References

  1. R.H. Kadlec, Effects of pollutant speciation in treatment wetlands design, Ecol. Eng., 20 (2003) 1–16.
  2. D.C. Seo, J.S. Cho, H.J. Lee, J.S. Heo, Phosphorus retention capacity of filter media for estimating the longevity of constructed wetland, Water Res., 39 (2005) 2445–2457.
  3. D. Konnerup, T. Koottatep, H. Brix, Treatment of domestic wastewater in tropical, subsurface flow constructed wetlands planted with Canna and Heliconia, Ecol. Eng., 35 (2009) 248–257.
  4. J. Vymazal, Removal of BOD5 in constructed wetlands with horizontal sub-surface flow: Czech experience, Water Sci. Technol., 40 (1999) 133–138.
  5. G. Maltais-Landry, R. Maranger, J. Brisson, F. Chazarenc, Greenhouse gas production and efficiency of planted and artificially aerated constructed wetlands, Environ. Pollut., 157 (2009) 748–754.
  6. P.S. Burgoon, K.R. Reddy, T.A. Debusk, Performance of subsurface flow wetlands with batch-load and continuous-flow conditions, Water Environ. Res., 67 (1995) 855–862.
  7. Q.L. Zhao, B.Z. Wang, Evaluation on a pilot-scale attachedgrowth pond system treating domestic wastewater, Water Res., 30 (1996) 242–245.
  8. T. Pan, X.D. Zhu, Y.P. Ye, Estimate of life-cycle greenhouse gas emissions from a vertical subsurface flow constructed wetland and conventional wastewater treatment plants: a case study in China, Ecol. Eng., 37 (2011) 248–254.
  9. L. Huang, X. Gao, J.S. Guo, X.X. Ma, M. Liu, A review on the mechanism and affecting factors of nitrous oxide emission in constructed wetlands, Environ. Earth Sci., 68 (2013) 2171–2180.
  10. L.A. Schipper, K.R. Reddy, Methane production and emissions from four reclaimed and pristine wetlands of southern United States, Soil Sci. Soc. Am. J., 58 (1998) 1270–1275.
  11. I.C. Change, The Supplementary Report to the IPCC Scientific Assessment, Cambridge University Press, Cambridge, 2001.
  12. Y. Wang, H. Yang, C. Ye, X. Chen, B. Xie, C. Huang, J. Zhang, M. Xu, Effects of plant species on soil microbial processes and CH4 emission from constructed wetlands, Environ. Pollut., 174 (2013) 273–278.
  13. H. Kang, C. Freeman, M.A. Lock, Trace gas emissions from a North Wales fen – role of hydrochemistry and soil enzyme activity, Water Air Soil Pollut., 105 (1998) 107–116.
  14. A.E. Johansson, A.M. Gustavsson, M.G. Oquist, B.H. Svensson, Methane emissions from a constructed wetland treating wastewater - seasonal and spatial distribution and dependence on edaphic factors, Water Res., 38 (2004) 3960–3970.
  15. A. Liikanen, J.T. Huttunen, S.M. Karjalainen, K. Heikkinen, T.S. Vaisanen, H. Nykanen, P.J. Martikainen, Temporal and seasonal changes in greenhouse gas emissions from a constructed wetland purifying peat mining runoff waters, Ecol. Eng., 26 (2006) 241–251.
  16. R. Inamori, P. Gui, P. Dass, M. Matsumura, K.Q. Xu, T. Kondo, Y. Ebie, Y. Inamori, Investigating CH4 and N2O emissions from eco-engineering wastewater treatment processes using constructed wetland microcosms, Process Biochem., 42 (2007) 363–373.
  17. Y.H. Wang, R.H. Inamori, H.N. Kong, K.Q. Xu, Y.H. Inamori, T.S. Kondo, J.X. Zhang, Nitrous oxide emission from polyculture constructed wetlands: effect of plant species, Environ. Pollut., 152 (2008) 351–360.
  18. Y.H. Wang, R. Inamori, H.N. Kong, K.Q. Xu, Y. Inamori, T. Kondo, J.X. Zhang, Influence of plant species and wastewater strength on constructed wetland methane emissions and associated microbial populations, Ecol. Eng., 32 (2008) 22–29.
  19. Y. Song, S.P. Deng, V. Acosta-Martinez, E. Katsalirou, Characterization of redox-related soil microbial communities along a river floodplain continuum by fatty acid methyl ester (FAME) and 16S rRNA genes, Appl. Soil Ecol., 40 (2008) 499–509.
  20. C. Yan, H. Zhang, B. Li, D. Wang, Y. Zhao, Z. Zheng, Effects of influent C/N ratios on CO2 and CH4 emissions from vertical subsurface flow constructed wetlands treating synthetic municipal wastewater, J. Hazard. Mater., 203–204 (2012) 188–194.
  21. Y.H. Liu, L.X. Wang, S.M. Bao, H.M. Liu, J.B. Yu, Y. Wang, H.B. Shao, O.Y. Yan, S.Q. An, Effects of different vegetation zones on CH4 and N2O emissions in coastal wetlands: a model case study, Scientific World J., l (2014).
  22. Z.H. Dai, C.C. Trettin, C.S. Li, H. Li, G. Sun, D.M. Amatya, Effect of assessment scale on spatial and temporal variations in CH4, CO2, and N2O fluxes in a forested wetland, Water Air Soil Pollut., 223 (2012) 253–265.
  23. T. Tuttolomondo, C. Leto, S. La Bella, R. Leone, G. Virga, M. Licata, Water balance and pollutant removal efficiency when considering evapotranspiration in a pilot-scale horizontal subsurface flow constructed wetland in Western Sicily (Italy), Ecol. Eng., 87 (2016) 295–304.
  24. C. Leto, T. Tuttolomondo, S. La Bella, R. Leone, M. Licata, Growth of Arundo donax L. and Cyperus alternifolius L. in a horizontal subsurface flow constructed wetland using pretreated urban wastewater-a case study in Sicily (Italy), Desal. Wat. Treat., 51 (2013) 7447–7459.
  25. W. Huang, L. Zhang, J. Gao, J. Li, J. Zhang, Z. Zheng, Removal of dissolved inorganic phosphorus with modified gravel sand: kinetics, equilibrium, and thermodynamic studies, Desal. Wat. Treat., 57 (2016) 3074–3084.
  26. APHA-AWWA-WPCF, Standard Methods for the Examination of Water and Wastewater, 19th ed, American Public Health Association, Washington, D.C., 1995.
  27. C. Chiemchaisri, W. Chiemchaisri, J. Junsod, S. Threedeach, P.N. Wicranarachchi, Leachate treatment and greenhouse gas emission in subsurface horizontal flow constructed wetland, Bioresource Technol., 100 (2009) 3808–3814.
  28. J. Zhai, H. Rahaman, J.C. Ji, Z.Y. Luo, Q.F. Wang, H.W. Xiao, K.P. Wang, Plant uptake of diclofenac in a mesocosm-scale freewater surface constructed wetland by Cyperus alternifolius, Water Sci. Technol., 73 (2016) 3008–3016.
  29. C. Li, S. Wu, R. Dong, Dynamics of organic matter, nitrogen and phosphorus removal and their interactions in a tidal operated constructed wetland, J. Environ. Manage., 151 (2015) 310–316.
  30. X. Wang, Y. Tian, X. Zhao, S. Peng, Q. Wu, L. Yan, Effects of aeration position on organics, nitrogen and phosphorus removal in combined oxidation pond-constructed wetland systems, Bioresour Technol., 198 (2015) 7–15.
  31. J.L. Fan, B. Zhang, J. Zhang, H.H. Ngo, W.S. Guo, F.F. Liu, Y.Y. Guo, H.M. Wu, Intermittent aeration strategy to enhance organics and nitrogen removal in subsurface flow constructed wetlands, Bioresource Technol., 141 (2013) 117–122.
  32. C. Ouellet-Plamondon, F. Chazarenc, Y. Comeau, J. Brisson, Artificial aeration to increase pollutant removal efficiency of constructed wetlands in cold climate, Ecol. Eng., 27 (2006) 258–264.
  33. Y.J. Zhao, B. Liu, W.G. Zhang, W.J. Kong, C.W. Hu, S.Q. An, Comparison of the treatment performances of high-strength wastewater in vertical subsurface flow constructed wetlands planted with Acorus calamus and Lythrum salicaria, J. Heal. Sci., 55 (2009) 757–766.
  34. A. Pai, B.C. McCarthy, Suitability of the medicinal plant, Acorus calamus L., for wetland restoration, Nat. Area. J., 30 (2010) 380–386.
  35. Z.L. Liu, X.Y. Fu, W. Chen, S. Yu, X.Y. He, Nitrogen and phosphorus removal by five ornamental and wetland plants from upstream of Hunhe River, China, Fresen. Environ. Bull., 25 (2016) 1477–1483.
  36. Y.P. Chen, K. Park, S. Niu, Y. Kim, Performance of a halfsaturated vertical flow wetland packed with volcanic gravel in stormwater treatment, Water Sci. Technol., 69 (2014) 2331–2338.