Aromatic, reaction with cyanide

The nickel-catalyzed transformation of aromatic halides into the corresponding nitriles by reaction with cyanide ions is reported. Both tris(triarylphosphine)nickel(0) complexes and tY2ins-chloro( aryl )bis( triarylphosphine )nickel(II) complexes catalyze the reaction. The influence of solvents, organophos-phines, and substituents on the aromatic nucleus on catalytic cyanation is studied. A mechanism of the catalytic process is suggested based on the study of stoichiometric cyanation of ti3ins-chloro(aryl)bis(triphenylphosphine)nickel-(II) complexes with NaCN and the oxidative addition reaction of Ni[P(C6H5)3]s with substituted aryl halides. 

Methoxy-l-nitronaphthalene (73a) and 1-nitronaphthalene (73b) undergo photochemical aromatic substitution reactions with cyanide (Scheme XXVIII). A two-fold increase in the quantum yield for the reaction is observed for (73a) when the reaction occurs in HDTC1 compared to aqueous solution 73). However, a 6800-fold catalytic increase in quantum yield is observed for (73b). SDS micelles decrease the quantum yield compared to aqueous solutions. The higher local concentration of cyanide near the HDTC1 micelles can explain a least partially the increase in quantum yield. However, the 6800-fold increase for (73b) is also due to a polarity effect on the reaction. This was demonstrated by an increase in the quantum yield of the reaction with decreasing polarity. 

Reaction with Cyanide Ion Reaction with Ilalide Ions Reaction with Amines Acetoxylation Reaction with Aromatics Reaction with Olefins Reaction with Ketones... 

Substitution at the aromatic ring (ipso-substitution) is also observed, but only in the cases of p-alkox-yphenylvinyUiahdes. The ipso-substitution process was first observed in the reaction with cyanide anion as the nucleophile. The irradiation illustrated in Equation 11.12 brings about double substitution followed by a cis-stilbene type photocycHzation to afford the dicyanophenanthrene shown. ... 

Arnold, D.R., McManus, K.A., and Chan, M.S.W., Photochemical nucleophile-olefin combination, aromatic substitution (photo-NOCAS) reaction. Part 13. The scope and limitations of the reaction with cyanide anions as the nucleophile. Can. J. Chem., 75, 1055,1997. 

The cleavage products of several sulfonates are utilized on an industrial scale (Fig. 3). The fusion of aromatic sulfonates with sodium hydroxide [1310-73-2J and other caustic alkalies produces phenohc salts (see Alkylphenols Phenol). Chlorinated aromatics are produced by treatment of an aromatic sulfonate with hydrochloric acid and sodium chlorate [7775-09-9J. Nitriles (qv) (see Supplement) can be produced by reaction of a sulfonate with a cyanide salt. Arenesulfonates can be converted to amines with the use of ammonia. This transformation is also rather facile using mono- and dialkylamines. 

Aromatic aldehydes 1 can undergo a condensation reaction to form a-hydroxy ketones 2 (also called benzoins) upon treatment with cyanide anions.This reaction, which is called benzoin condensation, works by that particular procedure with certain aromatic aldehydes and with glyoxals (RCOCHO). 

The preparation of a formyl-substituted aromatic derivative 3 from an aromatic substrate 1 by reaction with hydrogen cyanide and gaseous hydrogen chloride in the presence of a catalyst is called the Gattermann synthesis This reaction can be viewed as a special variant of the Friedel-Crafts acylation reaction. 

The electrophile 4 adds to the aromatic ring to give a cationic intermediate 5. Loss of a proton from 5 and concomitant rearomatization completes the substitution step. Subsequent hydrolysis of the iminium species 2 yields the formylated aromatic product 3. Instead of the highly toxic hydrogen cyanide, zinc cyanide can be used. The hydrogen cyanide is then generated in situ upon reaction with the hydrogen chloride. The zinc chloride, which is thereby formed, then acts as Lewis acid catalyst. 

A common method for the preparation of alkyl cyanide 2 is the treatment of corresponding alkyl halides 1 with cyanide. The corresponding reaction with aromatic substrates is called the Rosenmund-von-Braun reaction. 

Z)-compounds are formed in reactions with hydroxide, methoxide, cyanide, and sulfite ions, whereas (ii)-compounds are formed in most reactions with amines (formation of triazenes) and with diazo coupling components such as phenols and aromatic tertiary amines. 

When aromatic nitro compounds are treated with cyanide ion, the nitro group is displaced and a carboxyl group enters with cine substitution (p. 854), always ortho to the displaced group, never meta or para. The scope of this reaction, called the von Richter rearrangement, is variable. As with other nucleophilic aromatic substitutions, the reaction gives best results when electron-withdrawing groups are in ortho and para positions, but yields are low, usually < 20% and never > 50%. 

A particularly useful variation of this reaction uses cyanide rather than HCN. a-Amino nitriles can be prepared in one step by the treatment of an aldehyde or ketone with NaCN and NH4CI. This is called the Strecker synthesisand it is a special case of the Mannich reaction (16-15). Since the CN is easily hydrolyzed to the acid, this is a convenient method for the preparation of a-amino acids. The reaction has also been carried out with NH3-I-HCN and with NH4CN. Salts of primary and secondary amines can be used instead of NH to obtain N-substituted and N,N-disubstituted a-amino nitriles. Unlike 16-51, the Strecker synthesis is useful for aromatic as well as aliphatic ketones. As in 16-51, the Me3SiCN method has been used 64 is converted to the product with ammonia or an amine. ... 

Benzoin Condensation. The benzoin condensation is a related reaction consisting of treating an aromatic aldehyde with potassium cyanide or sodium cyanide usually in an aqueous ethanolic solution. Breslow studied the effects of inorganic salts on the rate... 

Arenes, on complexation with Cr, Fe, Mn, and so forth, acquire strongly electrophilic character such complexes in reactions with nucleophiles behave as electrophilic nitroarenes.71 Synthesis of aromatic nitriles via the temporary complexation of nitroarenes to the cationic cyclopentadienyliron moiety, cyanide addition, and oxidative demetalation with DDQ has been reported (Eq. 9.43).72... 

Nitrobenzenes react with potassium cyanide in the presence of cetyltrimethylammo-nium bromide to yield benzonitriles [71], The reaction also requires the presence of chloro substituents on the ring and at least two nitro groups (Table 2.9). Diazosulphides, ArN=NSPh, are converted into the benzonitriles, ArCN, by a photochemically induced SRN1 reaction with tetra-n-butylammonium cyanide [72, 73], Yields vary from <20% to >70%. Photocyanation of aromatic hydrocarbons has been achieved using tetra-n-butylammonium cyanide in acetonitrile or dichloromethane [74, 75]. 

Kanno. S.. Nojima. K.. and Ohya, T. Formation of cyanide ion or cyanogen chloride through the cleavage of aromatic rings by nitrous acid or chlorine. IV. On the reaction of aromatic hydrocarbons with hypochlorous acid in the presence of ammonium ion. Chemosphere, ll(7) 663-667,1982. 

Formylfuran behaves in a very similar manner to benzaldehyde and undergoes the usual reactions of an aromatic aldehyde, e.g. (i) the Cannizzaro reaction with cone, sodium hydroxide to give furan-2-ylmethanol and the sodium salt of furoic acid, (ii) the Perkin reaction with acetic anhydride and sodium acetate to yield an aldol product that dehydrates to 3-(furan-2-yl)propenoic acid, and (iii) a condensation with potassium cyanide in alcoholic solution to form furoin (under these conditions, benzaldehyde undergoes the benzoin condensation) (Scheme 6.32). 

Diimines of a-diketones—reaction of aromatic aldimines with sodium cyanide in DMSO at 20°C (72 hr) [57]. 

The Mannich reaction is a particularly good method of introducing a reactive functional group into a sensitive aromatic nucleus. The reaction has been very useful in ferrocene chemistry. Treatment of chromium acetylacetonate under Mannich conditions yielded a tris-V,N-dimethylaminomethyl chelate (XXXIII). This remarkable substance was very difficult to purify because of its extreme solubility in all solvents ranging from n-heptane to water. The trisamino chelate (XXXIII) is a deep purple, hydroscopic oil and behaves like a typical organic amine. Reaction of this amine with methyl iodide afforded a trisquater-nary ammonium salt (XXXIV), soluble in water but insoluble in organic solvents. When this salt (XXXIV) was treated with cyanide ion, trimethylamine was lost and the cyanomethyl chelate (XXXV) was formed. 

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