Insights on influence of polymer molecular weight on gas sorption, transport and plasticization in glassy 6FDA-DAM polyimide membranes

It is well-known that spinning of defect-free asymmetric polyimide hollow fibers is promoted by using high polymer molecular weight. On the other hand, effects of polymer molecular weight on microstructure and separation performance of dense film 6FDA-based polyimide membranes relevant to sheath lay...

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Bibliographic Details
Published in:Journal of membrane science 2024-12, Vol.712 (C), p.123242, Article 123242
Main Authors: Liu, Zhongyun, Cao, Yuhe, Qiu, Wulin, Kim, Jinyoung, Campbell, Zachary S., Schlosser, Steven, Koros, William J.
Format: Article
Language:English
Subjects:
Dual mode models
Gas sorption and transport
Molecular weight
Plasticization
Polyimide membrane
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Summary:It is well-known that spinning of defect-free asymmetric polyimide hollow fibers is promoted by using high polymer molecular weight. On the other hand, effects of polymer molecular weight on microstructure and separation performance of dense film 6FDA-based polyimide membranes relevant to sheath layers of composite membranes are less well-explored. In this work, gas sorption, diffusion and permeation of CO2, N2 and CH4 for 6FDA-DAM dense films are considered for 45 kDa and 176 kDa weight average molecular weights. Such molecular weights are relevant for practical hollow fiber spinning of membranes. Earlier results for polystyrene samples show similar trends in dual mode sorption model results like those noted here for the 6FDA-DAM polyimide case; however, effects on permeation like those considered here were not addressed for the polystyrene case. Here we also address actual pure and mixed gas CO2 and CH4 permeation and show higher free volumes, higher gas permeability but lower 50:50 CO2/CH4 selectivity associated with the higher molecular weight sample. Analysis using the self-consistent dual-mode sorption and transport models help understand the observed trends. Our results suggest denser packing of polymer segments exists in the Henry's law environment of the low molecular weight sample. Moreover, the higher polymer segmental packing in the Henry's law environment suppresses CO2 plasticization with a dual-mode microstructure controlling separation performance and plasticization behavior for this important member of the 6FDA polyimide family. We show evidence of effects of charge transfer complexes as possible main features in these trends. These dense film results help guide future work on dense sheath layers on composite hollow fiber membranes. [Display omitted] •Investigating polymer molecular weight effects on membrane structure and performance.•Densified Henry's law environment with more CTCs formation observed in lower Mw films.•Lower Mw films show decreased sorption and permeability with suppressed plasticization.•Dual-mode sorption and transport models used to provide insights into microstructures.
ISSN:0376-7388
DOI:10.1016/j.memsci.2024.123242