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1. Molecular driving forces for water adsorption in MOF-808: A comparative analysis with UiO-66

   https://doi.org/10.1063/5.0189569  

   Frank, Hilliary O; Paesani, Francesco (March 2024, The Journal of Chemical Physics)

   Metal–organic frameworks (MOFs), with their unique porous structures and versatile functionality, have emerged as promising materials for the adsorption, separation, and storage of diverse molecular species. In this study, we investigate water adsorption in MOF-808, a prototypical MOF that shares the same secondary building unit (SBU) as UiO-66, and elucidate how differences in topology and connectivity between the two MOFs influence the adsorption mechanism. To this end, molecular dynamics simulations were performed to calculate several thermodynamic and dynamical properties of water in MOF-808 as a function of relative humidity (RH), from the initial adsorption step to full pore filling. At low RH, the μ3-OH groups of the SBUs form hydrogen bonds with the initial water molecules entering the pores, which triggers the filling of these pores before the μ3-OH groups in other pores become engaged in hydrogen bonding with water molecules. Our analyses indicate that the pores of MOF-808 become filled by water sequentially as the RH increases. A similar mechanism has been reported for water adsorption in UiO-66. Despite this similarity, our study highlights distinct thermodynamic properties and framework characteristics that influence the adsorption process differently in MOF-808 and UiO-66. 

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2. Exploring the Effect of Framework Flexibility on Water Adsorption in the Metal–Organic Framework NbOFFIVE-1-Ni Using Molecular Modeling

   https://doi.org/10.1021/acs.jpcc.4c04486  

   Daglar, Hilal; Keskin, Seda; Snurr, Randall Q (November 2024, The Journal of Physical Chemistry C)

   Many metal-organic frameworks (MOFs) are known to show complex structural flexibility such as breathing, swelling, and linker rotations, and understanding the impact of these structural changes on their guest adsorption properties is important in developing MOFs for practical applications. In this study, we used a multi-scale computational approach to provide a molecular-level understanding of how flexibility affects water adsorption in the MOF, NbOFFIVE-1-Ni. This material has narrow pores and good hydrothermal stability, which make it attractive for CO2 capture. We utilized density functional theory (DFT) calculations and grand canonical Monte Carlo (GCMC) simulations to study the impact of NbOFFIVE-1-Ni structural flexibility on its water adsorption at different humidity conditions. Studying the water adsorption in different configurations of NbOFFIVE-1-Ni demonstrated that DFT optimization in the presence of adsorbed water molecules and rotating the linkers are useful strategies to mimic its structural flexibility. Our results illustrate the significance of taking structural flexibility into account when designing MOFs for water adsorption and other relevant applications. 

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3. Enhanced Thermal Conductivity in a Diamine-Appended Metal–Organic Framework as a Result of Cooperative CO ₂ Adsorption

   https://doi.org/10.1021/acsami.0c10233  

   Babaei, Hasan; Lee, Jung-Hoon; Dods, Matthew N.; Wilmer, Christopher E.; Long, Jeffrey R. (September 2020, ACS Applied Materials & Interfaces)

   Diamine-appended variants of the metal–organic framework M2(dobpdc) (M = Mg, Mn, Fe, Co, Zn; dobpdc4– = 4,4′-dioxidobiphenyl-3,3′-dicarboxylate) exhibit exceptional CO2 capture properties owing to a unique cooperative adsorption mechanism, and thus hold promise for use in the development of energy- and cost-efficient CO2 separations. Understanding the nature of thermal transport in these materials is essential for such practical applications, however, as temperature rises resulting from exothermic CO2 uptake could potentially offset the energy savings offered by such cooperative adsorbents. Here, molecular dynamics (MD) simulations are employed in investigating thermal transport in bare and e-2-appended Zn2(dobpdc) (e-2 = N-ethylethylenediamine), both with and without CO2 as a guest. In the absence of CO2, the appended diamines function to enhance thermal conductivity in the ab-plane of e-2–Zn2(dobpdc) relative to the bare framework, as a result of noncovalent interactions between adjacent diamines that provide additional heat transfer pathways across the pore channel. Upon introduction of CO2, the thermal conductivity along the pore channel (the c-axis) increases due to the cooperative formation of metal-bound ammonium carbamates, which serve to create additional heat transfer pathways. In contrast, the thermal conductivity of the bare framework remains unchanged in the presence of zinc-bound CO2 but decreases in the presence of additional adsorbed CO2. 

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4. Active learning for efficient navigation of multi-component gas adsorption landscapes in a MOF

   https://doi.org/10.1039/D3DD00106G  

   Mukherjee, Krishnendu; Osaro, Etinosa; Colón, Yamil J. (October 2023, Digital Discovery)

   In recent decades, metal–organic frameworks (MOFs) have gained recognition for their potential in multicomponent gas separations. Though molecular simulations have revealed structure–property relationships of MOF–adsorbate systems, they can be computationally expensive and there is a need for surrogate models that can predict the adsorption data faster. In this work, an active learning (AL) protocol is introduced that can predict multicomponent gas adsorption in a MOF for a range of thermodynamic conditions. This methodology is applied to build a model for the adsorption of three different gas mixtures (CO2–CH4, Xe–Kr, and H2S–CO2) in the MOF Cu-BTC. A Gaussian process regression (GPR) model is used to fit the data as well to leverage its predicted uncertainty to drive the learning. The training data is generated using grand-canonical Monte Carlo (GCMC) simulations as points are iteratively added to the model to minimize the predicted uncertainty. Also, a criteria which captures the perceived performance of the GPs is introduced to terminate the AL process when the perceived accuracy threshold is met. The three systems are tested for a pressure–mole fraction (P–X), and a pressure–mole fraction–temperature (P–X–T) feature space. It is demonstrated that AL one only needs a fraction of the data from simulations to build a reliable surrogate model for predicting mixture adsorption. Further, the final GP fit from AL outperforms ideal adsorbed solution theory predictions. 

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5. Using Phosphonic Acid Monolayers to Control CO ₂ Adsorption and Hydrogenation on Pt/Al ₂ O ₃

   https://doi.org/10.1002/cctc.202400451  

   Blanchette, Zachary; Zhou, Xinpei; Schwartz, Daniel_K; Medlin, J_Will (August 2024, ChemCatChem)

   Abstract Phosphonic acid (PA) self‐assembled monolayers (SAMs) were deposited onto Pt/Al₂O₃catalysts to modify the support to enable control over CO₂adsorption and CO₂hydrogenation activity. Significant differences in catalytic activity toward CO₂hydrogenation (reverse water‐gas shift, RWGS) were observed after coating Al₂O₃with PAs, suggesting that the reaction was mediated by CO₂adsorption on the support. Amine‐functionalized PAs were found to outperform their alkyl counterparts in terms of activity, however there was little effect of amine location in the SAM (i. e., spacing between the amine functional group and phosphonate attachment group). One amine‐PA and one alkyl‐PA, aminopropyl phosphonic acid (C₃NH₂PA) and methyl phosphonic acid (C₁PA), respectively, were investigated in more detail. The C₃NH₂PA‐modified catalyst was found to bind CO₂as a combination of carbamate and bicarbonate. Additionally, at 30 °C, both PAs were found to reduce CO₂adsorption uptake by approximately 50 % compared to unmodified 5 %Pt/Al₂O₃. CO₂adsorption enthalpy was measured for the catalysts and found to be strongly correlated with hydrogenation activity, with the trend in binding enthalpy and CO₂hydrogen rate trending as uncoated >C₃NH₂PA>C₁PA. PA SAMs were found to have weaker effects on CO binding and CO selectivity, consistent with selective modification of the Al₂O₃support by the PAs. 

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