Submit an Article
Become a reviewer
Vol 243
Pages:
388-392
Download volume:
RUS ENG

Geochemical approach in assessing the technogenic impact on soils

Authors:
Galina I. Sarapulova
About authors
  • Ph.D., Dr.Sci. Professor Irkutsk National Research Technical University
Date submitted:
2020-06-14
Date accepted:
2020-06-14
Date published:
2020-06-30

Abstract

The soil assessment was carried out in the technogenically-affected area of Irkutsk Oblast with the geochemical approach as a key geoecological method using physical and chemical techniques of analysis and ecodiagnostics. Diagnostic signs of the disturbed natural properties of the soil were revealed up to a depth of 40 cm in the profile based on macro- and micromorphometric parameters. The content of heavy metals (HM) – Pb, Zn, Hg, and Cu with an excess of standards was determined, and empirical HM – pH correlations were obtained by statistical clustering of the data array. The contributions of additional factors affecting the chemical element distribution in the soil layer were investigated. Significant soil contamination with sulfates and the possibility of implementing the ion-exchange of HM andfor element immobilization were revealed. It was shown that reactions with sulfates and the influence of pH, HM exchange processes involving mobile K and P can determine the nature of the described chemical element distribution in the multi-factor-contaminated technogenic soil. However, the effectiveness of such types of interaction is different for each metal and also depends on the quantitative ratio of substances and soil characteristics, even under a minor change in pH. Two-parameter correlations of HM distribution in sulfate-contaminated soils confirmed the different degrees of involvement of chemical elements in these types of interactions. The results obtained and the identified factors are of applied significance and can be used as the basis for geoecological differentiation of the contaminated soil, as well as for determining local geochemical fields in the technogenesis zone. Areas of advanced research are related to three-dimensional modeling for a more complete study of the cause-and-effect relationships of geochemical parameters.

Keywords:
geochemical parameters soils technogenic objects pollutants heavy metals sulfates empirical dependencies
10.31897/pmi.2020.3.388
Go to volume 243

References

  1. Akhtimankina A.V. Air Pollution Caused by Emissions of Industrial Enterprises of Irkutsk Region. Izvestiya IGU. Seriya Nauki o Zemle. 2017. Vol. 21, p. 15-27 (in Russian).
  2. Glazovskaya M.A. Problems and methods of assessment of the ecogeochemical resistance of soils and the soil cover towards technogenic impacts. Eurasian Soil Science. 1999. N 1, p. 99-108.
  3. State report “On the state of Lake Baikal and measures for its protection in 2017”. Irkutsk: ANO «KTs Ekspert», 2018, p. 340 (in Russian)
  4. State report “Assessment and protection of the environment of the Russian Federation in 2018”. Moscow: NPP Kadastr. 2019. 844 p. (in Russian).
  5. Zavaltseva O.A., Avanesyan N.M., Antonova J.A. Ecological and Geochemical Condition of the Upper Stratum of the Soils of Park Territories of the City of Ulyanovsk in the Conditions of Increasing Anthropogenic Loading. Contemporary Problems of Ecology. 2014. N 2, p. 319-327.
  6. Perelman A.I., Kasimov A.S. Landscape geochemistry. Moscow: Astreya, 2000, p. 763 (in Russian).
  7. Sarapulova G.I. Need to Сonsider Sulfates Transformation in Surface Water Under Environmental Control. Ecology and Industry of Russia. 2017. Vol. 21. N 11, p. 47-51 (in Russian).
  8. Sarapulova G.I. Environmental geochemical assessment of technogenic soils. Journal of Mining Institute. 2018. Vol. 234, p. 658-662. DOI: 10.25515/PMI.2018.6.658
  9. Siromlya T.I. About the Mobile Forms of the Compounds of Chemical Elements in Soils. Contemporary Problems of Ecology. 2009. Iss. 2, p. 307-318..
  10. Khalbaev V.L., Grebenshchikova V.I. Content of heavy metals (Pb, Zn, Cd, Hg) in soil cover of Irkutsk and its environs. Vestnik Irkutskogo gosudarstvennogo tekhnicheskogo universiteta. 2012. N 7(66), p. 71-80 (in Russian).
  11. Shibaeva I.N., Yapenga Ya. Soil quality criteria as a tool for calculating critical loads. Vestnik MGU. Ser. 17. Pochvovedenie. 2001. N 1, p. 7-13 (in Russian).
  12. Kasimov N.S., Kosheleva N.E., Sorokina O.I., Bazha S.N., Gunin P.D., Enkh-Amgalan S. Ecological-Geochemical State of Soils in Ulaanbaatar (Mongolia). Eurasian Soil Science. 2011. N 7, p. 709-721.
  13. Belogolova G.A., Koval P.V. Environmental geochemical mapping and assessment of anthropogenic chemical changes in the Irkutsk-Shelekhov region, southern Siberia, Russia. Journal of Geochemical Exploration. 1995. Vol. 55. Iss. 1-3, р. 193-201.
  14. Sanderson J., Harris L.D. Landscape Ecology: A top-down approach. Boca Raton, Florida, USA: Lewis Publishers, 2000, p. 246.
  15. Gambrell R.P., Wiesepape J.B., Patrick W.H., Duff M.C. The effects of pH, redox and salinity on metal release from a contaminated sediment. Water, Air and Soil Pollut. 1991. Vol. 57, p. 359-367.
  16. Wu J. Landscape ecology, cross-disciplinarity, and sustainability science. Landscape Ecology. 2006. Vol. 21. Iss. 1, p. 1-4.

Similar articles

Multi-terminal dc grid overall control with modular multilevel converters
2020 Miguel Jiménez Carrizosa, Nikola Stankovic, Jean-Claude Vannier, Yaroslav E. Shklyarskiy, Aleksei I. Bardanov
Management of hardening mixtures properties when stowing mining sites of ore deposits
2020 Vladimir I. Golik, Yury V. Dmitrak, Vitaly I. Komashchenko, Nikolay M. Kachurin
Methods for assessing the technical compatibility of heterogeneous elements within a technical system
2020 Sergey A. Vasin, Alexander S. Vasilev, Elena V. Plahotnikova
Revisiting the evolution of deformation zones under platform conditions in the case study of the Kungur Ice Cave (Cis-Urals)
2020 Nataliya V. Lavrova
Theoretical analysis of frozen wall dynamics during transition to ice holding stage
2020 Mikhail A. Semin, Lev Yu. Levin, Aleksandr V. Bogomyagkov
Non-destructive testing of multilayer medium by the method of velocity of elastic waves hodograph
2020 Aleksandr I. Potapov, Artem V. Kondratev