Aldehyde introduction

Aldehydes, introduction in polysaccharides, 189-190 Aligned fiber moderators, flow rate, 346r Amine functions, effect on pH sensitivity of poly(ortho esters), 176-178 Aminobenzoate esters, correlations of partition coefficients for solvent pairs, 62,63/... 

Summary Syntheses of Ketones and Aldehydes 837 18-11 Reactions of Ketones and Aldehydes Introduction to Nucleophilic Addition 839... 

Reactions of Ketones and Aldehydes Introduction to Nucleophilic Addition... 

Z)-con figured products with both aromatic and aliphatic aldehydes.Introduction of an SMe group at the a-carbon atom leads exclusively to the ( )-isomer [tra i-P(O)/H relationship Figure 2.1] with aromatic aldehydes and predominantly to the same isomer with aliphatic aldehydes. ... 

The final step can involve introduction of the amino group or of the carbonyl group. o-Nitrobenzyl aldehydes and ketones are useful intermediates which undergo cyclization and aromatization upon reduction. The carbonyl group can also be introduced by oxidation of alcohols or alkenes or by ozonolysis. There are also examples of preparing indoles from o-aminophcnyl-acetonitriles by partial reduction of the cyano group. 

In practice this reaction is difficult to carry out with simple aldehydes and ketones because aldol condensation competes with alkylation Furthermore it is not always possi ble to limit the reaction to the introduction of a single alkyl group The most successful alkylation procedures use p diketones as starting materials Because they are relatively acidic p diketones can be converted quantitatively to their enolate ions by weak bases and do not self condense Ideally the alkyl halide should be a methyl or primary alkyl halide... 

The enol content of a carboxylic acid is far less than that of an aldehyde or ketone and introduction of a halogen substituent at the a carbon atom requires a different set... 

Nitration and halogenation of furfural occurs under carehiUy controlled conditions with introduction of the substituent at the open 5-position (24,25). Nitration of furfural is usually carried out in the presence of acetic anhydride, resulting in the stable compound, 5-nitrofurfuryhdene diacetate (26,27). The free aldehyde is isolated by hydrolysis and must be used immediately in a reaction because it is not very stable. 

High purity acetaldehyde is desirable for oxidation. The aldehyde is diluted with solvent to moderate oxidation and to permit safer operation. In the hquid take-off process, acetaldehyde is maintained at 30—40 wt % and when a vapor product is taken, no more than 6 wt % aldehyde is in the reactor solvent. A considerable recycle stream is returned to the oxidation reactor to increase selectivity. Recycle air, chiefly nitrogen, is added to the air introducted to the reactor at 4000—4500 times the reactor volume per hour. The customary catalyst is a mixture of three parts copper acetate to one part cobalt acetate by weight. Either salt alone is less effective than the mixture. Copper acetate may be as high as 2 wt % in the reaction solvent, but cobalt acetate ought not rise above 0.5 wt %. The reaction is carried out at 45—60°C under 100—300 kPa (15—44 psi). The reaction solvent is far above the boiling point of acetaldehyde, but the reaction is so fast that Httle escapes unoxidized. This temperature helps oxygen absorption, reduces acetaldehyde losses, and inhibits anhydride hydrolysis. 

Amino resins are thermosetting polymers made by combining an aldehyde with a compound containing an amino (—NH2) group. Urea—formaldehyde (U/F) accounts for over 80% of amino resins melamine—formaldehyde accounts for most of the rest. Other aldehydes and other amino compounds are used to a very minor extent. The first commercially important amino resin appeared about 1930, or some 20 years after the introduction of phenol—formaldehyde resins and plastics (see Phenolic resins). 

The most versatile method for preparing enamines involves the condensation of aldehydes and ketones with secondary amines [Eq. (1)]. Mannich and Davidsen (/) discovered that the reaction of secondary amines with aldehydes in the presence of potassium carbonate and at temperatures near 0° gave enamines, while calcium oxide and elevated temperatures were required to cause a reaction between ketones and secondary amines, although usually in poor yield. The introduction by Herr and Heyl 2-4) of the removal of the water produced in the condensation by azeotropic distillation with benzene made possible the facile preparation of enamines from ketones and disubstituted aldehydes. 

Aldehyde (Chapter 19 introduction) A compound containing the -CHO functional group. 

However, addition of (+ )-(7 )-l-methyl-4-(mcthylsulfinyl)benzene, to aldehydes and ketones proceeds with low stereoselectivity. An improvement of the 3-syn diaslereoselectivity was found with the zinc reagent obtained by transmetalation of the lithiated sulfoxide with anhydrous zinc chloride38. An improvement of the stereoselectivity was also attained by exchange of the 4-methylphenyl substituent for a 2-methoxyphenyl or 2-pyridinyl substituent. Thus, the introduction of an additional complexing site into the aromatic part of the sulfoxide reagent enhances the stereoselectivity35. 

In addition to ketone enolates, azaenolatcs with chiral auxiliary groups attached to the nitrogen atom are suitable for the introduction of an a-unsubstituted enolate of the keto-type into an aldehyde in a stereoselective manner (see Section D.1.3.5.). 

A somewhat tedious extension of this methodology, which guarantees good induced stereoselectivity, relies on the reversible introduction of an a-substituent which is removed after the aldol addition is performed. For this purpose, the corresponding derivative of (methyl-thio)acetic acid is converted into the boron enolate and subsequently reacted with aldehydes. The... 

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