ECOLOGY
Original Paper
UDC 622.85:622.882:622.7.002.68:622.33(571.17) © I.S. Semina, V.A. Androkhanov, 2021
ISSN 0041-5790 (Print) • ISSN 2412-8333 (Online) • Ugol’ – Russian Coal Journal, 2021, № 6, pp. 74-79
DOI: http://dx.doi.org/10.18796/0041-5790-2022-6-74-79
Title
Geochemical background in semimature soils made on reclaimed sites using coal waste
Authors
Semina I.S.1 , Androkhanov V.A.2
1Siberian State Industrial University, Novokuznetsk, 654007, Russian Federation
2Institute of Soil Science and Agrochemistry of the Siberian Branch of the Russian Academy of Sciences, Novosibirsk, 630090, Russian Federation
Authors Information
Semina I.S., PhD (Biological), Associate Professor of Geology, geodesy and life protection department, e-mail: semina.i@mail.ru
Androkhanov V.A., Doctor of Biological Sciences, Director
Abstract
The limiting factors for application of coal processing wastes, especially the cake flotation product, i.e. the mineral composition, alkaline reaction of environment, density, porosity, considerable content of carbon in substrate, that make these wastes unsuitable for formation of the upper root layer on the man-made dumps have been revealed based on the results of the performed research. Prospects and limitations for using coal processing wastes in the technical and biological stages are shown.
Keywords
Reclamation, Coal processing waste, Waste dumps, Disturbed land, Technosoil, Embryosoil.
References
1. Tarazanov I.G. Russia’s coal industry performance for January – September, 2021. Ugol’, 2022, (1), pp. 47-58. (In Russ.). DOI: 10.18796/0041-5790-2022-1-47-58.
2. Murko V.I., Temlyantsev M.V., Litvinov Yu.A., Volkov M.A. & Baranova M.P. Development of justification of technological solutions for transformation of organic mass of fine coal processing wastes. Naukoemkie tehnologii razrabotki i ispol?zovaniya mineral?nyh resursov, 2020, (6), pp. 413-418. (In Russ.).
3. Zhuravleva N.V., Ivanykina O.V., Ismagilov Z.R. & Potokina R.R. Content of toxic elements in overburden and host rocks of Kemerovo region deposits. Gornyj informatsionno-analiticheskij byulleten, 2015, (3), pp. 187–196.
4. Zhuravleva N.V., Voropaeva T.N. & Ivanykina O.V. Complex assessment of the toxicity of industrial waste of enterprises in the Kemerovo region. Vestnik Kuzbasskogo gosudarstvennogo tehnicheskogo universiteta, 2006, (6-2), pp. 86-89. (In Russ.).
5. Ruiz F., Perlatti F., Oliveira D.P. & Ferreira T.O. Revealing tropical technosols as an alternative for mine reclamation and waste management. Minerals, 2020, (10), 110.
6. Masciandaro G. Phytoremediation of dredged marine sediment: Monitoring of chemical and biochemical processes contributing to sediment reclamation. Journal of Environmental Management, 2014, (134), pp. 166-174.
7. Santos E.S., Abreu M.M. & Mac?as F. Rehabilitation of mining areas through integrated biotechnological approach: Technosols derived from organic/inorganic wastes and autochthonous plant development. Chemosphere, 2019, (224), pp. 765-775.
8. Kirilov I. & Banov M. Reclamation of lands disturbed by mining activities in Bulgaria. Agricultural Science and Technology, 2016, (8), pp. 339-345.
9. Bilibio C., Retz S., Schellert C. & Hensel O. Drainage properties of technosols made of municipal solid waste incineration bottom ash and coal combustion residues on potash-tailings piles: A lysimeter study. Journal of Cleaner Production, 2021, (279), pp. 34-42.
10. Ramasamy M. & Power C. Evolution of acid mine drainage from a coal waste rock pile reclaimed with a simple soil cover. Hydrology, 2019, (6), 83.
11. Jacinthe P-A. & Lal R. Spatial variability of soil properties and trace gas fluxes in reclaimed mine land of southeastern Ohio. Geoderma, 2006, (136), pp. 598-608.
12. Nechaeva T.V., Sokolov D.A. & Sokolova N.A. Assessment of the absorption properties of coals of various metamorphism degrees as exemplified by potassium fixation. Vestnik Tomskogo gosudarstvennogo universiteta, Biologiya, 2018, (44), pp. 6-23. (In Russ.).
13. Glaser B. & Birk JJ. State of the scientific knowledge on properties and genesis of Anthropogenic Dark Earths in Central Amazonia (terra preta de ?ndio). Geochimica et Cosmochimica Acta, 2012, (82), pp. 39-51.
14. Kurachev V.M. & Androkhanov V.A. Classification of soils in technogenic landscapes // Sibirskij ekologicheskij zhurnal, 2002, (3), pp. 255-261. (In Russ.).
15. Methodology for determining the toxicity of waters, aqueous extracts from soils, sewage sludge and waste by changes in chlorophyll fluorescence levels and algal cell numbers. FR. 1.39.2007.03223. Introduced on 17.10.2005. Available at: https://meganorm<st1< a="">:personname >.ru/Index2/1/4293842/
4293842245.htm (accessed 15.05.2022). (In Russ.).
16. Methodology for determining the toxicity of waters, aqueous extracts from soils, sewage sludge and waste by changes in mortality and in fertility of Ceriodaphnia. FR. 1.39.2007.03221. Introduced on 17.10.2005. Available at: https://meganorm.ru/Index2/1/4293842/4293842244.htm(accessed 15.05.2022). (In Russ.).
17. Semina I.S. & Androkhanov V.A. Environmental and soil survey of sites re? claimed using coal processing wastes, as exemplified by the Kemerovo Region, Kuzbass. Ugol’, 2021, (7), pp. 57-62. (In Russ.). DOI: 10.18796/0041-5790-2021-7-57-62.
18. Approximate permissible concentration (APC) of chemical substances in soil. GN 2.1.7.2511–09 Sanitary-Hygienic Standard. Moscow, Federal Hygienic and Epidemiological Center of Rospotrebnadzor, 2009, 11 p. (In Russ.).
19. Maximum permissible concentration (MPC) of chemical substances in soils: GN 2.1.7.2041-06 Sanitary-Hygienic Standard. Moscow, Federal Hygienic and Epidemiological Center of Rospotrebnadzor, 2009, 15 p. (in Russian).
20. Vinogradov A.P. Average content of chemical elements in the main types of igneous rocks in the Earth's crust. Geohimiya, 1962, (7), pp. 555-571. (In Russ.).
21. Solovov A.P., Arkhipov A.Ya., Bugrov V.A. et al. Handbook on geochemical prospecting of minerals. Moscow, Nedra Publ., 1990, 335 p. (In Russ.).
22. Arbuzov S.I., Ershov V.V., Rikhvanov L.P. et al. Rare elements in coals of the Kuznetsk Basin. Kemerovo, 2000, 245 p. (In Russ.).
23. Shpirt M.Ya. & Rashevsky V.V. Micronutrients of combustible minerals. Moscow, Kuchkovo Pole Publ., 2010, 384 p. (In Russ.).
24. Shpirt M.Ya. & Punanova S.A. Specific features of microelement composition of coals, shales and oils from different sedimentary basins. Himiya tverdogo topliva, 2010, (4), pp. 57-65. (In Russ.).
25. Shpirt M.Ya. & Punanova S.A. Specific features of microelement accumulation in coals from different basins in the Russian Federation. Himiya tverdogo topliva, 2011, (3), pp. 10-25, 237. (In Russ.).
26. Shpirt M.Ya. & Punanova S.A. Specific features of mercury accumulation in oils, coals and refined products. Himiya tverdogo topliva, 2011, (5), pp. 42-49. (In Russ.).
27. Yudovich Ya.E. & Ketris M.P. Mercury in coals. Syktyvkar, Institute of Geology, Komi Scientific Centre, Urals Branch of the Russian Academy of Sciences, 2007, 96 p. (In Russ.).
28. Klika Z., Bartonova L., Lebedeva L.N., Kost L.A. & Gorlov E.G. Influence of operation modes of thermal power plants in the Czech Republic on distribution of microelements of coals and sulphur during combustion. Himiya tverdogo topliva, 2003, (6), pp. 49-59. (In Russ.).
Acknowledgments
The investigation was financially supported by the Kemerovo Region under Research Project No. 20-44-420006/20. The field studies were carried out during field work according to the planned assignments of the Institute of Soil Science and Agrochemistry of the Siberian Branch of the Russian Academy of Sciences.
For citation
Semina I.S. & Androkhanov V.A. Geochemical background in semimature soils made on reclaimed sites using coal waste. Ugol’, 2022, (6), pp. 74-79. (In Russ.). DOI: 10.18796/0041- 5790-2022-6-74-79.
Paper info
Received April 12, 2022
Reviewed April 28, 2022
Accepted May 23, 2022