Column Bioleaching of a Saline, Calcareous Copper Sulfide Ore

Eva Pakostova; Barry Grail; D. Barrie Johnson

doi:10.4028/www.scientific.net/SSP.262.7

Column Bioleaching of a Saline, Calcareous Copper Sulfide Ore

Eva Pakostova
, Barry Grail
, D. Barrie Johnson

Research output: Contribution to journal › Article › peer-review

Abstract

“Deep in situ biomining”, widely considered to be a potentially environmentally-benign and cost effective biotechnology for extracting and recovering base metals from deep-buried base metal deposits, is being developed within the EU Horizon 2020 project “BioMOre”. Data are presented from non-aerated column experiments in which a saline, calcareous copper-rich ore (kupferschiefer) was subjected to a three-stage eaching protocol: (i) with water, to remove soluble salts; (ii) with sulfuric acid, to remove calcareous minerals and other acid-soluble salts; (iii) indirect bioleaching with a microbiologically-generated ferric iron lixiviant. Sequential leaching with water and acid removed ~85% of the chloride prior to bio-processing, while ~13% of the copper present in the ore was leached using sulfuric acid, and a further 39 - 59% by the lixiviant.

Original language	English
Pages (from-to)	7-11
Journal	Solid State Phenomena
Volume	262
DOIs	https://doi.org/10.4028/www.scientific.net/SSP.262.7
Publication status	Published - Aug 2017

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title = "Column Bioleaching of a Saline, Calcareous Copper Sulfide Ore",

abstract = "“Deep in situ biomining”, widely considered to be a potentially environmentally-benign and cost effective biotechnology for extracting and recovering base metals from deep-buried base metal deposits, is being developed within the EU Horizon 2020 project “BioMOre”. Data are presented from non-aerated column experiments in which a saline, calcareous copper-rich ore (kupferschiefer) was subjected to a three-stage eaching protocol: (i) with water, to remove soluble salts; (ii) with sulfuric acid, to remove calcareous minerals and other acid-soluble salts; (iii) indirect bioleaching with a microbiologically-generated ferric iron lixiviant. Sequential leaching with water and acid removed \textasciitilde{}85\% of the chloride prior to bio-processing, while \textasciitilde{}13\% of the copper present in the ore was leached using sulfuric acid, and a further 39 - 59\% by the lixiviant.",

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AU - Grail, Barry

AU - Johnson, D. Barrie

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AB - “Deep in situ biomining”, widely considered to be a potentially environmentally-benign and cost effective biotechnology for extracting and recovering base metals from deep-buried base metal deposits, is being developed within the EU Horizon 2020 project “BioMOre”. Data are presented from non-aerated column experiments in which a saline, calcareous copper-rich ore (kupferschiefer) was subjected to a three-stage eaching protocol: (i) with water, to remove soluble salts; (ii) with sulfuric acid, to remove calcareous minerals and other acid-soluble salts; (iii) indirect bioleaching with a microbiologically-generated ferric iron lixiviant. Sequential leaching with water and acid removed ~85% of the chloride prior to bio-processing, while ~13% of the copper present in the ore was leached using sulfuric acid, and a further 39 - 59% by the lixiviant.

U2 - 10.4028/www.scientific.net/SSP.262.7

DO - 10.4028/www.scientific.net/SSP.262.7

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VL - 262

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EP - 11

JO - Solid State Phenomena

JF - Solid State Phenomena

ER -

Column Bioleaching of a Saline, Calcareous Copper Sulfide Ore

Abstract

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