Deep Copper Recovery from Autogenous Smelting Slags under Strongly Reducing Conditions
DOI:
https://doi.org/10.31643/2028/6445.13Keywords:
copper slag processing, pyrometallurgical treatment, copper-bearing sulfide materials, reductive melting, sem analysis, metallurgical waste.Abstract
Deep reduction of copper smelting slags is a promising route to recover entrained non-ferrous metals and to generate slags suitable for further processing. This work investigates the depletion of fayalite–magnetite slags formed during autogenous smelting of copper concentrates in conditions simulating the oxidation and reduction zones of a two-zone Vanyukov furnace. Laboratory charges of 100 g, containing 14.63–16.82 wt.% Cu, 25.6–27.6 wt.% Fe, 30 wt.% S and 15 wt.% SiO₂, were smelted at 1350 °C with controlled oxygen injection to produce slags containing 0.93–1.54 wt.% Cu, 30.05–32.30 wt.% SiO₂ and 7.8–9.8 wt.% Fe₃O₄. Subsequent reduction at 1300 °C was carried out with activated carbon in a fivefold stoichiometric excess relative to magnetite, at an oxygen-containing blast flow rate of 5 L/h and a 1 h holding time. Chemical analysis shows that Fe₃O₄ in slag decreases from 7.8–7.95 wt.% to 2.5–2.6 wt.%, while copper content drops from 0.93–1.033 wt.% to 0.43–0.50 wt.% under oxygen partial pressures of 10⁻¹²–10⁻¹¹ atm. X-ray diffraction and electron microscopic studies reveal a transition from fayalite–magnetite slags with dispersed metallic copper and sulfides to fayalite-dominated matrices containing ferruginous sphalerite, copper minerals of the bornite–chalcopyrite type, iron oxides and glassy phases. Simultaneous thermal analysis demonstrates that all major endothermic and exothermic events are completed by 1300 °C, supporting this as an optimal temperature for deep slag depletion. The results define an operating window—slag composition, temperature, reductant dosage and pO₂—under which copper losses to slag can be reduced to about 0.5 wt.% in industrially relevant fayalite slags.
Downloads
References
Suh IK, Waseda Y, Yazawa A, Davenport WG. Some Interesting Aspects of Non-Ferrous Metallurgical Slags. High Temperature Materials and Processes. 1988; 8(1):65–88. https://doi.org/10.1515/HTMP.1988.8.1.65
Wan X, Taskinen P, Shi J, Jokilaakso A. A potential industrial waste–waste co-treatment process of utilizing waste SO2 gas and residue heat to recover Co, Ni, and Cu from copper smelting slag. Journal of Hazardous Materials. 2021; 414:125541. https://doi.org/10.1016/j.jhazmat.2021.125541
Kenzhaliyev BK, Kvyatkovskiy SA, Dyussebekova MA, Semenova AS, Nurhadiyanto D. Analysis of Existing Technologies for Depletion of Dump Slags of Autogenous Melting. Kompleksnoe Ispolzovanie Mineralnogo Syra = Complex Use of Mineral Resources. 2022; 323(4):23–29. https://doi.org/10.31643/2022/6445.36
Rusen A, Derin B, Geveci A, Topkaya YA. Investigation of copper losses to synthetic slag at different oxygen partial pressures in the presence of colemanite. JOM. 2016; 68(9):2316-2322. https://doi.org/10.1007/s11837-016-1954-6
Bellemans I, Cnockaert V, De Wilde E, Moelans N, Verbeken K. Metal Droplet Entrainment by Solid Particles in Slags: An Experimental Approach. Journal of Sustainable Metallurgy. 2018; 4(1):15-32. https://doi.org/10.1007/s40831-017-0145-1
Kongoli F, McBow I, Yazawa A. Phase relations of ferrous calcium silicate slag and its possible application in the industrial practice. High Temperature Materials and Processes. 2011; 30(4):491–504. https://doi.org/10.1515/HTMP.2011.072
Kolesnikov AS, Sapargaliyeva BO, Bychkov AY, Alferyeva YO, Syrlybekkyzy S, Altybaeva ZK, Suigenbayeva AZ. Thermodynamic modeling of the formation of the main minerals of cement clinker and zinc fumesin the processing of toxic technogenic waste of the metallurgical industry. Metallurgy. 2022; 15(3):2181-2187. https://doi.org/10.31788/RJC.2022.1536230
Kenzhaliyev B, Berkinbayeva A, Baltabekova Z, Moldabayeva G, Smailov K, Saulebekkyzy S, Tolegenova N, Karim D, Omirbek T. Investigation of Phase Transformations in Technogenic Raw Materials Under Microwave Treatment for Enhanced Zinc Leaching. Processes. 2025; 13(4):1099. https://doi.org/10.3390/pr13041099
Khudyakova TM, Kolesnikov AS, Zhakipbaev BE, Kenzhibaeva GS, Kutzhanova AN, Iztleuov GM, Mynbaeva E. Optimization of raw material mixes in studying mixed cements and their physicomechnical properties. Refractories and Industrial Ceramics. 2019; 60(1):76-81. https://doi.org/10.1007/s11148-019-00312-2
Akhmadiyeva N, Abdulvaliyev R, Gladyshev S, Sukurov B, Abikak Y, Manapova A, Bakhytuly N. Optimizing technological parameters for chromium extraction from chromite ore beneficiation tailings. Minerals. 2025; 15(6):555. https://doi.org/10.3390/min15060555
Ushakov AV, Karpov IV, Fedorov LY, Goncharova EA, Brungardt MV, Demin VG. Investigation of the Effect of Oxygen Partial Pressure on the Phase Composition of Copper Oxide Nanoparticles by Vacuum Arc Synthesis. Technical Physics. 2024; 69 (4):1069-1074. https://doi.org/10.1134/S106378422403040X
Ulianov VV, Koshelev MM, Kremlyova VS, Kharchuk SE. Investigations of the regularities of the accumulation of slags reduced by hydrogen in the loops with lead-containing coolants. Izvestiya Wysshikh Uchebnykh Zawedeniy, Yadernaya Energetika. 2021; 2021(2):119–131. https://www.doi.org/10.26583/npe.2021.2.11
Dosmukhamedov NK, Fedorov AN, Zholdasbay EE. Termodinamika vosstanovitel'nykh suspenzionnykh sistem CU-ME-FE-O-SIO2 (ME - PB, ZN, AS) na prirodnom gaze [Thermodynamics of Restorative Suspension CU-МЕ-FE-O-SIO2 (МЕ - PB, ZN, AS) Systems By Natural Gas]. Mezhdunarodnyy zhurnal prikladnykh i fundamental'nykh issledovaniy [International journal of applied and fundamental research]. 2019; 9:62–68. (in Russ.).
Anindya A, Swinbourne DR, Reuter MA, Matusewicz RW. Distribution of elements between copper and FeOx–CaO–SiO2 slags during pyrometallurgical processing of WEEE: Part 1 – Tin: Part 1 – Tin. Mineral Processing and Extractive Metallurgy: Transactions of the Institutions of Mining and Metallurgy: Section C. 2013; 122(3):165-173. https://doi.org/10.1179/1743285513Y.0000000043
Ospanov K, Smailov K, Nuruly Y. Patterns of non-traditional thermodynamic functions ΔrG0/n and ΔfG0(averaged) changes for cobalt minerals. Chemical Bulletin of Kazakh National University. 2020; 96(1):22-30. https://doi.org/https://doi.org/10.15328/cb1005
Wang Y, Zhang SA, Wang L, Qin W, Han J. An unconventional approach for the efficient recovery of iron, cobalt, copper and silicon from copper slag. Journal of Hazardous Materials. 2024; 476:135168. https://doi.org/10.1016/j.jhazmat.2024.135168
Abdulvaliev RA, Surkova TYu, Baltabekova ZhA, Yessimova DM, Stachowicz M, Smailov KM, Dossymbayeva ZD, Berkinbayeva AN. Effect of amino acids on the extraction of copper from sub-conditional raw materials. Kompleksnoe Ispolzovanie Mineralnogo Syra = Complex Use of Mineral Resources. 2025; 335(4):50-58. https://doi.org/10.31643/2025/6445.39
Kenzhaliev BK, Kvyatkovskii SA, Kozhakhmetov SM. Determination of Optimum Production Parameters for Depletion of Balkhash Copper-Smelting Plant Dump Slags. Metallurgist. 2019; 63(7):759–765. https://doi.org/10.1007/s11015-019-00886-9
Milanović D, Stanujkić D, Ignjatović MR. Comparative results of copper flotation from smelter slag and granulated smelter slag. Mining and Metallurgy Engineering Bor. 2013; (2):167-194. https://doi.org/10.5937/MMEB1302167M
Svantesson J, Kojola N, Ersson M. Numerical study on the effect of material parameters and process conditions on the melting time of hydrogen-direct reduced iron. Metallurgical and Materials Transactions B. 2025; 56(3):2846-2872. https://doi.org/10.1007/s11663-025-03504-z
Coursol P, Cardona VN, Mackey P, Bell S, Davis B. Minimization of copper losses in copper smelting slag during electric furnace treatment. Jom. 2012; 64(11): 305-1313. https://doi.org/10.1007/s11837-012-0454-6
Pancnehko SV, Dli MI, Borisov VV, Panchenko DS. Analysis of thermalphysic processes in near-electrode zone of electrothermal reactor. Non-ferrous metals. 2016; 2:57-64.
Chen M, Avarmaa K, Taskinen P, Michallik R, Jokilaakso A. An experimental study on the phase equilibria of FeOx-saturated iron silicate slags and metallic copper alloys at 1200–300°C. Calphad. 2022; 77:102418. https://doi.org/10.1016/j.calphad.2022.102418
Yazawa A, Takeda Y. Equilibrium Relations between Liquid Copper and Calcium Ferrite Slag. Transactions of the Japan Institute of Metals. 1982; 23(6):328–333. https://doi.org/10.2320/matertrans1960.23.328
Zuo Z, Yu Q, Wei M, Xie H. Thermogravimetric study of the reduction of copper slag by biomass: Reduction characteristics and kinetics. Journal of Thermal Analysis and Calorimetry. 2016; 126(2):481–491. https://doi.org/10.1007/s10973-016-5570-z
Selivanov EN, Tyushnyakov SN, Gulyaeva RI. Viscosity of the Slags of the Autogenous Smelting of Copper–Zinc Concentrates. Russian Metallurgy (Metally). Pleiades journals. 2020; 2020(9):959–963.
Zhou S, Wei Y, Zhang S, Li B, Wang H, Yang Y, Barati M. Reduction of copper smelting slag using waste cooking oil. Journal of Cleaner Production. 2019; 236:117668. https://doi.org/10.1016/j.jclepro.2019.117668
Kucharski M, Nowak D, Czerwinski A, Saternus M. A study on the copper recovery from the slag of the Outokumpu direct-to-copper process. Metallurgical and Materials Transactions B: Process Metallurgy and Materials Processing Science. 2014; 45(2): 590–602.
Sun J, Zhang T, Dong L, Zhu H, Shen P, Liu D. Eco-friendly recovery of copper from copper slag via magnetic separation followed by flotation: Experimental and mechanistic insights. Journal of Environmental Chemical Engineering. 2025; 13(2):115746. https://doi.org/10.1016/j.jece.2025.115746
Zhang C, Zhang Y, Zhang Z, Zhang G. Effective separation and recovery of valuable metals from copper slag: A comprehensive review. Environmental Research. 2025; 283:122145. https://doi.org/10.1016/j.envres.2025.122145
Akhmadiyeva N, Gladyshev S, Abdulvaliyev R, Abikak Y, Imangaliyeva L, Kasymzhanova A, Ruzakhunova G. Activation of Mineral Composition via Thermochemical Disintegration. Minerals. 2025; 15(9):1000. https://doi.org/10.3390/min15091000
Zhang B, Xiao W, Yang Y, Zhou S, Wei Y, Li B, Wang H. Copper separation from slag in varying oxygen partial pressures during converting. Metallurgical and Materials Transactions B. 2024; 55(1):495-511. https://doi.org/10.1007/s11663-023-02972-5
Ospanov YA, Kvyatkovskiy SA, Kozhakhmetov SM, Sokolovskaya LV, Semenova AS, Dyussebekova M, Shakhalov AA. Slag heterogeneity of autogenous copper concentrates smelting. Canadian Metallurgical Quarterly. 2023; 62(3):594-601. https://doi.org/10.1080/00084433.2022.2119495
Downloads
Published
How to Cite
Issue
Section
License
Copyright (c) 2026 D.Kh. Altybayeva, B.K. Kenzhaliyev, S.A. Kvyatkovskiy, M.A. Dyussebekova, B.E. Abdikerim, A.S. Semenova, A. Gemeal
This work is licensed under a Creative Commons Attribution-ShareAlike 4.0 International License.
