Polyamide Nanofilms through a Non‐Isothermal‐Controlled Interfacial Polymerization

Efficient thin film composite polyamide (PA) membranes require optimization of interfacial polymerization (IP) process. However, it is challengeable owing to its ultrafast reaction rate coupled with mass and heat transfer, yielding heterogeneous PA membranes with low performance. Herein, a non‐isoth...

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Bibliographic Details
Published inAdvanced functional materials Vol. 34; no. 18
Main Authors Zhao, Guang‐Jin, Li, Lu‐Lu, Gao, Hai‐Qi, Zhao, Zhi‐Jian, Pang, Zi‐Fan, Pei, Chun‐Lei, Qu, Zhou, Dong, Liang‐Liang, Rao, De‐Wei, Caro, Jürgen, Meng, Hong
Format Journal Article
LanguageEnglish
Published Hoboken Wiley Subscription Services, Inc 01.05.2024
Subjects
antibiotic desalination
Antibiotics
Aqueous solutions
Desalination
Heat transfer
interfacial polymerization
Mass transfer
membrane separation
Membranes
nanofiltration
Phase transitions
polyamide
Polyamide resins
Polymerization
Thin films
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Summary:Efficient thin film composite polyamide (PA) membranes require optimization of interfacial polymerization (IP) process. However, it is challengeable owing to its ultrafast reaction rate coupled with mass and heat transfer, yielding heterogeneous PA membranes with low performance. Herein, a non‐isothermal‐controlled IP (NIIP) method is proposed to fabricate a highly permeable and selective PA membrane by engineering IP at the cryogenic aqueous phase (CAP) to achieve synchronous control of heat and mass transfer in the interfacial region. The CAP also enables the phase transition of the aqueous solution from the liquid to solid state, providing a more comprehensive understanding of the fundamental mechanisms involved in different phase states in the IP process. Consequently, the PA membrane exhibits excellent separation performance with ultrahigh water permeance (42.9 L m−2 h−1 bar−1) and antibiotic desalination efficiency (antibiotic/NaCl selectivity of 159.3). This study provides new insights for the in‐depth understanding of the precise mechanism linking IP to the performance of the targeting membrane. A non‐isothermal‐controlled IP method is proposed to fabricate a highly permeable and selective PA membrane by engineering IP at the cryogenic aqueous phase to achieve synchronous control of heat and mass transfer in the interfacial region. The membrane exhibits ultrahigh water permeance and antibiotic desalination efficiency.
ISSN:1616-301X
1616-3028
DOI:10.1002/adfm.202313026