Ketone higher-substituted

The glycidic esters are of interest primarily because upon hydrolysis aud decarboxylation they aflFord aldehydes (if ClCHjCOOEt is used) or ketones (if substituted chloroacetic esters- ClCHRCOOEt are employed) having a higher carbon content than the original aldehyde or ketone. Thus (I) gives o-phenyl-propionaldehyde or hydratropaldehyde (II) ... 

By-Products. Almost all commercial manufacture of pyridine compounds involves the concomitant manufacture of various side products. Liquid- and vapor-phase synthesis of pyridines from ammonia and aldehydes or ketones produces pyridine or an alkylated pyridine as a primary product, as well as isomeric aLkylpyridines and higher substituted aLkylpyridines, along with their isomers. Furthermore, self-condensation of aldehydes and ketones can produce substituted ben2enes. Condensation of ammonia with the aldehydes can produce certain alkyl or unsaturated nitrile side products. Lasdy, self-condensation of the aldehydes and ketones, perhaps with reduction, can lead to alkanes and alkenes. 

It s reasonable to ask why one would prepare a ketone by way of a keto ester (ethyl acetoacetate, for example) rather than by direct alkylation of the enolate of a ketone. One reason is that the monoalkylation of ketones via their enolates is a difficult reaction to cany out in good yield. (Remember, however, that acylation of ketone enolates as described in Section 21.4 is achieved readily.) A second reason is that the delocalized enolates of (3-keto esters, being far- less basic than ketone enolates, give a higher substitution-elimination ratio when they react with alkyl halides. This can be quite important in those syntheses in which the alkyl halide is expensive or difficult to obtain. 

Since most often the selective formation of just one stereoisomer is desired, it is of great importance to develop highly selective methods. For example the second step, the aldol reaction, can be carried out in the presence of a chiral auxiliary—e.g. a chiral base—to yield a product with high enantiomeric excess. This has been demonstrated for example for the reaction of 2-methylcyclopenta-1,3-dione with methyl vinyl ketone in the presence of a chiral amine or a-amino acid. By using either enantiomer of the amino acid proline—i.e. (S)-(-)-proline or (/ )-(+)-proline—as chiral auxiliary, either enantiomer of the annulation product 7a-methyl-5,6,7,7a-tetrahydroindan-l,5-dione could be obtained with high enantiomeric excess. a-Substituted ketones, e.g. 2-methylcyclohexanone 9, usually add with the higher substituted a-carbon to the Michael acceptor ... 

These constitutions have recently received support from the work of A. Haller. If they are correct, then thujone should be capable of yielding trialkyl substitution products, whilst isothujone should not be able to go beyond the dialkyl stage. By alkylation with the assistance of sodium amide, triallylthujone could be prepared, but no higher substitution product than dimethylisothujone could be prepared from isothujone. In the course of his work, Haller prepared the following alkyl derivatives of the two ketones —... 

Photodecomposition. The photodecomposition pathways appear simple in these compounds. In all cases, the photodecomposition quantum yield is 0.8 or greater (36,93). The products include CO, chlorofluoroethanes, chlorofluoromethanes, and in some instances, higher substituted ketones. These products can be explained in terms of two radical decomposition pathways followed by radical recombination reactions,... 

In esters, acids and ketones the substitution of a chlorine or bromine atom on an a-carbon atom to the carbonyl group results in a shift in the C=0 frequency to a higher value. With a direct attachment of the halogen to the carbonyl group, a considerably bigger shift in this direction is to be expected, and tliis is what is found in practice. 

It has been shown by House et cd. [23] that when in related enolization experiments an excess of the ketone was added to LDA, the formation of the higher-substituted enolate results under thermodynamic control through... 

When another group having higher priority for citation as principal group is also present, the ketonic oxygen may be expressed by the prefix 0x0-, or one can use the name of the carbonyl-containing radical, as, for example, acyl radicals and oxo-substituted radicals. Examples are... 

SuIfona.tlon, Sulfonation is a common reaction with dialkyl sulfates, either by slow decomposition on heating with the release of SO or by attack at the sulfur end of the O—S bond (63). Reaction products are usually the dimethyl ether, methanol, sulfonic acid, and methyl sulfonates, corresponding to both routes. Reactive aromatics are commonly those with higher reactivity to electrophilic substitution at temperatures > 100° C. Tn phenylamine, diphenylmethylamine, anisole, and diphenyl ether exhibit ring sulfonation at 150—160°C, 140°C, 155—160°C, and 180—190°C, respectively, but diphenyl ketone and benzyl methyl ether do not react up to 190°C. Diphenyl amine methylates and then sulfonates. Catalysis of sulfonation of anthraquinone by dimethyl sulfate occurs with thaHium(III) oxide or mercury(II) oxide at 170°C. Alkyl interchange also gives sulfation. 

The nitrites aie most conveniently prepared from the corresponding alcohols by treatment with nitrosyl chloride in pyridine. The crude nitrites can be precipitated by addition of water and recrystallized from appropriate solvents. However nitrites prepared from carbinols in which the adjacent carbon is substituted by halogen, free or esterified hydroxyl or a carbonyl function are very readily hydrolyzed and must be recrystallized with great care. In general the photolysis gives higher yields if purified and dried nitrites are used which do not contain acids or pyridine, although occasionally the addition of small amounts of pyridine is recommended in order to prevent hydrolysis of the nitrite. Traces of acids do in fact catalyze the thermal decomposition of secondary nitrites to equimolar amounts of alcohol and ketone. ... 

The secondary amines used in the preparation of enamines have been primarily simple dialkylamines or cyclic amines of five- or higher-membered rings. Azetidine (4) yields a stable enamine with cyclopentanone (28). No simple enamines formed by condensation of ethylenimine (5) or a substituted ethylenimine with an aldehyde or ketone have been reported. 

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