Bioelectrochemical Leaching of Copper Sulfide Minerals

Mohammad Ranjbar; Mohammadreza Esmailbagi; Mahin Schaffie

doi:10.4028/www.scientific.net/SSP.262.16

Paper Titles

Preface, Committees, Lecture Programme, Poster Presentations

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Column Bioleaching of a Saline, Calcareous Copper Sulfide Ore
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Production Development of Olimpiadinskoe Gold Processing Plant through BIONORD^® Technology Processing
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Bioelectrochemical Leaching of Copper Sulfide Minerals
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Bioleaching of Supergene Porphyry Copper Ores from Sungai Mak Gorontalo of Indonesia by an Iron- and Sulfur-Oxidizing Mixotrophic Bacterium
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Comparison of Reductive and Oxidative Bioleaching of Jarosite for Valuable Metals Recovery
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The MONDO Minerals Nickel Sulfide Bioleach Project: From Test Work to Early Plant Operation
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Recent Advances in Biomining and Microbial Characterisation
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Bioelectrochemical Leaching of Copper Sulfide Minerals

Abstract:

The objective of this study is to improve the understanding of copper sulfides dissolution and to use this knowledge for optimization of process parameters for commercial application of electrochemical bioleaching of chalcopyrite concentrates in stirred bioreactors. From the results of this study, the importance of the oxidation reduction potential (ORP) on the catalytic interaction between chalcopyrite and pyrite can be pointed out as the main parameters for successful bioprocessing of chalcopyrite concentrates. Under these conditions, the optimization of the average particle size of feed (D80) and adjusting the ORP in the range between 400-450 mV are important criteria for increasing the electrochemical bioleaching rate of chalcopyrite concentrates. It seems that the main reason for the increased copper recovery could be the control and prevention of chalcopyrite passivation resulting from improved galvanic interaction between copper sulfide minerals, here especially chalcopyrite and pyrite in the selected ORP range and the right particle size distribution of feed. At optimum conditions, the copper extraction from chalcopyrite flotation concentrate during 7 days of continuous electrochemical bioleaching operations in stirred tanks was about 95%, which should be high enough to justify the process economically.

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Periodical:

Solid State Phenomena (Volume 262)

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16-19

DOI:

https://doi.org/10.4028/www.scientific.net/SSP.262.16

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Online since:

August 2017

Authors:

Mohammad Ranjbar*, Mohammadreza Esmailbagi, Mahin Schaffie

Keywords:

Bioheap, Bioleaching, Bioreactor, Chalcopyrite, Copper Sulfides, Galvanic Interaction

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