References

  1. S. Pavlov, A. Novikov, A. Pavlov, O. Skvortsova, O. Nikonova, E. Semanina, R. Zafarov, K.-O. Wenkel, Methods of Improving Water Treatment Systems for Individual Residential Houses, MATEC Web of Conferences, 73 (2016), https://doi.org/10.1051/matecconf/20167303005.
  2. S. Pavlov, M. Arlanova, A. Nikonorov, V. Terleev, I. Togo, Y. Volkova, V. Garmanov, D. Shishov, K. Layshev, M. Arkhipov, The Water Exchange and Water Quality Improvement Measures on the Example of the Gulf of Cheboksary, MATEC Web of Conferences, 106 (2017), https://doi.org/10.1051/matecconf/ 201710607014.
  3. A.V. Chechevichkin, N.I. Vatin, V.V. Samonin, M.A. Grekov, Purification of hot water by zeolite modified with manganese dioxide, Mag. Civ. Eng., 76 (2017) 201–213.
  4. B. Halwani, S. Net, B. Ouddane, J. Halwani, A review of the most popular systems for greywater treatment, Desal. Wat. Treat., 135 (2018) 124–132.
  5. E.N. Arakcheev, V.E. Brunman, A.N. Volkov, V.A. D’yachenko, A.P. Petkova, A.V. Sorokin, M.V. Brunman, A.V. Konyashin, Complex electrolytic unit for producing anode liquor and ferrate to treat waters contaminated by oil-refining products and harmful admixtures, Chem. Pet. Eng., 52 (2016) 143–148.
  6. Ch. Aravind, K. Chanakya, K. Mahindra, Removal of heavy metals from industrial wastewater using coconut coir, Int. J. Civ. Eng. Technol., 8 (2017) 1869–1871.
  7. O. Ivanchenko, R. Khabibullin, R. Bhat, Wastewaters of Meat- Processing Enterprise: Assessment of Genotoxic Potential, MATEC Web of Conferences, 245 (2018), https://doi.org/10.1051/matecconf/201824518002.
  8. Y. Smyatskaya, A. Kosheleva, E. Taranovskaya, Sorption Properties of Materials Based on Residual Biomass, MATEC Web of Conferences, 245 (2018), https://doi.org/10.1051/matecconf/201824518005.
  9. R. Khabibullin, O. Ivanchenko, A. Petrov, R. Bhat, Optimization of the Process of Anaerobic-Aerobic Purification of Waste Waters of Food Production Using the Spatial Separation of Stages, MATEC Web of Conferences, 245 (2018), https://doi.org/10.1051/matecconf/201824518003.
  10. A. Asadpoori, C. Ankomah, A. Asadpoori, O. Derevianko, E. Shaburov, Sustained Municipal Waste Management Models in Russian Megapolicies Through Utilizing Waste-to-Energy Technologies, MATEC Web of Conferences, 193 (2018), https://doi.org/10.1051/matecconf/201819302039.
  11. M. Madeła, A. Grobelak, E. Neczaj, Impact of selected nanoparticles on wastewater treatment efficiency, Desal. Wat. Treat., 134 (2018) 115–120.
  12. V.S. Zavyalov, Sorption capacity of materials in relation to petroleum products, Ecol. Ind. Russia, 8 (2006) 7–9.
  13. V.V. Bordunov, S.V. Bordunov, V.V. Leonenko, Water purification from oil and oil products, Ecol. Ind. Russia, (2005) 8–10.
  14. R.Kh. Mertz, K.F. Kosygina, V.B. Boxer, Floating carbon sorbent for oil product film absorption on water, Chem. Technol. Water, 20 (1998) 301–305.
  15. N.A. Sobgayda, A.I. Finainov, New sorbents for petroleum products, Ecol. Ind. Russia, (2005) 8–1.
  16. L.N. Olshanskaya, N.A. Sobgayda, I.V. Nikitina, Wastewater Treatment from Petroleum Products Waste Production. Scientific Research, Nanosystems and Resource-Saving Technologies in Industry: Collection of Papers of the International Conference, Publishing House of BSTU Named After V.G. Shukhov, Belgorod, 5 (2007) 267.
  17. A.S. Fialkov, Carbon, Interlayer Compounds and Composites Based on it, Aspect Press, Moscow, 1997.
  18. A.A. Pashayan, A.V. Nesterov, Problems of cleaning waters polluted by oil and ways to solve them, Ecol. Ind. Russia, 5 (2008) 32–35.
  19. N. Politaeva, Yu. Bazarnova, Yu. Smyatskaya, V. Slugin, V. Prokhorov, Impact of carbon dopants on sorption properties of chitosan-based materials, J. Ind. Pollut. Control, 33 (2017) 1617–1621.
  20. L.A. Nikolaeva, A.G. Laptev, R.Y. Iskhakova, Improving the efficiency of wastewater biological treatment at chemical plants, Water Resour., 45 (2018) 231–237.
  21. L.A. Nikolaeva, M.A. Golubchikov, A.R. Minneyarova, Research on the mechanism and kinetics of oil-product adsorption from industrial wastewater by a modified hydrophobic carbonate sludge, Chem. Pet. Eng., 53 (2018) 806–813.
  22. L.A. Nikolaeva, R.Ya. Iskhakova, Complex use of waste in wastewater and circulating water treatment from oil in heat power stations, Therm. Eng., 64 (2017) 458–463.
  23. L.A. Nikolaeva, M.N. Kotlyar, D.A. Khamzina, Liquidation of oil spills from the surface of water bodies with a new hydrophobic sorption material, Water Ecol.: Prob. Solutions, 4 (2017) 53–61.
  24. L.A. Nikolaeva, D.I. Khasanova, E.R. Mukhutdinova, D.Kh. Safin, I.G. Sharifullin, Safe corrosion inhibitor for treating cooling water on heat power engineering plants, Therm. Eng., 64 (2017) 623–625.
  25. N.V. Vedeneeva, V.A. Zamathyrin, E.I. Tikhomirova, M.V. Istrashkina, et al., Innovative methods of surface and wastewater treatment using nanostructured sorbents, Innov. Activity, 1 (2014) 26–32.
  26. M.V. Istrashkina, O.V. Atamanova, E.I. Tikhomirova, Features of adsorption of aromatic amino compounds on various versions of modified bentonite, Proc. Samara Sci. Center Russian Acad. Sci., 18 (2016) 381–384.
  27. M.V. Istrashkina, O.V. Atamanova, E.I. Tikhomirova, N.V. Vedeneeva, Efficiency of a multicomponent adsorption filter with respect to organic compounds with different capacity for ionization in an aqueous medium (for example, o-toluidine, hydroquinone and p-dinitrobenzene), Proc. Samara Sci. Center Russian Acad. Sci., 18 (2016) 687–691.
  28. A.V. Kosarev, O.V. Atamanova, E.I. Tikhomirova, M.V. Istrashkina, Kinetics of adsorption of 2-methylaniline with modified bentonite during wastewater treatment, Water Ecol.: Prob. Solutions, 3 (2018) 24–31.
  29. E.I. Tikhomirove, Ed., Improving Sorption Methods for Purifying Polluted Natural and Waste Waters: A Collective Monograph, Yuri Gagarin State Technical University, Saratov, 2017.
  30. E.V. Vlasenko, I.A. Godunov, S.N. Lanin, Yu.S. Nikitin, T.D. Khokhlova, N.K. Shoni, Comparative analysis of the structural sorption characteristics of thermally expanded graphites and activated carbons in the purification of organic water, Moscow Univ. Chem. Bull., 46 (2005) 231–234.
  31. M.D. Nazarko, K.N. Romanova, S.Yu. Ksandopulo, V.G. Shcherbakov, A.V. Alexandrova, Sorbent for cleaning soils from oil pollution, Fundam. Res., 11 (2006) 96–97.
  32. Z. Terzopoulou, G.Z. Kyzas, D.N. Bikiaris, Recent advances in nanocomposite materials of graphene derivatives with polysaccharides, Materials (Basel), 8 (2015) 652–683.
  33. L. Zhao, P. Dong, J. Xie, J. Li, L. Wu, S.-T. Yang, J. Luo, Porous graphene oxide–chitosan aerogel for tetracycline removal, Mater. Res., 1 (2014) 245–247.
  34. R. Li, J.J. Wang, Z. Zhang, M.K. Awasthi, D. Du, P. Dang, Q. Huang, Y. Zhang, L. Wang, Recovery of phosphate and dissolved organic matter from aqueous solution using a novel CaO-MgO hybrid carbon composite and its easibility in phosphorus recycling, Sci. Total Environ., 642 (2018) 526–536
  35. R. Li, H. Deng, X. Zhang, J.J. Wang, M.K. Awasthi, Q. Wang, R. Xiao, B. Zhou, J. Du, Z. Zhang, High-efficiency removal of Pb(II) and humate by a CeO2–MoS2 hybrid magnetic biochar, Bioresour. Technol., 273 (2019) 335–340.
  36. R. Li, J.J. Wang, L.A. Gaston, B. Zhou, M. Li, R. Xiao, Q. Wang, Z. Zhang, An overview of carbothermal synthesis of metal–biochar composites for the removal of oxyanion contaminants from aqueous solution, Carbon, 129 (2018) 674–687.
  37. V.Ya. Varshavsky, L.S. Skvortsov, Modern fibrous materials for purification of liquid and gaseous media, Factory Economy, 6 (2004) 11–13.
  38. N.G. Skvortsov, T.A. Ananyeva, T.A. Khabazov, Fibrous sorbents for the extraction of nickel from wastewater, J. Appl. Chem., 5 (1989) 1161–1164.
  39. V.Ya. Varshavsky, Carbon Fibers, Aspect Press, Moscow, 2005.