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Toxic elements and persistent organic pollutants derived from industrial emissions in agricultural soils of the Northern Czech Republic

  • Soils and Sediments in Urban and Mining Areas
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Abstract

Purpose

This study reports on the surface distribution of toxic elements (TEs; As, Be, and Cd) and persistent organic pollutants [POPs; e.g., polycyclic aromatic hydrocarbons (PAHs)] in agricultural soils affected by mining and heavy industry from the industrial regions of North Bohemia and North Moravia. In this study, these regions are considered as test regions to study the impacts of heavy industry emissions on agricultural soils.

Materials and methods

From 2000 to 2010, agricultural soils were sampled and their physicochemical properties and contamination levels of TEs (As, Be, and Cd) and POPs (PAHs) determined. The pseudototal content (from Aqua regia extracts) and plant available fraction (from 1 M NH4NO3 extracts) of TEs, as well as the total PAH content in humic horizons of arable soils and grasslands, were analyzed. The surface spatial variability of these contaminants was evaluated using the kriging method. Threshold values for the probability estimation were adapted from the limit values provided by newly proposed Czech legislation.

Results and discussion

We show that the soil environments of the study area are polluted by anthropogenic material directly connected to historical mining and industrial activities, including lignite mining in North Bohemia and hard coal mining and heavy industry in North Moravia. The increased As contents in the soils contribute to the most important environmental problems in North Bohemia, where anthropogenic and geogenic sources of As interact. In North Moravia, anthropogenic pollution linked to coal combustion and metallurgy has increased Cd and PAH contents in agricultural soils. However, concentrations of these pollutants do not exceed limits for food safety in soils from these regions.

Conclusions

This study shows that agriculture can coexist in regions impacted by heavy industry emissions, like the study regions documented here. Such activity requires that a suitable methodology is implemented to evaluate soil contamination and a risk assessment is carried out. In addition, suitable precautions should be undertaken in areas close to industry, such as grassing over contaminated arable lands to reduce wind erosion.

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References

  • ČEZ Group (2012) Coal-fired power plants in CR. http://www.cez.cz/en/power-plants-and-environment/coal-fired-power-plants/cr/chvaletice.html

  • CHMI (2009) Czech Hydrometeorological Institute. http://portal.chmi.cz/files/portal

  • ČSN EN 13346 (2001) Characterization of sludges — determination of trace elements and phosphorus — aqua regia extraction methods. Czech Normalisation Institute, Prague

    Google Scholar 

  • ČSN ISO 10390 (1996) Soil quality — determination of pH. Czech Normalisation Institute, Prague

    Google Scholar 

  • DIN ISO 19730 (2008) Soil quality — extraction of trace elements from soil using ammonium nitrate solution. Deutsches Institut für Normung E.V Standards, Berlin

    Google Scholar 

  • Dostál M, Pastorková A, Rychlík S, Rychlíková E, Schallerová E, Švecová V, Šram RJ (2013a) Comparison of child morbidity in regions of Ostrava, Czech Republic, with different degrees of pollution: a retrospective cohort study. Environ Health Glob 12:74

    Article  Google Scholar 

  • Dostál SM, Arnold LL, Beck BD, Lewis AS, Eldan M (2013b) Evaluation of the carcinogenity of inorganic arsenic. Crit Rev Toxicol 43:711–752

    Article  Google Scholar 

  • Drahota P, Filippi M, Ettler V, Rohovec J, Mihaljevič M, Šebek O (2012) Natural attenuation of As in soils near a highly contaminated historical mine waste dump. Sci Total Environ 414:546–555

    Article  CAS  Google Scholar 

  • EPA Method 8082A (2000) Polychlorinated biphenyls (PCBs) by gas chromatography. US Environmental Protection Agency, USA

    Google Scholar 

  • EPA Method 8260B (1996) Volatile organic compounds by gas chromatography/mass spektrometry (GC/MS). US Environmental Protection Agency, USA

    Google Scholar 

  • Food and Agriculture Organization of the United Nations Rome (2014) World reference base for soil resources 2014. International soil classification system for naming soils and creating legends for soil maps. FAO, Rome

    Google Scholar 

  • Galušková I, Mihaljevič M, Boruvka L, Drabek O, Fruehauf M, Nemecek K. (2014) Lead isotope composition and risk elements ditribution in urban soils of historically different cities Ostrava and Prague, the Czech Republic. J Geochem Explor 147:215–221

  • Goovaerts P (1997) Geostatistics for natural resources evaluation. Oxford University Press, New York, pp 259–368

    Google Scholar 

  • ISO 14235 (1998) Soil quality — determination of organic carbon by sulfochromic oxidation. International Organisation for Standardation, Geneva

    Google Scholar 

  • Jahn M, Wolke R, Sandig B (2013) Detection of odor sources and high concentrations of pollutants in Ore Mountains by modeling of air mass path. Meteorol Z 22:213–220

    Article  Google Scholar 

  • Juang KW, Lee DY (1998) Simple indicator kriging for estimating the probability of incorrectly delineating hazardous areas in a contaminated site. Environ Sci Technol 32:2487–2493

    Article  CAS  Google Scholar 

  • Kohel J (1994) Exploitation of the loess-derived soils for the reclamation of lands damaged by mining activity in the Nord Bohemian brown-coal mining district. Rostl Výr 40:63–68

    Google Scholar 

  • Kozák J, Němeček J, Borůvka L, Kodešová R, Janků J, Jacko K, Hladík J (2010) Soil Atlas of the Czech Republic. Czech University of Life Sciences, Typus Pro Praha, Prague, pp 62–147

  • Kukučka P, Klánová J, Sáňka M, Holoubek I (2009) Soil burdens of persistent organic pollutants — their levels, fate and risk: Part II. Are there any trends in PCDDs/Fs levels in mountain soils? Environ Pollut 157:3255–3263

    Article  Google Scholar 

  • LABO (2003) Background values of inorganic and organic substances in the soils, 3rd revised and enlarged edn. Bund/Länder-Arbeitsgemeinschaft Bodenschuts, LABO, Berlin

  • Ministry of Agriculture of Czech Republic (2012) Soil: annual report of Ministry of Agriculture of CR. Ministry of Agriculture of CR, Prague

    Google Scholar 

  • Moreno-Jimenez E, Manzano R, Esteban E, Penalosa J (2010) The fate of arsenic in soils adjacent to an old mine site (Bustarviejo, Spain): mobility and transfer to native flora. J Soils Sediments 10:301–312

    Article  CAS  Google Scholar 

  • Němeček J, Podlešáková E, Pastuszková M (1996a) Proposal of soil contamination limits for persistent organic xenobiotic substances in the Czech Republic. Rostl Výr 42:49–53

    Google Scholar 

  • Němeček J, Podlešáková E, Vácha R (1996b) Geochemical and anthropogenic load of soils. Rostl Výr 42:535–541

    Google Scholar 

  • OKD (2012) New World Resources Plc. member http://www.okd.cz/cs/tezime-uhli/ostravsko-karvinska-uhelna-panev

  • Pena-Fernandez A, Gonzales-Munoz MJ, Lobo-Bedmar MC (2014) Establishing the importance of human health risk assessment for metals and metalloids in urban environments. Environ Int 72:176–185

    Article  CAS  Google Scholar 

  • Podlešáková E (1992) The pollution of atmosphere. In: Čihalík J (ed) The influence of agriculture on environment. Ministry of Agriculture of Czech Republic. Brazda Press, Prague, pp 32–37

    Google Scholar 

  • Podlešáková E, Němeček J, Hálová G (1994a) Proposal of soil contamination limits for potentially hazardous trace elements in the Czech Republic. Rostl Výr 42:119–125

    Google Scholar 

  • Podlešáková E, Němeček J, Vácha R (1994b) Contamination of soils in North-Bohemian region by hazardous elements. Rostl Výr 40:123–130

    Google Scholar 

  • Podlešáková E, Němeček J, Vácha R (2002) Critical values of trace elements in soils from the viewpoint of the transfer pathway soil–plant. Rostl Výr 48:193–202

    Google Scholar 

  • Rössnerová A, Špátová M, Rössner P, Nováková Z, Solanský I, Šram RJ (2011) Factors affecting the frequency of micronuclei in asthmatic and healthy children from Ostrava. Mutat Res-Fundam Mol Mech 708:44–49

    Article  Google Scholar 

  • Šafářová M, Řehoř M (2006) Trace elements in coal and non-coal sediments from the North Bohemian brown coal basin and in soils from recultivated localities. Chem List 100:462–466

    Google Scholar 

  • Sáňka M, Němeček J, Podlešáková E, Vácha R, Beneš S (2002) The elaboration of limit values of concentrations of risk elements and organic persistent compounds in the soil and their uptake by plants from the viewpoint of the protection of plant production quantity and quality. The report of the Ministry of Environment of the Czech Republic. Ministry of the Environment of CR, Prague

  • Skála J, Vácha R, Čechmánková J (2011) Evaluation of arsenic occurrence in agricultural soils of the Bohemian Forest Region. Silva Gabreta 17:55–67

    Google Scholar 

  • Šram RJ, Brdička R, Dostál M, Dostálová M, Gmuender H, Krejčík Z, Líbalová H, Milcová A, Pastorková A, Rössner P, Rössnerová A, Schmuczerová J, Špátová M, Topinka J, Votavová H (2012) Hot spot B(a)P exposure in the Czech Republic. Environ Mol Mutagen 53:S23

    Google Scholar 

  • Šram RJ, Binková B, Dostál M, Merkerová-Dostálová M, Líbalová H, Milcová A, Rössner P, Rössnerová A, Schmuczerová J, Švecová V, Topinka J, Votavová H (2013) Health impact of air pollution to children. Int J Hyg Environ Health 26:533–540

    Google Scholar 

  • Švecová V, Topinka J, Solanský I, Rössner P, Šram RJ (2013) Personal exposure to carcinogenic polycyclic aromatic hydrocarbons in the Czech Republic. J Expo Sci Environ Epidemiol 23:350–355

    Article  Google Scholar 

  • TNV 75 8055 (2004) Sludge characterisation — the analyse of selected polycyclic aromatic hydrocarbons (PAHs) by HPLC with fluorescence detection method. Czech Normalisation Institute, Prague

    Google Scholar 

  • US EPA (2002) Suplemental guidance for developing soil screening levels for superfund sites. EPA Publication OSWER 9355.4.24. Office Solid Waste and Emergency Response, Washington

    Google Scholar 

  • Vácha R, Němeček J, Podlešáková E (2002) Geochemical and anthropogenic soil loads by potentially risky elements. Rostl Výr 48:441–447

    Google Scholar 

  • Vácha R, Macurová H, Skála J, Havelková M, Čechmánková J, Horváthová V (2008) Possibilities of some methods for risk assessment of arsenic load in soils. Plant Soil Environ 54:279–287

    Google Scholar 

  • Vácha R, Sáňka M, Hauptman I, Zimová M, Čechmánková J (2014) Assessment of limit values of risk elements and persistent organic pollutants in soil for Czech legislation. Plant Soil Environ 60:191–197

    Google Scholar 

  • Van den Berg M, Birnbaum LS, Denison M, De Vito M, Farland W, Feeley M, Fiedler H, Hakansson H, Hanberg A, Haws L, Rose M, Safe S, Schrenk D, Tohyama C, Tritscher A, Tuomisto J, Tysklind J, Walker N, Peterson RE (2006) The 2005 World Health Organization re-evaluation of human and mammalian toxic equivalency factors for dioxins and dioxin-like compounds. Toxicol Sci 93:223–241

    Article  Google Scholar 

  • Vegter JJ (1993) The development of soil protection policy and experiences with soil clean-up activities in the Netherlands. Soil pollution, investigation methods, risk assessment. H.C. Van Hall Institute, Groningen

    Google Scholar 

  • Wang SZ, Zhao ZH, Xia B, Qiu H, Morel JL, Qiu RL (2014) A fuzzy-based methodology for an aggregative environmental risk assessment of restored soil. Pedosphere 24:220–231

    Article  CAS  Google Scholar 

  • Zbíral J, Honsa I, Malý S, Čižmár D (2004) Soil analysis II. Central Institute for Supervising and Testing in Agriculture, Brno

    Google Scholar 

  • Zimová M, Ďuriš M, Spěváčková V, Melicherčík J, Lepší P, Tesařová B, Knotek P, Kubínov R, Ronene Y (2001) Health risk of urban soils contaminated by heavy metals. Int J Occup Med Environ 14:231–234

    Google Scholar 

Download references

Acknowledgments

This study was funded by the Ministry of Agriculture of the Czech Republic under Grant No. MZE0002704902.

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Correspondence to Radim Vácha.

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Responsible editor: Jean Louis Morel

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Vácha, R., Skála, J., Čechmánková, J. et al. Toxic elements and persistent organic pollutants derived from industrial emissions in agricultural soils of the Northern Czech Republic. J Soils Sediments 15, 1813–1824 (2015). https://doi.org/10.1007/s11368-015-1120-8

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  • DOI: https://doi.org/10.1007/s11368-015-1120-8

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