References

1. G. Jishkariani, G. Jandieri, D. Sakhvadze, G. Tavadze, G.Z.G. Oniashvili, Z. Aslamazishvili, Ecological problems related to mining-metallurgical industries and innovatory, energy-efficient ways of solving them, Eng. J., 4 (2012) 83–89.
2. K.G. Pugin, Y.I. Vaysman, B.S. Yushkov, N.G. Maksimovich, Reducing the Environmental Load Under Handling Ferrous Metallurgy Slags, Perm State Technical University, Perm, 2008 (in Russian).
3. Y.A. Dolgorukov, Ways of increasing the recycling of metallurgical wastes, Metallurgist, 34 (1990) 91–94.
4. A.I. Senik, S.V. Milukov, O.B. Iroshkina, Formation of hydrogen sulfide emissions during out-of-furnace granulation of blast-furnace slags, Vestnik of NMSTU, 3 (2008) 75–79 (in Russian).
5. V. Sinelnikov, A. Chyczyński, D. Kalisz, R. Kuzemko, Application of slag for maintenance of refractory lining of an oxygen converter, Rudy Met. Nieżel. Recy., 64 (2019) 3–7 (in Polish).
6. J. Guo, Y. Bao, M. Wang, Steel slag in China: treatment, recycling, and management, Waste Manage., 78 (2018) 318–330.
7. H. Yi, G. Xu, H. Cheng, J. Wang, Y. Wan, H. Chen, An overview of utilization of steel slag, Procedia Environ. Sci., 16 (2012) 791–801.
8. E. Raper, S. Davies, B. Perkins, H. Lamb, M. Hermanson, A. Soares, T. Stephenson, Ecological conditions of ponds situated on blast furnace slag deposits located in South Gare Site of Special Scientific Interest (SSSI), Teesside, UK, Environ. Geochem. Health, 37 (2015) 545–556.
9. A. Potysz, E.D.van Hullebusch, J. Kierczak, Perspectives regarding the use of metallurgical slags as secondary metal resources – a review of bioleaching approaches, J. Environ. Manage., 219 (2018) 138–152.
10. I.A. Nikosh, A.A. Tomash, A.E. Kapustin, Elimination of pollution of the aquatic environment under using metallurgical slags as a material for hydraulic engineering (in Russian), Reporter of PSTU: Technol. Sci., 21 (2010) 145–148
11. S.V. Bryizgalov, Utilization of metallurgical slag in the production of reinforced concrete piles, Ecol. Ind. Russ., 7 (2008) 40–43 (in Russian).
12. C. González, R. Parra, A. Klenovcanova, I. Imris, M. Sánchez, Reduction of Chilean copper slags: a case of waste management project, Scand. J. Metall., 34 (2005) 143–149.
13. J. Kierczak, A. Potysz, A. Pietranik, R. Tyszka, M. Modelska, C. Néel, M. Mihaljevič, Environmental impact of the historical Cu smelting in the Rudawy Janowickie Mountains (southwestern Poland), J. Geochem. Explor., 124 (2013) 183–194.
14. N.M. Piatak, In: B.De. Vivo, Environmental Geochemistry: Site Characterization, Data Analysis and Case Histories, Elsevier Science, 2018, pp. 487–519.
15. L.A. Frolova, A.A. Pivovarov, T.E. Butirina, E.G. Tsepich, Studying the process of purification of chromium-containing wastewater sorbent based on blast furnace slag, J. Water Chem. Technol., 37 (2015) 342–351.
16. I.V. Butorina, M.V. Butorina. An overview of environmental and management problems in Mariupol, Ukraine, Environ. Manage. Health, 12 (2001) 88–99.
17. L.D. Poulikakos, C. Papadaskalopoulou, B. Hofko, F. Gschosser, A. Cannone Falchetto, M. Bueno, M. Arraigada, J. Sousa, R. Ruiz, C. Petit, M. Loizidou, M.N. Partl, Harvesting the unexplored potential of European waste materials for road construction, Resour. Conserv. Recycl., 116 (2017) 32–44.
18. O. Filonenko, Sustainable development of Ukrainian iron and steel industry enterprises in regards to the bulk manufacturing waste recycling efficiency improvement, Min. Miner. Depos., 12 (2018) 115–122.
19. M. Herczeg, D. McKinnon, L. Milios, I. Bakas, E. Klassens, K. Svatikova, O. Widerberg, Resource Efficiency in the Building Sector: Final Report, ECORYS, Rotterdam, 2014.
20. A.V. Volzhenskiy, Mineral Binders, Ripol Classic Publishing House, Moscow, 1986 (in Russian).
21. E.L. Dan, E.O. Butenko, A.E. Kapustin, Neutralization of hydrogen sulfide from industrial wastewater by oxidation, Water Ecol. Prob. Sol., 3 (2015) 49–59 (in Russian).
22. J. Wettestad, Clearing the Air: European Advances in Tackling Acid Rain and Atmospheric Pollution, Routledge, London, 2018.
23. G. Crini, Recent developments in polysaccharide-based materials used as adsorbents in wastewater treatment, Prog. Polym. Sci., 30 (2005) 38–70.
24. M.N. Rashed, In: M.N. Rashed, Organic Pollutants – Monitoring, Risk and Treatment, InTechOpen, London 2013, pp. 167–194.
25. I.N. Pugacheva, S.B. Zueva, L.I. Molokanova, Recycled sorbents for wastewater treatment, IOP Conf. Ser.: Earth Environ. Sci., 459 (2020) 032062.
26. E. Butenko, O. Dan, A. Kapustin, E. Neverova‑Dziopak. Naphthalene removal with layered double hydroxides, Geomat. Environ. Eng., 14 (2020) 19–30.
27. E.Y. Kopayeva, E.A. Pyak, V.V. Sluchenkova, P.P. Zatsepina, Comparative characteristics of sorbents used for eliminating dark and light oil spills, Asia Pacific J. Mar. Sci. Edu., 48 (2018) 48–55.
28. L.F. Dolina, Modern Equipment and Technologies for Wastewater Treatment from Heavy Metal Salts, Kontinent, Dnipropetrovsk, 2008 (in Russian).
29. E.O. Butenko, A.E. Kapustin, Technology of sulfides removal, East. Eur. J. Enterp. Technol., 3 (2010) 7–9.
30. S.V. Yakovlev, O.V. Demidov, Modern solutions for natural and waste water treatment, Ecol. Ind. Russ., 12 (1999) 12–15 (in Russian).
31. A. Corma, Solid acid catalysts, Curr. Opin. Solid State Mater. Sci., 2 (1997) 63–75.
32. E.O. Butenko, A.E. Kapustin, Sorption removal of toxic compounds from industrial wastewater using layered double hydroxides, Ecol. Ind., 3 (2010) 52–59 (in Russian).
33. E.O. Butenko, Development of technical solutions for the removal of hydrogen sulfide and sulfides from industrial wastewater, 1st Ind. Sci. J., 1–2 (2015) 31–36 (in Russian).
34. E. Butenko, A. Malyshev, A. Kapustin, A. LDHs as adsorbents of phenol and their environmental applications, Am. J. Environ. Prot., 2 (2015) 11–15.
35. O.V. Nagornyiy, M.M. Sokolova, T.K. Tomchuk, V.V. Volhin, O.I. Bahireva, A.D. Efimova, Layered double magnesiumaluminum hydroxide as a regenerable sorbent for some anions (in Russian), PNRPU Bull. Chem. Technol. Biotechnol., 12 (2011) 29–34.
36. E.O. Butenko, G.E. Abrosimova, A.S. Aronin, D. Bish, E.V. Kapustina, A.E. Kapustin, Sorption properties of natural and synthetic tacovites, Vestnik of PSTU: Technol. Sci., 19 (2009) 307–311 (in Russian).
37. K.H. Goh, T.T. Lim, Z. Dong, Application of layered double hydroxides for removal of oxyanions: a review, Water. Res., 42 (2008) 1343–1368.
38. M.A. Othman, W.M. Zahid, A.E. Abasaeed, Selectivity of layered double hydroxides and their derivative mixed metal oxides as sorbents of hydrogen sulfide, J. Hazard. Mater., 254–255 (2013) 221–227.
39. M. Daud, M.S. Kamal, F. Shehzad, M.A. Al-Harthi, Graphene/layered double hydroxides nanocomposites: a review of recent progress in synthesis and applications, Carbon, 104 (2016) 241–252.
40. F.R. Peligro, I. Pavlovic, R. Rojas, C. Barriga, Removal of heavy metals from simulated wastewater by in situ formation of layered double hydroxides, Chem. Eng. J., 306 (2016) 1035–1040.
41. P.F. Lito, J.P.S. Aniceto, C.M. Silva, Removal of anionic pollutants from waters and wastewaters and materials perspective for their selective sorption, Water Air Soil Pollut., 223 (2012) 6133–6155.
42. B.M. Choudary, B. Bharathi, C.V. Reddy, M.L. Kantam, Tungstate-exchanged Mg-Al-LDH catalyst: an eco-compatible route for the oxidation of sulfides in aqueous medium, J. Chem. Soc., 18 (2002) 2069–2074.
43. A. Ryzhikov, V. Hulea, D. Tichit, C. Leroi, D. Anglerot, B. Coq, P. Trens, Methyl mercaptan and carbonyl sulfide traces removal through adsorption and catalysis on zeolites and layered double hydroxides, Appl. Catal., A, 397 (2011) 218–224.
44. L. Ma, Q. Wang, S.M. Islam, Y. Liu, S. Ma, M.G. Kanatzidis, Highly selective and efficient removal of heavy metals by layered double hydroxide intercalated with the MoS₄^2– ion, J. Am. Chem. Soc., 138 (2016) 2858–2866.
45. Yu.Yu. Lurje, A.I. Ryibnikova, Chemical Analysis of Industrial Wastewater, Chemistry, Moscow, 1974 (in Russian).
46. I. Prigozhin, R. Defey, Chemical Thermodynamics, Science, Novosibirsk, 1966 (in Russian).
47. N.N. Grekova, O.V. Lebedeva, A.E. Kapustin, Problems of indicator titration of basic heterogeneous catalysts, Catal. Petrochem., 2 (1996) 76–79 (in Russian).