Ionic nanoporous membranes from self-assembled liquid crystalline brush-like imidazolium triblock copolymers

There is a need to generate mechanically and thermally robust ionic nanoporous membranes for separation and fuel cell applications. Herein, we report a general approach to the preparation of ionic nanoporous membranes through custom synthesis, self-assembly, and subsequent chemical manipulations of...

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Bibliographic Details
Published in:Soft matter 2024-08, Vol.2 (34), p.6834-6847
Main Authors: Abeysekera, Iyomali, Bosire, Reuben, Masese, Francis K, Ndaya, Dennis, Kasi, Rajeswari M
Format: Article
Language:English
Subjects:
Actuators
Anions
Biosensors
Block copolymers
Cations
Chemical synthesis
Copolymers
Crosslinking
Dimensional stability
Electrochemistry
Etching
Fuel cells
Hydrophobicity
Ion currents
Ion exchange
Ion transport
Liquid crystals
Mechanical properties
Membranes
Nanochannels
Polylactic acid
Polynorbornene
Self-assembly
Swelling ratio
Transport properties
Water uptake
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Summary:There is a need to generate mechanically and thermally robust ionic nanoporous membranes for separation and fuel cell applications. Herein, we report a general approach to the preparation of ionic nanoporous membranes through custom synthesis, self-assembly, and subsequent chemical manipulations of ionic brush block copolymers. We synthesized polynorbornene-based triblock copolymers containing imidazolium cations balanced by counter anions in the central block, side-chain liquid crystalline units, and sidechain polylactide end blocks. This unique platform comprises: (1) imidazolium/bis(trifluoromethanesulfonyl)imide (TFSI) as the middle block, which has an excellent ion-exchange ability, (2) cyanobiphenyl liquid crystalline end block, a sterically hindered hydrophobic segment, which is chemically stable and immune to hydroxide attack, (3) polylactide brush-like units on the other end block that is easily etched under mild alkaline conditions and (4) a polynorbornene backbone, a lightly crosslinked system that offers mechanical robustness. These membranes retain their morphology before and after backbone crosslinking as well as etching of polylactide sidechains. The ion exchange performance and dimensional stability of these membranes were investigated by water uptake capability and swelling ratio. Moreover, the length of the carbon spacer in the imidazolium/TFSI central block moiety endowed the membrane with improved ionic conductivity. The ionic nanoporous materials are unusual due to their singular thermal, mechanical, alkaline stability and ion transport properties. Applications of these materials include electrochemical actuators, solid-state ionic nanochannel biosensors, and ion-conducting membranes. Ion-conducting nanoporous membranes with high ion exchange capacity and mechanical, thermal and alkaline stability.
ISSN:1744-683X
1744-6848
1744-6848
DOI:10.1039/d4sm00449c