Peroxy acids alkane oxidation

Other examples of oxidant-iron(III) adducts as intermediates in iron porphyrin-catalyzed reactions have been published as listed in references 54a-k. Competitive alkene epoxidation experiments catalyzed by iron porphyrins with peroxy acids, RC(0)00F1, or idosylarenes as oxidants have been proposed to have various intermediates such as [(porphyrin)Fe (0-0-C(0)R] or [(porphyrin)Fe (0-I-Ar)]. Alkane hydroxylation experiments catalyzed by iron porphyrins with oxidant 3-chloroperoxybenzoic acid, m-CPBA, have been proposed to operate through the [(porphyrin)Fe (0-0-C(0)R] intermediate. J. P. CoUman and co-workers postulated multiple oxidizing species, [(TPFPP )Fe =0] and/or [(TPFPP)Fe (0-I-Ar)] in alkane hydroxylations carried out with various iodosylarenes in the presence of Fe(TPFPP)Cl, where TPFPP is the dianion of me50-tetrakis(pentafluorophenyl)porphyrin. ... 

Figure 16 Intermediates involved in alkane oxidation by cytochrome P450. Catalytic cycles involving either O2 and electrons (from NADPH), or a single oxygen atom donor (AO) are shown. Model reactions often use single oxygen atom donors AO such as iodosylbenzene, amine A-oxides and organic or inorganic hydroperoxides or peroxy acids ...

Soluble derivatives of various metals catalyze the alkane oxidation by peroxy-acids (or by HjOj in strong acids as solvents). Examples of these reactions are summarized in Table X.4. 

The oxidation of alkanes by r-butyl hydroperoxide (TBHP) has been catalysed by titanium alkoxides, producing the corresponding alcohols and ketones. A radical mechanism is proposed in which r-butoxyl radical formed from TBHP and titanium alkoxide initiates the reaction. The evolution of oxygen (from the decomposition of peroxide) and the abstraction of hydrogen from alkane to form alkyl radical occur competitively. A method for the determination of both the primary and secondary KIEs at a reactive centre based on starting-material reactivities allows the determination of the separate KIEs in reactions for which neither product analysis nor absolute rate measurements are applicable. It has been applied to the FeCls-catalysed oxidation of ethylbenzene with TBHP, which exhibits both a primary KIE and a substantial secondary KIE the findings are in accordance with previous mechanistic studies of this reaction. The oxidation of two l-arylazo-2-hydroxynaphthalene-6-sulfonate dyes by peroxy-acids and TBHP catalysed by iron(III) 5,10,15,20-tetra(2,6-dichloro-2-sulfonatophenyl)porphyrin [Fe(ni)P] is a two-step process. In single turnover reactions, dye and Fe(in)P compete for the initially formed OFe(IV)P+ in a fast reaction and OFe(IV)P is produced the peroxy acid dye stoichiometry is 1 1. This is followed by a slow phase with 2 1 peroxy acid dye stoichiometry [equivalent to a... 

Determination of the residual antioxidant content in polymers by HPLC and MAE is one way to determine the amoimt needed for reasonable stabilization of a material, and also to compare different antioxidants and their individual efficiencies. During ageing and oxidation of PE, carboxyhc acids, dicarboxylic acids, alcohols, ketones, aldehydes, n-alkanes and 1-alkenes are formed [86-89]. The carboxyhc acids are formed as a result of various reactions of alkoxy or peroxy radicals [90]. The oxidation of polyolefins is generally monitored by various analytical techniques. GC-MS analysis in combination with a selective extraction method is used to determine degradation products in plastics. ETIR enables the increase in carbonyls on a polymer chain, from carboxylic acids, dicarboxyhc acids, aldehydes, and ketones, to be monitored. It is regarded as one of the most definite spectroscopic methods for the quantification and identification of oxidation in materials, and it is used to quantify the oxidation of polymers [91-95]. Mechanical testing is a way to determine properties such as strength, stiffness and strain at break of polymeric materials. 

The mechanism is assumed to be a radical cleavage of the peroxy bond in peroxy-disulfuryl difluoride, subsequent H abstraction of the FSO3 radical at the alkane and oxidation of the resulting radical to a cation . In carboxylic acid oxidation a subsequent rapid hydrogen shift rearranges the cation preferentially to the electrostatically least deactivated (co — 1) position (see Section II.B). 

Since during the Purex process TBP, alkane, and aqueous nitric acid solution are in mixture or contact condition, the radiation chemical transformations depend on the composition, concentration of nitric acid, contaminant metal ions, irradiation conditions, and oxygen concentration (Triphathi and Ramanujam 2003 Katsumura 2004). Under aerated condition, the organic radicals react with oxygen forming peroxy radicals. After successive reactions a variety of alcohols, ketones, peroxides, and carbonyl compounds form. The ratio of nitration products to oxidation products is 0.8, and the ratio increases if there is no sufficient supply of O2. 

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