Production of 1-butene, a major monomer in polymer industry, is dominated by homogeneous protocols via ethylene dimerization. Homogeneous catalysts can achieve high selectivity but require large amounts of activators and solvents, and exhibit poor recyclability; in turn, heterogeneous systems are robust but lack selectivity. Here we show how the precise engineering of metal–organic frameworks (MOFs) holds promise for a sustainable process. The key to the (Ru)HKUST-1 MOF activity is the intrapore reactant condensation that enhances ethylene dimerization with high selectivity (> 99% 1-butene) and high stability (> 120 h) in the absence of activators and solvents. According to spectroscopy, kinetics, and modeling, the engineering of defective nodes via controlled thermal approaches rules the activity, while intrapore ethylene condensation accounts for selectivity and stability. The combination of well-defined actives sites with the concentration effect arising from condensation regimes paves the way toward the development of robust MOF catalysts for diverse gas-phase reactions.
Solid-state crystallization achieves selective confinement of metal-organic framework (MOF) nanocrystals within mesoporous materials, thereby rendering active sites more accessible compared to the bulk-MOF and enhancing the chemical and mechanical stability of MOF nanocrystals. (Zr)UiO-66(NH )/SiO hybrid materials were tested as efficient and reusable heterogeneous catalysts for the synthesis of steroid derivatives, outperforming the bulk (Zr)UiO-66(NH ) MOF. A clear correlation between the catalytic activity of the dispersed Zr sites present in the confined MOF, and the loading of the mesoporous SiO , is demonstrated for steroid transformations.
We characterized the mechanism and pharmacodynamics of five structurally distinct inhibitors of d-amino acid oxidase. All inhibitors bound the oxidized form of human enzyme with affinity slightly higher than that of benzoate (Kd ≈ 2-4 μM). Stopped-flow experiments showed that pyrrole-based inhibitors possessed high affinity (Kd ≈ 100-200 nM) and slow release kinetics (k < 0.01 s(-1)) in the presence of substrate, while inhibitors with pendent aromatic groups altered conformations of the active site lid, as evidenced by X-ray crystallography, and showed slower kinetics of association. Rigid bioisosteres of benzoic acid induced a closed-lid conformation, had slower release in the presence of substrate, and were more potent than benzoate. Steady-state d-serine concentrations were described in a PK/PD model, and competition for d-serine sites on NMDA receptors was demonstrated in vivo. DAAO inhibition increased the spatiotemporal influence of glial-derived d-serine, suggesting localized effects on neuronal circuits where DAAO can exert a neuromodulatory role.
A methodology
is introduced for controlled postsynthetic thermal defect engineering
(TDE) of precious group metal–organic frameworks (PGM-MOFs).
The case study is based on the Ru/Rh analogues of the archetypical
structure [Cu3(BTC)2] (HKUST-1; BTC = 1,3,5-benzenetricarboxylate).
Quantitative monitoring of the TDE process and extensive characterization
of the samples employing a complementary set of analytical and spectroscopic
techniques reveal that the compositionally very complex TDE-MOF materials
result from the elimination and/or fragmentation of ancillary ligands
and/or linkers. TDE involves the preferential secession of acetate
ligands, intrinsically introduced via coordination modulation during
synthesis, and the gradual decarboxylation of ligator sites of the
framework linker BTC. Both processes lead to modified Ru/Rh paddlewheel
nodes. These nodes exhibit a lowered average oxidation state and more
accessible open metal centers, as deduced from surface-ligand IR spectroscopy
using CO as a probe and supported by density functional theory (DFT)-based
computations. The monometallic and the mixed-metal PGM-MOFs systematically
differ in their TDE properties and, in particular in the hydride generation
ability (HGA). This latter property is an important indicator for
the catalytic activity of PGM-MOFs, as demonstrated by the ethylene
dimerization reaction to 1-butene.
scite is a Brooklyn-based organization that helps researchers better discover and understand research articles through Smart Citations–citations that display the context of the citation and describe whether the article provides supporting or contrasting evidence. scite is used by students and researchers from around the world and is funded in part by the National Science Foundation and the National Institute on Drug Abuse of the National Institutes of Health.