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Qinghe Hou
School of Architecture, Southeast University, Nanjing 210096, China

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Journal article
Published: 13 May 2019 in 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.

ACS Style

Mo Wang; Dongqing Zhang; Siwei Lou; Qinghe Hou; Yijie Liu; Yuning Cheng; Jinda Qi; Soon Keat Tan. Assessing Hydrological Effects of Bioretention Cells for Urban Stormwater Runoff in Response to Climatic Changes. Water 2019, 11, 997 .

AMA Style

Mo Wang, Dongqing Zhang, Siwei Lou, Qinghe Hou, Yijie Liu, Yuning Cheng, Jinda Qi, Soon Keat Tan. Assessing Hydrological Effects of Bioretention Cells for Urban Stormwater Runoff in Response to Climatic Changes. Water. 2019; 11 (5):997.

Chicago/Turabian Style

Mo Wang; Dongqing Zhang; Siwei Lou; Qinghe Hou; Yijie Liu; Yuning Cheng; Jinda Qi; Soon Keat Tan. 2019. "Assessing Hydrological Effects of Bioretention Cells for Urban Stormwater Runoff in Response to Climatic Changes." Water 11, no. 5: 997.

Journal article
Published: 12 November 2018 in Water
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A bioretention system is a low-impact and sustainable treatment facility for treating urban stormwater runoff. To meet or maintain a consistently satisfactory performance, especially in terms of increasing nitrogen removal efficiency, the introduction of a submerged (anoxic) zone (SZ) combined with a module-based carbon source (C) has been recommended. This study investigated the removal of nitrogen (N), phosphorus (P) and heavy metals with a retrofitted bioretention system. A significant (p < 0.05) removal enhancement of N as well as total phosphorus (TP) was observed, in the mesocosms with additions of exogenous carbon as opposed to those without such condition. However, even in the mesocosm with SZ alone (without exogenous C), TP removal showed significant enhancement. With regard to the effects of SZ depth on nutrient removal, the results showed that the removal of both N and P in module with a shallow SZ (200 mm) showed significant enhancement compared to that in module with a deep SZ (300 mm). Removal efficiencies greater than 93% were observed for all three heavy metals tested (Cu, Pb, and Zn) in all mesocosms, even in the bioretention module without an SZ or plants, and it indicated that adsorption by the filtration media itself is probably the most important removal mechanism. Only Cu (but not Pb or Zn) showed significantly enhanced removal in module with an SZ as compared to those without an SZ. Carbon source played a minor role in metal removal as no significant (p > 0.05) improvement was observed in module with C as compared to that without C. Based on these results, the incorporation of SZ with C in stormwater biofilters is recommended.

ACS Style

Mo Wang; Dongqing Zhang; Yong Li; Qinghe Hou; Yuying Yu; Jinda Qi; Weicong Fu; Jianwen Dong; Yuning Cheng. Effect of a Submerged Zone and Carbon Source on Nutrient and Metal Removal for Stormwater by Bioretention Cells. Water 2018, 10, 1629 .

AMA Style

Mo Wang, Dongqing Zhang, Yong Li, Qinghe Hou, Yuying Yu, Jinda Qi, Weicong Fu, Jianwen Dong, Yuning Cheng. Effect of a Submerged Zone and Carbon Source on Nutrient and Metal Removal for Stormwater by Bioretention Cells. Water. 2018; 10 (11):1629.

Chicago/Turabian Style

Mo Wang; Dongqing Zhang; Yong Li; Qinghe Hou; Yuying Yu; Jinda Qi; Weicong Fu; Jianwen Dong; Yuning Cheng. 2018. "Effect of a Submerged Zone and Carbon Source on Nutrient and Metal Removal for Stormwater by Bioretention Cells." Water 10, no. 11: 1629.