Volume 5, Issue 4, August 2020, Page: 71-78
Carbon-in-Leach Gold Recovery from Fungi-treated Carbonaceous Ore: Effect of Entrained Biomass on Activity of Activated Carbon
Grace Ofori-Sarpong, Department of Minerals Engineering, University of Mines and Technology, Tarkwa, Ghana
Charles Ebenezer Abbey, Department of Materials Science and Engineering, Missouri University of Science and Technology, Rolla, USA
Nelson Akuoko Sarpong, Processing Section, Gold Fields Ghana Limited, Tarkwa, Ghana
Richard Kwasi Amankwah, Department of Minerals Engineering, University of Mines and Technology, Tarkwa, Ghana
Received: Jun. 30, 2020;       Accepted: Jul. 20, 2020;       Published: Jul. 30, 2020
DOI: 10.11648/j.eas.20200504.11      View  237      Downloads  112
The ability of the fungus, Phanerochaete chrysosporium to reduce preg-robbing of carbonaceous matter (CM) in gold ores has been confirmed by many researchers, and studies are ongoing to minimize the effect of entrained biomass on subsequent gold leaching and adsorption processes. This paper presents a study on gold extraction from surrogate carbonaceous gold ore (CGO), and fungal-treated CGO to ascertain the influence of entrained biomass on the downstream carbon-in-leach (CIL) process. The surrogate CGO was prepared by adding 3% anthracite-grade CM to free-milling gold ore (FGO). The main minerals in the FGO were quartz, feldspar and sericite, with 8.4 g/t gold, 0.18% sulphide sulphur and 0.06% organic carbon. Aside biotreatment of the CGO with cell-free liquor of P. chrysosporium, anthracite and activated carbon (AC) were also contacted with P. chrysosporium to confirm the direct effect of biomass on the CMs’ ability to preg-rob aurocyanide. Preg-robbing effect of the as-received anthracite and AC were 95% and 80% respectively, and these reduced to 81% and 13% respectively. Water-washing, acid-washing and alkaline-washing of the treated CMs returned respective preg-robbing effects of 88%, 92% and 85% for AC and 32%, 38% and 28% for anthracite. Scanning electron microscopy and Raman spectroscopy of anthracite revealed a decrease in the degree of orderliness in the structure required for gold adsorption. The FGO and the prepared CGO gave cyanidation gold recoveries of 94.5% and 54.8% respectively. Following cell-free treatment of the CGO, direct cyanidation recorded 88.3% solution recovery, which was increased to 91.3% in CIL. The overall recovery onto activated carbon in CIL was 81%, which improved to 82% and 85% respectively after washing the fungal-treated CGO with water and NaOH. The results here affirm that thorough washing of fungal-treated CGO assists in removing some entrained biomass. However, the results also call for additional studies on purification of the cell-free liquor to further minimize the biomass effect, and sustainability of the enzyme activity during pretreatment to enhance the overall gold recovery.
Carbon-in-Leach, Fungal Biomass, Activated Carbon, Anthracite, Carbonaceous Gold Ore, Free-milling Ore
To cite this article
Grace Ofori-Sarpong, Charles Ebenezer Abbey, Nelson Akuoko Sarpong, Richard Kwasi Amankwah, Carbon-in-Leach Gold Recovery from Fungi-treated Carbonaceous Ore: Effect of Entrained Biomass on Activity of Activated Carbon, Engineering and Applied Sciences. Vol. 5, No. 4, 2020, pp. 71-78. doi: 10.11648/j.eas.20200504.11
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