Defect Engineering in Metal–Organic Frameworks Towards Advanced Mixed Matrix Membranes for Efficient Propylene/Propane Separation

Highly permselective and durable membrane materials have been sought for energy‐efficient C3H6/C3H8 separation. Mixed‐matrix membranes (MMMs) comprising a polymer matrix and metal–organic frameworks (MOFs) are promising candidates for this application; however, rational matching of filler‐matrix is...

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Veröffentlicht in:	Angewandte Chemie International Edition 2021-06, Vol.60 (23), p.13081-13088
Hauptverfasser:	Lee, Tae Hoon, Jung, Jae Gu, Kim, Yu Jin, Roh, Ji Soo, Yoon, Hee Wook, Ghanem, Bader S., Kim, Hyo Won, Cho, Young Hoon, Pinnau, Ingo, Park, Ho Bum
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Sprache:	eng
Schlagworte:	defect engineering Design defects Gas transport in situ FT-IR spectroscopy Membranes Metal-organic frameworks metal–organic frameworks (MOFs) olefin/paraffin separation Permeability Polymers Propylene Selectivity Separation Sorption
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creator	Lee, Tae Hoon Jung, Jae Gu Kim, Yu Jin Roh, Ji Soo Yoon, Hee Wook Ghanem, Bader S. Kim, Hyo Won Cho, Young Hoon Pinnau, Ingo Park, Ho Bum
description	Highly permselective and durable membrane materials have been sought for energy‐efficient C3H6/C3H8 separation. Mixed‐matrix membranes (MMMs) comprising a polymer matrix and metal–organic frameworks (MOFs) are promising candidates for this application; however, rational matching of filler‐matrix is challenging and their separation performances need to be further improved. Here, we propose a novel strategy of “defect engineering” in MOFs as an additional degree of freedom to design advanced MMMs. MMMs incorporated with defect‐engineered MOFs exhibit exceptionally high C3H6 permeability and maintained C3H6/C3H8 selectivity, especially with enhanced stability under industrial mixed‐gas conditions. The gas transport, sorption, and material characterizations reveal that the defect sites in MOFs provide the resulting MMMs with not only ultrafast diffusion pathways but also favorable C3H6 sorption by forming complexation with unsaturated open metal sites, confirmed by in situ FT‐IR studies. Most importantly, the concept is also valid for different polymer matrices and gas pairs, demonstrating its versatile potential in other fields. We first demonstrate the deliberate introduction of defects in metal–organic frameworks (MOFs) can be an additional degree of freedom towards highly permselective MOF/polymer mixed‐matrix membranes (MMMs). The developed MMM materials based on our concept exhibit promising potential for industrial propylene/propane separation processes as well as universal applicability in other fields.
doi_str_mv	10.1002/anie.202100841
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Mixed‐matrix membranes (MMMs) comprising a polymer matrix and metal–organic frameworks (MOFs) are promising candidates for this application; however, rational matching of filler‐matrix is challenging and their separation performances need to be further improved. Here, we propose a novel strategy of “defect engineering” in MOFs as an additional degree of freedom to design advanced MMMs. MMMs incorporated with defect‐engineered MOFs exhibit exceptionally high C3H6 permeability and maintained C3H6/C3H8 selectivity, especially with enhanced stability under industrial mixed‐gas conditions. The gas transport, sorption, and material characterizations reveal that the defect sites in MOFs provide the resulting MMMs with not only ultrafast diffusion pathways but also favorable C3H6 sorption by forming complexation with unsaturated open metal sites, confirmed by in situ FT‐IR studies. Most importantly, the concept is also valid for different polymer matrices and gas pairs, demonstrating its versatile potential in other fields. We first demonstrate the deliberate introduction of defects in metal–organic frameworks (MOFs) can be an additional degree of freedom towards highly permselective MOF/polymer mixed‐matrix membranes (MMMs). 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Mixed‐matrix membranes (MMMs) comprising a polymer matrix and metal–organic frameworks (MOFs) are promising candidates for this application; however, rational matching of filler‐matrix is challenging and their separation performances need to be further improved. Here, we propose a novel strategy of “defect engineering” in MOFs as an additional degree of freedom to design advanced MMMs. MMMs incorporated with defect‐engineered MOFs exhibit exceptionally high C3H6 permeability and maintained C3H6/C3H8 selectivity, especially with enhanced stability under industrial mixed‐gas conditions. The gas transport, sorption, and material characterizations reveal that the defect sites in MOFs provide the resulting MMMs with not only ultrafast diffusion pathways but also favorable C3H6 sorption by forming complexation with unsaturated open metal sites, confirmed by in situ FT‐IR studies. Most importantly, the concept is also valid for different polymer matrices and gas pairs, demonstrating its versatile potential in other fields. We first demonstrate the deliberate introduction of defects in metal–organic frameworks (MOFs) can be an additional degree of freedom towards highly permselective MOF/polymer mixed‐matrix membranes (MMMs). 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subjects	defect engineering Design defects Gas transport in situ FT-IR spectroscopy Membranes Metal-organic frameworks metal–organic frameworks (MOFs) olefin/paraffin separation Permeability Polymers Propylene Selectivity Separation Sorption
title	Defect Engineering in Metal–Organic Frameworks Towards Advanced Mixed Matrix Membranes for Efficient Propylene/Propane Separation
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