XXXI International Mineral Processing Congress 2024 Proceedings/Washington, DC/Sep 29–Oct 3 1713
Samaddar, P., &Sen, K. (2014). Cloud point extraction:
A sustainable method of elemental preconcentration
and speciation. Journal of Industrial and Engineering
Chemistry, 20,1209–1219. doi: 10.1016/j.jiec.2013
.10.033.
Shelimov, B.N., Lambert, J.F., Che, M., &Didillon, B.
(2000). Molecular-level studies of transition metal–
support interactions during the first steps of catalysts
preparation: platinum speciation in the hexachlo-
roplatinate/alumina system. Journal of Molecular
Catalysis A: Chemical, 158(1), 91–99. doi: 10.1016
/s1381-1169(00)00047-9.
Shen, S., Pan, T., Liu, X., Yua, L., Wang, J., Zhang,Y., &
Guo, Z. (2010). Adsorption of Rh (III) complexes
from chloride solutions obtained by leaching chlori-
nated spent automotive catalysts on ion-exchange resin
Diaion WA21J. Journal of Hazardous Materials, 179,
104–112. doi: 10.1016/j.jhazmat.2010.02.064.
Silva, R.A., Hawboldt, K., &Zhang, Y. (2018). Application
of resins with functional groups in the separation of
metal ions/species – a review. Mineral Processing and
Extractive Metallurgy Review, 39 (6), 395–413. doi:
10.1080/08827508.2018.1459619.
Sole, K.C., Mooiman, M.B., &Hardwick, E. (2017).
Ion Exchange in Hydrometallurgical Processing:
An Overview and Selected Applications.
Separation &Purification Reviews, 00, 1–20. doi:
10.1080/15422119.2017.1354304.
Souza, E.J.D.S., Amaral, C.D.B.D., Nagata, N., &
Grassi, M.T. (2020). Cloud point extractors for
simultaneous determination of Pd and Pt in water
samples by ICP OES with multivariate optimiza-
tion. Microchemical Journal, 152 (104309), 1–9. doi:
10.1016/j.microc.2019.104309.
Steinlechner, S., &Antrekowitsch, J. (2013). PGM
Recycling from Catalysts in a Closed Hydrometallurgical
Loop with an Optional Cerium Recovery. In: kvith-
yld A.et al. (Eds) REWAS 2013. Springer, Cham. doi:
10.1007/978-3-319-48763-2_39.
Suoranta, T., Zugazua, O., Niemelä, M., Perämäki, P.
(2015). Recovery of palladium, platinum, rho-
dium and ruthenium from catalyst materials using
microwave-assisted leaching and cloud point extrac-
tion. Hydrometallurgy, 154, 56–62. doi: 10.1016
/j.hydromet.2015.03.014.
Sun, P., Kim, T., Min, B., Song, H., and Cho, S. (2015).
Recovery of Platinum from Chloride Leaching
Solutions of Spent Reforming Catalysts by Ion
Exchange. Materials Transactions, 56 (50), 738–742.
doi: 10.2320/matertrans.M2015027.
Taninouchi, Y., &Okabe, T.H. (2023). Trends of
Technological Development of Platinum Group Metal
Recycling: Solubilization and Physical Concentration
Processes. Material transactions, 64(3), 627–637. doi:
10.2320/matertrans.MT-M2022150.
Torrejos, R.E.C., Nisola, G.M., Min, S.H., Han, J.W.,
Lee, S.P., &Chung, W.J. (2020). Highly selective
extraction of palladium from spent automotive cata-
lyst acid leachate using novel alkylated dioxa-dithi-
acrown ether derivatives. Journal of Industrial and
Engineering Chemistry, 89, 428–435. doi: 10.1016/j.
jiec.2020.06.015.
Wołowicz, A., &Hubicki, Z. (2011). Comparison of
strongly basic anion exchange resins applicability for
the removal of palladium (II) ions from acidic solu-
tions. Chemical engineering journal, 171(1), 206–215.
doi: 10.1016/j.cej.2011.03.092.
Yakoumis, I., Moschovi, A.M., Giannopoulou, I., &
Panias, D. (2018). Real life experimental determination
of Platinum Group Metals content in automotive cata-
lytic converters. Materials Science and Engineering, 329
(012009). doi: 10.1088/1757-899X/329/1/012009.
Yamini, Y., Feizi, N., &Moradi, M. (2020). Surfactant-Based
Extraction Systems. In C.F. Poole (Ed), Handbook in
Separation Science-Liquid-Phase Extraction, (pp.209–
240). Retrieved from http://app.knovel.com/hotlink
/toc/id:kpLPE00001/liquid-phase-extraction/liquid
-phase-extraction.
Yin, X., Yi, H., Wang, Q., Wang, Y., Sun, X., L, C., ...
&Yang, Y. (2017). Extraction and separation of mul-
tiple platinum group metals from hydrochloric acid
solution with sole1-hexyl-3-methylimidazole-2-thione
using microextraction method. Hydrometallurgy, 174,
167–174. doi: 10.1016/j.hydromet.2017.10.009.
Zou, L., Chen, J., &Pan, X. (1998). Solvent extraction of
rhodium from aqueous solution of Rh (III)–Sn (II)–
Cl– system by TBP. Hydrometallurgy, 50, 193–203. doi:
S0304-386X_98.00017-6.
Samaddar, P., &Sen, K. (2014). Cloud point extraction:
A sustainable method of elemental preconcentration
and speciation. Journal of Industrial and Engineering
Chemistry, 20,1209–1219. doi: 10.1016/j.jiec.2013
.10.033.
Shelimov, B.N., Lambert, J.F., Che, M., &Didillon, B.
(2000). Molecular-level studies of transition metal–
support interactions during the first steps of catalysts
preparation: platinum speciation in the hexachlo-
roplatinate/alumina system. Journal of Molecular
Catalysis A: Chemical, 158(1), 91–99. doi: 10.1016
/s1381-1169(00)00047-9.
Shen, S., Pan, T., Liu, X., Yua, L., Wang, J., Zhang,Y., &
Guo, Z. (2010). Adsorption of Rh (III) complexes
from chloride solutions obtained by leaching chlori-
nated spent automotive catalysts on ion-exchange resin
Diaion WA21J. Journal of Hazardous Materials, 179,
104–112. doi: 10.1016/j.jhazmat.2010.02.064.
Silva, R.A., Hawboldt, K., &Zhang, Y. (2018). Application
of resins with functional groups in the separation of
metal ions/species – a review. Mineral Processing and
Extractive Metallurgy Review, 39 (6), 395–413. doi:
10.1080/08827508.2018.1459619.
Sole, K.C., Mooiman, M.B., &Hardwick, E. (2017).
Ion Exchange in Hydrometallurgical Processing:
An Overview and Selected Applications.
Separation &Purification Reviews, 00, 1–20. doi:
10.1080/15422119.2017.1354304.
Souza, E.J.D.S., Amaral, C.D.B.D., Nagata, N., &
Grassi, M.T. (2020). Cloud point extractors for
simultaneous determination of Pd and Pt in water
samples by ICP OES with multivariate optimiza-
tion. Microchemical Journal, 152 (104309), 1–9. doi:
10.1016/j.microc.2019.104309.
Steinlechner, S., &Antrekowitsch, J. (2013). PGM
Recycling from Catalysts in a Closed Hydrometallurgical
Loop with an Optional Cerium Recovery. In: kvith-
yld A.et al. (Eds) REWAS 2013. Springer, Cham. doi:
10.1007/978-3-319-48763-2_39.
Suoranta, T., Zugazua, O., Niemelä, M., Perämäki, P.
(2015). Recovery of palladium, platinum, rho-
dium and ruthenium from catalyst materials using
microwave-assisted leaching and cloud point extrac-
tion. Hydrometallurgy, 154, 56–62. doi: 10.1016
/j.hydromet.2015.03.014.
Sun, P., Kim, T., Min, B., Song, H., and Cho, S. (2015).
Recovery of Platinum from Chloride Leaching
Solutions of Spent Reforming Catalysts by Ion
Exchange. Materials Transactions, 56 (50), 738–742.
doi: 10.2320/matertrans.M2015027.
Taninouchi, Y., &Okabe, T.H. (2023). Trends of
Technological Development of Platinum Group Metal
Recycling: Solubilization and Physical Concentration
Processes. Material transactions, 64(3), 627–637. doi:
10.2320/matertrans.MT-M2022150.
Torrejos, R.E.C., Nisola, G.M., Min, S.H., Han, J.W.,
Lee, S.P., &Chung, W.J. (2020). Highly selective
extraction of palladium from spent automotive cata-
lyst acid leachate using novel alkylated dioxa-dithi-
acrown ether derivatives. Journal of Industrial and
Engineering Chemistry, 89, 428–435. doi: 10.1016/j.
jiec.2020.06.015.
Wołowicz, A., &Hubicki, Z. (2011). Comparison of
strongly basic anion exchange resins applicability for
the removal of palladium (II) ions from acidic solu-
tions. Chemical engineering journal, 171(1), 206–215.
doi: 10.1016/j.cej.2011.03.092.
Yakoumis, I., Moschovi, A.M., Giannopoulou, I., &
Panias, D. (2018). Real life experimental determination
of Platinum Group Metals content in automotive cata-
lytic converters. Materials Science and Engineering, 329
(012009). doi: 10.1088/1757-899X/329/1/012009.
Yamini, Y., Feizi, N., &Moradi, M. (2020). Surfactant-Based
Extraction Systems. In C.F. Poole (Ed), Handbook in
Separation Science-Liquid-Phase Extraction, (pp.209–
240). Retrieved from http://app.knovel.com/hotlink
/toc/id:kpLPE00001/liquid-phase-extraction/liquid
-phase-extraction.
Yin, X., Yi, H., Wang, Q., Wang, Y., Sun, X., L, C., ...
&Yang, Y. (2017). Extraction and separation of mul-
tiple platinum group metals from hydrochloric acid
solution with sole1-hexyl-3-methylimidazole-2-thione
using microextraction method. Hydrometallurgy, 174,
167–174. doi: 10.1016/j.hydromet.2017.10.009.
Zou, L., Chen, J., &Pan, X. (1998). Solvent extraction of
rhodium from aqueous solution of Rh (III)–Sn (II)–
Cl– system by TBP. Hydrometallurgy, 50, 193–203. doi:
S0304-386X_98.00017-6.
