Abstract
The present study focuses on the fate of polycyclic aromatic hydrocarbons (PAHs) in soils amended with oil shale ash (OSA). Leachability studies to assess the release of PAHs to the environment are essential before the application of OSA in agriculture. A quantitative estimation of the leaching of PAHs from two types of soil and two types of OSA was undertaken in this study. Two leaching approaches were chosen: (1) a traditional one step leaching scheme and (2) a leaching scheme with pretreatment, i.e.., incubation of the material in wet conditions imitating the field conditions, followed by a traditional leaching procedure keeping the total amount of water constant. The total amount of PAHs leached from soil/OSA mixtures was in the range of 15 to 48 μg/kg. The amount of total PAHs leached was higher for the incubation method, compared to the traditional leaching method, particularly for Podzolic Gleysols soil. This suggests that for the incubation method, the content of organic matter and clay minerals of the soil influence the fate of PAHs more strongly compared to the traditional leaching scheme. The amount of PAHs leached from OSA samples is higher than from soil/OSA mixtures, which suggests soils to inhibit the release of PAHs. Calculated amount of PAHs from experimental soil and OSA leaching experiments differed considerably from real values. Thus, it is not possible to estimate the amount of PAHs leached from soil/OSA mixtures based on the knowledge of the amount of PAHs leached from soil and OSA samples separately.
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References
Adamson J, Irha N, Adamson K, Steinnes E, Kirso U (2010) Effect of oil shale ash application on leaching behavior of arable soils: an experimental study. Oil Shale 27(3):250–257
Ahmaruzzaman M (2010) A review on the utilization of fly ash. Prog Energ Combust 36(3):327–363
Alumaa P, Kirso U, Petersell V, Steinnes E (2001) Sorption of toxic heavy metals to soil. Int J Hyg Envir Heal 204(1–2):375–376
Bauert H, Kattai V (1997) Kukersite oil shale. In: Raukas A, Teedumae A (eds) Geology and mineral resources of Estonia. Estonian Academy Publishers, Tallinn, pp. 313–327
Beesley L, Moreno-Jiménez E, Gomez-Eyles JL (2010) Effects of biochar and greenwaste compost amendments on mobility, bioavailability and toxicity of inorganic and organic contaminants in a multi-element polluted soil. Environ Pollut 158:2282–2287
Biache C, Kouadio O, Lorgeoux C, Faure P (2014) Impact of clay mineral on air oxidation of PAH-contaminated soils. Environ Sci Pollut R 21:11017–11026. doi:10.1007/s11356-014-2966-9
Bityukova L, Mõtlep R, Kirsimäe K (2010) Composition of oil shale ashes from pulverized firing and circulating fluidized-bed boiler in Narva thermal power plants, Estonia. Oil Shale 27:339–353
Blissett RS, Rowson NA (2012) A review of the multi-component utilisation of coal fly ash. Fuel 97:1–23
Chung N, Alexander M (2002) Effect of soil properties on bioavailability and extractability of phenanthrene and atrazine sequestered in soil. Chemosphere 48:109–115
Cornelissen G, Gustafsson Ö, Bucheli TD, Jonker MT, Koelmans AA, van Noort PC (2005) Extensive sorption of organic compounds to black carbon, coal, and kerogen in sediments and soils: mechanisms and consequences for distribution, bioaccumulation, and biodegradation. Environ Sci Technol 39:6881–6895
Cornelissen G, Breedveld GD, Kalaitzidis S, Christanis K, Kibsgaard A, Oen AM (2006) Strong sorption of native PAHs to pyrogenic and unburned carbonaceous geosorbents in sediments. Environ Sci Technol 40:1197–1203
Directive 2013 /39/EU of the European Parliament and of the Council of 12 August 2013 amending Directives 2000/60/EC and 2008/105/EC as regards priority substances in the field of water policy http://eur-lex.europa.eu/legal-content/EN/TXT/?uri=celex:32013L0039
Ferreira C, Ribeiro A, Ottosen L (2003) Possible applications for municipal solid waste fly ash. J Hazard Mater 96:201–216
Garg RN, Pathak H, Das DK, et al. (2005) Use of flyash and biogas slurry for improving wheat yield and physical properties of soil. Environ Monit Assess 107:1–9
Ghosh U, Talley JW, Luthy RG (2001) Particle-scale investigation of PAH desorption kinetics and thermodynamics from sediment. Environ Sci Technol 35:3468–3475
Irha N, Reinik J, Jefimova J, Koroljova A, Raado L-M, Hain T, Uibu M, Kuusik R (2015) PAHs in leachates from thermal power plant wastes and ash-based construction materials. Environ Sci Pollut R 22:11877–11889
Jala S, Goyal D (2006) Fly ash as a soil ameliorant for improving crop production—a review. Bioresource Technol 97(9):1136–1147
Kalbe U, Berger W, Eckardt J, Simon F-G (2008) Evaluation of leaching and extraction procedures for soil and waste. Waste Manag 28:1027–1038
Kene DR, Lanjewar SA, Ingole BM, et al. (1991) Effect of application of fly ash on physico-chemical properties of soils. The International Journal of Soil and Crop Sciences 1(1):11–18
Kikas VH (1988) Mineral matter of kukersite oil shale and its utilization. Oil Shale 5(1):15–27 in Russian
Kirso U, Alumaa P, Irha N, Petersell V, Teinemaa E, Slet J, Steinnes E (2000) Sorption of pyrene to two Estonian soils. Polycycl Aromat Comp 20:55–66
Kirso U, Irha N (1999) Leaching of pyrene from fly ash and mineral particles. Polycycl Aromat Comp 14:161–168
Kirso U, Laja M, Urb G (2005) Polycyclic aromatic hydrocarbons (PAH) in ash fractions of oil shale combustion: fluidized bed vers pulverized fuel process. Oil Shale 22(4):537–545
Kollist-Siigur K, Nielsen T, Gron C, Hansen PE, Helwig C, Jonassen KEN, Jorgensen O, Kirso U (2001) Sorption of polycyclic aromatic compounds to humic and fulvic acid HPLC column materials. J Environ Qual 30:526–537. doi:10.2134/jeq2001.302526x
Krüger O, Kalbe U, Berger W, Simon F-G, López Meza S (2012) Leaching experiments on the release of heavy metals and PAH from soil and waste materials. J Hazard Mater 207–208:51–55
Kuusik R, Uibo M, Kirsimäe K (2005) Characterization of oil shale ashes formed at industrial-scale CFBC boilers. Oil Shale 22(4S):407–420
Laja M, Urb G, Irha N, Reinik J, Kirso U (2005) Leaching behavior of ash fractions from oil shale combustion by fluidized bed and pulverized firing processes. Oil Shale 22:453
Mackay D, Shiu WY, Ma KC, Lee SC (2006) Illustrated handbook of physical-chemical properties and environmental fate for organic chemicals Vol. 1, 2nd edn. CRC Press, Boca Raton.
Maliszewska-Kordybach B, Smreczek B, Klimkowicz-Pawlas A, Terelak H (2008) Monitoring of the total content of polycyclic aromatic hydrocarbons (PAHs) in arable soils in Poland. Chemosphere 73(8):1284–1291
Melnyk A, Dettlaff A, Kuklińska K, Namieśnik J, Wolska L (2015) Concentration and sources of polycyclic aromatic hydrocarbons (PAHs) and polychlorinated biphenyls (PCBs) in surface soil near a municipal solid waste (MSW) landfill. Sci Total Environ 530–531:18–27
Nieman JKC, Sims RC, Sims JL, Sorensen DL, Mclean JE, Rice JA (1999) Pyrene bound residue evaluation using MIBK fractionation method for creosote-contaminated soil. Environ Sci Technol 33:776–781
Northcott GL, Jones KC (2001) Partitioning, extractability, and formation of nonextractable PAH residues in soil. 1. Compound differences in aging and sequestration. Environ Sci Technol 35(6):1103–1110
Õispuu L, Rootamm R (1994) Medium contents of hazardous compounds in oil-shale and fly ash. Transactions of Tallinn Techn Univ 739:70–85 in Estonian
Onken BM, Traina SJ (1996) The sorption of pyrene and anthracene to humic acid-mineral complexes: effect of fractional organic carbon content. J Environ Qual 26:126–132
Ots A (2004) Oil shale combustion technology. Oil Shale 21:149–160
Petersell V, Mõttus K, Täht K, Unt L (1996) Bulletin of the geochemical monitoring of soil 1992–1994. Geological Survey of Estonia. Department of Environmental Geology, Tallinn
Piatt JJ, Brusseau ML (1998) Rate-limited sorption of hydrophobic organic compounds by soils with well-characterized organic matter. Environ Sci Technol 32:1604–1608
Ram LC, Masto RE (2014) Fly ash for soil amelioration: a review on the influence of ash blending with inorganic and organic amendments. Earth-Sci Rev 128:52–74
Reinik J, Heinmaa I, Mikkola J-P, Kirso U (2007) Hydrothermal alkaline treatment of oil shale ash for synthesis of tobermorites. Fuel 86:669–676
Saether OM, Banks D, Kirso U, Bityukova L, Sorlie JE (2004) The chemistry and mineralogy of waste from retorting and combustion of oil shale. In: Gieré R and Stille P (ed.) energy. Waste and the Environ: a Geochemical Perspective 236:263–284
Sajawan KS, Paramasivam S, Alva AK, Adriano DC, Hooda PS (2003) Assessing the feasibility of land application of fly ash, sewage sludge and their mixtures. Adv Environ Res 8(1):77–91
Shaheen SM, Hooda PS, Christos DT (2014) Opportunities and challenges in the use of coal fly ash for soil improvements—a review. J Environ Manag 145:249–267
Strizhakova YA, Usova TV (2007) Environmental problems of oil shale processing industry. Solid Fuel Chem 41(3):174–178
Tang J, Alexander M (1999) Mild extractability and bioavailability of polycyclic aromatic hydrocarbons in soil. Environ Toxicol Chem 18:2711–2714
Trapido M (1999) Polycyclic aromatic hydrocarbons in Estonian soil: contamination and profiles. Environ Pollut 105:67–74
Turbas E (1992) Use of oil-shale ashes as a lime fertilizer in Estonia. Oil Shale 9(4):301–309 in Russian
Uibu M, Somelar P, Raado L-M, Irha N, Hain T, Koroljova A, Kuusik R (2016) Oil shale ash based backfilling concrete—strength development, mineral transformations and leachability. Constr Build Mater 102:620–630
Ukwattage NL, Ranjith PG, Bouazza M (2013) The use of coal combustion fly ash as a soil amendment in agricultural lands (with comments on its potential to improve food security and sequester carbon). Fuel 109:400–408
Verma SK, Masto RE, Shalini Gautam DP, Choudhury LC, Ram SK, Maiti S (2015) Investigations on PAHs and trace elements in coal and its combustion residues from a power plant. Fuel 162:138–147
Wang R, Li G, Zhang J (2015) Variations of emission characterization of PAHs emitted from different utility boilers of coal-fired power plants and risk assessment related to atmospheric PAHs. Sci Total Environ 538:180–190
Wehrer M, Totsche KU (2009) Difference in PAH release processes from tar-oil contaminated soil materials with similar contamination history. Chem Erde 69(S2):109–124
Weissenfels WD, Klewer H-J, Langhoff J (1992) Adsorption of polycyclic aromatic hydrocarbons (PAHs) by soil particles: influence on biodegradability and biotoxicity. Appl Microbiol Biot 36:689–696
Yang Y, Ligouis B, Pies C, Grathwohl P, Hofmann T (2008) Occurrence of coal and coal-derived particle-bound polycyclic aromatic hydrocarbons (PAHs) in a river floodplain soil. Environ Pollut 151:121–129
Yang Y, Zhang N, Xue M, Tao S (2010) Impact of soil organic matter on the distribution of polycyclic aromatic hydrocarbons (PAHs) in soils. Environ Pollut 158:2170–2174
Yao ZT, Ji XS, Sarker PK, Tang JH, Ge LQ, Xia MS, Xi YQ (2015) A comprehensive review on the applications of coal fly ash. Earth-Sci Rev 141:105–121
Zhang Z, Zhang L, Li A (2015) Development of a sintering process for recycling oil shale fly ash and municipal solid waste incineration bottom ash into glass ceramic composite. Waste Manag 38:185–193
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The financial support of the Archimedes foundation (project 3.2.0501.10.0002) and Institutional Research Funding (IUT23-7) are gratefully acknowledged.
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Jefimova, J., Adamson, J., Reinik, J. et al. Leaching of PAHs from agricultural soils treated with oil shale combustion ash: an experimental study. Environ Sci Pollut Res 23, 20862–20870 (2016). https://doi.org/10.1007/s11356-016-7300-2
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DOI: https://doi.org/10.1007/s11356-016-7300-2