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

Denis W. Shiers; David M. Collinson; Helen R. Watling

doi:10.4028/www.scientific.net/SSP.262.233

Paper Titles

Biooxidation of a High-Grade Arsenopyritic Gold Ore Using a Mixed Culture of Moderate Thermophilic Microorganisms
p.215

Microbial Survey on Industrial Bioleaching Heap by High-Throughput 16S Sequencing and Metagenomics Analysis
p.219

Preliminary Study on In Situ Realtime Quantitation of Target Bacteria on the Principle of Flow Cytometry
p.224

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

HomeSolid State PhenomenaSolid State Phenomena Vol. 262The Impact of Heap Self-Heating on Microbial...

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

Abstract:

In this study, a dynamically-controlled column was used to evaluate two ores known to cause heap overheating. This enabled the simulation of heap self-heating under controlled conditions. The lixiviant was inoculated with a consortia of mesophilic and moderately thermophilic microorgaisms, and the impact of rapid temperature increases on biological activity and cell numbers was evaluated. During the leaching of ore sample A, the temperature lagged for 29 days before increasing rapidly from 26 to 88 °C. Cell numbers and solution potential increased concomitantly, before both were reduced as the temperature increased past maximum microbial tolerances. Cell numbers began increasing again within 10 days of reaching temperatures that would facilitate mesophilic growth being restored. During the leaching of ore B, the temperature lagged for 4 days before exhibiting a rapid increase in temperature, increasing from 30 to 76 °C over a six-day period. Cell numbers were reduced with the sudden temperature increase, and did not recover over the remainder of the experiment.

You might also be interested in these eBooks

22nd International Biohydrometallurgy Symposium

View Preview

Info:

Periodical:

Solid State Phenomena (Volume 262)

Pages:

233-236

DOI:

https://doi.org/10.4028/www.scientific.net/SSP.262.233

Citation:

Cite this paper

Online since:

August 2017

Authors:

Denis W. Shiers*, David M. Collinson, Helen R. Watling

Keywords:

Copper Sulfides, Heap Bioleaching, Microbial Activity, Self-Heating

Export:

RIS, BibTeX

Price:

Permissions CCC:

Request Permissions

Permissions PLS:

Request Permissions

Сopyright:

Citation:

* - Corresponding Author

References

[1] J. Petersen, D. Dixon, Thermophilic heap leaching of a chalcopyrite concentrate, Miner. Eng. 15 (2002) 777–785.

DOI: 10.1016/s0892-6875(02)00092-4

Google Scholar

[2] P.D. Franzmann, C.M. Haddad, R.B. Hawkes, W.J. Robertson, J.J. Plumb, Effects of temperature on the rates of iron and sulfur oxidation by selected bioleaching bacteria and archaea: application of the Ratkowsky equation, Miner. Eng. 18 (2005).

DOI: 10.1016/j.mineng.2005.04.006

Google Scholar

[3] H.R. Watling, The bioleaching of sulphide minerals with emphasis on copper sulphides - A review, Hydrometallurgy 84 (2006) 81–108.

DOI: 10.1016/j.hydromet.2006.05.001

Google Scholar

[4] D. Nordstrom, Thermochemical redox equilibria of Zobell's solution, Geochim. Cosmochim. Acta 41 (1977) 1835–1841.

DOI: 10.1016/0016-7037(77)90215-0

Google Scholar

[5] H.R. Watling, Microbiological advances in biohydrometallurgy, Minerals 6 (2016) 49.

Google Scholar

[6] D. Readett, L. Sylwestrzak, P.D. Franzmann, J.J. Plumb, W.R. Robertson, J.A.E. Gibson, H. Watling, The life cycle of a chalcocite heap bioleach system, in: C.A. Young, A.M. Alfantazi, C.G. Anderson, D.B. Dreisinger, B. Harris and A James (Eds. ), Hydrometallurgy 2003, TMS, Warrendale, 2003, p.365.

DOI: 10.1002/9781118804407

Google Scholar

[7] E.M. Cordoba, J.A. Munoz, M.L. Blazquez, F. Gonzalez, A. Ballester, Leaching of chalcopyrite with ferric ion. Part I: General aspects, Hydrometallurgy, 93 (2008) 81–87.

DOI: 10.1016/j.hydromet.2008.04.015

Google Scholar

[8] A.E. Norton, F.K. Crundwell, 2004. The HotHeapTM process for the heap leaching of chalcopyrite ores. In: SAIMM Colloquium: Innovations in Leaching Technologies (Saxonwold, RSA), SAIMM, Johannesburg, 2004, 24 pp.

Google Scholar