Polymer of Intrinsic Microporosity (PIM-1) Membranes Treated with Supercritical CO2

Polymers of intrinsic microporosity (PIMs) are a promising membrane material for gas separation, because of their high free volume and micro-cavity size distribution. This is countered by PIMs-based membranes being highly susceptible to physical aging, which dramatically reduces their permselectivity over extended periods of time. Supercritical carbon dioxide is known to plasticize and partially solubilise polymers, altering the underlying membrane morphology, and hence impacting the gas separation properties. This investigation reports on the change in PIM-1 membranes after being exposed to supercritical CO2 for two- and eight-hour intervals, followed by two depressurization protocols, a rapid depressurization and a slow depressurization. The exposure times enables the impact contact time with supercritical CO2 has on the membrane morphology to be investigated, as well as the subsequent depressurization event. The density of the post supercritical CO2 exposed membranes, irrespective of exposure time and depressurization, were greater than the untreated membrane. This indicated that supercritical CO2 had solubilised the polymer chain, enabling PIM-1 to rearrange and contract the free volume micro-cavities present. As a consequence, the permeabilities of He, CH4, O2 and CO2 were all reduced for the supercritical CO2-treated membranes compared to the original membrane, while N2 permeability remained unchanged. Importantly, the physical aging properties of the supercritical CO2-treated membranes altered, with only minor reductions in N2, CH4 and O2 permeabilities observed over extended periods of time. In contrast, He and CO2 permeabilities experienced similar physical aging in the supercritical treated membranes to that of the original membrane. This was interpreted as the supercritical CO2 treatment enabling micro-cavity contraction to favour the smaller CO2 molecule, due to size exclusion of the larger N2, CH4 and O2 molecules. Therefore, physical aging of the treated membranes only had minor impact on N2, CH4 and O2 permeability; while the smaller He and CO2 gases experience greater permeability loss. This result implies that supercritical CO2 exposure has potential to limit physical aging performance loss in PIM-1 based membranes for O2/N2 separation.

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Pentiptycene-based ladder polymers with configurational free volume for enhanced gas separation performance and physical aging resistance

Proceedings of the National Academy of Sciences ◽

10.1073/pnas.2022204118 ◽

2021 ◽

Vol 118 (37) ◽

pp. e2022204118

Author(s):

Tanner J. Corrado ◽

Zihan Huang ◽

Dezhao Huang ◽

Noah Wamble ◽

Tengfei Luo ◽

...

Keyword(s):

Free Volume ◽

Gas Separation ◽

Physical Aging ◽

Gas Permeation ◽

Separation Performance ◽

Structure Property ◽

Mixed Gas ◽

Initial Separation ◽

Primary Advantage ◽

Polymers Of Intrinsic Microporosity

Polymers of intrinsic microporosity (PIMs) have shown promise in pushing the limits of gas separation membranes, recently redefining upper bounds for a variety of gas pair separations. However, many of these membranes still suffer from reductions in permeability over time, removing the primary advantage of this class of polymer. In this work, a series of pentiptycene-based PIMs incorporated into copolymers with PIM-1 are examined to identify fundamental structure–property relationships between the configuration of the pentiptycene backbone and its accompanying linear or branched substituent group. The incorporation of pentiptycene provides a route to instill a more permanent, configuration-based free volume, resistant to physical aging via traditional collapse of conformation-based free volume. PPIM-ip-C and PPIM-np-S, copolymers with C- and S-shape backbones and branched isopropoxy and linear n-propoxy substituent groups, respectively, each exhibited initial separation performance enhancements relative to PIM-1. Additionally, aging-enhanced gas permeabilities were observed, a stark departure from the typical permeability losses pure PIM-1 experiences with aging. Mixed-gas separation data showed enhanced CO2/CH4 selectivity relative to the pure-gas permeation results, with only ∼20% decreases in selectivity when moving from a CO2 partial pressure of ∼2.4 to ∼7.1 atm (atmospheric pressure) when utilizing a mixed-gas CO2/CH4 feed stream. These results highlight the potential of pentiptycene’s intrinsic, configurational free volume for simultaneously delivering size-sieving above the 2008 upper bound, along with exceptional resistance to physical aging that often plagues high free volume PIMs.

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Thermal Cross Linking of Novel Azide Modified Polymers of Intrinsic Microporosity—Effect of Distribution and the Gas Separation Performance

Polymers ◽

10.3390/polym11081241 ◽

2019 ◽

Vol 11 (8) ◽

pp. 1241 ◽

Cited By ~ 1

Author(s):

Silvio Neumann ◽

Gisela Bengtson ◽

David Meis ◽

Volkan Filiz

Keyword(s):

Gas Separation ◽

Physical Aging ◽

Gas Permeability ◽

Time Lag ◽

Polymer Chains ◽

Separation Performance ◽

Polymer Backbone ◽

Cross Linkage ◽

Polymers Of Intrinsic Microporosity ◽

Intrinsic Microporosity

The synthesis of polymers of intrinsic microporosity (PIM) modified with azide groups, the cross linkage by nitrene reaction and their performance as gas separation membranes are reported. The azide modification of the spirobisindane units in the polymer backbone was done by post functionalization of methylated spirobisindane containing polymers. These polymers differ in distribution and concentration of the azide group containing spirobisindane units by applying perfectly alternating and randomly distributed copolymers along the polymer chains. To investigate the influence of concentration of the azide groups, additionally the homopolymer of methylated spirobisindane was synthesized and subjected to identical treatments and characterizations as both copolymers. Cross linkage by nitrene reaction was examined by different temperature treatments at 150, 200, 250 and 300 °C. Characterization of the new polymers was performed by NMR, SEC and FT-IR. Furthermore, the crosslinking process was investigated by means of solid state NMR, TGA-FTIR, DSC and isoconversional kinetic analysis performed with TGA. Gas permeability of CO2, N2, CH4, H2 and O2 was determined by time lag experiments and ideal selectivities for several gas pairs were calculated. The two azide groups per repeating unit degrade during thermal treatments by release of nitrogen and form mechanically stable PIM networks, leading to an increase in gas permeability while selectivity remained nearly constant. Measured diffusivity and solubility coefficients revealed differences in the formation of free volume elements depending on distribution and concentration of the azide groups. Aging studies over about five months were performed and physical aging rates (βP) were evaluated with regard to the concentration and distribution of curable azide functionalities. Subsequently, the enhanced sieving effect during aging resulted in membrane materials that surpassed the Robeson upper bound in selected gas pairs.

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Physical aging of polymers of intrinsic microporosity: a SAXS/WAXS study

Journal of Materials Chemistry A ◽

10.1039/c4ta02165g ◽

2014 ◽

Vol 2 (30) ◽

pp. 11742-11752 ◽

Cited By ~ 51

Author(s):

Amanda G. McDermott ◽

Peter M. Budd ◽

Neil B. McKeown ◽

Coray M. Colina ◽

James Runt

Keyword(s):

Film Thickness ◽

Free Volume ◽

Physical Aging ◽

Gas Separations ◽

X Ray ◽

Membrane Performance ◽

X Ray Scattering ◽

Polymeric Glasses ◽

Polymers Of Intrinsic Microporosity ◽

Intrinsic Microporosity

X-ray scattering patterns from these high free-volume polymeric glasses contain a feature strongly associated with porosity; it is sensitive to time, temperature and film thickness in a manner consistent with physical aging, which impacts membrane performance in gas separations.

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Boosting gas separation performance and suppressing the physical aging of polymers of intrinsic microporosity (PIM-1) by nanomaterial blending

Nanoscale ◽

10.1039/d0nr07042d ◽

2020 ◽

Vol 12 (46) ◽

pp. 23333-23370 ◽

Cited By ~ 2

Author(s):

Mohd Zamidi Ahmad ◽

Roberto Castro-Muñoz ◽

Peter M. Budd

Keyword(s):

Gas Separation ◽

Physical Aging ◽

Ideal Gas ◽

Mixed Matrix Membranes ◽

Separation Performance ◽

Hybrid Fillers ◽

Polymers Of Intrinsic Microporosity ◽

Intrinsic Microporosity ◽

Gas Separation Performance ◽

The Ideal

The development of PIM-1 mixed matrix membranes using organic, inorganic and hybrid fillers towards the ideal gas separation enhancement.

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Investigation of the Side Chain Effect on Gas and Water Vapor Transport Properties of Anthracene-Maleimide Based Polymers of Intrinsic Microporosity

Polymers ◽

10.3390/polym14010119 ◽

2021 ◽

Vol 14 (1) ◽

pp. 119

Author(s):

Esra Caliskan ◽

Sergey Shishatskiy ◽

Silvio Neumann ◽

Volker Abetz ◽

Volkan Filiz

Keyword(s):

Water Vapor ◽

Transport Properties ◽

Free Volume ◽

Diels Alder ◽

Vapor Transport ◽

Size Exclusion ◽

Water Vapor Transport ◽

Strong Impact ◽

Polymers Of Intrinsic Microporosity ◽

Intrinsic Microporosity

In the present work, a set of anthracene maleimide monomers with different aliphatic side groups obtained by Diels Alder reactions were used as precursors for a series of polymers of intrinsic microporosity (PIM) based homo- and copolymers that were successfully synthesized and characterized. Polymers with different sizes and shapes of aliphatic side groups were characterized by size-exclusion chromatography (SEC), (nuclear magnetic resonance) 1H-NMR, thermogravimetric (TG) analysis coupled with Fourier-Transform-Infrared (FTIR) spectroscopy (TG-FTIR) and density measurements. The TG-FTIR measurement of the monomer-containing methyl side group revealed that the maleimide group decomposes prior to the anthracene backbone. Thermal treatment of homopolymer methyl-100 thick film was conducted to establish retro-Diels Alder rearrangement of the homopolymer. Gas and water vapor transport properties of homopolymers and copolymers were investigated by time-lag measurements. Homopolymers with bulky side groups (i-propyl-100 and t-butyl-100) experienced a strong impact of these side groups in fractional free volume (FFV) and penetrant permeability, compared to the homopolymers with linear alkyl side chains. The effect of anthracene maleimide derivatives with a variety of aliphatic side groups on water vapor transport is discussed. The maleimide moiety increased the water affinity of the homopolymers. Phenyl-100 exhibited a high water solubility, which is related to a higher amount of aromatic rings in the polymer. Copolymers (methyl-50 and t-butyl-50) showed higher CO2 and CH4 permeability compared to PIM-1. In summary, the introduction of bulky substituents increased free volume and permeability whilst the maleimide moiety enhanced the water vapor affinity of the polymers.

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