Ac omprehensive model to describe the water stability of prototypical metal-organic frameworks (MOFs) is derivedby combining different types of theoretical and experimental approaches. The resultsp rovide an insight into the early stages of water-triggered destabilization of MOFs and allow detailed pathways to be proposed for the degradation of different MOFs under aqueous conditions. The essential elements of the approach are computing the pK a values of coordinated water molecules and geometry relaxations. Variable-temperature and pH infrared spectroscopy techniques are used to corroborate the main findings. The model developed herein helpst oe xplain stabilityl imits ob-servedf or severalp rototypical MOFs, including MOF-5, HKUST-1, UiO-66, and MIL-101-Cr,i na queouss olutions,a nd thus, providesa ni nsighti nto the possible degradation pathways in acidic and basic environments. The formation of a metalh ydroxide through the autoprotolysis of metal-coordinated water molecules and the strength of carboxylatemetali nteractions are suggested to be two key players that govern stability in basic and acidic media, respectively.T he methodology presentedh erein can effectivelyg uide future efforts, which are especially significantf or in silico screening, for developing novel MOFs with enhanced aqueous stability.[a] M.Supporting information and the ORCID identification number(s) for the author(s) of this article can be found under: https://doi.
The remarkable water stability of Zr-carboxylatebased metal−organic frameworks (MOFs) stimulated considerable interest toward their utilization in aqueous phase applications. The origin of such stability is probed here through pH titration and pK a modeling. A unique feature of the Zr 6 (μ 3 -OH) 4 (μ 3 -O) 4 (RCO 2 ) 12 cluster is the Zr-bridging oxo/hydroxyl groups, demonstrating several pK a values that appear to provide for the water stability at a wide range of pH. Accordingly, the tunability of the cage/surface charge of the MOF can feasibly be controlled through careful adjustment of solution pH. Such high stability, and facile control over cage/surface charge, can additionally be augmented through introducing chemical functionalities lining the cages of the MOF, specifically amine groups in the UiO-66-NH 2 presented herein. The variable protonation states of the Zr cluster and the pendant amino groups, their H-bond donor/acceptor characteristics, and their electrostatic interactions with guest molecules were effectively utilized in controlled experiments to demonstrate high uptake of model guest molecules (137 mg/g for Cr(VI), 1275 mg/g for methylene blue, and 909 mg/g for methyl orange). Additionally, a practical form of the silica-supported MOF, UiO-66-NH 2 @SiO 2 , constructed in under 2 h reaction time, is described, generating a true platform microporous sorbent for practical use in demanding applications.
The point-of-charge (PoC) approach was employed to investigate the characteristics of the tetrel bond from an electrostatic perspective. W-T-XYZ···B nomenclature was suggested where T is a tetrel atom, W is the atom along the σ-hole extension, B is a Lewis base, and X, Y, and Z are three atoms on the same side of the σ-hole. Quantum-mechanical calculations were carried out on F-T-F systems (where T = C, Si, Ge, or Sn) at the MP2/aug-cc-pVTZ level of theory, with PP functions for Ge and Sn atoms. The tetrel bond strength was estimated via the molecular stabilization energy. Tetrel bond strength was found to increase with increasing PoC negativity (i.e., Lewis basicity) and the electronegativity of the W atom. Moreover, the effects of the T···PoC distance, the W-T···PoC angle, and the aqueous medium on the tetrel bond strength were also investigated. Correlations between tetrel bond strength and several atomic and molecular descriptors such as the natural charge on the tetrel atom, E, and the p-orbital contribution to W-T bond hybridization were observed. Contrary to expectations, the tetrel bond strength in F-C-X increased as the electronegativity of X decreased. The σ-node criteria for the studied molecules were also introduced and discussed. The ability of these molecules to simultaneously form more than one tetrel bond was examined via the σ-hole test. In conclusion, the tetrel bond strength was found to be governed by the strengths of (i) the attractive electrostatic interaction of the Lewis base with the σ-hole, (ii) the attractive/repulsive interaction between the Lewis base and the X, Y, and Z atoms, and (iii) the van der Waals interaction between the Lewis base and the X, Y, and Z atoms. Graphical Abstract Characterization of tetrel bond using the Point-of-Charge (PoC) approach.
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