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Ultrathin graphene-based membrane with precise molecular sieving and ultrafast solvent permeation
journal contribution
posted on 2020-01-16, 13:57 authored by Q Yang, Yang Su, C Chi, CT Cherian, K Huang, VG Kravets, FC Wang, JC Zhang, A Pratt, AN Grigorenko, F Guinea, AK Geim, RR Nair© 2017 Macmillan Publishers Limited, part of Springer Nature. All rights reserved. Graphene oxide (GO) membranes continue to attract intense interest due to their unique molecular sieving properties combined with fast permeation. However, their use is limited to aqueous solutions because GO membranes appear impermeable to organic solvents, a phenomenon not yet fully understood. Here, we report efficient and fast filtration of organic solutions through GO laminates containing smooth two-dimensional (2D) capillaries made from large (10-20 μm) flakes. Without modification of sieving characteristics, these membranes can be made exceptionally thin, down to â 1/410 nm, which translates into fast water and organic solvent permeation. We attribute organic solvent permeation and sieving properties to randomly distributed pinholes interconnected by short graphene channels with a width of 1 nm. With increasing membrane thickness, organic solvent permeation rates decay exponentially but water continues to permeate quickly, in agreement with previous reports. The potential of ultrathin GO laminates for organic solvent nanofiltration is demonstrated by showing >99.9% rejection of small molecular weight organic dyes dissolved in methanol. Our work significantly expands possibilities for the use of GO membranes in purification and filtration technologies.
Funding
Royal Society, Engineering and Physical Sciences Research Council, UK (EP/K016946/1)
Lloyd’s Register Foundation
European Research Council (contract 679689)
History
School
- Aeronautical, Automotive, Chemical and Materials Engineering
Department
- Materials
Published in
Nature MaterialsVolume
16Issue
12Pages
1198 - 1202Publisher
Springer Science and Business Media LLCVersion
- AM (Accepted Manuscript)
Rights holder
© MacmillanPublisher statement
This paper was accepted for publication in the journal Nature Materials and the definitive published version is available at https://doi.org/10.1038/nmat5025Acceptance date
2017-10-05Publication date
2017-11-13Copyright date
2017ISSN
1476-1122eISSN
1476-4660Publisher version
Language
- en
Location
EnglandDepositor
Dr Yang Su Deposit date: 14 January 2020Usage metrics
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