Oximes aldoximes

Reaction of hydroxylamine with ketones or aldehydes yields oximes, aldoximes RHC=NOH, or ketoximes R2C=NOH. Almost all the hydroxylamine production (95%) is used for the production of either cyclohexanone oxime or caprolactam, both of which are intermediates for polyamide synthetics. The remainder of the hydroxylamine production is used as an anticreaming agent in paints and coatings, as an auxiliary in refining fats for soap production, as a regulator or inhibitor for various polymerizations, as a stabilizer for developers, and as an additive for color emulsions. Oximes are also used as pharmaceuticals or in crop protection. 

Reaction of oximes. Aldoximes are dehydrated to afford nitriles on treatment with HjSO -SiOj under microwave. Actually it suffices to irradiate the mixtures of aldehydes, NHjOH HCl, and HCOOH with microwave for the direct access to nitriles.- Regeneration of ketones from ketoximes is readily achieved by the same technique, while adding wet NalO orNaBiDOj to drive the reaction. 

Reduction of oximes. Aldoximes and ketoximes are reduced by diborane in THF at 25° to the corresponding N-monosubstituted hydroxylamines in very good yield.3 If the reaction is carried out at 105-110°in a diglyme-THF solution, the reduction is carried to the corresponding amine. The reaction probably proceeds by way of the hydroxylamine since hydroxylamines are reduced to amines in high yield under these conditions ... 

Reaction of hydroxylamine with ketones or aldehydes yields oximes, aldoximes RHC=NOH, or ketoximes R2C=NOH. 

In a 250 ml. conical flask mix a solution of 14 g. of sodium hydroxide in 40 ml. of water and 21 g. (20 ml.) of pure benzaldehyde (Section IV,115). Add 15 g. of hydroxylamine hydrochloride in small portions, and shake the mixture continually (mechanical stirring may be employed with advantage). Some heat is developed and the benzaldehyde eventually disappears. Upon coohiig, a crystalline mass of the sodium derivative separates out. Add sufficient water to form a clear solution, and pass carbon dioxide into the solution until saturated. A colourless emulsion of the a or syn-aldoxime separates. Extract the oxime with ether, dry the extract over anhydrous magnesium or sodium sulphate, and remove the ether on a water bath. Distil the residue under diminished pressure (Fig. 11,20, 1). Collect the pure syn-benzaldoxime (a-benzald-oxime) at 122-124°/12 mm. this gradually solidifies on cooling in ice and melts at 35°. The yield is 12 g. 

Internal nitroalkenes can be reduced to the corresponding ketox-imes by SnCla. The second method is a modification of the first, also allowing terminal nitroalkenes (such as nitrostyrenes) to be reduced to aldoximes. The oximes, in turn, can either be reduced to the corresponding amines, or cleaved to form the carbonyl compound. 

The rearrangement of oximes 1 under the influence of acidic reagents to yield A -substituted carboxylic amides 2, is called the Beckmann rearrangement. The reaction is usually applied to ketoximes aldoximes often are less reactive. 

It will be noted that intermediate 33 contains all of the carbon atoms and the two stereocenters of the targeted aldoxime 32. At the outset, it was anticipated that the terminal oxime function in 32 could be formed by the condensation of hydroxylamine with the... 

Nitrile oxides are usually prepared via halogenation and dehydrohalogenation of aldoximes [11] or via dehydration of primary nitro alkanes (Scheme 1) [12]. However, it is important to note that nitrile oxides are relatively unstable and are prone to dimerization or polymerization, especially upon heating. 1,3-Dipolar cycioaddition of a nitrile oxide with a suitable olefin generates an isoxazoline ring which is a versatile synthetic intermediate in that it provides easy access to y-amino alcohols, )5-hydroxy ketones, -hydroxy nitriles, unsaturated oximes, and a host of other multifunctional molecules (Scheme 1) [5a]. Particularly for the formation of )5-hydroxy ketones, nitrile oxide-olefin cycioaddition serve as an alternative to the Aldol reaction. 

The reaction of the a-bromo aldoxime 52e (R = R = Me) with unsaturated alcohols has been extended to the heterocyclic systems furfuryl alcohols and 2-thiophene methanol [29b]. The furanyl and thiophenyl oximes 63a-c were treated with NaOCl and the resulting heterocyclic nitrile oxides were found to undergo spontaneous intramolecular dipolar cycloaddition to produce the unsaturated tricyclic isoxazolines 64a-c in high yield (Eq. 5). In these cases, the heterocyclic ring acts as the dipolarophile with one of the double bonds adding to the nitrile oxide [30]. 

The conversion of oximes to nitroalkanes has been achieved by employing an Mo(IV) oxodiperoxo complex as oxidant in acetonitrile. Both aldoximes and ketoximes are converted into the corresponding nitroalkanes (Eqs. 2.61 and 2.62),123 representing a complementary synthetic route to the use of the UHP method. 

The quest for a solvent-free deprotection procedure has led to the use of relatively benign reagent, ammonium persulfate on silica, for regeneration of carbonyl compounds (Scheme 6.10) [48]. Neat oximes are simply mixed with solid supported reagent and the contents are irradiated in a MW oven to regenerate free aldehydes or ketones in a process that is applicable to both, aldoximes and ketoximes. The critical role of surface needs to be emphasized since the same reagent supported on clay surface delivers predominantly the Beckmann rearrangement products, the amides [49]. 

A simple montmorillonite K 10 clay surface is one among numerous acidic supports that have been explored for the Beckmann rearrangement of oximes (Scheme 6.27) [54]. However, the conditions are not adaptable for the aldoximes that are readily dehydrated to the corresponding nitriles under solventless conditions. Zinc chloride has been used in the above rearrangement for benzaldehyde and 2-hydroxyacetophe-none, the later being adapted for the synthesis of benzoxazoles. 

The Ponzio reaction provides a useful route to gem-dinitro compounds and involves treating oximes with a solution of nitrogen dioxide or its dimer in diethyl ether or a chlorinated solvent. The Ponzio reaction works best for aromatic oximes where the synthesis of many substituted aryldinitromethanes have been reported. Compound (56), an isomer of TNT, is formed from the reaction of dinitrogen tetroxide with the oxime of benzaldehyde (55) followed by mononitration of the aromatic ring with mixed acid. Yields are usually much lower for aliphatic aldoximes and ketoximes. " The parent carbonyl compound of the oxime is usually the major by-product in these reactions. 

Some recent advances have been reported in oxime oxidation, including the in situ generation of peroxytrifluoroacetic acid from the reaction of urea hydrogen peroxide complex with TFAA in acetonitrile at 0 °C This method gives good yields of nitroalkanes from aldoximes but fails with ketoximes. 

Peroxyacetic acid generated in situ from sodium perborate and glacial acetic acid has been used for oxime to nitro group conversion. Peroxyimidic acid generated from acetonitrile and hydrogen peroxide has found similar use. An Mo(IV) peroxy complex has been reported for the oxidation of both ketoximes and aldoximes. 

The restricted rotation around the C=N double bond in oximes (2) gives rise to two possible isomers, 9A and 9B for aldoximes and lOA and lOB for ketoximes. For aldoximes, these are labeled syn (9A) and anti (9B). 

We will look at three pairs of syn and anti aldoxime isomers, 9A and 9B, corresponding to R = CH3 (acetaldoxime), R = CH2CI (chloroacetaldoxime) and R = CgH5 (benzal-doxime). We will also consider the two isomeric forms lOA and lOB of acetophenone oxime, a ketoxime in which R = CH3 and R" = CeHs. 

In Table 2 are listed the hydroxylamines, oximes and hydroxamic acids for which we have determined the gas phase structures. We tried to select a representative group in each category. There are two types of oximes, as indicated, aldoximes and ketoximes. Due to restricted rotation around the C=N double bond, these can exist in two isomeric forms (except when R = H for an aldoxime and R = R" for a ketoxime). We have investigated both isomers in nearly every instance. For aldoximes, they are generally labeled syn when the H and OH are on the same side of the double bond and anti when on opposite sides. Note that the ketoximes in Table 2 contain one pair of isomers in which the >C=NOH group is not bonded to two carbons instead one bond is to a chlorine. One of these isomers wiU be of interest in Section B.D in the context of hydrogen bonding vi lone pair—lone pair repulsion. 

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