Achieving high permeability and enhanced selectivity for Angstrom-scale separations using artificial water channel membranes

Yue Xiao Shen; Woochul C. Song; D. Ryan Barden; Tingwei Ren; Chao Lang; Hasin Feroz; Codey B. Henderson; Patrick O. Saboe; Daniel Tsai; Hengjing Yan; Peter J. Butler; Guillermo C. Bazan; William A. Phillip; Robert J. Hickey; Paul S. Cremer; Harish Vashisth; Manish Kumar

doi:10.1038/s41467-018-04604-y

Achieving high permeability and enhanced selectivity for Angstrom-scale separations using artificial water channel membranes

Yue Xiao Shen
, Woochul C. Song
, D. Ryan Barden
, Tingwei Ren
, Chao Lang
, Hasin Feroz
, Codey B. Henderson
, Patrick O. Saboe
, Daniel Tsai
, Hengjing Yan
, Peter J. Butler
, Guillermo C. Bazan
, William A. Phillip
, Robert J. Hickey
, Paul S. Cremer
, Harish Vashisth
, Manish Kumar

Research output: Contribution to journal › Article › peer-review

133 Scopus citations

Abstract

Synthetic polymer membranes, critical to diverse energy-efficient separations, are subject to permeability-selectivity trade-offs that decrease their overall efficacy. These trade-offs are due to structural variations (e.g., broad pore size distributions) in both nonporous membranes used for Angstrom-scale separations and porous membranes used for nano to micron-scale separations. Biological membranes utilize well-defined Angstrom-scale pores to provide exceptional transport properties and can be used as inspiration to overcome this trade-off. Here, we present a comprehensive demonstration of such a bioinspired approach based on pillar[5]arene artificial water channels, resulting in artificial water channel-based block copolymer membranes. These membranes have a sharp selectivity profile with a molecular weight cutoff of ~ 500 Da, a size range challenging to achieve with current membranes, while achieving a large improvement in permeability (~65 L m^-2 h^-1 bar^-1 compared with 4-7 L m^-2 h^-1 bar^-1) over similarly rated commercial membranes.

Original language	English (US)
Article number	2294
Journal	Nature communications
Volume	9
Issue number	1
DOIs	https://doi.org/10.1038/s41467-018-04604-y
State	Published - Dec 1 2018

All Science Journal Classification (ASJC) codes

General Chemistry
General Biochemistry, Genetics and Molecular Biology
General Physics and Astronomy

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Shen, Y. X., Song, W. C., Ryan Barden, D., Ren, T., Lang, C., Feroz, H., Henderson, C. B., Saboe, P. O., Tsai, D., Yan, H., Butler, P. J., Bazan, G. C., Phillip, W. A., Hickey, R. J., Cremer, P. S., Vashisth, H., & Kumar, M. (2018). Achieving high permeability and enhanced selectivity for Angstrom-scale separations using artificial water channel membranes. Nature communications, 9(1), Article 2294. https://doi.org/10.1038/s41467-018-04604-y

@article{756c2824895145fe855b2124f116f873,

title = "Achieving high permeability and enhanced selectivity for Angstrom-scale separations using artificial water channel membranes",

abstract = "Synthetic polymer membranes, critical to diverse energy-efficient separations, are subject to permeability-selectivity trade-offs that decrease their overall efficacy. These trade-offs are due to structural variations (e.g., broad pore size distributions) in both nonporous membranes used for Angstrom-scale separations and porous membranes used for nano to micron-scale separations. Biological membranes utilize well-defined Angstrom-scale pores to provide exceptional transport properties and can be used as inspiration to overcome this trade-off. Here, we present a comprehensive demonstration of such a bioinspired approach based on pillar[5]arene artificial water channels, resulting in artificial water channel-based block copolymer membranes. These membranes have a sharp selectivity profile with a molecular weight cutoff of \textasciitilde{} 500 Da, a size range challenging to achieve with current membranes, while achieving a large improvement in permeability (\textasciitilde{}65 L m-2 h-1 bar-1 compared with 4-7 L m-2 h-1 bar-1) over similarly rated commercial membranes.",

author = "Shen, \{Yue Xiao\} and Song, \{Woochul C.\} and \{Ryan Barden\}, D. and Tingwei Ren and Chao Lang and Hasin Feroz and Henderson, \{Codey B.\} and Saboe, \{Patrick O.\} and Daniel Tsai and Hengjing Yan and Butler, \{Peter J.\} and Bazan, \{Guillermo C.\} and Phillip, \{William A.\} and Hickey, \{Robert J.\} and Cremer, \{Paul S.\} and Harish Vashisth and Manish Kumar",

note = "Publisher Copyright: {\textcopyright} 2018 The Author(s).",

year = "2018",

month = dec,

day = "1",

doi = "10.1038/s41467-018-04604-y",

language = "English (US)",

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Shen, YX, Song, WC, Ryan Barden, D, Ren, T, Lang, C, Feroz, H, Henderson, CB, Saboe, PO, Tsai, D, Yan, H, Butler, PJ, Bazan, GC, Phillip, WA, Hickey, RJ , Cremer, PS, Vashisth, H & Kumar, M 2018, 'Achieving high permeability and enhanced selectivity for Angstrom-scale separations using artificial water channel membranes', Nature communications, vol. 9, no. 1, 2294. https://doi.org/10.1038/s41467-018-04604-y

TY - JOUR

T1 - Achieving high permeability and enhanced selectivity for Angstrom-scale separations using artificial water channel membranes

AU - Shen, Yue Xiao

AU - Song, Woochul C.

AU - Ryan Barden, D.

AU - Ren, Tingwei

AU - Lang, Chao

AU - Feroz, Hasin

AU - Henderson, Codey B.

AU - Saboe, Patrick O.

AU - Tsai, Daniel

AU - Yan, Hengjing

AU - Butler, Peter J.

AU - Bazan, Guillermo C.

AU - Phillip, William A.

AU - Hickey, Robert J.

AU - Cremer, Paul S.

AU - Vashisth, Harish

AU - Kumar, Manish

PY - 2018/12/1

Y1 - 2018/12/1

N2 - Synthetic polymer membranes, critical to diverse energy-efficient separations, are subject to permeability-selectivity trade-offs that decrease their overall efficacy. These trade-offs are due to structural variations (e.g., broad pore size distributions) in both nonporous membranes used for Angstrom-scale separations and porous membranes used for nano to micron-scale separations. Biological membranes utilize well-defined Angstrom-scale pores to provide exceptional transport properties and can be used as inspiration to overcome this trade-off. Here, we present a comprehensive demonstration of such a bioinspired approach based on pillar[5]arene artificial water channels, resulting in artificial water channel-based block copolymer membranes. These membranes have a sharp selectivity profile with a molecular weight cutoff of ~ 500 Da, a size range challenging to achieve with current membranes, while achieving a large improvement in permeability (~65 L m-2 h-1 bar-1 compared with 4-7 L m-2 h-1 bar-1) over similarly rated commercial membranes.

AB - Synthetic polymer membranes, critical to diverse energy-efficient separations, are subject to permeability-selectivity trade-offs that decrease their overall efficacy. These trade-offs are due to structural variations (e.g., broad pore size distributions) in both nonporous membranes used for Angstrom-scale separations and porous membranes used for nano to micron-scale separations. Biological membranes utilize well-defined Angstrom-scale pores to provide exceptional transport properties and can be used as inspiration to overcome this trade-off. Here, we present a comprehensive demonstration of such a bioinspired approach based on pillar[5]arene artificial water channels, resulting in artificial water channel-based block copolymer membranes. These membranes have a sharp selectivity profile with a molecular weight cutoff of ~ 500 Da, a size range challenging to achieve with current membranes, while achieving a large improvement in permeability (~65 L m-2 h-1 bar-1 compared with 4-7 L m-2 h-1 bar-1) over similarly rated commercial membranes.

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JF - Nature communications

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ER -

Achieving high permeability and enhanced selectivity for Angstrom-scale separations using artificial water channel membranes

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