Exchangeable form of potentially toxic elements in floodplain soils along the river-marine systems of Southern Russia

Year 2021, Volume: 10 Issue: 2, 132 - 141, 01.04.2021

Elizaveta Konstantinova Tatiana Minkina Dina Nevidomskaya Saglara Mandzhieva Tatiana Bauer Inna Zamulina Marina Burachevskaya Svetlana Sushkova

https://doi.org/10.18393/ejss.838700

Cited By: 4

Abstract

Large rivers and especially their deltaic parts and adjacent coastal zones are subjected to strong anthropogenic influence and are often considered as hotspots of environmental pollution. The Don River is one of the largest and most important rivers in the South of Russia. The Don River basin is a highly urbanized area with developed agriculture and industry which negatively affect water quality, aquatic ecosystems and soils. The main objectives of the proposed research were to determine the levels exchangeable form of PHEs in soils of various aquatic landscapes of the study area, as well as to reveal the relationships between the content of exchangeable PTEs and the physical–chemical properties of floodplain soils. The obtained results showed that soils of the Lower Don and Taganrog Bay coastal zone are rather contrast in terms of properties and metal contents, which indicates the variability of landscapes, natural and anthropogenic processes in the studied systems. High CV values for a number of metals such as Pb, Zn, Cd and Cr indirectly indicate strong anthropogenic influence on these environments. The group median values for extractable forms for most of the metals except for Cu and Ni were higher for urbanized areas. The results of PCA analysis showed that there are two association of metals in terms of geochemical behavior and sources. The first one included Cr-Zn-Pb-Cd, the elements of anthropogenic origin, the second Mn, Ni, and Cu, which are probably of mixed origin. The obtained results showed that the Lower Don and Taganrog Bay coastal zone is a diverse and complex system subjected to anthropogenic activities, which is pronounced in the enrichment of aquatic soils with a number of metals and higher proportions of exchangeable forms from different types of sources that likely can be of both local and whole basin scale.

Keywords

Floodplain, heavy metals, Fluvisols, the Don River, Taganrog Bay, Azov Sea

References

• Ahn, J.M., Kim, S., Kim, Y.S., 2020. Selection of priority management of rivers by assessing heavy metal pollution and ecological risk of surface sediments. Environmental Geochemistry and Health 42: 1657-1669.
• Arafa, W.M., Badawy, W.M., Fahmi, N.M., Ali, K., Gad, M.S., Duliu, O.G., Frontasyeva, M.V., Steinnes, E., 2015. Geochemistry of sediments and surface soils from the Nile Delta and lower Nile valley studied by epithermal neutron activation analysis. Journal of African Earth Sciences 107: 57-64.
• Bartsev, O.B., Nikanorov, A.M., Gar’kusha, D.N., Zubkov, E.A., 2016. Assessment of groundwater impact on water quality in the built-up areas at the Lower Don. Russian Meteorology and Hydrology 41: 504-512.
• Bauer, T.V., Linnik, V.G., Minkina, T.M., Mandzhieva, S.S., Nevidomskaya, D.G., 2018. Ecological–geochemical studies of technogenic soils in the flood plain landscapes of the Seversky Donets, Lower Don basin. Geochemistry International 56: 992-1002.
• Beltrame, M.O., De Marco, S.G., Marcovecchio, J.E., 2009. Dissolved and particulate heavy metals distribution in coastal lagoons. A case study from Mar Chiquita Lagoon, Argentina. Estuarine, Coastal and Shelf Science 85(1): 45-56.
• Birch, G.F., Gunns, T.J., Olmos, M., 2015. Sediment-bound metals as indicators of anthropogenic change in estuarine environments. Marine Pollution Bulletin 101: 243-257.
• Botsou, F., Karageorgis, A.P., Paraskevopoulou, V., Dassenakis, M., Scoullos, M., 2019. Critical processes of trace metals mobility in transitional waters: implications from the remote, Antinioti Lagoon, Corfu Island, Greece. Journal of Marine Science and Engineering 7(9): 307.
• Buscaroli, A., Zannoni, D., Dinelli, E., 2021. Spatial distribution of elements in near surface sediments as a consequence of sediment origin and anthropogenic activities in a coastal area in northern Italy. Catena 196: 104842.
• Chalov, S., Moreido, V., Sharapova, E., Efimova, L., Efimov, V., Lychagin, M., Kasimov, N., 2020. Hydrodynamic controls of particulate metals partitioning along the Lower Selenga River-Main tributary of the Lake Baikal. Water 12(5): 1345.
• Chapman, A., Darby, S., 2016. Evaluating sustainable adaptation strategies for vulnerable mega-deltas using system dynamics modelling: Rice agriculture in the Mekong Delta's an Giang Province, Vietnam. Science of The Total Environment 559: 326-338.
• Chen, J., Liu, P., Sun, D., Zhang, D., Miao, B., Chen, J., 2020. Riverine sediment geochemistry as provenance fingerprints along the Eastern Coast of China: Constraint, approach, and application. Minerals 10(1): 29.
• Chichaeva, M.A., Lychagin, M.Yu., Syroeshkin, A.V., Chernitsova, O.V., 2020. Heavy metals in marine aerosols of the Azov Sea. Geography, Environment, Sustainability 13(2): 127-134.
• Chikin, A.L., Kleshchenkov, A.V., Chikina, L.G., 2019. Numerical study of the water flow effect on the water level in the Don Mouth. Physical Oceanography 26(4): 316-325.
• Dada, O.A., Li, G., Qiao, L., Ding, D., Ma, Y., Xu, J., 2016. Seasonal shoreline behaviours along the arcuate Niger Delta coast: Complex interaction between fluvial and marine processes. Continental Shelf Research 122: 51-67,
• Dhanakumar, S., Solaraj, G., Mohanraj, R., 2015. Heavy metal partitioning in sediments and bioaccumulation in commercial fish species of three major reservoirs of river Cauvery delta region, India. Ecotoxicology and Environmental Safety 113: 145-151.
• Elbehiry, F., Elbasiouny, H., El-Ramady, H., Brevik, E.C., 2019. Mobility, distribution, and potential risk assessment of selected trace elements in soils of the Nile Delta, Egypt. Environmental Monitoring and Assessment 191: 713.
• Enya, O., Lin, C., Qin, J., 2019. Heavy metal contamination status in soil-plant system in the Upper Mersey estuarine floodplain, Northwest England. Marine Pollution Bulletin 146: 292-304.
• Fulford, R.S., Russell, M., Hagy, J.D., Breitburg, D., 2020. Managing estuaries for ecosystem function. Global Ecology and Conservation 21: e00892.
• Ge, M., Liu, G., Liu, H., Yaun, Z., Liu, Y., 2019. The distributions, contamination status, and health risk assessments of mercury and arsenic in the soils from the Yellow River Delta of China. Environmental Science and Pollution Research 26: 35094-35106.
• GOST 17.4.4.02-2017, 2018. Nature protection. Soils. Methods (or sampling and preparation of soil for chemical, bacteriological, helmintological analysis. Standardinform, Moscow. [in Russian].
• Greening, H., Janicki, A., Sherwood, E.T., Pribble, R., Johansson, J.O.R., 2014. Ecosystem responses to long-term nutrient management in an urban estuary: Tampa Bay, Florida, USA. Estuarine, Coastal and Shelf Science 151: A1-A16.
• Hu, B., Zhou, Y., Jiang, Y., Ji, W., Fu, Z., Shao, S., Li, S., Huang, M., Zhou, L., Shi, Z., 2020. Spatio-temporal variation and source changes of potentially toxic elements in soil on a typical plain of the Yangtze River Delta, China (2002–2012). Journal of Environmental Management 271: 110943.
• IUSS, 2015. World reference base for soil resources 2014 International soil classification system for naming soils and creating legends for soil maps. Update 2015. World Soil Resources Reports No. 106. Food and Agriculture Organization of the United Nations (FAO), Rome, Italy. 192p. Available at [Access date: 11.05.2020]: http://www.fao.org/3/i3794en/I3794en.pdf
• Ivanov, V.V., Korotayev, V.N., Rimsky-Korsakov, N.A., Pronin, A.A., Chernov, A.V., 2013. Floodplain structure and channel dynamics in the lower reaches of the Don River. Vestnik Moskovskogo Universiteta Seria 5, Geografia, 5: 60-66. [in Russian].
• Kabata-Pendias, A., 2011. Trace Elements in Soils and Plants, fourth ed. CRC Press, Boca Raton. 505p.
• Kasimov, N., Shinkareva, G., Lychagin, M., Chalov, S., Pashkina, M., Thorslund, J., Jarsjö, J., 2020. River water quality of the Selenga-Baikal Basin: Part II—Metal partitioning under different hydroclimatic conditions. Water 12(9): 2392.
• Kasimov, N., Shinkareva, G., Lychagin, M., Kosheleva, N., Chalov, S., Pashkina, M., Thorslund, J., Jarsjö, J., 2020. River water quality of the Selenga-Baikal basin: Part I—Spatio-temporal patterns of dissolved and suspended metals. Water, 12(8): 2137.
• Kazakov, K., 2020. Weather and climate. Available at [Access date: 11.05.2020]: http://www.pogodaiklimat.ru/climate/28367.htm.
• Kolomyichuk, V.P., Fedyaeva, V.V., 2012. Vegetation of the Taganrog Bay banks. Izvestiya Vuzov. Severo-Kavkazskii Region. Natural Science 1: 76-81. [in Russian].
• Konstantinova, E., Burachevskaya, M., Mandzhieva, S., Bauer, T., Minkina, T., Chaplygin, V., Zamulina, I., Konstantinov, A., Sushkova, S., 2020. Geochemical transformation of soil cover and vegetation in a drained floodplain lake affected by long-term discharge of effluents from rayon industry plants, lower Don River Basin, Southern Russia. Environmental Geochemistry and Health [in Press].
• Korotaev, V.N., Chernov, A.V. 2018. Formation of floodplains in the lower reaches of large plain rivers under base level fluctuations. Vestnik Moskovskogo Universiteta. Seria 5, Geografia, 4: 3–12. [in Russian].
• Krylenko, M., Kosyan, R., Krylenko, V., 2017. Lagoons of the smallest Russian sea. In: The Diversity of Russian Estuaries and Lagoons Exposed to Human Influence. Kosyan, R. (Ed.). Series Estuaries of the World, Springer International Publishing, pp. 111-148
• Linnik, V.G., Bauer, T.V., Minkina, T.M., Mandzhieva, S.S., Mazarji, M., 2020. Spatial distribution of heavy metals in soils of the flood plain of the Seversky Donets River (Russia) based on geostatistical methods. Environmental Geochemistry and Health [in Press].
• Loureiro, D.D., Fernandez, M.A., Herms, F.W., Lacerda, L.D., 2009. Heavy metal inputs evolution to an urban hypertrophic coastal lagoon, Rodrigo De Freitas Lagoon, Rio De Janeiro, Brazil. Environmental Monitoring and Assessment 159: 577.
• Lu, Q., Bai, J., Zhang, G., Wu, J., 2020. Effects of coastal reclamation history on heavy metals in different types of wetland soils in the Pearl River Delta: Levels, sources and ecological risks. Journal of Cleaner Production 272: 122668.
• Lychagin, M.Y., Tkachenko, A.N., Kasimov, N.S., Kroonenberg, S.B., 2015. Heavy metals in the water, plants, and bottom sediments of the Volga River mouth area. Journal of Coastal Research 31(4): 859-868.
• Matishov G.G., Ivlieva O.V., Bespalova L.A., Kropyanko L.V., 2015. Ecological and geographical analysis of the sea coast of the Rostov region. Doklady Earth Sciences 460(1): 53-57.
• Matishov, G.G., Stepan’yan, O.V., Har’kovskii, V.M., Startsev, A.V., Bulysheva, N.I., Semin, V.V., Soier, V.G., Kreneva, K.V., Glushchenko, G.Yu., Svistunova, L.D., 2016. Characteristic of Lower Don aquatic ecosystem in late autumn. Water Resources 43: 873-884.
• Minkina, T., Konstantinova, E., Bauer, T., Mandzhieva, S., Sushkova, S., Chaplygin, V., Burachevskaya, M., Nazarenko, O., Kizilkaya, R., Gülser, C., Maksimov, A., 2020. Environmental and human health risk assessment of potentially toxic elements in soils around the largest coal-fired power station in Southern Russia. Environmental Geochemistry and Health [in Press].
• Minkina, T.M., Fedorenko, G.M., Nevidomskaya, D.G., Pol’shina, T.N., Fedorenko, A.G., Chaplygin, V.A., Mandzhieva, S.S., Sushkova, S.N., Hassan, T.M., 2019. Bioindication of soil pollution in the delta of the Don River and the coast of the Taganrog Bay with heavy metals based on anatomical, morphological and biogeochemical studies of macrophyte (Typha australis Schum. & Thonn). Environmental Geochemistry and Health [in Press].
• Minkina, T.M., Fedorov, Y.A., Nevidomskaya, D.G., Pol’shina, T.N., Mandzhieva, S.S., Chaplygin, V.A., 2017. Heavy metals in soils and plants of the don river estuary and the Taganrog Bay coast. Eurasian Soil Science 50: 1033-1047.
• Minkina, T.M., Nevidomskaya, D.G., Pol’shina, T.N., Fedorov, Y.A., Mandzhieva, S.S., Chaplygin, V.A., Bauer, T.V., Burachevskaya, M.V., 2017. Heavy metals in the soil–plant system of the Don River estuarine region and the Taganrog Bay coast. Journal of Soils and Sediments 17: 1474-1491.
• Nevidomskaya, D., Minkina, T., Fedorov, Y., Nazarenko, O., Kravtsova. N., Litvinov, Y., 2020. Integral assessment of heavy metal pollution in Don River estuary soils. E3S Web of Conferences - Actual Problems of Ecology and Environmental Management: Cooperation for Sustainable Development and Environmental Safety (APEEM 2020) 169: 01007.
• Nikanorov A.M., 2014. Selective response of water ecosystems to the anthropogenic effect. Doklady Earth Sciences 459(2): 1573-1575. Nikanorov A.M., Khoruzhaya T.A., 2012. Tendencies of long-term changes in water quality of water bodies in the South of Russia. Geography and Natural Resources 33(2): 125-130.
• OST 10-259-2000. 2001. Soil. X-ray fluorescence determination of the total content of heavy metals. The Russian Federation Ministry of Agriculture, Moscow. [in Russian].
• RD 52.18.289-90. 1990. Guidelines. Methods for measuring the mass fraction of mobile forms of metals (copper, lead, zinc, nickel, cadmium, cobalt, chromium, manganese) in soil samples by atomic absorption analysis (approved by Governm. USSR Committee for Hydrometeorology 04 October 1989). Goscomgidromet, Moscow. [in Russian].
• Savenko, A.V., Pokrovsky, O.S., 2020. Transformation of dissolved matter runoff in the Ural River Mouth. Geochemistry International 58: 947-958.
• Shaimukhametov, M., 1993. On determination technique of absorbed Ca and Mg in chernozem soils. Pochvovedenie 12: 105-111. [in Russian].
• Shokr, M.S., El Baroudy, A.A., Fullen, M.A., El-beshbeshy, T.R., Ramadan, A.R., Abd El Halim, A., Guerra, A.J.T., Jorge, M.C.O., 2016. Spatial distribution of heavy metals in the Middle Nile Delta of Egypt. International Soil and Water Conservation Research 4(4): 293-303.
• Sushkova, S., Mi̇nki̇na, T., Tari̇gholi̇zadeh, S., Antonenko, E., Konstanti̇nova, E., Gülser, C., Dudni̇kova, T., Barbashev, A., Kızılkaya, R.., 2020. PAHs accumulation in soil-plant system of Phragmites australis Cav. in soil under long-term chemical contamination. Eurasian Journal of Soil Science 9(3): 242-253.
• Thinh, N.V., Osanai, Y., Adachi, T., Thai, P.K., Nakano, N., Ozaki, A., Kuwahara, Y., Kato, R., Makio, M., Kurosawa, K., 2018. Chemical speciation and bioavailability concentration of arsenic and heavy metals in sediment and soil cores in estuarine ecosystem, Vietnam. Microchemical Journal 139: 268-277.
• Tkachenko A.N., Tkachenko O.V., Lychagin M.Y., 2016. Content of heavy metals in water objects of the Delta of Don: seasonal and spatial dynamics. Geologiya, Geografiya i Globalnaya Energiya (Geology, Geography and Global Energy) 2(61): 76-84. [in Russian].
• Tkachenko A.N., Tkachenko O.V., Lychagin M.Y., Kasimov N.S., 2017. Heavy metal flows in aquatic systems of the Don and Kuban River Deltas. Doklady Earth Sciences 474(1): 587-590.
• Uluturhan, E., Kontas, A., Can, E., 2011. Sediment concentrations of heavy metals in the Homa Lagoon (Eastern Aegean Sea): Assessment of contamination and ecological risks. Marine Pollution Bulletin 62: 1989-1997.
• Vorobyova, L.A., 2006. Theory and practice of chemical analysis of soils. GEOS, Moscow.400 p. [in Russian].
• Yan, X., Liu, M., Zhong, J., Guo, J., Wu, W., 2018. How human activities affect heavy metal contamination of soil and sediment in a long-term reclaimed area of the Liaohe River Delta, North China. Sustainability 10(2): 338.