Three-phase hybrid facilitated transport hollow fiber membranes for enhanced CO2 separation

•Three-phase hybrid TFC hollow fiber facilitated transport membranes were fabricated.•The selective layer contains optimal ratio of polymer, nanofillers, and mobile carriers.•Size-optimized porous GO enhances CO2 transport at a very low loading.•Mobile carriers increase the resistance to carrier sat...

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Bibliographic Details
Published in:Applied materials today 2020-12, Vol.21, p.100801, Article 100801
Main Authors: Janakiram, Saravanan, Martín Espejo, Juan Luis, Høisæter, Karen Karolina, Lindbråthen, Arne, Ansaloni, Luca, Deng, Liyuan
Format: Article
Language:English
Subjects:
CO2 separation
Facilitated transport
Graphene oxide
Hollow fiber membrane
Mobile carriers
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Summary:•Three-phase hybrid TFC hollow fiber facilitated transport membranes were fabricated.•The selective layer contains optimal ratio of polymer, nanofillers, and mobile carriers.•Size-optimized porous GO enhances CO2 transport at a very low loading.•Mobile carriers increase the resistance to carrier saturation at elevated pressures.•The facile fabrication leads to easy up-scaling and potential for industrial applications. The configuration of thin film composite (TFC) in the form of hollow fiber is desired for gas separation membranes to achieve better gas permeation and higher packing density. In this work, we developed and tested TFC hollow fiber membranes with a defect-free, ultrathin (200 nm) hybrid facilitated transport selective layer consisting of three phases, i.e., a host polymeric matrix with fixed-site carriers, a 2D inorganic filler, and, a CO2-philic mobile carrier. The effect of lateral size of graphene oxide (GO)-based fillers on CO2 permeation were studied in detail, and the modified size-optimized porous GO (pGO) fillers were found to enhance CO2 permeation at a very low loading of 0.2 wt%. The optimized hybrid materials were then combined with selected mobile carriers, which interact with CO2 reversibly to form carbonate/carbene-CO2 adduct to further enhance the CO2 permeation performance. The resulting hybrid facilitated transport membranes with mobile carriers showcase a CO2 permeance of up to 825 GPU with a CO2/N2 separation factor of 31 and a CO2/CH4 of 20. These membranes also exhibit increased resistance to carrier saturation phenomena typical of facilitated transport membranes, showing potential for CO2 separation applications also at elevated pressures. [Display omitted]
ISSN:2352-9407
2352-9415
DOI:10.1016/j.apmt.2020.100801