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Tytuł artykułu

Study of Oil-Contaminated Soils Phytotoxicity During Bioremediation Activities

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Identyfikatory
Warianty tytułu
Języki publikacji
EN
Abstrakty
EN
This work is devoted to studying the dynamics of changes in phytotoxicity of oil-contaminated meadow soils in the process of microbial bioremediation. The research was conducted under laboratory and field conditions. Winter rye (Secále cereále) was selected as the test object. In order to assess the degree of toxicity in the laboratory, the indicators of seed germination – germination rate and germination energy-were determined. In a field experiment, the ecological state of oil-contaminated soils was evaluated by the germination rate and the amount of aboveground plant biomass. The research results showed that the content of petroleum products significantly affected the percentage of germination of rye seeds. There are differences in the size of seedlings for different experimental schemes: in all tests, the average height of cleoptila on polluted soil was less than on unpolluted soil, but at the same time it varied for different experimental bioremediation schemes. The use of potassium humate and modified vermiculite as additives significantly reduced the toxicity of the oil-contaminated soil.
Słowa kluczowe
Rocznik
Strony
67--72
Opis fizyczny
Bibliogr. 32 poz., rys., tab.
Twórcy
autor
  • Department of Technospheric safety, Tyumen Industrial University, Tyumen, Russia
  • Department of Technospheric safety, Tyumen Industrial University, Tyumen, Russia
Bibliografia
  • 1. Kazuya, W. 2001. Microorganisms relevant to bioremediation: Current Opinion in Biotechnology, 237–241.
  • 2. Andreoni, V., & Gianfreda, L. 2007. Bioremediation and monitoring of aromatic-polluted habitats. Applied Microbiology and Biotechnology, 76(2), 287–308.
  • 3. Robles-González, I.V., Fava, F., & Poggi-Varaldo, H.M. 2008. A review on slurry bioreactors for bioremediation of soils and sediments. Microbial Cell Factories, 7(1), 5.
  • 4. Lakshmi, M.B., Perumal, V. & Velan, M. 2013. Bioremediation of phenanthrene by Mycoplana sp. MVMB2 isolated from contaminated soil: Clean Soil Air Water, 41 (1), 86–93.
  • 5. Laurie, A.D. & LloydJones, G. 1999. Conserved and hybrid meta-cleavage operons from PAHdegrading Burkholderia RP007: Biochem. Biophys. Res. Commun., 262, 308–314.
  • 6. Seo, J.S, Keum, Y.S. & Li, Q.X. 2009. Bacterial degradation of aromatic compounds: International Journal of Environmental Research and Public Health, 6, 278–309.
  • 7. Lu, J., Dang, Z., Lu, G., Yang, C., Yi, X. & Guo, C. 2012. Biodegradation Kinetics of Phenanthrene by a Fusant Strain: Current Microbiology, 65(3), 225–230.
  • 8. Lee R.F. 2003. Photo-oxidation and photo-toxicity of crude and refined oils. Spill Science and Technology Bulletin, 8(2), 157–162.
  • 9. Wang W. 1991. Literature review on higher plants for toxicity testing. Water Air Soil Pollut 59, 381–400.
  • 10. Masloboev, V.A., & Evdokimova, G.A. 2012. Bioremediation of oil product contaminated soils in conditions of North Near-Polar Area. In: Proceedings of the MSTU, Vol. 15, No. 2, pp. 357–360.
  • 11. Pawluśkiewicz B., Gnatowski T., Janicka M. 2020. The influence of soil contamination with diesel oil on germination dynamics and seedling development of selected species of the Fabaceae family. Journal of Ecological Engineering, 21(1), 210–218.
  • 12. Buluktaev A.A. 2019. Fitotoksichnost’ neftezagryaznennyh pochv aridnyh territorij (v usloviyah model’nogo eksperimenta). Russian Journal of Ecosystem Ecology, 3, 59–68.
  • 13. Płaza G., Nałecz-Jawecki G., Ulfig K., Brigmon R.L. 2005. The application of bioassays as indicators of petroleum-contaminated soil remediation. Chemosphere, 59, 289–296.
  • 14. Mayer, A.M., & Poljakoff-Mayber, A. 1982. The Germination of Seeds: Pergamon International Library of Science, Technology, Engineering and Social Studies. Elsevier.
  • 15. Muratova, A.Y., Dmitrieva, T.V., Panchenko, L.V., & Turkovskaya, O.V. 2008. Phytoremediation of Oil-Sludge–Contaminated Soil. International Journal of Phytoremediation, 10(6), 486–502.
  • 16. Muratova, A.Y., Bondarenkova, A.D., Panchenko, L.V., & Turkovskaya, O.V. 2010. Use of integrated phytoremediation for cleaning-up of oil-sludgecontaminated soil. Applied Biochemistry and Microbiology, 46(8), 789–794.
  • 17. Nõlvak, H., Truu, J., Limane, B., Truu, M., Cepurnieks, G., Bartkevičs, V., ... & Muter, O. 2013. Microbial community changes in TNT spiked soil bioremediation trial using biostimulation, phytoremediation and bioaugmentation. Journal of Environmental Engineering and Landscape Management, 21(3), 153–162.
  • 18. Bossert, I., & Bartha, R. 1985. Plant growth in soils with a history of oily sludge disposal. Soil Science, 140(1), 75–77.
  • 19. Chaineau, C.H., Morel, J.L., & Oudot, J. 1996. Land treatment of oil-based drill cuttings in an agricultural soil. Journal of environmental quality, 25(4), 858–867.
  • 20. Amakiri, J.O., & Onofeghara, F.A. 1983. Effect of crude oil pollution on the growth of Zea mays, Abelmoschus esculentus and Capsicum frutescens. Oil and Petrochemical Pollution, 1(3), 199–205.
  • 21. Udo, E.J., & Fayemi, A.A.A. 1975. The effect of oil pollution of soil on germination, growth and nutrient uptake of corn. Journal of Environmental Quality, 4(4), 537–540.
  • 22. Baker, J.M. 1970. The effects of oils on plants. Environmental Pollution, 1(1), 27–44.
  • 23. Klokk, T. 1984. Effects of oil pollution on the germination and vegetative growth of five species of vascular plant. Oil and Petrochemical Pollution, 2(1), 25–30.
  • 24. Kochany, J., & Smith, W. 2001. Application of humic substances in environmental remediation. In: Proceedings of WM’01 Conference, February, Vol. 25.
  • 25. Kuráň, P., Trögl, J., Nováková, J., Pilařová, V., Dáňová, P., Pavlorková, J., ... & Popelka, J. 2014. Biodegradation of spilled diesel fuel in agricultural soil: Effect of humates, zeolite, and bioaugmentation. The Scientific World Journal, 2014.
  • 26. Mosley, R.A.N.D.Y., & Morris & Mosley, I. 1998. The effects of humates on remediation of hydrocarbon and salt contaminated soils. In 5th International Petroleum Environmental Conference, New Mexico, pp. 5–14.
  • 27. Minnikova, T.V., Kolesnikov, S.I., Denisova, T.V., & Akimenko, Y.V. 2018. Biodiagnosis of the state of oilpolluted chernozem during remediation with urea and potassium humate. International Multidisciplinary Scientific GeoConference: SGEM, 18(3.2), 33–40.
  • 28. Kim, J., Lee, A.H., & Chang, W. 2018. Enhanced bioremediation of nutrient-amended, petroleum hydrocarbon-contaminated soils over a cold-climate winter: the rate and extent of hydrocarbon biodegradation and microbial response in a pilotscale biopile subjected to natural seasonal freezethaw temperatures. Science of the Total Environment, 612, 903–913.
  • 29. Rhykerd, R.L., Crews, B., McInnes, K.J., & Weaver, R.W. 1999. Impact of bulking agents, forced aeration, and tillage on remediation of oil-contaminated soil. Bioresource Technology, 67(3), 279–285.
  • 30. Embar, K., Forgacs, C., & Sivan, A. 2006. The role of indigenous bacterial and fungal soil populations in the biodegradation of crude oil in a desert soil. Biodegradation, 17(4), 369–377.
  • 31. Su, D., Li, P.J., Frank, S. and Xiong, X.Z. 2006. Biodegradation of benzo[a]pyrene in soil by Mucor sp. SF06 and Bacillus sp. SB02 co-immobilized on vermiculite. J. Environ. Sci. 18: 1204–1209
  • 32. Vasilyeva G.K., Strizhakova E.R., Kondrashina V.S., Myazin V.A., Korneikova M.V. 2019. Advantages of the technology of sorption-biological treatment of soils contaminated with oil and oil products. Environmental problems of the northern regions and ways to solve them. 320–321.
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-b495beb5-719f-4348-a023-6100ad8edc17
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