Electrophilic carbonylation

The Grignard reagent RMgX is nucleophilic by virtue of the potential car banion (alkyl anion) R. It will react with the electrophilic carbonyl group as follows ... 

TT-Allylpalladium chloride (36) reacts with the nucleophiles, generating Pd(0). whereas tr-allylnickel chloride (37) and allylmagnesium bromide (38) reacts with electrophiles (carbonyl), generating Ni(II) and Mg(II). Therefore, it is understandable that the Grignard reaction cannot be carried out with a catalytic amount of Mg, whereas the catalytic reaction is possible with the regeneration of an active Pd(0) catalyst, Pd is a noble metal and Pd(0) is more stable than Pd(II). The carbon-metal bonds of some transition metals such as Ni and Co react with nucleophiles and their reactions can be carried out catalytic ally, but not always. In this respect, Pd is very unique. 

In general, the xanthenes are synthesized by the reaction of two moles of a nucleophilic / -substituted phenol (10) with an electrophilic carbonyl compound (11), the reaction occurring most readily with an acid catalyst at temperatures of 100—200°C. 

Hydantoins can react with electrophiles at both nitrogen atoms and at C-5. The electrophilic carbonyl groups can be attacked by nucleophiles, leading to hydrolysis of the ring or to partial or total reduction of the carbonyl system. Other reactions are possible, including photochemical cleavage of the ring. 

Scheme 4 shows in a general manner cyclocondensations considered to involve reaction mechanisms in which nucleophilic heteroatoms condense with electrophilic carbonyl groups in a 1,3-relationship to each other. The standard method of preparation of pyrazoles involves such condensations (see Chapter 4.04). With hydrazine itself the question of regiospecificity in the condensation does not occur. However, with a monosubstituted hydrazine such as methylhydrazine and 4,4-dimethoxybutan-2-one (105) two products were obtained the 1,3-dimethylpyrazole (106) and the 1,5-dimethylpyrazole (107). Although Scheme 4 represents this type of reaction as a relatively straightforward process, it is considerably more complex and an appreciable effort has been expended on its study (77BSF1163). Details of these reactions and the possible variations of the procedure may be found in Chapter 4.04. 

The synthesis of a large number of y-pyrones and y-pyranols from enamines has been brought about through the use of a wide variety of bifunctional molecules. These molecules include phenolic aldehydes (126,127), phenolic Mannich bases (128), ketal esters (129), and diketene (120-132). All of these molecules have an electrophilic carbonyl group and a nucleophilic oxygen center in relative 1,4 positions. This is illustrated by the reaction between salicylaldehyde (101) and the morpholine enamine of cyclohexanone to give pyranol 102 in a quantitative yield (127). 

The reaction starts with the nucleophilic addition of a tertiary amine 4 to the alkene 2 bearing an electron-withdrawing group. The zwitterionic intermediate 5 thus formed, has an activated carbon center a to the carbonyl group, as represented by the resonance structure 5a. The activated a-carbon acts as a nucleophilic center in a reaction with the electrophilic carbonyl carbon of the aldehyde or ketone 1 ... 

Judging from the following electrostatic potential maps, which kind of carbonyl compound has the more electrophilic carbonyl carbon atom, a ketone or an acid chloride Which has the more nucleophilic carbonyl oxygen atom Explain. 

Electrophilic carbonyl group reacts with nucleophiles. 

The enolate ion acts as a nucleophilic donor and adds to the electrophilic carbonyl group of a second carbonyl compound. 

A carbonyl condensation reaction takes place between two carbonyl partners and involves both nucleophilic addition and -substitution steps. One carbonyl partner (the donor) is converted by base into a nucleophilic enolate ion, which adds to the electrophilic carbonyl group of the second partner (the acceptor). The donor molecule undergoes an a substitution, while the acceptor molecule undergoes a nucleophilic addition. 

Although intermediate 2 is terminated at both ends by electrophilic carbonyl groups, the aldehydic function at C-7 is inherently more reactive, and thus more susceptible to a nucleophilic attack, than the methoxycarbonyl group at C-l. As a result, it should be possible to selectively engage the aldehyde carbonyl of intermedi-... 

A rare example of the activation of 02 and CO by platinum involves the treatment of the nucleophilic dioxygen species [Pt(02)(PPh3)2] with the electrophilic carbonyl ligand in [PtCl(CO)(PPh3)2]+ to afford a dinuclear cycloperoxycarbonyl adduct (116) in high yield.311... 

We have exploited this base catalysis of the oxygen exchange process to effect oxygen lability in the less electrophilic carbonyl sites of neutral metal carbonyl species. Because [MCOOH] intermediates are readily decarboxylated in the presence of excess hydroxide ion, in order to observe oxygen exchange processes in neutral metal carbonyl complexes it was convenient to carry out these reactions in a biphasic system employing phase transfer catalysis () (16, 17. 18). Under conditions (eq. 7) the... 

Among the many useful electrophiles, carbonyl compounds and their derivatives lead to products of the highest value for synthetic endeavors. First experiments with aldehydes and ketones were performed by Hoff, Brandsma and Arens (Scheme 8.15) [12b]. The primary allenyl adducts 60, which are isolable in moderate to excellent yields [12b, 47], serve as starting materials for subsequent cyclizations (see Section 8.2.2.2). 

In almost the same manner, tandem hydroformylation/aldol condensation aldol condensation of ketoolefins, such as p,y-unsaturated ketones, gives a single cyclization product under acid catalysis. Similar to the stepwise reaction, the in situ generated aldehyde preferentially acts as the electrophilic carbonyl component, while the ketone acts as the nucleophilic enol to form the five-membered ring product. Subsequent dehydration and hydrogenation of the resulting enone readily occurs under the reductive reaction conditions used (Scheme 30) [84],... 

The first step is addition of Cl 1 to C4. We still need to form C10-C1 and break C4-C3. Since we have a 1,5-diene (Cl 1=C10-C4-C3-C2=C1), we can do an oxy-Cope rearrangement. This gives a 5-8 system in which we only have to form the C4-C2 bond. C4 is neither nucleophilic nor electrophilic, while Cl 1 is nucleophilic (conjugation from OSiMe3). Upon quenching with water, however, C4 becomes an electrophilic carbonyl C, whereupon Cl 1 attacks with concomitant desilylation of O to give the product. 

A disadvantage of the traditional synthesis of A -alkyl-A -tosylhydrazones, particularly in the reaction of the tosylhydrazine with weakly electrophilic carbonyl compounds, is the instability of the hydrazine under the reaction conditions. However, A -alkylation of the tosylhydrazone (Table 5.23) under weakly basic condi-... 

When 2-alkyl-3-keto esters or 2-aryl-3-keto esters are treated with sulfonyl azides under basic conditions, nucleophilic deacylation occurs to yield 2-alkyl/aryl-2-diazo esters [960-963]. Nucleophilic deacylation can also be used to convert acceptor-substituted diazoketones into the corresponding acceptor-substituted diazomethanes [964,965]. In all these deacylation reactions it is the most electrophilic carbonyl group which is attacked by the nucleophile and cleaved off. 

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