Water-stable ZIF-300/Ultrason® mixed-matrix membranes for selective CO2 capture from humid post combustion flue gas

doi:10.1016/j.cjche.2017.11.007

Abstract

Abstract: Water stable mixed-matrix membranes (MMMs) were developed to help control the global warming by capturing and sequestrating carbon dioxide (CO₂) from post-combustion flue gas originated from burning of fossil fuels. MMMs of different compositions were prepared by doping glassy polymer Ultrason^® S 6010 (US) with nanocrystals of zeolitic imidazolate frameworks (ZIF-300) in varying degrees. Solution-casting technique was used to fabricate various MMMs to optimize their CO₂ capturing performance from both dry and wet gases. The prepared composite membranes indicated enhanced filler-polymer interfacial adhesion, consistent distribution of nanofiller, and thermally established matrix configuration. CO₂ permeability of the membranes was enhanced as demonstrated by gas sorption and permeation experiments performed under both dry and wet conditions. As compared to neat Ultrason^® membrane, CO₂ permeability of the composite membrane doped with 40 wt% ZIF-300 nanocrystals was increased by four times without disturbing CO₂/N2 ideal selectivity. In contrast to majority of previously reported membranes, key features of the fabricated MMMs include their structural stability under humid conditions coupled with better and unaffected gas separation performance.

Key words: Hydrophobic MMMs, ZIF-300, Gas permeation, CO₂ capture, Permselectivity

摘要： Water stable mixed-matrix membranes (MMMs) were developed to help control the global warming by capturing and sequestrating carbon dioxide (CO₂) from post-combustion flue gas originated from burning of fossil fuels. MMMs of different compositions were prepared by doping glassy polymer Ultrason^® S 6010 (US) with nanocrystals of zeolitic imidazolate frameworks (ZIF-300) in varying degrees. Solution-casting technique was used to fabricate various MMMs to optimize their CO₂ capturing performance from both dry and wet gases. The prepared composite membranes indicated enhanced filler-polymer interfacial adhesion, consistent distribution of nanofiller, and thermally established matrix configuration. CO₂ permeability of the membranes was enhanced as demonstrated by gas sorption and permeation experiments performed under both dry and wet conditions. As compared to neat Ultrason^® membrane, CO₂ permeability of the composite membrane doped with 40 wt% ZIF-300 nanocrystals was increased by four times without disturbing CO₂/N2 ideal selectivity. In contrast to majority of previously reported membranes, key features of the fabricated MMMs include their structural stability under humid conditions coupled with better and unaffected gas separation performance.

关键词: Hydrophobic MMMs, ZIF-300, Gas permeation, CO₂ capture, Permselectivity

Muhammad Sarfraz, M. Ba-Shammakh. Water-stable ZIF-300/Ultrason^® mixed-matrix membranes for selective CO₂ capture from humid post combustion flue gas[J]. Chin.J.Chem.Eng., 2018, 26(5): 1012-1021.

Muhammad Sarfraz, M. Ba-Shammakh. Water-stable ZIF-300/Ultrason^® mixed-matrix membranes for selective CO₂ capture from humid post combustion flue gas[J]. Chinese Journal of Chemical Engineering, 2018, 26(5): 1012-1021.

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Water-stable ZIF-300/Ultrason^® mixed-matrix membranes for selective CO₂ capture from humid post combustion flue gas

Water-stable ZIF-300/Ultrason^® mixed-matrix membranes for selective CO₂ capture from humid post combustion flue gas

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