Influence of Deep-Treated Wastewater Discharge on Nitrification Activity in a Natural Reservoirs

Iurchenko, Valentyna; Radionov, Mykyta; Ivanin, Pavlo; Melnikova, Oksana

doi:10.12911/22998993/126984

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Tytuł artykułu

Influence of Deep-Treated Wastewater Discharge on Nitrification Activity in a Natural Reservoirs

Autorzy

Iurchenko Valentyna , Radionov Mykyta , Ivanin Pavlo , Melnikova Oksana

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DOI

10.12911/22998993/126984

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Abstrakty

The data from regular monitoring of the concentration of nitrogen-containing compounds and nitrification indicators in the Udy river (at sites 500 m before the discharge of treated wastewater in Kharkiv city and 500 m after discharge downstream) and in the wastewater being treated at urban wastewater treatment facilities were analyzed. Chemical and biological kinetic constants of nitrification in the water layer and biochemical characteristics of nitrification in the bottom deposits in these areas were determined in special laboratory experiments. It was stated that the rate of nitrification in the water layer increases twice in the area after the discharge of treated wastewater compared to the area before discharge. Biochemical and microbiological indicators of nitrification in the active sludge of wastewater treatment facilities were established. It was shown that the discharge of wastewater (and hence nitrifying bacteria) from wastewater treatment facilities that perform biological treatment with nitrification (without denitrification) increases the activity of nitrification processes in the water layer of a natural reservoir downstream.

Słowa kluczowe

nitrification natural reservoir discharge of treated wastewater chemical kinetic constant biokinetic constant concentration of nitrifying bacteria bottom deposit active sludge

Wydawca

Polskie Towarzystwo Inżynierii Ekologicznej
Lublin University of Technology

Czasopismo

Journal of Ecological Engineering

Rocznik

2020

Tom

Vol. 21, nr 8

Strony

146--155

Opis fizyczny

Bibliogr. 24 poz., rys., tab.

Twórcy

autor

Iurchenko Valentyna

Faculty of Sanitary Engineering, Kharkiv National University of Civil Engineering and Architecture, Sumska Str. 40, Kharkiv, Ukraine

autor

Radionov Mykyta

radionov.nikita@ukr.net

Ukrainian Research Institute of Environmental Problems, Bakulina Str. 6, Kharkiv, Ukraine

autor

Ivanin Pavlo

Faculty of Sanitary Engineering, Kharkiv National University of Civil Engineering and Architecture, Sumska Str. 40, Kharkiv, Ukraine

autor

Melnikova Oksana

Faculty of Sanitary Engineering, Kharkiv National University of Civil Engineering and Architecture, Sumska Str. 40, Kharkiv, Ukraine

Bibliografia

1. Beliakov A.V. 2014. Study of the biological wastewater treatment of an oil refinery with nitri-denitrification. diss…PhD (tech.). Samara. (in Russian).
2. Carini S. A &Joye S.B. (2008). Nitrification in Mono Lake, California: Activity and community composition during contrasting hydrological regimes, Limnol. Oceanogr., 53(6), 2546–2557.
3. Gnida A., Wiszniowski J., Felis E., Sikora J., Surmacz-GórskaJ., Miksch K. 2016. The effect of temperature on the efficiency of industrial wastewater nitrification and its (geno) toxicity.Archives of Environmental Protection, 42 (1), 27–34. DOI 10.1515/aep-2016–0003.
4. Iurchenko V.О. 2007. The development of scientific and technological foundations for the operation of sewage systems in the conditions of biochemical oxidation of inorganic compounds. diss ... Doctors of tech. Sciences. Kharkiv. (in Russian).
5. Haandel van A.C., Lubbe van der J.G.M. 2012. Design and Optimisation of Activated Sludge Systems, in Handbook of Biological Wastewater Treatment, IWA Publishing, London.
6. How S.W., Lim S.Y., Lim P.B., ArisA.M., NgohG.C., Curtis T.P., Chua A.S.M. 2018. Low-dissolved-oxygen nitrification in tropical sewage: an investigation on potential, performance and functional microbial community. Water SciTechnol, 77 (9), 2274–2283. https://doi.org/10.2166/wst.2018.143.
7. Lancaster K.M., Caranto J.D., Majer S.H. & Smith M.A. 2018. Alternative Bioenergy: Updates to and Challenges in Nitrification Metalloenzymology. Joule, 2, 421–441. DOI:10.1016/j.joule.2018.01.018.
8. List of methods for performing measurements (determinations) of the composition and properties of samples of environmental objects, emissions, wastes and discharges provisionally allowed for use by the State Inspectorate of Ukraine, approved by the Head of the State Environmental Inspectorate of Ukraine – Chief State Inspector of Ukraine for Environmental Protection on 01.03.2013. (in Ukraine).
9. Malyovanyy М. Sakalova G., Chornomaz N., Nahurskyy O. 2013. Waters option purification from ammonium pollution. Chemistry&Chemical Technology, 7(3), 355–358. https://doi.org/10.23939/chcht07.03.355
10. Malovanyy M., Zhuk V., Sliusar V., Sereda A. 2018. Two stage treatment of solid waste leachates in aerated lagoons and at municipal wastewater treatment plants. Eastern-European Journal of Enterprise Technologies, 1 (10), 23 – 30. doi.org/10.15587/1729–4061.2018.122425
11. Nezdoyminov V. I. 2013. Kinetic models of single-core biological systems with carbon oxidation, nitrification and denitrification. Engineering systems and technogenic safety, 5(103), 150–153. (in Russian).
12. Nozhevnikova A. N., Litti YU. V., Zubov G. M., Zubov M. G. 2017. Anammox bacteria in nature and ecobiotechnology. University Book, Moscow.
13. Raimonet M., Vilmin L., Flipo N., Rocher V., Laverman A.M. 2015. Modelling the fate of nitrite in an urbanized river using experimentally obtained nitrifier growth parameters. Water Research, 73, 373–387.
14. Ryzhakov A.V. 2012. Kinetic characteristics of the transformation of nitrogen-containing compounds in natural water. Ecological chemistry, 21 (2), 117–124 (in Russian).
15. Semenova E., Shaginurova G., Kirilina T., Sirotkin A. 2012. Biotransformation of nitrogen compounds in wastewater treatment technologies. Water: chemistry and ecology, 1, 26–32.
16. Shiozaki T.,Ijichi M., Isobe K., Hashihama F., Nakamura K., Ehama M., Hayashizaki K., Takahashi K, Hamasaki K. & Furuya K. 2016. Nitrification and its influence on biogeochemical cycles from the equatorial Pacific to the Arctic Ocean. The ISME Journal, 10, 2184–2197. Accessmodehttps://www.nature.com/articles/ismej201618.
17. Shmandiy V. et. al. 2017. Methods of salt content stabilization in circulating water supply systems Chemistry & Chemical Technology, 11 (2), 242–246. https://doi.org/10.23939/chcht11.02.242
18. Tulaydan Y., Malovanyy M., Kochubei V., Sakalova H. 2017. Treatment of high-strength wastewater from ammonium and phosphate ions with the obtaining of struvite. Chemistry&Chemical Technology. 11(4), 463–468. doi.org/10.23939/chcht11.04.463
19. Stahl D.A.,& de la Torre J.R. 2012. Physiology and diversity of ammonia oxidizing archaea. Annu. Rev. Microbiol, 66, 83–101.
20. Veuger B., Pitcher A., Schouten S., Sinninghe Damste´ J. S. and Middelburg J. J. 2013. Nitrification and growth of autotrophic nitrifying bacteria and Thaumarchaeota in the coastal North Sea. Biogeosciences, 10, 1775–1785, www.Biogeosciences.net/10/1775/2013/doi:10.5194/bg-10–1775–2013.
21. Vinnov A.S., Dolganova N.V. 2013. Kinetic analysis of the enzymatic hydrolysis of fish muscle tissue protein. Bulletin ASTU. Series: WaterManagement, 3, 153–161. (in Russian).
22. Vinogradova A.V., Kozlova G.A. 2012. Microorganism cultivation. Perm. nat. researched Polytechnic university, Permian. (in Russian).
23. Ward B.B., Arp D.J., Klotz M.G. 2011. Nitrification. American Society for Microbiology. DC, USA, Washington.
24. Zlyvko A.S., Chersnokova S.M., Trifonova, T.A. 2014. Assessment of the maximum permissible impact on on self-cleaning processes in the ecosystem of a small watercourse. Bulletin of the Samara Scientific Center of the Russian Academy of Sciences, 16, 1(4), 967–971 (in Russian).

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Bibliografia

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