Indium Extraction from Reiche Zeche Sphalerite and Community Analysis of Acidic Mine Water

Nadja Gelhaar; Simone Schopf; Michael Schlömann

doi:10.4028/www.scientific.net/AMR.1130.392

Paper Titles

Effect of Particle Size on the Column Bioleaching of Tibet Yulong Copper Ore
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Study on the Gold Recovery of Double Refractory Gold Ore Concentrate by Biological Oxidation Pretreatment
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Spectroscopic and Microscopic Investigation for Biohydrometallurgy
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Influence of Biological and Environmental Factors on Leaching Efficiency during Chalcopyrite Bioleaching Process
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Indium Extraction from Reiche Zeche Sphalerite and Community Analysis of Acidic Mine Water
p.392

Chalcopyrite Bioleaching at High Sulfate Concentrations
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Enhanced Column Bioleaching of Copper Sulfides by Forced Aeration
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Fluoride Toxicity in Bioleaching of Fluorapatite
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Roles of Oligotrophic Acidophiles (Alicyclobacillus) in Chalcopyrite Bioleaching System: Shake Flask Evaluation
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HomeAdvanced Materials ResearchAdvanced Materials Research Vol. 1130Indium Extraction from Reiche Zeche Sphalerite and...

Indium Extraction from Reiche Zeche Sphalerite and Community Analysis of Acidic Mine Water

Abstract:

During the process of industrialization, the world-wide demand for resources steadily increases. Significant amounts of crucial metals and metalloids remain in low grade mineral deposits, however using conventional metal extraction methods on these minerals is not environmentally feasible. To overcome these problems, biohydrometallurgy has become the focus of recent research. Biohydrometallurgy utilizes the activity of iron-oxidizing bacteria to catalyze the dissolution of sulfide minerals, in our case local sphalerite (ZnS), with the aim of winning zinc and indium. To achieve this enrichment cultures originating from waters of the Reiche Zeche mine in Freiberg, Germany, were used as inoculum for two acidic growth media. To explore the efficiency of the bioleaching process leaching tests have been performed in shaking-flasks under laboratory conditions. Ground ore from Reiche Zeche is mainly comprised of the sulfide minerals sphalerite, galena and pyrite. After the leaching process both the solution and the residue were analyzed either by ICP-MS or XRD.The results clearly show that it is possible to leach indium and zinc from natural sphalerite, but that leaching efficiency is hindered, and dissolved indium removed, by the formation of iron-hydroxy precipitates. Hence, optimal conditions for maximum indium recovery with minimal precipitation have to be determined by variation of physico-chemical parameters. Furthermore, the microbial diversity of Reiche Zeche mine waters were studied with cultivation dependent and independent methods.

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Periodical:

Advanced Materials Research (Volume 1130)

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392-395

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https://doi.org/10.4028/www.scientific.net/AMR.1130.392

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Online since:

November 2015

Authors:

Nadja Gelhaar*, Simone Schopf, Michael Schlömann

Keywords:

Bacterial Community Analysis, Bioleaching, Ore Material, Sphalerite

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References

[1] R. N. Kumar and R. Nagendran: J. of Hazardous Materials (2009) Vol. 169 p.1119–1126.

Google Scholar

[2] S. Mousavi, S. Yaghmaei, M. Vossoughi, R. Roostaazad, A. Jafari, M. Ebrahimi, O.C. Habibollahnia and I. Turunen: Bioresource Technology (2008) Vol. 99 p.2840–2845.

DOI: 10.1016/j.biortech.2007.06.009

Google Scholar

[3] W. Vishniac and M. Santer: Bacteriol Rev (1957) Vol. 21 p.195–213.

Google Scholar

[4] P. Olubambi, S. Ndlovu, J. Potgieter and J. Borode: Hydrometallurgy (2007) Vol. 86 p.96–104.

DOI: 10.1016/j.hydromet.2006.10.008

Google Scholar

[5] M.P. Silverman and D.G. Lundgren: J. Bacteriol. (1959) Vol. 77 p.642–647.

Google Scholar

[6] Y. Rodríguez: Hydrometallurgy (2003) Vol. 71 p.57–66.

Google Scholar

[7] S.M. Mousavi, S. Yaghmaei, M. Vossoughi, A. Jafari, R. Roostaazad and I. Turunen: Hydrometallurgy (2007) Vol. 85 p.59–65.

DOI: 10.1016/j.hydromet.2006.08.003

Google Scholar

[8] L. Ahonen and O.H. Tuovinen: Hydrometallurgy (1995) Vol. 37 p.1–21.

Google Scholar

[9] C. Gómez, M.L. Blázquez and A. Ballester: Miner. Eng. (1999) Vol. 12 p.93–106.

Google Scholar

[10] S.M. Mousavi, A. Jafari, S. Yaghmaei, M. Vossoughi amd R. Roostaazad: Hydrometallurgy (2006) Vol. 82 p.75–82.

DOI: 10.1016/j.hydromet.2006.03.001

Google Scholar

[11] J.S. Tischler, R.J. Jwair, N. Gelhaar, A. Drechsel, A.M. Skirl, C. Wiacek, E. Janneck and M. Schlömann: J. of Microbial Methods (2013) Vol. 95 p.138–144.

DOI: 10.1016/j.mimet.2013.07.027

Google Scholar

[12] B. Nazari, E. Jorjani, H. Hani, Z. Manafi and A. Riahi: Transactions of Nonferrous Metals Society of China (2014) Vol. 24 p.1152–1160.

DOI: 10.1016/s1003-6326(14)63174-5

Google Scholar