110 XXXI International Mineral Processing Congress 2024 Proceedings/Washington, DC/Sep 29–Oct 3
Harbort, G., De Bono, S., Carr, D. and Lawson, V. 2003.
Jameson Cell fundamentals—a revised perspective.
Minerals Engineering, 16:1091–1101.
Jameson, G.J. 2010. New directions in flotation machine
design. Minerals Engineering, 23:835–841.
Jameson, G.J. and Emer, C. 2019. Coarse chalcopy-
rite recovery in a universal froth flotation machine.
Minerals Engineering, 134:118–133.
Jefferson, M., Jones, R.T., Parbhakar-Fox, A., Curtis-
Morar, C., Forbes, G. and Forbes, E. 2024. Impact of
Pyrite Textures Prevalence on Flotation Performance
in Mount Isa Copper Orebodies. In preparation for
publication.
Jefferson, M., Yenial-Arslan, U., Evans, C., Curtis-Morar,
C., O’Donnell, R., Parbhakar-Fox, A. and Forbes, E.
2023. Effect of pyrite textures and composition on
flotation performance: A review. Minerals Engineering,
201, 108234.
Jiang, K., Dickinson, J.E. and Galvin, K.P. 2019. The
kinetics of fast flotation using the reflux flotation cell,
Chemical Engineering Science 196:463–477. doi:
10.1016/j.ces.2018.11.012.
Jokovic, V., Jorge Barbosa, K., Ndimande, C., Hilden, M.,
Runge, K. and Yahyaei, M. 2022. Measuring the
effect of hybrid classification in a pilot-scale test. In
International Minerals Processing Congress Asia-Pacific
2022, Melbourne, Australia, 22–24 August.
Klein, B., Wang, C. and Nadolski, S. 2018. Energy-
Efficient Comminution: Best Practices and
Future Research Needs. In: Energy Efficiency in the
Minerals Industry. Green Energy and Technology.
Edited by K. Awuah-Offei. Springer. Cham. doi:
10.1007/978-3-319-54199-0_11.
Kohmuench, J.N., Mankosa, M.J., Thanasekaran, H. and
Hobert, A. 2018. Improving coarse particle flotation
using the HydroFloat ™ (raising the trunk of the ele-
phant curve). Minerals Engineering 121: 137–145. doi:
10.1016/j.mineng.2018.03.004.
Ku, L.I., Forbes, L. and Brito e Abreu, S. 2024. An efficient
peptide screening method for mineral-binding pep-
tides. Minerals 14(2) 207. doi: 10.3390/min14020207.
Li, X. and Li, Q. 2016. Major advances in microbeam ana-
lytical techniques and their applications in earth sci-
ence, Science Bulletin, 61(23):1785—1787.
Lisso, M. 2024. Understanding and modelling the per-
formance of a semi-inverted hydrocyclone. PhD
Thesis. The University of Queensland -SMI -Julius
Kruttschnitt Mineral Research Centre, Brisbane
Australia.
Loesche Vertical Roller Mills for Ores and Steem Slag
Brochure 2024. PR_20_1299_Ore brochure_Rev
2020_km_1_3_150dpi_netto.pdf (loesche.com),
(Accessed April, 2024).
Mehrfert, P.J. 2017, Investigating the potential of
HydroFloatTM coarse particle flotation techniques on
copper sulphide ores, Engineering Materials Science.
Miller, J.D. and Lin, C.L. 2018. X-ray tomography for
mineral processing technology -3D particle character-
ization from mine to mill. Minerals and Metallurgical
Processing 35: 1–12.
Moon, K.S. and Fuerstenau, D.W. 2003. Surface crystal
chemistry in selective flotation of spodumene (LiAl[SiO
3] 2) from other aluminosilicates. International Journal
of Mineral Processing, 72(1), 11–24.
Napier-Munn, T. 2015. Is progress in energy-efficient com-
minution doomed? Minerals Engineering, 73: 1–6,
doi: 10.1016/j.mineng.2014.06.009.
Napier-Munn, T. 2016. Innovation in Mineral Processing:
Distinguished past and uncertain future. AusIMM
Delprat Lecture Series.
Ng, W.S., Connal, L.A., Forbes, E. and Franks, G.V. 2018.
A review of temperature-responsive polymers as novel
reagents for solid-liquid separation and froth flotation
of minerals. Minerals Engineering, 123, 144–159.
Pereira, L., Kupka, N., Huu Hoang, D., Michaux, B.,
Saquran, S., Ebert, D. and Rudolph, M. 2023. On the
impact of grinding conditions in the flotation of semi-
soluble salt-type mineral-containing ores driven by sur-
face or particle geometry effects? International Journal
of Mining Science and Technology, 33(7), 855–872.
Rasyid M.A., Jokovic, V. and Morrison, R. 2019.
Classification performance of semi-inverted hydro-
cyclones. Minerals Engineering 142. ISSN 08926875.
doi: 10.1016/j.mineng.2019.105889.
Reyes, F., Lin, Q., Cilliers, J.J. and Neethling, S.J. 2018.
Quantifying mineral liberation by particle grade
and surface exposure using X-ray microCT. Minerals
Engineering 125:75–82.
Runge, K.C., Frausto, J.J., Lisso, M.M., Jokovic, V. and
Yahyaei, M. 2024. Importance of considering classifi-
cation and liberation when optimizing comminution
and flotation. Minerals Engineering 209 doi: 10.1016/j.
mineng.2024.108612.
Runge, K.C., Brito e Abreu, S., Evans, C. and
O’Donnell, R.O. 2021. Analysis of the Mount Isa
Copper concentrate preflotation circuit using advanced
diagnostics techniques. In Mill Operators Conference
2021. AusIMM, Brisbane, Australia, p. 178 -192.
Harbort, G., De Bono, S., Carr, D. and Lawson, V. 2003.
Jameson Cell fundamentals—a revised perspective.
Minerals Engineering, 16:1091–1101.
Jameson, G.J. 2010. New directions in flotation machine
design. Minerals Engineering, 23:835–841.
Jameson, G.J. and Emer, C. 2019. Coarse chalcopy-
rite recovery in a universal froth flotation machine.
Minerals Engineering, 134:118–133.
Jefferson, M., Jones, R.T., Parbhakar-Fox, A., Curtis-
Morar, C., Forbes, G. and Forbes, E. 2024. Impact of
Pyrite Textures Prevalence on Flotation Performance
in Mount Isa Copper Orebodies. In preparation for
publication.
Jefferson, M., Yenial-Arslan, U., Evans, C., Curtis-Morar,
C., O’Donnell, R., Parbhakar-Fox, A. and Forbes, E.
2023. Effect of pyrite textures and composition on
flotation performance: A review. Minerals Engineering,
201, 108234.
Jiang, K., Dickinson, J.E. and Galvin, K.P. 2019. The
kinetics of fast flotation using the reflux flotation cell,
Chemical Engineering Science 196:463–477. doi:
10.1016/j.ces.2018.11.012.
Jokovic, V., Jorge Barbosa, K., Ndimande, C., Hilden, M.,
Runge, K. and Yahyaei, M. 2022. Measuring the
effect of hybrid classification in a pilot-scale test. In
International Minerals Processing Congress Asia-Pacific
2022, Melbourne, Australia, 22–24 August.
Klein, B., Wang, C. and Nadolski, S. 2018. Energy-
Efficient Comminution: Best Practices and
Future Research Needs. In: Energy Efficiency in the
Minerals Industry. Green Energy and Technology.
Edited by K. Awuah-Offei. Springer. Cham. doi:
10.1007/978-3-319-54199-0_11.
Kohmuench, J.N., Mankosa, M.J., Thanasekaran, H. and
Hobert, A. 2018. Improving coarse particle flotation
using the HydroFloat ™ (raising the trunk of the ele-
phant curve). Minerals Engineering 121: 137–145. doi:
10.1016/j.mineng.2018.03.004.
Ku, L.I., Forbes, L. and Brito e Abreu, S. 2024. An efficient
peptide screening method for mineral-binding pep-
tides. Minerals 14(2) 207. doi: 10.3390/min14020207.
Li, X. and Li, Q. 2016. Major advances in microbeam ana-
lytical techniques and their applications in earth sci-
ence, Science Bulletin, 61(23):1785—1787.
Lisso, M. 2024. Understanding and modelling the per-
formance of a semi-inverted hydrocyclone. PhD
Thesis. The University of Queensland -SMI -Julius
Kruttschnitt Mineral Research Centre, Brisbane
Australia.
Loesche Vertical Roller Mills for Ores and Steem Slag
Brochure 2024. PR_20_1299_Ore brochure_Rev
2020_km_1_3_150dpi_netto.pdf (loesche.com),
(Accessed April, 2024).
Mehrfert, P.J. 2017, Investigating the potential of
HydroFloatTM coarse particle flotation techniques on
copper sulphide ores, Engineering Materials Science.
Miller, J.D. and Lin, C.L. 2018. X-ray tomography for
mineral processing technology -3D particle character-
ization from mine to mill. Minerals and Metallurgical
Processing 35: 1–12.
Moon, K.S. and Fuerstenau, D.W. 2003. Surface crystal
chemistry in selective flotation of spodumene (LiAl[SiO
3] 2) from other aluminosilicates. International Journal
of Mineral Processing, 72(1), 11–24.
Napier-Munn, T. 2015. Is progress in energy-efficient com-
minution doomed? Minerals Engineering, 73: 1–6,
doi: 10.1016/j.mineng.2014.06.009.
Napier-Munn, T. 2016. Innovation in Mineral Processing:
Distinguished past and uncertain future. AusIMM
Delprat Lecture Series.
Ng, W.S., Connal, L.A., Forbes, E. and Franks, G.V. 2018.
A review of temperature-responsive polymers as novel
reagents for solid-liquid separation and froth flotation
of minerals. Minerals Engineering, 123, 144–159.
Pereira, L., Kupka, N., Huu Hoang, D., Michaux, B.,
Saquran, S., Ebert, D. and Rudolph, M. 2023. On the
impact of grinding conditions in the flotation of semi-
soluble salt-type mineral-containing ores driven by sur-
face or particle geometry effects? International Journal
of Mining Science and Technology, 33(7), 855–872.
Rasyid M.A., Jokovic, V. and Morrison, R. 2019.
Classification performance of semi-inverted hydro-
cyclones. Minerals Engineering 142. ISSN 08926875.
doi: 10.1016/j.mineng.2019.105889.
Reyes, F., Lin, Q., Cilliers, J.J. and Neethling, S.J. 2018.
Quantifying mineral liberation by particle grade
and surface exposure using X-ray microCT. Minerals
Engineering 125:75–82.
Runge, K.C., Frausto, J.J., Lisso, M.M., Jokovic, V. and
Yahyaei, M. 2024. Importance of considering classifi-
cation and liberation when optimizing comminution
and flotation. Minerals Engineering 209 doi: 10.1016/j.
mineng.2024.108612.
Runge, K.C., Brito e Abreu, S., Evans, C. and
O’Donnell, R.O. 2021. Analysis of the Mount Isa
Copper concentrate preflotation circuit using advanced
diagnostics techniques. In Mill Operators Conference
2021. AusIMM, Brisbane, Australia, p. 178 -192.