Cyclohexanone formation

The introduction of electronegative substituents into the benzene ring increases the reactivity thus phenol is hydrogenated to cyclohexanol in satisfactory yield at a platinized Pt cathode in aqueous acidic media. In the gas phase, Coussemant has reported cyclohexanone formation from phenol. 

Product selectivity and yields of cyclohexanol and cyclohexanone formation in the photocatalytic air oxidation of cyclohexane on TiOj irradiated by UV have... 

TABLE 8 The rates of cyclohexanol and cyclohexanone formation at various rates of ozone absorption (WqjXIO , M. s" )... 

Another method for the hydrogenoiysis of aryl bromides and iodides is to use MeONa[696], The removal of chlorine and bromine from benzene rings is possible with MeOH under basic conditions by use of dippp as a ligand[697]. The reduction is explained by the formation of the phenylpalladium methoxide 812, which undergoes elimination of /i-hydrogen to form benzene, and MeOH is oxidized to formaldehyde. Based on this mechanistic consideration, reaction of alcohols with aryl halides has another application. For example, cyclohex-anol (813) is oxidized smoothly to cyclohexanone with bromobenzene under basic conditions[698]. 

DCHA is normally obtained in low yields as a coproduct of aniline hydrogenation. The proposed mechanism of secondary amine formation in either reductive amination of cyclohexanone or arene hydrogenation iHurninates specific steps (Fig. 1) on which catalyst, solvents, and additives moderating catalyst supports all have effects. 

Formation of a 1,2-disubstituted hydrazine by acid hydrolysis of an appropriately substituted pyrazolidine has been noted (67HC(22)l), but the most interesting ring fission of pyrazolidines involves the N(l)—N(2) bond of 1-phenylpyrazolidines (421). If, instead of phenylhydrazone, compound (421) is used in the Fischer indole synthesis, N- aminopropylin-doles are formed (73T4045). Scheme 39 shows the reaction with cyclohexanone. 

Chloral forms well-crystallized adducts (126) with diaziridines containing at least one NH group (B-67MI50800). Carbonyl addition products to formaldehyde or cyclohexanone were also described. Mixtures of aldehydes and ammonia react with unsubstituted diaziridines with formation of a triazolidine ring (128). Fused diaziridines like (128) are always obtained in ring synthesis of diaziridines (127) from aldehyde, ammonia and chloramine. The existence of three stereoisomers of compounds (128) was demonstrated (76JOC3221). Diaziridines form Mannich bases with morpholine and formaldehyde (64JMC626), e.g. (129). 

Kinetic studies of acetal/ketal formation from cyclohexanone, and hydrolysis (3 X 0 N HCl/dioxane-H20, 20°), indicate the following orders of reactivity ... 

The stereoselective reactions in Scheme 2.10 include one example that is completely stereoselective (entry 3), one that is highly stereoselective (entry 6), and others in which the stereoselectivity is modest to low (entries 1,2,4, 5, and 7). The addition of formic acid to norbomene (entry 3) produces only the exo ester. Reduction of 4-r-butylcyclohexanone (entry 6) is typical of the reduction of unhindered cyclohexanones in that the major diastereomer produced has an equatorial hydroxyl group. Certain other reducing agents, particularly sterically bulky ones, exhibit the opposite stereoselectivity and favor the formation of the diastereomer having an axial hydroxyl groi. The alkylation of 4-t-butylpiperidine with benzyl chloride (entry 7) provides only a slight excess of one diastereomer over the other. 

The direct formation of a dimethyl ketal by reaction of the ketone with methanol is particularly sensitive to steric effects. Only cyclohexanones react under these conditions.In the steroid series only saturated 3-ketones form dimethyl ketals with methanol and acid although partial reaction of a 2-ketone has been observed in the presence of homogenous rhodium catalyst. ... 

The presence of 1,3-diaxial interaction between the C-2 alkyl group and the C-4 axial hydrogen atom is reflected in the rate of enamine formation of 2-substituted cyclohexanone. It has been shown by Hunig and Salzwedel (20) that even under forcing conditions, the yield of pyrrolidine and morpholine enamines of 2-methylcyclohexanone does not exceed 58%, whereas the C-2 unsubstituted ketones underwent enamine formation under rather milder conditions in better than 80 % yield. 

Risaliti et al. (22), have shown that in the addition of the electrophilic olefins to the enamines of cyclohexanone, the formation of the less substituted enamine is favored when a bulky group is present at the electrophilic carbon atom. For instance, the reaction of (8-nitrostyrene with the morpholine enamine of cyclohexanone gave only the trisubstituted isomer (30) with the substituent in the axial orientation (23). The product on hydrolysis led to the ketone (31) to which erythro configuration was assigned on the grounds illustrated in Scheme 3 (24). 

Reaction of the pyrrolidine enamine of cyclohexanone with phenyl vinyl sulfone afforded a 9 1 mixture of the tri- and tetrasubstituted isomers (2(5). The preference of the less substituted isomer in this case is in keeping with the greater overlap requirement between the n electrons of the double bond and the electron pair on the nitrogen atom, since the double bond exo to the five-membered ring is much more favored than the double bond exo to the six-membered ring. It is, however, hard to explain the formation of largely the trisubstituted isomer with the piperidine enamine of cyclohexanone, where both of the rings involved are six-membered. 

Risaliti et al. (2J) have also studied the addition of 2-nitropropene, which also lacks any substituent at the electrophilic carbon atom, to the morpholine enamine of cyclohexanone. The product, as expected, was the tetrasubstituted isomer, the formation of which may be envisioned via the transition state (42). 

The reaction of the morpholine enamine of cyclohexanone with phenyl isothiocyanate led only to the tetrasubstituted isomer of the monoadduct (54), which failed to add any more of the phenyl isothiocyanate. The formation of only the tetrasubstituted isomer has been attributed by Hunig et al. (37) to the stronger conjugation of the C=S group with the enamine double bond than that of the C=0 group in the enamine (49). 

The intermediacy of an aminal in the formation of enamines from ketones and secondary amines is not usually proposed. The only direct evidence for this is the infrared spectra of the reaction mixtures produced when dimethyl-or diethylamine was allowed to react with cyclohexanone or cyclopentanone... 

Experimental evidence, obtained in protonation (3,6), acylation (1,4), and alkylation (1,4,7-9) reactions, always indicates a concurrence between electrophilic attack on the nitrogen atom and the -carbon atom in the enamine. Concerning the nucleophilic reactivity of the j3-carbon atom in enamines, Opitz and Griesinger (10) observed, in a study of salt formation, the following series of reactivities of the amine and carbonyl components pyrrolidine and hexamethylene imine s> piperidine > morpholine > cthyl-butylamine cyclopentanone s> cycloheptanone cyclooctanone > cyclohexanone monosubstituted acetaldehyde > disubstituted acetaldehyde. 

There is some spectral evidence that acylation of enamines of cyclic ketones with acid chlorides having an a-hydrogen in the presence of triethylamine proceeds via the ketene and subsequent cycloaddition (84). The intermediate cyclobutanone is then opened to give the enamino ketone which is hydrolyzed to the 2-acyl cyclohexanone. In the case of enamines of larger cyclic ketones the alternate mode of the cyclobutanone opening predominates, with the formation of ring-expanded 1,3-diketones upon... 

The illumination of enamines as general activa ting derivatives of ketones in alkylation reactions also threw light on their special usefulness for controlling alkylations (3), particularly in the formation of monosubstituted cyclohexanones. Thus 2-methylcyclohexanone could be obtained in 80% yield from the pyrrolidine enamine of cyclohexanone, and further alkylation, which required more drastic conditions, gave only 2,6-dimethylcyclo-hexanone (1,237). 

The formation of bicyclic imines (263,264) from piperidine enamines and y-bromopropyl amines may appear at first sight to be a simple extension of the reactions of enamines with alkyl halides. However, evidence has been found that the products are formed by an initial enamine exchange, followed by an intramolecular enamine alkylation. Thus y-bromodiethylamino-propane does not react with piperidinocyclohexene under conditions suitable for the corresponding primary amine. Furthermore, the enamine of cyclopentanone, but not that of cyclohexanone, requires a secondary rather than primary y-bromopropylamine, presumably because of the less favorable imine to enamine conversion in this instance. 

The addition of phenylisocyanate to aldehyde-derived enamines resulted in the formation of aminobutyrolactams (438,439). As aminal derivatives these produets can be hydrolyzed to the linear aldehyde amides and thus furnish a route to derivatives of the synthetically valuable malonaldehyde-acid system. With this class of reactions, a second acylation on nitrogen becomes possible and the six-membered cyclization products have been reported (440). Closely related to the reactions of enamines with isocyanates is the condensation of cyclohexanone with urea in base (441). 

In the reactions of arylsulfenyl chlorides with enamines one encounters an unusual result for enamine chemistry, in that the formation of 2,6-disubstituted cyclohexanone enamines predominates over the formation of monosubstitution products 474). A rationalization of this result suggests the formation of an intermediate which can act as an intramolecular electrophile in formation of the second carbon-sulfur bond. 

The application of this addition to aminomethylene ketones provides a convenient synthesis of monoamides of pimelic acid (508). It should be noted that the corresponding oxidation of hydroxy methylene cyclohexanone leads to ring contraction and formation of cyclopentanoic acid. 

A -Chloromethylamine attacks ketones in alkaline solution with formation of oxaziranes with cyclohexanone, compound 17 is produced in 50% yield. The reaction with aldehydes with zV-chloromethyl-amine yields predominantly acid amides. However, oxaziranes are also produced here as by-products. From benzaldehyde and A -chloro-methylamine, 2-raethyl-3-phenyloxazirane (15) was obtained in 10% yield. 

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