R-Butyl hydroperoxide-dialkyl

Oxidation reactions r-Butyl hydroperoxide-Dialkyl tar-trate-Titanium(IV) isopropoxide, 51 m-Chloroperbenzoic acid, 76 Reduction reactions Chlorodiisopinocampheylborane, 72 Diisobutylaluminum hydride-Tin(II) chloride- (S) -1 - [ l-Methyl-2-pyrrolidi-nyljmethylpiperidine, 116 Lithium borohydride, 92 Lithium tri-sec-butylborohydride, 21 B-3-Pinanyl-9-borabicyclo[3.3.1]-nonane, 249... 

OXIDATION, REAGENTS Barium mangan-ate. Benzyl(triethyl)ammonium permanganate. Bispyridinesilver permanganate. Bis(trimethylsilyl)peroxide. r-Butyl hydroperoxide. t-Butyl hydroperoxide-Benzyltri-methylammonium tetrabromooxomolyb-date. r-Butyl hydroperoxide-Bisoxobis-(2,4-pentadionato)molybdenum. r-Butyl hydroperoxide-Chromium carbonyl. r-Bu-tyl hydroperoxide-Dialkyl tartrate-Titan-ium(IV) isopropoxide. r-Butyl hydroper-... 

Peroxides are a common source of radical intermediates. Commonly used initiators include benzoyl peroxide, f-butyl peroxybenzoate, di-f-butyl peroxide, and r-butyl hydroperoxide. Reaction generally occurs at relatively low temperature (80° -100°C). The oxygen-oxygen bond in peroxides is weak ( 30kcal/mol) and activation energies for radical formation are low. Dialkyl peroxides decompose thermally to give two alkoxy radicals. ... 

In 1989, a method for the peroxysilylation of alkenes nsing triethylsUane and oxygen was reported by Isayama and Mnkaiyama (eqnation 25). The reaction was catalyzed by several cobalt(II)-diketonato complexes. With the best catalyst Co(modp)2 [bis(l-morpholinocarbamoyl-4,4-dunethyl-l,3-pentanedionato)cobalt(n)] prodnct yields ranged between 75 and 99%. DiaUcyl peroxides can also be obtained starting from tertiary amines 87, amides 89 or lactams via selective oxidation in the a-position of the Af-fnnctional group with tert-butyl hydroperoxide in the presence of a ruthenium catalyst as presented by Murahashi and coworkers in 1988 ° (Scheme 38). With tertiary amines 87 as substrates the yields of the dialkyl peroxide products 88 ranged between 65 and 96%, while the amides 89 depicted in Scheme 38 are converted to the corresponding peroxides 90 in yields of 87% (R = Me) and 77% (R = Ph). 

The HPLC method with CLD described in Section V.B.2.C for determination of hydroperoxides using luminol (124) with hemin (75a) catalysis is ineffective with dialkyl peroxides, such as di-r-butyl peroxide, cumyl propyl peroxide and cumyl 3-phenylpropyl peroxide. However, for a certain set of experimental conditions, cumyl allyl peroxide can be determined, but the sensitivity is much lower than for hydroperoxides164. 

The Sharpless asymmetric epoxidation of allylic alcohols (one of the reactions that helped K. Barry Sharpless earn his part of the 2001 Nobel Prize) offers a good example of an enantioselective technique that can be used to create either enantiomer of an epoxide product. This reaction uses a diester of tartaric acid, such as diethyl tartrate (DET) or diisopropyl tartrate (DIPT), as the source of chirality. The dialkyl tartrate coordinates with the titanium tetraisopropoxide [Ti(Oi-Pr)4] catalyst and t-butyl hydroperoxide (r-BuOOH) to make a chiral oxidizing agent. Since both enantiomers of tartaric acid are commercially available, and each enantiomer will direct the reaction to a different prochiral face of the alkene, both enantiomers of an epoxide can be synthesized. 

Secondary alcohols, such as isopropyl alcohol, j -butyl alcohol, 2-pentanol, 3-pentanol, cyclopentanol, and cyclohexanol, have been autoxidized to hydroxyaLkyl hydroperoxides (1, X = OH R = H) (10,44). These autoxidations usually are carried out at ca 20°C with uv radiation in the presence of a photosensitizer, eg, benzophenone. a-Oxygen-substituted dialkyl peroxides (2, X = Y = OH and X = Y = OOH), also are formed and sometimes they are the exclusive products (10). 

As was the case for the alkyl hydroperoxides in reaction 4, the enthalpies of the oxy-gen/hydrocarbon double exchange reaction 8 for dialkyl peroxides are different depending on the classification of the carbon bonded to oxygen. For R = Me, Et and f-Bu, the liquid phase values are —4, 24.6 and 52.7 kJmoR, respectively, and the gas phase values are 0.1, 25.7 and 56.5 kJmoR, respectively. For the formal deoxygenation reaction 9, the enthalpies of reaction are virtually the same for dimethyl and diethyl peroxide in the gas phase, —58.5 0.6 kJ moR. This value is the same as the enthalpy of reaction of diethyl peroxide in the liquid phase, —56.0 kJ moR (there is no directly determined liquid phase enthalpy of formation of dimethyl ether). Because of steric strain in the di-ferf-butyl ether, the enthalpy of reaction is much less negative, but still exothermic, —17.7 kJmol (Iq) and —19.6 kJmol (g). 

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