Aldehydes reaction with phenoxide

In the strongly basic medium, the reactant is the phenoxide ion high nucleophilic activity at the ortho and para positions is provided through the electromeric shifts indicated. The above scheme indicates theorpara substitution is similar. The intermediate o-hydroxybenzal chloride anion (I) may react either with a hydroxide ion or with water to give the anion of salicyl-aldehyde (II), or with phenoxide ion or with phenol to give the anion of the diphenylacetal of salicylaldehyde (III). Both these anions are stable in basic solution. Upon acidification (III) is hydrolysed to salicylaldehyde and phenol this probably accounts for the recovery of much unreacted phenol from the reaction. 

Similar information is available for other bases. Lithium phenoxide (LiOPh) is a tetramer in THF. Lithium 3,5-dimethylphenoxide is a tetramer in ether, but addition of HMPA leads to dissociation to a monomer. Enolate anions are nucleophiles in reactions with alkyl halides (reaction 10-68), with aldehydes and ketones (reactions 16-34, 16-36) and with acid derivatives (reaction 16-85). Enolate anions are also bases, reacting with water, alcohols and other protic solvents, and even the carbonyl precursor to the enolate anion. Enolate anions exist as aggregates, and the effect of solvent on aggregation and reactivity of lithium enolate anions has been studied. The influence of alkyl substitution on the energetics of enolate anions has been studied. ... 

Polymer bound acrylic ester is reacted in a Baylis-Hillman reaction with aldehydes to form 3-hydroxy-2-methylidenepropionic acids or with aldehydes and sulfonamides in a three-component reaction to form 2-methylidene-3-[(arylsulfonyl)amino]propionic acids. In order to show the possibility of Michael additions, the synthesis of pyrazolones was chosen. The Michael addition was carried out with ethyl acetoacetate and BEMP as base to form the resin bound p-keto ester. This was then transformed into the hydrazone with phenylhydrazine hydrochloride in the presence of TMOF and DIPEA [28]. The polymer bound phenol was readily coupled to a variety of allyl halides by using the Pl- Bu to generate a reactive phenoxide [29]. 

We recall that enolates undergo condensation reactions with the carbonyl carbon atom of aldehydes (Section 21.7). Enolates tend to react to give alkylation at carbon. A similar reaction occurs between the phenolate ion and formaldehyde. Because both C-2 and C-4 are nucleophilic, two possible condensation products may result. The following reaction shows condensation at C-4, producing a conjugation-extended enolate. Subsequent tautomerization generates the enol form, which is a phenol. Solvent-mediated proton transfer also occurs, giving a phenoxide rather than the more basic (and less stable) alkoxide ion. 

Although 4-hydroxybenzaldehyde can be made by the saligenin route, it has been made historically by the Reimer-Tiemann process, which also produces sahcylaldehyde (64). Treatment of phenol with chloroform and aqueous sodium hydroxide results in the formation of benzal chlorides, which are rapidly hydrolyzed by the alkaline medium into aldehydes. Acidification of the phenoxides results in the formation of the final products, sahcylaldehyde and 4-hydroxybenzaldehyde. The ratio of ortho and para isomers is flexible and can be controlled within certain limits. The overall reaction scheme is shown in Figure 1. Product separation is accomphshed by distillation, but this process leads to environmental problems because of the quantities of sodium chloride produced. 

Dialkoxyaldehydes of the type RCH(OCHj)CR(OCH,)CHO ate prepared from the corresponding a,/3-dichloroaldehydes by the action of very dilute solutions of sodium alkoxide below 15° (70-85%). In these preparations, the presence of potassium iodide or an alkyl iodide has been helpful. The yield of phenoxyacetone from chloroacetone and sodium phenoxide is increased from 16-23% to more than 90% chiefly by the presence of potassium iodide in the reaction mixture. The reaction of alkyl iodides with phenolic aldehydes in methanolic potassium hydroxide gives p-alkoxy-benzaldehydes (60-75%). ... 

Intramolecular alkenylchromium additions to aldehydes have been repotted and are outlined in Section 1.6.4.3. An intriguing example of an intramolecular organochromium reaction has been communicated by Gorques and coworkers. Treatment of (130 Scheme 5) with CrCh in HMPA elicits a reductive 1,5-acyl transposition and generates chromium phenoxide (131). Wodc-up with aqueous ammonium chloride affords phenol (132). However, when the reaction occurs in the presence of boron trifluoride etherate benzo[h]furan (133) is obtained directly in excellent yield. 

Trost and coworkers developed a chiral zinc phenoxide for the asymmetric aldol reaction of acetophenone or hydroxyacetophenone with aldehydes (equations 62 and 63) . This method does not involve the prior activation of the carbonyls to silyl enol ethers as in the Mukaiyama aldol reactions. Shibasaki and coworkers employed titanium phenoxide derived from a phenoxy sugar for the asymmetric cyanosilylation of ketones (equation 64). 2-Hydroxy-2 -amino-l,l -binaphthyl was employed in the asymmetric carbonyl addition of diethylzinc , and a 2 -mercapto derivative in the asymmetric reduction of ketones and carbonyl allylation using allyltin ° . ... 

Nucleophilic addition of the trifluoromethyl group to aldehydes, ketones and other carbonyl compounds leads primarily to the corresponding trimethylsilyl ether this must subsequently be hydrolyzed to the alcohol. Because typical reaction conditions are very mild, the method is widely applicable, even for sensitive substrates. In contrast with most other methods, fluoride-induced perfluoroalkylation via silicon compounds also works for enolizable carbonyl compounds. With c(, -un-saturated substrates 1,2-addition directly to the carbonyl group is strongly preferred [64b]. If the oxygen is coordinated to a bulky Lewis acid, for example aluminum tri(2,6-bis(tert-butyl)phenoxide (ATPH), the 1,4-addition products are obtained selectively [73f] (Scheme 2.128). 

Acetals of a-bromo aldehydes are obtainable from <%,/ -dibromoalkyl acetates by an analogous procedure in which these esters are prepared from enol acetates and bromine and are then converted into acetals by means of alcohols.939 A simple synthesis of <%-keto aldehydes is to treat a-brominated phenacyl phenyl ethers with alkoxides or phenoxides.940 This method is particularly useful for the preparation of aryl acetals because it avoids the side reactions that can complicate reactions between phenols and aldehydes in an acidic medium. 

---