Surpassing Robeson Upper Limit for CO2/N2 Separation with Fluorinated Carbon Molecular Sieve Membranes

Zhenzhen Yang; Wei Guo; Shannon Mark Mahurin; Song Wang; Hao Chen; Long Cheng; Kecheng Jie; Harry M. Meyer; De en Jiang; Gongping Liu; Wanqin Jin; Ilja Popovs; Sheng Dai

doi:10.1016/j.chempr.2019.12.006

Surpassing Robeson Upper Limit for CO₂/N₂ Separation with Fluorinated Carbon Molecular Sieve Membranes

Zhenzhen Yang, Wei Guo, Shannon Mark Mahurin, Song Wang, Hao Chen, Long Cheng, Kecheng Jie, Harry M. Meyer, De en Jiang, Gongping Liu, Wanqin Jin, Ilja Popovs, Sheng Dai

COLLEGE OF CHEMICAL ENGINEERING

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

94 Scopus citations

Abstract

Rational design of robust and highly selective separation processes leading to an efficient sequestration of anthropogenic CO₂ is one of the most important problems, especially considering the effects of climate change. Unsurprisingly, the fabrication of highly selective CO₂ separation membranes, especially those capable of overcoming undesirable trade-off relationship between permeability and selectivity, is a vibrant and ever-growing field. However, there are only a handful examples of membranes that reportedly overcome the Robeson upper limit in CO₂ separations. In this work, we present an efficient strategy that addresses a rational design of materials that exhibit remarkable affinity toward CO₂ by introducing CO₂-philic fluorine-containing substituents into their structure, via a bottom up polymerization and pyrolysis approach and a precise control over the ultra-microporosity, resulting in some of the most efficient and promising CO₂ separation media reported thus far.

Original language	English
Pages (from-to)	631-645
Number of pages	15
Journal	Chem
Volume	6
Issue number	3
DOIs	https://doi.org/10.1016/j.chempr.2019.12.006
State	Published - 12 Mar 2020

Keywords

SDG13: Climate action
carbon dioxide capture
covalent triazine framework
fluorine
membrane separation
molecular sieve membrane

UN SDGs

This output contributes to the following UN Sustainable Development Goals (SDGs)

Access to Document

10.1016/j.chempr.2019.12.006

Cite this

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title = "Surpassing Robeson Upper Limit for CO2/N2 Separation with Fluorinated Carbon Molecular Sieve Membranes",

abstract = "Rational design of robust and highly selective separation processes leading to an efficient sequestration of anthropogenic CO2 is one of the most important problems, especially considering the effects of climate change. Unsurprisingly, the fabrication of highly selective CO2 separation membranes, especially those capable of overcoming undesirable trade-off relationship between permeability and selectivity, is a vibrant and ever-growing field. However, there are only a handful examples of membranes that reportedly overcome the Robeson upper limit in CO2 separations. In this work, we present an efficient strategy that addresses a rational design of materials that exhibit remarkable affinity toward CO2 by introducing CO2-philic fluorine-containing substituents into their structure, via a bottom up polymerization and pyrolysis approach and a precise control over the ultra-microporosity, resulting in some of the most efficient and promising CO2 separation media reported thus far.",

keywords = "SDG13: Climate action, carbon dioxide capture, covalent triazine framework, fluorine, membrane separation, molecular sieve membrane",

author = "Zhenzhen Yang and Wei Guo and Mahurin, {Shannon Mark} and Song Wang and Hao Chen and Long Cheng and Kecheng Jie and Meyer, {Harry M.} and Jiang, {De en} and Gongping Liu and Wanqin Jin and Ilja Popovs and Sheng Dai",

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doi = "10.1016/j.chempr.2019.12.006",

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T1 - Surpassing Robeson Upper Limit for CO2/N2 Separation with Fluorinated Carbon Molecular Sieve Membranes

AU - Yang, Zhenzhen

AU - Guo, Wei

AU - Mahurin, Shannon Mark

AU - Wang, Song

AU - Chen, Hao

AU - Cheng, Long

AU - Jie, Kecheng

AU - Meyer, Harry M.

AU - Jiang, De en

AU - Liu, Gongping

AU - Jin, Wanqin

AU - Popovs, Ilja

AU - Dai, Sheng

PY - 2020/3/12

Y1 - 2020/3/12

N2 - Rational design of robust and highly selective separation processes leading to an efficient sequestration of anthropogenic CO2 is one of the most important problems, especially considering the effects of climate change. Unsurprisingly, the fabrication of highly selective CO2 separation membranes, especially those capable of overcoming undesirable trade-off relationship between permeability and selectivity, is a vibrant and ever-growing field. However, there are only a handful examples of membranes that reportedly overcome the Robeson upper limit in CO2 separations. In this work, we present an efficient strategy that addresses a rational design of materials that exhibit remarkable affinity toward CO2 by introducing CO2-philic fluorine-containing substituents into their structure, via a bottom up polymerization and pyrolysis approach and a precise control over the ultra-microporosity, resulting in some of the most efficient and promising CO2 separation media reported thus far.

AB - Rational design of robust and highly selective separation processes leading to an efficient sequestration of anthropogenic CO2 is one of the most important problems, especially considering the effects of climate change. Unsurprisingly, the fabrication of highly selective CO2 separation membranes, especially those capable of overcoming undesirable trade-off relationship between permeability and selectivity, is a vibrant and ever-growing field. However, there are only a handful examples of membranes that reportedly overcome the Robeson upper limit in CO2 separations. In this work, we present an efficient strategy that addresses a rational design of materials that exhibit remarkable affinity toward CO2 by introducing CO2-philic fluorine-containing substituents into their structure, via a bottom up polymerization and pyrolysis approach and a precise control over the ultra-microporosity, resulting in some of the most efficient and promising CO2 separation media reported thus far.

KW - SDG13: Climate action

KW - carbon dioxide capture

KW - covalent triazine framework

KW - fluorine

KW - membrane separation

KW - molecular sieve membrane

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