2730 XXXI International Mineral Processing Congress 2024 Proceedings/Washington, DC/Sep 29–Oct 3
Derjaguin, B. V., and S. S. Dukhin. “Theory of flotation
of small and medium size particles.” Trans. Inst. Min.
Metall 70.5 (1961): 221–246.
Exerowa, Dotchi, and Pyotr M. Kruglyakov. Foam and
foam films: theory, experiment, application. Elsevier,
1997.
Fuerstenau, D. W, Pradip. “Zeta potentials in the flotation
of oxide and silicate minerals.” Advances in colloid and
interface science 114 (2005): 9–26.
Fuerstenau, D. W. “Correlation of contact angles, adsorp-
tion density, zeta potentials, and flotation rate.” Trans.
AIME 208 (1957): 1365–1367.
Gupta, M., &Yoon, R. H. (2024). Maximizing the recov-
ery and throughput of a rougher flotation bank by
improving the recovery of composite particles. Minerals
Engineering, 207, 108545.
Gupta, M., Huang, K., Noble, A., Yoon, R.H., 2023.
Improving the performance of a low-grade porphyry
copper ore flotation plant using a simulator that can
predict grade vs. recovery curves. Miner. Eng. 202,
108243.
Gupta, M., Huang, K., Yoon, R.H., 2022. Predicting the
recovery and grade of a rougher flotation circuit from
liberation data. Miner. Eng. 188, 107853.
Huang, Kaiwu, and Roe-Hoan Yoon. “Control of bubble
ζ-potentials to improve the kinetics of bubblepar-
ticle interactions.” Minerals Engineering 151 (2020):
106295.
Huang, K., &Yoon, R. H. (2019). Effect of ζ-Potentials
on Bubble-Particle Interactions. Mining, Metallurgy &
Exploration, 36(1), 21–34.
Huang, K., Keles, S., Sherrell, I., Noble, A., Yoon, R.H.,
2022. Development of a flotation simulator that can
predict grade vs. Recovery curves from mineral libera-
tion data. Miner. Eng. 181, 107510.
Manica, R., Connor, J.N., Dagastine, R.R., Carnie, S.L.,
Horn, R.G., Chan, D.Y., 2008. Hydrodynamic forces
involving deformable interfaces at nanometer separa-
tions. Phys. Fluids 20 (3), 032101.
Pan, L., &Yoon, R. H. (2016). Measurement of hydro-
phobic forces in thin liquid films of water between
bubbles and xanthate-treated gold surfaces. Minerals
Engineering, 98, 240–250.
Pan, L., Jung, S., &Yoon, R. H. (2011). Effect of hydro-
phobicity on the stability of the wetting films of water
formed on gold surfaces. Journal of colloid and inter-
face science, 361(1), 321–330.
Xu, Z., &Yoon, R. H. (1989). The role of hydrophobia
interactions in coagulation. Journal of colloid and
interface science, 132(2), 532–541.
Derjaguin, B. V., and S. S. Dukhin. “Theory of flotation
of small and medium size particles.” Trans. Inst. Min.
Metall 70.5 (1961): 221–246.
Exerowa, Dotchi, and Pyotr M. Kruglyakov. Foam and
foam films: theory, experiment, application. Elsevier,
1997.
Fuerstenau, D. W, Pradip. “Zeta potentials in the flotation
of oxide and silicate minerals.” Advances in colloid and
interface science 114 (2005): 9–26.
Fuerstenau, D. W. “Correlation of contact angles, adsorp-
tion density, zeta potentials, and flotation rate.” Trans.
AIME 208 (1957): 1365–1367.
Gupta, M., &Yoon, R. H. (2024). Maximizing the recov-
ery and throughput of a rougher flotation bank by
improving the recovery of composite particles. Minerals
Engineering, 207, 108545.
Gupta, M., Huang, K., Noble, A., Yoon, R.H., 2023.
Improving the performance of a low-grade porphyry
copper ore flotation plant using a simulator that can
predict grade vs. recovery curves. Miner. Eng. 202,
108243.
Gupta, M., Huang, K., Yoon, R.H., 2022. Predicting the
recovery and grade of a rougher flotation circuit from
liberation data. Miner. Eng. 188, 107853.
Huang, Kaiwu, and Roe-Hoan Yoon. “Control of bubble
ζ-potentials to improve the kinetics of bubblepar-
ticle interactions.” Minerals Engineering 151 (2020):
106295.
Huang, K., &Yoon, R. H. (2019). Effect of ζ-Potentials
on Bubble-Particle Interactions. Mining, Metallurgy &
Exploration, 36(1), 21–34.
Huang, K., Keles, S., Sherrell, I., Noble, A., Yoon, R.H.,
2022. Development of a flotation simulator that can
predict grade vs. Recovery curves from mineral libera-
tion data. Miner. Eng. 181, 107510.
Manica, R., Connor, J.N., Dagastine, R.R., Carnie, S.L.,
Horn, R.G., Chan, D.Y., 2008. Hydrodynamic forces
involving deformable interfaces at nanometer separa-
tions. Phys. Fluids 20 (3), 032101.
Pan, L., &Yoon, R. H. (2016). Measurement of hydro-
phobic forces in thin liquid films of water between
bubbles and xanthate-treated gold surfaces. Minerals
Engineering, 98, 240–250.
Pan, L., Jung, S., &Yoon, R. H. (2011). Effect of hydro-
phobicity on the stability of the wetting films of water
formed on gold surfaces. Journal of colloid and inter-
face science, 361(1), 321–330.
Xu, Z., &Yoon, R. H. (1989). The role of hydrophobia
interactions in coagulation. Journal of colloid and
interface science, 132(2), 532–541.