[1] Behnajady, B. and Moghaddam, J., "Statistical evaluation and optimization of zinc electrolyte hot purification process by Taguchi method", J. Cent. South Univ., 22 (6), 2066 (2015).
[2] Boyanov, B.S., Konareva, V.V. and Kolev, N.K., "Purification of zinc sulfate solutions from cobalt and nickel through activated cementation", Hydrometallurgy., 73 (1), 163 (2004).
[3] Behnajady, B., Balesini, A. and Moghaddam, J., "A new approach to the optimization of zinc electrolyte cold purification process by Taguchi’s method", Can. Metall. Q., 53 (3), 333 (2014).
[4] Dib, A. and Makhloufi, L., "Mass transfer correlation of simultaneous removal by cementation of nickel and cobalt from sulfate industrial solution containing copper: Part I: Onto rotating zinc electrode disc", Chem. Eng. J., 130 (1), 39 (2006).
[5] Bae, E. and Yoo, K., "Leaching behavior of valuable metals from by-product generated during purification of zinc electrolyte" Geosystem Eng., 19 (6), 312) 2016).
[6] Huang, Y., Zhang, Z., Cao, Y., Han, G., Peng, W., Zhu, X., Zhang, T.A. and Dou, Z., "Overview of cobalt resources and comprehensive analysis of cobalt recovery from zinc plant purification residue-a review", Hydrometallurgy., 193 (1), 105 (2020).
[7] Abbasi, P., Investigation of effective parameters on nickel and cadmium removal from ZnSO4 solution at mixed reactor and modeling of reactor performance, MS Thesis. University of Mohaghegh Ardabili, (2019).
[8] Zhang, B. Yang, C. Zhu, H. Li, Y. and Gui, W., "Kinetic modeling and parameter estimation for competing reactions in copper removal process from zinc sulfate solution", Ind. Eng. Chem. Res., 52, 17074 (2013).
[9] Nelson, A., Novel activators in cobalt removal from zinc electrolyte by cementation, MS Thesis. McGill University Montreal, Montreal, (1998).
[10] Lu, J., Dreisinger, D. and Rees, K., "Simultaneous removal of Co, Cu, Cd and Ni from zinc sulfate solution by zinc dust cementation", Hydrometallurgy., 197 (1), 105 (2020)
[11] Laatikainen, K., Lahtinen, M., Laatikainen, M. and Paatero, E., "Copper removal by chelating adsorption in solution purification of hydrometallurgical zinc production", Hydrometallurgy., 104 (1), 9 (2010).
[12] Karlsson, T., Cao, Y., Colombus, Y. and Steenari, BM., "Investigation of the kinetics and the morphology of cementation products formed during purification of a synthetic zinc sulfate electrolyte", Hydrometallurgy., 181 (1), 169 (2018).
[13] Lew, R.W., The removal of cobalt from zinc sulphate electrolytes using the copper-antimoney process, MS Thesis. University of British Columbia, (1994).
[14] Wang, L.Y., Gui, W.H., Teo, K.L., Loxton, R. and Yang, Ch.H., "Optimal control problems arising in the zinc sulfate electrolyte purification process", J. Glob Optim., 54 (2), 307 (2012).
[15] Xu, R., Ma, K. and Guo, Z., "Activation mechanism of Sb2O3 during removal of cobalt from zinc sulfate solution", Hydrometallurgy, 82 (3), 150 (2006).
[16] Halli, P., Agarwal, V., Partinen, J. and Lundström, M., "Recovery of Pb and Zn from a citrate leach liquor of a roasted EAF dust using precipitation and solvent extraction", Sep. Purif. Technol., 236 (1), 116 (2020).
[17] Vahidfard, V., "In study alternative cementation process with using manganometry for removing Cobalt from ZnSO4 solution". MS Thesis. University of Mohaghegh Ardabili (2019).
[18] Bøckman, O., Østvold, T., Voyiatzis, G. A. and Papatheodorou, G. N., "Raman spectroscopy of cemented cobalt on zinc substrates", Hydrometallurgy., 55, 93 (2000).
[19] Shayesteh, K., Abbasi, P., Vahid Fard, V. and Shahedi Asl, M., "Simultaneous removal of nickel and cadmium during the cold purification of zinc sulfate solution", Arab. J. Sci. Eng., 45 (2), 587 (2020).
[20] Younesi, S.R., Alimadadi, H., Keshavarz Alamdari, E. and Marashi S.P.H., "Kinetic mechanisms of cementation of cadmium ions by zinc powder from sulphate solutions", Hydrometallurgy., 84, 155 (2006).
[21] Pal, P., Nazim, M., Dutta, B. K. and AlShoaibi A., "Copper deposition and formation of nano-particles", Sep. Sci. Technol., 49, 2728 (2014).
[22] Karavasteva, M., "The effect of magnesium and zinc on indium cementation kinetics and deposit morphology in the presence of and without nonylphenylpolyethylene glycol", Hydrometallurgy, 150, 47 (2014).
[23] Zakeri, A., Bafghi, M. Sh. and Shahriari, Sh., "Dissolution kinetics of manganese dioxide ore in sulfuric acid in the presence of ferrous ion", Iran. J. Mater. Sci. Eng., 4 (3-4), 22 (2007).
[24] Krause, B. and Sandenbergh, R., "Optimization of cobalt removal from an aqueous sulfate zinc leach solution for zinc electrowinning", Hydrometallurgy, 155, 132 (2015).
[25] Zaheri, S., "High temperature and high pressure cobalt cementation onto zinc dust". MS Thesis. University of British Columbia (2015).
[26] Krause B. J., Optimization of the purification process of a zinc sulfate leach solution for zinc Electrowinning, MS Thesis, University of Pretoria, (2014).
[27] Abbasi, P., Shayesteh, K., Vahid Fard, V. and Hosseini, M., "Optimization of the nickel removal process from zinc sulfate solution using central composite design of experiments", Iran. J. Anal. Chem., 81, 17 (2021).
[28] Shayesteh, K., Abbasi, P., Vahid Fard, V. and Hosseini, M., "Providing practical instruction for solving environmental problems from residue (cake) of cold purification process in zinc production process", J. Environ. Sci. Technol., 23 (1), 53 (2021).
[29] Abbasi, P., Shayesteh, K., Vahid Fard, V. and Hosseini, M., "Optimization and comparison of ni and cd removal using zinc powder with the response surface methodology", Iran. J. Chem. Eng., 17 (4), 3 (2020).
[30] Güler, E. and Seyrankaya, A., "Precipitation of impurity ions from zinc leach solutions with high iron contents-A special emphasis on cobalt precipitation", Hydrometallurgy, 164, 118 (2016).
[31] Van der Pas V., A fundamental study of cobalt cementation with zinc dust in the presence of copper and antimony additives, MS Thesis, University of British Columbia, (1995).
[32] Boyanov, B.S., Konareva, V.V. and Kolev, N.K., "Purification of zinc sulfate solutions from cobalt and nickel through activated cementation", Hydrometallurgy, 73 (1), 163 (2004).
