XXXI International Mineral Processing Congress 2024 Proceedings/Washington, DC/Sep 29–Oct 3 657
Ndamase, N., Tadie, M. and Korin, K.C., 2020.
Considering the action of degrading water quality on
the electrochemical response of sulfide minerals, In
Processings of the XXX IMPC Cape Town, South Africa,
October. 1421–1430.
Owusu, C., Abreu, S.B., Skinner, W., Addai-Mensah, J.,
Zanin, M., (2014), “The influence of pyrite content
on the flotation of chalcopyrite /pyrite mixtures,”
Minerals Engineering, 55, pp. 87–95.
Parraguez, L., Bernal, L. &Cartagena, G., (2009),
“Chemical study for selectivity and recovery of met-
als sulphides by flotation using seawater” (Amelunxen,
P., Kracht, W. &Kuyvenhoven, R. ed.), In Proceedings
of the VI International Mineral Processing Congress,
Santiago, pp. 323–33.
Pugh, R.J., Weissenborn, P., Paulson, O., (1997), “Flotation
of inorganic electrolytes the relationship between
recovery of hydrophobic particles, surface tension,
bubble coalescence and gas solubility,” International
Journal of Mineral Processing 51, pp.125–138.
Pytkowicz, R.M. &Atlas, E., (1975), Buffer intensity of
seawater, Limnology and Oceanography, 20(2):222–229.
Ross, V.E. &Van Deventer, J.S.J., (1985, The interactive
effects of sulphite ion, pH and dissolved oxygen on
the flotation of chalcopyrite and galena from Black
Mountain ore, J.S. Afr. Inst. Min. Metall., vol 85, No.1,
Jan 1985, pp. 13–21.
Smith, L.K., Davey, K.J., and Bruckard, W.J., (2012). The
use of pulp potential control to separate copper and
arsenic – an overview based on selected case studies, In:
proc. IMPC, New Delhi, Sept 2012, pp. 5057–5067.
Woods, R., (2010). Electrochemical aspects of sulfide min-
eral flotation, Flotation Plant Optimization, Chapter
7, Published by Australian Institute of Mining and
Metallurgy. 123–135.
Ndamase, N., Tadie, M. and Korin, K.C., 2020.
Considering the action of degrading water quality on
the electrochemical response of sulfide minerals, In
Processings of the XXX IMPC Cape Town, South Africa,
October. 1421–1430.
Owusu, C., Abreu, S.B., Skinner, W., Addai-Mensah, J.,
Zanin, M., (2014), “The influence of pyrite content
on the flotation of chalcopyrite /pyrite mixtures,”
Minerals Engineering, 55, pp. 87–95.
Parraguez, L., Bernal, L. &Cartagena, G., (2009),
“Chemical study for selectivity and recovery of met-
als sulphides by flotation using seawater” (Amelunxen,
P., Kracht, W. &Kuyvenhoven, R. ed.), In Proceedings
of the VI International Mineral Processing Congress,
Santiago, pp. 323–33.
Pugh, R.J., Weissenborn, P., Paulson, O., (1997), “Flotation
of inorganic electrolytes the relationship between
recovery of hydrophobic particles, surface tension,
bubble coalescence and gas solubility,” International
Journal of Mineral Processing 51, pp.125–138.
Pytkowicz, R.M. &Atlas, E., (1975), Buffer intensity of
seawater, Limnology and Oceanography, 20(2):222–229.
Ross, V.E. &Van Deventer, J.S.J., (1985, The interactive
effects of sulphite ion, pH and dissolved oxygen on
the flotation of chalcopyrite and galena from Black
Mountain ore, J.S. Afr. Inst. Min. Metall., vol 85, No.1,
Jan 1985, pp. 13–21.
Smith, L.K., Davey, K.J., and Bruckard, W.J., (2012). The
use of pulp potential control to separate copper and
arsenic – an overview based on selected case studies, In:
proc. IMPC, New Delhi, Sept 2012, pp. 5057–5067.
Woods, R., (2010). Electrochemical aspects of sulfide min-
eral flotation, Flotation Plant Optimization, Chapter
7, Published by Australian Institute of Mining and
Metallurgy. 123–135.