Abstract
Understanding the changes of a mineral during ore processing is of capital importance for the development of strategies aimed at increasing the efficiency of metal extraction. This task is often difficult due to the variability of the ore in terms of composition, mineralogy and texture. In particular, surface processes such as metal re-adsorption (preg-robbing) on specific minerals are difficult to evaluate, even though they may be of importance as the re-adsorbed material can be blocking the valuable mineral and negatively affect the extraction process. Here, we show a simple yet powerful approach, through which surface processes in individual minerals are identified by combining polarization microscopy (MP) and X-ray photoelectron spectroscopy (XPS). Taking as an example a silver-containing polymetallic sulfide ore from the Peruvian central Andes (pyrite-based with small amounts of galena), we track the changes in the sample during the course of cyanidation. While polarization microscopy is instrumental for identifying mineralogical species, XPS provides evidence of the re-adsorption of lead on a pyrite surface, possibly as lead oxide/hydroxide. The surface of pyrite does not show significant changes after the leaching process according to the microscopic results, although forms of oxidized iron are detected together with the re-adsorption of lead by XPS. Galena, embedded in pyrite, dissolves during cyanide leaching, as evidenced by PM and by the decrease of XPS signals at the positions associated with sulfide and sulfate. At the same time, the rise of a lead peak at a different position confirms that the re-adsorbed lead species cannot be sulfides or sulfates. Interestingly, lead is not detected on covellite surfaces during leaching, which shows that lead re-adsorption is a process that depends on the nature of the mineral. The methodology shown here is a tool of significant importance for understanding complex surface processes affecting various minerals during metal extraction.
Highlights
Understanding the metallurgical behavior of an ore is key in determining the viability of a project in mineral processing
Polished sections were prepared by embedding ore samples in an epoxy resin, which after curing was polished to ensure flatness so that it can be characterized by polarization microscopy and X-ray photoelectron spectroscopy (XPS)
Polarization microscopy allowed for the identification of the most representative minerals in the ore
Summary
Understanding the metallurgical behavior of an ore is key in determining the viability of a project in mineral processing. Minerals with transition metals will have characteristic reflection indexes; other minerals (such as carbonates and silicates) do not reflect light and appear opaque. By combining experiments with reflected and transmitted polarized light, this technique allows for the identification of textures, alterations, intergrowths, among other characteristics of the mineral [2]. This technique is often complemented by more detailed microscopies, such as scanning electron microscopy (including its variant for quantitative evaluation of minerals, QEM-SCAN), which together provide complete information regarding the mineralogical composition of ores. Applied to different stages of a metallurgical process, these techniques allow for a better understanding of the effect of such process on specific minerals within the ore [3]
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