Tytuł artykułu
Autorzy
Treść / Zawartość
Pełne teksty:
Identyfikatory
Warianty tytułu
Języki publikacji
Abstrakty
The study was conducted with the purpose of experimentally developing the method of water purification from ions of cadmium (II) using a new design of a bio-plateau, which is based on the use of terrestrial plants. In order to construct the bio–plateau, the following chemically inert floating materials were used as the substrate: perlite, expanded clay, granular foam, vermiculite, cork, on top of which the seeds of higher terrestrial plants were placed. The experimental data showed that foam was the best of the tested substrates, and of plants – barley, oats, corn and rye. The constructed bio-plateau was placed into tanks with a solution of cadmium on the 9th day of incubation to study the cleaning efficiency of terrestrial plants on the aquatic environment. Determination of the residual concentration of cadmium was performed with the method of AAC at λ=228.8. As a result, it was found that rye showed the best sorption properties of the tested plants. The influence of additional aeration and pH of the medium on the degree of water purification was established. The highest treatment efficiency was observed in the variant of a bio-plateau with aeration and at a pH of 8-9. The study shows the possibility of using terrestrial plants for the phytoremediation of water bodies.
Słowa kluczowe
Czasopismo
Rocznik
Tom
Strony
29--34
Opis fizyczny
Bibliogr. 17 poz., rys.
Twórcy
autor
- Department of Biophysics and Radiobiology, Institute of Cell Biology and Genetic Engineering, National Academy of Science of Ukraine, Kyiv, 03143, Ukraine
autor
- Department of Biophysics and Radiobiology, Institute of Cell Biology and Genetic Engineering, National Academy of Science of Ukraine, Kyiv, 03143, Ukraine
autor
- National Aviation University, Kyiv, 03058, Ukraine
autor
- National Aviation University, Kyiv, 03058, Ukraine
autor
- National Aviation University, Kyiv, 03058, Ukraine
autor
- National Aviation University, Kyiv, 03058, Ukraine
Bibliografia
- 1. Evdokimova G.A., Ivanova L.P., Mozgova N.P., Myazin V.A., Fokina N.V. 2016. Floating bioplato for purification of waste quarry waters from mineral nitrogen compounds in the Arctic. Journal of Environmental Science and Health, Part A, No. 51, 1–6. DOI:10.1080/10934529.2016.1181454
- 2. Glazunova I.V., Romashchenko A.K., Tishina K.A. 2018. Bioengineering structures and storage of local drainage of watersheds for the most effective use of water resources of river resources. Prirodoobustroystvo, 2, 46–54 [in Russion].
- 3. Filipchuk V.L., Bondar О.І., Kuriluk М.S., Ayaya А., Krivoshey P.P., Kuriluk О.М., Pochtar О.V. 2016. Water purification in filtration regenerative wetland. Bulletin NUWEE. 2(74), 193–204.
- 4. Filipchuk V.L., Kuriluk М.S., Filipchuk L.V., Kuriluk О.М., Krylyuk V.М., Pochtar О.V. 2016. Purification of muddy waters in filtration regenerative wetland. Bulletin of the Engineering Academy of Ukraine, 3, 150–155.
- 5. Khavezov I., Tsalev D. 1983. Atomno-absorbtsionnyy analiz, Leningrad, Khimiya, pp. 144 [in Russion].
- 6. Madzhd S.M. 2016. Experience in exploiting hydrophilic structures in Ukraine and in the world. Naukoiemni technologii, 2, 228–231 [in Ukrainian].
- 7. Madzhd S.M., Panchenko A.O., Bondar A.M. 2017. The role of higher aquatic plants in the degradation of pollutants in bioengineering hydrofit structures. Naukoiemni technologii, 1, 89–93 [in Ukrainian].
- 8. Mikheev, A.N., Lapan, O.V., Madzhd, S.M. (2018). Development of a new method of garment filtering purification of water objects of chrome (VI) Water Chemistry and Technology, 40(3), 309–314 [in Russion].
- 9. Nefedeva E.E., Sivolobova N.O., Kravtsov M.V., Shayhiev I.G. 2017. Purification of sewage with the help of phytoremediation. Vestnik tehnologicheskogo universiteta, 20(10), 145–148 [in Russion].
- 10. Ostrovskaya S.S. 2014. Токсичні ефекти кадмію. Visnyk problem biologii i medytsyny, 3(2), 33–37 [in Ukrainian].
- 11. Rоманенко В.Д., Крот Ю.Г., Киризій Т.Я. та ін. 2012. Natural and artificial biplane. Fundamental and practical aspects – К.: Наук. думка, p. 110 [in Ukrainian].
- 12. Shachneva E.Yu. Alykov N.M., Archibasova D.E. 2012. Adsorption of cadmium from aqueous solutions on modified sorbents. Tehnika i tehnologiya pischevyih proizvodstv, 4, 1–5 [in Russion].
- 13. Ülo Mander, Valdo Kuusemets, Märt Öövel, Raimo Ihme, Pertti Sevola & Arnold Pieterse 2000. Experimentally constructed wetlands for wastewater treatment in Estonia, Journal of Environmental Science and Health, Part A, 35(8), 1389–1401, DOI: 10.1080/10934520009377042
- 14. Ul’rih D.V., Bryuhov M.N. 2014. The ability to use phytoremediation facilities for wastewater treatment. Nauka YuUrGU: meterialy 66 nauchnoj konferentsii, 1050–1054 [in Russion].
- 15. Ul’rih D.V., Timofeeva S.S. 2016. Phytoremedia of contaminated soils and man-made soils of tailings in the territory of the Southern Ural Mining Companies. Gornyiy informatsionno-analiticheskiy byulleten (nauchno-tehnicheskiy zhurnal), 15, 341–349 [in Russion].
- 16. Yuriy Vergeles, Nataliya Butenko, Andriy Ishchenko, Felix Stolberg, Marika Hogland & William Hogland (2016). Formation and properties of sediments in constructed wetlands for treatment of domestic wastewater, Urban Water Journal, 13(3), 293–301, DOI:10.1080/1573062X.2014.993178.
- 17. Zavatskiy S. V., Kotelchuk L. S., Kotelchuk А. L. 2012. Bioengineering structures for low-waste sewage treatment // Construction, engineering systems and communications, 1(3). 57–63.
Typ dokumentu
Bibliografia
Identyfikator YADDA
bwmeta1.element.baztech-b3b6948d-e8c6-449f-baa4-228791045655