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Alkyl hydroperoxides formed

Alkyl hydroperoxides form stable alkaU metal salts with caustic however, when equimolar amounts of the hydroperoxide and its sodium salt are present in aqueous solution, rapid decomposition to tert-AcohoX and oxygen occurs (28). [Pg.103]

Vinyl-substituted aromatic compounds such as a-methylstyrene,148 /S-isopropylstyrene,148 1-phenylcyclohexene,153 indene, 149 and 1,2-dihydronaphthalene151,152 give cyclic peroxides on autoxidation. For example, /3-isopropylstyrene gives the 1,2-dioxene derivative (149) together with polymeric peroxide. After the isopropyl group had been reduced with sodium sulfite, 149 could be isolated in 26.4% yield by means of an alumina column. [Pg.204]

Chemical structure of hydroperoxide forming the initial complex. This alters the structure and spin state of the Fe" + complex and, consequently, affects dominant product pathways (73). H2O2 forms low spin complexes that undergo heterolytic scission, whereas alkyl hydroperoxides form high spin complexes that release alkoxyl radicals in homolytic scissions (81). [Pg.323]

In most cases dialkyl peroxides arise from the alkyl hydroperoxides formed as primary products this is so in autoxidation of isochroman,333 phthalan,334 2-methyl-l,3-dioxolane,344 and tetrahydroacenaphthacene.345 Formation of dialkyl peroxides from alkyl hydroperoxides can occur under the influence of acids, and in this ionic dimerization 333,334 hydrogen peroxide is also formed ... [Pg.310]

The structure giving rise directly to the excited state is now clearly seen as a dioxetanone such as (2) or (22). Cyclisation of the alkyl hydroperoxide forms a strained per-ester - a very much stronger oxidant. Since the electron rich donor is part of the same molecule it is not surprising that reaction is thought to be instantaneous, precluding isolation. [Pg.160]

Although primary and secondary alkyl hydroperoxides are attacked by free radicals, as in equations 8 and 9, such reactions are not chain scission reactions since the alkylperoxy radicals terminate by disproportionation without forming the new radicals needed to continue the chain (53). Overall decomposition rates are faster than the tme first-order rates if radical-induced decompositions are not suppressed. [Pg.103]

The susceptibihty of dialkyl peroxides to acids and bases depends on peroxide stmcture and the type and strength of the acid or base. In dilute aqueous sulfuric acid (<50%) di-Z fZ-butyl peroxide is resistant to reaction whereas in concentrated sulfuric acid this peroxide gradually forms polyisobutylene. In 50 wt % methanolic sulfuric acid, Z fZ-butyl methyl ether is produced in high yield (66). In acidic environments, unsymmetrical acychc alkyl aralkyl peroxides undergo carbon—oxygen fission, forming acychc alkyl hydroperoxides and aralkyl carbonium ions. The latter react with nucleophiles,... [Pg.107]

Primary and secondary alkyl haUdes and sulfonates react with potassium superoxide to form dialkyl peroxides (101,102) (eq. 28). Dia2oalkanes, eg, dia2omethane, have been used to alkylate hydroperoxides (66) (eq. 29). [Pg.109]

In the presence of strong acid catalysts such as sulfuric acid, aUphatic (R CHO) aldehydes react with alkyl hydroperoxides, eg, tert-55ky hydroperoxides, to form hydroxyalkyl alkyl peroxides (1), where X = OH R, = hydrogen, alkyl and = tert — alkyl. [Pg.114]

Most ozonolysis reaction products are postulated to form by the reaction of the 1,3-zwitterion with the extmded carbonyl compound in a 1,3-dipolar cycloaddition reaction to produce stable 1,2,4-trioxanes (ozonides) (17) as shown with itself (dimerization) to form cycHc diperoxides (4) or with protic solvents, such as alcohols, carboxyUc acids, etc, to form a-substituted alkyl hydroperoxides. The latter can form other peroxidic products, depending on reactants, reaction conditions, and solvent. [Pg.117]

There are several available terminal oxidants for the transition metal-catalyzed epoxidation of olefins (Table 6.1). Typical oxidants compatible with most metal-based epoxidation systems are various alkyl hydroperoxides, hypochlorite, or iodo-sylbenzene. A problem associated with these oxidants is their low active oxygen content (Table 6.1), while there are further drawbacks with these oxidants from the point of view of the nature of the waste produced. Thus, from an environmental and economical perspective, molecular oxygen should be the preferred oxidant, because of its high active oxygen content and since no waste (or only water) is formed as a byproduct. One of the major limitations of the use of molecular oxygen as terminal oxidant for the formation of epoxides, however, is the poor product selectivity obtained in these processes [6]. Aerobic oxidations are often difficult to control and can sometimes result in combustion or in substrate overoxidation. In... [Pg.186]

The common initiators of this class are f-alkyl derivatives, for example, t-butyl hydroperoxide (59), Aamyl hydroperoxide (60), cumene hydroperoxide (61), and a range of peroxyketals (62). Hydroperoxides formed by hydrocarbon autoxidation have also been used as initiators of polymerization. [Pg.92]

The formed hydroxyperoxide decomposes into free radicals much more rapidly than alkyl hydroperoxide [128]. So, the equilibrium addition of the hydroperoxide to the ketone changes the rate of formation of the radicals. This effect was first observed for cyclohexanone and 1,1-dimethylethyl hydroperoxide [128]. In this system, the rate of radical formation increases with an increase in the ketone concentration. The mechanism of radical formation is described by the following scheme ... [Pg.196]

Chain propagation in an oxidized aldehyde is limited by the reaction of the acylperoxyl radical with the aldehyde. The dissociation energy of the O—H bond of the formed peracid is sufficiently higher than that of the alkyl hydroperoxide. For example, in hydroperoxide PhMeCHOOH, Z)0 H = 365.5 kJ mol-1 and in benzoic peracid... [Pg.326]

These BDEs are higher than that for alkyl hydroperoxides (see Chapter 2) and this is the main reason for the extremely high reactivity of peroxyl radicals formed from aldehydes. The absolute rate constants of the reactions of different peroxyl radicals with aldehydes are collected in Table 8.7. [Pg.333]

The important role of reaction enthalpy in the free radical abstraction reactions is well known and was discussed in Chapters 6 and 7. The BDE of the O—H bonds of alkyl hydroperoxides depends slightly on the structure of the alkyl radical D0 H = 365.5 kJ mol 1 for all primary and secondary hydroperoxides and P0—h = 358.6 kJ mol 1 for tertiary hydroperoxides (see Chapter 2). Therefore, the enthalpy of the reaction RjOO + RjH depends on the BDE of the attacked C—H bond of the hydrocarbon. But a different situation is encountered during oxidation and co-oxidation of aldehydes. As proved earlier, the BDE of peracids formed from acylperoxyl radicals is much higher than the BDE of the O—H bond of alkyl hydroperoxides and depends on the structure of the acyl substituent. Therefore, the BDEs of both the attacked C—H and O—H of the formed peracid are important factors that influence the chain propagation reaction. This is demonstrated in Table 8.9 where the calculated values of the enthalpy of the reaction RjCV + RjH for different RjHs including aldehydes and different peroxyl radicals are presented. One can see that the value A//( R02 + RH) is much lower in the reactions of the same compound with acylperoxyl radicals. [Pg.333]

The experimental data are in agreement with this equation. In the presence of dioxygen, the alkyl radicals formed from enol rapidly react with dioxygen and thus the formed peroxyl radicals react with Fe2+ with the formation of hydroperoxide. The formed hydroperoxide is decomposed catalytically to molecular products (AcOH and AcH) as well as to free radicals. The free radicals initiate the chain reaction resulting in the increase of the oxidation rate. [Pg.408]

The majority of the titanium ions in titanosilicate molecular sieves in the dehydrated state are present in two types of structures, the framework tetrapodal and tripodal structures. The tetrapodal species dominate in TS-1 and Ti-beta, and the tripodals are more prevalent in Ti-MCM-41 and other mesoporous materials. The coordinatively unsaturated Ti ions in these structures exhibit Lewis acidity and strongly adsorb molecules such as H2O, NH3, H2O2, alkenes, etc. On interaction with H2O2, H2 + O2, or alkyl hydroperoxides, the Ti ions expand their coordination number to 5 or 6 and form side-on Ti-peroxo and superoxo complexes which catalyze the many oxidation reactions of NH3 and organic molecules. [Pg.149]

On one hand, systematic analysis of the reaction medium liquid phase by H and C NMR in the presence of a standard has shown that siloxy (-OSiMe3, -OSiEts) Hgands are easily displaced from the metallic centers and leach during the reaction. Their de-coordination by exchange with the alkyl hydroperoxide is irreversible because they form condensation products such as R3SiOSiR3 and R3SiOO Bu with... [Pg.114]

See other pages where Alkyl hydroperoxides formed is mentioned: [Pg.320]    [Pg.412]    [Pg.432]    [Pg.435]    [Pg.320]    [Pg.412]    [Pg.432]    [Pg.435]    [Pg.227]    [Pg.103]    [Pg.114]    [Pg.127]    [Pg.73]    [Pg.195]    [Pg.677]    [Pg.677]    [Pg.138]    [Pg.288]    [Pg.585]    [Pg.619]    [Pg.818]    [Pg.261]    [Pg.162]    [Pg.55]    [Pg.73]    [Pg.103]    [Pg.104]    [Pg.309]    [Pg.309]    [Pg.310]    [Pg.313]    [Pg.315]    [Pg.320]   


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