Lithium Extraction by Emerging Metal–Organic Framework‐Based Membranes

Hou, Jue; Zhang, Huacheng; Thornton, Aaron W.; Hill, Anita J.; Wang, Huanting; Konstas, Kristina

doi:10.1002/adfm.202105991

Cited by 91 publications

(65 citation statements)

References 122 publications

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“…Recently, a lithium capacity of 7.5 mg·g –1 was observed on MIL-121 by replacing the protons of the carboxylic groups . In addition, MOF-based membranes with intrinsic properties have shown great potential in lithium extraction . By doping iron into the ion sieves, excellent lithium selectivity and enhanced lithium storage have been achieved recently …”

Section: Introductionmentioning

confidence: 99%

“…30 In addition, MOF-based membranes with intrinsic properties have shown great potential in lithium extraction. 31 By doping iron into the ion sieves, excellent lithium selectivity and enhanced lithium storage have been achieved recently. 32 Considering the limited research on using MOFs for selective lithium uptake and their structural potentials as adsorbents, here we designed a novel MOF termed as TJU-21, where the layers of benzene-1,3,5-tricarboxylate-coordinated Fe−O chains are pillared by fluorine.…”

Section: ■ Introductionmentioning

confidence: 99%

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Novel Fluorine-Pillared Metal–Organic Framework for Highly Effective Lithium Enrichment from Brine

Jiang

Bai

et al. 2021

ACS Appl. Mater. Interfaces

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The continuously developing lithium battery market makes seeking a reliable lithium supply a top priority for technology companies. Although metal–organic frameworks have been extensively researched as adsorbents owing to their exceptional properties, lithium adsorption has been scarcely investigated. Herein, we prepared a novel cuboid rod-shaped three-dimensional framework termed TJU-21 composed of fluorine-pillared coordination layers of Fe–O inorganic chains and benzene-1,3,5-tricarboxylate (BTC) linkages. Besides thermal and chemical robustness, a remarkably high lithium uptake of about 41 mg·g–1 was observed on TJU-21 as a fast-spontaneous endothermic process. Single-crystal X-ray diffraction demonstrated that the adsorbed lithium was located in the cavity symmetrically assembled by iron sites and organic ligands between adjacent layers, while another kind of cavity in the framework circled by Fe–O–Fe–O–Fe–O–Fe chains and shared BTC linkages was occupied by hydrogen-bonded water molecules. Lithium adsorption resulted in decreased curviness of the coordination layers, and the binding energy change at O 1s as well as the increased Fe 2p peak, suggested potential interaction with iron sites. The practicability of TJU-21 as a lithium adsorbent was further proved by the considerable capacity and selectivity in simulated salt brines with excellent reusability.

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Section: Introductionmentioning

confidence: 99%

Section: ■ Introductionmentioning

confidence: 99%

Novel Fluorine-Pillared Metal–Organic Framework for Highly Effective Lithium Enrichment from Brine

Jiang

Bai

et al. 2021

ACS Appl. Mater. Interfaces

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“…The development of Li + -selective materials is essential for efficient lithium extraction and recovery to satisfy the increasing demand for lithium batteries. So far, a series of MOF, 124,135,137,218 2D material, 167,[219][220][221] and polymer 131,222,223 membranes have achieved precise Li + selectivity over Na + , K + , and other cations. These single Li + -selective membranes can directly extract Li + ions from a mixture with monovalent, divalent, and multivalent ions compared to the mono-/divalent cation-selective membranes.…”

Section: Proton Selectivitymentioning

confidence: 99%

“…Monovalent metal ion-selective membranes 218,245,246 have been used for lithium-ion separation technologies. The integration of ion-selective membranes into electrodialysis devices is an effective way to achieve efficient ion separation.…”

Section: Ion Separationmentioning

confidence: 99%

Angstrom-scale ion channels towards single-ion selectivity

et al. 2022

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“…For lithium recovery from its aqueous resources, generally as LiCl or LiCO 3 salt [9], several methods were proposed, including solar evaporation [10], adsorption [11][12][13][14][15], complexation [16][17][18][19], precipitation [20,21], solvent extraction [22,23] and membrane process [24][25][26][27][28]. Among these proposed techniques and despite the time consumption and environmental effects of solar evaporation, this remains the most used method for actual lithium salt production [29].…”

Section: Introductionmentioning

confidence: 99%

Lithium-Sodium Separation by a Lithium Composite Membrane Used in Electrodialysis Process: Concept Validation

et al. 2022

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The recent expansion of global Lithium Ion Battery (LIBs) production has generated a significant stress on the lithium demand. One of the means to produce this element is its extraction from different aqueous sources (salars, geothermal water etc.). However, the presence of other mono- and divalent cations makes this extraction relatively complex. Herein, we propose lithium-sodium separation by an electrodialysis (ED) process using a Lithium Composite Membrane (LCM), whose effectiveness was previously demonstrated by a Diffusion Dialysis process (previous work). LCM performances in terms of lithium Recovery Ratio (RR(Li+)) and Selectivity (S(Li/Na)) were investigated using different Li+/Na+ reconstituted solutions and two ED cells: a two-compartment cell was chosen for its simplicity, and a four-compartment one was selected for its potential to isolate the redox reactions at the electrodes. We demonstrated that the four-compartment cell use was advantageous since it provided membrane protection from protons and gases generated by the electrodes but that membrane selectivity was negatively affected. The impact of the applied current density and the concentration ratio of Na+ and Li+ in the feed compartment ([Na+]F/[Li+]F) were tested using the four-compartment cell. We showed that increasing the current density led to an improvement of RR(Li+) but to a reduction in the LCM selectivity towards Li+. Increasing the [Na+]F/[Li+]F ratios to 10 had a positive effect on the membrane performance. However, for high values of this ratio, both RR(Li+) and S(Li/Na) decreased. The optimal results were obtained at [Na+]F/[Li+]F near 10, where we succeeded in extracting more than 10% of the initial Li+ concentration with a selectivity value around 112 after 4 h of ED experiment at 0.5 mA·cm−2. Thus, we can objectively estimate that the concept of this selective extraction of Li+ from a mixture even when concentrated in Na+ using an ED process was validated.

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Lithium Extraction by Emerging Metal–Organic Framework‐Based Membranes

Cited by 91 publications

References 122 publications

Novel Fluorine-Pillared Metal–Organic Framework for Highly Effective Lithium Enrichment from Brine

Novel Fluorine-Pillared Metal–Organic Framework for Highly Effective Lithium Enrichment from Brine

Angstrom-scale ion channels towards single-ion selectivity

Lithium-Sodium Separation by a Lithium Composite Membrane Used in Electrodialysis Process: Concept Validation

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