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2024 | OriginalPaper | Chapter

Enhanced Removal of Nitrogen and Organic Matter from Wastewater in Constructed Wetland Technology by Artificial Aeration

Authors : A. K. Ragen, D. Surroop, P. D. Jeetah

Published in: Emerging Technologies in Biological and Hybrid Wastewater Treatment: Lessons from Developed to Enhancing Practices in Developing Countries

Publisher: Springer Nature Switzerland

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Abstract

The main aim of this study was to investigate the enhanced performance of a horizontal subsurface flow constructed wetland (HSSFCW) in terms of nitrogen and organics removal through a proper spatial distribution of aeration to ensure simultaneous aerobic and anaerobic conditions. Two HSSFCWs, one aerated in its front section only and the other one non-aerated (as control), were operated in parallel at a hydraulic retention time (HRT) of 24 h, a hydraulic rate (HLR) of 0.16 m day and a water depth of 0.4 m. Three distinct types of synthetic effluents were prepared and fed in the systems to simulate a wide range of wastewaters. The rate of aeration provided in the aerated (or intensified) bed was also varied to assess its impact on the intensified removal of ammonium-N (NH₄-N) and chemical oxygen demand (COD).The enhanced performance of the aerated bed, when compared to the non-aerated one, in terms of COD, NH₄-N and total nitrogen (TN) removal efficiency were found to be 26.0 ± 14.7% (N = 68), 61.6 ± 11.7% (N = 60) and 18.2 ± 5.5% (N = 60), respectively. Aeration did impact significantly (p < 0.05) and positively on the aerated bed performance in terms of COD and NH₄-N removal efficiency. The rate constant of COD and NH₄-N degradation in the aerated bed were 3 times and 10 times higher than in control bed, indicating that aeration indeed enhanced the performance of HSSFCW. This study shows that without aeration, such a natural treatment system may not be capable of effectively treating medium to high strength wastewater. This aeration strategy had overcome its oxygen transfer limitation and will constitute a sustainable solution to treat different kind of wastewater with high organic and nitrogen concentration.

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Akratos CS, Tsihrintzis VA (2007) Effect of temperature, HRT, vegetation and porous media on removal efficiency of pilotscale horizontal subsurface flow constructed wetlands. J Ecol Eng 29(2):173–191CrossRef

Butterworth E, Dotro G, Jones M, Richards A, Onunkwo P, Narroway Y, Jefferson B (2013) Effect of artificial aeration on tertiary nitrification in a full scale subsurface horizontal flow constructed wetland. Ecol Eng 54:236–244CrossRef

Chen Y, Wen Y, Zhou Q, Vymazal J (2014) Effects of plant biomass on denitrifying genes in subsurface-flow constructed wetlands. Biores Technol 157:341–345CrossRef

Chyan JM, Jhu YX, Chen IM, Shiu RF (2016) Improvement of nitrogen removal by external aeration and intermittent circulation in a subsurface flow constructed wetland of landscape garden ponds. Process Saf Environ Prot 104:587–597CrossRef

Dong H, Qiang Z, Li T, Jin H, Chen W (2012) Effect of artificial aeration on the performance of vertical-flow constructed wetland treating heavily polluted riverwater. J Environ Sci 24:596–601CrossRef

Fan J, Liang S, Zhang B, Zhang J (2012) Enhanced organics and nitrogen removal in batch-operated vertical flow constructed wetlands by combination of intermittent aeration and step feeding strategy. Environ Sci Pollut Res 1–8

Foladori P, Ortigara ARC, Ruaben J, Andreottola G (2012) Influence of high organic loads during the summer period on the performance of hybrid constructed wetlands (VSSF þ HSSF) treating domestic wastewater in the Alps region. Water Sci Technol 65(5):890–897CrossRef

Fonder N, Xanthoulis D (2007) Removal processes and their distribution inside a subsurface horizontal flow constructed wetland. In: Borin M, Bacelle S (eds) Proceedings of the international conference on multi functions of wetland systems. P.A.N. s.r.l., Padova, Italy, pp 60–71

Hao Z, Ali A, Ren Y, Su J, Zhao W (2022) A mechanistic review on aerobic denitrification for nitrogen removal in water treatment. Sci Total Environ 847:157452. https://doi.org/10.1016/j.scitotenv.2022.157452

10.

Ilyas H, Masih I (2017) The performance of the intensified constructed wetland for organic matter and nitrogen removal: a review. J Environ Manage 198:372–383CrossRef

11.

Li F, Lu L, Zheng X, Zhang X (2014) Three stage horizontal subsurface flow constructed wetlands for organics and nitrogen removal: effect of aeration. Ecol Eng 68:90–96CrossRef

12.

Lin JL, Tu YT, Chiang PC, Chen SH, Kao CM (2015) Using aerated gravel-packed contact bed and constructed wetland system for polluted river water purification: a case study in Taiwan. J Hydrol 525:400–408CrossRef

13.

Lu J, Guo Z, Kang Y, Fan J, Zhang J (2020) Recent advances in the enhanced nitrogen removal by oxygen-increasing technology in constructed wetlands. Ecotoxicol Environ Saf 205:111330. https://doi.org/10.1016/j.ecoenv.2020.111330CrossRef

14.

Ma XY, Du YL, Peng WQ, Zhang SH, Liu XB, Wang SY, Yuan SJ, Kolditz O (2021) Modeling the impacts of plants and internal organic carbon on remediation performance in the integrated vertical flow constructed wetland. Water Res 204:117635. https://doi.org/10.1016/j.watres.2021.117635CrossRef

15.

Masi F, Conte G, Martinuzzi N, Pucci B (2002) Winery high organic content wastewaters treated by constructed wetlands in Mediterranean climate. In: Proceedings of the 8th international conference on wetland systems for water pollution control, University of Dar-es-Salaam, Tanzania and IWA, pp 274–282

16.

Nivala J, Hoos MB, Cross C, Wallace S, Parkin G (2007) Treatment of landfill leachate using an aerated, horizontal subsurface-flow constructed wetland. Sci Total Environ 380(1–3):19–27CrossRef

17.

Ouellet-Plamondon C, Chazarenc F, Comeau Y, Brisson J (2006) Artificial aeration to increase pollutant removal efficiency of constructed wetlands in cold climate. Ecol Eng 27(3):258–264CrossRef

18.

Pascual A, Alvarez JA, de la Varga D, Arias CA, Van Oirschot D, Kilian R, Soto M (2024) Horizontal flow aerated constructed wetlands for municipal wastewater treatment: the influence of bed depth. Sci Total Environ 908. https://doi.org/10.1016/j.scitotenv.2023.168257

19.

Rousseau DP, Vanrolleghem PA, De Pauw N (2004) Model-based design of horizontal subsurface flow constructed treatment wetlands: a review. Water Res 38(6):1484–1493CrossRef

20.

Stefanakis AI, Tsihrintzis V (2009) Effect of outlet water level raising and effluent recirculation on removal efficiency of pilot-scale, horizontal subsurface flow constructed wetlands. Desalination 248:961–976CrossRef

21.

Uggetti E, Garcia J, Lind SE, Martikainen PJ, Ferrer I (2012) Quantification of greenhouse gas emissions from sludge treatment wetlands. Water Res 46(6):1755–1762

22.

Von Sperling V, de Paoli AC (2013) First order COD decay coefficient associated with different hydraulic models applied to planted and unplanted horizontal sub surface constructed wetlands. Ecol Eng 57:205–209CrossRef

23.

Wang W, Song X, Li F, Ji X, Hou M (2020) Intensified nitrogen removal in constructed wetlands by novel spray aeration system and different influent COD/N ratio. Bioresour Technol 306:123008. https://doi.org/10.1016/j.biortech.2020.123008

24.

Wu H, Fa J, Zhang J, Ngo HH, Guo W, Hu Z, Li J (2016) Optimization of organics and nitrogen removal in intermittently aerated vertical flow constructed wetlands: effects of aeration time and aeration rate. Int Biodeterior Biodegrad 113:139–145

25.

Zhang LY, Zhang L, Liu YD, Shen YW, Liu H, Xiong Y (2010) Effect of limited artificial aeration on constructed wetland treatment of domestic wastewater. Desalination 250:915–920CrossRef

26.

Zhang DQ, Jinadasa KBSN, Gersberg RM, Liu Y, Ng WJ, Tan SK (2014) Application of constructed wetlands for wastewater treatment in developing countries—a review of recent developments (2000–2013). J Environ Manage 141:11–131CrossRef

27.

Zapater-Pereyra M, Gashugi E, Rousseau DPL, Alam MR, Bayansa LPNL (2014) Effect of aeration on pollutants removal: biofilm activity and protozoan abundance in conventional and hybrid horizontal subsurface-flow constructed wetlands. Environ Technol 35(16):2086–2094CrossRef

28.

Zheng Y, Zhang N, Zhang R, Li C, Liu Z, Guo Y, Zhang L, Wang Q, Li Y, Salah M, Zheng H, Li F (2024) Improved nitrogen removal by optimizing the distribution of dissolved oxygen in a simulated constructed wetland system with embedding a water-sealed zone for polishing reclaimed water. J Water Process Eng 62:105287. https://doi.org/10.1016/j.jwpe.2024.105287CrossRef

29.

Zhong F, Wu J, Dai Y, Xiang D, Cheng S, Ji H (2015) Performance evaluation of wastewater treatment using horizontal subsurface flow constructed wetlands optimized by micro-aeration and substrate selection. Water Sci Technol 71(9):1317–1324CrossRef

30.

Zhuang L, Yang T, Zhang J, Li X (2019) The configuration, purification effect and mechanism of intensified constructed wetland for wastewater treatment from the aspect of nitrogen removal: a review. Bioresour Technol 293:122086

Title: Enhanced Removal of Nitrogen and Organic Matter from Wastewater in Constructed Wetland Technology by Artificial Aeration
Authors: A. K. Ragen
D. Surroop
P. D. Jeetah
Publisher: Springer Nature Switzerland
Book: Emerging Technologies in Biological and Hybrid Wastewater Treatment: Lessons from Developed to Enhancing Practices in Developing Countries
Print ISBN: 978-3-031-74514-0

Electronic ISBN: 978-3-031-74515-7

Copyright Year: 2024
DOI: https://doi.org/10.1007/978-3-031-74515-7_8