Zhenzi Yu scite author profile

The separation of xenon/krypton (Xe/Kr) mixtures is a challenging process. Many porous materials allow the adsorption of both Xe and Kr but only with low selectivity. Anion-pillared metal–organic frameworks (MOFs), featuring the anion groups as structural pillars, show potential in gas separations, but only a limited number of them have been synthesized. Here, we describe a collection of 936 anion-pillared MOFs based on 22 experimentally available structures. We performed density functional theory (DFT) optimization and then assigned density-derived electrostatic and chemical (DDEC) charges for each MOF to make them well suited to molecular simulations. The structural properties of the MOFs vary more strongly with the choice of the organic ligand than with other aspects like fluorine groups and metal centers. We then screened the entire collection of MOFs in the context of Xe/Kr separation at room temperature. Compared with previously reported MOFs, the interpenetrated MOF SIFSIX-6-Cd-i is predicted to perform better for Xe/Kr separations, with a good balance between working capacity (1.62 mmol/g) and separation selectivity (16.4) at 298 K and 100 kPa. We also found that the heterogeneity of fluorine groups within a MOF can help to enhance Xe working capacity without reducing the Xe/Kr selectivity, suggesting that synthesis of anion-pillared MOFs with mixed fluorine groups may lead to improved Xe/Kr separation performance.

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Interpretable Machine Learning-Based Predictions of Methane Uptake Isotherms in Metal–Organic Frameworks

Gurnani

Kim

et al. 2021

Chem. Mater.

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Tuning the structure of metal–organic frameworks (MOFs) is a promising pathway toward the development of high-performing materials for methane storage. To aid such discoveries, we introduce techniques for the machine-learned prediction of methane isotherms in MOFs. We demonstrate that our predictors surpass prior benchmarks. We use these models to search for novel (from both a structural and chemical point of view), high-performing MOFs and test them using density functional theory (DFT)-based structural relaxation and molecular simulation of methane adsorption. These simulations reveal that our model generalizes to chemistries not seen during training. One novel candidate, predicted to surpass the 2008 world record for volumetric methane uptake in MOFs, is proposed. Our simulations also reveal that DFT relaxation has a systematic effect on the uptake value. Finally, we interpret the models to discover and present potential MOF–methane uptake structure–property relationships.

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Incorporating Flexibility Effects into Metal–Organic Framework Adsorption Simulations Using Different Models

Anstine

Boulfelfel

et al. 2021

ACS Appl. Mater. Interfaces

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High-throughput calculations based on molecular simulations to predict the adsorption of molecules inside metal–organic frameworks (MOFs) have become a useful complement to experimental efforts to identify promising adsorbents for chemical separations and storage. For computational convenience, all existing efforts of this kind have relied on simulations in which the MOF is approximated as rigid. In this paper, we use extensive adsorption–relaxation simulations that fully include MOF flexibility effects to explore the validity of the rigid framework approximation. We also examine the accuracy of several approximate methods to incorporate framework flexibility that are more computationally efficient than adsorption–relaxation calculations. We first benchmark various models of MOF flexibility for four MOFs with well-established CO2 experimental consensus isotherms. We then consider a range of adsorption properties, including Henry’s constants, nondilute loadings, and adsorption selectivity, for seven adsorbates in 15 MOFs randomly selected from the CoRE MOF database. Our results indicate that in many MOFs adsorption–relaxation simulations are necessary to make quantitative predictions of adsorption, particularly for adsorption at dilute concentrations, although more standard calculations based on rigid structures can provide useful information. Finally, we investigate whether a correlation exists between the elastic properties of empty MOFs and the importance of including framework flexibility in making accurate predictions of molecular adsorption. Our results did not identify a simple correlation of this type.

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Effect of Loading on the Water Stability of the Metal–Organic Framework DMOF-1 [Zn(bdc)(dabco)_0.5]

Chen

Sholl

et al. 2022

J. Phys. Chem. Lett.

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In this work, the degradation of the metal–organic framework (MOF) DMOF-1 as a function of water adsorption was investigated. As the quantity of water vapor adsorbed by DMOF-1 increases, degradation of the MOF from hydrolysis accelerates. Degradation was attributed to clustering of water molecules in the void space of DMOF-1, as seen in NVT Monte Carlo simulations. Our molecular simulations strongly suggest that degradation of DMOF-1 by water is driven by water adsorption at defect sites in the MOF. Interestingly, it was observed that DMOF-1 can remain stable if it adsorbs less water than the 1 mmol/g necessary to initiate degradation within the framework. Even though the rate of hydrolysis increases at higher temperatures, the degradation threshold for DMOF-1 remains 1 mmol/g regardless of temperature. This suggests that at sufficiently elevated temperatures (above ∼50 °C) DMOF-1 is stable toward water vapor at all relative humidities.

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Enhancing enzymatic hydrolysis of corn cob, corn stover and sorghum stalk by dilute aqueous ammonia combined with ultrasonic pretreatment

Zhao

et al. 2017

Industrial Crops and Products

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Zhenzi Yu

Construction of an Anion-Pillared MOF Database and the Screening of MOFs Suitable for Xe/Kr Separation

Interpretable Machine Learning-Based Predictions of Methane Uptake Isotherms in Metal–Organic Frameworks

Incorporating Flexibility Effects into Metal–Organic Framework Adsorption Simulations Using Different Models

Effect of Loading on the Water Stability of the Metal–Organic Framework DMOF-1 [Zn(bdc)(dabco)_0.5]

Enhancing enzymatic hydrolysis of corn cob, corn stover and sorghum stalk by dilute aqueous ammonia combined with ultrasonic pretreatment

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Zhenzi Yu

Construction of an Anion-Pillared MOF Database and the Screening of MOFs Suitable for Xe/Kr Separation

Interpretable Machine Learning-Based Predictions of Methane Uptake Isotherms in Metal–Organic Frameworks

Incorporating Flexibility Effects into Metal–Organic Framework Adsorption Simulations Using Different Models

Effect of Loading on the Water Stability of the Metal–Organic Framework DMOF-1 [Zn(bdc)(dabco)0.5]

Enhancing enzymatic hydrolysis of corn cob, corn stover and sorghum stalk by dilute aqueous ammonia combined with ultrasonic pretreatment

Contact Info

Product

Resources

About

Effect of Loading on the Water Stability of the Metal–Organic Framework DMOF-1 [Zn(bdc)(dabco)_0.5]