Transport and Co-Transport of Carboxylate Ions and Ethanol in Anion Exchange Membranes

Kim, Jung Min; Lin, Yi-hung; Hunter, Brock; Beckingham, Bryan S.

doi:10.3390/polym13172885

Cited by 11 publications

(17 citation statements)

References 69 publications

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“…While diffusion of H 2(aq) is slower across thicker membranes, ion flux will also be proportionally depressed. The free volume model works reasonably well for neutral solutes with relatively high molecule weights and high swelling degree IEMs, suggesting that the permeants indeed transport through the solvated fraction of the membranes (Yasuda et al, 1969;Kato et al, 1992;Dischinger et al, 2020;Kim and Beckingham, 2021;Kim et al, 2021a;Kim et al, 2022a). However, for smaller solutes, such as H 2(aq) , and low swelling degree membranes, the permeant can plausibly be transported through the unsolvated free volumes within the polymer chains, akin to gas permeation across dense films (Baker, 2012).…”

Section: Ion/uncharged Solute Selectivitymentioning

confidence: 99%

Advancing ion-exchange membranes to ion-selective membranes: principles, status, and opportunities

Fan

Huang

Yip

2022

Front. Environ. Sci. Eng.

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Ion-exchange membranes (IEMs) are utilized in numerous established, emergent, and emerging applications for water, energy, and the environment. This article reviews the five different types of IEM selectivity, namely charge, valence, specific ion, ion/solvent, and ion/uncharged solute selectivities. Technological pathways to advance the selectivities through the sorption and migration mechanisms of transport in IEM are critically analyzed. Because of the underlying principles governing transport, efforts to enhance selectivity by tuning the membrane structural and chemical properties are almost always accompanied by a concomitant decline in permeability of the desired ion. Suppressing the undesired crossover of solvent and neutral species is crucial to realize the practical implementation of several technologies, including bioelectrochemical systems, hypersaline electrodialysis desalination, fuel cells, and redox flow batteries, but the ion/solvent and ion/uncharged solute selectivities are relatively understudied, compared to the ion/ion selectivities. Deepening fundamental understanding of the transport phenomena, specifically the factors underpinning structure-property-performance relationships, will be vital to guide the informed development of more selective IEMs. Innovations in material and membrane design offer opportunities to utilize ion discrimination mechanisms that are radically different from conventional IEMs and potentially depart from the putative permeability-selectivity tradeoff. Advancements in IEM selectivity can contribute to meeting the aqueous separation needs of water, energy, and environmental challenges.

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Section: Ion/uncharged Solute Selectivitymentioning

confidence: 99%

Advancing ion-exchange membranes to ion-selective membranes: principles, status, and opportunities

Fan

Huang

Yip

2022

Front. Environ. Sci. Eng.

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“…As a conjecture, mobile formate anions (OFm – ) may be more favorable in QA + -containing films (counterion condensation , ). In mixed solute sorption, OFm – mobility can be reduced in these films as MeOH softens the fixed charge interface and interferes with the counterion condensation. , …”

Section: Resultsmentioning

confidence: 99%

Improved Structural Stability of Charged Hydrogels under Organic CO₂ Reduction Products: Effect of Acrylate and Methacrylate Backbone Linkages

et al. 2023

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Understanding the mixed solute transport behavior of CO 2 reduction products (methanol and formate) in ion exchange membranes (IEMs) is of interest for CO 2 reduction cells (CO 2 RCs). The role of an IEM in a typical CO 2 RC is to suppress the crossover of all CO 2 reduction products while allowing the transport of electrolytes. Tuning the polymer rigidity of the membrane is a key contributor to such highly controlled transport of organic solutes in a dense hydrated membrane. Here, we investigate the mixed solute transport behavior of methanol and formate in a series of tough phenyl acrylate-based cross-linked IEMs. We then investigate the effects of a structural modification on mixed solute transport behavior by introducing quaternary carbons within the membrane. We measured the relative permittivity properties of swollen films to determine if the water hydrogen bonding environment within the IEMs, which is related to maintaining selective ion transport within the membrane (electrolytes over CO 2 reduction products), was impacted by various organic solutes. We observed films with methacrylate backbone linkages have effectively constant relative permittivities when exposed to solutions containing methanol, formate, and a mix thereof. These findings may assist in designing membranes for applications, including CO 2 reduction cells and water−organic separation.

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“…These relative permeabilities are attributed to the differences in solute size, kinetic diameter for the alcohols, and hydrated diameter for the carboxylate salts. The kinetic diameter of EtOH (4.5 Å [ 33 ]) is higher than the kinetic diameter of MeOH (3.6 Å [ 34 ]), and the hydrated diameter of OFm − (5.9 Å [ 35 ]) is smaller than the hydrated diameter of OAc − (7.44 Å [ 32 , 36 ]). The smaller solutes permeate faster than the larger solutes (diffusivity varies inversely proportional to the solute size).…”

Section: Resultsmentioning

confidence: 99%

“…However, at higher pre−polymerization water content, and thereby higher water volume fraction, EtOH permeability decreases in co-permeation with NaOAc. Recently, in a study by Kim et al (2021) , it was observed that EtOH permeability remained essentially the same in PEGDA-based films in single and co-transport with carboxylate ions, which was attributed to the larger observed differences in sorption behavior of EtOH for these mixtures (ethanol’s solubility was 0.298 whereas the solubility was 0.386 while co-transporting with NaOFm) [ 34 ]. Thus, in our current study, the consistency in permeability values for EtOH between single and co-permeation in PEGDA-PEGMA films with NaOFm is likely also a result of analogous sorption differences that might compensate for the difference in the diffusive behavior between two molecules.…”

Section: Resultsmentioning

confidence: 99%

“…As with MeOH and EtOH, the observed differences are smaller in absolute terms at lower water volume fraction, with the largest differences observed at the highest water volume fraction. While the underlying reason for this difference is unclear, two contributing factors are likely to be differences in sorption behavior as well as the differences in hydrated radius (NaOAc has a larger hydrated radius than NaOFm) [ 34 ].…”

Section: Resultsmentioning

confidence: 99%

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Controlling Fractional Free Volume, Transport, and Co-Transport of Alcohols and Carboxylate Salts in PEGDA Membranes

et al. 2022

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Understanding multi-component transport through polymer membranes is critical for separation applications such as water purification, energy devices, etc. Specifically for CO2 reduction cells, where the CO2 reduction products (alcohols and carboxylate salts), crossover of these species is undesirable and improving the design of ion exchange membranes to prevent this behavior is needed. Previously, it was observed that acetate transport increased in copermeation with alcohols for cation exchange membranes consisting of poly(ethylene glycol) diacrylate (PEGDA) and 2-acrylamido-2-methyl-1-propanesulfonic acid (AMPS) and that the inclusion of poly(ethylene glycol) methacrylate (PEGMA) (n = 5, n represents the number of ethylene oxide repeat units) could suppress this behavior. Here, we further investigate the role of PEGMA in modulating fractional free volume and transport behavior of alcohols and carboxylates. PEGDA-PEGMA membranes of varied membranes are fabricated with both varied pre −polymerization water content at constant PEGMA (n = 9) content and varied PEGMA content at two pre −polymerization water contents (20 and 60 wt.% water). Permeability to sodium acetate also decreases in these charge-neutral PEGDA-PEGMA membranes compared to PEGMA-free films. Therefore, incorporation of comonomers such as PEGMA with long side chains may provide a useful membrane chemistry structural motif for preventing undesirable carboxylate crossover in polymer membranes.

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Transport and Co-Transport of Carboxylate Ions and Ethanol in Anion Exchange Membranes

Cited by 11 publications

References 69 publications

Advancing ion-exchange membranes to ion-selective membranes: principles, status, and opportunities

Advancing ion-exchange membranes to ion-selective membranes: principles, status, and opportunities

Improved Structural Stability of Charged Hydrogels under Organic CO₂ Reduction Products: Effect of Acrylate and Methacrylate Backbone Linkages

Controlling Fractional Free Volume, Transport, and Co-Transport of Alcohols and Carboxylate Salts in PEGDA Membranes

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Transport and Co-Transport of Carboxylate Ions and Ethanol in Anion Exchange Membranes

Cited by 11 publications

References 69 publications

Advancing ion-exchange membranes to ion-selective membranes: principles, status, and opportunities

Advancing ion-exchange membranes to ion-selective membranes: principles, status, and opportunities

Improved Structural Stability of Charged Hydrogels under Organic CO2 Reduction Products: Effect of Acrylate and Methacrylate Backbone Linkages

Controlling Fractional Free Volume, Transport, and Co-Transport of Alcohols and Carboxylate Salts in PEGDA Membranes

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Improved Structural Stability of Charged Hydrogels under Organic CO₂ Reduction Products: Effect of Acrylate and Methacrylate Backbone Linkages