Hydrometallurgical Processing of Chalcopyrite by Attrition-Aided Leaching

We report the investigation of a chalcopyrite leaching process that implements millimeter-sized glass beads that are stirred in the leach reactor to combine particle grinding, mechanical activation, and surface removal of reaction products. The paper focuses on demonstrating the impact of the so-cal...

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Bibliographic Details
Published inACS Engineering Au Vol. 3; no. 3; pp. 195 - 209
Main Authors Dakkoune, Amine, Bourgeois, Florent, Po, Adeline, Joulian, Catherine, Hubau, Agathe, Touzé, Solène, Julcour, Carine, Guezennec, Anne-Gwénaëlle, Cassayre, Laurent
Format Journal Article
LanguageEnglish
Published American Chemical Society 21.06.2023
Subjects
Chemical engineering
Chemical Sciences
Material chemistry
attrition-leaching
particle size
depassivation
hydrometallurgy
chalcopyrite sulfuric leaching
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Summary:We report the investigation of a chalcopyrite leaching process that implements millimeter-sized glass beads that are stirred in the leach reactor to combine particle grinding, mechanical activation, and surface removal of reaction products. The paper focuses on demonstrating the impact of the so-called attrition-leaching phenomenon on the leaching rate of a chalcopyrite concentrate and provides a first understanding of the underlying mechanisms. For this purpose, we have compared the copper leaching yield for different configurations under controlled chemical conditions (1 kg of glass beads and 84 g of chalcopyrite concentrate in 2.5 L of H2SO4-H2O solution, pH = 1.3, E h = 700 mV vs SHE, and T = 42 °C). On top of elemental analysis of the leach solution with time, we provide a full characterization of the solid residue based on X-ray diffraction, elemental analysis, and sulfur speciation. We demonstrate that glass beads led to a remarkable enhancement of the leaching rate in conditions where particles were already passivated by simple leaching and even when large amounts of solid products (elemental sulfur and jarosite) were present. An in-depth evaluation of particle size distribution showed that particle breakage occurred during a rather short time (a few hours) at the beginning of the runs, transforming the initial particles with d 4/3 = 30 μm to finer particles with d 4/3 = 15 μm. Then, particle breakage almost stopped, while an attrition phenomenon was evidenced, inducing the formation of very fine particles (<1 μm) and aggregates concomitantly with copper leaching.
ISSN:2694-2488
2694-2488
DOI:10.1021/acsengineeringau.2c00051