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Title:
EXTRACTION OF METALS
Document Type and Number:
WIPO Patent Application WO/2012/079130
Kind Code:
A1
Abstract:
A process for extracting a target metal ion from an aqueous feedstock containing, inter alia, the target metal ion. The process comprises providing said feedstock and contacting the feedstock with a room temperature ionic liquid (RTIL) that is substantially free of an extraneous organic extractant under liquid-liquid extraction conditions for a time sufficient to allow transfer of at least some of the target metal ions from the feedstock to the RTIL. The RTIL is then separated from the feedstock and the target metal ions are recovered from the RTIL.

Inventors:
ZHOU JINGFANG (AU)
RALSTON JOHN (AU)
PRIEST CRAIG IAN (AU)
SEDEV ROSSEN VELIZAROV (AU)
Application Number:
PCT/AU2011/001633
Publication Date:
June 21, 2012
Filing Date:
December 16, 2011
Export Citation:
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Assignee:
UNIV SOUTH AUSTRALIA (AU)
ZHOU JINGFANG (AU)
RALSTON JOHN (AU)
PRIEST CRAIG IAN (AU)
SEDEV ROSSEN VELIZAROV (AU)
International Classes:
C22B3/26
Foreign References:
CN101457292A2009-06-17
CN101736157A2010-06-16
Other References:
OUADI, A. ET AL.: "Task-specific ionic liquid bearing 2-hydroxybenzylamine units: synthesis and americium-extraction studies", CHEMISTRY EUROPEAN JOURNAL, vol. 12, 2006, pages 3074 - 3081
PAPAICONOMOU, N. ET AL.: "Selective extraction of copper, mercury, silver, and palladium ions from water using hydrophobic ionic liquids", INDUSTRIAL ENGINEERING CHEMISTRY RESEARCH, vol. 47, 2008, pages 5080 - 5086
Attorney, Agent or Firm:
MADDERNS PATENT & TRADE MARK ATTORNEYS (Adelaide, South Australia 5001, AU)
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Claims:
THE CLAIMS

1. A process for extracting a target metal ion from an aqueous feedstock containing, inter alia, the target metal ion, the process comprising: - providing said feedstock; contacting the feedstock with a room temperature ionic liquid (RTIL) under liquid-liquid extraction conditions for a time sufficient to allow transfer of at least some of the target metal ions from the feedstock to the RTIL; separating the RTIL from the feedstock; - recovering the target metal ions from the RTIL, wherein the RTIL is substantially free of an extraneous organic extractant.

2. The process according to claim 1 , wherein the metal ion is chosen from one or more of the group consisting of: Pt, Pd, Fe, Co, Cu, Sn, Bi, Zn, and Mn.

3. The process according to either claim 1 or claim 2, wherein the process also comprises treating the aqueous feedstock to increase the concentration of inorganic anions in the feedstock prior to contact with the RTIL.

4. The process according to claim 3, wherein the inorganic anion is a halide ion selected from iodide; bromide, chloride, and fluoride.

5. The process according to claim 4, wherein the halide ion is chloride. 6. The process according to any one of claims 3 to 5, wherein the concentration of inorganic anions in the aqueous feedstock is increased by adding a salt containing the inorganic anion to the feedstock.

7. The process according to claim 6, wherein the concentration of halide ion in the aqueous feedstock can be increased by adding a halide salt to the feedstock. 8. The process according to claim 8, wherein the process comprises treating the aqueous feedstock with HCl to increase the chloride concentration in the feedstock prior to contact with the RTIL.

9. The process according to claim 8, wherein the aqueous feedstock is about 0.02M HCl.

10. The process according to claim 8, wherein the aqueous feedstock is about 0.1M HC1.

1 1. The process according to claim 8, wherein the aqueous feedstock is about 2M HC1.

12. The process according to claim 8, wherein the aqueous feedstock is about 3M HC1.

13. The process according to claim 8, wherein the aqueous feedstock is about 7M HC1. 14. The process according to claim 8, wherein the process comprises treating the aqueous feedstock with KCl to increase the chloride concentration in the feedstock prior to contact with the

RTIL.

15. The process according to claim 14, wherein the aqueous feedstock is about 3M KCl.

16. The process according to any one of the preceding claims, wherein the cation of the RTIL is imidazolium.

17. The process according to any one of claims 1 to 15, wherein the cation of RTIL is piperidinium.

18. The process according to any one of claims 1 to 15, wherein the cation of the RTIL is pyrrolidiunium. 19. The process according to any one of claims 1 to 15, wherein the cation of the RTIL is ammonium.

20. The process according to any one of claims 1 to 15, wherein the cation of the RTIL is phosphonium.

21. ' The process according to any one of the preceding claims, wherein the cation of the RTIL comprises at least one alkyl group having six or more carbon atoms in the normal chain.

22. The process according to any one of the preceding claims, wherein the anion of the RTIL is bis(trifluoromethanesulfonyl) imide.

23. The process according to any one of claims 1 to 22, wherein the anion of the RTIL is chloride.

24. The process according to any one of claims 1 to 22, wherein the anion of the RTIL hexafluorophosphate.

25. The process according to any one of claims 1 to 15, wherein the RTIL is tetradecyl(trihexyl)phosphonium chloride (Pu,6.6.6-Cl).

26. The process according to claim 25, wherein the target metal is selected from the group consisting of: Pt, Pd, Cu, Fe, Co, Mn, Zn, Bi, and Sn. 27. The process according to any one of claims 1 to 15, wherein the RTIL is l-hexyl-3- methylimidazolium bis(trifluoromethanesulfonyl)imide (hmim.NTf2).

28. The process according to claim 27, wherein the target metal is selected from the group consisting of: Pt, Bi, and Sn.

29. The process according to any one of claims 1 to 15, wherein the RTIL is l-dodecyl-3- methylimidazolium bis(trifluoromethanesulfonyl)imide (dmim.NTf2).

30. The process according to claim 29, wherein the target metal is Pt.

31. The process according to any one of claims 1 to 15, wherein the RTIL is

methyltrioctylammonium bis(trifluoromethylsulfonyl)imide (Ng.8.8.i . Tf2). ·

32. The process according to claim 31 , wherein the target metal is selected from the group consisting of: Pt, Pd, Bi, and Sn.

33. The process according to any one of claims 1 to 15, wherein the RTIL is l-hexyl-3- methylimidazolium hexafluorophosphate (hmim.PF6).

34. The process according to claim 33, wherein the target metal is selected from the group consisting of: Pt and Pd. 35. A process for selectively extracting Sn, Bi, Cu, Zn, Mn, Fe and/or Co ions from an aqueous feedstock that also contains Mg, Ca, Al, Cr, and/or Ni ions, the process comprising: providing said feedstock; treating the feedstock with hydrochloric acid to a concentration of about 3M HC1; contacting the feedstock with tetradecyl(trihexyl)phosphonium chloride under liquid- liquid extraction conditions for a time sufficient to allow transfer of at least some of any

Sn, Bi, Cu, Zn, Mn, Fe and/or Co ions from the feedstock to the

tetradecyl(trihexyl)phosphonium chloride; and separating the tetradecyl(trihexyl)phosphonium chloride from the feedstock.

36. A process for selectively extracting Sn, Bi, and/or Fe ions from an aqueous feedstock that also contains Mg, Ca, Al° Cu, Zn, Cr, Mn, Co, and/or Ni ions, the process comprising: providing said feedstock; treating the feedstock with hydrochloric acid to a concentration of about 3M HC1; - contacting the feedstock with l-hexyl-3-methylimidazolium hexafluorophosphate under liquid-liquid extraction conditions for a time sufficient to allow transfer of at least some of any Sn, Bi, and/or Fe ions from the feedstock to the 1 -hexyl-3-methylimidazolium hexafluorophosphate; and separating the l-hexyl-3-methylimidazolium hexafluorophosphate from the feedstock. 37. A process for selectively extracting Sn, Bi, and/or Fe ions from an aqueous feedstock that also contains Mg, Ca, Al, Cu, Zn, Cr, Mn, Co, and/or Ni ions, the process comprising: providing said feedstock; treating the feedstock with hydrochloric acid to a concentration of about 3M HC1; contacting the feedstock with methyltrioctylammonium bis(trifluoromethylsulfonyl)imide under liquid-liquid extraction conditions for a time sufficient to allow transfer of at least some of any Sn, Bi, and/or Fe ions from the feedstock to the methyltrioctylammonium bis(trifluoromethylsulfonyl)imide; and separating the methyltrioctyiammonium bis(trifluoromethylsulfonyl)imide from the feedstock 38. The process according to any one of claims 1 to 37, wherein the process is carried out in a microfluidic extraction device.

Description:
EXTRACTION OF METALS

This patent application claims priority from Australian Provisional Patent Application No.

2010905533 titled "Extraction of Metals" and filed 17 December 2010, the entire contents of which are hereby incorporated by reference. FIELD

The present invention relates to processes for extracting target metal ions from aqueous solutions using liquid-liquid extraction.

BACKGROUND

Liquid-liquid extraction, also known as solvent extraction (SX), is a process for separating a specific component from a mixture that is widely used in manufacturing, synthetic chemistry, analytical chemistry, waste treatment, and nuclear waste processing (Bemardis, Grant et al. 2005). In mineral processing, SX plays an important role in recovery and refining of valuable metals from mineral ores including copper, precious metals, uranium and lanthanides, etc (Billard, Ouadi et al.; Kumar, Sahu et al. 2010). SX offers a number of advantages of other separation processes, such as continuous operation, simple equipment, high throughput, as well as diversity of the extraction chemistry. Thus, SX is a separation technique of major industrial significance (Bond, Dietz et al. 1999; Gmehling 2004). In traditional SX, the two immiscible phases are an organic solvent and an aqueous solution. However, many common organic solvents are volatile, flammable and toxic, and therefore are hazardous and are becoming less acceptable from an environmental viewpoint. Disposal of spent extractants and diluents also attracts increasing costs through the impact of environmental protection regulations.

In recent times, room temperature ionic liquids (RTILs) have gained interest in solvent extraction processes as they are potentially environmentally benign alternatives to the use of volatile organic compounds (VOCs). RTILs possess a number of potential advantages over traditional VOCs, such as a wide liquid range of up to 200°C, good thermal stability up to 300°C, extremely low vapour pressure, non-flammability and the properties of the RTILs can be fine-tuned by varying the anion and cation. RTILs are known to be polar but non-coordinating media, and have been shown to dissolve different organic, inorganic, organometallic and biomolecules. For example, RTILs have been used as a liquid-liquid extraction media to separate organic solutes, such as aromatic solutes, from aqueous solutions (Huddleston, Wilauer et al. 1998; Gmehlig, 2004). To date, a limited range of RTILs have been used in solvent extraction processes to extract metal ions from aqueous solutions. Dai et al. (1999) describes a process for extracting strontium from aqueous solutions of strontium nitrate using an RTIL containing a crown ether. Dietz et al. (2006) describes processes for extracting various metal ions using ionic liquids containing organic extractants such as l-(2-pyridylazo)-2-naphthol (PAN), l-(2-thiazolyl)-2-naphthol (TAN), crown ethers and calixarenes. Visser and Rogers (2003) describe processes for extracting actinide metals from aqueous solutions using RTILs containing crown ethers. In each of the aforementioned processes, the RTILs are used as a solvent and an organic extractant is added to the organic phase. In the absence of an extractant, the distribution ratios in [C 4 mim][PF 6 ]/aqueous phases at pH 1 to 13 of the metal ions studied (including Hg 2+ , Cd 2+ , Co 2+ , Ni 2+ , Fe 3+ ) were all relatively low, indicating retention in the aqueous phase. In the presence of extractants, the partitioning of the extracted organic moieties or metal ions in the RTIL/water systems is similar to the partitioning that is achieved in traditional organic solvent-water systems.

A problem with the use of RTILs on a large scale is the cost of the solvent and the higher viscosity of the RTILs relative to VOCs. This is further compounded by the fact that extractants need to be added to the RTILs to assist in the efficient extraction of metals from aqueous solutions.

There is a need for a better understanding of the kinetics of extraction of metal ions from aqueous solutions using RTILs and also any relationship between the structure of the RTIL (the cation and/or the anion) and the extraction efficiency. Alternatively and/or in addition, there is a need for improved extraction processes using RTILs.

SUMMARY

The present invention arises from research into the extraction of precious metals and base metals from aqueous phases into different types of RTILs, and in particular, our finding that RTILs can be used in liquid-liquid extraction of metal ions not only as solvents but also extractants. We have shown that RTILs can be used as effective anion exchange extractants and that the extraction process is fast and highly efficient with extraordinarily high loading capacity. For example, some metals can be extracted quantitatively in one cycle.

In a first aspect, the present invention provides a process for extracting a target metal ion from an aqueous feedstock containing the target metal ion, the process comprising: providing said feedstock; contacting the feedstock with a room temperature ionic liquid (RTIL) under liquid-liquid extraction conditions for a time sufficient to allow transfer of at least some of the target metal ions from the feedstock to the RTIL; and separating the RTIL from the feedstock, wherein the RTIL is substantially free of an extraneous organic extractant.

In some embodiments, the target metal ion is chosen from one or more of the group consisting of: Pt, Pd, Fe, Co, Cu, Sn, Bi, Zn, and Mn.

In some embodiments, the process further comprises recovering the target metal ions or metal from the RTIL. In some embodiments, the process further comprises treating the aqueous feedstock to increase the concentration of inorganic anions in the feedstock prior to contact with the RTIL. In some embodiments, the inorganic anion is selected from the group consisting of: halide ion, thiocyanate ion, thiosulfate ion, nitrate ion, and perchlorate ion. In some embodiments, the halide ion is selected from iodide, bromide, chloride, and fluoride. In some specific embodiments, the halide ion is chloride.

In some embodiments, the RTIL is selected from the group consisting of: ethyl-3-methylimidazolium bis(trifluoromethanesulfonyl)imide (emim.NTf 2 ); l-hexyl-3-methylimidazolium

bis(trifluoromethanesulfonyl)imide (hmim.NTf 2 ); l-hexyl-3-methylimidazolium hexafluorophosphate ( hmim.PF 6 ); l-dodecyl-3-methylimidazoliumbis(trifluoromethylsulfonyl)imi de (dmim.NTf 2 ); 1 - methyl- 1 -propylpiperidinium bis(trifluoromethylsulfonyl)imide (mppip.NTf 2 ); 1 -methyl- 1- propylpyrrolidinium bis(trifluoromethylsulfonyl)imide (mpPyr.NTf 2 ); tradecyl(trihexyl)phosphonium bis(trifluoromethanesulfonyl)imide P| 4 6 6 6 .NTf 2 ); tetradecyl(trihexyl)phosphonium chloride

(Pi4.6.6.6-Cl); methyltrioctylammonium bis(trifluoromethylsulfonyl)imide (N 8 .8.8.i -NTf 2 ); and butyltrimethylammonium bis(trifluoromethylsulfonyl)imide (N4.1.1.1. Tf 2 ). In some specific embodiments, the RTIL is tetradecyl(trihexyl)phosphonium chloride (Pi 4, 6.6.6-Cl). In these embodiments, the target metal ion may be selected from the group consisting of: Pt, Pd, Cu, Fe, Co, Mn, Zn, Bi, and Sn ions.

In some specific embodiments, the RTIL is l-hexyl-3-methylimidazolium

bis(trifluoromethanesulfonyl)imide (lmiim.NTf 2 ). In these embodiments, the target metal ion may be selected from the group consisting of: Pt, Bi, and Sn ions. In some specific embodiments, the RTIL is 1 -dodecyl-3-methylimidazolium

bis(trifluoromethanesulfonyl)imide (dmim.NTf 2 ). In these embodiments, the target metal ion may be Pt ions.

In some specific embodiments, the RTIL is methyltrioctylammonium

bis(trifluoromethylsulfonyl)imide (N 8 , 8 . 8 .i.NTf 2 ). In these embodiments, the target metal ions may be selected from the group consisting of: Pt, Pd, Bi, and Sn ions.

In some specific embodiments, the RTIL is l-hexyl-3-methylimidazolium hexafluorophosphate (hmim.PF 6 ). In these embodiments, the target metal ion may be selected from the group consisting of: Pt and Pd ions. Surprisingly, we have found that Sn, Bi, Cu, Zn, Mn, Fe and/or Co ions can be selectively extracted from an aqueous feedstock that also contains Mg, Ca, Al, Cr, and/or Ni ions at 3M HCl concentration using tetradecyl(trihexyl)phosphonium chloride as the RTIL.

We have also found that Sn, Bi, and/or Fe ions can be selectively extracted from an aqueous feedstock containing Mg, Ca, Al, Cu, Zn, Cr, Mn, Co, and/or Ni ions at 3M HCl concentration using 1 -hexyl-3- methylimidazolium hexafluorophosphate as the RTIL.

We have further found that Sn, Bi, and or Fe ions can be selectively extracted from aqueous feedstock containing Mg, Ca, Al, Cu, Zn, Cr, Mn, Co, and/or Ni ions at 3M HCl concentration using methyltrioctylammonium bis(trifluoromethylsulfonyl)imide as the RTIL.

BRIEF DESCRIPTION OF THE ACCOMPANYING FIGURES Figure 1 shows a plot of extraction percentage of Pt versus various RTILs at different HCl concentrations.

Figure 2 shows a plot of extraction percentage of Pd versus various RTILs at different HCl concentrations.

Figure 3 shows a plot showing a comparison of extraction percentage of Pt and Pd versus various RTILs at different 3M HCl concentration.

Figure 4 shows a plot of extraction percentage of Cu versus various RTILs at different HCl concentrations.

Figure 5 shows a plot of extraction percentage of Fe, Co and Cu by Pi4.6.6. & -Cl at different HCl concentrations and 3M KC1 concentration. Figure 6 shows a plot of the logarithm of distribution reation of Fe, Co and Cu extracted by Pi .6.6.6-Cl at different HC1 concentrations.

Figure 7 shows a plot of extraction percentage of different metals extracted by hmim.NTf 2 ,

8.8.8.i- Tf 2 and Pi4 ,666 .Cl at 3M HC1 concentration. Figure 8 (a) shows a schematic of the solvent extraction using microfluidic streams of aqueous and organic phase; (b) shows an image of the microchip in operation; (c) shows an image of the UV-vis flow cell (Fiber Optic SMA Z-Flow Cell) which was coupled to the outlet of the solvent extraction chip for online analysis of the extraction performance. The direction of flow is shown by the arrows. Optic fibres were connected to the light source and spectrometer (not shown), and fitted to the cell (left and right).

Figure 9 shows a plot of extraction percentage of Au, Pt and Pd from their mixture versus RTILs at 0.02 M HC1 concentration

Figure 10 shows a plot of extraction percentage of Au, Pt and Pd from their mixture versus RTILs at 0.1 M HC1 concentration Figure 11 shows a plot of extraction percentage of Au, Pt and Pd from their mixture versus RTILs at 2 M HC1 concentration

Figure 12 shows a plot of extraction percentage of Au, Pt and Pd from their mixture at 0.1 M HC1 solution in a microchannel as a function of residence time

DETAILED DESCRIPTION The present invention provides a process for extracting a target metal ion from an aqueous feedstock containing the target metal ion. The process comprises providing said feedstock. The feedstock may be any aqueous solution, suspension, emulsion, etc containing the target metal ion. Examples of feedstocks include leachates, leach solutions, waste water, nuclear waste, reaction mixtures, etc.

The feedstock is contacted with a room temperature ionic liquid (RTIL) under liquid-liquid extraction conditions for a time sufficient to allow transfer of at least some of the target metal from the feedstock to the RTIL. As iised herein, the terms "room temperature ionic liquid", "RTIL", and similar terms, mean a salt that is in the liquid state at room temperature. Room temperature ionic liquids consist of a bulky, asymmetric organic cation and a smaller anion and they are liquids at relatively low temperatures (eg below about 100°C). A range of RTILs are available commercially or can be synthesised using known methods. Specific RTILs that are suitable for use in processes of the present invention have imidazolium, piperidinium, pyrrolidiunium, ammonium or phosphonium cations. The anion of the RTIL may be bis(trifluoromethanesulfonyl) imide, chloride or hexafiuorophosphate.

In some embodiments, the RTEL is selected from the group consisting of: ethyl-3-methylimidazolium bis(trifluoromethanesulfonyl)imide (emim.NTf 2 ); 1 -hexyl-3-methylimidazoIium

bis(trifluoromethanesulfonyl)imide (hmim.NTf 2 ); l-hexyl-3-methylimidazoHum hexafiuorophosphate ( hmim.PFe); l-dodecyl-3-methylimidazoliumbis(trifluoromethylsulfonyI)imi de (dmim.NTf 2 ); 1 - methyl- 1 -propylpiperidinium bis(trifluoromethy lsulfonyl)imide (mppip.NTf 2 ); 1 -methyl- 1 - propylpyrrolidinium bis(trifluoromethylsulfonyl)imide (mpPyr.NTf 2 ); tradecyl(trihexyl)phosphonium bis(trifluoromethanesulfonyl)imide Pi4,6,6,6- Tf 2 ); tetradecyl(trihexyl)phosphonium chloride

(Pi4,6,6,6-Cl); methyltrioctylammonium bis(trifluoromethylsulfonyl)imide (N8,8 , . , i.NTf 2 ); and butyltrimethylammonium bis(trifiuoromethylsulfonyl)imide (N4 , i , i i.NTf 2 ).

Specific RTILs that we have found to be particularly suitable for use in the processes of the present invention include tetradecyl(trihexyl)phosphonium chloride (Ρΐ4,6,6,6·0), l-hexyl-3- methylimidazolium bis(trifluoromethanesulfonyl)imide (hmim.NTf 2 ), l-dodecyl-3- methylimidazolium bis(trifluoromethanesulfonyl)imide (dmim.NTf 2 ), methyltrioctylammonium bis(trifluoromethylsulfonyl)imide (N8,8,8.i-NTf 2 ), and l-hexyl-3-methylimidazolium

hexafiuorophosphate (hmim.PF 6 ).

The RTIL may be a pure or semi-pure RTIL or it could be part of a mixture containing, for example, another water immiscible solvent. The RTIL is substantially free of an extraneous organic extractant, the significance, of which will be described in more detail later.

The feedstock can be contacted with the RTIL using any apparatus or technique suitable for liquid- liquid extraction. For example, the feedstock may be contacted with the RTIL by combining the two phases in a suitable vessel and mixing to at least partially disperse the phases in one another. The time taken for mixing will vary depending on the nature of the ion to be extracted, the feedstock, the particular RTIL used, the temperature, etc. Processes for bulk phase solvent extraction are known in the art.

Alternatively, the feedstock and the RTIL may be mixed in a microfluidic liquid-liquid extraction device. The microfluidic liquid-liquid extraction device may be as described herein and/or as described in our co-pending published application WO 2010/022441 titled "Extraction Processes" (the disclosure of which is incorporated herein in its entirety) and/or our co-pending unpublished

Australian provisional patent application 2010905349 titled "High Throughput Microfluidic Device" and/or using any of the microfluidic separation techniques known in the art. Briefly, the microfluidic device may comprise a microchip containing an aqueous phase microchannel and an extractant phase microchannel. A pressure driven, co-current laminar flow technique may be applied during the process of solvent extraction in the microchannel, where the aqueous phase and the extractant phase converge at a Y-junction and flow together without mixing along the channel length, before separating at another Y-junction downstream. The residence time for extraction can be manipulated by altering the flow rate of the two phases using syringe pumps.

After the feedstock and the RTIL have been in contact with one another for a time sufficient to allow transfer of at least some of the target metal ion from the feedstock to the RTIL, the RTIL is separated from the feedstock. In most cases, the two phases are physically separated from one another using any of the techniques known for that purpose in the art. For example, in a bulk extraction vessel, the aqueous feesdstock may be removed from the bottom of the vessel using a suitable valve located toward the bottom of the vessel.

After separating the RTIL from the feedstock, the target metal ion can be recovered from the RTIL either as ions or as the metal. Methods for recovering metal ions or metals from solvents or solution are known in the art and can be used in the processes of the present invention. For example, the RTILs can be used as electrolytes and, therefore, many of the metals extracted into RTILs, including Pd, Pt, Sn, Bi, Cu and Zn, can be recovered by electro-deposition from the RTILs. The stripping stage that is typically used in conventional solvent extraction is therefore not needed in the processes of the present invention. By way of further example, the RTIL containing the target metal ion can be treated with a reducing agent to reduce metal ions to metals which are then able to be separated from the RTIL.

It will be appreciated from the foregoing description that in the processes of the present invention the RTIL is substantially free of any extraneous organic extractant. This is in contrast to prior art processes described previously which use an organic extractant in the RTIL.

The process may further comprise treating the aqueous feedstock to increase the concentration of inorganic anions in the feedstock prior to contact with the RTIL. In some embodiments, the

"inorganic anion" is selected from the group consisting of: halide ion, thiocyanate ion, thiosulfate ion, nitrate ion, and perchlorate ion. In some embodiments, the halide ion is selected from iodide, bromide, chloride, and fluoride. In some specific embodiments, the halide ion is chloride.

The concentration of inorganic anions in the aqueous feedstock can be increased by adding a salt containing the inorganic anion to the feedstock. For example, the concentration of halide ion in the aqueous feedstock can be increased by adding a halide salt to the feedstock. In the case of chloride, suitable halide salts include HC1, KC1, NaCl, NH 4 CI, etc. Equivalent iodide, bromide, fluoride, thicyanate, nitrate or perchlorate salts could be used. In some specific embodiments, the process comprises treating the aqueous feedstock with HC1 to increase the chloride concentration in the feedstock prior to contact with the RTIL. The amount of HC1 added to the feedstock may depend on the target metal and/or the RTIL used. In some embodiments, the aqueous feedstock is from about 0.01M to about 10M HC1. In some specific embodiments, the aqueous feedstock is from about 0.01M to about 0.090M HC1. In some other specific embodiments, the aqueous feedstock is from about 1M to about 9M HC1. In some other specific embodiments, the aqueous feedstock is from about 2M to about 4M HC1. In some other specific embodiments, the aqueous feedstock is from about 6M to about 9M HQ. In some other specific embodiments, the aqueous feedstock is about 0.02M HQ. In some other specific embodiments, the aqueous feedstock is about 3M HQ. In some other specific embodiments, the aqueous feedstock is about 7M HQ.

In some specific embodiments, the process comprises treating the aqueous feedstock with Q to increase the chloride concentration in the feedstock prior to contact with the RTIL. The amount of KQ added to the feedstock may depend on the target metal and/or the RTIL used. In some embodiments, the aqueous feedstock is from about 1M to about 9M HQ. In some specific embodiments, the aqueous feedstock is about 3M KQ.

In some embodiments, the process also comprises treating the aqueous feedstock to decrease the pH of the feedstock prior to contact with the RTIL.

The target metal ion may be chosen from one or more of the group consisting of: Pt, Pd, Fe, Co, Cu, Sn, Bi, Zn, and Mn. We have found that certain RTILs show selectivity for some of these metal ions over other metal ions. This means that the processes described herein may be used to selectively extract a target metal ion from an aqueous feedstock solution containing other non-target metal ions.

In some embodiments, the RTIL is tetradecyl(trihexyl)phosphonium chloride (Pi4.6.6.6-Cl). In these embodiments, the target metal may be selected from the group consisting of: Pt, Pd, Cu, Fe, Co, Mn, Zn, Bi, and Sn.

In some embodiments, the RTIL is l-hexyl-3-methylimidazolium bis(trifluoromethanesulfonyl)imide (hmim.NTf 2 ). In these embodiments, the target metal may be selected from the group consisting of: Pt, Bi, and Sn.

In some embodiments, the RTIL is l-dodecyl-3-methylimidazolium

bis(trifluoromethanesulfonyl)imide (dmim.NTf 2 ). In these embodiments, the target metal may be Pt. In some embodiments, the RTIL is methyltrioctylammonium bis(trifluoromethylsulfonyl)imide (N8. 8 . 8 .i-NTf 2 ). In these embodiments, the target metal may be selected from the group consisting of: Pt, Pd, Bi, and Sn.

In some embodiments, the RTIL is 1 -hexyl-3-methylimidazolium hexafluorophosphate (hmim.PF 6 ). In these embodiments, the target metal may be selected from the group consisting of: Pt and Pd.

Surprisingly, we have found that Sn, Bi, Cu, Zn, Mn, Fe and/or Co ions can be selectively extracted from aqueous feedstock that also contains Mg, Ca, Al, Cr, and/or Ni ions at 3M HCl concentration using tetradecyl(trihexyl)phosphonium chloride as the RTIL.

We have also found that Sn, Bi, and/or Fe ions can be selectively extracted from aqueous feedstock containing Mg, Ca, Al, Cu, Zn, Cr, Mn, Co, and/or Ni ions at 3M HCl concentration using l-hexyl-3- methylimidazolium hexafluorophosphate as the RTIL.

We have further found that Sn, Bi, and/or Fe ions can be selectively extracted from aqueous feedstock containing Mg, Ca, Al, Cu, Zn, Cr, Mn, Co, and/or Ni ions at 3M HCl concentration using methyltrioctylammonium bis(trifluoromethylsulfonyl)imide as the RTIL. The performance of specific ionic liquids on the extraction of Pt and Pd from 0.02 and 3 M HCl solutions is shown in Figures 1 and 2, respectively. The results show that Pt can be extracted effectively by PH. 6 . 6 . 6 -C1, N G . 8 . 8 .i-NTf 2 , hmim.PF 6 and dmim.NTf 2 . Pd can be extracted by PMAM-CI, 8. 8 . 8 .i-NTf2 and hmim.PF 6 . With an increase in HCl concentration, the extraction percentage decreases except for Pt extracted with dmim.NTf 2 . Longer hydrocarbon chains in the cation of the RTIL give rise to a higher extraction percentage. With chains shorter than six carbon atoms in the normal chain, low extraction percentages were found. N 8,8 ;8.i.NTf 2 can extract Pt and Pd better than hmim.PF 6 . The efficiency of RTILs decreases in the following order: Pi . 6 . 6 . 6 .Cl > N 8, 8.8.i.NTf 2 > hmim.PF 6 > other RTILs.

Figure 3 shows the comparison of extraction percentage of Pt and Pd versus different RTILs at 3 M HCl concentration. It shows that the extraction percentage decreases in the order of Pt > Pd. RTILs including Pi 4 . 6 . 6 . 6 Cl, N G . 8 .8.i-NTf 2 , hmim.PF 6 , dmim.NTf 2 and hmim.NTf 2 can extract both of these metals to a certain extent. Among them, Pi 4 . 6 . 6 . 6 -Cl can extract Pt and Pd well above 85 % for each metal.

The invention is hereinafter described by way of the following non-limiting examples. EXAMPLES

Example 1 - Bulk solution phase extraction of various metals using RTILs RTILs

All RTILs used in this investigation (listed below) were purchased from IoLiTec, Germany, except for tetradecyl(trihexyl)phosphonium bis(trifluoromethanesulfonyl) imide, which was purchased from Strem Chemicals, USA. Five types of cations were studied: imidazolium (Im), piperidinium (Pip), pyrrolidinium (Pyr), ammonium (N) and phosphonium (P). In all cases the anion was

bis(trifluoromethanesulfonyl) imide ( Tf 2 ). The anions hexafluorophosphate (PF 6 ) and chloride (CI) were further chosen for hmim and phosphonium cations, respectively. Imidazolium and ammonium cations with different chain lengths were also used.

Ethyl-3-methylimidazolium bis(trifluoromethanesulfonyl)imide, 98 %, (emim.NTf 2 ) l-Hexyl-3-methylimidazolium bis(trifluoromethanesulfonyl)imide, 98 %, (hmim.NTf 2 ) l-Hexyl-3-methylimidazolium hexafluorophosphate, 99 %, ( hmim.PF 6 ) l-D0decyl-3-methylimidazoliumbis(trifluoromethylsulfonyl)imi de, 98 %, (dmim.NTf 2 ) 1 -Methyl- 1 -propylpiperidinium bis(trifluoromethylsulfonyl)imide, 99 %, (mppip.NTf 2 )

1 -Methyl- 1-propylpyrrolidinium bis(trifluoromethylsulfonyl)imide, 99 %: mpPyr.NTf 2 Tetradecyi(trihexyl)phosphonium bis(trifluoromethanesulfonyl)imide, 97 %, (Pi4.6,6. 6 NTf 2 ) Tetradecyl(trihexyl)phosphonium chloride, 96 %, ( P 14 . 6-6 , 6 .C1) Methyltrioctylammonium bis(trifluoromethylsulfonyl)imide, 99 %, (N 8 ,8,8.i-NTf 2 ) Butyltrimethylammonium bis(trifluoromethylsulfonyl)imide, 99 %, (N 4, i ,u . Tf 2 )

Metal salts

Fifteen metals were tested. Precious metal salts of AR grade, PdCl 2 , and H 2 PtCl 6 xH 2 C\ were purchased from Sigma-Aldrich. AR grade CuCl 2 -2H 2 0, MgCl 2 -6H 2 0, A1C1 3 -6H 2 0 and CaCl 2 were purchased from Chem-Supply. AR grade BiOCl, SnCl 2 -2H 2 0, MnCl 2 -4H 2 0, FeCl 3 . NiSCyxH 2 0 and CrCl 3 -6H 2 0 were obtained from BDH. AR grade CoCl 2 -6H 2 0 was purchased from Merck. Stock solution for each metal

All metal salts were dissolved in pure water with different HCl concentrations (typically 0.02, 3 and 7 M HCl). Stock solutions of the precious metals were prepared: 500 ppm PdCl 2 and 1000 ppm H 2 PtCl 6 The concentrations of copper and nickel were 5 and 15 g/L, respectively. For all other metals, the concentration of metal salt was 10 g/L.

Conventional batch solvent extraction

0.5 ml RTIL and 2 ml aqueous solution containing metal ions were added into a small glass vial. They were mixed vigorously with a magnetic stirrer for 30 min to achieve equilibrium distribution. When extraction was completed, the solution was left overnight to phase separate. After that, the aqueous phase was carefully removed and used for UV or ICP measurement.

The influence of hydrophobic Si0 2 nanoparticles on copper extraction

Si0 2 nanoparticles (R816) were purchased from Degussa. The primary particle size is 12 nm and the water contact angle is 30-40°. 5 g/L of copper solution was prepared in 0.02 and 3 M HCl, as well as in 3 M KC1 solution. Si0 2 nanoparticles (5 g/L) were then added in the above solution and sonicated for 30 min before extraction. The copper solution loaded with Si0 2 nanoparticles was extracted with P|4.6.6.6-C1 under the same conditions as described above.

Extraction percentage

Extraction percentage is defined as the amount of solute in the ionic liquid phase (after extraction) divided by the amount in aqueous phase (before extraction). UV-vis and ICP techniques were used to determine the concentration of metal ions in the aqueous solutions before and after extraction. For precious metals and Cu, Ni, Fe, and Co, the UV-vis absorption spectra in the aqueous phase were recorded. The absorbance at a given wavelength (HAuCl 4 at 310 nm, PdCl 2 at 429 nm, H 2 PtCl 6 at 375 nm CuCl 2 at 807 nm NiCl 2 at 393 nm, FeCl 2 at 337 nm and CoCl 2 at 510 nm) was used to calculate the extraction percentage as: E % = [(Ao - A*) / Ao] x 100

Ao: absorbance before extraction, A*: absorbance after extraction.

For all other metals, the ICP technique was used to measure the concentration of metal ions in aqueous solution after extraction. The extraction percentage was calculated as: E % = [(Co - C*) / Co] x 100

C 0 : concentration before extraction, C*: concentration after extraction. Distribution ratio

The distribution ratio is defined as the concentration of the solute in the ionic liquid divided by its concentration in the aqueous phase:

D = [M] IL / [M] aq

The relationship between extraction percentage and distribution ratio is: E % = 100 D / [D + (V aq / V IL )]

In our study, the volume ratio of ionic liquid and aqueous phase is not equal to 1. The distribution ratio is therefore calculated as:

D = [(Co - C*) / C 0 ] x V aq / V IL

C 0 : concentration before extraction, C*: concentration after extraction. V aq is the volume of the aqueous phase (2 ml). Vi L is the volume of the ionic liquid. The weight of the ionic liquids was measured and the volume was calculated using the known density.

RTILs can also be used to extract base metals. Cu extraction was carried out under the same conditions as those used for the precious metals. The results for Cu extraction with different RTILs from 0.02 M and 3 M HCl solutions are shown in Figure 4. With Pi4,6 , 6.6-Cl over 90% of the Cu can be extracted from a 3 M HCl solution. All other RTILs were inefficient in extracting Cu from both 0.02 and 3 M HCl solutions. With the increase of HCl concentration in the copper solution, the extraction percentage increased slightly for all RTILs except for Pi 4 .6.6,6-Cl at 3 M HCl, which enhanced Cu . extraction dramatically. The increase of chain length can enhance the Cu extraction as observed for precious metals. For copper extraction, only the CI anion performed well no matter what type and structure the cation RTILs have. In order to understand the extraction mechanism of base metals, the extraction of Fe, Co and Cu using Pi4.6.6.6-Cl was conducted under different conditions. The extraction results along with the corresponding distribution ratios are shown in Figures 5 and 6.

Iron can be extracted (E ~ 70%) even from neutral water. The extraction percentage reached nearly 100% in 3 and 7 M HCl solutions (the distribution ratio was above 3000 in 7 M HCl). Cobalt is not extracted efficiently from neutral water. With increasing HCl concentration, the extraction percentage increases significantly. For copper, no extraction was observed from neutral water. This indicates that, for example, Fe can be selectively extracted from an aqueous feedstock containing Fe, Co and/or Cu ions at neutral pH. However, the extraction percentage of Cu increased dramatically in 3 and 7 M HCl solution. The extraction percentage in 3 M KC1 solution was comparable to that in 3 M HCl. Under these conditions, added Si0 2 nanoparticles did not have a significant influence on the - extraction percentage. When compared with Si0 2 loaded-organic solvent/aqueous system where particle-stabilized emulsions are formed, RTIL/aqueous system did not show the same phenomena. As the aqueous phase was clear and no apparent UV absorption was observed, Si0 2 particles were likely transferred to the RTILs (which were opaque, though clear when free of Si0 2 particles).

The phenomena observed showed that it is possible to extract base metals effectively when using RTILs including hrnim.PF 6 , N g ,8 ,8 NTf 2 and Pi4.6.6.6-Cl under high chloride concentrations. Based on these observations, the extraction of other metals, including Mg, Ca, Al, Sn, Bi, Zn, Cf , Mn and Ni, from 3 M HCl was carried out. The results are shown in Figure 7. For group A metals, no appreciable Mg can be extracted, while Ca and Al can be extracted to a low extent. However, Sn can be extracted efficiently and Bi can be extracted quantitatively by the three RTILs. With the order of group A metals moving from IIA to VA, extraction efficiency increased dramatically. As for group B metals, Cr and Ni was not extracted by the three RTILs. Zn, Co and Mn can be extracted only by phCl with the extraction percentage above 99 %, 80 % and less than 40 %, respectively. Hmim.NTf2 and mta.NTf2 can extract Cu to a low extent and Fe less than 30 %. However, they can be extracted above 98 % by phCl. When the order of group B metals moved from IB to IIVB, extraction efficiency decreased significantly. As for group fflVB metals, the extraction percentage decreased in the order ofFe > Co » Ni≡0.

It was observed that phase separation can be completed in one to two minutes in most cases. Phase separation time increased with an increase of hydrocarbon chain length. It can take several hours for RTILs with longer chain lengths (> 12 CH 2 units) at low HCl concentrations to complete phase separation. However, it was improved dramatically at high HCl or salt concentrations, where phase separation took only a few minutes.

Anion exchange extraction is a process where metal complex anions move from an aqueous phase to an organic phase, while anions in the organic phase transfer from the organic phase to the aqueous phase. Metal complex anions are surrounded by water molecules and interact with cations in the aqueous phase. When they leave the aqueous phase, they absorb the hydration energy, AE hy , as well as the ion association energy, ΔΕ ω ν , releasing cavitation energy in the aqueous phase, - AE W _ W . During transfer, they absorb cavitation energy, ΔΕο^, to enter into organic phase, meanwhile releasing solvation energy with organic molecules, - ΔΕ 50 |, as well as ion association energy with cations in organic phase, - AE as ^,. Ignoring any entropy change, the free energy change during transfer of metal complex anions can be described by equation 1 (Al-bazi and Chow 1984; Zhang 1984; Yu 2004): (AE h y - AEjoi) A . w + (— AE„,. W + ΔΕ 0- ο) A - W + (AE as . w - AE as _o) A - W ( 1 ) Three types of energy are thus involved during this process, which are solvation energy, cavitation energy and ion association energy. Solvation or Hydration energy is proportional to the charge density of ions, while cavitation energy is inversely proportional to charge density. Ion association energy can be expressed by the ion-pair formation constant, which follows Bjerrum's equation for purely Coulombic attraction(Morrison and Freiser 1957):

4 zN e 2

K= 1000 ar Q (b)

where N is Avogadro's number, e is the unit of charge, ε is the dielectric constant of the medium, k is the Boltzmann constant, T is the absolute temperature, Q ( οεκ ) j s a calculable function, and a is an empirical parameter which represents the distance between charge centres of the paired ions when in contact. If the temperature is constant, it is evident that ion association depends on the values of a and ε, decreasing with increasing a and ε values. However, if specific interactions between the paired ions occur, greatly increased stability would result. In most cases, it is expected that AE hy » ΔΕ Μΐ , ΔΕ*,. » , » ΔΕο-ο and AE as . w « ΔΕ^, therefore, ΔΕ ΜΑ can be simply described by equation 2: ΔΕΑ-W = (ΔΕι,γ) A -W - (AEw. w ) A -w - (AE as-0 ) A-w (2)

When anions in the organic phase transfer to the aqueous phase, the free energy change follows the equation 3:

ΔΕ Α . 0 = - (AEhy) A-O + (AEw -w ) A - 0 + (ΔΕ^) A -o (3)

Therefore, the total free energy change of anion exchange extraction follows the equation 4(Al-bazi and Chow 1984; Mooiriian 1993; Yu 2004): ΔΕ = AE A _w + ΔΕ Α -ο

= [(AE hy ) A-w - (AE hy ) A-o] + [(AEw. w ) A -o- (ΔΕ^) A -w] + [(ΔΕ^) A -o - (ΔΕ 35 ^,) A . w ] (4)

It is evident that when the charge density of metal complex anion in aqueous phase is small, where (AE hy ) A W is small and (AEw. w ) A . w is large, metal complex anions have a high probability of transferring to the organic phase. Vice versa, when the charge density of anion in organic phase is big, where (AE hy ) A . 0 is large and (ΔΕ^) A . 0 is small, the tendency for anions transfer to aqueous phase is enhanced. However, the contribution of the ion association energy depends on the volume of anions when specific interaction can be neglected. A smaller sized metal complex anion and larger sized anion in organic phase tend to improve anion exchange. In most cases, the contribution from hydration energy is generally higher than those from cavitation and solvation energies, when any specific interaction is neglected.

The phenomena observed in this study can be well explained by anion exchange extraction. As there are not enough data in the literature to obtain the actual value of charge density, the estimated value is calculated using charge of an ion divided by the number of atoms forming the ion. The charge density of anions of Cl ~ , PF 6 ~ and NTfT is thus calculated and the corresponding values are 1 , 0.143 and 0.067, respectively. Precious metals Pt and Pd, in HC1 solution present in the form of chloride complex as PtCl 6 - and PdCl 4 2" . The corresponding charge density is 0.286 and 0.4, respectively. Therefore, the extraction percentage decreased in the order of PtCl 6 " > PdCl 4 2~ for metal chloride complex and in the order of CI " > PF 6 ~ » NTf 2 ~ for anion in RTIL phase as shown in Figures 1 to 4. With same anion of TFSI, it was observed that distribution ratio increased when increasing the number of CH 2 unit in the cations. It is expected that dielectric constant of RTIL would decrease with increase of the number of GH 2 units in the cations, which enhanced ion association energy, resulting in higher distribution ratio. However, the RTIL of N8,8,8,l NTff did not follow the trend on anion influence. It might be attributed to the specific interactions between N8,8,8,l cation and metal complex anion, which increased significantly the extraction percentage. Without specific interaction, the centre atoms of cations of RTILs would not show much influence on ion association energy, which is purely Coulombic attraction, and so did on extraction percentage and distribution ratio. Based on the extraction mechanism described above, metal complex anions present in the same form in both phases and protons do not take part in transfer process. Therefore, solution acidity does not affect extraction percentage. It was observed, however, the extraction percentage of AuCl 4 ~ , PtCl 6 " and PdCL 2" decreased with increase of HC1 concentration as shown in Figures 1 to 4. It has been confirmed that the dielectric constant of aqueous phase decreases with increase of salt concentration, which enhanced ion association energy of metal complex anion with cations in aqueous phase, a lower extraction percentage was thus observed. The charge density of bare base metal ions, M n+ , is n, indicating that bare metal ions have high hydration energy and tend to stay in aqueous phase. In order to lower charge density, complexation needs occur to reduce charge and enlarge the volume of metal ions. Bare metal ions are highly hydrated in aqueous solution. In order to form complex, ligands need to replace water molecules . associated with metal ions. When the charge density is low enough for anion exchange, extraction occurs. Therefore, the process of extraction of base metal ions involves two steps: complexation and transfer. During complexation, it is expected that higher concentration of ligands present in the solution, more metal complex is formed, and thus higher extraction percentage is observed as shown in Figs. 5 to 7. In the stage of transfer of metal complex ions into organic phase, water molecules surrounding metal complex ions are replaced by organic molecules. This process can be viewed by the colour change during transfer, for examples, Cu + , Co 2+ and Fe 3+ showed blue, pink and brown colour in aqueous phase, respectively, all of which presented in the hydrated form of metal complex, but changed to red, blue and yellow in RTIL phase, respectively, which are believed in the anhydrous form of metal complex. In HCl solution, different metal ions, however, have different affinity to water molecules and chloride ions. According to the Hard Soft Acid Base (HSAB) principle, both water molecule and chloride ion are hard bases, but the former is harder than the latter. For group A metals, group I and II A metals belong to hard acid. When the order of group A metals move from LA to VA, the hardness decreases, vice versa, the softness increases. The well-accepted empirical rule is that 'hard likes hard and soft likes soft', indicating group I and II A metals have higher affinity to water molecules, so they are highly hydrated and tend to stay in water. Therefore, even phCl can only extract group I or II A metals to a very low extent. The aluminium ions, Al 3+ , in group IIIA belongs to hard acid because of high charge and small ion radii, so it showed the same trend as group I and II A metals. However, group rv and V A metals are less hard, which would show high affinity to chloride ions. Group IV and V A metal ions thus interact with chloride ions to form chloride complex, facilitating the anion exchange and high extraction percentage was observed as shown in Figure 8.

As for group B transition metals, Cr 3+ and Mn 2+ belong to hard acids, while Zn 2+ and Cu 2+ are borderline acids. The hardness follows the order of Cr 3* > Mn + > Zn 2+ = Cu 2+ , resulting in the order of extraction percentage as Cr 3 * < Mn + < Zn + = Cu + . However, HSAB principle cannot explain the extraction behaviour of group IIIV B metals. Fe 3+ is a hard acid, while Co 2+ and Ni 2+ are borderline acids. The order of hardness is Fe 3+ > Co 2+ > Ni 2+ , so is the extraction percentage. This phenomenon might be attributed to the different tendency of metal ions to form a chloride complex, which plays a vital role in the anion exchange extraction. From the UV spectra of metal ions presented in different HCl concentrations, it was found that FeCl 3 presented in chloride complex form even in neutral water, and CoCl 2 existed in hydrated form in neutral water and changed to chloride complex in high HCl concentrations, while NiCl 2 only presented in hydrated form in all HC1 concentrations. Therefore, Fe 3+ can be extracted efficiently in all HC1 concentrations, Co 2+ can be extracted well in high HC1 concentrations, but Ni 2+ cannot be extracted in all HC1 concentrations as seen in Figure 8.

For conventional organic solvent/water systems, when hydrophobic Si0 2 nanoparticles are present in aqueous solution, Si0 2 nanoparticles tend to transfer to organic solvent/water interface and form particle-stabilized emulsion during mixing. However, this phenomenon was not observed at RTIL/water systems in most cases, which might be attributed to the different interfacial tensions between these two systems. For the latter, Si0 2 nanoparticles cannot attach to the RTIL/water interface and, therefore, particle-stabilized emulsion cannot form. RTILs with longer hydrocarbon chain length tend to form micelle in aqueous phase, a prolonged phase separation time was observed. However, the formation of micelles can be prevented in high salt concentrations and rapid phase separation was achieved.

In summary, we have shown that extractions of metals including Pt, Pd, Mg, Ca, Al, Sn, Bi, Cu, Zn, Cr, Mn, Fe, Co and Ni using pure RTILs can be carried out in HO solutions. The extraction efficiency increased dramatically for group A metals moving from IIA to VA, while it decreased significantly for group B metals moving from IB to IIVB. The extraction percentage decreased in the order of Fe > Co » Ni for group IIFVB metals.

The influence of anion on extraction percentage showed in the order of CI > PF 6 » TFSI. The increase of hydrocarbon chain length can enhance the extraction. Cations did not show much influence on extraction except for ammonium cation. The extraction behaviour of metal ions using RTILs can be well described by anion exchange mechanism. RTILs can be used not only as solvent medium/but also novel effective liquid anion exchange extractants. Phase separation can be completed in a few minutes for RTILs with shorter chain length. RTILs containing long hydrocarbon chain showed slow phase separation, however, it can be improved effectively at high chloride concentrations. It was observed that Si0 2 nanoparticles did not show much influence on Cu extraction. For RTIL/Water system, no particle-stabilized emulsion was observed for copper extraction containing hydrophobic Si0 2 nanoparticles in the solution.

Example 2 - Extraction of metals from mixed metal ion solutions using RTILs

RTILs All RTILs used in this investigation (listed below) were purchased from IoLiTec, Germany, except for tetradecyl(trihexyl)phosphonium bis(trifluoromethanesulfonyl) imide, which was purchased from Strem Chemicals, USA. Five types of cations were studied: imidazolium (Im), piperidinium (Pip), pyrrolidinium (Pyr), ammonium (N) and phosphonium (P). In all cases the anion was bis(trifluoromethanesulfonyl) imide (NTf 2 ). The anions hexafluorophosphate (PF 6 ) and chloride (CI) were further chosen for hmim and phosphonium cations, respectively. Imidazolium and ammonium cations with different chain lengths were also used.

Ethyl-3-methylimidazolium bis(trifluoromethanesulfonyl)imide, 98 %, (emim.NTf 2 ) l-Hexyl-3-methylimidazolium bis(trifluoromethanesulfonyl)imide, 98 %, (hmim.NTf 2 ) l-Hexyl-3-methylimidazolium hexafluorophosphate, 99 %, ( hmim.PF 6 )

1 -Dodecyl-3-methylimidazoliumbis(trifluoromethylsulfonyl)imid e, 98 %, (dmim.NTf 2 )

1 -Methyl- 1-propylpiperidinium bis(trifluoromethylsulfonyl)imide, 99 %, (mppip.NTf 2 )

1 -Methyl- 1 -propylpyrrolidinium bis(trifluoromethylsulfonyl)imide, 99 %: mpPyr.NTf 2 Tetradecyl(trihexyl)phosphonium bis(trifluoromethanesulfonyl)imide, 97 %, (Pi4.6.6.6-NTf 2 )

Tetradecyl(trihexyl)phosphonium chloride, 96 %, ( Pi4.6.6.6-Cl)

Methyltrioctylammonium bis(trifluoromethylsulfonyl)imide, 99 %, (N 8 ,8.8.i-NTf 2 )

Butyltrimethylammonium bis(trifluoromethylsulfonyl)imide, 99 %, (N4.i. u .NTf 2 )

Metal salts Precious metal salts of AR grade, HAuCU-3H 2 0, PdCl 2 , and H 2 PtCl 6 xH 2 0. were purchased from Sigma-Aldrich.

Stock solutions ofAu, Pt and Pd mixtures

All metal salts were dissolved in MilliQ water of different HCl concentrations (typically 0.02, 0.1 and 2 M HCl, respectively). The concentration of Au, Pt and Pd in the mixture was measured using ICP. Conventional batch solvent extraction

0.5 ml RTDL and 2 ml aqueous solutions containing metal ions were added into a small glass vial. They were mixed vigorously with a magnetic stirrer for 30 min to achieve equilibrium distribution. When extraction was completed, the solution was left overnight to phase separate. After that, the aqueous phase was carefully removed and used for ICP measurement. Microfluidic solvent extraction

Glass microfluidic chips (IMT, Japan) containing two microchannels (100 μπι χ 40 μπι), that merge temporarily to form a liquid-liquid interface between the flowing aqueous and organic phases, were used for the microfluidic solvent extractions and details of these are shown in Figure 8. The merged (extraction) channel was 160μπι x 40μπι, with a "guide structure" in the middle (a 5μηι high ridge parallel to the direction of flow) to stabilize the two phase concurrent flow. The microfluidic experiments were carried out according to the protocol described in published international patent application 2010/022441 (details of which are incorporated herein by reference), with a variable flow rate to adjust the contact time in each extraction experiment.

Liquids were introduced into the microchip using precision syringe pumps (KD Scientific) with glass syringes (Hamilton, 1 mL and 2.5 mL) that were fitted with PEEK adaptors and tubing (Upchurch Scientific, 150μηι inner diameter). The microchip experiments were monitored optically (Olympus microscope, BH2-UMA, with a Moticam 2000 digital camera). Different flow rates (up to -10 ml/h) and two different liquid-liquid contact lengths, L (80 or 240 mm) were used to access a wide range of extraction times (Priest, Zhou et al. 201 1).

Extraction percentage, Distribution ratio and Separation factor

Extraction percentage is defined as the amount of solute in the ionic liquid phase (after extraction) divided by the amount in aqueous phase (before extraction). ICP techniques were used to determine the concentration of metal ions in the aqueous solutions before and after extraction. The extraction percentage was calculated as:

E % = [(Co - C*) / Co] * 100

Co: concentration before extraction, C*: concentration after extraction.

Distribution ratio (DR) is defined as the concentration of solute in the ionic liquid phase divided by its concentration in aqueous phase after extraction. It was calculated as: DR = [M] IU / [M] Aq .

[M] IL and [M] Aq : concentration in ionic liquid phase or aqueous phase after extraction.

Separation factor (SF) of A to B from A and B mixed solution is calculated as:

SF = DR A /DR B

DR A : distribution ratio of A, DR B : distribution ratio of B. Results - Conventional batch extraction

The selective extraction of Au versus Pt and Pd from HCl solutions using pure RTILs was carried out in conventional batch solvent extraction. The influence of different ionic liquids on the extraction of Au, Pt and Pd from Au, Pt and Pd mixtures dissolved in 0.02, 0.1 and 2 M HCl solutions is shown in Figures 9-11, respectively. The same extraction performance of Au, Pt and Pd from their mixtures using RTILs was observed when compared with that from single metal solutions. The extractability of precious metals decreases in the order of Au > Pt > Pd from HCl solutions. The influence of anions of RTILs on extraction efficiency is dominant. For all the metals, the extraction efficiency of RTILs decreases in the following order: CI " > PF 6 " > NTf 2 regardless of what cations the RTILs have. Longer hydrocarbon chains in the cation of the RTIL give rise to a higher extraction percentage. With chains shorter than six C¾ units, low extraction percentages were found. With an increase in HCl concentration, the extraction percentage decreases in most cases.

The distribution ratio describes how well a substance can be extracted, while the separation factor describes how well two substances can be separated from their mixture. The distribution ratios of Au, Pt and Pd in 2 M HCl concentration, as well as the separation factors of Au/Pt, Au/Pd and Pt/Pd are listed in Table 1. It can be seen that Au can be extracted very well by all RTILs selected with extraction percentages above 90 % in most cases. Except for Pi4.6.6.6-Cl, which can extract effectively all metals, hmim.PF 6 can extract Pt and Pd to a moderate extent. For all other RTILs selected, Pt and Pd cannot be extracted efficiently. Good selectivity for Au extraction can be found using RTILs including emim.NTf2, mppip.NTf2, mppyr.NTf2, N4,l,l,l .NTf2 and P14,6,6,6.NTf2. It was found that above 85 % of gold was extracted using the five RTILs mentioned above, while less than 5 % of Pt and Pd were extracted. To separate Pt from Pd, dmim.NTG, hmim.NTf2 and hmim.PF 6 are effective from 2 HCl solution. Continuous separation of Au, Pt and Pd from their mixture can be achieved by first choosing one of the RTILs such as emim.NTf2, mppip.NTf2, mppyr.NTf2, N4,l,l,l .NTf2 and P14,6,6,6.NTf2 to extract Au, then using hmim.PF 6 to extract Pt , whilst Pd will be left in the feed solution.

Table 1 - The distribution ratios and separation factors of Au, Pt and Pd in 2 M HC1

Results - Microfluidic extraction

The extraction of Au, Pt and Pd from their mixtures at 0.ΓΜ HC1 solution was carried out in a microchannel. ICP was used to measure the concentration of metals in the solution before and after extraction. The extraction percentage of Au, Pt and Pd as a function of residence time using hmimNTf 2 is shown in Figure 12. The extraction percentage of all metals increased with an increase in residence time. Au can be extracted above 85 %, while Pt and Pd can be extracted around 20 % and 5 % in several seconds. The extraction percentages of Au, Pt and Pd in the microchannel are compatible with those in bulk extraction, shown in Figure 9, which indicates that the extraction using RTILs proceeds very fast and reaches the maximum (indicated by a plateau) within seconds. In summary, the extraction of precious metals including Pt and Pd from their mixtures in HC1 solutions using pure RTILs was carried out in both bulk and microchannels. The influence of anion on extraction percentage showed in the order of CI > PF 6 » TFSI. The increase of hydrocarbon chain length can enhance the extraction. Highly selective extraction and continuous separation of Au, Pt and Pd can be achieved by choosing suitable RTILs and adjusting the HC1 concentration.

It will be appreciated by persons skilled in the art that numerous variations and/or modifications may be made to the invention as shown in the specific embodiments without departing from the spirit or scope of the invention as broadly described. The present embodiments are, therefore, to be considered in all respects as illustrative and not restrictive.

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Priest, C, J. Zhou, et al. (201 1). "Microfluidic extraction of copper from particle-laden solutions." Int. J. Miner. Process. 98(3-4): 168-173. Visser, A.E. and Rogers R.D. (2003). "Room temperature ionic liquids: new solvents for the /-element separations and associated solution chemistry." Journal of Solid State Chemistry: 109-113.

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Throughout this specification the word "comprise", or variations such as "comprises" or

"comprising", will be understood to imply the inclusion of a stated element, integer or step, or group of elements, integers or steps, but not the exclusion of any other element, integer or step, or group of elements, integers or steps.

All publications mentioned in this specification are herein incorporated by reference. Any discussion of documents, acts, materials, devices, articles or the like which has been included in the present specification is solely for the purpose of providing a context for the present invention. It is not to be taken as an admission that any or all of these matters form part of the prior art base or were common general knowledge in the field relevant to the present invention as it existed in Australia or elsewhere before the priority date of each claim of this application.




 
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