APPROXIMATE CALCULATION OF N2O FORMATION IN HETEROTROPHIC DENITRIFICATION PROCESSES OF WASTEWATER DURING BIOLOGICAL TREATMENT

PDF(UKRAINIAN)

 

Iurchenko Valentyna

O. M. Beketov National University of Urban EconomyKharkiv, Ukraine

https://orcid.org/0000-0001-7123-710X

 

Avdiienko Iryna

O. M. Beketov National University of Urban EconomyKharkiv, Ukraine

https://orcid.org/0009-0008-4140-1923

 

DOI: 10.52363/2522-1892.2024.2.5

 

Key words: greenhouse gases, biological wastewater treatment, nitrification, denitrification, nitrous oxide emissions, N2O emission factor, nitrogen balance

 

Abstract

This article addresses the important ecological issue of quantitatively determining greenhouse gas emissions – nitrous oxide – from municipal wastewater treatment facilities, which is a factor in global climate change. Data from scientific research indicate that deep biological treatment of nitrogen compounds at wastewater treatment facilities significantly contributes to the gross emissions of nitrous oxide from industrial facilities. Direct measurements of nitrous oxide emissions from biological treatment facilities in Ukraine have not been conducted. The aim of this study is to assess the potential emissions of the greenhouse gas N2O during the biological treatment of municipal wastewater in aeration tanks operating under the traditional, non-zoned scheme in Ukraine, which ensures deep nitrification. The study was conducted at municipal wastewater treatment facilities equipped with 3-channel aeration tanks. The process of wastewater treatment in aeration tanks operating under the traditional non-zoned scheme is fully aerobic and characterized by deep nitrification. Measurements of hydrochemical indicators of wastewater composition (BOD5, N–NH4, N–NO2, and N–NO3, Kjeldahl nitrogen) were carried out using certified methods in an accredited laboratory. It was found that biological treatment of municipal wastewater exclusively under aerobic conditions does not effectively remove nitrates from the wastewater. The nitrogen balance in incoming and treated wastewater was calculated, and the formation of N2O in the processes of suppressed denitrification was quantitatively determined. The consumption of nitrogen for the formation of excess activated sludge biomass, the efficiency of nitrification to nitrates, and the probable formation of N2O as a result of inhibition of the final heterotrophic denitrification reaction (reduction of N2O to N2) were calculated. The results showed that the maximum value of the N2O emission coefficient (the ratio of formed N2O to the concentration of total nitrogen entering the treatment process) at the studied facility could range from 3.24 % to 6.47 %, which is consistent with direct measurement data conducted at operating treatment facilities by foreign scientists. The study results confirm that modern technologies for deep biological wastewater treatment should consider not only effective removal of biogenic elements but also the minimization of greenhouse gas emissions.

 

References

  1. Paris Agreement of April 22, 2015 [Paryzka uhoda vid 22.04.2015 roku]. (2015). URL: from https://zakon.rada.gov.ua/laws/show/995_l61#Text. [in Ukrainian]

  2. Pro skhvalennia Onovlenoho natsionalno vyznachenoho vnesku Ukrainy do Paryzkoi uhody [On the approval of Ukraine's updated nationally determined contribution to the Paris Agreement], 868-r Decree of the Cabinet of Ministers of Ukraine (2021). URL:  https://zakon.rada.gov.ua/laws/show/868-2021-р#Text. [in Ukrainian]

  3. Ministry of Environmental Protection and Natural Resources of Ukraine. (2023). Ukraine’s greenhouse gas inventory 1990-2021. URL: https://mepr.gov.ua/wp-content/uploads/2023/03/Kadastr_2023.pdf. [in Ukrainian]

  4. Intergovernmental Panel on Climate Change (IPCC). (2021). IPCC sixth assessment report. Chapter 5: Global carbon and other biogeochemical cycles and feedbacks. URL: https://www.ipcc.ch/report/ar6/wg1/chapter/chapter-5/.

  5. Dentener, F., Derwent, R., Dlugokencky, E., Holland, E., Isaksen, I., Katima, J., Kirchhoff, V., Matson, P., Midgley, P., & Wang, M. (2001). Atmospheric chemistry and greenhouse gases. URL: https://www.ipcc.ch/site/assets/uploads/2018/03/TAR-04.pdf.

  6. Gruber, W. (2021). Long-term N2O emission monitoring in biological wastewater treatment: Methods, applications, and relevance. ETH Zurich.

  7. Hanaki, K., Hong, Z., & Matsuo, T. (1992). Production of nitrous oxide gas during denitrification of wastewater. Water Science and Technology, 26(5-6), 1027-1036.

  8. Daelman, M. R., van Voorthuizen, E. M., van Dongen, U. G., Volcke, E. I., & van Loosdrecht, M. C. (2015). Seasonal and diurnal variability of N2O emissions from a full-scale municipal wastewater treatment plant. Science of The Total Environment, 536, 1-11.

  9. Kosonen, H., Heinonen, M., Mikola, A., Haimi, H., Mulas, M., Corona, F., & Vahala, R. (2016). Nitrous oxide production at a fully covered wastewater treatment plant: Results of a long-term online monitoring campaign. Environmental Science & Technology, 50(11), 5547-5554.

  10. European Environment Agency. (2017). Greenhouse gas emissions from waste management. URL. https://www.eea.europa.eu/publications/annual-european-union-greenhouse-gas-inventory-2017.

  11. Ahn, H. J., Kim, S., Park, H. C., Katehis, D., & Pagilla, K. (2010). Spatial and temporal variability in atmospheric nitrous oxide generation and emission from full-scale biological nitrogen removal and non-BNR processes. Water Environment Research.

  12. Kemmou, L., & Amanatidou, E. (2023). Factors affecting nitrous oxide emissions from activated sludge wastewater treatment plants—A review. Resources, 12, 114.  DOI: 10.3390/resources12100114.

  13. Aboobakar, A., Cartmell, E., Stephenson, T., Jones, M., Vale, P., & Dotro, G. (2013). Nitrous oxide emissions and dissolved oxygen profiling in a full-scale nitrifying activated sludge treatment plant. Water Research, 47(2), 524-534.

  14. GND 211.1.4.024-95. Metodyka vyznachennia biokhimichnoho spozhyvannia kysniu pislia n dniv (BSK) v pryrodnykh i stichnykh vodakh [Method for determining biochemical oxygen demand after n days (BOD) in natural and wastewater]. (1995). [in Ukrainian]

  15. GND 211.1.4.030-95. Metodyka fotometrychnoho vyznachennia amonii ioniv z reaktyvom Neslera v stichnykh vodakh [Method for photometric determination of ammonium ions using Nessler's reagent in wastewater]. (1995). [in Ukrainian]

  16. GND 211.1.4.023-95. Metodyka fotometrychnoho vyznachennia nitryt-ioniv z reaktyvom Hrisa v poverkhnevykh ta ochyshchenykh stichnykh vodakh [Method for photometric determination of nitrite ions using Griess reagent in surface and treated wastewater]. (1995). [in Ukrainian]

  17. GND 211.1.4.027-95. Metodyka fotometrychnoho vyznachennia nitrativ z salitsylovoiu kyslotoiu u poverkhnevykh ta biolohichno ochyshchenykh vodakh [Method for photometric determination of nitrates with salicylic acid in surface and biologically treated water]. [in Ukrainian]

  18. DSTU ISO 8968-1:2005 (IDF 20-1:2001). Metod Kieldalia [Kjeldahl Method]. (2005). [in Ukrainian]

  19. Bonin, P., Gilewicz, M., & Bertrand, J. C. (1989). Effects of oxygen on each step of denitrification on Pseudomonas nautica. Canadian Journal of Microbiology, 35, 24452451. DOI: 10.1139/m89-177.

  20. Henze, M., Harremoës, P., Jansen, J. L. C., & Arvin, E. (2002). Wastewater treatment: Biological and chemical processes. Berlin; New York: Springer. URL: https://searchworks.stanford.edu/view/4735121.

  21. Yurchenko, V. O. (2007). Rozvytok naukovo-tekhnolohichnykh osnov funktsionuvannia sporud kanalizatsii v umovakh biokhimichnoho okyslennia neorhanichnykh spoluk [Development of scientific and technological foundations for the operation of sewerage facilities under conditions of biochemical oxidation of inorganic compounds] (Doctoral thesis in Technical Sciences: 05.23.04). Kharkiv. [in Ukrainian]

  22. DBN V.2.5-75:2013. Kanalizatsiia. Zovnishni merezhi ta sporudy. Osnovni polozhennia proektuvannia [Sewerage. External networks and facilities. Basic design guidelines]. (2013). [in Ukrainian]

  23. Davies, K. J. P., Lloyd, D., & Boddy, L. (1989). The effect of oxygen on denitrification in Paracoccus denitrificans and Pseudomonas aeruginosaJournal of General Microbiology, 135, 24452451.