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Carbonyl groups halides

Carbonyl Compounds I. Aldehydes and Ketones. Addition Reactions of the Carbonyl Group halides). The naming of these compounds is described in Sections 7-4 to 7-7. [Pg.672]

Alkyl halides and sulfonates are the most frequently used alkylating acceptor synthons. The carbonyl group is used as the classical a -synthon. O-Silylated hemithioacetals (T.H. Chan, 1976) and fomic acid orthoesters are examples for less common a -synthons. In most synthetic reactions carbon atoms with a partial positive charge (= positively polarized carbon) are involved. More reactive, "free carbocations as occurring in Friedel-Crafts type alkylations and acylations are of comparably limited synthetic value, because they tend to react non-selectively. [Pg.15]

Carbonylation of halides in the presence of primary and secondary amines at I atm affords amides[351j. The intramolecular carbonylation of an aryl bromide which has amino group affords a lactam and has been used for the synthesis of the isoquinoline alkaloid 498(352], The naturally occurring seven-membered lactam 499 (tomaymycin, neothramycin) is prepared by this method(353]. The a-methylene-d-lactam 500 is formed by the intramolecular carbonylation of 2-bromo-3-alkylamino-l-propene(354]. [Pg.196]

The alkenylzirconium 685, prepared by hydrozirconation of a terminal alkyne with hydrozirconocene chloride, reacts with alkenyl halide to afford the conjugated diene 686(545]. The Zr reagent can be used even in the presence of the carbonyl group in 687, which is sensitive to Al and Mg reagents. [Pg.228]

There ate numerous alkyltitaniums, and many of their reactions resemble those of alkyllithiums and alkylmagnesium halides. They ate protolyzed by water and alcohols, R Ti(R )3 + HA — RH + A-Ti(R )3 they insert oxygen, R TiR + O2 — ROTiR and they add to a carbonyl group ... [Pg.154]

The unstable CH TiCl [12747-38-8] from (CH3 )2 2n + TiCl forms stable complexes with such donors as (CH2)2NCH2CH2N(CH2)2, THF, and sparteine, which methylate carbonyl groups stereoselectively. They give 80% of the isomer shown and 20% of the diastereomer this is considerably more selective than the mote active CH MgBt (201). Such complexes or CH2Ti(OC2H2 methylate tertiary halides or ethers (202) as follows ... [Pg.154]

I Primary alkyl halides S 2 substitution occurs if a good nucleophile is used, 2 elimination occurs if a strong base is used, and ElcB elimination occurs if the leaving group is two carbons away from a carbonyl group. [Pg.394]

Conversion of Acid Halides into Acids Hydrolysis Acid chlorides react with water to yield carboxylic acids. This hydrolysis reaction is a typical nucleophilic acyl substitution process and is initiated by attack of water on the acid chloride carbonyl group. The tetrahedral intermediate undergoes elimination of Cl and loss of H+ fo give the product carboxylic acid plus HC1. [Pg.802]

The reactivity of an acid derivative toward substitution depends both on the steric environment near the carbonyl group and on the electronic nature of the substituent, Y. The reactivity order is acid halide > acid anhydride > thioester > ester > amide. [Pg.826]

Ethyl 3-oxobutanoate, commonly called ethyl acetoacetate or ace tome tic ester, is much like malonic ester in that its ct hydrogens are flanked by two carbonyl groups. It is therefore readily converted into its enolate ion, which can be alkylated by reaction with an alkyl halide. A second alkylation can also be carried out if desired, since acetoacetic ester has two acidic a hydrogens. [Pg.859]

Another alternative for preparing a primary amine from an alkyl halide is the Gabriel amine synthesis, which uses a phthalimide alkylation. An imide (—CONHCO—) is similar to a /3-keto ester in that the acidic N-H hydrogen is flanked by two carbonyl groups. Thus, imides are deprotonated by such bases as KOH, and the resultant anions are readily alkylated in a reaction similar to the acetoacetic ester synthesis (Section 22.7). Basic hydrolysis of the N-alkylated imide then yields a primary amine product. The imide hydrolysis step is analogous to the hydrolysis of an amide (Section 21.7). [Pg.929]

In all the desulphonylation reactions discussed in Sections III.B and III.C the sulphur is lost from the starting sulphone and is reduced in the process simultaneously, the former carbon-sulphur bond is either reduced to a C—H bond or is converted into a C=C bond. The reactions described in this section have the common thread that the sulphur atom is lost with reduction at sulphur, but the carbon atom is converted directly into a carbonyl group. Formally, these reactions offer a route from alkyl halides to aldehydes or ketones. [Pg.961]

Polk et al. reported27 that PET fibers could be hydrolyzed with 5% aqueous sodium hydroxide at 80°C in the presence of trioctylmethylammonium bromide in 60 min to obtain terephthalic acid in 93% yield. The results of catalytic depolymerization of PET without agitation are listed in Table 10.1. The results of catalytic depolymerization of PET with agitation are listed in Table 10.2. As expected, agitation shortened the time required for 100% conversion. Results (Table 10.1) for the quaternary salts with a halide counterion were promising. Phenyltrimethylammonium chloride (PTMAC) was chosen to ascertain whether steric effects would hinder catalytic activity. Bulky alkyl groups of the quaternary ammonium compounds were expected to hinder close approach of the catalyst to the somewhat hidden carbonyl groups of the fiber structure. The results indicate that steric hindrance is not a problem for PET hydrolysis under this set of conditions since the depolymerization results were substantially lower for PTMAC than for die more sterically hindered quaternary salts. [Pg.547]

Similar additions have been successfully carried out with carboxylic acids, anhydrides, acyl halides, carboxylic esters, nitriles, and other types of compounds. These reactions are not successful when the alkene contains electron-withdrawing groups such as halo or carbonyl groups. A free-radical initiator is required, usually peroxides or UV light. The mechanism is illustrated for aldehydes but is similar for the other compounds ... [Pg.1034]

The decarboxylation reaction usually proceeds from the dissociated form of a carboxyl group. As a result, the primary reaction intermediate is more or less a carbanion-like species. In one case, the carbanion is stabilized by the adjacent carbonyl group to form an enolate intermediate as seen in the case of decarboxylation of malonic acid and tropic acid derivatives. In the other case, the anion is stabilized by the aid of the thiazolium ring of TPP. This is the case of transketolases. The formation of carbanion equivalents is essentially important in the synthetic chemistry no matter what methods one takes, i.e., enzymatic or ordinary chemical. They undergo C—C bond-forming reactions with carbonyl compounds as well as a number of reactions with electrophiles, such as protonation, Michael-type addition, substitution with pyrophosphate and halides and so on. In this context,... [Pg.337]

See other pages where Carbonyl groups halides is mentioned: [Pg.82]    [Pg.231]    [Pg.20]    [Pg.48]    [Pg.595]    [Pg.426]    [Pg.129]    [Pg.164]    [Pg.485]    [Pg.595]    [Pg.1037]    [Pg.108]    [Pg.396]    [Pg.139]    [Pg.18]    [Pg.580]    [Pg.856]    [Pg.381]    [Pg.107]    [Pg.525]    [Pg.540]    [Pg.542]    [Pg.907]    [Pg.21]    [Pg.177]    [Pg.16]    [Pg.95]    [Pg.182]    [Pg.247]    [Pg.619]   
See also in sourсe #XX -- [ Pg.137 ]



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