Radicals heteroatom-based

Using a similar approach, Evans and co-workers obtained values of hsi = -1.50, kcsi = 0.55, 8 = 0.15 for a series of trimethylsilyl-substituted naphthalene radical anions based on a Q value of -26.1 49). For phenyltrimethylsilylacetylene radical anion, the values of the heteroatom parameters that gave the best fit of the Huckel calculated spin densities with experimental values, using a Q value of 28, were hs, = -1.3, and kCSi = 0.65 when a 8 value of 0.1 was assumed. A resulting C—Si 7r-bond order of about 0.3 is obtained 43). 

The converse situation in which ring closure is initiated by the attack of a carbon-based radical on the heteroatom has been employed only infrequently (Scheme 18c) (66JA4096). The example in Scheme 18d begins with an intramolecular carbene attack on sulfur followed by rearrangement (75BCJ1490). The formation of pyrrolidines by intramolecular attack of an amino radical on a carbon-carbon double bond is exemplified in Scheme 19. In the third example, where cyclization is catalyzed by a metal ion (Ti, Cu, Fe, Co " ), the stereospecificity of the reaction depends upon the choice of metal ion. 

Interestingly, homolytic substitution at boron does not proceed with carbon centered radicals [8]. However, many different types of heteroatom centered radicals, for example alkoxyl radicals, react efficiently with the organoboranes (Scheme 2). This difference in reactivity is caused by the Lewis base character of the heteroatom centered radicals. Indeed, the first step of the homolytic substitution is the formation of a Lewis acid-Lewis base complex between the borane and the radical. This complex can then undergo a -fragmentation leading to the alkyl radical. This process is of particular interest for the development of radical chain reactions. 

Volume I. Liquid-Phase, Base-Catalyzed and Heteroatom Oxidations, Radical Initiation and Interactions, Inhibition... 

The effects of heteroatoms on autoxidation reactions are reviewed and discussed in terms of six phenomena (1) the effect on reactivity of a-hydrogens in the hydroperoxide chain mechanism in terms of electron supply and withdrawal (2) the effect on a-hydrogen acidity in base-catalyzed oxidation (3) the effect on radical ion stability in base-catalyzed redox chains (4) the possibility of heteroatom hydrogen bond attack and subsequent reactions of the resulting heteroradical (5) the possibility of radical attack on higher row elements via valence expansion (6) the possibility of radical addition to electron-deficient II and III group... 

Alkanes can be prepared by the addition of carbon radicals to C=C double bonds (Figure 5.4). The highest yields are usually obtained when electron-rich radicals (e.g. alkyl radicals or heteroatom-substituted radicals) add to acceptor-substituted alkenes, or when electron-poor radicals add to electron-rich double bonds. These reactions have also been performed on solid phase, and polystyrene-based supports seem to be particularly well suited for radical-mediated processes [39,40]. 

Whereas base-induced deprotonation at a heteroatom is very fast (practically diffusion-controlled), deprotonation at carbon is generally much slower (Eigen et al. 1964, 1965). Thus, this type of 02 -elimination is observed at higher pH values compared to the reactions discussed before. The elimination of HO2 is subject to steric restrictions, but the OH -induced 02 -elimination is not, and at high pH all hydroxycyclohexadienylperoxyl radicals eliminate 02 bringing the phenolate yield close to 100% [reactions (9) and (14)/(15)] competing reactions (see below) are thereby suppressed. 

Radical Cations and their Conjugate Bases, the Heteroatom-Centered Radicals 217... 

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