12. Dynamics of interacting of association spore-former soil microorganisms with Fe (ІІІ)

Govoruha V. M., Tashyrev O. B.
Pages: 59-62.

Full article: 
Abstract
Goal. Investigate the dynamics of the interaction of the association of spore-forming soil microorganisms with Fe (III) compounds. Methods. Microbiological, potentiometric, colorimetric methods and gas chromatography were applied. Results The dynamics of the interaction of the association of spore-forming soil microorganisms with Fe (III) compounds was investigated. It has been established that the natural microbial group maintains the stability of the function of introducing Fe (III) compounds. It was found that the efficiency of reduction of Fe (III) in 74 years was 65%, and precipitation efficiency - 35%. Conclusions The ability of an association to interact with Fe compounds indicates its significant role in the biogeochemical cycles of the transformation of Fe in the genus. The assessment of the effectiveness of the interaction of the natural soil association with Fe compounds creates the basis for the development of effective biotechnologies for purifying water from Fe, as well as the removal of its compounds from depleted deposits.

Key words: thermodynamic forecasting, biogeochemical cycles of Fe transformation, association of spore-forming soil microorganisms.

References
  1. Apyctobckaia T.B. Mykpobyoloryia npotsec cob nochboobpazobahyia/T.B. Apyctobckaia. – L.: Hayka, 1980. – 187 c.
  2. Bodiahytskyj Ju.H. Okcydbl zheleza y yx polb b nlodopodyy nochb/Ju.H. Bodiahytskyj. – M.: Hayka, 1989. – 160 c.
  3. Glyhka H.L. Obschaia xymyia/H.L. Glyhka. – K.: Byscha shk., 1976. – 624 c.
  4. Dpyrob Ju.C. Gazoxpomatorpafycheckyj ahaliz zarpiazhehhoro bozdyxa/Ju.C. Dpyrob, B.G. Bepezkyh.– M.: Xymyia, 1981. – 256 c.
  5. Obpazobahye molekyliaphoro bodopoda accotsyatsyej cnopoobpazyiuschyx mykpooprahyzmob/ H.A. Matbeeba, A.C. Lebyshko, Y.P. Ppytyla y dp.//Mikpobiolorichhyj zhyph. – 2011. – T. 73, № 1. – C. 36 — 43.
  6. Cehdel E. Kolopymetpycheckye metodbl onpedelehyia cledob metallob/E. Cehdel. – M.: Myp, 1964. – 899 c.
  7. Clobodkyh A.Y. Tepmofylbhble zhelezobocctahablybaiuschye npokapyotbl: abtopef. dyc. ha coyck. haych. ctenehy d-pa byol. hayk/A.Y. Clobodkyh. – M., 2008. – 35 c.
  8. Cnpabochhyk xymyka; nod ped. B.P. Hykolbckoro. – T. 3. – M., L.: Xymyia, 1965. – 1008 c.
  9. Becker M. Iron toxity in rice-conditions and management concepts/M. Becker, F. Asch//J. Plant Nutr. Soil Sci. – 2005. – 168. – P. 558 — 573.
  10. Lovley D.R. Organic matter mineralization with the reduction of ferric iron: a review/D.R. Lovley//Geomicrobiology J. – 1987. – V. 5, № 3 — 4. – P. 375 — 399.
  11. Nealson K.H. Microbial reduction of manganese and iron: new approaches to carbon cycling/K.H. Nealson, Ch.R. Myers//Applied and Environmental Microbiology. – 1992. – V. 58, № 2. – P. 439 — 443.
  12. Tashyreva A. The Novel Comprehensive Approach for Agricultural and Landfill Biomass Microbial Fermentation and Biogas Production/A. Tashyreva, O. Tashyrev, I. Prytula//Biotechnology and Plant Breeding Perspectives, Eds., R.K. Behl and Ed.Arseniuk, Agrobios (International) Publishers, 2014. – P. 347 — 356.