Hydride shifts reactions with carbonyl compounds

How does structure determine organic reactivity, 35, 67 Hydrated electrons, reactions of, with organic compounds, 7,115 Hydration, reversible, of carbonyl compounds, 4, 1 Hydride shifts and transfers, 24, 57... 

The classic Hieber-base reaction 16 is that of a hydroxide with metal carbonyls, which proceeds by nucleophilic attack of the hydroxide at a carbon atom of a carbonyl ligand to give a carboxy group or consequently carbon dioxide and a metal hydride.17 Metal carbonyls are catalysts for the water-gas shift reaction.18 Pentacarbonyl(tetrafluoroborato)rhenium reacts with alkali hydroxide in a similar way however, due to the coordinatively unsaturated nature of the [Re(CO)5]+ group polynuclear compounds are formed.15... 

In the past, this field has been dominated by ruthenium, rhodium and iridium catalysts with extraordinary activities and furthermore superior enantioselectivities however, some investigations were carried out with iron catalysts. Early efforts were reported on the successful use of hydridocarbonyliron complexes HFcm(CO) as reducing reagent for a, P-unsaturated carbonyl compounds, dienes and C=N double bonds, albeit complexes were used in stoichiometric amounts [7]. The first catalytic approach was presented by Marko et al. on the reduction of acetone in the presence of Fe3(CO)12 or Fe(CO)5 [8]. In this reaction, the hydrogen is delivered by water under more drastic reaction conditions (100 bar, 100 °C). Addition of NEt3 as co-catalyst was necessary to obtain reasonable yields. The authors assumed a reaction of Fe(CO)5 with hydroxide ions to yield H Fe(CO)4 with liberation of carbon dioxide since basic conditions are present and exclude the formation of molecular hydrogen via the water gas shift reaction. H Fe(CO)4 is believed to be the active catalyst, which transfers the hydride to the acceptor. The catalyst presented displayed activity in the reduction of several ketones and aldehydes (Scheme 4.1) [9]. 

How does structure determine organic reactivity, 35, 67 Hydrated electrons, reactions of, with organic compounds, 7,1 15 Hydration, reversible, of carbonyl compounds, 4, 1 Hydride shifts and transfers, 24, 57 Hydrocarbons, small-ring, gas-phase pyrolysis of, 4, 147 Hydrogen atom abstraction from O—H bonds, 9, 127 Hydrogen bonding and chemical reactivity, 26, 255 Hydrogen isotope effects in aromatic substitution reactions. 2, 163... 

This homologation reaction most likely proceeds via nucleophilic addition of the diazo compound to the Lewis acid complexed carbonyl, followed by 1,2-alkyl migration with concomitant loss of N2. Application of this reaction to an aldehyde (168) gives, via 1,2-hydride shift, the corresponding P-keto ester (169 equation 70). ... 

Evidence for the presence of organic cations was provided by bright red or purple colors observed immediately upon addition of the carbonyl compounds to the catalyst-aromatic mixtures, and by isolation of side products derived from hydride shifts to intermediate carbonium ions. Mechanistically, these reactions are visualized as proceeding by initial Bideal-like attack of aromatic on the adsorbed conjugate acid derived from the carbonyl compound, with the formation of an intermediate tert-benzylic carbinol ... 

Lewis acid complexes of p-substituted a,p-unsaturated ketones and aldehydes are unreactive toward alkenes. Crotonaldehyde and 3-penten-2-one can not be induced to undergo ene reactions as acrolein and MVK do. 34 The presence of a substituent on the p-carbon stabilizes the enal- or enone-Lewis acid complex and sterically retards the approach of an alkene to the p-carbon. However, we have found that a complex of these ketones and aldehydes with 2 equivalents of EtAlQ2 reacts reversibly with alkenes to give a zwitterion. 34 This zwitterion, which is formed in the absence of a nucleophile, reacts reversibly to give a cyclobutane or undergoes two 1,2-hydride or alkyl shifts to irreversibly generate a p,p-disubstituted-o,p-unsaturated carbonyl compound (see Figure 19). The intermolecular addition of an enone, as an electrophile, to an alkene has been observed only rarely. The specific termination of the reaction by a series of alkyl and hydride shifts is also very unusual. 35 The absence of polymer is remarkable. 

This oxidation reaction with water is understood by the sequence hydroxypalladation followed by carbonyl generation via 1,2-hydride shift (eq 4). It has been confirmed that no incorporation of deuterium occurs when the reaction is carried out in D2O and that all hydrogens of the alkene are retained in the carbonyl compound, which is clearly indicative of the hydride shift. 

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