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Extrinsically microporous polymer membranes derived from thermally cross-linked perfluorinated aryl-ether-free polymers for gas separation

Ju Ho Shin, Hyun Jung Yu, Jiyoon Jung, Heseong An, Jung Hoon Park, Albert S. Lee, Jong Suk Lee

2025Nature Communications10 citationsDOIOpen Access PDF

Abstract

Abstract State-of-the-art membranes derived from polymers of intrinsic microporosity offer promising alternatives to energy-intensive, thermally driven separation techniques but often suffer from reduced performance under condensable gases or physical aging. Here, extrinsically microporous polymer membranes (EMPMs) are introduced as a distinct class of microporous membranes, fabricated from perfluorinated aryl-ether-free aromatic polymers via defluorination-induced thermal cross-linking. This process generates extrinsic micropores, increases intersegmental distances, and significantly enhances gas permeability. EMPMs exhibit a Brunauer-Emmett-Teller surface area of 552 m 2 g −1 and demonstrate exceptional plasticization resistance under equimolar CO 2 /CH 4 mixed gas at pressures up to 40 bar. CO 2 permeability increases from 280 to 12,000 Barrer at 1 bar and 35 °C, while CO 2 /N 2 selectivity reaches 46 at −20 °C, surpassing the 2019 polymeric upper bound. Furthermore, extrinsically microporous hollow fiber membranes prepared via dip-coating achieve a CO 2 permeance of 2174 gas permeation units and CO 2 /N 2 selectivity of 30 at −20 °C, highlighting their industrial relevance. This study establishes a scalable method for fabricating high-performance microporous polymeric membranes with exceptional stability for sustainable energy and environmental applications.

Topics & Concepts

Microporous materialMembraneBarrerPermeationGas separationMaterials scienceChemical engineeringPolymerPermeancePolymer chemistryEtherSelectivityOrganic chemistryChemistryComposite materialCatalysisBiochemistryEngineeringMembrane Separation and Gas TransportCovalent Organic Framework ApplicationsSynthesis and properties of polymers