Disproportionation in addition

The perhydroxyl radical is a relatively weak and short-lived oxidizing agent. Together with their conjugate bases (i.e., H02 /02 ), these radicals disappear in aqueous solution in the absence of the other reactants by pH-dependent disproportionation. In addition, the disproportionation reaction of H02 /02 contributes to the regeneration of H202/ as shown below ... 

Liquid chlorine dioxide, ClOj, boils at 284 K to give an orange-yellow gas. A very reactive compound, it decomposes readily and violently into its constituents. It is a powerful oxidising agent which has recently found favour as a commercial oxidising agent and as a bleach for wood pulp and flour. In addition, it is used in water sterilisation where, unlike chlorine, it does not produce an unpleasant taste. It is produced when potassium chlorate(V) is treated with concentrated sulphuric acid, the reaction being essentially a disproportionation of chloric(V) acid ... 

Chemical Properties. In addition to the reactions Hsted in Table 3, boron trifluoride reacts with alkali or alkaline-earth metal oxides, as well as other inorganic alkaline materials, at 450°C to yield the trimer trifluoroboroxine [13703-95-2] (BOF), MBF, and MF (29) where M is a univalent metal ion. The trimer is stable below — 135°C but disproportionates to B2O2 and BF at higher temperatures (30). 

Japan held 37.5% of the world antibiotic market ki 1988, the USA 23.2%, Italy 8.0%, the United Kingdom 5.4%, Germany 3.6%, and other countries 22.3% (20). The disproportionate size of the Japanese market is in part a consequence of the inherent strengths of Japanese industry which include expertise in fermentation technology and intensive chemical manipulation of known stmctures. In addition, antibiotic prescribing in Japan is extremely popular among doctors as a result of the Japanese reimbursement system. 

Organochlorosilanes containing Si—H disproportionate in the presence of aluminum chloride without addition of more organosilane. Organic groups can be replaced by hydrogen (157). For example, tetraphenylsdane [1048-08-4] can be made from phenylmethylsilane [766-08-5]. 

In addition to the trialkyldihalo- and triaryldihalo antimony compounds, mixed dihalo compounds such as chi oroiodo triphenyl antimony [7289-82-9], (CgH3)2SbClI, have been reported (182). It has been shown, however, that such compounds disproportionate ia solutioa to give a mixture of startiag material plus products (183) ... 

The principal chemical uses of BTX are illustrated in Figure 1 and Hsted in Table 1 (2). A very wide range of consumer products from solvents to fibers, films, and plastics are based on BTX. The consumption of BTX is approximately in the proportions of 67 5 28, respectively. However, no BTX process gives BTX in these proportions. The economic value of benzene and xylenes (especially -xylene) is normally higher than that of toluene. Because of this, processes that convert toluene to benzene by hydrodealkylation (3) and disproportionate toluene to benzene and xylenes (4) have been commercialized. In addition, reforming processes that emphasize production of either benzene or -xylene [106 2-3] have been described (5). Since these are not classified as BTX processes they are not discussed in detail here. 

The stoichiometry in acid solution implies that, in addition to the more usual disproportionation into C103 and Cl , the following disproportionation also occurs ... 

Since no relatively stable free radical is present (such as 26 in 14-17), most of the product arises from dimerization and disproportionation. The addition of a small amount of nitrobenzene increases the yield of arylation product because the nitrobenzene is converted to diphenyl nitroxide, which abstracts the hydrogen from 1 and reduces the extent of side reactions. ... 

As described in the previous section, the silica-alumina catalyst covered with the silicalite membrane showed exceUent p-xylene selectivity in disproportionation of toluene [37] at the expense of activity, because the thickness of the sihcahte-1 membrane was large (40 pm), limiting the diffusion of the products. In addition, the catalytic activity of silica-alumina was not so high. To solve these problems, Miyamoto et al. [41 -43] have developed a novel composite zeohte catalyst consisting of a zeolite crystal with an inactive thin layer. In Miyamoto s study [41], a sihcahte-1 layer was grown on proton-exchanged ZSM-5 crystals (silicalite/H-ZSM-5) [42]. The silicalite/H-ZSM-5 catalysts showed excellent para-selectivity of >99.9%, compared to the 63.1% for the uncoated sample, and independent of the toluene conversion. 

The chemistry of iron(IV) in solid-state materials and minerals is restricted to that of oxides, since other systems such as iron(IV)-halides are not stable [186]. Iron(lV) oxides are easy to handle because they are usually stable in air, but they often have a substoichiometric composition, with oxygen vacancies contributing to varying degrees. Moreover, the samples may contain different amounts of iron(lll) in addition to the intended iron(IV) oxide, a complication which may obscure the Mossbauer data [185]. Even iron(V) was found in iron(IV) oxides due to temperature-dependent charge disproportionation [188, 189]. 

We think two mechanisms take place at the same ime. Besides the P -elimination mechanism, which has been described above as a kind of disproportionation, an a-elimination like the Harrod mechanism seems also to take place. From the experimental results, the polymerization of trisilanes or tetrasilanes yields preferably the dimeric species, hexa- or octa-silanes respectively. In addition, oligosilanes with odd numbers of silicon atoms were formed. We do not yet understand why these hexa-and octasilanes were formed in the iso-forms. 

A very serious problem was to clear up the formation of hydroperoxides as the primary product of the oxidation of a linear aliphatic hydrocarbon. Paraffins can be oxidized by dioxygen at an elevated temperature (more than 400 K). In addition, the formed secondary hydroperoxides are easily decomposed. As a result, the products of hydroperoxide decomposition are formed at low conversion of hydrocarbon. The question of the role of hydroperoxide among the products of hydrocarbon oxidation has been specially studied on the basis of decane oxidation [82]. The kinetics of the formation of hydroperoxide and other products of oxidation in oxidized decane at 413 K was studied. In addition, the kinetics of hydroperoxide decomposition in the oxidized decane was also studied. The comparison of the rates of hydroperoxide decomposition and formation other products (alcohol, ketones, and acids) proved that practically all these products were formed due to hydroperoxide decomposition. Small amounts of alcohols and ketones were found to be formed in parallel with ROOH. Their formation was explained on the basis of the disproportionation of peroxide radicals in parallel with the reaction R02 + RH. 

In addition to two peroxyl radicals, H02 and R1R2C(0H)00 , participating in chain propagation in the oxidized alcohols, there are three reactions that are guilty of chain termination in the oxidized alcohols. The most probable reaction between them is disproportionation. 

In addition to disproportionation, another mechanism of the alkylhyroxyperoxyl radical chain termination is recombination [38,39],... 

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