3008 XXXI International Mineral Processing Congress 2024 Proceedings/Washington, DC/Sep 29–Oct 3
Ball, J. W. and Nordstrom, D. K. 1991. User’s manual for
WATEQ4F, with revised thermodynamic data base and
text cases for calculating speciation of major, trace, and
redox elements in natural waters. In U.S. Geological
Survey Water-Resources Investigations Report (Version 2.).
Open-File Report 91-183: U.S. Geological Survey.
Bilal, M., Park, I., Hornn, V. et al. 2022. The Challenges
and Prospects of Recovering Fine Copper Sulfides
from Tailings Using Different Flotation Techniques: A
Review. Minerals, 12(5): 586.
El-Shall, H. E., Elgillani, D. A., and Abdel-Khalek, N.
A. 2000. Role of zinc sulfate in depression of lead-
activated sphalerite. International Journal of Mineral
Processing, 58(1–4): 67–75.
Farahmand, F., Moradkhani, D., Safarzadeh, M. S. et al.
2009. Brine leaching of lead-bearing zinc plant resi-
dues: Process optimization using orthogonal array
design methodology. Hydrometallurgy, 95(3–4):
316–324.
Hornn, V., Park, I., Ito, M. et al. 2021. Agglomeration-
flotation of finely ground chalcopyrite using surfactant-
stabilized oil emulsions: Effects of co-existing minerals
and ions. Minerals Engineering, 171, 107076.
Houot, R., &Raveneau, P. (1992). Activation of sphaler-
ite flotation in the presence of lead ions. International
Journal of Mineral Processing, 35(3–4), 253–271. doi:
10.1016/0301-7516(92)90037-W.
Laskowski, J. S., Liu, Q., and Zhan, Y. (1997). Sphalerite
activation: Flotation and electrokinetic studies.
Minerals Engineering, 10(8): 787–802.
Rashchi, F., Sui, C., and Finch, J. A. (2002). Sphalerite acti-
vation and surface Pb ion concentration. International
Journal of Mineral Processing, 67(1–4): 43–58.
Silwamba, M., Ito, M., Hiroyoshi, N. at al. 2020.
Detoxification of lead-bearing zinc plant leach resi-
dues from Kabwe, Zambia by coupled extraction-
cementation method. Journal of Environmental
Chemical Engineering, 8(4): 104197.
Trahar, W. J., Senior, G. D., Heyes, G. W. et al. 1997. The
activation of sphalerite by lead—a flotation perspec-
tive. International Journal of Mineral Processing, 49(3–
4): 121–148.
Wills, B. A., and Finch, J. A. 2016. Mineral processing
technology: an introduction to the practical aspects of ore
treatment and mineral recovery (8th ed.). Oxford, U.K.
Butterworth-Heinemann.
Woodcock, J. T., Sparrow, G. J., Bruckard, W. J. et al. 2007.
Plant Practice: Sulfide Minerals and Precious Metals.
In Froth flotation A century of innovation. Edited by M
C Fuerstenau, G J Jameson and R H Yoon. Colorado:
Society for Mining, Metallurgy, and Exploration Inc.
Zeng, Z., Chen, Z., and Qi, H. 2021. Two Processes
of Anglesite Formation and a Model of Secondary
Supergene Enrichment of Bi and Ag in Seafloor
Hydrothermal Sulfide Deposits. Journal of Marine
Science and Engineering, 10(1): 35.
Zhang, Y., Jin, B., Song, Q. et al. 2019. Leaching Behavior
of Lead and Silver from Lead Sulfate Hazardous
Residues in NaCl-CaCl2-NaClO3 Media. JOM, 71(7):
2388–2395.
Ball, J. W. and Nordstrom, D. K. 1991. User’s manual for
WATEQ4F, with revised thermodynamic data base and
text cases for calculating speciation of major, trace, and
redox elements in natural waters. In U.S. Geological
Survey Water-Resources Investigations Report (Version 2.).
Open-File Report 91-183: U.S. Geological Survey.
Bilal, M., Park, I., Hornn, V. et al. 2022. The Challenges
and Prospects of Recovering Fine Copper Sulfides
from Tailings Using Different Flotation Techniques: A
Review. Minerals, 12(5): 586.
El-Shall, H. E., Elgillani, D. A., and Abdel-Khalek, N.
A. 2000. Role of zinc sulfate in depression of lead-
activated sphalerite. International Journal of Mineral
Processing, 58(1–4): 67–75.
Farahmand, F., Moradkhani, D., Safarzadeh, M. S. et al.
2009. Brine leaching of lead-bearing zinc plant resi-
dues: Process optimization using orthogonal array
design methodology. Hydrometallurgy, 95(3–4):
316–324.
Hornn, V., Park, I., Ito, M. et al. 2021. Agglomeration-
flotation of finely ground chalcopyrite using surfactant-
stabilized oil emulsions: Effects of co-existing minerals
and ions. Minerals Engineering, 171, 107076.
Houot, R., &Raveneau, P. (1992). Activation of sphaler-
ite flotation in the presence of lead ions. International
Journal of Mineral Processing, 35(3–4), 253–271. doi:
10.1016/0301-7516(92)90037-W.
Laskowski, J. S., Liu, Q., and Zhan, Y. (1997). Sphalerite
activation: Flotation and electrokinetic studies.
Minerals Engineering, 10(8): 787–802.
Rashchi, F., Sui, C., and Finch, J. A. (2002). Sphalerite acti-
vation and surface Pb ion concentration. International
Journal of Mineral Processing, 67(1–4): 43–58.
Silwamba, M., Ito, M., Hiroyoshi, N. at al. 2020.
Detoxification of lead-bearing zinc plant leach resi-
dues from Kabwe, Zambia by coupled extraction-
cementation method. Journal of Environmental
Chemical Engineering, 8(4): 104197.
Trahar, W. J., Senior, G. D., Heyes, G. W. et al. 1997. The
activation of sphalerite by lead—a flotation perspec-
tive. International Journal of Mineral Processing, 49(3–
4): 121–148.
Wills, B. A., and Finch, J. A. 2016. Mineral processing
technology: an introduction to the practical aspects of ore
treatment and mineral recovery (8th ed.). Oxford, U.K.
Butterworth-Heinemann.
Woodcock, J. T., Sparrow, G. J., Bruckard, W. J. et al. 2007.
Plant Practice: Sulfide Minerals and Precious Metals.
In Froth flotation A century of innovation. Edited by M
C Fuerstenau, G J Jameson and R H Yoon. Colorado:
Society for Mining, Metallurgy, and Exploration Inc.
Zeng, Z., Chen, Z., and Qi, H. 2021. Two Processes
of Anglesite Formation and a Model of Secondary
Supergene Enrichment of Bi and Ag in Seafloor
Hydrothermal Sulfide Deposits. Journal of Marine
Science and Engineering, 10(1): 35.
Zhang, Y., Jin, B., Song, Q. et al. 2019. Leaching Behavior
of Lead and Silver from Lead Sulfate Hazardous
Residues in NaCl-CaCl2-NaClO3 Media. JOM, 71(7):
2388–2395.