Role of ionic liquids in the efficient transfer of lithium by Cyanex 923 in solvent extraction system

Cui, Li; Jiang, Kun; Wang, Junfeng; Dong, Kun; Zhang, Xiangping; Cheng, Fangqin

doi:10.1002/aic.16606

Cited by 37 publications

(24 citation statements)

References 49 publications

(65 reference statements)

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“…The ESI‐MS spectra and slope methods yet were employed to determine the quantity relationship between the extracted ions and TBP. [ 36,39 ] To further analyze the composite of lithium and magnesium complexes with TBP which were formed in the extraction process, ESI‐MS spectrum of the loaded organic phase was characterized, and the results are shown in Figure 8. The peak at 289.1489 was [Na·TBP] + , which was the peak of the free TBP in the organic phase.…”

Section: Resultsmentioning

confidence: 99%

“…1‐(2‐Hydroxyethyl)‐3‐methylimidazolium bis(trifluoromethyl sulfonyl)imide ([HOEmim][NTf 2 ]), as co‐extractant, was reported in our previous work [ 36,37 ] that exhibited excellent performance in separating Li + from the alkali aqueous solution with high sodium to lithium ratio. In this work, [HOEmim][NTf 2 ] was chosen to separate Li + from the brine with high Mg/Li mass ratio with TBP, and a possible recycle route of IL‐based extraction system was put forward.…”

Section: Background and Originality Contentmentioning

confidence: 99%

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Efficient Extraction of Lithium Ions from High Mg/Li Ratio Brine through the Synergy of TBP and Hydroxyl Functional Ionic Liquids

et al. 2020

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of main observation and conclusion The extraction of Li + from the high Mg/Li ratio brine was performed using hydroxyl functional ionic liquids (ILs) as the coextractant and tributyl phosphate (TBP) as the extractant. Firstly, the extractive system, 1-(2-hydroxyethyl)-3-methylimidazolium bis(trifluoromethylsulfonyl)imide ([HOEmim][NTf2]) + TBP was proved to exhibit the highest extraction efficiency of Li + (88.15%) from LiCl aqueous solutions among the extractants composed of different ILs, TBP, and ILs + TBP. Effects of various extraction parameters on the extraction efficiencies of Li + and Mg 2+ were then investigated. 95.01% of Li + was extracted and the Li/Mg separation factor reached 405.76 in a single-stage at 278.15 K and O/A of 2 : 1. The extraction complexes were determined by the slope analysis method and ESI-MS analysis, and the metal complexes in the organic phase were indicated to be mainly [Li•2 TBP][NTf2]. The striping study showed that 92.86% of Li + was stripped with 1.0 mol•L-1 HCl. 98% extraction capacity of the synergy extractants was remained after 5 regeneration cycles. The thermodynamic parameters (ΔG°, ΔH°, and ΔS°), together with the mechanism of the Li + extraction were further demonstrated finally. According to the results, [HOEmim][NTf2] + TBP extraction system showed promising performance in extracting lithium from salt lake brine with high Mg/Li ratio.

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Section: Resultsmentioning

confidence: 99%

Section: Background and Originality Contentmentioning

confidence: 99%

Efficient Extraction of Lithium Ions from High Mg/Li Ratio Brine through the Synergy of TBP and Hydroxyl Functional Ionic Liquids

et al. 2020

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“…Liquid–liquid extraction is a widely used separation technology in many fields of chemical industry, for example, removal of aromatic sulfurs and nitrogens from fuel oil, 1‐9 separation of phenols or cresols from coal tar oil or water, 10‐15 recovery of organic acids and metal ions from aqueous solution, 16‐20 and so forth. Between two solvent phases (α and β), the distribution of solute (A) equilibrium concentrations ( C A ) is crucial for liquid–liquid equilibrium (LLE) systems 21,22 .…”

Section: Introductionmentioning

confidence: 99%

A simple model for precisely describing liquid–liquid equilibrium and better understanding extraction mechanism

et al. 2020

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Describing distribution of solute equilibrium concentrations between two solvents is important for liquid–liquid equilibrium (LLE). Due to non‐ideality of solutions, the distribution usually possesses non‐linear characteristic. In this work, the non‐ideality was simply represented by pseudo reaction (or chemical interaction) between the solute and the solvent without recourse to the complicated activity coefficient models. On this basis, a simple model, which combined physical partition and pseudo reaction equilibriums, was proposed and can precisely correlate various LLE systems, for example, the immiscible, the partially miscible, the organic, and even the electrolyte. More interestingly, the model can accurately reflect intrinsic mechanism by fitted parameters, that is, stoichiometric ratio of the pseudo reaction and total equilibrium constant for the interaction intensity. Besides, influence of the solute, the extractant, and temperature on the parameters was discussed deeply. This simple model is promising for precisely describing the LLE systems and better understanding their intrinsic extraction mechanism.

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“…7 Li NMR spectrum is a useful probe to study the speciation of Li in solvent extraction 40 . 7 Li NMR spectra were recorded for the organic phase loaded with Li (Figure 9a).…”

Section: Resultsmentioning

confidence: 99%

Selective removal of magnesium from lithium‐rich brine for lithium purification by synergic solvent extraction using β‐diketones and Cyanex 923

Binnemans

2020

AIChE Journal

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In the production of battery‐grade and high‐purity Li2CO3, it is essential to remove magnesium impurities. The state‐of‐the‐art solvent extraction (SX) process using Versatic Acid 10 and D2EHPA co‐extracts 3.3–5.5% lithium, while removing 86–98% magnesium. Here, we demonstrate that synergic SX systems containing a β‐diketone (HPMBP, HTTA or HDBM) and Cyanex 923 are highly selective for magnesium extraction over lithium (separation factor α > 1,000). The extracted magnesium and lithium complexes have the stoichiometry of [Mg∙A2∙(C923)2] and [Li∙A x∙(C923)2] (x = 1, 2), respectively (A represents deprotonated β‐diketone). The three β‐diketone synergic SX systems all considerably outperformed the Versatic Acid 10 system for magnesium removal from a synthetic solution containing 24 g L−1 Li and 0.24 g L−1 Mg. In a three‐stage batch counter‐current extraction, the HPMBP and Cyanex 923 synergic SX system removed 100% magnesium with only 0.6% co‐extraction of lithium. This excellent Mg/Li separation is the best result reported so far.

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Role of ionic liquids in the efficient transfer of lithium by Cyanex 923 in solvent extraction system

Cited by 37 publications

References 49 publications

Efficient Extraction of Lithium Ions from High Mg/Li Ratio Brine through the Synergy of TBP and Hydroxyl Functional Ionic Liquids

Efficient Extraction of Lithium Ions from High Mg/Li Ratio Brine through the Synergy of TBP and Hydroxyl Functional Ionic Liquids

A simple model for precisely describing liquid–liquid equilibrium and better understanding extraction mechanism

Selective removal of magnesium from lithium‐rich brine for lithium purification by synergic solvent extraction using β‐diketones and Cyanex 923

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