Oxidation benzylic bromide

Among the few cases of oxidants examined, KMn04 was soluble in PEG 400, but the solutions were unstable and not further investigated. Potassium dichromate, K2Cr20y, is relatively soluble in PEG 400 and solutions about 0,15 molar could be prepared. These stable solutions oxidized benzyl bromide as well as allylic and benzylic alcohols with good yields of isolated products (Scheme 2), It should be mentioned that the aldehydes obtained by oxidation of allylic alcohols showed a 30% isomerization of the double bond. 

Solvent Preparation. The most critical aspect of the solvent is that it must be dry (less than 0.02 wt % of H2O) and free of O2. If the H2O content is above 0.02 wt %, then the reaction of Mg and RX does not initiate, except for an extremely reactive RX species, such as benzyl bromide. Although adventitious O2 does not retard the initiation process, the O2 reacts with the Grignard reagent to form a RMg02X species. Furthermore, upon hydrolysis, the oxidized Grignard reagent forms a ROH species that may cause purification problems. 

FIGURE 6.46 Oxidation chemistry of 5-(4-methylphenyl)- y-tocopherol (76), establishing a reaction system phenylogous to a-tocopherol (1), with quinone methide 77 and benzyl bromide 78 being the conjugatively stabilized, phenylogous counterparts of o-QM 3 and 5a-bromo-a-tocopherol (46), respectively. 

Thus, the reaction of alkyl halides and a-halo esters with sodium nitrite provides a very useful synthetic method for nitroalkanes and a-nitro esters. However, ethyl bromoacetate is exceptional in that it fails to give ethyl nitroacetate on treatment with sodium nitrite.93 This is due to the acidic hydrogen of the ethyl nitroacetate, which undergoes a further reaction with sodium nitrite to give the oxidized products (see Section 6.1, which discusses the Nef reaction). In a similar way, the reaction of benzyl bromide with sodium nitrite at 25 °C gives benzoic acid predominantly. To get phenylnitromethane, the reaction must be carried out at low temperature (-16 °C) (Eq. 2.48).93... 

Williams and Rastetter also accomplished an elegant synthesis of ( )-hyalodendrin (83) in 1980 [39]. Beginning with the sarcosine anhydride-derived enolic aldehyde 78, silyl protection of the enal enabled alkylation of the glycine center with benzyl bromide and thiolation using LDA and monoclinic sulfur a la Schmidt. After protection of the thiol with methylsulfenyl chloride and deprotection of the silyl ether, the enol was sulfenylated with triphenylmethyl chlorodisulfide to afford bis(disulfide) 82 as a 2 1 mixture of diastereomers favoring the anti isomer. Reduction of the disulfides with sodium borohydride and oxidation with KI3 in pyridine afforded ( )-hyalodendrin (83) in 29 % yield (Scheme 9.4). 

Acetyl-3-methyl-4,5-dihydrothiophen-4-one Benzyl alcohol, Hydrogen bromide, Iron Benzyl bromide, Molecular sieve Benzyl chloride, Catalytic impurities Benzyl fluoride l,2-Bis(chloromethyl)benzene Ethylene oxide, Contaminants Furoyl chloride... 

R = Me R = R = R = H, R = Me and R = R = H, R = R = Me) were reacted with the carbon electrophiles n-butyl, isopropyl and benzyl bromides, and isobutenyl chloride, in each case the alkylating agent attacked mainly at the carbon remote from the nitrogen, thus giving the conjugated product 82 (R = electrophile) with the double bond cis. Eth-oxide-catalyzed isomerization of 83 converted it to 84. °... 

Formerly, benzoic acid was produced by the decarboxylation of phthalic anhydride. Oxidation of acetophenon, benzyl bromide, and toluene with sulfur and water has been described in the literature, but are not commercially feasible routes of synthesis. Carboxylation of benzene with carbon dioxide is not practical due to the instability of benzoic acid at the required reaction conditions [8]. 

As an active initiator for a co-polymerization, acyl-cobalt complexes also work well. As demonstrated by Alper and Lee, an equimolar mixture of Go2(GO)s, benzyl bromide (BnBr), and dihydro-1,10-phenanthroline 17, possibly generating BnGOGo(GO)4 under the reaction conditions, co-polymerized PO or 1,2-butene oxide with GO, and the... 

Other Alkyl Ethers. Sucrose has been selectively etherified by electrochemical means to generate a sucrose anion followed by reaction with an alkyl halide (21,22). The benzylation of sucrose using this technique gives 2-O-benzyl- (49%), T-O-benzyl- (41%), and 3 -O-benzyl- (10%) sucrose (22). The benzylation of sucrose with benzyl bromide and silver oxide in DMF also produces the 2-O-benzyl ether as the principal product, but smaller proportions of T- and 3 -ethers (23). Octadienyl ether derivatives of sucrose, intermediates for polymers, have been prepared by a palladium-catalyzed telomerization reaction with butadiene in 2-propanol—water (24). 

Reduction of the complex on Raney nickel yielded benzylamine, N-methyl-benzylamine, and N,N-dimethylbenzylamine but no / -phenylbenzylamine, a reduction product resulting under the same reaction conditions from benzyl cyanide. Hydrolysis with dilute sulfuric acid in acetic acid yielded benzylamine only, and oxidation of the complex with potassium permanganate gave 4.2 moles of benzoic acid per mole of complex. The bromide anion can be exchanged metathetically with various other anions such as perchlorate, iodide, and thiocyanate. When heated at 100° C. in vacuum, the complex lost one mole of benzyl bromide and yielded only one dicyanotetrakis(benzylisonitrile)iron(II) complex. 

Benzyl bromide was obtained from Aldrich Chemical Company, Inc., and purified by passage through 5 g of activated basic aluminum oxide. 

According to visible spectra (Figure 6) and potentiometric titration, the concentration of bromide ion decreases gradually as toluene oxidation proceeds, but the total amount of bromide ion after treating the solution with alkali remains constant (Figure 7). The bromide ion converted to organic bromides (benzyl bromide) during the oxidation can be hardly... 

During the workup of the o-xylene oxidation run, a strong lachrymator made its presence felt. This was probably a-bromo-o-xylene, although it was not detected in the low voltage mass spectrum. We suspected that a strong peak at mass 104, undoubtedly caused chiefly by a fragment ion derived from o-methylbenzyl alcohol by loss of H20 (I), might also contain a contribution from benzocyclobutene from the interaction of a-bromo-o-xylene with the indium tube used to introduce samples into the spectrometer. To test this possibility, benzyl bromide and a-bromo-o-xylene were run separately under the same conditions. 

Ellis K. Fields We have found o-methylbenzyl bromide among the oxidation products of o-xylene. Even though this bromide persists during the oxidation period and appears to solvolyze somewhat more slowly than other benzyl bromides, it releases its bromine eventually to initiate and propagate free radical chains. 

A mixture of benzyl-fl-i>-galactopyranoside U (1 mmol) and dibutyltin oxide (1 mmol) in benzene was refluxed for 16 b, with azeotropic removal of water. The solution was evaporated to approximately 25 mL, tetrabutylammonium iodide (1 mmol) and benzyl bromide (0.25 mL) woe added, and the mixture was refluxed for 2 h. Evaporation to... 

The 2,3-dihydrobenzo[6]selenophene (113) yields the oxide (114) on treatment with ozone. The oxide may be ring opened by treatment with sodium hydride and the product of the ring opening can be alkylated by reaction with benzyl bromide. Thermal rearrangement of the oxide yields a 15 85 mixture of compounds (115) and (116) (Scheme 15) (76JOC2503). 

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