Evaluating the Robustness of Metal–Organic Frameworks for Synthetic Chemistry

Wang, Zihao; Bilegsaikhan, Arvin; Jerozal, Ronald T.; Pitt, Tristan; Milner, Phillip J.

doi:10.1021/acsami.1c01329

Cited by 49 publications

(77 citation statements)

References 70 publications

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“…4,[7][8][9][10][11][12] Despite challenges in MOF synthesis [13][14] and post-synthetic modification 15 , intense synthesis effort has led to rapid growth 16 in the number of reports of experimentally realized MOFs. MOFs with varying pore size, metals, and linker chemistry have demonstrated desirable properties for storage [17][18] , separations 7,19 , sensing [20][21] , conductivity [22][23][24] , and catalysis [25][26][27][28][29] . Most MOFs are formed with solvent present in their pores that must be removed for such applications.…”

Section: Introductionmentioning

confidence: 99%

“…Metal–organic frameworks (MOFs) have the potential to revolutionize catalysis and functional materials design due to their reticular nature and well-defined, isolated metal sites. , To meet numerous design criteria, an exhaustive search of MOFs must be carried out for each potential application, beyond the tens of MOFs that an experimentalist could synthesize. − The modularity of inorganic secondary building units (SBUs) and linkers that are the building blocks of MOFs have motivated the search for new materials via virtual high throughput screening (VHTS). ,− Despite challenges in MOF synthesis , and postsynthetic modification, intense synthesis effort has led to rapid growth in the number of reports of experimentally realized MOFs. MOFs with varying pore size, metals, and linker chemistry have demonstrated desirable properties for storage, , separations, , sensing, , conductivity, − and catalysis. − Most MOFs are formed with solvent present in their pores that must be removed for such applications. Although new methods for solvent removal have been developed to activate these materials, , many crystalline MOFs collapse upon activation, ,, rendering them unusable …”

Section: Introductionmentioning

confidence: 99%

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Using Machine Learning and Data Mining to Leverage Community Knowledge for the Engineering of Stable Metal–Organic Frameworks

2021

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Although the tailored metal active sites and porous architectures of MOFs hold great promise for engineering challenges ranging from gas separations to catalysis, a lack of understanding of how to improve their stability limits their use in practice. To overcome this limitation, we extract thousands of published reports of the key aspects of MOF stability necessary for their practical application: the ability to withstand high temperatures without degrading and the capacity to be activated by removal of solvent molecules. From nearly 4,000 manuscripts, we use natural language processing and automated image analysis to obtain over 2,000 solvent-removal stability measures and 3,000 thermal degradation temperatures. We analyze the relationships between stability properties and the chemical and geometric structures in this set to identify limits of prior heuristics derived from smaller sets of MOFs. By training predictive machine learning (ML, i.e., Gaussian process and artificial neural network) models to encode the structure-property relationships with graph-and pore-structure-based representations, we are able to make predictions of stability orders of magnitude faster than conventional physicsbased modeling or experiment. Interpretation of important features in ML models provides insights that we use to identify strategies to engineer increased stability into typically unstable 3d-containing MOFs that are frequently targeted for catalytic applications. We expect our approach to accelerate the time to discovery of stable, practical MOF materials for a wide range of applications.

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Section: Introductionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Using Machine Learning and Data Mining to Leverage Community Knowledge for the Engineering of Stable Metal–Organic Frameworks

2021

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“…35,36 In contrast to the wide study of amine-functionalized porous solids for CO2 capture, hydroxide-and alkoxide-functionalized porous solids remain remarkably understudied. 32 This may be due in part to the generally poor stability of traditional solid supports such as mesoporous silicas 37 and MOFs 38,39 towards OH − . Nonetheless, previous studies have shown that robust azolate MOFs bearing terminal M−OH (M = Zn, Ni, Co) sites can undergo selective and reversible reaction with CO2 to form metal-bound bicarbonates, akin to the enzyme carbonic anhydrase.…”

Section: Introductionmentioning

confidence: 99%

Carbon Dioxide Capture at Nucleophilic Hydroxide Sites in Oxidation-Resistant Cyclodextrin-Based Metal-Organic Frameworks

Zick

Pugh

Lee

et al. 2022

Preprint

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Carbon capture and utilization or sequestration (CCUS) from industrial point sources and direct air capture (DAC) are like-ly necessary to combat global climate change. Reducing the costs of CCUS and DAC requires next-generation sorbents ca-pable of reversible CO2 capture under realistic conditions. A particular challenge faced by amine-based sorbents—the current leading technology for carbon capture—is poor stability towards O2, which is present in high partial pressures in most emission streams of interest as well as in air. Sorbents containing oxygen-based nucleophiles, such as hydroxide (OH−), can reversibly react with CO2 to form (bi)carbonate (HCO3−) species and should display improved oxidative stabil-ities compared to amine-based materials. Here, we provide gas sorption, spectroscopic, and computational studies sup-porting that CO2 chemisorption in γ-cylodextrin-based metal-organic frameworks (CD-MOFs) occurs via HCO3− formation at nucleophilic OH− sites within the framework pores, rather than via previously proposed pathways involving carbonic acid or alkyl carbonate formation. Of the CD-MOFs studied herein, the new framework KHCO3 CD-MOF possesses rapid and high-capacity CO2 uptake, good thermal, oxidative, and cycling stabilities compared to previously reported materials, and selective CO2 capture under mixed gas conditions in dynamic breakthrough experiments. Because of its low cost and performance under realistic conditions, KHCO3 CD-MOF is a promising new platform for CCUS. More broadly, our work demonstrates that the encapsulation of reactive OH− sites within a porous framework represents a potentially general strategy for the design of oxidation-resistant adsorbents for carbon dioxide capture.

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“…After nearly two decades since the first report of Cr-MOF, there are still few Cr-MOFs. Furthermore, known low-connected Cr-MOFs have limited stability, especially in basic solution (stable only at pH ≤ 12). ,, …”

mentioning

confidence: 99%

“…Furthermore, known low-connected Cr-MOFs have limited stability, especially in basic solution (stable only at pH ≤ 12). 29,31,32 To make new Cr-MOFs with superior stability, going beyond currently known 6-connected Cr 3 O frameworks is a worthy pursuit. High-connected Cr-MOFs are expected to be difficult to crystallize, given what we know about lowconnected Cr-MOFs.…”

mentioning

confidence: 99%

Ultrastable High-Connected Chromium Metal–Organic Frameworks

et al. 2021

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State-of-the-art MOFs are generally known for chemical stability at one end of the pH scale (i.e., pH < 0 or pH > 14). Herein, we report new Cr-MOFs capable of withstanding extreme pH conditions across approximately 16 pH units from pH < 0 to pH > 14, likely the largest observed pH range for MOFs. The integration of multiple stability-enhancing factors including nonlabile Cr 3+ , mixed Cr−N and Cr−O cross-links, and the highest possible connectivity by Cr 3 O trimers enables extraordinary chemical stability confirmed by both PXRD and gas adsorption. Notably, the base stability is much higher than literature Cr-MOFs, thereby revitalizing Cr-MOF's viability in the pursuit for the most chemically stable MOFs. Among known cationic MOFs, the chemical stability of these new Cr-MOFs is unmatchable, to our knowledge. These Cr-MOFs can be developed into multiseries of isoreticular MOFs with a rich potential for functionalization, pore size, and pore geometry engineering and applications.

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Evaluating the Robustness of Metal–Organic Frameworks for Synthetic Chemistry

Cited by 49 publications

References 70 publications

Using Machine Learning and Data Mining to Leverage Community Knowledge for the Engineering of Stable Metal–Organic Frameworks

Using Machine Learning and Data Mining to Leverage Community Knowledge for the Engineering of Stable Metal–Organic Frameworks

Carbon Dioxide Capture at Nucleophilic Hydroxide Sites in Oxidation-Resistant Cyclodextrin-Based Metal-Organic Frameworks

Ultrastable High-Connected Chromium Metal–Organic Frameworks

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