1376 XXXI International Mineral Processing Congress 2024 Proceedings/Washington, DC/Sep 29–Oct 3
Das, S., G. Gaustad, A. Sekar and E. Williams (2018).
“Techno-economic analysis of supercritical extraction
of rare earth elements from coal ash.” Journal of Cleaner
Production 189: 539–551.
De Lima, I. B., and Walter Leal Filho (2015). Rare earths
industry: Technological, economic, and environmental
implications, Elsevier.
Ding, X., Q. L. Liu, X. P. Hou and T. Fang (2017).
“Supercritical Fluid Extraction of Metal Chelate: A
Review.” Critical Reviews in Analytical Chemistry 47(2):
99–118.
Duan, W. H., P. J. Cao and Y. J. Zhu (2010). “Extraction
of rare earth elements from their oxides using organo-
phosphorus reagent complexes with HNO3 and H2O
in supercritical CO2.” Journal of Rare Earths 28(2):
221–226.
Dushyantha, N., N. Batapola, I. M. S. K. Ilankoon, S.
Rohitha, R. Premasiri, B. Abeysinghe, N. Ratnayake
and K. Dissanayake (2020). “The story of rare earth
elements (REEs): Occurrences, global distribution,
genesis, geology, mineralogy and global production.”
Ore Geology Reviews 122.
Fathollahzadeh, H., Becker, T., Eksteen, J.J., Kaksonen,
A.K. and Watkin, E.L.J. (2018). “Microbial con-
tact enhances bioleaching of rare earth elements.”
Bioresource Technology Reports 3: 102–108.
Fathollahzadeh, H., J. J. Eksteen, A. H. Kaksonen and E.
L. J. Watkin (2019). “Role of microorganisms in biole-
aching of rare earth elements from primary and second-
ary resources.” Applied Microbiology and Biotechnology
103(3): 1043–1057.
Fathollahzadeh, H., Hackett, M.J., Khaleque, H.N.,
Eksteen, J.J., Kaksonen, A.H. and Watkin, E.L.J.
(2018). “Better together: Potential of co-culture micro-
organisms to enhance bioleaching of rare earth ele-
ments from monazite.” Bioresource Technology Reports
3: 109–118.
Fathollahzadeh, H., H. N. Khaleque, J. Eksteen, A. H.
Kaksonen and E. L. J. Watkin (2019). “Effect of glycine
on bioleaching of rare earth elements from Western
Australian monazite by heterotrophic and autotrophic
microorganisms.” Hydrometallurgy 189.
Fox, R. V., R. D. Ball, P. D. Harrington, H. W. Rollins, J.
J. Jolley and C. A. Wai (2004). “Praseodymium nitrate
and neodymium nitrate complexation with organo-
phosphorus reagents in supercritical carbon dioxide
solvent.” Journal of Supercritical Fluids 31(3): 273–286.
Gupta, C. K. and N. Krishnamurthy (2005). Extractive
Metallurgy of Rare-Earths, CRC Press.
Kuzmin, V. I., G. L. Pashkov, V. G. Lomaev, E. N.
Voskresenskaya and V. N. Kuzmina (2012). “Combined
approaches for comprehensive processing of rare earth
metal ores.” Hydrometallurgy 129: 1–6.
Laintz, K. E., C. M. Wai, C. R. Yonker and R. D. Smith
(1992). “Extraction of Metal-Ions from Liquid and
Solid Materials by Supercritical Carbon-Dioxide.”
Analytical Chemistry 64(22): 2875–2878.
Reisdörfer, G., D. A. Bertuol and E. H. Tanabe (2020).
“Extraction of neodymium from hard disk drives using
supercritical CO2 with organic acids solutions acting
as cosolvents.” Journal of Co2 Utilization 35: 277–287.
Samsonov, M. D., T. I. Trofimov, Y. M. Kulyako, D. A.
Malikov and B. F. Myasoedov (2016). “Supercritical
fluid extraction of rare earth elements, thorium and
uranium from monazite concentrate and phosphogyp-
sum using carbon dioxide containing tributyl phos-
phate and di-(2-ethylhexyl)phosphoric acid.” Russian
Journal of Physical Chemistry B 10(7): 1078–1084.
Samsonov, M. D., T. I. Trofimov, Y. M. Kulyako, S. E.
Vinokurov, D. A. Malikov, G. S. Batorshin and B. F.
Myasoedov (2015). “Recovery of Rare Earth Elements,
Uranium, and Thorium from Monazite Concentrate
by Supercritical Fluid Extraction.” Radiochemistry
57(4): 343–347.
Sawada, K., D. Hirabayashi and Y. Enokida (2008).
“Fundamental studies on extraction of actinides from
spent fuels using liquefied gases -:Conversion of cop-
per into nitrate with NO2 and extraction of Nd(III)
nitrate by CO2 with TBP.” Progress in Nuclear Energy
50(2–6): 483–486.
Shimizu, R., K. Sawada, Y. Enokida and I. Yamamoto
(2005). “Supercritical fluid extraction of rare earth ele-
ments from luminescent material in waste fluorescent
lamps.” Journal of Supercritical Fluids 33(3): 235–241.
Sinclair, L. K., D. L. Baek, J. Thompson, J. W. Tester and
R. V. Fox (2017). “Rare earth element extraction from
pretreated bastnasite in supercritical carbon dioxide.”
Journal of Supercritical Fluids 124: 20–29.
Smart, N. G., T. Carleson, T. Kast, A. A. Clifford, M. D.
Burford and C. M. Wai (1997). “Solubility of chelat-
ing agents and metal-containing compounds in super-
critical fluid carbon dioxide.” Talanta 44(2): 137–150.
Tomioka, O., Y. Enokida and I. Yamamoto (1998).
“Solvent extraction of lanthanides from their oxides
with TBP in supercritical carbon dioxide.” Journal of
Nuclear Science and Technology 35(7): 515–516.
Das, S., G. Gaustad, A. Sekar and E. Williams (2018).
“Techno-economic analysis of supercritical extraction
of rare earth elements from coal ash.” Journal of Cleaner
Production 189: 539–551.
De Lima, I. B., and Walter Leal Filho (2015). Rare earths
industry: Technological, economic, and environmental
implications, Elsevier.
Ding, X., Q. L. Liu, X. P. Hou and T. Fang (2017).
“Supercritical Fluid Extraction of Metal Chelate: A
Review.” Critical Reviews in Analytical Chemistry 47(2):
99–118.
Duan, W. H., P. J. Cao and Y. J. Zhu (2010). “Extraction
of rare earth elements from their oxides using organo-
phosphorus reagent complexes with HNO3 and H2O
in supercritical CO2.” Journal of Rare Earths 28(2):
221–226.
Dushyantha, N., N. Batapola, I. M. S. K. Ilankoon, S.
Rohitha, R. Premasiri, B. Abeysinghe, N. Ratnayake
and K. Dissanayake (2020). “The story of rare earth
elements (REEs): Occurrences, global distribution,
genesis, geology, mineralogy and global production.”
Ore Geology Reviews 122.
Fathollahzadeh, H., Becker, T., Eksteen, J.J., Kaksonen,
A.K. and Watkin, E.L.J. (2018). “Microbial con-
tact enhances bioleaching of rare earth elements.”
Bioresource Technology Reports 3: 102–108.
Fathollahzadeh, H., J. J. Eksteen, A. H. Kaksonen and E.
L. J. Watkin (2019). “Role of microorganisms in biole-
aching of rare earth elements from primary and second-
ary resources.” Applied Microbiology and Biotechnology
103(3): 1043–1057.
Fathollahzadeh, H., Hackett, M.J., Khaleque, H.N.,
Eksteen, J.J., Kaksonen, A.H. and Watkin, E.L.J.
(2018). “Better together: Potential of co-culture micro-
organisms to enhance bioleaching of rare earth ele-
ments from monazite.” Bioresource Technology Reports
3: 109–118.
Fathollahzadeh, H., H. N. Khaleque, J. Eksteen, A. H.
Kaksonen and E. L. J. Watkin (2019). “Effect of glycine
on bioleaching of rare earth elements from Western
Australian monazite by heterotrophic and autotrophic
microorganisms.” Hydrometallurgy 189.
Fox, R. V., R. D. Ball, P. D. Harrington, H. W. Rollins, J.
J. Jolley and C. A. Wai (2004). “Praseodymium nitrate
and neodymium nitrate complexation with organo-
phosphorus reagents in supercritical carbon dioxide
solvent.” Journal of Supercritical Fluids 31(3): 273–286.
Gupta, C. K. and N. Krishnamurthy (2005). Extractive
Metallurgy of Rare-Earths, CRC Press.
Kuzmin, V. I., G. L. Pashkov, V. G. Lomaev, E. N.
Voskresenskaya and V. N. Kuzmina (2012). “Combined
approaches for comprehensive processing of rare earth
metal ores.” Hydrometallurgy 129: 1–6.
Laintz, K. E., C. M. Wai, C. R. Yonker and R. D. Smith
(1992). “Extraction of Metal-Ions from Liquid and
Solid Materials by Supercritical Carbon-Dioxide.”
Analytical Chemistry 64(22): 2875–2878.
Reisdörfer, G., D. A. Bertuol and E. H. Tanabe (2020).
“Extraction of neodymium from hard disk drives using
supercritical CO2 with organic acids solutions acting
as cosolvents.” Journal of Co2 Utilization 35: 277–287.
Samsonov, M. D., T. I. Trofimov, Y. M. Kulyako, D. A.
Malikov and B. F. Myasoedov (2016). “Supercritical
fluid extraction of rare earth elements, thorium and
uranium from monazite concentrate and phosphogyp-
sum using carbon dioxide containing tributyl phos-
phate and di-(2-ethylhexyl)phosphoric acid.” Russian
Journal of Physical Chemistry B 10(7): 1078–1084.
Samsonov, M. D., T. I. Trofimov, Y. M. Kulyako, S. E.
Vinokurov, D. A. Malikov, G. S. Batorshin and B. F.
Myasoedov (2015). “Recovery of Rare Earth Elements,
Uranium, and Thorium from Monazite Concentrate
by Supercritical Fluid Extraction.” Radiochemistry
57(4): 343–347.
Sawada, K., D. Hirabayashi and Y. Enokida (2008).
“Fundamental studies on extraction of actinides from
spent fuels using liquefied gases -:Conversion of cop-
per into nitrate with NO2 and extraction of Nd(III)
nitrate by CO2 with TBP.” Progress in Nuclear Energy
50(2–6): 483–486.
Shimizu, R., K. Sawada, Y. Enokida and I. Yamamoto
(2005). “Supercritical fluid extraction of rare earth ele-
ments from luminescent material in waste fluorescent
lamps.” Journal of Supercritical Fluids 33(3): 235–241.
Sinclair, L. K., D. L. Baek, J. Thompson, J. W. Tester and
R. V. Fox (2017). “Rare earth element extraction from
pretreated bastnasite in supercritical carbon dioxide.”
Journal of Supercritical Fluids 124: 20–29.
Smart, N. G., T. Carleson, T. Kast, A. A. Clifford, M. D.
Burford and C. M. Wai (1997). “Solubility of chelat-
ing agents and metal-containing compounds in super-
critical fluid carbon dioxide.” Talanta 44(2): 137–150.
Tomioka, O., Y. Enokida and I. Yamamoto (1998).
“Solvent extraction of lanthanides from their oxides
with TBP in supercritical carbon dioxide.” Journal of
Nuclear Science and Technology 35(7): 515–516.