Mechanism of Silver-Catalyzed Bioleaching of Enargite Concentrate

Keishi Oyama; Tsuyoshi Hirajima; Keiko Sasaki; Hajime Miki; Naoko Okibe

doi:10.4028/www.scientific.net/SSP.262.273

Paper Titles

Microbial Dissolution of Iron Surface Coatings in Industrial Minerals
p.255

Characterization and Localized Insight into Leaching of Sulfide Minerals
p.261

Method for the Recovery of Indium from Diluted Bioleaching Solutions
p.265

Changes in Metal Leachability through Stimulation of Iron Reducing Communities within Waste Sludge
p.269

Mechanism of Silver-Catalyzed Bioleaching of Enargite Concentrate
p.273

Bioleaching of Chalcopyrite with Two Different Metallogenic Types: A Mineralogical Perspective
p.277

Investigation of Controlled Redox Potential with Pyrite during Chalcopyrite Bioleaching by Mixed Moderately Thermophiles
p.281

From Knowledge to Best Practices in Bioleaching
p.285

Microbial Community Composition of Mine Wastes in Cornwall and West Devon (UK)
p.290

HomeSolid State PhenomenaSolid State Phenomena Vol. 262Mechanism of Silver-Catalyzed Bioleaching of...

Mechanism of Silver-Catalyzed Bioleaching of Enargite Concentrate

Abstract:

Silver-catalyzed bioleaching of enargite concentrate with three bacteria (Acidimicrobium ferrooxidans ICP, Sulfobacillus sibiricus N1, Acidithiobacillus caldus KU) and one archaeon (Ferroplasma acidiphilum Y) was conducted in order to elucidate the catalytic mechanism of silver sulfide in enargite bioleaching. Whereas Cu recovery remained relatively low (43%) and Fe dissolved completely without silver sulfide, Cu recovery was greatly enhanced (96%) and Fe dissolution was suppressed (29%) in the presence of 0.04% silver sulfide. In the latter case, 52% of the solubilized As was re-immobilized, in contrast to only 14% As re-immobilization in the former. The silver-catalyzed bioleaching (at 0.04% silver sulfide) proceeded at low redox potentials within the optimal range, which likely promoted enargite dissolution via formation of intermediate Cu₂S. XAFS analysis revealed that As was mainly immobilized as As (V), which was in agreement with the EPMA results detecting ferric arsenate passivation on some enargite grains. Furthermore, formation of trisilver arsenic sulfide (Ag₃AsS₄) was detected by XRD and EPMA, covering the surface of enargite particles. An intermediate layer, consisting of (Cu,Ag)₃AsS₄, was also observed between the enargite grain and trisilver arsenic sulfide layer, implying that Cu in enargite may be gradually substituted by solubilized Ag. The overall mechanism of silver-catalyzed bioleaching of enargite concentrate will be proposed.

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Solid State Phenomena (Volume 262)

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273-276

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https://doi.org/10.4028/www.scientific.net/SSP.262.273

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Online since:

August 2017

Authors:

Keishi Oyama, Tsuyoshi Hirajima, Keiko Sasaki, Hajime Miki, Naoko Okibe*

Keywords:

Arsenic, Bioleaching, Enargite, Silver Catalyst, Solution Redox Potential (Eh)

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References

[1] K. Takatsugi, K. Sasaki, T. Hirajima, Mechanism of the enhancement of bioleaching of copper from enargite by thermophilic iron-oxidizing archaea with the concomitant precipitation of arsenic, Hydrometallurgy. 109 (2011) 90-96.

DOI: 10.1016/j.hydromet.2011.05.013

Google Scholar

[2] K. Sasaki, K. Takatsugi, K. Kaneko, N. Kozai, T. Ohnuki, O.H. Tuovinen, T. Hirajima, Characterization of secondary arsenic-bearing precipitates formed in the bioleaching of enargite by Acidithiobacillus ferrooxidans, Hydrometallurgy. 104 (2010).

DOI: 10.1016/j.hydromet.2009.12.012

Google Scholar

[3] J.A. Muñoz, D.B. Dreisinger, W.C. Cooper, S.K. Young, Silver-catalyzed bioleaching of low-grade copper ores. Part I: Shake flasks tests, Hydrometallurgy. 88 (2007) 3-18.

DOI: 10.1016/j.hydromet.2007.01.007

Google Scholar

[4] N. Hiroyoshi, M. Arai, H. Miki, M. Tsunekawa, T. Hirajima, A new reaction model for the catalytic effect of silver ions on chalcopyrite leaching in sulphuric acid solutions, Hydrometallurgy. 63 (2002) 257-267.

DOI: 10.1016/s0304-386x(01)00228-6

Google Scholar

[5] H. Majima, How oxidation affects selective flotation of complex sulphide ores, Can. Metall. Quart. 8 (1969) 269-273.

DOI: 10.1179/cmq.1969.8.3.269

Google Scholar

[6] H. Miki, A. Iguchi, T. Hirajima, K. Sasaki, Catalytic effect of silver on arsenic-containing copper sulfide dissolution in acidic solution, Hydrometallurgy. 162 (2016) 1-8.

DOI: 10.1016/j.hydromet.2016.02.007

Google Scholar

[7] E.M. Córdoba, J.A. Muñoz, M.L. Blázquez, F. González, A. Ballester, Leaching of chalcopyrite with ferric ion. Part III: Effect of redox potential on the silver-catalyzed process, Hydrometallurgy. 93 (2008) 97-105.

DOI: 10.1016/j.hydromet.2007.11.006

Google Scholar