Non‐biological catalysts following the governing principles of enzymes are attractive systems to disclose unprecedented reactivities. Most of those existing catalysts feature an adaptable molecular recognition site for substrate binding that are prone to undergo conformational selection pathways. Herein, we present a non‐biological catalyst that is able to bind substrates via the induced fit model according to in‐depth computational calculations. The system, which is constituted by an inflexible substrate‐recognition site derived from a zinc‐porphyrin in the second coordination sphere, features destabilization of ground states as well as stabilization of transition states for the relevant iridium‐catalyzed C−H bond borylation of pyridine. In addition, this catalyst appears to be most suited to tightly bind the transition state rather than the substrate. Besides these features, which are reminiscent of the action modes of enzymes, new elementary catalytic steps (i. e. C−B bond formation and catalyst regeneration) have been disclosed owing to the unique distortions encountered in the different intermediates and transition states.
Selective
iridium-catalyzed C–H bond borylations of unbiased
or directing-group-free substrates typically occur under long reaction
times and mild temperatures in order to avoid unselective processes
including catalyst deactivation. Herein, we describe a supramolecular
approach that enables the C–H bond borylation of challenging
pyiridines and imidazoles in very short reaction times (up to 2 h)
with a negligible incubation period for catalyst activation. The catalyst
is based on a highly rigid zinc–porphyrin substrate-recognition
site in the secondary coordination sphere and a triazolopyridine chelating
fragment attached to the first coordination sphere at iridium. The
borylation occurs at the C–H bond from the substrate located
at four chemical bonds apart from the molecular recognition site with
the selectivity being exclusively imposed by the distance between
the active site and the molecular recognition site regardless of the
nature of the N,N-chelating fragment
coordinating to iridium as further supported by density functional
theory (DFT) calculations. Additional studies (control experiments,
nuclear magnetic resonance, and single-crystal X-ray diffraction)
unraveled key catalyst deactivation pathways in which up to three
different partners (water, methoxide ligands from the iridium precursor,
and the triazolopyridine fragment) compete with the N-heterocycle
substrate for binding to the molecular recognition site of the supramolecular
catalyst. This fundamental understanding made possible the identification
of a supramolecular catalyst featuring a 4-methyl substitution pattern
in the first coordination sphere at iridium that provides a suitable
balance of steric and electronic effects in both primary and secondary
coordination spheres, thereby bypassing the manifold catalyst deactivation
pathways. DFT calculations further indicated the importance of noncovalent
interactions beyond the molecular recognition site on the stabilization
of the different intermediates and transition sates.
Poly (vinyl ethers) are compounds with great value in the coating industry due to exhibiting properties such as high viscosity, soft adhesiveness, resistance to saponification and solubility in water and organic solvents. However, the main challenge in this field is the synthesis of vinyl ether monomers that can be synthetized by methodologies such as vinyl transfer, reduction of vinyl phosphate ether, isomerization, hydrogenation of acetylenic ethers, elimination, addition of alcohols to alkyne species etc. Nevertheless, the most successful strategy to access to vinyl ether derivatives is the addition of alcohols to alkynes catalyzed by transition metals such as molybdenum, tungsten, ruthenium, palladium, platinum, gold, silver, iridium and rhodium, where gold-NHC catalysts have shown the best results in vinyl ether synthesis. Recently, the hydrophenoxylation reaction was found to proceed through a digold-assisted process where the species that determine the rate of the reaction are PhO-[Au(IPr)] and alkyne-[Au(IPr)]. Later, the improvement of the hydrophenoxylation reaction by using a mixed combination of Cu-NHC and Au-NHC catalysts was also reported. DFT studies confirmed a cost-effective method for the hydrophenoxylation reaction and located the rate-determining step, which turned out to be quite sensitive to the sterical hindrance due to the NHC ligands.
The cis-trans isomerization of (thio)amides was studied by DFT calculations to get the model for the higher preference for the cis conformation by guided predictive analyses, suggesting how to select...
Nanoscale control of chemical reactivity, manipulation of reaction pathways, and ultimately driving the outcome of chemical reactions are quickly becoming reality. A variety of tools are concurring to establish such capability. The confinement of guest molecules inside nanoreactors, such as the hollow nanostructures of carbon nanotubes (CNTs), is a straightforward and highly fascinating approach. It mechanically hinders some molecular movements but also decreases the free energy of translation of the system with respect to that of a macroscopic solution. Here, we examined, at the quantum mechanics/molecular mechanics (QM/MM) level, the effect of confinement inside CNTs on nucleophilic substitution (SN2) and elimination (syn-E2 and anti-E2) using as a model system the reaction between ethyl chloride and chloride. Our results show that the three reaction mechanisms are kinetically and thermodynamically affected by the CNT host. The size of the nanoreactor, i.e., the CNT diameter, represents the key factor to control the energy profiles of the reactions. A careful analysis of the interactions between the CNTs and the reactive system allowed us to identify the driving force of the catalytic process. The electrostatic term controls the reaction kinetics in the SN2 and syn/anti-E2 reactions. The van der Waals interactions play an important role in the stabilization of the product of the elimination process.
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