Carbonyl compounds shifts

The effect of substituting oxygen-18 for oxygen-16 in the infra-red spectra of a molecule should be detectable, and has been calculated by Halmann and Pinchas (1958a) to be of the order of 40 cm. in carbonyl compounds. Shifts of this order have been found in 0 -labeled benzo-phenone (Halmann and Pinchas, 1958a), triphenylphosphine oxide (Halmann and Pinchas, 1958b), and also in nitromethane (Halmann and Pinchas, 1960), benzamide, Af-methyl and Af,Af -dimethyl benzamide, benzoic acid, benzoyl chloride and methyl benzoate, diphenylsulfoxide and sulfone (Pinchas, Samuel and Weiss-Broday, 1961, and previous papers), diisopropyl ketone (Karabatsos, 1960). 

Hydrogen bonding to a carbonyl group causes a shift to lower frequency of 40 to 60 cm k Acids, amides, enolized /3-keto carbonyl systems, and o-hydroxyphenol and o-aminophenyl carbonyl compounds show this effect. All carbonyl compounds tend to give slightly lower values for the carbonyl stretching frequency in the solid state compared with the value for dilute solutions. 

Study of the mechanism of this complex reduction-Hquefaction suggests that part of the mechanism involves formate production from carbonate, dehydration of the vicinal hydroxyl groups in the ceUulosic feed to carbonyl compounds via enols, reduction of the carbonyl group to an alcohol by formate and water, and regeneration of formate (46). In view of the complex nature of the reactants and products, it is likely that a complete understanding of all of the chemical reactions that occur will not be developed. However, the Hquefaction mechanism probably involves catalytic hydrogenation because carbon monoxide would be expected to form at least some hydrogen by the water-gas shift reaction. 

The close agreement of the three methods supports the contention that protonation at low temperatures first occurs at nitrogen and is followed by a proton shift to give the iminium salt (M). The rate of this rearrangement is dependent on temperature, the nature of the amine, and the nature of the carbonyl compound from which the enamine was made. Even with this complication the availability of iminium salts is not impaired since the protonation reaction is usually carried out at higher temperatures than —70°. Structurally complicated enamines such as trichlorovinyl amine can be readily protonated (17,18). 

A closely related method does not require conversion of enantiomers to diastereomers but relies on the fact that (in principle, at least) enantiomers have different NMR spectra in a chiral solvent, or when mixed with a chiral molecule (in which case transient diastereomeric species may form). In such cases, the peaks may be separated enough to permit the proportions of enantiomers to be determined from their intensities. Another variation, which gives better results in many cases, is to use an achiral solvent but with the addition of a chiral lanthanide shift reagent such as tris[3-trifiuoroacetyl-Lanthanide shift reagents have the property of spreading NMR peaks of compounds with which they can form coordination compounds, for examples, alcohols, carbonyl compounds, amines, and so on. Chiral lanthanide shift reagents shift the peaks of the two enantiomers of many such compounds to different extents. 

Thermal [2h-2] cycloaddition reactions of carbonyl compounds were catalyzed by a Lewis acid. The catalyst forms complexes with the carbonyl compounds and enhances the electron-accepting power. The reaction shifts from the delocalization band to the pseudoexcitation band. Catalyzed [2h-2] cycloaddition reactions were observed with acetylenic compounds [28] and ketenes [29-31]. 

The chemical shifts of trifluoromethyl groups at the terminus of a,(3-unsaturated carbonyl compounds are not affected by the presence of the carbonyl group, as is indicated by the examples in Scheme 5.37, and as exemplified by the fluorine NMR of 4,4,4-trifluorocrotonic acid, given in Fig. 5.14. 

During the early period of oxidation, this equilibrium is shifted to the right due to the very low concentration of carbonyl compound. The concentration of carbonyl compound is increasing during oxidation and in parallel the concentration of hydroxyperoxide increases. The thermodynamic parameters of this equilibrium are the following for formaldehyde and acetone in the gas phase [46]. 

A study518 of the mechanism of oxidation of alcohols by the reagent suggested that a reversible, oriented adsorption of the alcohol onto the surface of the oxidant occurs, with the oxygen atom of the alcohol forming a coordinate bond to a silver ion, followed by a concerted, irreversible, homolytic shift of electrons to generate silver atoms, carbon dioxide, water, and the carbonyl compound. The reactivity of a polyhydroxy compound may not, it appears, be deduced from the relative reactivity of its component functions, as the geometry of the adsorbed state, itself affected by solvent polarity, exerts an important influence on the selectivity observed.519... 

Thus the weak n — n band in a saturated carbonyl compound is shifted from below 300 nm to above 300 nm with an increase in s. Conjugation of additional chromophoric groups moves mx progressively... 

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... 

Transfer hydrogenations of carbonyl compounds are often conducted using 2-propanol as the hydrogen donor. One advantage of this compound is that it can be used simultaneously as a solvent. A large excess of the hydrogen donor shifts the redox equilibrium towards the desired product (see also Section 20.3.1). 

Once again, use of these donors as solvent may shift the reaction equilibrium towards the desired product. Since the reactivity of olefins is lower than that of carbonyl compounds, higher reaction temperatures are usually required to achieve acceptable TOFs, and then the relatively higher boiling hydrogen donating solvents mentioned above may be the best choice. 

Regarding the first problem, the most elemental treatment consists of focusing on a few points on the gas-phase potential energy hypersurface, namely, the reactants, transition state structures and products. As an example, we will mention the work [35,36] that was done on the Meyer-Schuster reaction, an acid catalyzed rearrangement of a-acetylenic secondary and tertiary alcohols to a.p-unsaturatcd carbonyl compounds, in which the solvent plays an active role. This reaction comprises four steps. In the first, a rapid protonation takes place at the hydroxyl group. The second, which is the rate limiting step, is an apparent 1, 3-shift of the protonated hydroxyl group from carbon Ci to carbon C3. The third step is presumably a rapid allenol deprotonation, followed by a keto-enol equilibrium that leads to the final product. 

Thermodynamic and kinetic data for Cope rearrangements leading to allenes have been measured [511]. For preparatively useful yields the equilibrium can be shifted to the allene, for example by the classical use of allylic alcohols leading to carbonyl compounds [512],... 

Addition of diazomethane to cyanoallene took place at the internal C=C bond of the cyanoallene to give 4-methylenepyrazoline 85. The following isomerization via 1,3-hydrogen shifts afforded 4-methyl-5-cyanopyrazole 86 [83], a-Diazo carbonyl compounds reacted in an analogous way [84]. 

---