Recovery of Zinc during the Pre-Treatment of a Refractory Gold-Bearing Ore

Natalia Marchevsky; María Sofía Urbieta; Cecilia Bernardelli; Miguel Mas; Edgardo Donati

doi:10.4028/www.scientific.net/AMR.825.431

Paper Titles

Minimum Aeration in Acidithiobacillus ferrooxidans Cultures Required to Maintain Substrate Oxidation without Oxygen Limitation
p.414

Molybdenite Bioleaching by Thermophilic Bacteria in a RELVA-ARBP Bioreactor
p.418

Potassium Extraction from Biotite by Penicillium and Aspergillus
p.423

Pretreatment of Refractory Gold Ores Using Cell-Free Extracts of P. chrysosporium: A Preliminary Study
p.427

Recovery of Zinc during the Pre-Treatment of a Refractory Gold-Bearing Ore
p.431

Substrate Utilisation and Chalcopyrite Concentrate Bioleaching at 60°C in the Presence of Nitrate
p.435

Synthesis of Biogenic Mn Oxide and its Application as Lithium Ion Sieve
p.439

The Bioleaching Characteristics of Chalcopyrite with Different Genetic Types
p.443

The Effect of Ferrous Iron Addition during Tetrathionate Utilisation by Some Sulfobacillus Species
p.447

HomeAdvanced Materials ResearchAdvanced Materials Research Vol. 825Recovery of Zinc during the Pre-Treatment of a...

Recovery of Zinc during the Pre-Treatment of a Refractory Gold-Bearing Ore

Abstract:

Mesophilic bacteria were enriched from samples collected from acid mine drainages in La Carolina (San Luis, Argentina). Two enrichments, E1 and E2, showed suitable rates for iron or sulphur oxidation, respectively. Both enrichments were characterized by FISH analysis. They were mainly composed by Leptospirillum ferrooxidans and Acidithiobacillus ferrooxidans respectively. Studies with both, mixed and individual enrichments, showed biooxidation (measured as iron solubilisation) of a refractory gold-bearing pyrite ore from Hualilán (San Juan, Argentina). Pyrite and sphalerite were the main mineral species in the ore with 7% w/w and 8% w/w of iron and zinc and approximately 25 ppm of gold. Leaching experiments (2% w/v ore, 1.8 initial pH, 180 rpm and 30°C) were carried out with the addition of different alternative energy sources (6.67 g/L sulphur powder, 1 g/L ferrous iron, 0.02% w/v yeast extract). Redox potential, pH, ferrous iron concentration and total Fe and Zn were measured regularly. A 100% of iron leaching (after 28 days in the best experimental condition) was observed in some of the cultures. In other systems high zinc release was obtained (100% of dissolution after 28 days in the best experimental condition). Our results strongly suggest that under the correct operating conditions, biooxidation pre-treatment can be used to recover zinc as a subproduct of gold extraction from refractory ore.

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Advanced Materials Research (Volume 825)

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431-434

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https://doi.org/10.4028/www.scientific.net/AMR.825.431

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Online since:

October 2013

Authors:

Natalia Marchevsky, María Sofía Urbieta, Cecilia Bernardelli, Miguel Mas, Edgardo Donati

Keywords:

Bioleaching, Gold-Bearing Ore, Recovery of Zinc

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