Abstract
A nitrate-dominant synthetic wastewater simulating slightly polluted water with low C/N and poor biochemical availability was treated in lab-scale vertical-flow (VF)-constructed wetlands, which had Phragmites australis planted with different types of external carbon sources: Platanus acerifolia leaf litters, P. australis litters, glucose and a blank test with no external carbon sources. A comparison of the TN removal and N2O flux performances among the four wetland reactors indicated higher TN removal efficiencies and N2O release fluxes in the VF wetland columns with external carbon sources, as measured by the percentage removal of TN (P. acerifolia leaf litters 82.49 %, P. australis litters 70.55 %, glucose 62.50 % and blank 46.45 %) and N2O flux (P. acerifolia leaf litters 2275.22 μg · m−2 · h−1, P. australis litters 1920.53 μg · m−2 · h−1, glucose 1598.57 μg · m−2 · h−1 and blank 1192.08 μg · m−2 · h−1). This was primarily because of an improved supply of organic carbon from the external carbon sources for heterotrophic denitrification. And, the nitrogen released from the decomposition of plant materials resulted in the N2O release fluxes to some extent. However, employing P. acerifolia leaf litters and P. australis litters as external carbon sources caused net increases in organics of the final effluent water. Overall, the results not only demonstrated the potential of using external plant carbon sources in VF wetlands to enhance the TN removal efficiency but also showed a risk of excessive organic release and greater N2O flux feedback to global warming. Hence, future studies are needed to optimise the quantity and method for adding external carbon sources to VF-constructed wetlands so that sufficient nitrate removal efficiency is achieved and the N2O flux and organic pollution are minimised.
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References
Adouani, N., Lendormi, T., Limousy, L., & Sire, O. (2010). Effect of the carbon source on N2O emissions during biological denitrification. Resources, Conservation and Recycling, 54(5), 299–302.
American Public Health Association. APHA. (1998). Standard methods for the examination of water and wastewater, 20.
Azam, F. (2002). Studies on organic matter dynamics and nitrogen availability using 14C and 15 N. Journal of Agronomy, 1(1), 20–24.
Bastviken, S. K., Eriksson, P. G., Ekström, A., & Tonderski, K. (2007). Seasonal denitrification potential in wetland sediments with organic matter from different plant species. Water, Air, and Soil Pollution, 183(1–4), 25–35.
Chen, Y., Wen, Y., Cheng, J., Xue, C., Yang, D., & Zhou, Q. (2011). Effects of dissolved oxygen on extracellular enzymes activities and transformation of carbon sources from plant biomass: implications for denitrification in constructed wetlands. Bioresource Technology, 102(3), 2433–2440.
Cole, J. J., & Caraco, N. F. (2001). Emissions of nitrous oxide (N2O) from a tidal, freshwater river, the Hudson River, New York. Environmental Science & Technology, 35(6), 991–996.
García-Lledó, A., Vilar-Sanz, A., Trias, R., Hallin, S., & Bañeras, L. (2011). Genetic potential for N2O emissions from the sediment of a free water surface constructed wetland. Water Research, 45(17), 5621–5632.
Hu, R. G., Lin, S., & Feng, M. L. (2009). Effect of soil available organic carbon and nitrogen on N2O fluxes. In Sustainable use of soil resources and ecological environment security conference proceedings (pp. 380–386). Guangzhou: Soil Science Society of China.
Hume, N. P., Fleming, M. S., & Horne, A. J. (2002a). Plant carbohydrate limitation on nitrate reduction in wetland microcosms. Water Research, 36(3), 577–584.
Hume, N. P., Fleming, M. S., & Horne, A. J. (2002b). Denitrification potential and carbon quality of four aquatic plants in wetland microcosms. Soil Science Society of America Journal, 66(5), 1706–1712.
Huttunen, J. T., Alm, J., Liikanen, A., Juutinen, S., Larmola, T., Hammar, T., Silvola, J., & Martikainen, P. J. (2003). Fluxes of methane, carbon dioxide and nitrous oxide in boreal lakes and potential anthropogenic effects on the aquatic greenhouse gas emissions. Chemosphere, 52(3), 609–621.
IPCC. (2001). Atmospheric chemistry and greenhouse gases. In J. T. Houghton, Y. Ding, D. J. Griggs, M. Noguer, P. J. van der Linden, X. Dai, K. Maskell, & C. A. Johnson (Eds.), Climate change 2001: the scientific basis. A report of working group II (pp. 239–287). Cambridge: Cambridge University Press.
Liang, D. L., Tong, Y. A., Emteryd, O., & Zhang, S. L. (2002). Effect of irrigation and rainfall on the N2O losses in dryland. Plant Nutrition and Fertilizer Science, 8(3), 298–302.
Lin, Y. F., Jing, S. R., Wang, T. W., & Lee, D. Y. (2002). Effects of macrophytes and external carbon sources on nitrate removal from groundwater in constructed wetlands. Environmental Pollution, 119(3), 413–420.
Liu, G., Wen, Y., & Zhou, Q. (2010). Advance in enhancement of denitrification in the constructed wetlands using external carbon sources. Technology of Water Treatment, 36(4), 1–5.
Lu, L. M., Zhang, L., Qu, F. L., Lu, H. X., Zhang, X. B., Wu, Z. S., Huan, S. Y., Wang, Q. A., Shen, G. L., & Yu, R. Q. (2009). A nano-Ni based ultrasensitive nonenzymatic electrochemical sensor for glucose: enhancing sensitivity through a nanowire array strategy. Biosensors and Bioelectronics, 25(1), 218–223.
Ma, W. K., Bedard-Haughn, A., Siciliano, S. D., & Farrell, R. E. (2008). Relationship between nitrifier and denitrifier community composition and abundance in predicting nitrous oxide emissions from ephemeral wetland soils. Soil Biology and Biochemistry, 40(5), 1114–1123.
Maltais-Landry, G., Maranger, R., Brisson, J., & Chazarenc, F. (2009a). Greenhouse gas production and efficiency of planted and artificially aerated constructed wetlands. Environmental Pollution, 157(3), 748–754.
Maltais-Landry, G., Maranger, R., Brisson, J., & Chazarenc, F. (2009b). Nitrogen transformations and retention in planted and artificially aerated constructed wetlands. Water Research, 43(2), 535–545.
Mørkved, P., Søvik, A., Klve, B., & Bakken, L. (2005). Removal of nitrogen in different wetland filter materials: use of stable nitrogen isotopes to determine factors controlling denitrification and DNRA. Water Science and Technology, 51(9), 63–71.
Müller, C., Stevens, R. J., Laughlin, R. J., & Jäger, H. J. (2004). Microbial processes and the site of N2O production in a temperate grassland soil. Soil Biology and Biochemistry, 36(3), 453–461.
Regina, K., Nykänen, H., Silvola, J., & Martikainen, P. J. (1996). Fluxes of nitrous oxide from boreal peatlands as affected by peatland type, water table level and nitrification capacity. Biogeochemistry, 35(3), 401–418.
Rustige, H., & Nolde, E. (2007). Nitrogen elimination from landfill leachates using an extra carbon source in subsurface flow constructed wetlands. Water Science and Technology, 56(3), 125–133.
Saeed, T., & Sun, G. (2012). A review on nitrogen and organics removal mechanisms in subsurface flow constructed wetlands: Dependency on environmental parameters, operating conditions and supporting media. Journal of Environmental Management, 112, 429–448.
Shao, L., Xu, Z. X., & Yin, H. L. (2007). Advances in the polluted water denitrification by using additional carbon sources. Industrial Water Treatment, 27(12), 10–14.
Shao, L.,Xu, Z. X., Wang, S., Jin, W., & Yin, H. L. (2011). Performance of new solid carbon source materials for denitrification. Environmental Sciences, 32(8), 2323–2327.
She, L. H., He, F., Xu, D., Lin, J. D., & Wu, Z. B. (2009). Nitrogen removal under the condition of carbon source supplement in integrated vertical-flow constructed wetland. Environmental Sciences, 30(11), 3300–3305.
Stadmark, J., Seifert, A. G., & Leonardson, L. (2009). Transforming meadows into free surface water wetlands: Impact of increased nitrate and carbon loading on greenhouse gas production. Atmospheric Environment, 43(6), 1182–1188.
Ståhl, M. (2000). The influence of organic carbon on nitrogen transformations in five wetland soils. Soil Science Society of America Journal, 64(3), 1129–1136.
US EPA. (2000). Manual: constructed wetlands treatment of municipal wastewater, Cincinnati, Ohio. EPA/625/R-99/010.
Vymazal, J. (2005). Horizontal sub-surface flow and hybrid constructed wetlands systems for wastewater treatment. Ecological Engineering, 25(5), 478–490.
Vymazal, J., & Kröpfelová, L. (2009). Removal of organics in constructed wetlands with horizontal sub-surface flow: a review of the field experience. Science of the Total Environment, 407(13), 3911–3922.
Wan, X. H., Kuang, S. F., Zhou, H. D., & Wang, Y. C. (2009). Research of exogenous nitrogen input on N2O fluxes in constructed wetland. Journal of China Institute of Water Resources and Hydropower Research, 7(004), 264–269.
Wang, Q. J., Li, S. X., Jing, Z. C., & Wang, W. Y. (2008). Response of carbon and nitrogen content in plants and soils to vegetation cover change in alpine Kobresia meadow of the source region of Lantsang, Yellow and Yangtze Rivers. Acta Ecologica Sinica, 28(3), 885–894.
Warneke, S., Schipper, L. A., Matiasek, M. G., Scow, K. M., Cameron, S., Bruesewitz, D. A., & McDonald, I. R. (2011). Nitrate removal, communities of denitrifiers and adverse effects in different carbon substrates for use in denitrification beds. Water Research, 45(17), 5463–5475.
Wen, Y., Chen, Y., Zheng, N., Yang, D., & Zhou, Q. (2010). Effects of plant biomass on nitrate removal and transformation of carbon sources in subsurface-flow constructed wetlands. Bioresource Technology, 101(19), 7286–7292.
Wu, J., Zhang, J., Jia, W., Xie, H., Gu, R. R., Li, C., & Gao, B. (2009a). Impact of COD/N ratio on nitrous oxide emission from microcosm wetlands and their performance in removing nitrogen from wastewater. Bioresource Technology, 100(12), 2910–2917.
Wu, J., Zhang, J., Jia, W., Xie, H., & Zhang, B. (2009b). Relationships of nitrous oxide fluxes with water quality parameters in free water surface constructed wetlands. Frontiers of Environmental Science & Engineering in China, 3(2), 241–247.
Xiong, F., Li, W. C., Pan, J. Z., Li, A. Q., & Xia, T. X. (2005). Efficiency and functioning of nitrogen and phosphorus removal in constructed wetlands: a review. Wetland Science, 3(3), 228–234.
Xiong, J. F., Xu, H., Yan, N., & Zhang, Y. M. (2012). Leaves of Platanus Orientals as the carbon source for denitrification. Environmental Sciences, 33(011), 4057–4061.
Yang, D., & Zhou, Q. (2003). Mechanism and application of nitrogen removal by constructed wetlands. China Water & Wastewater, 19(1), 23–24.
Zhang, D. Y., Li, G. H., Wang, Y., Zhou, G. Z., & Zhang, W. J. (2009). Slow-release organic carbon-source materials for groundwater in situ denitrification. Journal of Tsinghua University (Science and Technology), 49(9), 75–79.
Zhao, L. F., Zhu, W., & Gao, Q. (2009). Improving nitrogen removal of constructed wetlands by supplying plant carbon. Journal of PLA University of Science and Technology (Natural Science Edition), 10(6), 644–649.
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The authors acknowledge financial support for this work from the National Natural Science Funds (51209070) and the Natural Science Fund Project in Jiangsu Province (BK20130834).
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Zhang, M., Zhao, L., Mei, C. et al. Effects of Plant Material as Carbon Sources on TN Removal Efficiency and N2O Flux in Vertical-Flow-Constructed Wetlands. Water Air Soil Pollut 225, 2181 (2014). https://doi.org/10.1007/s11270-014-2181-9
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DOI: https://doi.org/10.1007/s11270-014-2181-9