Enol carbonylation reactions

The first three chapters discuss fundamental bonding theory, stereochemistry, and conformation, respectively. Chapter 4 discusses the means of study and description of reaction mechanisms. Chapter 9 focuses on aromaticity and aromatic stabilization and can be used at an earlier stage of a course if an instructor desires to do so. The other chapters discuss specific mechanistic types, including nucleophilic substitution, polar additions and eliminations, carbon acids and enolates, carbonyl chemistry, aromatic substitution, concerted reactions, free-radical reactions, and photochemistry. 

Among the most useful carbonyl derivatives are (V-acyloxazolidinones, and as we shall see in Section 2.3.4, they provide facial selectivity in aldol addition reactions. l,3-Thiazoline-2-thiones constitute another useful type of chiral auxiliary, and they can be used in conjunction with Bu2B03SCF3,44 Sn(03SCF3)2,45 or TiCl446 for generation of enolates. The stereoselectivity of the reactions is consistent with formation of a Z-enolate and reaction through a cyclic TS. 

The course of the reductive carbonylation reaction is considered to involve intially the alkoxycarbonyl complex 156, which attacks 150 to form the nickel enolates 157 followed by protonation [81]. (Scheme 56)... 

Two reports are available on the rearrangement of mixed vinyl phosphite esters to produce phosphonate diesters in moderate yield.94 95 In both instances, the vinyl phosphite esters were prepared by reaction of the dialkyl phosphorous chloride with highly enolized carbonyl compounds. The mixed ester products undergo thermal rearrangement to the phosphonate diesters (Figure 6.25). 

A reaction involving phosphorus trichloride providing a free phosphonic acid apparently involves an enolized carbonyl compound as the species attacking the phosphorus.96 Methyl aromatic ketones thus provide access to the vinylicphosphonic acids (Figure 6.26). 

Covalently bonded chiral auxiliaries readily induce high stereoselectivity for propionate enolates, while the case of acetate enolates has proved to be difficult. Alkylation of carbonyl compound with a novel cyclopentadienyl titanium carbohydrate complex has been found to give high stereoselectivity,44 and a variety of ft-hydroxyl carboxylic acids are accessible with 90-95% optical yields. This compound was also tested in enantioselective aldol reactions. Transmetalation of the relatively stable lithium enolate of t-butyl acetate with chloro(cyclopentadienyl)-bis(l,2 5,6-di-<9-isopropylidene-a-D-glucofuranose-3-0-yl)titanate provided the titanium enolate 66. Reaction of 66 with aldehydes gave -hydroxy esters in high ee (Scheme 3-23). 

Another major problem in oxidative carbonylation is the presence in the reaction medium of water, which, as we have seen, is even formed as a co-product when oxygen is used as reoxidant for Cu(I) or for M(X-2). In fact, in the presence of water, competitive M-promoted oxidation processes, such as oxidation of CO to C02, may take place, which reduce the activity of the catalyst towards the desired carbonylation reaction. The oxidation of CO to C02 may be promoted by Ir(IV), Pt(IV, II), Rh(III), and especially by Pd(II), and can be stoichiometric (Eq. 8) or catalytic (working in the presence of an oxidant such as 02, Cu(II) or quinone, Eq. 9). In the case of particularly water-sensible oxidative carbonylation processes, a dehydrating agent has proven necessary to achieve acceptable catalytic efficiencies and/or product yields. Several systems have been envisaged to eliminate water, such as acetals, enol ethers,... 

The oxidative carbonylation reaction of enolizable ketones follows the general routes already illustrated for simple alkenes. Thus, a-methoxycarbonyl-ation may occur either by addition of a Cl - Pd - C02Me species to the enolic... 

One of the most useful classes of metal and phase transfer catalyzed reactions are carbonylation reactions. Cobalt carbonyl is a valuable catalyst for such processes(1 ). When used in conjunction with methyl iodide, acetylcobalt carbonyl [CH3C0Co(C0) ] is generated and can undergo addition to various unsaturated substrates including alkynes and Schiff bases. In addition, one can add this species to styrene oxides to give the enol... 

As shown in Scheme 9.31, the (S)-enolate (100a), from Evans reagent 100. reacts on its Re face if the metal is not coordinated to the oxazolidone carbonyl group at the time of electrophilic attack, which is the normal situation in an uncatalysed boron enolate aldol reaction (see Scheme 9.14) and on the Si face if the metal is coordinated to the oxazolidone carbonyl group (lOOb), which is the normal situation in enolate alkylation (see 9.3.2). 

Enzymes with oxyanion holes are now known to catalyze a wide range of reactions with substrates that have a carbonyl moiety. The examples discussed in this chapter include thioesters, oxygen esters, peptides, and ketones (Figure 4.1). Two classes of high-energy intermediates with oxyanions are generated in these reactions (Table 4.3), a tetrahedral intermediate and an enolate. These reactions are... 

One of the most important factors for successful diastereoselection in chiral amide enolate alkylation reactions is the presence of strongly chelated ionic intermediates1 3. The chelation serves the purpose of locking the chiral auxiliary in a fixed position relative to the enolate. The metal counterion is chelated between the enolate oxygen and an additional polar group, anionic, carbonyl or ether oxygen attached to the chiral auxiliary. 

A more deep-seated change than decarboxylation can easily occur. You will remember that I have stressed all along that these carbonyl reactions are reversible, though we don t always show them as such. Even the format ion of carbon-carbon bonds is re vers ible. If we take some of this compound and treat it with EtO, will it form a substantial amount of enolate ... 

Several reactions of carbonyl compounds that have one or more a hydrogens proceed through the enol form. Reaction of ketones with chlorine, bromine, and iodine result in substitution of halogen for a hydrogen rates are typically first-order in ketone and independent of halogen concentration and even of which halogen is used. Racemization of ketones with asymmetric centers adjacent to the... 

In most cases98 conjugate addition-enolate alkylation reaction sequences do not exhibit particular sensitivity with respect to the identity of the alkyl group present in the alkyl alkenoate substrate. When a Michael donor has been chosen that reacts in both the 1,4- and 1,2-addition modes, it may be possible to choose an alkyl group for the ester substrate that forces the Michael donor to undergo exclusive 1,4-addition by sterically shielding the carbonyl carbon from attack by the nucleophile (equation 23)."... 

The stereochemical outcome of these electrophilic additions is consistent with a transition state in which the metal chelates the oxazolidinone carbonyl and the enolate oxygen. Reaction with an electrophile would, therefore, occur at the less hindered diastereotopic face of the (Z)-enolate, away from the shielding methyl groups of the auxiliary (Figure 24.6). Because both enantiomers of oxazolidinone 108 are equally available, the direction of the asymmetric induction can be controlled by proper choice of the absolute stereochemistry of the chiral auxiliary.106... 

By way of Mannich reaction (step 1) and /1-elimination (step 2), the transformations shown in Figures 12.14 and 12.15 demonstrate how an aldol condensation (for the term see Section 13.4.1) can be conducted under acidic conditions as well. Both the enamine reaction in Figure 12.18 and the enol ether reaction in Figure 12.23 illustrate the same thing differently. Many aldol condensations, however, start from carbonyl compounds only and proceed under basic conditions. They follow a totally different mechanism (Section 13.4.1). 

Silyl enol ethers, Reaction of carbonyl compounds with in situ generated BrSi(CH3)3 and triethylamine results mainly in the thermodynamic silyl ether, usually the (Z)-isomer. 

Treatment of silyl enolates with methyllithium followed by an addition of gallium trichloride affords the corresponding gallium enolates. The reaction of the resulting gallium enolates with a-halo carbonyl compounds in the presence of triethylborane provides 1,4-dicarbonyl compounds in good yields (Scheme 142).433... 

Tantalum enolate chemistry shows the dichotomy for the carbonylation reaction " of Cp Ta(CH2R)Cl3 with CO which results in the mono-THF adduct of rj -acyl complex Cp Ta(0=CCH2R)Cl3(THF) for R = t-Bu (the acyl group is anionic) but the isomeric enolate Cp Ta((Z)-7j -OCH=CHR)Cl3 for R = p-Tol. This invites the question of the relative thermodynamic stabilities of metal complexes of RCH2CO and RCHCHO and additionally the question of Z vs. E enolate stabilities. Only for organometalhc compounds (X = [M]) do we find examples where RCH2COX is less stable than RCH=CHOX. 

In modern organic chemistry, silyl enol ethers, as well as the corresponding titanium, tin, boron, or zirconium derivatives, are widely employed as nucleophilic components in enolate alkylation reactions. Their usefulness prompted the elaboration of numerous methods for the selective production of isomeri-cally pure enol ethers from almost any type of carbonyl compounds. 

There are a number of variations of the condensation reaction of acid derivatives. The reaction between a cyclic ketone having a pendant alkynyl ester unit and tetra-butylammonium fluoride leads to cyclization to a bicyclic alcohol with an exocyclic allene moiety. A chain-extension reaction culminates in acyl addition of an ester enolate. The reaction of a p-keto ester, such as methyl 3-oxobutanote and EtZnCH2k leads to chain extension via a carbenoid-like insertion reaction (p. 803), which reacts with an aldehyde in a second step to give a methyl 3-oxopentanoate derivative with a —CH(OH)R group at C-2 relative to the ester carbonyl. ... 

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