Elimination reactions radicals

The primary and secondary products of photolysis of common diazirines are collected in Table 4. According to the table secondary reactions include not only isomerization of alkenes and hydrogen elimination to alkynes, but also a retro-Diels-Alder reaction of vibrationally excited cyclohexene, as well as obvious radical reactions in the case of excited propene. 

In this reaction, too, the stability of the radical being eliminated is the major factor in determining the rate of fragmentation. 

The first three chapters discuss fundamental bonding theory, stereochemistry, and conformation, respectively. Chapter 4 discusses the means of study and description of reaction mechanisms. Chapter 9 focuses on aromaticity and aromatic stabilization and can be used at an earlier stage of a course if an instructor desires to do so. The other chapters discuss specific mechanistic types, including nucleophilic substitution, polar additions and eliminations, carbon acids and enolates, carbonyl chemistry, aromatic substitution, concerted reactions, free-radical reactions, and photochemistry. 

In a few cases extensive cleavage of the substrate molecule occurs The case documented [JS] involves beta cleavage of tetramethylorthocarbonate and tri-methylorthoacetate The mechanism of this reaction involves the formation of a radical which can form a more stable radical by eliminating a stable molecule by beta cleavage Interestingly tetramethylorthocarbonate seems to suffer less cleav age by the LTG method [9] Examples of beta cleavage during direct fluorination are shown in equahons 6-9, where AF is aerosol direct fluorination procedure... 

Claisen rearrangement, 1194-1195 dehydration, 622 elimination reactions, 393 oxidation, 625-626 radical reactions, 243-244 characteristics of, 162-164 comparison with laboratory reactions, 162-164 conventions for writing, 162. 190 energy diagram of, 161 reduction, 723-725 reductive animation, 932 substitution reactions, 381-383 Biological reduction, NADH and, 610-611... 

Though there is still debate about detailed mechanism, in each of the processes (a-c) the propagating species is believed to be a conventional propagating radical. Thus, termination by radical-radical reaction is not eliminated, though, as we shall see, with appropriate choice of reaction conditions, the significance of this process can be markedly reduced. 

A5-hexenyl substituent, extensive cyclization occurs to yield the cyclopentylcarbinyl product from the yields of uncyclized and cyclized products for A5-hexenylmercury chloride, the rate constants for equation 50 have been estimated (vide supra). The SH2 reaction 49 has also been invoked to be the key step in the alkylation of -substituted styrenes by a free-radical addition-elimination sequence, namely96... 

In pulse radiolysis studies it is feasible to eliminate undesired radical reactions by the use of "scavengers". For example, to produce a totally reducing system simple aliphatic alcohols are added and the ensuing reaction... 

These reactions can take place by either heterolytic or pericyclic mechanisms. Examples of the latter are shown on page 1322. Free-radical P eliminations are extremely rare. In heterolytic ehminations, W and X may or may not leave simultaneously and may or may not combine. 

Organic halides play a fundamental role in organic chemistry. These compounds are important precursors for carbocations, carbanions, radicals, and carbenes and thus serve as an important platform for organic functional group transformations. Many classical reactions involve the reactions of organic halides. Examples of these reactions include the nucleophilic substitution reactions, elimination reactions, Grignard-type reactions, various transition-metal catalyzed coupling reactions, carbene-related cyclopropanations reactions, and radical cyclization reactions. All these reactions can be carried out in aqueous media. 

The driving force of the reaction is the formation of a more stable radical, i.e. the unpaired electron is delocalised more effectively by Q in (1276) than by H in (127a). Migration of fluorine does not occur as its d orbitals are not accessible, and migration of Br only rarely as the intermediate radicals undergo elimination (to alkene) more readily than rearrangement. 

The sequence of S l reactions (see the section 7.1.1 discussing the radical reaction) and elimination of HN02 provide a new synthetic method for various kinds of alkenes. For example,... 

Anions 207, derived from l-(diarylmethyl)benzotriazoles 206, can be oxidized with mild oxidants to relatively stable triaryl radicals 208. One of the possible reactions of radicals 208 is ring opening to give radicals 209. Elimination of nitrogen from 209 produces unstable species 210 that undergo intramolecular cyclization to phenan-thridines 211 (Scheme 25) <1996JHC607, 1998JOC1467>. When substituents X and Y are identical, products 211... 

Analysis of the data in Table XVIII suggests that silene formation is kinetically the most favorable process. However, according to experiment, metallated silenes are formed. This is related to the fact that in polar solvents proton transfer from the carbon atom to silicon is intermolecular, which leads to a considerable decrease in the reaction barrier. We believe that when the migration of substituents from the carbon atom to silicon is suppressed, for example, by the introduction of two alkyl radicals, the elimination of phosphines resulting in silene formation becomes the most probable process. 

Oxidative radical cyclization of fi-keto esters. Radical cyclizations of unsaturated 0-keto esters initiated by Mn(III) acetate (1) can be terminated by oxidative 0-hydride elimination by Cu(OAc)2 (equation I). This radical reaction can... 

Antioxidants act so as to interrupt this chain reaction. Primary antioxidants, such as hindered phenol type antioxidants, function by reacting with free radical sites on the polymer chain. The free radical source is reduced because the reactive chain radical is eliminated and the antioxidant radical produced is stabilised by internal resonance. Secondary antioxidants decompose the hydroperoxide into harmless non-radical products. Where acidic decomposition products can themselves promote degradation, acid scavengers function by deactivating them. 

The competitive kinetics of Scheme 3.1 can also be applied to calibrate the unimolecular radical reactions provided that kn is a known rate constant. In particular the reaction of primary alkyl radicals with (Mc3Si)3SiH has been used to obtain kinetic data for some important unimolecular reactions such as the p-elimination of octanethiyl radical from 12 (Reaction 3.5) [12], the ring expansion of radical 13 (Reaction 3.6) [8] and the S-endo-trig cyclization of radical 14 (Reaction 3.7) [13]. The relative Arrhenius expressions shown below for the... 

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