Interaction mechanism between galena and calcium and sulfate ions

Interaction mechanism between galena and calcium and sulfate ions

•The interference mechanisms of calcium and sulfate ions on the adsorption of xanthate on galena have been elucidated.•Calcium species interact with the oxidized sites (sulfate, carbonate, hydroxide) of the galena surface.•The presence of sulfate in solution contributes to the formation of passivati...

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Bibliographic Details
Published in:Minerals engineering Vol. 111; pp. 116 - 123
Main Authors: Elizondo-Álvarez, Martha Araceli, Flores-Álvarez, José Manuel, Dávila-Pulido, Gloria Ivone, Uribe-Salas, Alejandro
Format: Journal Article
Language:English
Published: Elsevier Ltd 01-09-2017
Subjects:
Adsorption
Contact angle
Galena
Microflotation
Pre-conditioning
Xanthate
Microflotation
Contact angle
Adsorption
Xanthate
Pre-conditioning
Galena
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Summary:•The interference mechanisms of calcium and sulfate ions on the adsorption of xanthate on galena have been elucidated.•Calcium species interact with the oxidized sites (sulfate, carbonate, hydroxide) of the galena surface.•The presence of sulfate in solution contributes to the formation of passivating lead sulfate layer on the galena surface. This paper presents and discusses measurements performed to study the interaction mechanism of calcium and sulfate with galena and their effect on xanthate adsorption. The results of collector adsorption show that regardless of the solution pH (5.5, 7.5 and 9.5), the presence of calcium and sulfate during the mineral pre-conditioning, decreases the adsorption of isopropyl xanthate onto galena. Microflotation measurements carried out at pH 9.5 show that at low concentrations of calcium and sulfate (below about 0.005mol/L), the recovery of galena is not affected. However, as the concentration of both ions increases, flotation recovery substantially decreases. Contact angle measurements corroborate this behavior: a relatively large contact angle in the absence of calcium and sulfate (i.e., 64°), and a significant decrease when these species are present (i.e., ca. 45°). The observed behavior suggests that calcium ion probably has a certain chemical affinity for the active sites of the galena, which hinders the occurrence of ion exchange collector-sulfate or collector-hydroxyl to form lead xanthate (PbX2), which is the species responsible for the enhanced hydrophobicity of the mineral. On the other hand, the adverse effect of the sulfate is probably due to the formation of a layer of lead sulfate on the galena surface, which acts as a barrier that hinders the interaction of the collector with the metallic sites of the mineral lattice, thus negatively affecting the chemisorption mechanism. Likewise, the decreasing of lead concentration in solution, in equilibrium with the precipitated PbSO4 and the sulfate, limits the precipitation/coagulation of lead xanthate in the vicinity of the interface. Electrochemical measurements corroborate the proposed mechanism.
ISSN:0892-6875
1872-9444
DOI:10.1016/j.mineng.2017.06.011