3054 XXXI International Mineral Processing Congress 2024 Proceedings/Washington, DC/Sep 29–Oct 3
[7] Chen, J.H., Lan, L.H. and Liao, X.J., 2013.
Depression effect of pseudo glycolythiourea
acid in flotation separation of copper–molybde-
num. Transactions of Nonferrous Metals Society of
China, 23(3), pp.824–831.
[8] Kavitha, E., Sundaraganesan, N. and Sebastian, S.,
2010. Molecular structure, vibrational spectroscopic
and HOMO, LUMO studies of 4-nitroaniline by
density functional method.
[9] Laskowski, J.S., Liu, Q. and Bolin, N.J., 1991.
Polysaccharides in flotation of sulphides. Part I.
Adsorption of polysaccharides onto mineral sur-
faces. International journal of mineral processing, 33(1–
4), pp.223–234.
[10] Lindman, S., Linse, S., Mulder, F.A. and André, I.,
2007. pKa values for side-chain carboxyl groups of a
PGB1 variant explain salt and pH-dependent stabil-
ity. Biophysical journal, 92(1), pp.257–266.
[11] Lindman, S., Linse, S., Mulder, F.A. and André, I.,
2007. pKa values for side-chain carboxyl groups of a
PGB1 variant explain salt and pH-dependent stabil-
ity. Biophysical journal, 92(1), pp.257–266.
[12] Liu, Q., 2010. Synthetical technological research
of Cu− Mo separation inhibitor sodium thioglycol-
late. North West Univ, pp.3–5.
[13] Ma, X., Xia, L., Wang, S., Zhong, H. and Jia, H.,
2017. Structural modification of xanthate collec-
tors to enhance the flotation selectivity of chal-
copyrite. Industrial &Engineering Chemistry
Research, 56(21), pp.6307–6316.
[14] Ma, X., Xia, L., Wang, S., Zhong, H. and Jia, H.,
2017. Structural modification of xanthate collec-
tors to enhance the flotation selectivity of chal-
copyrite. Industrial &Engineering Chemistry
Research, 56(21), pp.6307–6316.
[15] Mukhanova, A., Tussupbayev, N., Turysbekov, D. and
Yessengaziyev, A., 2022. Improvement of the selection
technology of copper-molybdenum concentrate with
the use of modified flotoragents. Metalurgija, 61(1),
pp.221–224.
[16] Taheri, B., Rezaei, F., Shadjou, N. and Hassanzadeh,
A., 2022. A molecular analysis on nitrile-based col-
lectors and their application to chalcopyrite flota-
tion. Minerals Engineering, 186, p.107763.
[17] Timbillah, S., 2019. Mechanism for disodium car-
boxymethyl trithiocarbonate (Orfom ® D8) depression
in chalcopyrite-molybdenite flotation systems (Doctoral
dissertation, Montana Tech of The University of
Montana).
[18] Timbillah, S., LaDouceur, R., Das, A. and Young,
C.A., 2021. Theoretical and experimental investi-
gation of disodium carboxymethyl trithiocarbon-
ate in Cu-Mo flotation. Minerals Engineering, 169,
p.106943.
[19] Timbillah, S., Young, C. and Das, A., 2018. A
Fundamental Study of Disodium Carboxymethyl
Trithiocarbonate (Orfom ® D8) in Flotation
Separation of Copper-Molybdenum Sulfides.
In Extraction 2018: Proceedings of the First Global
Conference on Extractive Metallurgy (pp. 2927–2945).
Springer International Publishing.
[20] Young, C., Das, A., Ladouceur, R., Timbillah, S. And
Childress, S., 2022. Review of the Mechanism for
Orfom ® D8 Depression of Chalcopyrite in Cu-Mo
Separation during Cleaner Flotation. International
Journal of the Society of Materials Engineering for
Resources, 25(1), pp.18–22.
[7] Chen, J.H., Lan, L.H. and Liao, X.J., 2013.
Depression effect of pseudo glycolythiourea
acid in flotation separation of copper–molybde-
num. Transactions of Nonferrous Metals Society of
China, 23(3), pp.824–831.
[8] Kavitha, E., Sundaraganesan, N. and Sebastian, S.,
2010. Molecular structure, vibrational spectroscopic
and HOMO, LUMO studies of 4-nitroaniline by
density functional method.
[9] Laskowski, J.S., Liu, Q. and Bolin, N.J., 1991.
Polysaccharides in flotation of sulphides. Part I.
Adsorption of polysaccharides onto mineral sur-
faces. International journal of mineral processing, 33(1–
4), pp.223–234.
[10] Lindman, S., Linse, S., Mulder, F.A. and André, I.,
2007. pKa values for side-chain carboxyl groups of a
PGB1 variant explain salt and pH-dependent stabil-
ity. Biophysical journal, 92(1), pp.257–266.
[11] Lindman, S., Linse, S., Mulder, F.A. and André, I.,
2007. pKa values for side-chain carboxyl groups of a
PGB1 variant explain salt and pH-dependent stabil-
ity. Biophysical journal, 92(1), pp.257–266.
[12] Liu, Q., 2010. Synthetical technological research
of Cu− Mo separation inhibitor sodium thioglycol-
late. North West Univ, pp.3–5.
[13] Ma, X., Xia, L., Wang, S., Zhong, H. and Jia, H.,
2017. Structural modification of xanthate collec-
tors to enhance the flotation selectivity of chal-
copyrite. Industrial &Engineering Chemistry
Research, 56(21), pp.6307–6316.
[14] Ma, X., Xia, L., Wang, S., Zhong, H. and Jia, H.,
2017. Structural modification of xanthate collec-
tors to enhance the flotation selectivity of chal-
copyrite. Industrial &Engineering Chemistry
Research, 56(21), pp.6307–6316.
[15] Mukhanova, A., Tussupbayev, N., Turysbekov, D. and
Yessengaziyev, A., 2022. Improvement of the selection
technology of copper-molybdenum concentrate with
the use of modified flotoragents. Metalurgija, 61(1),
pp.221–224.
[16] Taheri, B., Rezaei, F., Shadjou, N. and Hassanzadeh,
A., 2022. A molecular analysis on nitrile-based col-
lectors and their application to chalcopyrite flota-
tion. Minerals Engineering, 186, p.107763.
[17] Timbillah, S., 2019. Mechanism for disodium car-
boxymethyl trithiocarbonate (Orfom ® D8) depression
in chalcopyrite-molybdenite flotation systems (Doctoral
dissertation, Montana Tech of The University of
Montana).
[18] Timbillah, S., LaDouceur, R., Das, A. and Young,
C.A., 2021. Theoretical and experimental investi-
gation of disodium carboxymethyl trithiocarbon-
ate in Cu-Mo flotation. Minerals Engineering, 169,
p.106943.
[19] Timbillah, S., Young, C. and Das, A., 2018. A
Fundamental Study of Disodium Carboxymethyl
Trithiocarbonate (Orfom ® D8) in Flotation
Separation of Copper-Molybdenum Sulfides.
In Extraction 2018: Proceedings of the First Global
Conference on Extractive Metallurgy (pp. 2927–2945).
Springer International Publishing.
[20] Young, C., Das, A., Ladouceur, R., Timbillah, S. And
Childress, S., 2022. Review of the Mechanism for
Orfom ® D8 Depression of Chalcopyrite in Cu-Mo
Separation during Cleaner Flotation. International
Journal of the Society of Materials Engineering for
Resources, 25(1), pp.18–22.