1892 XXXI International Mineral Processing Congress 2024 Proceedings/Washington, DC/Sep 29–Oct 3
Nazemi, M., Rashchi, F., &Mostoufi, N. 2011. A new
approach for identifying the rate controlling step
applied to the leaching of nickel from spent catalyst.
International Journal of Mineral Processing, 100(1‑2),
21–26.
Neou-Singouna, P., &Fourlaris, G. 1990. A kinetic study
of the ferric chloride leaching of an iron-activated bulk
sulfide concentrate. Hydrometallurgy, 23(2), 203–219.
doi: 10.1016/0304-386X(90)90005-M.
Owusu, C., Mends, E.A., &Acquah, G. 2022. Enhancing
the physical qualities of activated carbon produced from
palm kernel shell via response surface methodology—
process variable optimization. Biomass Conversion and
Biorefinery. doi: 10.1007/s13399-022-03595-7.
Park, K.H., Mohapatra, D., &Reddy, B.R. 2006. A study
on the acidified ferric chloride leaching of a complex
(Cu–Ni–Co–Fe) matte. Separation and Purification
Technology, 51(3), 332–337. doi: 10.1016/j.seppur
.2006.02.013.
Rao, G. 2000. Nickel and Cobalt ores: flotation.
Encyclopedia of Separation Science, 67, 3491–3500.
Rao, M.D., Singh, K.K., Morrison, C.A., &Love, J.B.
2021. Optimization of process parameters for the
selective leaching of copper, nickel and isolation of
gold from obsolete mobile phone PCBs. Cleaner
Engineering and Technology, 4, 100180.
Reddy, R.G., Anderson, A., Anderson, C.G., et al. 2023.
New Directions in Mineral Processing, Extractive
Metallurgy, Recycling and Waste Minimization: An EPD
Symposium in Honor of Patrick R. Taylor. Springer
Nature.
Sastre, J., Sahuquillo, A., Vidal, M., &Rauret, G. 2002.
Determination of Cd, Cu, Pb and Zn in environmen-
tal samples: microwave-assisted total digestion versus
aqua regia and nitric acid extraction. Analytica Chimica
Acta, 462(1), 59–72.
Tang, J., &Steenari, B.-M. 2016. Leaching optimization
of municipal solid waste incineration ash for resource
recovery: A case study of Cu, Zn, Pb and Cd. Waste
management, 48, 315–322.
Veglio, F., Trifoni, M., Pagnanelli, F., &Toro, L. 2001.
Shrinking core model with variable activation energy:
a kinetic model of manganiferous ore leaching with
sulphuric acid and lactose. Hydrometallurgy, 60(2),
167–179.
Watling, H. 2013. Chalcopyrite hydrometallurgy at
atmospheric pressure: 1. Review of acidic sulfate,
sulfate–chloride and sulfate–nitrate process options.
Hydrometallurgy, 140, 163–180.
Xu, X., Mu, W., Wang, L., et al. 2022. Direct extraction of
nickel and copper from low-grade nickel sulfide ore by
chlorination roasting with mixed MgCl2· 6H2O and
NaCl. JOM, 74(5), 1989–1999.
Nazemi, M., Rashchi, F., &Mostoufi, N. 2011. A new
approach for identifying the rate controlling step
applied to the leaching of nickel from spent catalyst.
International Journal of Mineral Processing, 100(1‑2),
21–26.
Neou-Singouna, P., &Fourlaris, G. 1990. A kinetic study
of the ferric chloride leaching of an iron-activated bulk
sulfide concentrate. Hydrometallurgy, 23(2), 203–219.
doi: 10.1016/0304-386X(90)90005-M.
Owusu, C., Mends, E.A., &Acquah, G. 2022. Enhancing
the physical qualities of activated carbon produced from
palm kernel shell via response surface methodology—
process variable optimization. Biomass Conversion and
Biorefinery. doi: 10.1007/s13399-022-03595-7.
Park, K.H., Mohapatra, D., &Reddy, B.R. 2006. A study
on the acidified ferric chloride leaching of a complex
(Cu–Ni–Co–Fe) matte. Separation and Purification
Technology, 51(3), 332–337. doi: 10.1016/j.seppur
.2006.02.013.
Rao, G. 2000. Nickel and Cobalt ores: flotation.
Encyclopedia of Separation Science, 67, 3491–3500.
Rao, M.D., Singh, K.K., Morrison, C.A., &Love, J.B.
2021. Optimization of process parameters for the
selective leaching of copper, nickel and isolation of
gold from obsolete mobile phone PCBs. Cleaner
Engineering and Technology, 4, 100180.
Reddy, R.G., Anderson, A., Anderson, C.G., et al. 2023.
New Directions in Mineral Processing, Extractive
Metallurgy, Recycling and Waste Minimization: An EPD
Symposium in Honor of Patrick R. Taylor. Springer
Nature.
Sastre, J., Sahuquillo, A., Vidal, M., &Rauret, G. 2002.
Determination of Cd, Cu, Pb and Zn in environmen-
tal samples: microwave-assisted total digestion versus
aqua regia and nitric acid extraction. Analytica Chimica
Acta, 462(1), 59–72.
Tang, J., &Steenari, B.-M. 2016. Leaching optimization
of municipal solid waste incineration ash for resource
recovery: A case study of Cu, Zn, Pb and Cd. Waste
management, 48, 315–322.
Veglio, F., Trifoni, M., Pagnanelli, F., &Toro, L. 2001.
Shrinking core model with variable activation energy:
a kinetic model of manganiferous ore leaching with
sulphuric acid and lactose. Hydrometallurgy, 60(2),
167–179.
Watling, H. 2013. Chalcopyrite hydrometallurgy at
atmospheric pressure: 1. Review of acidic sulfate,
sulfate–chloride and sulfate–nitrate process options.
Hydrometallurgy, 140, 163–180.
Xu, X., Mu, W., Wang, L., et al. 2022. Direct extraction of
nickel and copper from low-grade nickel sulfide ore by
chlorination roasting with mixed MgCl2· 6H2O and
NaCl. JOM, 74(5), 1989–1999.