Unravelling the Complexity of Heap Bioleaching

Jochen Petersen

doi:10.4028/www.scientific.net/SSP.262.246

Paper Titles

Investigating the Microbial Metabolic Activity on Mineral Surfaces of Pyrite-Rich Waste Rocks in an Unsaturated Heap-Simulating Column System
p.228

The Impact of Heap Self-Heating on Microbial Activity during the Bioleaching of Low-Grade Copper Sulfide Ores
p.233

Bioleaching of Low-Grade Chalcopyrite Ore by the Thermophilic Archaean Acidianus brierleyi
p.237

Influence of CO₂ Supplementation on the Bioleaching of a Copper Concentrate from Kupferschiefer Ore
p.242

Unravelling the Complexity of Heap Bioleaching
p.246

Copper Heap Bioleach Microbiology - Progress and Challenges
p.250

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

HomeSolid State PhenomenaSolid State Phenomena Vol. 262Unravelling the Complexity of Heap Bioleaching

Unravelling the Complexity of Heap Bioleaching

Abstract:

Heap and dump leaching of sulphide minerals have become well-established techniques for the processing of low grade ores, especially of copper, over the past 30 years. The oxidative dissolution of sulphides in heaps can be significantly enhanced by microbial colonies, but the complexities of the heap leach process overall often counteract the potential advantages, or prevent microbial colonisation and bioleaching in the first place. This overview discusses the multiple layers of complexities that govern percolation leaching processes, such as the interactions between mineral grains, particle pores and leach solution, microbial responses to solution chemistry typical of heaps, solution and solute transport in heterogeneous unsaturated ore beds, as well as heap aeration and microbial response to CO₂ supply. It becomes clear that economically successful heap bioleaching hinges on careful engineering and operation of the heap process as a whole to create an environment in which microbial colonies can thrive and the value metal is released sufficiently rapidly into solution.

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Periodical:

Solid State Phenomena (Volume 262)

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246-249

DOI:

https://doi.org/10.4028/www.scientific.net/SSP.262.246

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Online since:

August 2017

Authors:

Jochen Petersen*

Keywords:

Bioleaching, Heap Leaching

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