Free-standing, thin-film, symmetric membranes: Next-generation membranes for engineered osmosis

Free-standing, thin-film, symmetric membranes: Next-generation membranes for engineered osmosis

The support layer of an asymmetric thin-film composite membrane results in structural resistance (internal concentration polarization) that significantly undermines engineered osmosis. Increasing the porosity and reducing the thickness and tortuosity of the membrane support layer reduces structural...

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Bibliographic Details
Published in:Journal of membrane science Vol. 607; p. 118145
Main Authors: Phuntsho, Sherub, Kim, Jung Eun, Tran, Van Huy, Tahara, Shuji, Uehara, Naoki, Maruko, Nobuhiro, Matsuno, Hirozumi, Lim, Sungil, Shon, Ho Kyong
Format: Journal Article
Language:English
Published: Elsevier B.V 15-07-2020
Subjects:
Desalination
Engineered osmosis
Non-polyamide-based membrane
Self-standing membrane
Sulfonated poly ether ketone
Non-polyamide-based membrane
Self-standing membrane
Desalination
Sulfonated poly ether ketone
Engineered osmosis
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Summary:The support layer of an asymmetric thin-film composite membrane results in structural resistance (internal concentration polarization) that significantly undermines engineered osmosis. Increasing the porosity and reducing the thickness and tortuosity of the membrane support layer reduces structural resistance; however, internal concentration polarization still impacts membrane performance. A novel, ultrathin, free-standing and symmetric membrane has been synthesized using sulfonated polyether ketone and tested for forward osmosis applications. This membrane is composed of a protonic acid group containing an aromatic polyether resin with sulfonated structural units. Polyether ketone provides high mechanical strength essential for ultrathin free-standing membranes, while sulfonation enhances the membrane hydrophilicity. These sulfonated polyether ketone membranes show promising water flux performances with impressive mechanical strength under the hydraulic operating conditions used for a FO process. •Ultrathin and free-standing FO membrane was synthesized using SPEK polymer.•0.6 μm thick membrane showed FO water flux of 20.5 Lm−2h−1 with 1 M NaCl: DI.•The specific reverse solute flux of this 0.6 μm thick membrane was 1.2 gL-1.•Free-standing SPEK film exhibited adequate mechanical strength for FO operations.•Embedding polyester mesh enhanced mechanical strength without impacting FO water flux.
ISSN:0376-7388
1873-3123
DOI:10.1016/j.memsci.2020.118145