Real-solution stability diagrams for copper-ammonia-chloride-water system

Xi Wang; Qi-yuan Chen; Zhou-lan Yin; Hui-ping Hu; Zhong-liang Xiao

doi:10.1007/s11771-011-0657-y

Journal of Central South University ›› 2011, Vol. 18 ›› Issue (1) : 48 -55. DOI: 10.1007/s11771-011-0657-y

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Real-solution stability diagrams for copper-ammonia-chloride-water system

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Abstract

A comprehensive thermodynamic model, which combined the Helgeson-Kirkham-Flowers (HKF) equation of state for standard-state thermodynamic properties of all species with realistic activity coefficient model developed by BROMLEY, was used to calculate the thermodynamic equilibrium, and a graphical method was developed to construct predominance existence diagrams (PED) for copper-ammonia-chloride in the presence of realistically modeled aqueous solutions. The existence of the different predominant chemical species for Cu(II) predicted by the diagrams was corroborated by spectrophotometrical studies and X-ray diffractometry. The simulated and experimental results indicate that the predominance of a given species in solution strongly depends on the pH value in this system. More quantitative information on real copper hydrometallurgy in the presence of ammonia and chloride can be obtained from these diagrams compared with the conventional predominance existence diagrams.

Keywords

stability diagrams / copper / ammonia / chloride / thermodynamics / real solution

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Xi Wang, Qi-yuan Chen, Zhou-lan Yin, Hui-ping Hu, Zhong-liang Xiao. Real-solution stability diagrams for copper-ammonia-chloride-water system. Journal of Central South University, 2011, 18(1): 48-55 DOI:10.1007/s11771-011-0657-y

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References

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[1]	EkmekyaparA., OyaR.. Dissolution kinetics of an oxidized copper ore in ammonium chloride solution [J]. Chemical and Biochemical Engineering Quarterly, 2003, 17(4): 261-266

[2]	BingolD., CanbazogluM., AydoganS.. Dissolution kinetics of malachite in ammonia/ammonium carbonate leaching [J]. Hydrometallurgy, 2005, 76(1/2): 55-62

[3]	YartasiA., CopurM.. Dissolution kinetics of copper(II) oxide in ammonium chloride solutions [J]. Minerals Engineering, 1996, 9(6): 693-698

[4]	McdonaldR. G., MuirD. M.. Pressure oxidation leaching of chalcopyrite (Part II): Comparison of medium temperature kinetics and products and effect of chloride ion [J]. Hydrometallurgy, 2007, 86(3/4): 206-220

[5]	LuZ. Y., JeffreyM. I., LawsonF.. The effect of chloride ions on the dissolution of chalcopyrite in acidic solutions [J]. Hydrometallurgy, 2000, 56(2): 189-202

[6]	TANG Yue-fei. Potential-pH relationship in the complex system [J]. Nonferrous Metals, 1979(2): 28–30. (in Chinese)

[7]	FU Chong-yue, ZHENG Di-ji. Thermodynamic study on the system Cu-NH₃-H₂O complexes [J]. Journal of Central South Institute of Mining and Metallurgy, 1979(1): 27–37. (in Chinese)

[8]	LuoR.-tie.. Overall equilibrium diagrams for hydrometallurgical systems: Copper-ammonia-water system [J]. Hydrometallurgy, 1987, 17(2): 177-199

[9]	LI Hao-yue, ZHENG Di-ji, FU Chong-yue. Equilibrium study of the Cu-Cl-H₂O system [J]. Journal of Central South Institute of Mining and Metallurgy, 1982(3): 39–45. (in Chinese)

[10]	FU Chong-yue, ZHENG Di-ji. Thermodynamic analysis on the Cu-Cl-H₂O system and its potential-pH diagrams [J]. Journal of Central South Institute of Mining and Metallurgy, 1980(3): 12–23. (in Chinese)

[11]	NilaC., Gonz LezI.. Thermodynamics of Cu-H₂SO₄-Cl—H₂O and Cu-NH₄Cl-H₂O based on predominance-existence diagrams and Pourbaix-type diagrams [J]. Hydrometallurgy, 1996, 42(1): 63-82

[12]	Vazquez-ArenasJ., LazaroI., CruzR.. Electrochemical study of binary and ternary copper complexes in ammonia-chloride medium [J]. Electrochimica Acta, 2007, 52(20): 6106-6117

[13]	HelgesonH. C., KirkhamD. H.. Theoretical prediction of the thermodynamic behavior of aqueous electrolytes at high pressures and temperatures: I. Summary of the thermodynamic/electrostatic properties of the solvent [J]. American Journal of Science, 1974, 274: 1089-1199

[14]

HelgesonH. C., KirkhamD. H., FlowersG. C.. Theoretical prediction of the thermodynamic behavior of aqueous electrolytes at high pressures and temperatures (IV): Calculation of activity coefficients, osmotic coefficients, and apparent molal and standard and relative partial molal properties to 600 °C and 5 kb [J]. American Journal of Science, 1981, 281: 1249-1516

[15]	TangerJ. C., HelgesonH. C.. Calculation of the thermodynamic and transport properties of aqueous species at high pressures and temperatures: Revised equations of state for standard partial molal properties of ions and electrolytes [J]. American Journal of Science, 1988, 288(1): 19-98

[16]	SverjenskyD. A., ShockE. L., HelgesonH. C.. Prediction of the thermodynamic properties of aqueous metal complexes to 1 000 °C and 5 kb [J]. Geochim Cosmo Acta, 1997, 61(7): 1359-1412

[17]	MartellA. E., SmithR. M.NIST standard reference database 46, Version 7.0 [M], 2003, Gaithersburg, USA, NIST

[18]	SmithR. M., MartellA. E.NIST Critical stability constants of metal complexes database, Ver. 5.0 [M], 1998, Gaithersburg, MD, USA, NIST: 643-652

[19]	SmithR. M., MartellA. E.NIST critically selected stability constants of metal complexes database, Version 3.0 [M], 1997, Gaithersburg, MD, USA, NIST: 246-264

[20]	SmithR. M., MartellA. E.Critical stability constants [M], 1976, New York and London, Plenum Press: 257-286

[21]	BALL J W, NORDSTROM D K. User’s manual for WATEQ4F, with revised thermodynamic data base and test cases for calculating speciation of major, trace, and redox elements in natural waters, USGS-OFR-91-183 [R]. U.S. Geological Survey, Menlo Park, California.

[22]	GubeliA. O., HebertJ., CoteP. A., TaillonR.. The action of the simple and mixed complex-species of copper(II) with hydroxide and ammonia as ligands [J]. Helvetica Chimica Acta, 1970, 53: 186-197

[23]	LimpoJ. L., LuisA., CristinaM. C.. Solubility of cupric chloride in ammoniacal ammonium chloride solutions [J]. Rev Metal Madrid, 1993, 29: 27-35

[24]	SolisJ. S., HefterG., MayP. M.. Chemical speciation in the copper(I)-ammonia-chloride system [J]. Australian Journal of Chemistry, 1995, 48: 1283-1292

[25]	StankovicZ. D.. The effect of Cl(I) ions on kinetics and mechanism of anodic dissolution and cathodic deposition of copper [J]. Electrochimica Acta, 1984, 29(3): 407-409

[26]	GorbunovaI. V., LyaminaL. I., GorbunovaK. M.. Some kinetics on cathodic solid-phase reduction of copper(I) oxide [J]. Soviet Electrochemistry, 1987, 23: 1027-1033

[27]	KhanM. A., Schwing-WeillM. J.. Stability and electronic spectra of the copper(II) chloride complexes in aqueous solutions [J]. Inorganic Chemistry, 1976, 15(9): 2202-2205

[28]	LeverA. B. P.Inorganic electronic spectroscopy [M], 1984, Amsterdam, Elsevier: 554-572

[29]	BjerrumJ., BallhausenC. J., JorgensenC. K.. Studies on absorption spectra (I): Results of calculations on the spectra and configuration of copper(II) ions [J]. Acta Chemica Scandinavica, 1954, 8: 1275-1289