Benzyl chloride toluene from

the contents of the flask are directly distilled in a vacuum. After a fraction consisting of unchanged toluene has passed over, the bulk of the distillate is collected over a range of 7° (at 12 mm. between 63° and 70°). Pure benzyl chloride boils at 64°/12 mm. Yield 65-70 per cent of the theoretical. 

The preparation obtained by vacuum distillation is purer and keeps better than that distilled under atmospheric pressure, since in the latter case elimination of HC1 always occurs. 

Uses for benzyl cyanide (p. 137), ethyl benzylmalonate (p. 255), the Grignard reaction. 

Substitution occurs exclusively in the ring when typical halogen-carriers such as iron filings or iodine are used. From toluene the o-and p-derivatives are produced together. 

Benzyl chloride undergoes all the transformations of the alkyl halides. Hydrolysis with hot aqueous alkalis yields the corresponding alcohol, benzyl alcohol C6H5.CH2OH, a colourless liquid which boils at 206°. (Chap. V. 4, p. 220.) 

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Kennedy and Stock reported the first use of Oxone for many common oxidation reactions such as formation of benzoic acid from toluene and of benzaldehyde, of ben-zophenone from diphenyhnethane, of frawi-cyclohexanediol Ifom cyclohexene, of acetone from 2-propanol, of hydroquinone from phenol, of e-caprolactone from cyclohexanone, of pyrocatechol from salicylaldehyde, of p-dinitrosobenzene from p-phenylenediamine, of phenylacetic acid from 2-phenethylamine, of dodecylsulfonic acid from dodecyl mercaptan, of diphenyl sulfone from diphenyl sulfide, of triphenylphosphine oxide from triphenylphosphine, of iodoxy benzene from iodobenzene, of benzyl chloride from toluene using NaCl and Oxone and bromination of 2-octene using KBr and Oxone . Thus, they... 

Rates that are independent of aromatic substrate concentration have been found for reaction of benzyl chloride catalyzed by TiCl4 or SbFj in nitromethane. This can be interpreted as resulting from rate-determining formation of the electrophile, presumably a benzyl cation. The reaction of benzyl chloride and toluene shows a second-order dependence on titanium tetrachloride concentration under conditions where there is a large excess of hydrocarbon. ... 

Two methods were used to measure the chlorine leaving-group KIE for the 5n2 reduction of benzyl chloride to toluene by sodium borohydride in DMSO at 30 °C. One procedure involved the classical IRMS technique. The second method was a new technique in which the ratio of the chlorine isotopes was obtained by fast atom bombardment mass spectrometry on silver chloride recovered from the reaction. The KIE values found by the two methods were 1.007 and 1.008, respectively,... 

CHLOROCARBONSANDCHLOROHYDROCARBONS - BENZYL CHLORIDE, BENZAL CHLORIDE -from toluene (TOLUENE] (Vol 24)... 

Comments This procedure will yield /n-dinitrobenzene from either benzene or nitrobenzene, the p-nitro derivatives from chlorobenzene, bromo-benzene, benzyl chloride, etc. Toluene yields an oily mixture of 0- and p-nitro compounds and should be subjected to procedure (b). 

From the brief discussion above, one may wonder as to the actual utility of such CP-modified electrodes, apart from scientific curiosity. The answer to this question may lie in preliminary studies of their catalytic activity, which is discussed at length elsewhere in this book. Here we may cite one brief, illustrative example of such activity. Bedioui et al. [55] have polymerized a Co(TPP) with a pyrrole pendant group, yielding a poly(pyrrole) of sorts in direct contact with the electrode substrate, which has catalytically active Co "(TPP) pendant groups. These display all the normal Co(I/II/III) redox chemistry in both the conductive and insulating states of the poly(pyrrole) backbone. This modified electrode is able to catalyze the reduction of benzyl chloride to toluene. 

In the past benzal and benzyl chlorides were co-produced for the manufacture of benzaldehyde and benzyl alcohol, but today the vast majority of the benzaldehyde produced from benzal chloride is that which is made from recovered (by-product) material. For an historical article regarding the chlorination of toluene and the subsequent production of benzaldehyde, benzyl alcohol, and benzoic acid, see reference 4. 

Manufacture. Today benzyl alcohol is almost universally manufactured from toluene which is first chlorinated to give benzyl chloride [100-44-7]. This is then hydrolyzed to benzyl alcohol by treatment with aqueous sodium carbonate. 

Benzotrichloride is produced from total side-chain chlorination of toluene or of residual products from benzyl chloride production. In Western Europe, Bayer has the largest capacity (14,000 t/yr), and there are only two significant producers in the United States Occidental Chemical in Niagara EaUs, New York (20,000 t/yr), and Velsicol Chemical (11,000 t/yr). Total capacity in the western world is 68,000 t/yr and production of benzotrichloride in 1988 was estimated at 31,500 t. 

Benzyioxycarbonyi chioride (Cbz-Ci, benzyi cbioroformate) [501-53-1] M 170.6, b 103 /20mm, d 1.195, n 1.5190. Commercial material is better than 95% pure and may contain some toluene, benzyl alcohol, benzyl chloride and HCl. After long storage (e.g. two years at 4 , Greenstein and Winitz [The Chemistry of the Amino Acids Voi 2 p. 890, J Wiley and Sons NY, 1961] recommended that the liquid should be flushed with a stream of dry air, filtered and stored over sodium sulfate to remove CO2 and HCl which are formed by decomposition. It may further be distilled from an oil bath at a temperature below 85 because Thiel and Dent [Annalen 301 257 1898] stated that benzyioxycarbonyi chloride decarboxylates to benzyl chloride slowly at 100 and vigorously at 155 . Redistillation at higher vac below 85 yields material which shows no other peaks than those of benzyioxycarbonyi chloride by NMR spectroscopy. LACHRYMATORY and TOXIC. 

This acid, CgHj. CH COOH, is a sweet-smelling substance, especially recommended for sweetening soap perfumes. It occurs in neroli oil, and has a sweet honey-like odour. It is formed by converting toluene into benzyl chloride which is converted into benzyl cyanide, which is digested with dilute sulphuric acid, and so converted into phenyl-acetic acid. It is a crystalline body, melting at 76° to 76 5° and Iwiling at 266°. It has been isolated from oil of neroli. 

The ratio of the chloride mixture mainly derives from the toluene/chlo-rine ratio and the contact time. Benzyl chloride is produced hy passing dry chlorine into hoiling toluene (110°C) until reaching a density of 1.283. At this density, the concentration of henzyl chloride reaches the maximum. Light can initiate the reaction. 

Direct esr evidence for the intermediacy of radical-cations was obtained on flowing solutions of Co(III) acetate and a variety of substituted benzenes and polynuclear aromatics together in glacial acetic acid or trifluoroacetic acid solution . A p value of —2.4 was reported for a series of toluenes but addition of chloride ions, which greatly accelerated the reaction rate, resulted in p falling to —1.35. Only trace quantities of -CH2OAC adducts were obtained and benzyl acetate is the chief product from toluene, in conformity with the equation given above. 

Dehmlow and Klauck (1994) have shown how O- vs C-alkylations of 2-naphtholate, with benzyl bromide in toluene, in solid-liquid mode can be influenced by the PT catalyst (benzyltriethylammonium chloride) concentration. The ratio of O- to C-alkylated product could be varied from 0.02 to 7.5 depending on the catalyst concentration, temperature, etc. 

Benzyl radical abstracts C14 from S3 to give benzyl chloride and C13CS02 radical. This radical then fragments to give SO2 and CCI3, which then abstracts H- from toluene to complete the chain. 

Mechanistic aspects of the reduction of benzyl halides at mercury have been extensively investigated [35, 38]. From the reduction of benzyl iodide at platinum, Koch and coworkers [39] obtained toluene, bibenzyl, and hydrocinnamonitrile. Electrolysis of benzyl chloride in the presence of acyl chlorides can be used to synthesize alkyl benzyl ketones [40], whereas alcohols are formed by electrolysis of... 

Phenol (508) is found to be produced continuously from benzene (507) by aerial oxidation in aqueous sulfuric acid when a Cu(I)/Cu(II) redox couple is used as a mediator (Scheme 176) [581]. The Cu(I)-mediated electroreduction of oxygen in the presence of chloride is found to be effective for toluene oxidation, leading to benzaldehyde and benzyl chloride [582]. Recently, benzene has also been oxidized... 

SYNTHESIS A solution of 0.67 g 5-hydroxyindole (indol-5-ol) in 10 ml dry MeOH was treated with a solution of 0.30 g NaOMe in MeOH, followed by 0.70 g benzyl chloride. The mixture was heated on the steam bath for 0.5 h, and the solvent removed under vacuum. The residue was suspended between H20 and CH2CI2, the organic phase separated and the aqueous phase extracted once with CH2CI2. The combined organics were stripped of solvent under vacuum, and the residue distilled. A colorless fraction came over at 170-190 °C and spontaneously crystallized in the receiver. There was obtained 0.90 g (80%) 5-benzyloxyindole with a mp 81-86 °C which increased, on recrystallization from toluene / hexane, to 94-96 °C. A sample prepared from the decarboxylation of 5-benzyloxyindole-2-carboxylic acid has been reported to have a mp of 102 °C from benzene. 

Substituted benzyl chlorides were carbonylated using a Pd/tppts catalyst in aqueous/organic two phase systems under basic reaction conditions to afford the sodium salts of the corresponding phenylacetic acids. After acidification the phenylacetic acid dissolved in the organic phase and could be readily separated from the Pd/tppts catalyst contained in the aqueous phase (Figure 12) 466-468 TOFs up to 21 h 1 (turnover number, TON=165) and phenylacetic acid yields up to 94% were obtained at 70°C, 1 bar CO, tppts/Pd=10, NaOH/substrate=3/2 in an aqueous/toluene (1/1) two phase system in a batchwise procedure.466 The TOFs were improved to a maximum of 135 h 1 (TON=1560) in a continuous operation mode. Palladium catalysts modified with binas (Table 2 25) exhibited low catalytic activity (TONs up to 140) in the carbonylation of benzyl chloride 466 In strongly acidic media (pH=l) the Pd/25 catalyst was active and remained stable during the reaction which contrasts with Pd/tppts where palladium black was observed. However, the catalyst was completely deactivated after three cycles.466... 

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