[1] Savchenko, V., Sinyavsky, O., & Bunko, V. (2019). Influence of magnetic field on water. Energy and automation, 2019(1), 6-15.
[2] Smith, J., Jones, M., & Brown, A. (2021). Title of the article. Sustainability and Environment Research, 21(1), 1-10.
[3] Smith, J. (2014). The Magnetic Field Effects on Water and Its Magnetization. In Water . World Scientific Publishing. 203-324.
[4] Jawad, S. I., Karkush, M., & Kaliakin, V. N. (2023). Alteration of physicochemical properties of tap water passing through different intensities of magnetic field. Journal of the Mechanical Behavior of Materials, 32(1), 1-9.
[5] Zeron, I. M., Abascal, J. L. F., & Vega, C. (2019). A force field of Li+, Na+, K+, Mg2+, Ca2+, Cl−, and SO42− in aqueous solution based on the TIP4P/2005 water model and scaled charges for the ions. The Journal of Chemical Physics, 151(13), 134504, 2-17.
[6] Amor, H., Elaoud, A., & Hozayn, M. (2018). Does Magnetic Field Change Water pH?. Asian Research Journal of Agriculture, 8(1), 1-7.
[7] Wu, T., & Brant, J. A. (2020). Magnetic Field Effects on pH and Electrical Conductivity: Implications for Water and Wastewater Treatment. Environmental Engineering Science, 717-727.
[8] Boufa, N. K. (2021). Investigation of the Effect of Magnetic Field on some Physical Properties of Water. International Science and Technology Journal, 26, 18.
[9] Attan, N., et al. (2023). What is the Effect of a Magnetic Field on Dye Adsorption onto Graphite Carbon?. Malaysian Journal of Fundamental and Applied Sciences, 19(6), 1190-1202.
[10] Kontsur, A., Sysa, L., & Petrova, M. (2017). Investigation of copper adsorption on natural and microwave-treated bentonite. Eastern-European Journal of Enterprise Technologies, 6(6 (90)), 26-32.
[11] Kontsur, A. Z., & Sysa, L. V. (2018). Sorption of biogenic anions on bentonite stimulated by ultrahigh-frequency electromagnetic radiation. Visnyk Lvivskoho derzhavnoho universytetu bezpeky zhyttyediyalnosti, 13, 87-92. [in Ukranian]
[12] Polina Bozhedai, scientific supervisor – Tyutko S.M. Modern methods of water treatment. Electronic resource: Articles and theses - Professional College. Professional College - National University of Pharmacy. [in Ukranian]
[13] Dushkin, S., Martynov, S., & Dushkin, S. (2020). The increasing efficiency of upflow clarifiers at the drinking water preparation. Acta Periodica Technologica, 50, 17-27.
[14] Dushkin, S. (2023). Study of the process of activation of aluminum sulfate coagulant solutions during filtration on rapid filters. International Journal of Chemistry, Mathematics and Physics, 7(6), 01-06.
[15] Gomelia, M.D. Application of magnetite-modified cationite KU-2-8 for demanganisation of groundwater / Gomelia M.D., Trus I.M., Tverdokhlib M.M. // Chysta voda. Fundamental, applied and industrial aspects : materials of the VII International Scientific and Practical Conference, 25-26 November 2021, Kyiv - Kyiv : Igor Sikorsky Kyiv Polytechnic Institute, 2021. [in Ukranian]
[16] Xavier, C., & Jhonny, V. F. (2017). Application of the bipolar electrodialysis technique for the production of hydrochloric acid from wastewater regeneration of ion exchange resins. Journal of sciences and engineering, 1(1), 1-11.
[17] Kovtun, D., & Dushkin, S. (2023). Analysis of existing methods for improving the physical and chemical conditions of the ion exchange process in water treatment. Technogenic and Ecological Safety, 14(2/2023), 92-97.
[18] Karkush, M. O., Ahmed, M. D., & Al-Ani, S. M. A. (2019). Magnetic Field Influence on The Properties of Water Treated by Reverse Osmosis. Engineering, Technology & Applied Science Research, 9(4), 4433-4439.
[19] Study of the dynamics of ion exchange processes during water treatment. Proceedings of the international scientific and technical conference "New and non-traditional technologies in resource and energy conservation" 6-7 December 2023 - Odesa: 2023. - Ð . 101-102. [in Ukranian]
[20] Lupa, L., & Cocheci, L. (2023). Heavy Metals Removal from Water and Wastewater. Heavy Metals - Recent Advances [Working Title].