Mixing ligands to enhance gas uptake in polyMOFs

Matthew A. Pearson; Sachin Bhagchandani; Mircea Dincă; Jeremiah A. Johnson

doi:10.1039/d2me00227b

Mixing ligands to enhance gas uptake in polyMOFs

Matthew A. Pearson, Sachin Bhagchandani, Mircea Dincă, Jeremiah A. Johnson

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

2 Scopus citations

Abstract

Polymer-metal organic frameworks (polyMOFs) offer a pathway toward processable polymer-MOF hybrid materials; however, because polymeric ligands are incorporated throughout the MOF lattice, polyMOFs have an inherent shortcoming of reduced pore accessability and surface area compared to traditional MOFs. Herein, a strategy for altering the degree of polymer incorporation in polyMOFs by mixing a multivalent polymer ligand containing MOF-forming linkers with “free” linkers is investigated as a means to tune the properties of polyMOFs, resulting in polyMOFs with superior N₂ and CO₂ uptake. The mixed ligand approach is further extended to distinct MOF-forming polymer ligands to create multivariate (MTV)-polyMOFs, which provides a method for incorporating low-dispersity polymer ligands with complex architectures into polyMOF lattices without the addition of small molecule components.

Original language	English (US)
Pages (from-to)	591-597
Number of pages	7
Journal	Molecular Systems Design and Engineering
Volume	8
Issue number	5
DOIs	https://doi.org/10.1039/d2me00227b
State	Published - Jan 25 2023
Externally published	Yes

All Science Journal Classification (ASJC) codes

Chemistry (miscellaneous)
Chemical Engineering (miscellaneous)
Biomedical Engineering
Energy Engineering and Power Technology
Process Chemistry and Technology
Industrial and Manufacturing Engineering
Materials Chemistry

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10.1039/d2me00227b

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title = "Mixing ligands to enhance gas uptake in polyMOFs",

abstract = "Polymer-metal organic frameworks (polyMOFs) offer a pathway toward processable polymer-MOF hybrid materials; however, because polymeric ligands are incorporated throughout the MOF lattice, polyMOFs have an inherent shortcoming of reduced pore accessability and surface area compared to traditional MOFs. Herein, a strategy for altering the degree of polymer incorporation in polyMOFs by mixing a multivalent polymer ligand containing MOF-forming linkers with “free” linkers is investigated as a means to tune the properties of polyMOFs, resulting in polyMOFs with superior N2 and CO2 uptake. The mixed ligand approach is further extended to distinct MOF-forming polymer ligands to create multivariate (MTV)-polyMOFs, which provides a method for incorporating low-dispersity polymer ligands with complex architectures into polyMOF lattices without the addition of small molecule components.",

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AU - Pearson, Matthew A.

AU - Bhagchandani, Sachin

AU - Dincă, Mircea

AU - Johnson, Jeremiah A.

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AB - Polymer-metal organic frameworks (polyMOFs) offer a pathway toward processable polymer-MOF hybrid materials; however, because polymeric ligands are incorporated throughout the MOF lattice, polyMOFs have an inherent shortcoming of reduced pore accessability and surface area compared to traditional MOFs. Herein, a strategy for altering the degree of polymer incorporation in polyMOFs by mixing a multivalent polymer ligand containing MOF-forming linkers with “free” linkers is investigated as a means to tune the properties of polyMOFs, resulting in polyMOFs with superior N2 and CO2 uptake. The mixed ligand approach is further extended to distinct MOF-forming polymer ligands to create multivariate (MTV)-polyMOFs, which provides a method for incorporating low-dispersity polymer ligands with complex architectures into polyMOF lattices without the addition of small molecule components.

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Mixing ligands to enhance gas uptake in polyMOFs

Abstract

All Science Journal Classification (ASJC) codes

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