Cyclohexyl radicals transfer reactions

However, when MAIs are thermolyzed in solution, the role of the cage effect has to be taken into account. The thermolytically formed macroradicals can, due to their size, diffuse only slowly apart from each other. Therefore, the number of combination events will be much higher for MAIs than for low-molecular weight AIBN derivatives. As was shown by Smith [16], the tendency toward radical combination depends significantly on the rigidity and the bulkiness of the chain. Species such as cyclohexyl or diphenylmethyl incorporated into the MAI s main chain lead to the almost quantitative combination of the radicals formed upon thermolysis. In addition, combination chain transfer reactions may... 

The interaction of alkyl halides with mercaptans or alkaline mercaptides prodnces thioalkyl derivatives. This is a typical nncleophilic substitution reaction, and one cannot tell by the nature of products whether or not it proceeds through the ion-radical stage. However, the version of the reaction between 5-bromo-5-nitro-l,3-dioxan and sodium ethylmercaptide can be explained only by the intermediate stage involving electron transfer. As found (Zorin et al. 1983), this reaction in DMSO leads to diethyldisulfide (yield 95%), sodium bromide (quantitative yield), and 5,5 -bis(5-nitro-l,3-dioxanyl) (yield 90%). UV irradiation markedly accelerates this reaction, whereas benzene nitro derivatives decelerate it. The result obtained shows that the process begins with the formation of ethylthiyl radicals and anion-radical of the substrate. Ethylthiyl radicals dimerize (diethyldisulfide is obtained), and anion-radicals of the substrate decompose monomolecularly to give 5-nitro-l,3-dioxa-5-cyclohexyl radicals. The latter radicals recombine and form the final dioxanyl (Scheme 4.4). 

The simple addition reaction in Scheme 19 illustrates how the notation is used. Ester (1) can be dissected into synthons (2), (3) and (4). Synthons for radical precursors (pro-radicals) possess radical sites ( ) A reagent that is an appropriate radical precursor for the cyclohexyl radical, such as cyclohexyl iodide, is the actual equivalent of synthon (2). By nature, alkene acceptors have one site that reacts with a radical ( ) and one adjacent radical site ( ) that is created upon addition of a radical. Ethyl acrylate is a reagent that is equivalent to synthon (3). Atom or group donors are represented as sites that react with radicals ( ) Tributyltin hydride is a reagent equivalent of (4). In practice, such analysis will usually focus on carbon-carbon bond forming reactions and the atom transfer step may be omitted in the notation for simplicity. 

Naito has also described analogous tandem radical addition-cyclization processes under iodine atom-transfer reaction conditions [16,32], Treatment of 186 with z-PrI (30 eq.) and triethylborane (3x3 eq.) in toluene at 100 °C gave, after cleavage from the resin, the desired lactam product 190 in 69% yield (Scheme 46). Similar reactions involving cyclohexyl iodide, cyclopentyl iodide, and butyl iodide were also reported as well as the reaction with ethyl radical from triethylborane [16,32], The relative stereochemistry of the products was not discussed. 

Enantiomerically pure bis-Gp derivatives with chiral Gp ligands have been used with success in the catalytic enantioselective opening of meso-epoxides via electron transfer (see Section 4.05.8). The structural features are of relevance for the understanding of activity and selectivity of these complexes in diastereoselective reactions and for the design of novel catalysts. A comparison of the structure of three of these bis-Gp Ti derivatives (Scheme 481) in the solid state and in solution determined by X-ray crystallography and NMR methods indicated that the structures in the crystal and in solution are the same, and that applications of these complexes in catalysis can de discussed on the basis of crystallographic data.1114 In a similar study, the 1-methylcyclohexyl-Cp, 1-butyl-1-methylbutyl-Cp, and cyclohexyl-Cp titanocene dichlorides (Scheme 481) have been prepared and their molecular structures compared. The use of these three compounds in radical addition reactions has been studied.1115... 

The chain mechanism which describes the perbenzoic decomposition in cyclohexane at the reflux temperature, becomes more complex but easy to understand [20, 29]. First of all, as PhCO 2 slowly loses C02 [41], it can lead (before decarboxylation), by H abstraction from the solvent, to PhC02H and the cyclohexyl radical (reaction (14)). Ph formed by reaction (12), has a low nucleophilic character [34]. Consequently it cannot transfer OH from the peracid but abstracts H from cyclohexane leading to PhH. Finally, Cy obtained by reactions (12)—(13) or (14) gives CyOH via reaction (15). 

This reaction proceeds by an initial hydrogen atom transfer from cyclohexane to Cr(Vl). The cyclohexyl radical is rapidly trapped by the chromium species via one of three pathways ... 

Chlorine transfer reactions. The rate constants and Arrhenius parameters of chlorine transfer reactions, given in Table II, were determined by competition studies in solutions that contained another compound, SX, in addition to the chloro-methane (CIM) or chloroethane (EtCl2) under investigation. The reaction of SX with cyclohexyl radicals C eaction 38) served as a reference. 

Table II. Rate Constants and Arrhenius Parameters of Cl Atom Transfer Reactions of Cyclohexyl Radicals Ce)...

Most of the useful iodine transfer radical reactions arise from the addition of alkyl iodides, which have been activated by one or more adjacent carbonyl or nitrile substituents, to unactivated olefins. This both labilizes the initial iodide, facilitating chain initiation, and helps ensure that the atom transfer step is exothermic. The requisite iodides are typically synthesized by deprotonation with EDA or NaH, followed by iodination with I2 or A-iodosuccinimide. Cyclization of an iodoester yields primarily lactone product, proceeding through the intermediacy of the I-transfer products as shown in Scheme 5 [19]. Reactions in which a-iodoesters cyclized with alkynes also proved efficient. Similar ketones yielded less synthetically useful mixtures of cyclopentyl and cyclohexyl (arising from 6-endo transition states) products. 

Exposure of 14 (m = 3, R = rcrf-Bu) to cyclohexyl iodide, allyltributylstannane, and AIBN leads to a macrocycle 15 with two new stereogenic centers. The allyl group provides additional functionality for further transformations and also creates a new stereocenter in the process. In order to effect the desired macrocyclization, addition of the first-formed radical to the proximal acrylamide moiety must be faster than addition to the chain transfer agent allyltributylstannane, a requirement that can be fulfilled under appropriate reaction conditions. Premature chain transfer in this particular system, under conditions that discourage bimolecular reaction between two templates, leads to two simple n = 1 products (vide infra). 

Li and coworkers reported the conjugate addition of alkyl groups to enamides mediated by zinc in aq. NH4CI to generate a -amino acid derivatives (Eq. 4.73). No reaction was observed in the absence of water. Both secondary and tertiary alkyl groups such as linear (2-butyl, 2-propyl, 2-pentyl), cyclic (cyclohexyl, cyclopentyl, cycloheptyl), and bulky ones (tert-butyl) were all transferred to the substrate successfully. Even simple primary iodides and methyl iodide provided the desired products in good yields. Miyabe et al. as well as Jang and Cho reported the addition of alkyl radicals from alkyl iodide to a,p unsaturated ketones, esters, and nitriles mediated by indium in aqueous media. Indium-mediated Michael addition of allyl bromide to l,l-dicyano-2-arylethenes also proceeded well in aqueous medium. ... 

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