Free Radical and Related Addition Reactions

The reductive elimination of a variety of )3-substituted sulfones for the preparation of di-and tri-substituted olefins (e.g. 75 to 76) and the use of allyl sulfones as synthetic equivalents of the allyl dianion CH=CH—CHj , has prompted considerable interest in the [1,3]rearrangements of allylic sulfones ". Kocienski has thus reported that while epoxidation of allylic sulfone 74 with MCPBA in CH2CI2 at room temperature afforded the expected product 75, epoxidation in the presence of two equivalents of NaHCOj afforded the isomeric j ,y-epoxysulfone 77. Similar results were obtained with other a-mono- or di-substituted sulfones. On the other hand, the reaction of y-substituted allylic sulfones results in the isomerization of the double bond, only. The following addition-elimination free radical chain mechanism has been suggested (equations 45, 46). In a closely related and simultaneously published investigation, Whitham and coworkers reported the 1,3-rearrangement of a number of acyclic and cyclic allylic p-tolyl sulfones on treatment with either benzoyl peroxide in CCI4 under reflux or with... 

The same group recently disclosed a related free radical process, namely an efficient one-pot sequence comprising a homolytic aromatic substitution followed by an ionic Homer-Wadsworth-Emmons olefination, for the production of a small library of a,/3-unsaturated oxindoles (Scheme 6.164) [311]. Suitable TEMPO-derived alkoxy-amine precursors were exposed to microwave irradiation in N,N-dimethylformam-ide for 2 min to generate an oxindole intermediate via a radical reaction pathway (intramolecular homolytic aromatic substitution). After the addition of potassium tert-butoxide base (1.2 equivalents) and a suitable aromatic aldehyde (10-20 equivalents), the mixture was further exposed to microwave irradiation at 180 °C for 6 min to provide the a,jS-unsaturated oxindoles in moderate to high overall yields. A number of related oxindoles were also prepared via the same one-pot radical/ionic pathway (Scheme 6.164). 

Diels-Alder adduct from cyclopentadiene, 8 222t Diels-Alder reactions of, 25 488-489 economic aspects of, 25 507-509 electrophilic addition of, 25 490 in ene reactions, 25 490 esterification of, 25 491 free-radical reactions of, 25 491 from butadiene, 4 371 Grignard-type reactions of, 25 491 halogenation of, 15 491—492 health and safety factors related to, 25 510-511... 

Consideration of reasonable mechanisms for producing formic acid from an aldose led to the hypothesis that the sugar forms an addition product with the hydroperoxide anion, comparable with an aldehyde sulfite or the addition product of aldoses with chlorous acid (52). The intermediate product (12) could decompose by a free-radical or an ionic mechanism. In the absence of a free-radical catalyst, the ionic mechanism of Scheme VIII seems probable. By either mechanism the products are formic acid and the next lower sugar. The lower sugar then repeats the process, with the result that the aldose is degraded stepwise to formic acid. Addition of the hydroperoxide anion to the carbonyl carbon is in accord with its strong nucleophilic character (53) and with certain reaction mechanisms suggested in the literature (54) for related substances. 

The addition of HX to double bonds in the dark and in the absence of free-radical initiators is closely related to hydration The orientation of the elements of HX in the adduct always rnrrrsponds to Markownikoff addition 16 no deuterium exchange wish solvent is found in unreacted olefins recovered after partial reaction, nor is recovered starting material isomerized after partial reaction.17 However. the addition of HX apparently can proceed by a number of different mechanisms depending on the nature Ol the substrate and on the reaction conditions. Thus when HC1 is added to f-butylethylene in acetic acid, the rate is first-order in each reactant and the products are those shown in Equation 7.5.le Since 4 and 6 were demonstrated to be stable to the reaction conditions, the rearranged product (5) can be formed only if a carbocationic intermediate is formed during reaction. However, the carbocation exists almost solely in an intimate ion pair, and the rate of collapse of the ion pair to products must be faster than, or comparable to, the rate of diffusion of Cl- away from the carbocation. This must be so because the ratio of chloride to acetate products is unaffected by... 

Sibi and Chen [42] reported a related tandem intermolecular nucleophilic free-radical addition-trapping reaction of enoate 168 establishing chirality at both a and /(-centers with control over both absolute and relative stereochemistry (Scheme 9.30) using a Lewis acid catalyst and the bisoxazoline ligand 169. They observed... 

The oxidation of DMS is initiated by the hydroxyl free radical which either abstracts a hydrogen from DMS or undergoes an addition reaction (46-48). Kinetic isotope effects would be associated with these types of reactions. However, the remaining oxidation steps may involve larger equilibrium isotope effects resulting in heavier end products. These effects have not been measured. The S S values for sulfate and methane sulfonate should be related if they are derived from the same DMS pool (4 ). At this time there are no fi34S measurements for methane sulfonate or sulfate which are unambiguously from the oxidation of DMS. 

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