Alkyl halides with carbonyls

Barbierreactions. In nitrile solvents, the condensation of alkyl halides with carbonyl compounds gives alcohols. The reaction between esters and iodoalkanes proceeds only in the presence of Nil. With an iron(IIl) salt as a catalyst, cyclic A-iodoalkyl imides form polycyclic enamides via carbinol lactams. ... 

An aldehyde or ketone reacts with a phosphorus ylide to yield an alkene in which the oxygen atom of the carbonyl reactant is replaced by the =0 2 of the ylide. Preparation of the phosphorus ylide itself usually involves reaction of a primary alkyl halide with triphenylphosphine, so the ylide is typically primary, RCH = P Ph)3-This means that the disubstituted alkene carbon in the product comes from the carbonyl reactant, while the monosubstituted alkene carbon comes from the ylicle. 

Nitriles are similar in some respects to carboxylic acids and are prepared either by SN2 reaction of an alkyl halide with cyanide ion or by dehydration of an amide. Nitriles undergo nucleophilic addition to the polar C=N bond in the same way that carbonyl compounds do. The most important reactions of nitriles are their hydrolysis to carboxylic acids, reduction to primary amines, and reaction with organometallic reagents to yield ketones. 

Iron-acyl enolates such as 1, 2, and 3 react readily with electrophiles such as alkyl halides and carbonyl compounds (see Houben-Weyl, Vol. 13/9a p418). The reactions of these enolatc species with alkyl halides and similar electrophiles are discussed in Section D.1.1.1.3.4.1.3. To date, only the simple enolates prepared by a-deprotonation of acetyl and propanoyl complexes have been reacted with ketones or aldehydes. 

The procedure involves C-alkylation of an a-sulfonyl carbanion derived from 245 with alkyl halides or carbonyl compounds, followed by cleavage of the cyclopropanols 247 produced by deprotection of the hydroxy group of 246 to give (E)-substituted aldehydes141. 

Addition of Bu3SnLi or McsSnI.i to 4-t-butylcyclohexanone affords mixtures of trans and cis adducts in ratios that depend on reaction conditions (Table ll)68. In THF, a 93 7 mixture is obtained with both reagents. This ratio is thought to represent the thermodynamic distribution—the axial stannane being favored. In ether, the cis isomer predominates, suggesting a kinetic preference for equatorial addition. Each of the two isomers can be lithiated with BuLi. Subsequent treatment with alkyl halides or carbonyl compounds affords the substituted alkoxy cyclohexanes with retention of stereochemistry. 

Acceptor-substituted allenes can be prepared from the corresponding propargyl precursors by prototropic isomerization (see Section 7.2.2). Conversely, such allenes can also be used to synthesize propargyl compounds. For example, treatment of the sulfoxides 417 with 1 equivalent of a lithiation reagent leads to the intermediates 418, which furnish propargyl sulfoxides 419 by hydrolysis (Scheme 7.55) [101]. If the electrophiles used are not protons but primary alkyl halides or carbonyl compounds, the products 420 or 421, respectively, are formed by C,C linkage. 

Catalytic processes based on the use of electrogenerated nickel(O) bipyridine complexes have been a prominent theme in the laboratories of Nedelec, Perichon, and Troupel some of the more recent work has involved the following (1) cross-coupling of aryl halides with ethyl chloroacetate [143], with activated olefins [144], and with activated alkyl halides [145], (2) coupling of organic halides with carbon monoxide to form ketones [146], (3) coupling of a-chloroketones with aryl halides to give O -arylated ketones [147], and (4) formation of ketones via reduction of a mixture of a benzyl or alkyl halide with a metal carbonyl [148]. 

Alkylation at the 2-position can be achieved by formation of the anion with sodium hydride in 1,2-dimethoxyethane (DME) at 0°C followed by reaction with an alkyl halide at room temperature. Alternatively, selective alkylation at C-4 Involves sequential treatment with sodium hydride (at 10°C) and butyllithlum in DME (at -40°C) to form the dianion, followed by kinetic alkylation with an alkyl halide (or carbonyl compound). ... 

Oxathiolane 3,3-dioxide (332) metallates in its 2-position to yield an anion which reacts with various electrophiles (alkyl halides and carbonyl compounds) to give substituted oxathiolanes (333) in good to excellent yield (79TL3375). Pyrolysis of these alkylated products affords the corresponding aldehydes or 2-hydroxyaldehydes in addition to sulfur dioxide and isobutylene (Scheme 71). The oxathiolane (332) thus becomes another member of the already burgeoning class of carbonyl anion equivalents. 

Carbonylation (see also Formylation) of alkyl halides with loss of X (RX— RCHO)... 

The ring opening of tetrahydro-l,3-oxazines to aldehydes has recently found wide application through the work of Meyers.2-3 2-Alkylidene-tetrahydro-l,3-oxazines, prepared from the readily available 5,6-dihydro-4//-1,3-oxazines, possess strong nucleophilic properties and can react with alkyl halides and carbonyl compounds. The derivatives so obtained can be reduced to tetrahydro-l,3-oxazines, and through ring opening the latter can furnish acyclic, alicyclic, and a,jS-unsaturated aldehydes and their C-l deuterated derivatives.221-223 228... 

Recently, organic carbamates have been synthesized by the reaction of amines and alkyl halides with scC02 in the presence of potassium carbonate and an onium salt (Bu4N)Br [52]. In order to ascertain the carbonyl-active species (carbonate or C02 ), the reaction was carried out also with potassium phosphate instead of the carbonate salt the similar results obtained confirmed that scC02 acted in the process not only as a solvent but also as a carboxylating agent. 

Enals vinyl silyl ketones.1 The anion of I reacts smoothly with va rious electrophiles (alkyl halides, epoxides, carbonyl compounds). The products are converted to (E)-enals by oxidation with 30% H202. 

In general, the zinc promoted condensation of alkyl halides with aliphatic aldehydes and ketones gives only poor results.2 In contrast good results are obtained when one of the reactants is unsaturated. Thus the addition of an allylic group to a carbonyl compound, or the conjugate addition of an alkyl moiety to an activated olefin, occur in excellent yields. Some corrections to this schematic view will be given in the following discussion. 

The overall reaction involves replacing the halogen atom of the alkyl halide with an NH, unit. Another method is the Gabriel synthesis of amines. This involves treating phthalimide with KOH to abstract the N-H proton. The N-H proton of phthalimide is more acidic (pK9) than the N-H proton of an amide since the anion formed can be stabilised by resonance with both neighbouring carbonyl groups. The phthalimide ion can then be alkylated by treating it with an alkyl halide in nucleophilic substitution. 

An alkyl halide can undergo an elimination reaction if it has a susceptible proton situated on a (1-carbon, i.e. the carbon next to the C-X group. This proton is lost during the elimination reaction along with the halide ion. In some respects, there is similarity here between alkyl halides and carbonyl compounds (Following fig.). Alkyl halides can have susceptible protons at the (1-position whilst carbonyl compounds can have acidic protons at their a-position. By comparing both structures, it can be seen that the acidic/ susceptible proton is attached to a carbon neighbouring an electrophilic carbon. 

Also ketones and aldehydes react with the lithiated bis-lactim ether 7 with rather high asymmetric induction to give the aldol-type adduct 13 (Table 2). Like alkyl halides, the carbonyl compounds enter trans to the methyl group at C-6 i.e. (R)-configuration is induced at C-3 13). 

Oxathiolane 2,2-dioxide undergoes metallation with n-butyllithium as expected at the 3-position (81JOC101). The anion may be alkylated with alkyl halides or carbonyl compounds. The isomeric 1,3-oxathiolane 3,3-dioxides also undergo metallation ortho to the sulfone and, when the 4-position is blocked, metallation at the 2-position may be used as an efficient conversion of alkyl halides into aldehydes as shown in Scheme 22 (79TL3375). 

We have already encountered one type of organometallic compound with a negative charge on carbon sodium acetylides, covered in Section 9-7. Terminal alkynes are weakly acidic, and they are converted to sodium acetylides by treatment with an unusually strong base, sodium amide. These sodium acetylides are useful nucleophiles, reacting with alkyl halides and carbonyl compounds to form new carbon-carbon bonds. 

You have now seen how enols and enolates react with electrophiles based on hydrogen (deuterium), carbon, halogens, silicon, sulfur, and nitrogen. What remains to be seen is how new carbon-carbon bonds can be formed with alkyl halides and carbonyl compounds in their normal electrophilic mode. These reactions are the subject of Chapters 26-29. We must first look at the ways aromatic compounds react with electrophiles. You will see similarities with the behaviour of enols. 

So the only remaining question is when thioamides combine with a-haloketones, which atom (N or S) attacks the ketone, and which atom (N or S) attacks the alkyl halide Carbonyl groups are hard electrophiles—their reactions are mainly under charge control and so they react best with basic nucleophiles (Chapter 12). Alkyl halides are soft electrophiles—their reactions are mainly under frontier orbital control and they react best with large uncharged nucleophiles from the lower rows of the periodic table. The ketone reacts with nitrogen and the alkyl halide with sulfur. 

Phenylsulfonyl)tetrahydropyran 369 has been lithiated with w-BuLi at — 78 °C to give the anion 370, which has been allowed to react with alkyl halides and carbonyl compounds (Scheme 97)548. The corresponding 2-substituted derivatives suffered after aqueous work-up spontaneous /3-elimination of benzenesulfmic acid to give products 371. When the alkyl halide has an additional protected hydroxy group at the y- or 5-position (such as in compound 372), spiroketals (e.g. compound 373, Scheme 97) were obtained, this methodology having been applied to the synthesis of ionophore antibiotic CP 61,405 (routiennocin)550. 

Vinyl selenides have been lithiated at the a-position by LDA983,984 at —78 °C in THF to give a-(arylselanyl)vinyllithiums 680, a-(methylselanyl)vinyllithiums 681 being obtained by selenium-lithium transmetallation from l,l-bis(methylselanyl)alkenes with n-BuLi in THF or t-BuLi in ether at —78 °C985 986. These intermediates reacted with alkyl halides, epoxides, carbonyl compounds and DMF985, the final deprotection being performed by mercury(II) salts986. 

Metallated 1-ethoxy-1,3-dienes 697 and 712, obtained from the corresponding acetals by means of the LICKOR base, have been treated with alkyl halides, epoxides, carbonyl compounds, carbon dioxide and carboxylic esters affording ( )-l-substituted 1-ethoxy-1,3-dienes and, after hydrolysis, a,P-unsaturated carbonyl compounds1007-1010 (Scheme 186). Intermediates 697 and 712 have been transformed into the corresponding vinyl stan-nanes, which were submitted to Stille couplings with iodobenzene and benzoyl chloride823. 

---