Biotechnology of Underground Waters Treatment with Ferrobacteria Under the Influence of Constant Magnetic Field

• Autorzy: Kvartenko Oleksandr M. , Gerasimov Ievgienii G.

Identyfikatory

DOI

10.2478/heem-2024-0007

• Języki publikacji: EN

Abstrakty

EN

In the modern global field of underground water treatment, the technology of biological iron removal is gaining more and more recognition, as it has a number of significant advantages compared to traditional ones, namely: increased rates of Fe(II) oxidation, filtration, as well as a large dirt capacity of the filter filling. Therefore, the search for methods to activate cellular metabolic processes has practical implications. One of the possible ways of such activation is by using the effect of a constant magnetic field (CMF) on communities of ferrobacteria attached to the contact loading of bioabsorbents made of synthetic material. Based on the results of the research, it has been established that the CMF with an induction value of 5–10 mT is the most favorable for the development of ferrobacteria colonies, while the induction of 130–150 mT, on the contrary, inhibits their development. There has been studied the effect of CMF with the power of 10–15 mT on the efficiency of combined processes of treatment from dissolved organic compounds and Fe(II). The results of comparative studies on the effectiveness of various technological schemes are presented. It was found that with the use of CMF with a magnetic induction of 5–10 mT, the effect of iron removal increases by 20%. There has been developed biotechnology for treating weak acid (pH 6.3–6.5), iron-containing (Fe2+ 6–8 mg/dm3) underground waters which is based on the combinatorics of physical (aeration, influence of constant magnetic field) and biochemical (use of ferrobacteria consortia) methods. The main technological parameters of the process: filtration rate for the bioreactor 7–10 m/h, for filters 6–8 m/h; duration of filter cycles for the bioreactor is 2–3 weeks; for filters 44–48 hours have been determined. The theoretical aspects of the impact of CMF on the processes of biochemical treatment of underground water have been substantiated.

Słowa kluczowe

EN

underground water; ferrobacteria; biological method of iron removal; bioreactor; constant magnetic field

• Wydawca: Institute of Hydro-Engineering of Polish Academy of Sciences
• Czasopismo: Archives of Hydro-Engineering and Environmental Mechanics
• Rocznik: 2024
• Tom: Vol. 71, nr 1
• Strony: 105--122
• Opis fizyczny: Bibliogr. 28 poz., rys., wykr.

Twórcy

autor

Kvartenko Oleksandr M.

• National University of Water and Environmental Engineering, 11 Soborna Str., Rivne, Ukraine, 33028;

autor

Gerasimov Ievgienii G.

• National University of Water and Environmental Engineering, 11 Soborna Str., Rivne, Ukraine, 33028;

Bibliografia

• Abrajevitch A., Kondratyeva L. M., Golubeva E. M., Kodama K., Hori R. S. (2016) Magnetic properties of iron minerals produced by natural iron- and manganese-reducing underground waters bacteria, Geophysical Journal International, 206 (2.1), 1340–1351, https://doi.org/10.1093/gji/ggw221.
• Angelova R., Slavov L., Iliev M., Mitova M., Blagoev B., Nedkov I., Groudeva V. (2015) Biogenic iron oxides from laboratory cultivated Leptothrix SP. for application in the bionanotechnology, First National Conference of Biotechnology, Sofia 2014, Annuaire de l’Universit´e de Sofia “St. Kliment Ohridski” Faculte de Biologie, 100 (4), 231–238.
• Ankrah D. A., Søgaard E. G. (2009) A review of biological iron removal, Thirteenth International Water Technology Conference, IWTC 13 2009, Hurghada, Egypt, 999–1005.
• Beretta G., Mastorgio A. F., Pedrali L., Saponaro S., Sezenna E. (2019) The effects of electric, magnetic and electromagnetic fields on microorganisms in the perspective of bioremediation, Rev. Environ Sci Biotechnol, 18, 29–75, https://doi.org/10.1007/s11157-018-09491-9.
• Casey T. J. (2009) Iron and manganese in water: Occurrence, drinking water standards, treatment options, Aquavarra Research Publications Water Engineering Papers Aquavarra Research Limited, 22a Brook Field Avenue, Blackrock, County Dublin, Ireland.
• Chana C. S., Fakra S. C., Edwards D., Emerson D., Banfield J. F. (2009) Iron oxyhydroxide mineralization on microbial extracellular polysaccharides, Geochimica et Cosmochimica Acta, 73, 3807–3818.
• Cullimore D. R., McCann A. E. (1974) The Global Distribution of Iron Bacteria in Water, Unpublished report No 9, Regina Water Research Institute, Canada.
• Cullimore D. R., McCann A. E. (1978) The Identification, Cultivation and Control of Iron Bacteria In Ground Water, in: Skinner F. A., Shewan J. M. (eds) Aquatic Microbiology, Academic Press, New York, 219–261.
• Goldscheider N., Hunkeler D., Rossi P. (2006) Review: bacterial biocenoses in pristine aquifers and an assessment of investigative methods, Hydrogeol. J., 14, 926–941, DOI:10.1007/S10040-005-0009-9.
• GOST (1978) 23268.12-78 Mineral drinking medicinal, medical-table and natural table waters. Method of determination of permanganate oxidizability.
• Hettler J. P. (1982) Une Station de Defferrisation Biologique, TSN, L’Eau, 481 p.
• Kennedy C. B., Scott S. D, Ferris F. G (2004) Hydrothermal phase stabilization of 2-line ferrihydrite by bacteria, Chem. Geol., 212, 269–277.
• Kvartenko A. N., Zhurba M. G. (2010) Theoretical substantiation of the conditioning of underground waters of complex physical and chemical composition in a constant magnetic field, Water: chemistry and ecology, 11, 24–32.
• Kvartenko A. N. (2017) Research into factors of mutual influence of ground waters quality parameters on choice of water cleansing technologies, Water and water purification technologies. Scientific and technical news, 1 (21), 39–49.
• Kvartenko O., Sabliy L., Kovalchuk N., Lysytsya A. (2018) The use of the biological method for treating iron containing underground waters, Journal of Water and Land Development, 39 (X–XII), 77–82, DOI: 10.2478/jwld-2018-0061.
• Kvartenko O. (2023) The Use of Biotechnologies for Treating Underground Waters in North-Western Regions of Ukraine, Chapter 18, 298–323 in collective monograph Handbook of Research on Improving the Natural and Ecological Conditions of the Polesie Zone, IGI Global – May, 2023, 479 p., DOI: 10.4018/978-1-6684-8248-3.ch018.
• Lee J. H., Lee B. J., Unno T. (2018) Bacterial communities in ground-and surface water mixing zone induced by seasonal heavy extraction of underground waters, Geomicrobiol. J., 35 (9), 768–774, doi.org/10.1080/01490451.2018.1468834.
• Mouchet P. (1992) From Conventional to Biological Removal of Iron and Manganese in France, JAWWA, 84 (4), 158–167.
• Mouchet P. (1995) Biological Filtration for Iron and Manganese Removal, Proc. AWWA Water Quality Technol. Conf., Pt. 2, 2287–2305.
• Murad E., Bigham J. M., Bowen L. H., Schwertmann U. (1990) Magnetic properties of iron oxides produced by bacterial oxidation of Fe2+ under acid conditions, Hyperfine Interactions, 58, 2373–2376.
• MVV (2005) No. 081/12-0175-05. Surface, underground and return waters. The technique of measuring the mass concentration of total iron by the photocolorimetric method with rhodanide.
• Nesterova M., Moreau J., Banfield J. F. (2003) Model biomimetic studies of templated growth and assembly of nanocrystalline FeOOH, Geochim. Cosmochim. Acta, 67, 1177–1187.
• Neubauer S. C., Emerson D., Megonigal J. P. (2002) Life at the energetic edge: kinetics of circumneutral Fe oxidation by Lithotrophic iron oxidizing bacteria isolated from the wetland plant rhizosphere, Appl Environ Microbiol, 68, 3988–3995.
• Safonov N. A., Rusak G. V. (1984) Self-cleaning plant for biological removal of iron from underground waters, in: Preparation of water for drinking purposes Conference, Leningrad, LEBI, 162–167.
• Sepp¨anen H. (1991) Experiences of Biological Iron and Manganese Removal in Finland, Proc. IWEM Ann. Sym., 15 (1), 9–11.
• Sha C., Wu J., Shen C., Wu J., Yan Zh., Wang M. (2023) The ecology of bacterial communities in underground waters of industrial areas: Diversity, composition, network, and assembly, Environmental Pollution, 322, 1 April 2023, 121207 https://doi.org/10.1016/j.envpol.2023.121207.
• Søgaard E. G., Aruna R., Abraham-Peskir J., Koch C. B. (2001) Conditions for biological precipitation of iron by Gallionella ferruginea in a slightly polluted ground water, Applied Geochemistry, 16, 1129–1137.
• Tanimoto K. (1952) Suido Kyokai Zasshi, J. Japan Water Works Assoc., 213, 19–21