We study the effect of counter-ion complexation on the example of Cl(-) ions interacting with the [Co(en)(3)](3+) complex. The H-bonding of the N-H groups of the ethylenediamine (en) ligands with the Cl(-) ions may lead to giant enhancement of the VCD intensity for the N-H stretches, but may also lead to VCD sign changes in the finger print region of N-H wagging, twisting and scissoring motions. Such sign changes should not be mistaken for signatures of the presence of the other enantiomer. We elucidate the mechanism for the sign changes and give a recommendation on how to deal with this problem. We also show that the experimental spectrum is only in good accord with the calculations if complexation of 5 Cl(-) ions (two axial, three equatorial) is assumed, but not with two (axial) or three (equatorial) Cl(-) ions, thus showing the potential of VCD to be used as an experimental probe for complexation.
A ketone's carbonyl carbon is electrophilic and harbors a part of the lowest unoccupied molecular orbital of the carbonyl group, resembling a Lewis acidic center; under the right circumstances it exhibits very useful chemical reactivity, although the natural electrophilicity of the ketone's carbonyl carbon is often not strong enough on its own to produce such reactivity. Quantum chemical calculations predict that a proton shared between a ketone and the Lewis basic solvent molecule (dioxane or THF) activates carbonyl carbon to the point of enabling a facile heterolytic splitting of H . Proton-catalyzed hydrogenation of a ketone in Lewis basic solvent is the result. The mechanism involves the interaction of H with the enhanced Lewis acidity of a carbonyl carbon and the free Lewis basic solvent molecule polarizes H and enables the hydride-type attack on carbonyl carbon, which is very strongly influenced by the proton shared between a ketone and solvent. The hydride-type attack on carbon is reminiscent of the splitting of H by singlet carbenes except that, in this case, a Lewis base from the surrounding environment (solvent) is necessary for polarization of H and acceptance of the proton resulting from the heterolytic splitting of H .
Using the 6,6'-dibromo-[1,1'-binaphthalene]-2,2'-diol molecule and its vibrational absorption (VA) and vibrational circular dichroism (VCD) spectra measured in deuterated dimethyl sulfoxide as example, we present a first detailed study of the effects induced in VCD spectra by the large-amplitude motions of solvent molecules loosely bound to a solute molecule. We show that this type of perturbation can induce significant effects in the VA and VCD spectra. We also outline a computational procedure that can effectively model the effects induced in the spectra and at the same time provide detailed structural information regarding the relative orientations of moieties involved in a solute-solvent molecular complex.
The
great potential of frustrated Lewis pairs (FLPs) as metal-free
catalysts for activation of molecular hydrogen has attracted increasing
interest as an alternative to transition-metal catalysts. However,
the complexity of FLP systems, involving the simultaneous interaction
of three molecules, impedes a detailed understanding of the activation
mechanism and the individual roles of the Lewis acid (LA) and Lewis
base (LB). In the present work, using density functional theory (DFT)
calculations, we examine the reactivity of 75 FLPs for the H
2
splitting reaction, including a series of experimentally investigated
LAs combined with conventional phosphine-based (
t
Bu
3
P) and oxygen-based (i.e., ethereal solvent) Lewis
bases. We find that the catalytic activity of the FLP is the result
of a delicate balance of the LA and LB strengths and their bulkiness.
The H
2
splitting reaction can be changed from endergonic
to exergonic by tuning the electrophilicity of the LA. Also, a more
nucleophilic LB results in a more stable ion pair product and a lower
barrier for the hydrogen splitting. The bulkiness of the LB leads
to an early transition state to reduce steric hindrance and lower
the barrier height. The bulkiness of the fragments determines the
cavity size in the FLP complex, and a large cavity allows for a larger
charge separation in the ion pair configuration. A shorter proton–hydride
distance in this product complex correlates with a stronger attraction
between the fragments, which forms more reactive ion pairs and facilitates
the proton and hydride donations in the subsequent hydrogenation process.
These insights may help with rationalizing the experimentally observed
reactivities of FLPs and with designing better FLP systems for hydrogenation
catalysis and hydrogen storage.
The
reaction between H2 and CO2 catalyzed
by an intramolecular frustrated Lewis pair, which is covalently bonded
to a UiO-66 metal–organic framework (MOF), is considered in
this work. Free energy surfaces (FESs) for this reaction are generated
throughout finite-temperature density functional theory (DFT) metadynamics
(MD) simulations. The simulated FESs indicate an alternative stepwise
pathway for the hydrogenation of CO2. Furthermore, indications
of weaker binding of CO2 than H2 to the Lewis
pair centers have been observed via metadynamics simulations. These
findings were unknown from the results of static-DFT calculations,
which proposed a concerted reduction of CO2. The results
of the present work may influence the design of new efficient heterogeneous Lewis
pair (LP)-functionalized MOFs to catalyze capture and conversion of
CO2 to high-value chemicals.
Enantiomeric excess (ee) in asymmetric catalysis may be strongly dependent on the solvent. The reaction product may range from an almost racemic mixture to an ee of over 90% for different solvents. We study this phenomenon for the C-C coupling reaction between nitromethane and benzaldehyde (the Henry reaction) with cinchona thiourea as the catalyst, where solvents that are strong Lewis bases induce a high ee. We show that the effect of the solvent does not consist of a change in the reaction mechanism. Instead, the solvation "prepares" the molecule, which is very flexible, in a specific conformation. The reaction barriers in this conformer are not lower than for other conformers, but are sufficiently differentiated between the enantiomers to give rise to a large ee. It is the strong Lewis basicity of the solvent that leads to the clear preference in solution for the "asymmetric" conformer. Although general rules or predictions for how solvent effects could be harnessed to produce a desired ee in general would be hard to formulate, this study does show that it is in this case (and presumably in many other cases as well) specific solute-solvent interactions rather than effects of the dielectric continuum of the solvent that are the root cause of the solvent effect. This is in agreement with experiment for the Henry reaction.
By using transition-state (TS) calculations, we examined how Lewis acid (LA) complexation activates carbonyl compounds in the context of hydrogenation of carbonyl compounds by H in Lewis basic (ethereal) solvents containing borane LAs of the type (C F ) B. According to our calculations, LA complexation does not activate a ketone sufficiently enough for the direct addition of H to the O=C unsaturated bond; but, calculations indicate a possibly facile heterolytic cleavage of H at the activated and thus sufficiently Lewis acidic carbonyl carbon atom with the assistance of the Lewis basic solvent (i.e., 1,4-dioxane or THF). For the solvent-assisted H splitting at the carbonyl carbon atom of (C F ) B adducts with different ketones, a number of TSs are computed and the obtained results are related to insights from experiment. By using the Born-Oppenheimer molecular dynamics with the DFT for electronic structure calculations, the evolution of the (C F ) B-alkoxide ionic intermediate and the proton transfer to the alkoxide oxygen atom were investigated. The results indicate a plausible hydrogenation mechanism with a LA, that is, (C F ) B, as a catalyst, namely, 1) the step of H cleavage that involves a Lewis basic solvent molecule plus the carbonyl carbon atom of thermodynamically stable and experimentally identifiable (C F ) B-ketone adducts in which (C F ) B is the "Lewis acid promoter", 2) the transfer of the solvent-bound proton to the oxygen atom of the (C F ) B-alkoxide intermediate giving the (C F ) B-alcohol adduct, and 3) the S 2-style displacement of the alcohol by a ketone or a Lewis basic solvent molecule.
Knowing that the Papai's electron transfer (ET) and the Grimme's electric field (EF) models draw attention to somewhat different physical aspects, we are going to systematically (re)examine interactions in the transition states (TSs) of the heterolytic H-cleavage by the Frustrated Lewis Pairs (FLPs). Our main vehicle is the quantitative energy decomposition analysis (EDA), a powerful method for elucidation of interactions, plus the analysis of molecular orbitals (MOs). Herein, the Lewis acid (LA) is B(CF) and the Lewis bases (LBs) are tBuP, ( o-CHMe)P, 2,6-lutidine, 2,4,6-lutidine, MeN═C(Ph)Me imine, MeN(H)-C(H)PhMe amine, THF, 1,4-dioxane, and acetone. For a series of the phosphorus-, nitrogen-, and oxygen-bearing LBs plus B(CF), we will show that (i) neither the electrostatic nor the orbital interactions dominate but instead both are essential alongside the Pauli repulsion and (ii) the frontier molecular orbitals (FMOs) of a TS can arise not only from the "push-pull" molecular orbital scheme by Papai et al., which directly involves the occupied σ and the empty σ* MOs of H, but also from a more intricate but energetically more fitting orbital interactions which have escaped notice thus far.
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.