ArticleName |
Recycling
of red mud in iron-containing catalyst for oxidizing organic
impurities in waste water |
ArticleAuthorData |
Mendeleev University of Chemical Technology (Moscow, Russia)
T. V. Konkova, Dr. Eng., Prof., Dept. “Technology of inorganic substances and electrochemical processes”, e-mail: kontat@list.ru A. M. Gaydukova, Cand. Eng., Associate Prof., Dept. “Technology of inorganic substances and electrochemical processes”, e-mail: GaydukovaAM@yandex.ru E. Yu. Liberman, Dr. Chem., Prof., Dept. “Technology of inorganic substances and electrochemical processes”, e-mail: el-liberman@mail.ru A. A. Seitkasymova, Postgraduate Student, Dept. “Technology of inorganic substances and electrochemical processes», e-mail: seitkassymovaa@gmail.com |
References |
1. Zinoveev D. V., Grudinskiy P. I., Dyubanov V. G., Kovalenko L. V., Leontyev L. I.Review of the global practice of red mud processing. Part 1. Pyrometallurgical methods. Izvestiya vysshikh uchebnykh zavedeniy. Chernaya metallurgiya. 2018. Vol. 61. No. 11. pp. 843–858. 2. Vasyunina N. V., Dubova I. V., Druzhinin K. E., Gilmanshina T. R. Ferrum extraction in cast iron via reduction smelting of red mud. CIS Iron and Steel Review. 2023. Vol. 25. pp. 115–121. 3. Boyarintsev A., Aung H.Y., Stepanov S., Shoustikov A. Complex reprocessing of industrial alkaline waste of alumina production (red mud) for solving raw materials and environmental problems. E3S Web of Conferences. 2021. Vol. 258. No. 08026. 4. Pyagay I. N., Kozhevnikov V. L., Pasechnik L. A., Skachkov V. M. Processing of dump slime in alumina production with extraction of scandium concentrate. Zapiski gornogo instituta. 2016. Vol. 218. pp. 225–232. 5. Kuzin E., Kruchinina N., Kostyleva E. A Concept Scheme for the Joint Processing of Red Sludge and Large Tonnage Waste from the Oil and Petrochemical Industries. Ekologiya i promyshlennost Rossii. 2023. Vol. 27 (2). pp. 26–31. 6. Boyarintsev A. V., Aung H. Y., Stepanov S. I. Ivanov P. I., Giganov V. G. Evaluation of Main Factors for Improvement of the Scandium Leaching Process from Russian Bauxite Residue (Red Mud) in Carbonate Media. ACS Omega. 2022. Vol. 7 (1). pp. 259–273. 7. Poulin E., Blais J. F., Mercier G. Transformation of red mud from aluminium industry into a coagulant for wastewater treatment. Hydrometallurgy. 2008. Vol. 92 (16). pp. 17–25. 8. Wang X., Zhang Y., Lu R., Zhou F., An Q. Novel multiple coagulant from Bayer red mud for oily sewage treatment. Desalination and Water Treatment. 2015. Vol. 54. pp. 690–698. 9. Kyrii S., Dontsova T., Kosogina I., Astrelin I., Klymenko N. Local Wastewater Treatment by Effective Coagulants Based on Wastes. Journal of Ecological Engineering. 2020. Vol. 21 (5). pp. 34–41. 10. Orescanin V., Tibljas D., Valkovic V. A study of coagulant production from red mud and its use for heavy metals removal. Journal of trace and microprobe techniques. 2002. Vol. 20 (2). pp. 233–245. 11. Shaobin Wang S., Ang H. M., Tade M. O. Novel applications of red mud as coagulant, adsorbent and catalyst for environmentally benign processes. Chemosphere. 2008. Vol. 72. pp. 1621–1635. 12. Vu S. M., Nguen T. Z., Le T. M. Kh. Study of dyes adsorption from aqueous solution using red mud activated by sulfuric acid. Izvestiya vuzov. Khimiya i khimicheskaya tekhnoloogiya. 2019. Vol. 62. No. 11. pp. 143–149. 13. Naidu K. G., Krishna K. V., Rao K. K. Red mud and graphene oxide blend as an effective coagulant and adsorbent for the treatment of waste water from various industries. International Journal of Mechanical Engineering and Technology. 2019. Vol.10. Iss. 3. pp. 331–340. 14. Abbasi S. M., Abbasi A., Ghorbani A., Khalaj G. Synthesis, processing, characterization, and applications of red mud/carbon nanotube composites. Ceramics International. 2016. Vol. 42. Iss. 15. pp. 16738–16743. 15. Li C., Zeng H., Liu P., Yu J., Guo F., Xu G., Zhang Z.G. The recycle of red mud as excellent SCR catalyst for removal of NOx. RSC Advances. 2017. Vol. 7. No. 84. pp. 53622–53620. 16. Liberman E. Yu., Konkova T. B., Kleusov B. S., Semenov A. F., Seitkasymova A. A. Processing of Red Mud into Catalysts for the Treatment of Gas Emissions from Carbon Monoxide. Ekologiya i promyshlennost Rossii. 2023. Vol. 27 (10). pp. 36–41. 17. Aline A. S., Oliveira A. A., Costa D. A., Teixeira I. F., Moura F. C. Gold nanoparticles supported on modified red mud for biphasic oxidation of sulfur compounds: a synergistic effect. Applied Catalysis B: Environmental. 2015. Vol. 162. pp. 475–482. 18. Hu Z. P., Zhao H., Gao Z. M., Yuan Z. Y. High-surface-area activated red mud supported Co3O4 catalysts for efficient catalytic oxidation of CO. RSC Advances. 2016. Vol. 6. No. 97. pp. 94748–94755. 19. Cao J. L., Yan Z. L, Deng Q. F., Wang W. Mesoporous modifiedred-mud supported Ni catalysts for ammonia decomposition to hydrogen. International journal of hydrogen energy. 2014. Vol. 39. pp. 5747–5755. 20. Van Nguyen T. T., Nguyen T., Nguyen P. A., Pham T. T. P., Mai T. P., Truong Q. D., Ha H. K. P. Mn-Doped material synthesized from red mud and rice husk ash as a highly active catalyst for the oxidation of carbon monoxide and p-xylene. New Journal of Chemistry. 2020. Vol. 44. No. 46. pp. 20241–20252. 21. Chen J., Wang Y., Liu Z. Red mud-based catalysts for the catalytic removal of typical air pollutants: A review. Journal of Environmental Sciences. 2023. Vol. 127. pp. 628–640. 22. Chen H., Long Q., Wei F., Wei Z., Liu M. Enhanced Fenton removal of phenol catalyzed by a modifed red mud derived from the reduction of oxalic acid and l ascorbic acid. Environmental Science and Pollution Research. 2022. Vol. 29. pp. 63216–63226. 23. Luhua S., Guangtao W.; Yizhi W., Zhongmin L.; Linye Z. Preparation and application of acidified/calcined red mud catalyst for catalytic degradation of butyl xanthate in Fenton-like process. Environmental Science and Pollution Research. 2016. Vol. 23 (15). pp. 15202–15207. 24. Li W., Wei G., Shao L., Li Z., Yu F., Yang X. Green synthesis of red mud based ZnO-Fe2O3 composite used for photo-Fenton reaction under visible light. Journal of Cleaner Production. 2019. Vol. 207. pp. 717–727. 25. Dharitri R., Binita N., Kulamani P. Sustainable nano composite of mesoporous silica supported red mud for solar powered degradation of aquatic pollutants. Journal of Environmental Chemical Engineering. 2017. Vol. 5 (6). pp. 6137–6147. 26. Bento N., Santos I., Souza P. S. C, Oliveira T. E., Castro L. C. A. Composites based on PET and red mud residues as catalyst for organic removal from water. Journal of Hazardous Materials. 2016. Vol. 314. pp. 304–311. |