Accumulating capacity of herbaceous plants of the Asteraceae and Poaceae families under technogenic soil pollution with zinc and cadmium

Yıl 2020, Cilt: 9 Sayı: 2, 165 - 172, 01.04.2020

Victor Chaplygin Saglara Mandzhieva Tatiana Minkina Anatolii Barahov Dina Nevidomskaya Rıdvan Kızılkaya Coşkun Gülser Natalia Chernikova Mahmoud Mazarji Luydmila Iljina Vishnu Rajput

https://doi.org/10.18393/ejss.707659

Cited By: 3

Öz

In this study, the environmental monitoring of the long-term technogenic pollution zone of Novocherkassk, a region containing numerous heavy metal contaminations, was carried out. In the plants growing in the 5 km zone around Novocherkasskaya power station, contamination with the studied elements was revealed. The dependence of the content of Zn and Cd in herbaceous plants of the families Asteraceae and Poaceae on the distance to the source of the anthropogenic load was established. The selectivity of accumulation of metals by studied species of herbaceous plants at different levels of technogenic pollution is revealed. Achillea nobilis has the least pollutants resistant from the soil. Poa pratensis has the highest resistance to Zn and Cd pollution in terms of the set of assessment indicators. The granulometric composition of the soil has a significant impact on the availability of metals to plants.

Anahtar Kelimeler

Heavy metals, technogenic pollution, soil-plant system

Kaynakça

• Andresen, E., Küpper, H., 2013. Cadmium toxicity in plants. In: Cadmium: from toxicity to essentiality. Sigel, A., Sigel, H., Sigel, R.C.O. (Eds.). Springer, Dordrecht. pp. 395-413
• Burachevskaya, M., Minkina, T., Mandzhieva, S., Bauer, T., Chaplygin, V., Zamulina, I., Sushkova, S., Fedorenko, A., Ghazaryan, K., Movsesyan, H., Makhinya, D., 2019. Study of copper, lead, and zinc speciation in the Haplic Chernozem surrounding coal-fired power plant. Applied Geochemistry 104: 102-108.
• Chaplygin, V., Minkina, T., Mandzhieva, S., Burachevskaya, M., Sushkova, S., Poluektov, E., Antonenko, E., Kumacheva, V., 2018. The effect of technogenic emissions on the heavy metals accumulation by herbaceous plants. Environmental Monitoring and Assessment 190(3): 124.
• Environmental Bulletin of the Don: On the state of the environment and natural resources of the Rostov region in 2017. 2018. Rostov-on-Don, Russian Federation. 283p. [in Russian].
• Ghazaryan, K.A., Movsesyan, H.S., Minkina, T.M., Sushkova, S.N., Rajput, V.D., 2019.. The identification of phytoextraction potential of Melilotus officinalis and Amaranthus retroflexus growing on copper- and molybdenum-polluted soils. Environmental Geochemistry and Health [in press]
• GN 2.1.7.2042-06. 2006. Maximum permissible concentrations of chemicals in the soil: Hygienic standards. Rospotrebnadzor, Moscow, Russian Federation. [in Russian].
• GN 2.1.7.2511-09. 2009. Approximate permissible concentrations of chemicals in soil: Hygiene standards. Rospotrebnadzor, Moscow, Russian Federation. [in Russian].
• Guidelines for the determination of heavy metals in farmland soils and crop production. 1992. Moscow, Russian Federation. TSINAO. 61p. [in Russian].
• Ilyin, V.B., Syso, A.I., 2012. Heavy metals and nonmetals in the soil-plant system. Siberian branch RAS publishing House, Novosibirsk. Russian Federation. 220 р. [in Russian].
• Kabata-Pendias, A., Pendias, H. (2001). Trace elements in soils and plants. CRC Press, Boca Raton. 403p.
• Maksimov, N., Evmenyeva, A., Breygina, M. Yermakov, I., 2018. The role of reactive oxygen species in pollen germination in Picea pungens (blue spruce). Plant Reproduction 31(4): 357-365.
• Minkina, T.M., Mandzhieva, S.S., Burachevskaya, M.V., Bauer, T.V., Sushkova, S.N., 2018. Method of determining loosely bound compounds of heavy metals in the soil. MethodsX 5: 217-226.
• Minkina, T.M., Mandzhieva, S.S., Chaplygin, V.A., Nazarenko, O.G., Maksimov, A.Y., Zamulina, I.V., Burachevskaya, M.V., Sushkova, S.N., 2018. Accumulation of heavy metals by forb steppe vegetation according to long-term monitoring data. Arid Ecosystems 8(3): 190-202.
• Minkina, T.M., Motuzova, G.V., Mandzhieva, S.S., 2008. Barrier functions of the soil-plant system. Moscow University Soil Science Bulletin 63(2): 45-50.
• Nkongolo, K.K., Spiers, G., Beckett, P., Narendrula, R., Theriault, G., Tran, A., Kalubi, K.N., 2013. Long-term effects of liming on soil chemistry in stable and eroded upland areas in a mining region. Water, Air, & Soil Pollution 224(7): 1618.
• Plyaskina, O.V., Ladonin, D.V., 2005. Compounds of heavy metals in granulometric fractions of certain soil types. Moscow University Soil Science Bulletin 4:36-43. [in Russian].
• Provisional maximum permissible levels (MPL) for some chemical elements and gossypol in forage for farm animals and feed additives, 1987. Moscow, Russian Federation. [in Russian].
• Seregin, I.V., Ivanov, V.B., 2001. Physiological aspects of cadmium and lead toxic effects on higher plants. Russian Journal of Plant Physiology 48(4): 523-544.
• Shtangeeva, I., Viksna, A., Grebnevs, V., 2020. Geochemical (soil) and phylogenetic (plant taxa) factors affecting accumulation of macro-and trace elements in three natural plant species. Environmental Geochemistry and Health 42(1): 209-219.
• Zhao, Z.J., Nan, Z.R., Wang, Z.W., Yang, Y.M., Shimizu, M. (2014). Interaction between Cd and Pb in the soil-plant system: a case study of an arid oasis soil-cole system. Journal of Arid Land 6(1): 59-68.
• Zhuikova, T.V., Zinnatova, E.R., 2014. Accumulating capacity of plants in conditions of technogenic soil pollution with heavy metals. Volga Ecological Journal 2: 196-207 [in Russian].