Behavior of arsenic in hydrometallurgical zinc production and environmental impact

1. Boyanov, B. & Peltekov, A. (2012). X-Ray, DTA and TGA analysis of zinc sulfide concentrates and study of their charging for roasting in fl uidized bed furnace. Bulgarian Chemical Communications (44 Spec. Issue), 17-23.Search in Google Scholar

2. Arias-Arce, V., Coronado-Falcón, R., Puente Santibáñez, L. & Lovera-Dávila, D. (2005). Refractory of gold concentrate. Revista del Instituto de Investigación FIGMMG (8) 5-16.Search in Google Scholar

3. Monhemius, A.J. & Swash, P.M. (1999). The Removal and Stabilization of Arsenic from Copper Refining Circuits by Hydrothermal Processing. J. Miner. Met. Mat. Soc. 51 (9) 30-34.Search in Google Scholar

4. Yuhu, L., Zhihong, L., Qihou, L., Zhongwei, Z., Zhiyong, L. & Zeng, L. (2011). Removal of arsenic from arsenate complex contained in secondary zinc oxide. Hydromettalurgy 108 (3-4), 165-170.Search in Google Scholar

5. Shibayama, A., Takasaki, Y., William, T., Yamatodani, A., Higuchi, Y., Sinagawa, S. & Ono, E. (2010). Treatment of smelting residue for arsenic removal and recovery of copper using pyro-hydrometallurgical process. J. Hazard. Mater. (180), 1016-1023. DOI: 10.1016/j.jhazmat.2010.05.116.10.1016/j.jhazmat.2010.05.116Search in Google Scholar

6. Sander, U.F.H. (1984). Sulphur, sulphur dioxide, and sulphuric acid: An introduction to their industrial chemistry and technology. British Sulphur Corporation. Verlag Chemie International; English ed edition, p. 415. ISBN-10: 0902777645. ISBN-13: 978-0902777644.Search in Google Scholar

7. Mutler, W. & Warren, G. (2009). Burning pyrites compared to sulphur, Sulphur and Sulphuric Acid Conference, 4-6 May 2009 (147-156). Johannesburg, South Africa.Search in Google Scholar

8. Langmuir, D., Mahoney, J. & Rowson, J. (2006). Solubility products of amorphous ferric arsenate and crystalline scorodite (FeAsO4 · 2H2O) and their application to arsenic behavior in buried tailings. Geochim. Cosmochim. Acta. (70) 2942-2956.10.1016/j.gca.2006.03.006Search in Google Scholar

9. Zhu, Y. & Merkel, B.J. (2001). The Dissolution and Solubility of Scorodite, FeAsO4 · 2H2O: Evaluation and Simulation with PHREEQC2. Wiss. Mitt. Inst. für Geologie, TU Bergakedemie Freiberg, Germany (18) 1-12.Search in Google Scholar

10. Fleming, C.A. (2009). Basic iron sulphate - a potential killer for pressure oxidation processing of refractory gold concentrates if not handled appropriately. SGS Minerals Services, Technical paper -06.Search in Google Scholar

11. Papangelakis, V.G. & Demopoulos, G.P. (1990). Acid Pressure Oxidation of Arsenopyrite: Part I, Reaction Chemistry, Can. Metallur. Q. 29 (1) 1−12.10.1179/cmq.1990.29.1.1Search in Google Scholar

12. Papangelakis, V.G. & Demopoulos, G.P. (1990). Acid Pressure Oxidation of Arsenopyrite: Part II, Reaction Kinetics, Can. Metallurg. Q. 29 (1) 13−20.Search in Google Scholar

13. Swash, P.M. & Monhemius, A.J. (1994). Hydrothermal precipitation from aqueous solutions containing iron (III), arsenate and sulphate. International Symposium “Hydrometallurgy ’94” 11-15 July 1994, Cambridge, England, 177−190.10.1007/978-94-011-1214-7_10Search in Google Scholar

14. Jia, Y.F., Demopoulos, G.P., Chen, N., Cutler, J.N. & Jiang, D.T. (2003). Preparation, characterization and solubilities of adsorbed and co-precipitated iron (III)-arsenate solids (Conference Paper). Proceedings of the TMS Fall Extraction and Processing Conference 2 (2003) 1923-1935, Hydrometallurgy 2003: Proceedings of the 5th International Symposium, 24-27 August 2003, Vancouver, Canada, Code 62514.Search in Google Scholar

15. Dutrizac, J.E., Jambor, J.L. & Chen, T.T. (1987). Behaviour of Arsenic During Jarosite Precipitation: Reactions at 150 degree C and the Mechanism of Arsenic Precipitation. Can. Metallurg. Q. 26 (2) 103−115.10.1179/cmq.1987.26.2.103Search in Google Scholar

16. Dutrizac, J.E. & Jambor, J.L. (1987). Behaviour of Arsenic During Jarosite Precipitation: Arsenic Precipitation at 97 degree C from Sulphate or Chloride Media. Can. Metallurg. Q. 26 (2) 91−101.10.1179/cmq.1987.26.2.91Search in Google Scholar

17. Filippou, D. & Demopoulos, G.P. (1997). Arsenic immobilization by controlled scorodite precipitation (Review). JOM 49 (1-2), 52−55.Search in Google Scholar

18. De Klerk, R. J., Jia, Y., Daenzer, R., Gomez, M.A. & Demopoulos, G.P. (2012). Continuous circuit coprecipitation of arsenic(V) with ferric iron by lime neutralization: Process parameter effects on arsenic removal and precipitate quality. Hydrometallurgy 111-112 (1), 65−72.10.1016/j.hydromet.2011.10.004Search in Google Scholar

19. Ugarte, F.J.G. & Monhemius, A.J. (1992). Characterisation of high - temperature arsenic - containing residues from hydrometallurgical processes. Hydrometallurgy 30 (1-3), 69−86.10.1016/0304-386X(92)90078-ESearch in Google Scholar

20. Jia, Y., Demopoulos, G.P., Chen, N. & Cutler, J. (2005). Coprecipitation of As(V) with Fe(III) in sulfate media: Solubility and speciation of arsenic (Conference Paper). TMS Annual Meeting, San Francisco, United States, 13-17 February, 137-148, Code 65371.Search in Google Scholar

21. Azcue, J.M., Mudroch, A., Rosa & F., Hall, G.E.M., (1994). Effects of abandoned gold mine tailings on the arsenic concentrations in water and sediments of Jake of Clubs Lakes, B.C. Environ. Technol. 15 (7), 669-678. DOI: 10.1080/09593339409385472.10.1080/09593339409385472Search in Google Scholar

22. Matera, V., Le Hecho, I., Laboudigue, A., Thomas, P., Tellier, S. & Astruc, M. 2003. A methodological approach for the identification of arsenic bearing phases in polluted soils. Environ. Pollut. 126, 51-64.Search in Google Scholar

23. Sheppard, S.C. (1992). Summary of phytotoxic levels of soil arsenic. Water Air Soil Pollut. (64) 539-550.10.1007/BF00483364Search in Google Scholar

24. Yoshida, Y. & Langouche, G. (2013). Mössbauer spectroscopy - Tutorial Book, Spinger - Verlag Berlin Heidelberg.10.1007/978-3-642-32220-4Search in Google Scholar

25. Bindi, L., Moёlo, Y., Lèone, P. & Suchaud, M. (2012). Stoichiomeric arsenopyrite, FeAsS, from La Roche - Balue Quarry, Loire - Atlantique, France: Crystal structure and Mössbauer study, Can. Mineral: 50 (2) 471-479.Search in Google Scholar

26. Constantinescu, Ş., Udubasa, S.S., Popescu-Pogrion, N., Mercioniu, I. & Udubasa, G.A. (2011). Complex investigations of the iron and gold inclusions in inerals species at nanosize scale. Rom. J. Phys. 56 (5-6), 708-718.Search in Google Scholar

27. Darby Dyar, M., Agresti, D.G., Schaefer, M.W., Grant, C.A. & Sklute, E.C. (2006). Mössbauer Spectroscopy of Earth and Planetary Materials, Annu. Rev. Earth Planet. (34) 83-125.Search in Google Scholar

28. Baláž, P. & Lipka, J. (2000). Mössbauer spectroscopy of sulphidic minerals. Acta Montan. Slov. Roč., 5 (2), 105-112.Search in Google Scholar

29. Kjekshus, A. & Nicholsen, D.G. (1971). The significance of Back - Bonding in compounds with pyrite, marcasite and arsenopyrite Type structures. Acta Chem. Scandin., (25) 866-876.10.3891/acta.chem.scand.25-0866Search in Google Scholar

30. Imbert, P., Gerard, A. & Wintenberger, M. (1963). Etude des sulfure arseniosulfure et arseniuret de fer naturels par effect Mosbauer, Comp. Rend. (256), 4391-4393.Search in Google Scholar

31. Friedrich, B., Krüger, J. & Bernal, G.M. (2002). Alternative solution purification in the hydrometallurgical zinc production. Sav. Inzen. Metalurg. Jugoslav. 85-101.Search in Google Scholar

32. http://www.kcm.bgSearch in Google Scholar

33. Boyanov, B.S., Kehayov, Y.I. & Ivanov, K.I. (2012). Monitoring of soil contamination in vicinity of lead-zinc smelter KCM SA, Bulgaria, Proceedings - 2012 International Conference on Biomedical Engineering and Biotechnology, iCBEB 2012, art. No. 6245135, 385-388. Search in Google Scholar