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Hydrometallurgical Processing of Copper-Arsenic Concentrates

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Extraction 2018

Part of the book series: The Minerals, Metals & Materials Series ((MMMS))

Abstract

Sulphidic copper concentrates are generally processed by pyrometallurgical means; while oxidative pressure leach processing of such materials has been shown to be technically feasible, there has traditionally been little incentive to choose this route in favour of a smelting option. However, for concentrates with elevated arsenic levels, oxidative pressure leaching offers distinct advantages, as smelter air emission standards and restrictions on concentrate importation have tightened. The current state of pressure leach technology allows for high copper extractions from arsenical copper concentrates, while producing an environmentally stable process residue, without atmospheric emissions of sulphur dioxide or arsenic. In its studies on pressure leaching of copper concentrates, Sherritt has shown that arsenical feed materials can be converted into environmentally stable residues, with excellent copper extractions. The results of recent batch and pilot plant test work are discussed, including the deportments of copper, arsenic and precious metals.

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References

  1. Vizsolyi A, Veltman H, Warren IH, Mackiw VN (1967) Copper and elemental sulphur from chalcopyrite by pressure leaching. J Metals 19(11):52–59

    CAS  Google Scholar 

  2. Swinkels GM, Berezowsky RMGS (1978) The Sherritt-Cominco copper process—part I: the process. CIM Bull 71:105–121

    CAS  Google Scholar 

  3. Barta L, Buban K, Stiksma J, Collins MJ (1999) Pressure leaching of chalcopyrite concentrates by Dynatec. In: Young SK, Dreisinger DB, Hackl RP, Dixon DG (eds) Copper 99, vol IV. Hydrometallurgy of Copper. TMS, Warrendale, PA, pp 167–180

    Google Scholar 

  4. Collins MJ, Holloway PC, Masters IM, Tuffrey NE, Yuan D, Lagno F, Obreque D (2014) Pilot plant pressure oxidation of codelco copper concentrate. In: Ugarte G (ed) Copper 2013, vol IV. Book 2. Hydrometallurgy. IIMCh, Santiago, Chile, pp 77–89

    Google Scholar 

  5. Buban K, Collins M, Holloway P (2016) Recovery of copper from arsenic-containing process feed, PCT Patent Application No. PCT/CA2016/000188

    Google Scholar 

  6. Kalanchey RM, Berezowsky RM, Collins MJ (2007) The treatment of arsenical materials in pressure leaching of copper concentrates at dynatec. In: Riveros PA, Dixon D, Dreisinger D, Collins MJ (eds) The John E. Dutrizac symposium on copper hydrometallurgy, Copper 2007—Cu2007 series vol IV. Book 2. CIM. Montreal, Canada, pp 133–148

    Google Scholar 

  7. Marsden JO, Brewer RE, Hazen N (2003) Copper concentrate leaching developments by phelps dodge corporation. In: Young CA, Alfantazi AM, Anderson CG, Dreisinger DB, Harris B, James A (eds) Hydrometallurgy 2003, vol 2. TMS, Electrometallurgy and Environmental Hydrometallurgy, pp 1429–1446

    Google Scholar 

  8. King JA (1997) Hydrometallurgical process for copper-containing materials. US Patent 5,698,170

    Google Scholar 

  9. Marsden JO et al (2004) Method for recovering metal values from metal-containing materials using high temperature pressure leaching. US Patent 6,680,034 B2

    Google Scholar 

  10. Palmer CM, Johnson GD (2005) The Activox® process: growing significance in the nickel industry. JOM 57(7):40–47

    Article  CAS  Google Scholar 

  11. Defreyne J, Brace T, Miller C, Omena A, Matos M, Cobral T (2008) Commissioning UHC: a vale copper refinery based on CESL technology. In: Young CA, Taylor PR, Anderson CG, Choi Y (Eds) Hydrometallurgy 2008. SME, pp 357–366

    Google Scholar 

  12. Berezowsky RMGS, Weir DR (1986) Process for the recovery of silver from a residue essentially free of elemental sulphur. US Patent 4,632,701

    Google Scholar 

  13. Collins MJ, Yuan D, Masters IM, Kalanchey R, Yan L (2013) Pilot plant pressure oxidation of a refractory gold-silver concentrate. CIM J 4(3):160–166

    CAS  Google Scholar 

  14. Gomez MA, Becze L, Cutler JN, Demopoulos GP (2011) Hydrothermal reaction chemistry and characterization of ferric arsenate phases precipitated from Fe2(SO4)3–As2O5–H2SO4 solutions. Hydrometallurgy 107:74–90

    Article  CAS  Google Scholar 

  15. Dutrizac JE (1990) Converting jarosite residues into compact hematite products. JOM 42(1):36–39

    Article  CAS  Google Scholar 

  16. Simmons GL, Gathje JC (2003) High temperature pressure oxidation of ores and ore concentrates containing silver using controlled precipitation of sulphate species. US Patent 6,641,642

    Google Scholar 

Download references

Author information

Authors and Affiliations

  1. Sherritt International Corporation, Fort Saskatchewan, AB, Canada

    Jan Smit, Kelvin Buban, Mike Collins & Preston Holloway

Authors
  1. Jan Smit
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  2. Kelvin Buban
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  3. Mike Collins
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  4. Preston Holloway
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Corresponding author

Correspondence to Jan Smit .

Editor information

Editors and Affiliations

  1. Kingston Process Metallurgy Inc., Kingston, Canada

    Boyd R. Davis

  2. Missouri University of Science and Technology, Rolla, USA

    Michael S. Moats

  3. Rio Tinto Kennecott Utah Copper Corporation, South Jordan, USA

    Shijie Wang

  4. RHI Magnesita, Leoben, Austria

    Dean Gregurek

  5. BBA Inc., Montreal, Canada

    Joël Kapusta

  6. Extractive Metallurgy Consultant, Kingston, Canada

    Thomas P. Battle

  7. Missouri University of Science and Technology, Rolla, USA

    Mark E. Schlesinger

  8. Aurubis, Hamburg, Germany

    Gerardo Raul Alvear Flores

  9. University of Queensland, Queensland, Australia

    Evgueni Jak

  10. XPS-Glencore, Falconbridge, Canada

    Graeme Goodall

  11. University of Utah, Salt Lake City, USA

    Michael L. Free

  12. University of British Columbia, Vancouver, Canada

    Edouard Asselin

  13. University of Lorraine, Vandœuvre-lès-Nancy, France

    Alexandre Chagnes

  14. University of British Columbia, Vancouver, Canada

    David Dreisinger

  15. Newmont Mining, Elko, USA

    Matthew Jeffrey

  16. University of Arizona, Tucson, USA

    Jaeheon Lee

  17. Miller Metallurgical Services Pty Ltd., Brisbane, Australia

    Graeme Miller

  18. University of Cape Town, Rondebosch, Australia

    Jochen Petersen

  19. Universidade Federal de Minas Gerais, Belo Horizonte, Brazil

    Virginia S. T. Ciminelli

  20. Shanghai University, Shanghai, China

    Qian Xu

  21. MetNetH20 Inc., Peterborough, Canada

    Ronald Molnar

  22. Hatch, Mississauga, Canada

    Jeff Adams

  23. University of British Columbia, Vancouver, Canada

    Wenying Liu

  24. SGS Minerals, Lakefield, Canada

    Niels Verbaan

  25. J.R. Goode and Associates Metallurgical Consulting, Toronto, Canada

    John Goode

  26. Avalon Rare Metals Inc., Toronto, Canada

    Ian M. London

  27. University of Toronto, Toronto, Canada

    Gisele Azimi

  28. SGS Minerals, Lakefield, Canada

    Alex Forstner

  29. Newmont Mining, Greenwood Village, USA

    Ronel Kappes

  30. Newmont Mining Corporation, Greenwood village, USA

    Tarun Bhambhani

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© 2018 The Minerals, Metals & Materials Society

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Smit, J., Buban, K., Collins, M., Holloway, P. (2018). Hydrometallurgical Processing of Copper-Arsenic Concentrates. In: Davis, B., et al. Extraction 2018. The Minerals, Metals & Materials Series. Springer, Cham. https://doi.org/10.1007/978-3-319-95022-8_103

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