XXXI International Mineral Processing Congress 2024 Proceedings/Washington, DC/Sep 29–Oct 3 3377
30. Hussaini, S., et al., Pb-Zn recovery from a malic leach
solution of a carbonate type ore flotation tailing by precipi-
tation and solvent extraction. Separation and Purification
Technology, 2021. 272: p. 118963.
31. Hussaini, S., et al., Recovery of Lead and Zinc from a
Citric Leach Solution of a Non-sulfide Type Ore Flotation
Tailing via Precipitation Followed by Solvent Extraction.
Jom, 2023. 75(5): p. 1569–1580. doi: 10.1007/
s11837-022-05691-5.
32. Wilson, M., et al., Total elemental analysis digestion
method evaluation on soils and clays. Communications
in soil science and plant analysis, 1997. 28(6–8):
p. 407–426.
33. Peña-Icart, M., et al., Comparative study of digestion
methods EPA 3050B (HNO3–H2O2–HCl) and ISO
11466.3 (aqua regia) for Cu, Ni and Pb contamination
assessment in marine sediments. Marine environmental
research, 2011. 72(1–2): p. 60–66.
34. Musariri, B., et al., Evaluating organic acids as alterna-
tive leaching reagents for metal recovery from lithium ion
batteries. Minerals Engineering, 2019. 137: p. 108–
117. doi: 10.1016/j.mineng.2019.03.027.
35. Golmohammadzadeh, R., F. Faraji, and F. Rashchi,
Recovery of lithium and cobalt from spent lithium
ion batteries (LIBs) using organic acids as leach-
ing reagents: A review. Resources, Conservation and
Recycling, 2018. 136: p. 418–435. doi: 10.1016/j.
resconrec.2018.04.024.
36. Angumeenal, A.R. and D. Venkappayya, An overview
of citric acid production. LWT -Food Science and
Technology, 2013. 50(2): p. 367–370. doi: 10.1016/j.
lwt.2012.05.016.
37. Theron, M.M. and J.R. Lues, Organic acids and food
preservation. 2010: CRC press.
38. Gharabaghi, M., M. Irannajad, and M. Noaparast, A
review of the beneficiation of calcareous phosphate ores using
organic acid leaching. Hydrometallurgy, 2010. 103(1):
p. 96–107. doi: 10.1016/j.hydromet.2010.03.002.
39. Astuti, W., et al., Comparison of atmospheric citric acid
leaching kinetics of nickel from different Indonesian sap-
rolitic ores. Hydrometallurgy, 2016. 161: p. 138–151.
doi: 10.1016/j.hydromet.2015.12.015.
40. Hussaini, S., et al., Recovery of Lead and Zinc from a
Citric Leach Solution of a Non-sulfide Type Ore Flotation
Tailing via Precipitation Followed by Solvent Extraction.
JOM, 2023: p. 1–12.
41. Pradier, C.-M. and Y.J. Chabal, Biointerface character-
ization by advanced IR spectroscopy. 2011: Elsevier.
42. Benson, T., The Geology and Origin of Sedimentary
Lithium Deposits. 2021. p. V41B–06.
43. Benson, T.R., M.A. Coble, and J.H. Dilles,
Hydrothermal enrichment of lithium in intracaldera
illite-bearing claystones. Science Advances, 2023. 9(35):
p. eadh8183. doi: 10.1126/sciadv.adh8183.
44. Verma, A., et al., Metal Recovery Using Oxalate
Chemistry: A Technical Review. Industrial &Engineering
Chemistry Research, 2019. 58(34): p. 15381–15393.
doi: 10.1021/acs.iecr.9b02598.
45. Krishnamurty, K.V. and G.M. Harris, The Chemistry of
the Metal Oxalato Complexes. Chemical Reviews, 1961.
61(3): p. 213–246. doi: 10.1021/cr60211a001.
30. Hussaini, S., et al., Pb-Zn recovery from a malic leach
solution of a carbonate type ore flotation tailing by precipi-
tation and solvent extraction. Separation and Purification
Technology, 2021. 272: p. 118963.
31. Hussaini, S., et al., Recovery of Lead and Zinc from a
Citric Leach Solution of a Non-sulfide Type Ore Flotation
Tailing via Precipitation Followed by Solvent Extraction.
Jom, 2023. 75(5): p. 1569–1580. doi: 10.1007/
s11837-022-05691-5.
32. Wilson, M., et al., Total elemental analysis digestion
method evaluation on soils and clays. Communications
in soil science and plant analysis, 1997. 28(6–8):
p. 407–426.
33. Peña-Icart, M., et al., Comparative study of digestion
methods EPA 3050B (HNO3–H2O2–HCl) and ISO
11466.3 (aqua regia) for Cu, Ni and Pb contamination
assessment in marine sediments. Marine environmental
research, 2011. 72(1–2): p. 60–66.
34. Musariri, B., et al., Evaluating organic acids as alterna-
tive leaching reagents for metal recovery from lithium ion
batteries. Minerals Engineering, 2019. 137: p. 108–
117. doi: 10.1016/j.mineng.2019.03.027.
35. Golmohammadzadeh, R., F. Faraji, and F. Rashchi,
Recovery of lithium and cobalt from spent lithium
ion batteries (LIBs) using organic acids as leach-
ing reagents: A review. Resources, Conservation and
Recycling, 2018. 136: p. 418–435. doi: 10.1016/j.
resconrec.2018.04.024.
36. Angumeenal, A.R. and D. Venkappayya, An overview
of citric acid production. LWT -Food Science and
Technology, 2013. 50(2): p. 367–370. doi: 10.1016/j.
lwt.2012.05.016.
37. Theron, M.M. and J.R. Lues, Organic acids and food
preservation. 2010: CRC press.
38. Gharabaghi, M., M. Irannajad, and M. Noaparast, A
review of the beneficiation of calcareous phosphate ores using
organic acid leaching. Hydrometallurgy, 2010. 103(1):
p. 96–107. doi: 10.1016/j.hydromet.2010.03.002.
39. Astuti, W., et al., Comparison of atmospheric citric acid
leaching kinetics of nickel from different Indonesian sap-
rolitic ores. Hydrometallurgy, 2016. 161: p. 138–151.
doi: 10.1016/j.hydromet.2015.12.015.
40. Hussaini, S., et al., Recovery of Lead and Zinc from a
Citric Leach Solution of a Non-sulfide Type Ore Flotation
Tailing via Precipitation Followed by Solvent Extraction.
JOM, 2023: p. 1–12.
41. Pradier, C.-M. and Y.J. Chabal, Biointerface character-
ization by advanced IR spectroscopy. 2011: Elsevier.
42. Benson, T., The Geology and Origin of Sedimentary
Lithium Deposits. 2021. p. V41B–06.
43. Benson, T.R., M.A. Coble, and J.H. Dilles,
Hydrothermal enrichment of lithium in intracaldera
illite-bearing claystones. Science Advances, 2023. 9(35):
p. eadh8183. doi: 10.1126/sciadv.adh8183.
44. Verma, A., et al., Metal Recovery Using Oxalate
Chemistry: A Technical Review. Industrial &Engineering
Chemistry Research, 2019. 58(34): p. 15381–15393.
doi: 10.1021/acs.iecr.9b02598.
45. Krishnamurty, K.V. and G.M. Harris, The Chemistry of
the Metal Oxalato Complexes. Chemical Reviews, 1961.
61(3): p. 213–246. doi: 10.1021/cr60211a001.