Effect of post-precipitation conditions on surface properties of colloidal metal sulphide precipitates.
Journal Article
2012
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Journal Title
Hydrometallurgy
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Elsevier
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University of Cape Town
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Abstract
Metal sulphide precipitation is important in several hydrometallurgical processes. However, challenges exist
in solid–liquid separation and recovery of the colloidal precipitates produced in some systems. This study
presents the effect of downstream processing options on the surface properties of colloidal particles produced
during copper and zinc sulphide precipitation. XRD and EDAX characterisation indicated the copper
precipitate was a mixture of covellite (63%) and copper hydroxysulphate (37%), while the zinc sulphide
was more pure, but less crystalline. The effect on surface charge and aggregation tendency of different
concentrations of background electrolyte (1–100 mM KCl), suspension pH, aqueous sulphide, a divalent
(Ca2+) and trivalent (Al3+) cation were studied. The magnitude of the negative surface charge increased
with increasing suspension pH (pH 6 to pH 11) for both copper and zinc precipitates. The addition of aqueous
sulphide (0.84 mM) to the zinc precipitate resulted in a significant decrease in the zeta potential and suppressed
aggregation, due to adsorption of the negatively charged sulphide ions. This effect was reduced at
high ionic strength. A higher sulphide concentration was required to replicate the phenomenon with the copper
precipitate due to sulphidisation of the copper hydroxysulphate initially. Addition of a divalent cation
(Ca2+) to the suspension had little effect on the surface charge of the particles and did not promote aggregation.
However, addition of a small amount (0.5 mM) of Al3+ ions resulted in a significant change in surface
charge (−30 to −10 mV for copper and −23 mV to −5 mV for zinc) and subsequent aggregation. The results
of this study show that downstream processing of colloidal metal sulphide precipitates, produced
where supersaturation cannot be managed, can lead to effective solid–liquid separation, by changing the surface
properties of the precipitate.
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Reference:
Mokone, T. P., Lewis, A. E., & van Hille, R. P. (2012). Effect of post-precipitation conditions on surface properties of colloidal metal sulphide precipitates. Hydrometallurgy, 119, 55-66.