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Warianty tytułu
Języki publikacji
Abstrakty
Thermal power plants (TPP) belong to the enterprises that accompany the development of any city. These industrial facilities consume and discharge large amounts of water. Therefore, thermal power plants are often located near water bodies that need to assess their ecological state and predict the consequences of the anthropogenic impact. The purpose of the work was to assess the ecological state of the floodplain Lake Ivanovskoye (Russia, Kirov region), which receives the wastewater from a thermal power plant, using a triadic approach and comparing the results of chemical analysis, bioassay and bioindication. It was shown that the main pollutant in the lake and the canal connecting Lake Ivanovskoye with the nearest river Vyatka is ammonium ion (up to 3.2 mg/dm3). In addition, the Russian standards for biological oxygen consumption are exceeded (analysis period is 20 days). The tests for the toxicity of wastewater showed inhibition of Paramecium caudatum and Escherichia coli reactions. In contrast, natural surface water from Lake Ivanovskoye stimulated the test functions of Scenedesmus quadricauda, P. caudatum, and E. coli. The death of Daphnia magna in the samples were not recorded. The totality of the facts pointed to the organic nature of pollution, leading to the anthropogenic eutrophication of the lake. The hypothesis was tested by using the bioindication method and by analyzing the totality of species of coastal aquatic plants. It was shown that the reservoir belongs to the mesotrophic type with a moderate degree of pollution, which decreases with distance from the wastewater discharge points. The increase in the trophicity of the reservoir is facilitated by thermal pollution (up to +15℃) and an alkaline pH of wastewater (up to 9.2). Thus, the joint analysis of the results of chemical analysis, bioassay and bioindication made it possible to carry out an objective assessment of the ecological state of the reservoir and identify the reasons for the revealed facts.
Czasopismo
Rocznik
Tom
Strony
155--160
Opis fizyczny
Bibliogr. 19 poz., tab.
Twórcy
autor
- Department of Zoohygiene, Physiology and Biochemistry, Vyatka State Agricultural Academy, Oktyabrsky Prospekt 133, Kirov, 610017, Kirov Region, Russia
Bibliografia
- 1. Aguiar, F.C., Ferreira, M.T., Albuquerque, A., Rodriguez-Gonzalez, P., Segurado, P. 2009. Structural and functional responses of riparian vegetation to human disturbance: Performance and spatial scaledependence. Fundamental and Applied Limnology, 175(3), 249-267.
- 2. Alemu, T., Bahrndorff, S., Pertoldi, C., Hundera, K., Alemayehu, E., Ambelu, A. 2018. Development of a plant based riparian index of biotic integrity (RIBI) for assessing the ecological condition of highland streams in East Africa. Ecological Indicators, 87, 77-85. DOI: 10.1016/j.ecolind.2017.12.032.
- 3. Chapman, P. M. 1986. Sediment quality criteria from the sediment quality triad – an example. Environmental Toxicology and Chemistry, 5(11), 957-964.
- 4. Directive 2000/60/EC of the European Parliament and of the Council establishing a framework for the Community action in the field of water policy – EU Water Framework Directive (as amended on October 20, 2014). 2000. Available at: https://eur-lex.europa.eu/legal-content/EN/TXT/?uri=CELEX:32000L0060 [Accessed 14.09.2020].
- 5. Environmental Regulatory Document PND FT 14.1:2:3:4.11-04. T.16.1:2:3:3.8-04. 2010. Method for determining the integrated toxicity of surface waters, including marine, ground, drinking, waste waters, water extracts from soils, waste, sewage sludge by changes in bacterial bioluminescence using the Ecolum test-system. Moscow: Nera-S, 30 p.
- 6. Erofeeva, E.A. 2014. Hormesis and paradoxical effects upon exposure to pollutants. Dose-Response, 12(1), 121–135.
- 7. Federal Register FR 1.39.2007.03222. 2007. Methodology for determining the toxicity of water and water extracts from soils, sewage sludge, and waste by mortality and changes in fertility of daphnias. Moscow: Akvaros. 51 p.
- 8. Federal Register FR 1.39.2007.03223. 2007. Methodology for determining the toxicity of water, water extracts from the soil, sewage sludge and waste by changing the level of chlorophyll fluorescence and the number of algae cells. Moscow: Akvaros. 50 p.
- 9. Federal Register FR 1.39.2015.19242. 2015. Environmental Regulatory Document PND F T 16.2:2.298. Methodology for determining the toxicity of samples of natural, drinking, domestic and drinking, household waste, treated sewage, waste, thawed, technological water by the express method using the Biotester device. St. Petersburg: Spektrum, p. 21.
- 10. Hong, Y.K., Yoon, D.H., Kim, J.W., Chae, M.J., Ko, B.K., Kim, S.C. 2020. Ecological risk assessment of heavy metal-contaminated soil using the triad approach. Journal of Soils and Sediments. DOI: 10.1007/s11368-020-02750-9.
- 11. Karri, R.R., Sahu, J.N., Chimmiri, V. 2018. Critical review of abatement of ammonia from wastewater. Journal of Molecular Liquids, 261, 21–31, DOI: 10.1016/j.molliq.2018.03.120.
- 12. Klimkowicz-Pawlas, A., Maliszewska-Kordybach, B., Smreczak, B. 2019. Triad-based screening risk assessment of the agricultural area exposed to the long-term PAHs contamination. Environmental Geochemistry and Health, 41(3), 1369-1385, DOI: 10.1007/s10653-018-0220-y.
- 13. Melekhova, O.P., Sarapul’tseva, E.I. 2010. Biological control of the environment: bioindication and bioassay. Moscow: Akademiya. 288 p.
- 14. Ol’kova, A.S. 2017. The conditions of cultivation and the variety of test functions of Daphnia magna Straus in bioassay. Water and ecology: problems and solutions, 1, 64–82. DOI: 10.23968/2305-3488.2017.22.4.111-115.
- 15. Pandard, P., Devillers, J., Charissou, A.M., Poulsen, V. 2006. Selecting a battery of bioassays for ecotoxicological characterization of wastes. Science of the Total Environment, 363, 114–125.
- 16. Slimani, N., Jimenez, J.J., Guilbert, E., Boumaiz, M., Thioulouse, J. 2020. Surface water quality assessment in a semiarid Mediterranean region (Medjerda, Northern Tunisia) using partial triadic analysis. Environmental Science and Pollution Research, 27(24), 30190-30198 DOI: 10.1007/s11356-020-09326-7.
- 17. Stesevic, D., Feiler, U., Sundic, D., Mijovic, S., Erdinger, L., Seiler, T.B., Heininger, P., Hollert, H. 2007. Application of a new sediment contact test with Myriophyllum aquaticum and of the aquatic Lemna test to assess the sediment quality of Lake Skadar. Journal of Soils and Sediments, 7(5), 342349, DOI: 10.1065/jss2007.08.249.
- 18. Water Code of the Russian Federation (as amended on December 27, 2018). 2006. Available at: http://docs.cntd.ru/document/901982862 [Date accessed 02.05.2019].
- 19. Zovko, M., Vidaković-Cifrek, Ž., Cvetković, Ž., Bošnir, J. 2015. Assessment of acrylamide toxicity using a battery of standardised bioassays. Archives of Industrial Hygiene and Toxicology, 66, 315–321.
Uwagi
Opracowanie rekordu ze środków MNiSW, umowa Nr 461252 w ramach programu "Społeczna odpowiedzialność nauki" - moduł: Popularyzacja nauki i promocja sportu (2021).
Typ dokumentu
Bibliografia
Identyfikator YADDA
bwmeta1.element.baztech-ca10da84-8a2d-4f3a-8a28-65db34c6cfb5