AMBIO

, Volume 41, Issue 3, pp 292–301 | Cite as

Impact of Dust Filter Installation in Ironworks and Construction on Brownfield Area on the Toxic Metal Concentration in Street and House Dust (Celje, Slovenia)

Report

Abstract

This article presents the impact of the ecological investment in ironworks (dust filter installation) and construction works at a highly contaminated brownfield site on the chemical composition of household dust (HD) and street sediment (SS) in Celje, Slovenia. The evaluation is based on two sampling campaigns: the first was undertaken 1 month before the ecological investment became operational and the second 3 years later. The results show that dust filter installations reduced the content of Co, Cr, Fe, Mn, Mo, W and Zn on average by 58% in HD and by 51% in SS. No reduction was observed at sampling points in the upwind direction from the ironworks. By contrast, the impact of the construction works on the highly contaminated brownfield site was detected by a significant increase (on average by 37%) of elements connected to the brownfield contamination in SS. Such increase was not detected in HD.

Keywords

House dust Street sediment Toxic metals Industrial dust filters Ironworks Celje 

Notes

Acknowledgments

The author would like to thank both the municipality of Celje and the Research Agency of the Republic of Slovenia for funding the research, and all those who provided the vacuum cleaner bags. Credits are also addressed to everybody who checked the manuscript in detail and provided valuable comments.

References

  1. Aliijagić, J., and R. Šajn. 2011. Distribution of chemical elements in an old metallurgical area, Zenica (Bosnia and Herzegovina). Geoderma 162: 71–85.CrossRefGoogle Scholar
  2. Dimovska, S., T. Stafilov, R. Šajn, and M. Frontasyeva. 2010. Distribution of some natural and man-made radionuclides in soil from the city of Veles (Republic of Macedonia) and its environs. Radiation Protection Dosimetry 138: 144–157.CrossRefGoogle Scholar
  3. GovRS. 2009. Operational programme for the protection of ambient air against pollution caused by PM10. Report no. 35405-4/2009/9. Ljubljana, Slovenia: Government of the Republic of Slovenia (in Slovenian).Google Scholar
  4. Molhave, L., T. Schneider, S.K. Kjvrgaard, L. Larsen, S. Norn, and O. Jorgensen. 2000. House dust in seven Danish offices. Atmospheric Environment 34: 4767–4779.CrossRefGoogle Scholar
  5. OG. 2005. Decree about “Tehnološki park Celje”. Official Gazette of the Republic of Slovenia 91: 9321–9332 (in Slovenian).Google Scholar
  6. Rasmussen, P.E., K.S. Subramanian, and B.J. Jessiman. 2001. A multi-element profile of housedust in relation to exterior dust and soils in the city of Ottawa, Canada. Science of the Total Environment 267: 125–140.CrossRefGoogle Scholar
  7. Romih, N., B. Grabner, B. Tajnik, T. Marovt, T. Širše, G. Žibret, and C. Ribarič-Lasnik. 2010. Evaluation of soil contamination in the area of Bukovžlak. In Onesnaženost okolja in naravni viri kot omejitveni dejavnik razvoja v Sloveniji - modelni pristop za degradirana območja, ed. C. Ribarič-Lasnik, M. Lakota, and F. Lobnik, 73–84. Celje: Inštitut za okolje in prostor (in Slovenian, English abstract).Google Scholar
  8. Šajn, R. 2005. Using attic dust and soil for the separation of anthropogenic and geogenic elemental distributions in an old metallurgic area (Celje, Slovenia). Geochemistry: Exploration, Environment, Analysis 5: 59–67.CrossRefGoogle Scholar
  9. Stafilov, T., M. Aliu, and R. Šajn. 2010a. Arsenic in surface soils affected by mining and metallurgical processing in K. Mitrovica Region, Kosovo. International Journal of Environmental Research 7: 4050–4061.Google Scholar
  10. Stafilov, T., R. Šajn, B. Boev, J. Cvetković, D. Mukaetov, M. Andreevski, and S. Lepitkova. 2010b. Distribution of some elements in surface soil over the Kavadarci region, Republic of Macedonia. Environmental Earth Sciences 61: 1515–1530.CrossRefGoogle Scholar
  11. Stafilov, T., R. Šajn, Z. Pančevski, B. Boev, M.V. Frontasyeva, and L.P. Strelkova. 2010c. Heavy metal contamination of topsoils around a lead and zinc smelter in the Republic of Macedonia. Journal of Hazardous Materials 175: 896–914.CrossRefGoogle Scholar
  12. Turner, A., and L. Simmonds. 2006. Elemental concentrations and metal bioaccessibility in UK household dust. Science of the Total Environment 371: 74–81.CrossRefGoogle Scholar
  13. Voglar, G.E., and D. Leštan. 2010. Solidification/stabilisation of metals contaminated industrial soil from former Zn smelter in Celje, Slovenia, using cement as a hydraulic binder. Journal of Hazardous Materials 178: 926–933.CrossRefGoogle Scholar
  14. World Bank Group—International Finance Corporation. 2007. Environmental, health, and safety guidelines—integrated steel mills. Retrieved 1 June 2011 from http://www.ifc.org/ifcext/sustainability.nsf/AttachmentsByTitle/gui_EHSGuidelines2007_IntegratedSteelMills/$FILE/Final+-+Integrated+Steel+Mills.pdf.
  15. World Steel Association. 2010. Steel statistical yearbook 2009. Retrieved 1 June 2011 from http://www.worldsteel.org/pictures/programfiles/SSY2009.pdf.
  16. Žibret, G. 2002. Geochemical properties of soil and attic dust on the Celje area. Diploma thesis, University of Ljubljana, Ljubljana (in Slovenian, English abstract).Google Scholar
  17. Žibret, G. 2008. Determination of historical emission of heavy metals into the atmosphere: Celje case study. Environmental Geology 56: 189–196.CrossRefGoogle Scholar
  18. Žibret, G., and D. Rokavec. 2010. Household dust and street sediment as an indicator of recent heavy metals in atmospheric emissions: A case study on a previously heavily contaminated area. Environmental Earth Sciences 61: 443–453.CrossRefGoogle Scholar
  19. Žibret, G., and R. Šajn. 2008. Modelling of atmospheric dispersion of heavy metals in the Celje area, Slovenia. Journal of Geochemical Exploration 97: 29–41.CrossRefGoogle Scholar
  20. Žibret, G., and R. Šajn. 2010. Chemical composition of urban sediments (dusts) on the Celje area and comparison with other Slovenian towns. In Onesnaženost okolja in naravni viri kot omejitveni dejavnik razvoja v Sloveniji - modelni pristop za degradirana območja, ed. C. Ribarič-Lasnik, M. Lakota, and F. Lobnik, 73–84. Celje: Inštitut za okolje in prostor (in Slovenian, English abstract).Google Scholar

Copyright information

© Royal Swedish Academy of Sciences 2011

Authors and Affiliations

  1. 1.Geological Survey of SloveniaLjubljanaSlovenia

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