Nucleophilic Attack on Halogen

Nucleophilic Attack on Halogen.- (/ )-( +)-2,2-dimethylpropan( H)ol has been converted to the chloride with inversion of configuration using triphenylphosphine and carbon tetrachloride. The corresponding reaction using carbon tetrabromide gave the bromide with considerable racemiza-tion.  

Geranyl chloride can be prepared from geraniol by the careful use of triphenylphosphine in carbon tetrachloride. Tris(dimethylamino)phosphine reacts with carbon tetrachloride to form the complex (42) which can be used to form the enol esters (43) from acid anhydrides. Similarly, aldehydes form the alkenes (44), and esters or amides of trichloroacetic acid are converted to glycidic esters.  

The simultaneous addition of ammonia or amines and carbon tetrachloride to phosphines yields aminophosphonium chlorides (45). 

The use of the triphenylphosphine-carbon tetrachloride adduct for dehydration reactions appears to be a very simple way of synthesizing nitriles from amides, carbodi-imides from ureas, and isocyanides from monosubstituted formamides. All of these reactions involve the simultaneous addition of triphenylphosphine, carbon tetrachloride, and tri-ethylamine to the compound to be dehydrated. The elimination of the elements of water is stepwise. An adduct, e.g. (46), is first formed, chloroform being eliminated, which decomposes to produce hydrogen chloride and the dehydrated product. 

The same reagents can be used to form amides from carboxylic acids and amines, a method which is applicable to peptide synthesis. Condensation of A-benzyloxycarbonyl-L-phenylalanine and ethyl glycinate hydrochloride gave an 85% yield of purified dipeptide. 

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Nucleophilic Attack on Halogen.—Tris(dimethylamino)phosphine and carbon tetrachloride has been used to prepare C-glycosides (38) which are precursors for C-nucleosides. Carbon tetrachloride and the silylaminophosphines (39) can give different products, (40) or (41), depending on the reaction conditions. ... 

PTC has been used for the reactions of carbanions with CCI4, hex-achloroethane, etc. (for review, see Ref 45). These processes consist of nucleophilic attack on halogen atom (halophilic reaction) and result in halogenation of the carbanions. Depending on the structure of the carbanion and other factors, halogenated product often enters further reactions (eq. 95). 

A key step in the reaction mechanism appears to be nucleophilic attack on the alkyl halide by the negatively charged copper atom but the details of the mechanism are not well understood Indeed there is probably more than one mechanism by which cuprates react with organic halogen compounds Vinyl halides and aryl halides are known to be very unreactive toward nucleophilic attack yet react with lithium dialkylcuprates... 

Because of thetr electron deficient nature, fluoroolefms are often nucleophihcally attacked by alcohols and alkoxides Ethers are commonly produced by these addition and addition-elimination reactions The wide availability of alcohols and fliioroolefins has established the generality of the nucleophilic addition reactions The mechanism of the addition reaction is generally believed to proceed by attack at a vinylic carbon to produce an intermediate fluorocarbanion as the rate-determining slow step The intermediate carbanion may react with a proton source to yield the saturated addition product Alternatively, the intermediate carbanion may, by elimination of P-halogen, lead to an unsaturated ether, often an enol or vinylic ether These addition and addition-elimination reactions have been previously reviewed [1, 2] The intermediate carbanions resulting from nucleophilic attack on fluoroolefins have also been trapped in situ with carbon dioxide, carbonates, and esters of fluorinated acids [3, 4, 5] (equations 1 and 2)... 

A much faster reaction for bromides than chlorides usually suggests attack on halogen, since bromine is more readily attacked by nucleophilic phosphorus. However, for phenyl acetylenes (82 = Ph) these rates... 

As with chlorine-containing oxidants, JV-bromo species have been used to oxidize sulphoxides to sulphones (with no bromine incorporation) through the initial formation of a bromosulphonium ion, by nucleophilic attack of the sulphoxide sulphur atom on the electrophilic halogen atom. Such reactions involve JV-bromosuccinimide ° bromamine-T, iV-bromoacetamide ° and iV-bromobenzenesulphonamide. All reported studies were of a kinetic nature and yields were not quoted. In acid solution all oxidations occurred at or around room temperature with the nucleophilic attack on the electrophilic bromine atom being the rate-limiting step. In alkaline solution a catalyst such as osmium tetroxide is required for the reaction to proceed . ... 

Direct nucleophilic displacement of halo substituents proceeds via attack on the ring carbon atom (see Section 5.10.5.6). Nucleophilic attack on the halogen has not been reported. 

Both reactions involve nucleophilic attack of tricoordinated phosphorus on tetrahedral carbon and show all the characteristics of non-polar reactants combining through polar transition states although the solvent effects are sometimes quite modest.— Subsequent studies have demonstrated nucleophilic attack on activated alkenes,Z activated alkynes,Z the carbonyl groupZ-Z and halogen , whilst in the Perkow reaction (eqn. 1) all four possible sites in... 

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