Nanochannel Stability of Chemically Converted Graphene Oxide Membranes

Nanochannel Stability of Chemically Converted Graphene Oxide Membranes

Chemically converted graphene oxide laminate membranes, which exhibit stable interlayered nanochannels in aqueous environments, are receiving increasing attention owing to their potential for selective water and ion permeation. However, how the molecular properties of conversion agents influence the...

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Published in:Small (Weinheim an der Bergstrasse, Germany) Vol. 20; no. 34; pp. e2311237 - n/a
Main Authors: Zhou, Siyu, Guan, Kecheng, Li, Zhan, Xu, Ping, Fang, Shang, Zhang, Aiwen, Wang, Zheng, He, Shengnan, Nakagawa, Keizo, Matsuyama, Hideto
Format: Journal Article
Language:English
Published: Germany Wiley Subscription Services, Inc 01-08-2024
Subjects:
Aqueous environments
Carbohydrates
chemical conversion
Chemical reduction
desalination
Graphene
graphene oxide
Maltose
Membranes
Molecular properties
nanochannel membrane
Nanochannels
Separation
Stability
Stabilization
graphene oxide
desalination
chemical conversion
nanochannel membrane
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Summary:Chemically converted graphene oxide laminate membranes, which exhibit stable interlayered nanochannels in aqueous environments, are receiving increasing attention owing to their potential for selective water and ion permeation. However, how the molecular properties of conversion agents influence the stabilization of nanochannels and how effectively nanochannels are stabilized have rarely been studied. In this study, mono‐, di‐, and tri‐saccharide molecules of glucose (Glu), maltose (Glu2), and maltotriose (Glu3) are utilized, respectively, to chemically modify graphene oxide (GO). The aim is to create nanochannels with different levels of stability and investigate how these functional conversion agents affect the separation performance. The effects of the property differences between different conversion agents on nanochannel stabilization are demonstrated. An agent with efficient chemical reduction of GO and limited intercalation in the resulting nanochannel ensures satisfactory nanochannel stability during desalination. The stabilized membrane nanochannel exhibits a permeance of 0.69 L m−2 h−1 bar−1 and excellent Na2SO4 rejection of 96.42%. Furthermore, this optimized membrane nanochannel demonstrates enhanced stability under varying external conditions compared to the original GO. This study provides useful information for the design of chemical conversion agents for GO nanochannel stabilization and the development of nanochannel membranes for precise separation. The effects of property difference between different conversion agents on the nanochannel stabilization are evidenced. The agent with efficient chemical reduction of GO and limited intercalation effect in the resulting nanochannel ensures satisfactory nanochannel stability under desalination process. The optimal membrane nanochannel possess significantly improved stability under various changing conditions as compared to the original GO.
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ISSN:1613-6810
1613-6829
1613-6829
DOI:10.1002/smll.202311237