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Using the mineral component of building refuse in heavy metals sorption from their mixture

V. M. Yurk, O. B. Zaytsev, A. V. Zaytseva, N. A. Malahova

Abstract


The sorption properties of the sand-breakstone mixture based on the mineral component of building refuse of the 0-10 mm fraction with respect to Pb2+, Zn2+, Cu2+, Ni2+, Cd2+ and Hg2+ ions were studied using atomic absorption spectroscopy. The mechanisms of accumulation of heavy metal ions on the surface of the mixture particles are described. It was found that after washing the contaminated material distilled water, the residual concentration of metals in the filtrate does not exceed the established sanitary and hygienic standards. The practical value of the work lies in the possibility of applying the results in reclamation of technogenic formations or production of materials for the technical stage of reclamation using technogenic soils.

Keywords


contamination; heavy metal; building refuse; soil pollution

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References


Perel'man AI. Geochemical barriers: theory and practical applications. Applied Geochemistry. 1986;1(6):669-80. doi:10.1016/0883-2927(86)90088-0

Maximovich N, Khayrulina E. Artificial geochemical barriers for environmental improvement in a coal basin region. Environmental Earth Sciences. 2914;72:1915-24. doi:10.1007/s12665-014-3099-7

Bogush AA, Galkova OG, Ishuk NV. Geochemical barriers to elemental migration in sulfide-rich tailings: three case studies from Western Siberia. Mineralogical Magazine. 2012;76(7):2693-707. doi:10.1180/minmag.2012.076.7.05

Zhao Q, Choo H, Bhatt A, Burns SE, Bate B. Review of the fundamental geochemical and physical behaviors of organoclays in barrier applications. Applied Clay Science. 2017;142:2-20. doi:10.1016/j.clay.2016.11.024

Nguyena TAH, Ngoa HH, Guoa WS, Zhangb J, Liangb S, Yueb QY, Lib Q, Nguyen TV. Applicability of agricultural waste and by-products for adsorptive removal of heavy metals from wastewater. Bioresource Technology. 2013;148:574-85. doi:10.1016/j.biortech.2013.08.124

Kumar PS, Ramalingam S, Abhinaya RV, Kirupha SD, Murugesan A, Sivanesan S. Adsorption of metal ions onto the chemically modified agricultural waste. Clean – Soil, Air, Water. 2012;40(2):188-97. doi:10.1002/clen.201100118

Chandrappa AK, Biligiri KP. Pervious concrete as a sustainable pavement material – Research findings and future prospects: A state-of-the-art review. Construction and Building Materials. 2016;111:262-74. doi:10.1016/j.conbuildmat.2016.02.054

Shershneva MV, Puzanova IE, Soloviova VI. Geoekologicheskii aspekt ispol'zovaniia kal'tsiisoderzhashchikh stroitel'nykh otkhodov [Geoecological aspect of the use of calcium-containing construction waste]. Proceedings of Petersburg Transport University. 2010;2:286-92. Russian.

Shershneva MV. Ispol'zovanie geozashhitnyh svojstv tverdyh othodov na transporte [Use of geoprotective properties of solid waste in transport]. Proceedings of Petersburg Transport University. 2007;3:89-95. Russian.

Shershneva MV. Estestvenno-nauchnye osnovy geozashhitnogo rezerva prirodnyh i iskusstvennyh mineralov [Natural-scientific foundations of the geoprotective reserve of natural and artificial minerals]. Proceedings of Petersburg Transport University. 2011;1:237-46. Russian.

Navarro-Blasco I, Duran A, Sirera R, Fernández JM, Alvarez JI. Solidification/stabilization of toxic metals in calcium aluminate cement matrices. Journal of Hazardous Materials. 2013;260:89-103. doi:10.1016/j.jhazmat.2013.04.048

Svatovskayaa L, Shershneva M, Baydarashvily M, Sychova A, Sychov M, Gravit M. Geoecoprotective properties of cement and concrete against heavy metal ions. Procedia Engineering. 2015;117:345-9. doi:10.1016/j.proeng.2015.08.171

Adinarayana KNV, Sasidhar P, Balasubramaniyan V. Modelling of calcium leaching and its influence on radionuclide migration across the concrete engineered barrier in a NSDF. Journal of Environmental Radioactivity. 2013;124:93-100. doi:10.1016/j.jenvrad.2013.04.009

Panin АV, Puzanova IE. Geojekologicheskie reshenija obezvrezhivanija ionov tjazhelyh metallov s pomoshh'ju othodov stroitel'noj promyshlennosti [Geoecological solutions for the neutralization of heavy metal ions using waste from the construction industry]. Proceedings of Petersburg Transport University. 2010;2:251-61. Russian.

Djegola LA, Simakova YM, Rubleva AV, Nikitina OV, Kuatalieva SB. Model’ geokhimicheskogo bar’era dlya akkumulyatsii ionov tyazhelykh toksichnykh I radioaktivnykh metallov [The geochemical barrier model for heavy, toxic and radioactive metals storage]. Estestvennye nauki [Natural Sciences]. 2009;4(29):180-3. Russian.

Levit RL, Kudryavtseva VA. Sorption of zinc, cadmium, lead and copper by mineral particulate matter. Regional Ecology. 2015;6(41):52-7. doi:10.30694/1026-5600-2019-1-5-12

Azmatova E, Myakisheva A, Tashkinova I. Theoretical and experimental justification of using construction and demolition wastes for disturbed areas rehabilitation. PNRPU Bulletin, Applied ecology. Urban development. 2016;31:110-25. doi:10.15593/2409;5125/2016.03.08

Nevedrov NP, Procenko EP, Balabina IP, Fomina MJu. Tjazhelye metally v pochvah goroda: zagrjaznenie i remediacija [Heavy metals in city soils: pollution and remediation]. Moscow: Ru-Science; 2017. 120 p. Russian.




DOI: https://doi.org/10.15826/chimtech.2021.8.1.12

Copyright (c) 2020 V. M. Yurk, O. B. Zaytsev, A. V. Zaytseva, N. A. Malahova

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