PRACA ORYGINALNA
Composition and properties of soils developed within the ash disposal areas originated from peat combustion (Tyumen, Russia)
 
Więcej
Ukryj
1
University of Tyumen, Institute of Environmental and Agricultural Biology (X-BIO), 6 Volodarskogo St., 625003, Tyumen, Russia
2
University of Tyumen, Institute of Earth Sciences, 2 Osipenko st., 625002, Tyumen, Russia
3
Southern Federal University, Academy of Biology and Biotechnology in the name of D. I. Ivanovsky, 194/1 Stachki ave., 344090, Rostov-on-Don, Russia
4
National Research Tomsk State University, BIO-GEO-CLIM Laboratory, 36 Lenina st., 634050, Tomsk, Russia
5
Tomsk Oil and Gas Research and Design Institute (TomskNIPIneft), 72 Mira st., 634027, Tomsk, Russia
Data nadesłania: 18-06-2019
Data akceptacji: 24-01-2020
Data publikacji online: 19-05-2020
Data publikacji: 19-05-2020
 
Soil Sci. Ann., 2020, 71(1), 3–14
 
SŁOWA KLUCZOWE
STRESZCZENIE ARTYKUŁU
Electrical power generation by burning fossil fuels leads to the formation of a significant amount of industrial waste that is often stored at ash disposal sites, which leads to a negative impact on the environment. Therefore, studies devoted to soil formation within such areas are rather sufficient for planning their reclamation. The proposed paper presents the results of a study of soil development at the inactive self-grown ash disposal area of Tyumen combined heat and power (CHP-1) plant (Western Siberia, Russia), formed due to the combustion of peat from the local Tarman deposit. Four soil pits representing different areas of ash dumps with grassy and woody vegetation were selected for detailed studies. The laboratory analyses included chemical, mineralogical and microscopic studies. The obtained results showed that the studied soils are characterised by a poorly developed humus horizon and strong stratification of the ash parent material and can be classified as Spolic Technosols. The studied technogenic soils are characterised by neutral and alkaline pH values, high LOI values, diversity of pedogenic carbonates and strong heterogeneity of the profile, due to the alteration of layers composed of fly and bottom ash material. These peculiarities of soils are related to properties of peat ashes, technology of peat consumption, and the intensity of weathering under cold continental climate conditions. The main indicators of pedogenic processes are the formation of humus horizons, the decrease in alkalinity in the upper part of the profile, disturbance of the primary stratification of the parent material, and the formation of pedogenic carbonates. It is possible to suppose further evolution of studied soils towards Andosol-like soils.
 
REFERENCJE (38)
1.
Ahmaruzzaman, M., 2010. A review on the utilization of fly ash. Progress in Energy and Combustion Science 36(3), 327–363. https://doi.org/10.1016/j.pecs....
 
2.
Blissett, R., Rowson, N., 2012. A review of the multicomponent utilization of coal fly ash. Fuel 97, 1–23. https://doi.org/10.1016/j.fuel....
 
3.
Chygov, B.E., Pariguina, N.G., Suslov, A.V., Atkina, L.I., 2007. The inventory of a ash dump Tumen and methods of a laying out of a park in it. Lesnoy vestnik (Forestry Bulletin) 8(57), 85–90 (in Russian with English abstract).
 
4.
Delitzin, L.M., Ezhova, N.N., Vlasov, A.S., Sudareva, S.V., 2012. Ash disposal areas of coal’s power stations as the threat to environmental safety. Èkologiâ promyšlennogo proizvodstva 4, 15–26 (in Russian with English abstract).
 
5.
FAO, 2006. Guidelines for soil description. Fourth edition. FAO, Rome.
 
6.
Grekhova, I.V., 2005. Characteristics on lowland peats of the Transuralian Region and their use я soil fertility recovery. Doctoral (Biol.) Dissertation. Tyumen. (in Russian).
 
7.
Haynes, R.J., 2009. Reclamation and revegetation of fly ash disposal sites – challenges and research needs. Journal of Environmental Management 90(1), 43–53. https://doi.org/10.1016/j.jenv....
 
8.
IUSS Working Group WRB, 2015. World Reference Base of Soil Resources 2014, update 2015 International Soil Classification System for Naming Soils and Creating Legends for Soil Maps. World Soil Resources Reports no. 106. FAO, Rome.
 
9.
Kim, J.K., Lee, H.D., Kim, H.S., Park, H.Y., Kim, S.C., 2014. Combustion possibility of low rank Russian peat as a blended fuel of pulverized coal fired power plant. Journal of Industrial and Engineering Chemistry 20(4), 1752–1760. https://doi.org/10.1016/j.jiec....
 
10.
Konstantinov, A.O., Novoselov, A.A., Loiko, S.V., 2018. Special features of soil development within overgrowing fly ash deposit sites of the solid fuel power plant. Tomsk State University Journal of Biology 43, 6–24 (in Russian with English abstract). http://dx.doi.org/10.17223/199....
 
11.
Kostić, O., Jarić, S., Gajić, G., Pavlović, D., Pavlović, M., Mitrović, M., Pavlović, P., 2018. Pedological properties and ecological implications of substrates derived 3 and 11 years after the revegetation of lignite fly ash disposal sites in Serbia. CATENA 163, 78–88. https://doi.org/10.1016/j.cate....
 
12.
Krechetov, P., Kostin, A., Chernitsov, O., Terskaya, E., 2019. Environmental changes due to wet disposal of wastes from coal-fired heat power plant: A case study from the Tula Region, Central Russia. Applied Geochemistry 105, 105–113. https://doi.org/10.1016/j.apge....
 
13.
Kurlenya, M.V., Cheskidov, V.I., 2001. Prospects of coal mining in Siberia. Journal of Mining Science 37(3), 319–322. https://doi.org/10.1023/A:1013....
 
14.
Li, J., Zhuang, X., Querol, X., Font, O., Moreno, N., 2018. A review on the applications of coal combustion products in China. International Geology Review 60(5–6), 671–716. https://doi.org/10.1080/002068....
 
15.
Makarov, A.A., Voropai, N.I., Saenko, V.V., Saneev, B.G., 2010. Regional features of fuel and energy complex. [In:] Yanovsky, A.B. et al. (Eds.), Russia’s energy: look into the future”. Materials for the energy strategy of Russia 2030. Publishing House “Energiya”, Moscow, 435–460 (in Russian).
 
16.
Makhnev, A.K., Makhneva, N.E., 2010. Landscape-ecological and population aspects of the strategy of restoration of disturbed lands. Contemporary Problems of Ecology 3(3), 318–322. http://dx.doi.org/10.1134/S199....
 
17.
Pandey, V.C., 2015. Assisted phytoremediation of fly ash dumps through naturally colonized plants. Ecological Engineering 82, 1–5. http://dx.doi.org/10.1016/j.ec....
 
18.
Rakov E.A, Chibrik T.S., 2009. On the problem of flora formation in industrially disturbed land areas. Russian Journal of Ecology 6(40), 448. http://dx.doi.org/10.1134/S106....
 
19.
Soil Survey Staff, 2014. Soil Survey Field and Laboratory Methods Manual. Soil Survey Investigations Report No. 51. Version 2. U.S. Department of Agriculture, Natural Resources Conservation Service.
 
20.
Sokol, E.V., Kalugin, V.M., Nigmatulina, E.N., Volkova, N.I., Frenkel, A.E., Maksimova, N.V., 2002. Ferrospheres from fly ashes of Chelyabinsk coals: chemical composition, morphology and formation conditions. Fuel 81(7), 867–876. http://dx.doi.org/10.1016/S001....
 
21.
Sokolov, D.A., Kulizhskii, S.P., Lim, A.G., Gurkova, E.A., Nechaeva, T.V., Merzlyakov, O.E., 2017. Comparative evaluation of methods for determination of pedogenic organic carbon in coal-bearing soils. Tomsk State University Journal of Biology (39), 29–43 (in Russian with English abstract). https://doi.org/10.17223/19988....
 
22.
Suslova, N.G., Atkina, L.I., Chizhov, B.Ye, Agafonov, Ye.Yu., 2008. Construction of recreational objects on the territory of ash-heaps in the town of Tyumen. News of the Orenburg State Agrarian University 2(18), 219–222 (in Russian with English abstract).
 
23.
Tcvetkov, P.S., 2017. The history, present status and future prospects of the Russian fuel peat industry. Mires and Peat 19(14), 1–12. http://doi.org/10.19189/MaP.20....
 
24.
Uzarowicz, Ł., Kwasowski, W., Śpiewak, O., Świtoniak, M., 2018a. Indicators of pedogenesis of Technosol developed in an ash settling pond at the Bełchatów thermal power station (central Poland). Soil Science Annual 69(1), 49–59. https://doi.org/10.2478/ssa-20....
 
25.
Uzarowicz, Ł., Skiba, M., Leue, M., Zagórski, Z., Gąsiński, A., Trzciński, J., 2018b. Technogenic soils (Technosols) developed from fly ash and bottom ash from thermal power stations combusting bituminous coal and lignite. Part II. Mineral transformations and soil evolution. CATENA 162, 255–269. https://doi.org/10.1016/j.cate....
 
26.
Uzarowicz, Ł., Zagórski, Z., 2015. Mineralogy and chemical composition of technogenic soils (Technosols) developed from fly ash and bottom ash from selected thermal power stations in Poland. Soil Science Annual 66(2), 82–91. https://doi.org/10.1515/ssa-20....
 
27.
Uzarowicz, Ł., Zagórski, Z., Mendak, E., Bartmiński, P., Szara, E., Kondras, M., Oktaba, L., Turek, A., Rogoziński, R., 2017. Technogenic soils (Technosols) developed from fly ash and bottom ash from thermal power stations combusting bituminous coal and lignite. Part I. Properties, classification, and indicators of early pedogenesis. CATENA 157, 75–89. https://doi.org/10.1016/j.cate....
 
28.
Vorobyova, L.A., 2006. Theory and practice chemical analysis of soils. GEOS, Moscow. (in Russian with English abstract).
 
29.
Warren, C.J., Dudas, M.J., 1984. Weathering processes in relation to leachate properties of alkaline fly ash. Journal of Environmental Quality 13(4), 530–538. http://dx.doi.org/10.2134/jeq1....
 
30.
Warren, C.J., Dudas, M.J., 1985. Formation of secondary minerals in artificially weathered fly ash. Journal of Environmental Quality 14(3), 405–410. http://dx.doi.org/10.2134/jeq1....
 
31.
Weber, J., Strączyńska, S., Kocowicz, A., Gilewska, M., Bogacz, A., Gwiżdż, M., Debicka, M., 2015. Properties of soil materials derived from fly ash 11years after revegetation of post-mining excavation. CATENA 133, 250–254. https://doi.org/10.1016/j.cate....
 
32.
Yao, Z., Ji, X., Sarker, P., Tang, J., Ge, L., Xia, M., Xi, Y., 2015. A comprehensive review on the applications of coal fly ash. Earth-Science Reviews 141, 105–121. https://doi.org/10.1016/j.ears....
 
33.
Yudovich, Ya.E., Ketris, M.P. 2005. Toxic trace elements in Coal. UrB RAS, Ekaterinburg. (in Russian with English abstract).
 
34.
Zen’kov, I.V., Nefedov, B.N., Baradulin, I.M., Kiryushina, E.V., Vokin, V.N., 2015. Environmental problems during the maintenance of ash-and-slag storages in the fuel-energy complex of Russia. Ekologia i promyshlennost Rossii (Ecology and Industry of Russia) 19(2), 24–28 (in Russian with English abstract). https://doi.org/10.18412/1816-....
 
35.
Zikeli, S., Jahn, R., Kastler, M., 2002. Initial soil development in lignite ash landfills and settling ponds in Saxony-Anhalt, Germany. Journal of Plant Nutrition and Soil Science 165(4), 530–536. https://doi.org/10.1002/1522-2...<530::AID-JPLN530>3.0.CO;2-J.
 
36.
Zikeli, S., Kastler, M., Jahn, R., 2004. Cation exchange properties of soils derived from lignite ashes. Journal of Plant Nutrition and Soil Science 167(4), 439–448. https://doi.org/10.1002/jpln.2....
 
37.
Zikeli, S., Kastler, M., Jahn, R., 2005. Classification of anthrosols with vitric/andic properties derived from lignite ash. Geoderma 124(3–4), 253–265. https://doi.org/10.1016/j.geod....
 
38.
 
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