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Oxides carbon-hydrogen bonds

Several kinetic models for photocatalytic processes have been proposed. One of the possible reaction paths for the initiation of the degradation reaction of several hydrocarbon compounds appears to be an oxidative carbon-hydrogen bond cleavage by hydroxyl radicals attack. Hydroxyl radicals are generated as a consequence of electron transfer to the semiconductor holes by adsorbed hydroxyl ions or water molecules (Turchi and Ollis, 1990). [Pg.156]

In addition to olefin oxidation, carbon-hydrogen bond oxidation has also been extensively investigated. Thus, the group of Que Jr. and by Costas have... [Pg.398]

Oxidation of carbon corresponds to an increase in the number of bonds between carbon and oxygen or to a decrease in the number of carbon-hydrogen bonds Conversely reduction corresponds to an increase in the number of carbon-hydrogen bonds or to a decrease in the number of carbon-oxygen bonds From Table 2 4 it can be seen that each successive increase m oxidation state increases the number of bonds between carbon and oxygen and decreases the number of carbon-hydrogen bonds Methane has four C—H bonds and no C—O bonds car bon dioxide has four C—O bonds and no C—H bonds... [Pg.87]

Like most other engineering thermoplastics, acetal resins are susceptible to photooxidation by oxidative radical chain reactions. Carbon—hydrogen bonds in the methylene groups are principal sites for initial attack. Photooxidative degradation is typically first manifested as chalking on the surfaces of parts. [Pg.57]

Ca.ta.lysis, Iridium compounds do not have industrial appHcations as catalysts. However, these compounds have been studied to model fundamental catalytic steps (174), such as substrate binding of unsaturated molecules and dioxygen oxidative addition of hydrogen, alkyl haHdes, and the carbon—hydrogen bond reductive elimination and important metal-centered transformations such as carbonylation, -elimination, CO reduction, and... [Pg.181]

L = P(CH3)3 or CO, oxidatively add arene and alkane carbon—hydrogen bonds (181,182). Catalytic dehydrogenation of alkanes (183) and carbonylation of bensene (184) has also been observed. Iridium compounds have also been shown to catalyse hydrogenation (185) and isomerisation of unsaturated alkanes (186), hydrogen-transfer reactions, and enantioselective hydrogenation of ketones (187) and imines (188). [Pg.182]

The reaction rate of molecular oxygen with alkyl radicals to form peroxy radicals (eq. 5) is much higher than the reaction rate of peroxy radicals with a hydrogen atom of the substrate (eq. 6). The rate of the latter depends on the dissociation energies (Table 1) and the steric accessibiUty of the various carbon—hydrogen bonds it is an important factor in determining oxidative stabiUty. [Pg.223]

Most rubbers used in adhesives are not resistant to oxidation. Because the degree of unsaturation present in the polymer backbone of natural rubber, styrene-butadiene rubber, nitrile rubber and polychloroprene rubber, they can easily react with oxygen. Butyl rubber, however, possesses small degree of unsaturation and is quite resistant to oxidation. The effects of oxidation in rubber base adhesives after some years of service life can be assessed using FTIR spectroscopy. The ratio of the intensities of the absorption bands at 1740 cm" (carbonyl group) and at 2900 cm" (carbon-hydrogen bonds) significantly increases when the elastomer has been oxidized [50]. [Pg.640]

There are also reactions in which hydride is transferred from carbon. The carbon-hydrogen bond has little intrinsic tendency to act as a hydride donor, so especially favorable circumstances are required to promote this reactivity. Frequently these reactions proceed through a cyclic TS in which a new C—H bond is formed simultaneously with the C-H cleavage. Hydride transfer is facilitated by high electron density at the carbon atom. Aluminum alkoxides catalyze transfer of hydride from an alcohol to a ketone. This is generally an equilibrium process and the reaction can be driven to completion if the ketone is removed from the system, by, e.g., distillation, in a process known as the Meerwein-Pondorff-Verley reduction,189 The reverse reaction in which the ketone is used in excess is called the Oppenauer oxidation. [Pg.429]

The unsaturated structure of the diene hydrocarbon rubbers makes them susceptible to attack by both oxygen and ozone. Oxidative degradation of all rubbers, irrespective of their structures, is inevitable as the energy associated with incident natural light is approximately three times that of a typical carbon-carbon or carbon-hydrogen bond. [Pg.134]

Organometals and metal hydrides as electron donors in addition reactions 245 Oxidative cleavage of carbon-carbon and carbon-hydrogen bonds 253 Electron-transfer activation in cycloaddition reactions 264 Osmylation of arene donors 270... [Pg.193]

OXIDATIVE CLEAVAGE OF CARBON-CARBON AND CARBON-HYDROGEN BONDS... [Pg.253]

Oxidation of sp3 Carbon-Hydrogen Bonds of Simple Alkanes... [Pg.67]

The oxidation of alkanes involves what is formally the insertion of an oxygen atom into a carbon-hydrogen bond (Fig. 4.41), although the reality of the mechanism is considerably more complex. [Pg.67]

Oxidation of Benzylic and Allylic sp3 Carbon-Hydrogen Bonds... [Pg.71]

Oxidative attack on a carbon-hydrogen bond of an alkyl group a to a nitrogen atom is not restricted to saturated aliphatic amines. In fact X in an X-N-CH- structural subunit can be virtually any common atomic grouping that can be found in stable organic molecules. For example, w-carbon hydrogens of Aralkyl-substituted aromatic cyclic amines (119), aryl amines (120), amides (121), amidines (122), A-nitrosodialkylamines (123), etc. are all subject to oxidative attack, carbinolamine formation, and in most cases release of an aldehyde or ketone depending on the substitution pattern (1° or 2°)... [Pg.79]


See other pages where Oxides carbon-hydrogen bonds is mentioned: [Pg.75]    [Pg.392]    [Pg.75]    [Pg.392]    [Pg.67]    [Pg.22]    [Pg.122]    [Pg.237]    [Pg.73]    [Pg.78]    [Pg.398]    [Pg.610]    [Pg.162]    [Pg.104]    [Pg.91]    [Pg.15]    [Pg.119]    [Pg.151]    [Pg.98]    [Pg.172]    [Pg.913]    [Pg.917]    [Pg.361]    [Pg.391]    [Pg.29]    [Pg.66]    [Pg.31]    [Pg.31]    [Pg.37]    [Pg.38]    [Pg.68]    [Pg.70]    [Pg.75]    [Pg.78]   
See also in sourсe #XX -- [ Pg.3 , Pg.4 , Pg.5 , Pg.6 ]




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Carbon-hydrogen bonds

Carbon-hydrogen bonds cleavage, anodic oxidation

Carbon-hydrogen bonds oxidative addition

Carbon-hydrogen bonds, oxidation

Manganese oxidation carbon-hydrogen bonds

Oxidation of carbon-hydrogen bond

Oxidative rearrangements carbon-hydrogen bond activation

Oxides bonding

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