2D MXene Nanofilms with Tunable Gas Transport Channels

2D materials' membranes with well‐defined nanochannels are promising for precise molecular separation. Herein, the design and engineering of atomically thin 2D MXene flacks into nanofilms with a thickness of 20 nm for gas separation are reported. Well‐stacked pristine MXene nanofilms are proven...

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Bibliographic Details
Published in:Advanced functional materials 2018-08, Vol.28 (31), p.n/a
Main Authors: Shen, Jie, Liu, Guozhen, Ji, Yufan, Liu, Quan, Cheng, Long, Guan, Kecheng, Zhang, Mengchen, Liu, Gongping, Xiong, Jie, Yang, Jian, Jin, Wanqin
Format: Article
Language:English
Subjects:
2D materials
Carbon dioxide
Catalysis
Confined spaces
Design engineering
Diffusion layers
Energy conversion
Fluidics
Gas separation
Gas transport
Interlayers
Materials science
Membranes
molecular sieving
MXene
MXenes
Nanochannels
nanofilms
Nanofluids
Organic chemistry
Polyethyleneimine
Thickness
Tuning
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Summary:2D materials' membranes with well‐defined nanochannels are promising for precise molecular separation. Herein, the design and engineering of atomically thin 2D MXene flacks into nanofilms with a thickness of 20 nm for gas separation are reported. Well‐stacked pristine MXene nanofilms are proven to show outstanding molecular sieving property for H2 preferential transport. Chemical tuning of the MXene nanochannels is also rationally designed for selective permeating CO2. Borate and polyethylenimine (PEI) molecules are well interlocked into MXene layers, realizing the delicate regulation of stacking behaviors and interlayer spacing of MXene nanosheets. The MXene nanofilms with either H2‐ or CO2‐selective transport channels exhibit excellent gas separation performance beyond the limits for state‐of‐the‐art membranes. The mechanisms within these nanoconfined MXene layers are discussed, revealing the transformation from “diffusion‐controlled” to “solution‐controlled” channels after chemical tuning. This work of precisely tailoring the 2D nanostructure may inspire the exploring of nanofluidics in 2D confined space with applications in many other fields like catalysis and energy conversion processes. Ultrathin 2D MXene nanofilms with a thickness of 20 nm are designed and fabricated. A highly ordered stacking nanostructure and penetrantphilic interlayer spaces with sub‐nanometer size are delicately regulated to enable the MXene nanofilms with tunable gas transport channels (H2‐ or CO2‐selective), and exhibit extraordinary molecular gas sieving performance transcending the upper bound of state‐of‐the‐art membranes.
ISSN:1616-301X
1616-3028
DOI:10.1002/adfm.201801511