How to search?
advanced search

Search results

Filters

  • Journals
  • Authors
  • Keywords
  • Date
  • Type

Search results

Number of results: 2
items per page: 25 50 75
Sort by:

Monitoring of Greenhouse Gases in the Atmosphere – A Polish Perspective

Kazimierz Różański Łukasz Chmura Michał Gałkowski Jarosław Nęcki Mirosław Zimnoch Jakub Bartyzel Simon O’Doherty
Papers on Global Change IGBP | 2016 | No 23 | DOI: 10.1515/igbp-2016-0009
Download PDF Download RIS Download Bibtex

Authors and Affiliations

Kazimierz Różański
Łukasz Chmura
Michał Gałkowski
Jarosław Nęcki
Mirosław Zimnoch
Jakub Bartyzel
Simon O’Doherty

The geochemical and fractionation study on toxic elements in road dust collected from the arterial roads in Kraków

Ewa Adamiec Elżbieta Jarosz-Krzemińska Robert Brzoza-Woch Mateusz Rzeszutek Jakub Bartyzel Tomasz Pełech-Pilichowski Janusz Zyśk
Archives of Environmental Protection | 2023 | vol. 49 | No 2 | 104-110 | DOI: 10.24425/aep.2023.145902
Keywords air pollution heavy metals traffic fractionation road dust
Download PDF Download RIS Download Bibtex

Abstract

Road dust should be considered as a secondary source of contamination in the environment, especially when re-suspended. In our study road dust samples were collected from 8 high-capacity urban roads in two districts of Kraków (Krowodrza and Nowa Huta). Total concentration of toxic elements, such as Cd, Cr, Cu, Mn, Zn, Co, Pb, Ni, Ba and Se were determined using ICP –MS ELAN 6100 Perkin Elmer. A fractionation study were performed using VI step sequential extraction, according to the modified method provided by Salomons and Fӧrstner. Appropriate quality control was ensured by using reagent blanks and analysing certified reference material BCR 723 and SRM 1848a. Concentration of metals in the road dust varied as follows [mg/kg]: Cd 1.02-1.78, Cr 34.4-90.3, Cu 65-224, Mn 232-760, Zn 261-365, Co 4.32-6.46, Pb 85.6-132, Ni 32.2-43.9, Ba 98.9-104 and Se 78.3-132. Degree of contamination of road dust from Nowa Huta was very high (Cdeg 54) and considerable for road dust from Krowodrza (Cdeg 25). Results revealed that road dust samples were heavily contaminated with Cd, Cu, Zn, Mn, Co, Pb, Ni, Ba and Se, in amounts exceeding multiple times geochemical background values. The chemical speciation study using VI step sequential extraction, followed by assessing risk assessment code (RAC) revealed that elements in road dust are mostly bound with mobile and easy bioavailable fractions such as carbonates and exchangeable cations, with the exception for Cr and Cu being mostly associated and fixed with residual and organic matter fraction.
Go to article

Bibliography

  1. Adamiec, E., Jarosz-Krzemińska E., Wieszała R. (2016). Heavy metals from non-exhaust vehicle emissions in urban and motorway road dusts. Environmental monitoring and assessment 188, 1-11
  2. Adamiec, E. (2017a). Road Environments: Impact of Metals on Human Health in Heavily Congested Cities of Poland. Int J Environ Res Public Health 14(697), 1–17, DOI: 10.3390/ijerph14070697.
  3. Adamiec, E. (2017b). Traffic related metals as sources of urban environment pollution: a case study of Kraków, Poland. WIT Transactions on Ecology and the Environment 214, 87–89.
  4. Ali-Taleshi M. S., Moeinaddini M., Feiznia S., Squizzato S. (2020). Heavy Metal Pollution in Street Dust from Tehran in 2018: Metal Richness and Degree of Contamination Assessment. Journal of Envir. Health Engin. 7 (2) :179-194
  5. Ali-Taleshi, M.S., Feiznia, S., Bourliva, A., Squizzato, S. (2021). Road dusts-bound elements in a major metropolitan area, Tehran (Iran): Source tracking, pollution characteristics, ecological risks, spatiotemporal and geochemical patterns. Urban Climate, 39, 100933.
  6. Ali-Taleshi M.S., Squizzato S., Feiznia S., Carabalí G. (2022). From dust to the sources: The first quantitative assessment of the relative contributions of emissions sources to elements (toxic and non-toxic) in the urban roads of Tehran, Iran. Microchemical Journal, 181, 107817, DOI: 10.1016/j.microc.2022.107817.
  7. AQEG (2012) Fine Particle Matter (PM2.5) in the United Kingdom. Air Quality Expert Group. https://www.gov.uk/goverment/publications/fine-particulate-matter-pm2-5-in-the-uk.
  8. Ayrault S., Catinon M., Boudouma O., Bordier L., Agnello G., Reynaud S., Tissut M. 2013. Street Dust: Source and Sink of Heavy Metals To Urban Environment. E3S Web of Conferences, Vol 1, Proceedings of the 16th International Conference on Heavy Metals in the Environment, DOI:10.1051/e3sconf/2013012000.
  9. Brewer, P. 1997. M.Sc. Thesis: ‘Vehicles as a source of heavy metal contamination in the environment’. University of Reading, Berkshire, UK.
  10. EPA (2020). Smog, Soot, and Other Air Pollution from Transportation, https://www.epa.gov/transportation-air-pollution-and-climate-change/smog-soot-and-local-air-pollution
  11. Filgueiras, A. F., Lavilla, I., & Bendicho, C. (2002). Chemical sequential extraction for metal partitioning in environmental solid samples. Environmental Monitoring, 4, 823–857.
  12. Godłowska J., Kaszowski K, Kaszowski W. (2022). Application of the FAPPS system based
  13. on the CALPUFF model in short-term air pollution forecasting in Krakow and Lesser Poland. Archives of Environmental Protection. 48 (3), 109-117,
  14. DOI: 10.24425/aep.2022.142695
  15. Gunawardana C., Goonetilleke A., Egodawatta P., Dawes L., Kokot S. (2012). Source characterisation of road dust based on chemical and mineralogical composition. Chemosphere 87 (2), 163-170, DOI: 10.1016/j.chemosphere.2011.12.012.
  16. Hakanson L. (1980). An ecological risk index for aquatic pollution control: A sediment ecological approach. Water Res.14:975–1001.
  17. Holnicki P., Kałuszko A., Nahorski Z. (2021) Analysis of emission abatement scenario to improve urban air quality. Archives of Environmental Protection. 47(2) 103–114. DOI 10.24425/aep.2021.137282.
  18. Hu X., Zhang Y., Luo J., Wang T. & Lian H. (2011) Total concentrations and fractionation of heavy metals in road-deposited sediments collected from different land use zones in a large city (Nanjing), China, Chemical Speciation & Bioavailability, 23:1, 46-52, DOI: 10.3184/095422911X12971903458891
  19. Kowalik R., Gawdzik J., Bąk-Patyna P., Ramiączek P., Jurišević N. (2022), Risk Analysis of Heavy Metals Migration from Sewage Sludge of Wastewater Treatment Plants. Int J Environ Res Public Health, 19(18):11829. DOI: 10.3390/ijerph191811829. PMID: 36142102; PMCID: PMC9517408.
  20. Li J.L., He M., Han W., Gu Y.F. (2009). Availability and mobility of metal fractions related to the characteristics of the coastal soils developed from alluvial deposits. Environ Monit Assess 158:459–469, DOI: 10.1007/s10661-008-0596-8
  21. Lis J., Pasieczna A. (1995). Atlas geochemiczny Krakowa i okolic 1:100 000. Państwowy Instytut Geologiczny, Warszawa.
  22. Marin J., Colina M., Ledo H., Gardiner P. H. E. (2022). Ecological risk by potentially toxic elements in surface sediments of the Lake Maracaibo (Venezuela). Environ. Eng. Res, 27(4), 210232, DOI: 10.4491/eer.2021.232.
  23. Matabane D. L., Godeto T. W., Mampa R. M., Ambushe A. A. (2021). Sequential Extraction and Risk Assessment of Potentially Toxic Elements in River Sediments. Minerals, 11(8), 874, DOI: 10.3390/min11080874.
  24. Muschack W. (1990) Pollution of street run-off by traffic and local conditions. Science of The Total Environment, 93, 419-431, DOI: 10.1016/0048-9697(90)90133-f.
  25. Miazgowicz A., Krennhuber K., Lanzerstorfer C. (2020). Metals concentrations in road dust from high traffic and low traffic area: a size dependent comparison. Int. J. Environ. Sci. Technol. 17, 3365–3372, DOI:1007/s13762-020-02667-3.
  26. Michlaski R., Pecyna-Utylska P. (2022). Chemical characterization of bulk deposition in two cities of Upper Silesia (Zabrze, Bytom), Poland. Case study. Archives of Environmental Protection, 48(2),106–116, DOI 10.24425/aep.2022.140784.
  27. Perin G., Craboledda L., Lucchese M., Cirillo R., Dotta L., Zanetta M. L., Oro A. A. (1985). Heavy metal speciation in the sediments of northern Adriatic Sea. A new approach for environmental toxicity determination. In Heavy Metals in the Environment; LakkasT.D., Ed.; CEP Consultants: Edinburgh, Scotland; 2, 454–456.
  28. Sabouhi, M., Ali-Taleshi, M.S., Bourliva, A., Nejadkoorki, F., Squizzato, S. (2020).Insights into the anthropogenic load and occupational health risk of heavy metals in floor dust of selected workplaces in an industrial city of Iran.Science of The total Envir.744, 140862.Salomons W. , Förstner (1985). U. Metals in the Hydrocycle (Springer Verlag)
  29. Sutherland R. A., Tack F. M. G, Ziegler A.D. (2012) Road-deposited sediments in an urban environment: A first look at sequentially extracted element loads in grain size fractions. Journal of Hazardous Materials 225– 226, 54– 62.
  30. Świetlik, R., Trojanowska, M., Strzelecka, M., & Bocho-Janiszewska, A. (2015). Fractionation and mobility of Cu, Fe, Mn, Pb and Zn in the road dust retained on noise barriers along expressway. A potential tool for determining the effects of driving conditions on speciation of emitted particulate metals. Environmental Pollution, 196, 404–413
  31. Vlasov D., Ramirez O., Luhar A. (2022). Road dust in Urban and Industrial Environments: Sources, Pollutants, Impacts, and Management. Atmosphere, 13, 607, DOI: 10.3390/atmos13040607.
  32. Zhang, M. & Wang, H. (2009) Concentrations and chemical forms of potentially toxic metals in road-deposited sediments from different zones of Hangzhou, China. J. Environ. Sci., 21, 625 – 631.
Go to article

Authors and Affiliations

Ewa Adamiec
1
ORCID: ORCID
Elżbieta Jarosz-Krzemińska
1
ORCID: ORCID
Robert Brzoza-Woch
1
ORCID: ORCID
Mateusz Rzeszutek
1
ORCID: ORCID
Jakub Bartyzel
1
ORCID: ORCID
Tomasz Pełech-Pilichowski
1
ORCID: ORCID
Janusz Zyśk
1
  1. AGH – University of Science and Technology, Poland

This page uses 'cookies'. Learn more