Facile manufacture of porous organic framework membranes for precombustion CO2 capture

Meixia Shan; Xinlei Liu; Xuerui Wang; Irina Yarulina; Beatriz Seoane; Freek Kapteijn; Jorge Gascon

doi:10.1126/sciadv.aau1698

Facile manufacture of porous organic framework membranes for precombustion CO₂ capture

Meixia Shan, Xinlei Liu, Xuerui Wang, Irina Yarulina, Beatriz Seoane, Freek Kapteijn, Jorge Gascon

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

121 Scopus citations

Abstract

The development of new membranes with high H₂ separation performance under industrially relevant conditions (high temperatures and pressures) is of primary importance. For instance, these membranes may facilitate the implementation of energy-efficient precombustion CO₂ capture or reduce energy intensity in other industrial processes such as ammonia synthesis. We report a facile synthetic protocol based on interfacial polymerization for the fabrication of supported benzimidazole-linked polymer membranes that display an unprecedented H₂/CO₂ selectivity (up to 40) at 423 K together with high-pressure resistance and long-term stability (>800 hours in the presence of water vapor).

Original language	English
Article number	aau1698
Journal	Science advances
Volume	4
Issue number	9
DOIs	https://doi.org/10.1126/sciadv.aau1698
State	Published - 21 Sep 2018
Externally published	Yes

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title = "Facile manufacture of porous organic framework membranes for precombustion CO2 capture",

abstract = "The development of new membranes with high H2 separation performance under industrially relevant conditions (high temperatures and pressures) is of primary importance. For instance, these membranes may facilitate the implementation of energy-efficient precombustion CO2 capture or reduce energy intensity in other industrial processes such as ammonia synthesis. We report a facile synthetic protocol based on interfacial polymerization for the fabrication of supported benzimidazole-linked polymer membranes that display an unprecedented H2/CO2 selectivity (up to 40) at 423 K together with high-pressure resistance and long-term stability (>800 hours in the presence of water vapor).",

author = "Meixia Shan and Xinlei Liu and Xuerui Wang and Irina Yarulina and Beatriz Seoane and Freek Kapteijn and Jorge Gascon",

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AU - Shan, Meixia

AU - Liu, Xinlei

AU - Wang, Xuerui

AU - Yarulina, Irina

AU - Seoane, Beatriz

AU - Kapteijn, Freek

AU - Gascon, Jorge

PY - 2018/9/21

Y1 - 2018/9/21

N2 - The development of new membranes with high H2 separation performance under industrially relevant conditions (high temperatures and pressures) is of primary importance. For instance, these membranes may facilitate the implementation of energy-efficient precombustion CO2 capture or reduce energy intensity in other industrial processes such as ammonia synthesis. We report a facile synthetic protocol based on interfacial polymerization for the fabrication of supported benzimidazole-linked polymer membranes that display an unprecedented H2/CO2 selectivity (up to 40) at 423 K together with high-pressure resistance and long-term stability (>800 hours in the presence of water vapor).

AB - The development of new membranes with high H2 separation performance under industrially relevant conditions (high temperatures and pressures) is of primary importance. For instance, these membranes may facilitate the implementation of energy-efficient precombustion CO2 capture or reduce energy intensity in other industrial processes such as ammonia synthesis. We report a facile synthetic protocol based on interfacial polymerization for the fabrication of supported benzimidazole-linked polymer membranes that display an unprecedented H2/CO2 selectivity (up to 40) at 423 K together with high-pressure resistance and long-term stability (>800 hours in the presence of water vapor).

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JO - Science advances

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ER -

Facile manufacture of porous organic framework membranes for precombustion CO₂ capture

Abstract

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