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Comparative analysis of soil magnetic susceptibility and concentration of rare earth elements in soil of problematic areas

Treść / Zawartość
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Warianty tytułu
Języki publikacji
EN
Abstrakty
EN
Soil contamination with rare earth metals (REE) can have both direct and indirect connection with industrial activity and ore-exploration. In the studies conducted so far, the presence of rare earth elements in coal seams, coal combustion waste as well as fly ash was found. It is important that detailed studies of the REE content in soil were not carried out in Poland. Until now, in a few studies, a high content of cerium and lanthanum was found in relation to the average content of the torn ones in the world. This work focuses on the areas under the influence of the industry associated with the extraction and combustion of hard coal, but also with other types of industry. Analyzes of REE content in soil were conducted in selected areas of the Upper Silesian Industrial Region and Norway, located near the Bjornevatn mine. In study areas, soil samples were collected and used for chemical and magnetometric measurements. Firstly, concentrations of REE were determined, and after that soil samples were used to measure soil magnetic susceptibility. Finally, statistical analyses were performed in order to check the correlation between REE concentrations in soil and soil magnetic susceptibility.
Rocznik
Strony
81--90
Opis fizyczny
Bibliogr. 25 poz., fig., tab.
Twórcy
  • Warsaw University of Technology, Poland
Bibliografia
  • 1. Beckwith, R., Bulter, J. (1993). Aspects of the chemistry of soil organic matter. In soils, An Australian Viewpoint. Division of Soils. CSIRO. Australia: Canberra.
  • 2. Bronder, L., Kudrik, I., Nikitin, A., Jorgensen, K.V. and Nikiforov V. (2010). Environmental Challenges in the Arctic, Norilsk Nickel. The Soviet Legacy of Industrial Pollution. Bellona report.
  • 3. Cao, X. (2001). Effects of redox potential and pH value on the release of rare earth elements from soil. Chemosphere, 44, pp. 655-661.
  • 4. Dai, S.F., Zoua, J., Jiang, Y., Ward, C.R., Wang, X., Li, T., Xue, W., Liu, Sh., Tian, H., Sun, X. and Zhou, D. (2012). Mineralogical and geochemical compositions of the Pennsylvanian coal in the Adaohai Mine, Daqingshan Coalfield, Inner Mongolia, China: Modes of occurrence and origin of diaspore, gorceixite and ammonianillite. International Journal of Coal Geology, 94, pp. 250-270.
  • 5. Dearing, J.A. (1994). Environmental Magnetic Susceptibility. Using the Bartington MS2 System. Chi Publishing. UK: Kenilworth.
  • 6. Fabijańczyk, P., Zawadzki, J. and Magiera T. (2017). Magnetometric assessment of soil contamination in problematic area using empirical Bayesian and indicator kriging: A case study in Upper Silesia. Poland. Geoderma, 308, pp. 69-77.
  • 7. Fürst, Ch., Lorz, C. and Makeschin, F. (2009). Testing a Soil Magnetometry Technique in a Highly Polluted Industrial Region in North-Eastern Germany. Water Air Soil Poll, 202(1-4), pp. 33-43.
  • 8. Hower, J.C., Ruppert, L.F., Eble, C.F. (1999). Lanthanide, yttrium, and zirconium anomalies in the Fire Clay coal bed. Eastern Kentucky. International Journal of Coal Geology, 39, pp. 141-153.
  • 9. Hu, Z., Haneklaus, S., Sparovek, G. and Schnug, E. (2006). Rare earth elements in soil. Communications in Soil Science and Plant Analysis, 37, pp. 1381–1420.
  • 10. Jarosiński, A. (2016). Możliwości pozyskiwania metali ziem rzadkich w Polsce. Zeszyty Naukowe, Instytutu Gospodarki Surowcami Mineralnymi i Energią, Polskiej Akademii Nauk, 92, pp. 75-88.
  • 11. Jones, A., Montanarella, L., Micheli, E., Spaargaren, O. and Jones, R.J.A. (2010). Major soil types of Europe. European Commission Joint Research Centre. R. Salminen, M. Batista, J. Bidovec, M. Demetriades, A. et al. Geochemical atlas of Europe. Part 1: Background information, methodology and maps.
  • 12. Kowalczyk, J., Mazanek, C. (1989). Metale ziem rzadkich i ich związki. Warszawa: WNT.
  • 13. Ramos, S.J., Dinali, G.S., Oliveira, C. et al., (2016). Rare Earth Elements in the Soil. Environment Curr Pollution Rep, 2, pp. 28-50.
  • 14. Magiera, T., Zawadzki, J., (2006). Magnetometria glebowa – nowe narzędzie geofizyczne do oceny zanieczyszczenia gleb. Geofizyka. Biuletyn Informacyjny, 2(2006), pp. 74-90.
  • 15. Magiera, T., Zawadzki, J. (2007). Using of high-resolution topsoil magnetic screening for assessment of dust deposition: comparison of forest and arable soil datasets. Environ. Monit. Assess., 125, pp. 19-28.
  • 16. Magiera, T., Zawadzki, J., Szuszkiewicz, M., Fabijańczyk, P., Steinnes, E., Fabian K., Miszczak E. (2018). Impact of an iron mine and a nickel smelter at the Norwegian/Russian border close to the Barents Sea on surface soil magnetic susceptibility and content of potentially toxic elements. Chemosphere, 195, pp. 48-62.
  • 17. Petrovský, E., Kapička, A., Jordanova, N., Knab, M., Hoffmann, V. (2000). Low-field magnetic susceptibility: a proxy method of estimating increased pollution of different environmental systems. Environ. Geol., 39, pp. 312-318.
  • 18. Ran, Y., Liu, Z. (1993). Adsobtion and desorbtion of rare earth elements on soils and synthetic oxides. Acta Scientiae Circumstantiae, 13(3), pp. 287-293.
  • 19. Smółka-Danielowska D. (2007). REE w popiołach lotnych w procesie spalania węgla kamiennego w elektrowniach górnośląskiego okręgu przemysłowego. Ochrona Środowiska i Zasobów Naturalnych, 32, pp. 190-194.
  • 20. Spiteri, C., Kalinski, V., Rosler, W., Hoffman, V. and Appel, E. (2005). Magnetic Screening of Pollution Hotspots in the Lausitz Area, Eastern Germany: Correlation Analysis Between Magnetic Proxies and Heavy Metal Concentration in Soil. Environ. Geol., 49, pp. 1-9.
  • 21. Seredin, V.V., Dai, S. (2012). Coal deposits as potential alternative sources for lanthanides and yttrium. International. J. Coal Geol., 94, pp. 67-93.
  • 22. Strzyszcz, Z., Magiera, T., Heller F. (1996). The influence of industrial immisions on the magnetic susceptibility of soils in Upper Silesia. Studia Geoph, et Geod., 40, pp. 276-286.
  • 23. Steinnes, E., Friedland, A.J. (2006). Metal contamination of natural surface soils from long-range atmospheric transport: existing and missing knowledge. Environ Rev.,14(3), pp. 169-186.
  • 24. Thompson, R., Stober, J.C., Turner, G.M., Oldfield, F., Bloemendal, J., Dearing, J.A., Rummery, T.A. (1980). Environmental applications of magnetic measurements, Science, 207(4430), pp. 481-486.
  • 25. Zawadzki, J., Fabijańczyk, P., Magiera, T. (2009). Geostatistical evaluation of magnetic indicators of forest soil contamination with heavy metals. Studia Geophysica et Geodaetica, 53(1), pp.133-149.
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-652f62ca-4402-4ed6-b8ad-a0c7b28cddaa
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