High ionic liquid content polymeric gel membranes: Correlation of membrane structure with gas and vapour transport properties

High ionic liquid content polymeric gel membranes: Correlation of membrane structure with gas and vapour transport properties

In this paper the transport properties of ionic liquid polymeric gel membranes, containing up to 80wt.% of the ionic liquid 1-ethyl-3-methylimidazolium bis(trifluoromethylsulfonyl)imide ([EMIM][TFSI]) in poly(vinylidene fluoride-co-hexafluoropropylene) (p(VDF-HFP)), are investigated. Gas permeabilit...

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Veröffentlicht in:Journal of membrane science 2012-10, Vol.415-416, p.801-809
Hauptverfasser: Friess, Karel, Jansen, Johannes Carolus, Bazzarelli, Fabio, Izák, Pavel, Jarmarová, Veronika, Kačírková, Marie, Schauer, Jan, Clarizia, Gabriele, Bernardo, Paola
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alcohols
artificial membranes
carbon dioxide
Chemistry
Colloidal state and disperse state
cyclohexanes
Diffusion
Exact sciences and technology
gels
General and physical chemistry
Ionic liquid membrane
ionic liquids
mass transfer
Membranes
modulus of elasticity
molecular weight
natural gas
Permeability
polar compounds
Polymer gel
solubility
Sorption
Surface physical chemistry
temperature
toluene
vapors
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container_end_page 809
container_issue
container_start_page 801
container_title Journal of membrane science
container_volume 415-416
creator Friess, Karel
Jansen, Johannes Carolus
Bazzarelli, Fabio
Izák, Pavel
Jarmarová, Veronika
Kačírková, Marie
Schauer, Jan
Clarizia, Gabriele
Bernardo, Paola
description In this paper the transport properties of ionic liquid polymeric gel membranes, containing up to 80wt.% of the ionic liquid 1-ethyl-3-methylimidazolium bis(trifluoromethylsulfonyl)imide ([EMIM][TFSI]) in poly(vinylidene fluoride-co-hexafluoropropylene) (p(VDF-HFP)), are investigated. Gas permeability significantly increases in the presence of [EMIM][TFSI], especially for CO2. This suggests a potential application in gas separation membranes, for instance for natural gas sweetening and for CO2 sequestration from flue gas. A correlation of the transport properties with Young's modulus is proposed for the first time. It reveals a transition from diffusion-controlled transport to solubility-controlled transport with increasing IL content in the membrane. Vapour permeation experiments with the most permeable membrane containing 80wt.% of ionic liquid were carried out. Permeability, diffusion and solubility coefficients were correlated with molecular kinetic diameter or critical temperature and volume, respectively. These correlations show clear and distinct trends for water, alcohols, linear and cyclic hydrocarbons. Polar compounds (linear C1–C4 alcohols, water) are more permeable and more sorbing than the corresponding hydrocarbons. The two classes show the opposite trends in permeability as a function of the critical volume, with an increase for the alkanes and a decrease for the alcohols. The same trends are observed for the solubility as a function of the critical temperature, evidencing that at such high IL concentrations in the membrane the mass transport is solubility controlled. On the other hand, diffusion is mainly correlated with the critical volume and the molecular size, regardless the chemical nature of the permeants. Significant differences in the transport of toluene and cyclohexane suggest that these membranes are also suitable for the separation of alkanes and aromatics. The manuscript intends to give fundamental information on how the presence of IL influences the transport properties of polymeric membranes. [Display omitted] ► Polymeric gel membranes based on the ionic liquid [EMIM][TFSI] and p(VDF-HFP). ► Young's modulus versus permeability distinguishes D and S controlled transport. ► The ionic liquid strongly enhances the membrane permeability. ► The ionic liquid gives high selectivity of vapours versus permanent gases. ► Correlation with molecular properties enhances understanding of transport phenomena.
doi_str_mv 10.1016/j.memsci.2012.05.072
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Gas permeability significantly increases in the presence of [EMIM][TFSI], especially for CO2. This suggests a potential application in gas separation membranes, for instance for natural gas sweetening and for CO2 sequestration from flue gas. A correlation of the transport properties with Young's modulus is proposed for the first time. It reveals a transition from diffusion-controlled transport to solubility-controlled transport with increasing IL content in the membrane. Vapour permeation experiments with the most permeable membrane containing 80wt.% of ionic liquid were carried out. Permeability, diffusion and solubility coefficients were correlated with molecular kinetic diameter or critical temperature and volume, respectively. These correlations show clear and distinct trends for water, alcohols, linear and cyclic hydrocarbons. Polar compounds (linear C1–C4 alcohols, water) are more permeable and more sorbing than the corresponding hydrocarbons. The two classes show the opposite trends in permeability as a function of the critical volume, with an increase for the alkanes and a decrease for the alcohols. The same trends are observed for the solubility as a function of the critical temperature, evidencing that at such high IL concentrations in the membrane the mass transport is solubility controlled. On the other hand, diffusion is mainly correlated with the critical volume and the molecular size, regardless the chemical nature of the permeants. Significant differences in the transport of toluene and cyclohexane suggest that these membranes are also suitable for the separation of alkanes and aromatics. The manuscript intends to give fundamental information on how the presence of IL influences the transport properties of polymeric membranes. [Display omitted] ► Polymeric gel membranes based on the ionic liquid [EMIM][TFSI] and p(VDF-HFP). ► Young's modulus versus permeability distinguishes D and S controlled transport. ► The ionic liquid strongly enhances the membrane permeability. ► The ionic liquid gives high selectivity of vapours versus permanent gases. ► Correlation with molecular properties enhances understanding of transport phenomena.</abstract><cop>Amsterdam</cop><pub>Elsevier B.V</pub><doi>10.1016/j.memsci.2012.05.072</doi><tpages>9</tpages></addata></record>
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source Elsevier ScienceDirect Journals
subjects alcohols
artificial membranes
carbon dioxide
Chemistry
Colloidal state and disperse state
cyclohexanes
Diffusion
Exact sciences and technology
gels
General and physical chemistry
Ionic liquid membrane
ionic liquids
mass transfer
Membranes
modulus of elasticity
molecular weight
natural gas
Permeability
polar compounds
Polymer gel
solubility
Sorption
Surface physical chemistry
temperature
toluene
vapors
title High ionic liquid content polymeric gel membranes: Correlation of membrane structure with gas and vapour transport properties
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