of BCs on multiple parameters, including reduction of runoff volume, peak runoff, and first flush, were examined in different design storms using a hydrology model (SWMM). The effectiveness of BCs varied non-linearly with scale. Their performance fell by varying amounts in the various scenarios. BCs could provide sufficient effects in response to short-return-period and short-duration storms, but the performance of BCs decreased with heavy storms, especially considering climate change. Hence, BCs cannot replace grey infrastructure but should be integrated with them. The method developed in this study could be useful in the planning and design of low impact development in view of future climate changes.

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“…Although plants can partially degrade the organic compounds, nevertheless, complete degradation is indispensable without effective partnership with microorganisms . The partnership can be neutral, commensal, and dormant . Plant roots are the primary site for bacteria to colonize plant tissue.…”

Section: Plant–bacterial Synergism In Ftwsmentioning

confidence: 99%

“…[76,77] The partnership can be neutral, commensal, and dormant. [75,[78][79][80] Plant roots are the primary site for bacteria to colonize plant tissue. However, they do not remain limited to roots surface but can also enter the plant to dwell inside and to get nutrients.…”

Section: Plant-bacterial Synergism In Ftwsmentioning

confidence: 99%

Floating Wetlands: A Sustainable Tool for Wastewater Treatment

Shahid

Arslan

Ali

et al. 2018

CLEAN Soil Air Water

101

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Floating treatment wetland (FTW) is an effective and sustainable technology for wastewater treatment. It has been widely adopted for treating various kinds of polluted water including agricultural runoff, stormwater, industrial effluents, etc. In FTWs, plants are vegetated on a floating mat while their roots are extended down to the contaminated water hence acting as biological filters. Nutrients and potentially toxic metal(s)/element(s) are taken up from the wastewater by plants through their roots whereas organic matter is degraded by the microorganisms forming biofilms on the roots and mat surface. Additionally, organic contaminants which are already taken up by the plants are degraded by endophytic bacteria in planta. This article provides an overview of FTWs and their application for wastewater treatment. The key factors which have an impact on the performance of FTWs are also described. Lastly, the potential role of combined use of plants and bacteria in FTWs for the maximum remediation of polluted water is emphasized.

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Performance Evaluation of a Full‐Scale Constructed Wetland for Treating Stormwater Runoff

Cited by 25 publications

References 37 publications

Assessing nitrogen and phosphorus removal potential of five plant species in floating treatment wetlands receiving simulated nursery runoff

Assessing nitrogen and phosphorus removal potential of five plant species in floating treatment wetlands receiving simulated nursery runoff

Assessing Hydrological Effects of Bioretention Cells for Urban Stormwater Runoff in Response to Climatic Changes

Floating Wetlands: A Sustainable Tool for Wastewater Treatment

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