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International Journal Of Chemistry, Mathematics And Physics(IJCMP)

Magnetic Modification of Ion Exchange Processes

D.E. Kovtun , S.S. Dushkin


International Journal of Chemistry, Mathematics And Physics(IJCMP), Vol-8,Issue-2, April - June 2024, Pages 8-11 , 10.22161/ijcmp.8.2.2

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Article Info: Received: 28 Mar 2024; Received in revised form: 01 May 2024; Accepted: 08 May 2024; Available online: 19 May 2024

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Today, the ion exchange method is widely used in water treatment systems. Ion exchange systems are used to correct the mineral composition of water to the required standards; wastewater treatment; desalination and softening of natural waters. To present day, there are technical solutions to improve the process of water purification, treatment, softening and demineralization. They include: improvement of physical and chemical conditions; intensification of the ion exchange process; use of new ion exchange materials; modification of ion exchange resins; combination with other water treatment methods; modernization of equipment and designs of ion exchange devices. In order to improve the flow conditions and reduce the burden on the environment, it is promising to implement technologies aimed at intensifying the ion exchange process by activating the components of the process. The paper investigates the effect of magnetic modification on the intensification of ion exchange processes during the adjustment of the mineral composition of natural waters. The obtained results demonstrate the influence of the magnetic field on the ion exchange process.

ion exchange, magnetic modification, intensification, natural waters, correction of mineral composition, purification, softening, demineralization.

[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. - Р. 101-102. [in Ukranian]
[20] Lupa, L., & Cocheci, L. (2023). Heavy Metals Removal from Water and Wastewater. Heavy Metals - Recent Advances [Working Title].