Chemistry of Intermolecular Frustrated Lewis Pairs in Motion: Emerging Perspectives and Prospects

2016

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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 .

Section: Figurementioning

confidence: 99%

mentioning

confidence: 99%

A Prediction of Proton‐Catalyzed Hydrogenation of Ketones in Lewis Basic Solvent through Facile Splitting of Hydrogen Molecules

2016

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“…According to the literature, it is not quite certain what the rate‐limiting step is in the thus far computed reaction profiles involving Brønsted acid activation/catalysis . For a comparison of the TS calculations describing competing reaction pathways of the FLP activation of H 2 , significant uncertainties can be expected to arise from the non‐static (fluid) nature of 1) interactions of solvent molecules with the ionic intermediate A2 and 2) interactions of the solvated ketone with the ionic intermediate B2 . The latter is particularly important because intermediates alike B2 are regarded as plausible source of the activated proton and hydride for hydrogenation (reduction) of the solvated substrate.…”

Section: Introductionmentioning

confidence: 96%

Carbonyl Activation by Borane Lewis Acid Complexation: Transition States of H₂ Splitting at the Activated Carbonyl Carbon Atom in a Lewis Basic Solvent and the Proton‐Transfer Dynamics of the Boroalkoxide Intermediate

2017

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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.

“…In the reported TSs of this reaction, H 2 is polarized by LA and LB into H (δ−) −H (δ+) state with the hydride‐like H (δ−) and the proton‐like H (δ+) atoms . Typically in the reaction given in Equation (1), LAs are boranes with electron‐withdrawing substituents, that is, B(C 6 F 5 ) 3− n (C 6 Cl 5 ) n with n =0–3, in combination with phosphine LB species, as imines/amines, or carbonyl compounds and ethers with nitrogen or oxygen atoms as sufficiently potent LB centers .…”

Section: Introductionmentioning

confidence: 99%

Theory‐Based Extension of the Catalyst Scope in the Base‐Catalyzed Hydrogenation of Ketones: RCOOH‐Catalyzed Hydrogenation of Carbonyl Compounds with H₂ Involving a Proton Shuttle

2017

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As an extension of the reaction mechanism describing the base-catalyzed hydrogenation of ketones according to Berkessel et al., we use a standard methodology for transition-state (TS) calculations in order to check the possibility of heterolytic cleavage of H at the ketone's carbonyl carbon atom, yielding one-step hydrogenation path with involvement of carboxylic acid as a catalyst. As an extension of the catalyst scope in the base-catalyzed hydrogenation of ketones, our mechanism involves a molecule with a labile proton and a Lewis basic oxygen atom as a catalyst-for example, R-C(=O)OH carboxylic acids-so that the heterolytic cleavage of H could take place between the Lewis basic oxygen atom of a carboxylic acid and the electrophilic (Lewis acidic) carbonyl carbon of a ketone/aldehyde. According to our TS calculations, protonation of a ketone/aldehyde by a proton shuttle (hydrogen bond) facilitates the hydride-type attack on the ketone's carbonyl carbon atom in the process of the heterolytic cleavage of H . Ketones with electron-rich and electron-withdrawing substituents in combination with a few carboxylic and amino acids-in total, 41 substrate-catalyst couples-have been computationally evaluated in this article and the calculated reaction barriers are encouragingly moderate for many of the considered substrate-catalyst couples.