Tuning the Redox Activity of Metal-Organic Frameworks for Enhanced, Selective O2Binding: Design Rules and Ambient Temperature O2Chemisorption in a Cobalt-Triazolate Framework

Andrew S. Rosen; M. Rasel Mian; Timur Islamoglu; Haoyuan Chen; Omar K. Farha; Justin M. Notestein; Randall Q. Snurr

doi:10.1021/jacs.9b12401

Tuning the Redox Activity of Metal-Organic Frameworks for Enhanced, Selective O₂Binding: Design Rules and Ambient Temperature O₂Chemisorption in a Cobalt-Triazolate Framework

Andrew S. Rosen, M. Rasel Mian, Timur Islamoglu, Haoyuan Chen, Omar K. Farha, Justin M. Notestein, Randall Q. Snurr

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

71 Scopus citations

Abstract

Metal-organic frameworks (MOFs) with coordinatively unsaturated metal sites are appealing as adsorbent materials due to their tunable functionality and ability to selectively bind small molecules. Through the use of computational screening methods based on periodic density functional theory, we investigate O2 and N2 adsorption at the coordinatively unsaturated metal sites of several MOF families. A variety of design handles are identified that can be used to modify the redox activity of the metal centers, including changing the functionalization of the linkers (replacing oxido donors with sulfido donors), anion exchange of bridging ligands (considering μ-Br-, μ-Cl-, μ-F-, μ-SH-, or μ-OH- groups), and altering the formal oxidation state of the metal. As a result, we show that it is possible to tune the O2 affinity at the open metal sites of MOFs for applications involving the strong and/or selective binding of O2. In contrast with O2 adsorption, N2 adsorption at open metal sites is predicted to be relatively weak across the MOF dataset, with the exception of MOFs containing synthetically elusive V2+ open metal sites. As one example from the screening study, we predicted that exchanging the μ-Cl- ligands of M2Cl2(BBTA) (H2BBTA = 1H,5H-benzo(1,2-d:4,5-d′)bistriazole) with μ-OH- groups would significantly enhance the strength of O2 adsorption at the open metal sites without a corresponding increase in the N2 affinity. Experimental investigation of Co2Cl2(BBTA) and Co2(OH)2(BBTA) confirms that the former exhibits weak physisorption of both N2 and O2, whereas the latter is capable of chemisorbing O2 at room temperature in a highly selective manner. The O2 chemisorption behavior is attributed to the greater electron-donating character of the μ-OH- ligands and the presence of H-bonding interactions between the μ-OH- bridging ligands and the reduced O2 adsorbate.

Original language	English (US)
Pages (from-to)	4317-4328
Number of pages	12
Journal	Journal of the American Chemical Society
Volume	142
Issue number	9
DOIs	https://doi.org/10.1021/jacs.9b12401
State	Published - Mar 4 2020
Externally published	Yes

All Science Journal Classification (ASJC) codes

Catalysis
General Chemistry
Biochemistry
Colloid and Surface Chemistry

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10.1021/jacs.9b12401

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Rosen, A. S., Mian, M. R., Islamoglu, T., Chen, H., Farha, O. K., Notestein, J. M., & Snurr, R. Q. (2020). Tuning the Redox Activity of Metal-Organic Frameworks for Enhanced, Selective O₂Binding: Design Rules and Ambient Temperature O₂Chemisorption in a Cobalt-Triazolate Framework. Journal of the American Chemical Society, 142(9), 4317-4328. https://doi.org/10.1021/jacs.9b12401

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title = "Tuning the Redox Activity of Metal-Organic Frameworks for Enhanced, Selective O2Binding: Design Rules and Ambient Temperature O2Chemisorption in a Cobalt-Triazolate Framework",

abstract = "Metal-organic frameworks (MOFs) with coordinatively unsaturated metal sites are appealing as adsorbent materials due to their tunable functionality and ability to selectively bind small molecules. Through the use of computational screening methods based on periodic density functional theory, we investigate O2 and N2 adsorption at the coordinatively unsaturated metal sites of several MOF families. A variety of design handles are identified that can be used to modify the redox activity of the metal centers, including changing the functionalization of the linkers (replacing oxido donors with sulfido donors), anion exchange of bridging ligands (considering μ-Br-, μ-Cl-, μ-F-, μ-SH-, or μ-OH- groups), and altering the formal oxidation state of the metal. As a result, we show that it is possible to tune the O2 affinity at the open metal sites of MOFs for applications involving the strong and/or selective binding of O2. In contrast with O2 adsorption, N2 adsorption at open metal sites is predicted to be relatively weak across the MOF dataset, with the exception of MOFs containing synthetically elusive V2+ open metal sites. As one example from the screening study, we predicted that exchanging the μ-Cl- ligands of M2Cl2(BBTA) (H2BBTA = 1H,5H-benzo(1,2-d:4,5-d′)bistriazole) with μ-OH- groups would significantly enhance the strength of O2 adsorption at the open metal sites without a corresponding increase in the N2 affinity. Experimental investigation of Co2Cl2(BBTA) and Co2(OH)2(BBTA) confirms that the former exhibits weak physisorption of both N2 and O2, whereas the latter is capable of chemisorbing O2 at room temperature in a highly selective manner. The O2 chemisorption behavior is attributed to the greater electron-donating character of the μ-OH- ligands and the presence of H-bonding interactions between the μ-OH- bridging ligands and the reduced O2 adsorbate.",

author = "Rosen, {Andrew S.} and Mian, {M. Rasel} and Timur Islamoglu and Haoyuan Chen and Farha, {Omar K.} and Notestein, {Justin M.} and Snurr, {Randall Q.}",

note = "Publisher Copyright: {\textcopyright} 2020 American Chemical Society.",

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Rosen, AS, Mian, MR, Islamoglu, T, Chen, H, Farha, OK, Notestein, JM & Snurr, RQ 2020, 'Tuning the Redox Activity of Metal-Organic Frameworks for Enhanced, Selective O₂Binding: Design Rules and Ambient Temperature O₂Chemisorption in a Cobalt-Triazolate Framework', Journal of the American Chemical Society, vol. 142, no. 9, pp. 4317-4328. https://doi.org/10.1021/jacs.9b12401

Tuning the Redox Activity of Metal-Organic Frameworks for Enhanced, Selective O₂Binding: Design Rules and Ambient Temperature O₂Chemisorption in a Cobalt-Triazolate Framework. / Rosen, Andrew S.; Mian, M. Rasel; Islamoglu, Timur et al.
In: Journal of the American Chemical Society, Vol. 142, No. 9, 04.03.2020, p. 4317-4328.

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

TY - JOUR

T1 - Tuning the Redox Activity of Metal-Organic Frameworks for Enhanced, Selective O2Binding

T2 - Design Rules and Ambient Temperature O2Chemisorption in a Cobalt-Triazolate Framework

AU - Rosen, Andrew S.

AU - Mian, M. Rasel

AU - Islamoglu, Timur

AU - Chen, Haoyuan

AU - Farha, Omar K.

AU - Notestein, Justin M.

AU - Snurr, Randall Q.

PY - 2020/3/4

Y1 - 2020/3/4

N2 - Metal-organic frameworks (MOFs) with coordinatively unsaturated metal sites are appealing as adsorbent materials due to their tunable functionality and ability to selectively bind small molecules. Through the use of computational screening methods based on periodic density functional theory, we investigate O2 and N2 adsorption at the coordinatively unsaturated metal sites of several MOF families. A variety of design handles are identified that can be used to modify the redox activity of the metal centers, including changing the functionalization of the linkers (replacing oxido donors with sulfido donors), anion exchange of bridging ligands (considering μ-Br-, μ-Cl-, μ-F-, μ-SH-, or μ-OH- groups), and altering the formal oxidation state of the metal. As a result, we show that it is possible to tune the O2 affinity at the open metal sites of MOFs for applications involving the strong and/or selective binding of O2. In contrast with O2 adsorption, N2 adsorption at open metal sites is predicted to be relatively weak across the MOF dataset, with the exception of MOFs containing synthetically elusive V2+ open metal sites. As one example from the screening study, we predicted that exchanging the μ-Cl- ligands of M2Cl2(BBTA) (H2BBTA = 1H,5H-benzo(1,2-d:4,5-d′)bistriazole) with μ-OH- groups would significantly enhance the strength of O2 adsorption at the open metal sites without a corresponding increase in the N2 affinity. Experimental investigation of Co2Cl2(BBTA) and Co2(OH)2(BBTA) confirms that the former exhibits weak physisorption of both N2 and O2, whereas the latter is capable of chemisorbing O2 at room temperature in a highly selective manner. The O2 chemisorption behavior is attributed to the greater electron-donating character of the μ-OH- ligands and the presence of H-bonding interactions between the μ-OH- bridging ligands and the reduced O2 adsorbate.

AB - Metal-organic frameworks (MOFs) with coordinatively unsaturated metal sites are appealing as adsorbent materials due to their tunable functionality and ability to selectively bind small molecules. Through the use of computational screening methods based on periodic density functional theory, we investigate O2 and N2 adsorption at the coordinatively unsaturated metal sites of several MOF families. A variety of design handles are identified that can be used to modify the redox activity of the metal centers, including changing the functionalization of the linkers (replacing oxido donors with sulfido donors), anion exchange of bridging ligands (considering μ-Br-, μ-Cl-, μ-F-, μ-SH-, or μ-OH- groups), and altering the formal oxidation state of the metal. As a result, we show that it is possible to tune the O2 affinity at the open metal sites of MOFs for applications involving the strong and/or selective binding of O2. In contrast with O2 adsorption, N2 adsorption at open metal sites is predicted to be relatively weak across the MOF dataset, with the exception of MOFs containing synthetically elusive V2+ open metal sites. As one example from the screening study, we predicted that exchanging the μ-Cl- ligands of M2Cl2(BBTA) (H2BBTA = 1H,5H-benzo(1,2-d:4,5-d′)bistriazole) with μ-OH- groups would significantly enhance the strength of O2 adsorption at the open metal sites without a corresponding increase in the N2 affinity. Experimental investigation of Co2Cl2(BBTA) and Co2(OH)2(BBTA) confirms that the former exhibits weak physisorption of both N2 and O2, whereas the latter is capable of chemisorbing O2 at room temperature in a highly selective manner. The O2 chemisorption behavior is attributed to the greater electron-donating character of the μ-OH- ligands and the presence of H-bonding interactions between the μ-OH- bridging ligands and the reduced O2 adsorbate.

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Tuning the Redox Activity of Metal-Organic Frameworks for Enhanced, Selective O₂Binding: Design Rules and Ambient Temperature O₂Chemisorption in a Cobalt-Triazolate Framework

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