ArticleName |
Effect of various factors on the physicochemical properties of cathodes during copper electrorefining |
ArticleAuthorData |
MMC Norilsk Nickel’s Polar Division, Norilsk, Russia:
D. D. Novikova, Principal Specialist at the Engineering Support Centre, e-mail: cisp@nornik.ru E. V. Shulga, Head of the Laboratory at the Engineering Support Centre, Candidate of Technical Sciences, e-mail: shulgaev@nornik.ru A. S. Rendov, Chief Engineer at the Electrowinning Section of the Copper Plant, e-mail: rendovas@nornik.ru V. A. Novoseltsev, Principal Specialist at the Science and Technology Directorate, e-mail: Novoseltsevva@nornik.ru |
References |
1. Levin A. I. Fundamentals of electrochemistry. Moscow : Metallurgizdat, 1963. 432 p. 2. Tarasov A. V. Production of non-ferrous metals and alloys: Reference book. In 3 vol. Vol. 1. General problems of metallurgy. Moscow : Metallurgiya, 2001. 344 p. 3. Baymakov Yu. V., Zhurin A. I. Hydrometallurgy and electrolysis. Moscow : Metallurgizdat, 1963. 616 p. 4. Rotinyan A. L., Tikhonov K. I., Shonina I. A. Theoretical electrochemistry. Ed. by A. L. Rotinyan. Leningrad : Khimiya, 1981. 424 p. 5. Volkhin A. I., Eliseev E. I., Zhukov V. P., Smirnov B. N. Copper for anodes and cathodes. Ed. by B. N. Smirnov. Chelyabinsk : Yuzhno-Uralskoe knizhnoe izdatelstvo, 2001. 431 p. 6. Mubarok Z., Filzwieser I., Paschen P. Dendritic Cathode Grown during cooper Electrorefining in the Presence of Solid Particles. Erzmetall. 2005. Vol. 58, No. 6. p. 315. 7. Antropov L. I. Effect of thiourea on the copper electrocrystallization process. Zhurnal prikladnoy khimii. 1954. Vol. XXVII, No. 1. pp. 55–63. 8. Gorelik S. S., Dobatkin S. V., Kaputkina L. M. Recrystallization of metals and alloys. Moscow : MISiS, 2005. 432 p. 9. Demin I. P., Rudoy V. M., Ostanin N. I., Plekhanov K. A. Understanding how impurities penetrate copper cathodes during electrolytic refining. Tsvetnye Metally. 2002. No. 5. pp. 23–28. 10. Demin I. P. Hidden mechanics behind accumulation of impurities in the cathode deposit during electrolytic refining of copper: Candidate of chemical sciences dissertation. Yekaterinburg : UPI, 2008. 11. Daldynbay A., Nefedov A. N., Nurmanova R. A., Nauryzbaev M. K. Understanding the effect of surface active agents during the initial stage of the copper electrodeposition process. Chemical Bulletin of Kazakh National University. 2017. No. 4. pp. 13–19. 12. Sekar R. Structural and morphological characteristics of nanocrystalline copper electrodeposits from acid sulphate electrolytes. The International Journal of Surface Engineering and Coatings. 2015. Vol. 93, Iss. 5. pp. 255–261. 13. Grujicic D., Pesic B. Electrodeposition of copper the nucleation mechanisms. Electrochimica Acta. 2002. Vol. 47, Iss. 18. pp. 2901–2912. 14. Stelter M., Bombach H. Process Optimization in copper Electrorefining. Advanced Engineering Materials. 2004. Vol. 6. pp. 558–562. 15. Yuryev A. I., Bolshakova O. V., Karpushova D. D. Dependence of physical properties of copper cathode on the concentration of surfactant in the electrolyte, which evens the surface of the cathode. XVI International Conference Surface Forces. Book of Abstracts. Kazan, Russia, 2018. p. 98. 16. Salimzhanova E. V., Devochkin A. I., Yudin E. V., Karpushova D. D. Development and indtroduction of technical solutions to bring the quality of Polar Division cathode copper to conformity with London Metal Exchange standard. Tsvetnye Metally. 2018. No. 6. pp. 44–51. 17. Yuriev A. I., Zolotoreva E. V., Karpushova D. D., Nosova O. V. Understanding the effect of electrolyte composition on the properties of copper cathodes produced by electrorefining. Nauchnyy vestnik Arktiki. 2018. No. 3. pp. 24–30. 18. Copper and copper alloys. Determination of spiral elongation number. BS EN 12893–2000. Published: 01.05.2020. 19. GOST 859–2014. Copper. Grades. Introduced: 01.03.2002. 20. Leuprecht G. Spiral elongation number and AR-value of copper rod in correlation to cathode quality. ISA Process Users Conference. Hitachi (Japan). 2004. 21. Kozlov S. L., Yudin E. V. Improvement of physical and mechanic characteristics of cathode copper. Tsvetnye Metally. 2013. No. 6. pp. 73–78. 22. Shivrin G. N. et al. The problems of copper and nickel electrowinning. Ryazan : Golos gubernii, 2011. pp. 25–54. 23. Gerlach J., Ziber H., Pawlek F. Possible application of organic additives (for electrolyte) in the copper electrolytic refining process. Express information. Tsvetnaya metallurgiya. 1968. No. 3. pp. 8–11. 24. Gomez H., Lizama H., Suarez C., Valenzuela A. Effect of thiourea concentration on the electrochemical behavior of gold and copper electrodes in presence and absence of Cu(II) ions. Journal of the Chilean Chemical Society. 2009. Vol. 54. pp. 439–444. 25. Safizaden F. Monitoring deposit properties and passivation of impure copper anodes by electrochemical noise measurements : presentee a la Faculte des etudes superieures de l’Universite Laval dans le cadre du programme de doctorat engnie des matriaux et de la metallurgie pour l’obtention du grade de de Philosophiae doctor (Ph.D.). Qubec, 2011. 258 p |