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Intermediate carbon-centered

Polymerization of the oxathiocinone 771 proceeded, in benzene at 40-70 °C, with complete ring-opening up to ca. 25% conversion. A two-step mechanism was involved addition of sulfanyl radical onto monomer exocyclic double bond to form the intermediate carbon centered radical 782 fragmentation of this latter yielding a new propagating sulfanyl radical and polymer backbone double bond (Scheme 152) <2005ASC1811>. [Pg.446]

The potential of this methodology is shown in equation (34) [76]. If the reaction occurs in the presence of oxygen, the intermediate carbon-centered radical could react with molecular oxygen prior to the hydrogen abstraction leading to a hydroperoxide (equation (35)) [77]. The reduction of other thiohydro-xamic acid esters has also been performed using t-BuSH in a similar fashion [78]. [Pg.328]

Cation-radicals are also known to undergo electron transfer with olefins The intermediate carbon centered cation-radical often dimerizes and polymerization may be initiated by the resulting dication. [Pg.16]

An interaction of the intermediate carbon-centered radical (A) with a neighboring carbon-carbon bond in this ring expansion leads to a transannular radical cyclization the treatment of the unsaturated decanols with (diacetoxyiodo) benzene-iodine followed by irradiation underwent fragmentation of intermediate allyloxy radicals (A) to give the bicyclo(5.3.0]decanones (40-78%) and to give the 7,5,5-tricycKc compound (81%) by way of a Billiard reaction, as outlined in Scheme 687 ... [Pg.2254]

Michael Additions and Other Radical Reactions. As decomposition of O-acyl thiohydroxamates provides radicals, these can subsequently participate in a variety of other reactions, the most common of which are Michael additions to electrondefi-cient alkenes. The most commonly successful pathway (eq 12) involves reaction of the intermediate carbon-centered radical adjacent to the electron-withdrawing group with a second molecule of the thiohydroxamate, rather than hydrogen abstraction, to give an a-5-pyridyl derivative, which can subsequently be manipulated in a variety of ways. Other thiohydroxamates can lead to higher yields the mildness and potential of this methodology is illustrated in eq 13. ... [Pg.224]

In peptide syntheses, where partial racemization of the chiral a-carbon centers is a serious problem, the application of 1-hydroxy-1 H-benzotriazole ( HBT") and DCC has been very successful in increasing yields and decreasing racemization (W. Kdnig, 1970 G.C. Windridge, 1971 H.R. Bosshard, 1973), l-(Acyloxy)-lif-benzotriazoles or l-acyl-17f-benzo-triazole 3-oxides are formed as reactive intermediates. If carboxylic or phosphoric esters are to be formed from the acids and alcohols using DCC, 4-(pyrrolidin-l -yl)pyridine ( PPY A. Hassner, 1978 K.M. Patel, 1979) and HBT are efficient catalysts even with tert-alkyl, choles-teryl, aryl, and other unreactive alcohols as well as with highly bulky or labile acids. [Pg.145]

Cycloalkoxy radical intermediates are readily generated from a parent alcohol by various methods (e.g., nitrite ester photolysis, hypohalite thermolysis, lead tetraacetate oxidation) (83MI1). Once formed, reactive cycloalkoxy radicals undergo /3-scission to produce a carbonyl compound and a new carbon-centered radical. [Pg.108]

The reaction starts with the nucleophilic addition of a tertiary amine 4 to the alkene 2 bearing an electron-withdrawing group. The zwitterionic intermediate 5 thus formed, has an activated carbon center a to the carbonyl group, as represented by the resonance structure 5a. The activated a-carbon acts as a nucleophilic center in a reaction with the electrophilic carbonyl carbon of the aldehyde or ketone 1 ... [Pg.28]

With alkali cyanides, a reaction via a SN2-mechanism takes place the alkyl halide is attacked by cyanide with the more nucleophilic carbon center rather than the nitrogen center, and the alkylnitrile is formed. In contrast, with silver cyanide the reaction proceeds by a SnI-mechanism, and an isonitrile is formed, since the carbenium intermediate reacts preferentially with the more electronegative center of the cyanide—i.e. the nitrogen (Kornblum s rule, HSAB concept). ... [Pg.185]

The aldehyde or ketone, when treated with aluminum triisopropoxide in isopropanol as solvent, reacts via a six-membered cyclic transition state 4. The aluminum center of the Lewis-acidic reagent coordinates to the carbonyl oxygen, enhancing the polar character of the carbonyl group, and thus facilitating the hydride transfer from the isopropyl group to the carbonyl carbon center. The intermediate mixed aluminum alkoxide 5 presumably reacts with the solvent isopropanol to yield the product alcohol 3 and regenerated aluminum triisopropoxide 2 the latter thus acts as a catalyst in the overall process ... [Pg.199]

The initial step of olefin formation is a nucleophilic addition of the negatively polarized ylide carbon center (see the resonance structure 1 above) to the carbonyl carbon center of an aldehyde or ketone. A betain 8 is thus formed, which can cyclize to give the oxaphosphetane 9 as an intermediate. The latter decomposes to yield a trisubstituted phosphine oxide 4—e.g. triphenylphosphine oxide (with R = Ph) and an alkene 3. The driving force for that reaction is the formation of the strong double bond between phosphorus and oxygen ... [Pg.294]

The wide variety of methods available for the synthesis of orga-noselenides,36 and the observation that the carbon-selenium bond can be easily cleaved homolytically to give a carbon-centered radical creates interesting possibilities in organic synthesis. For example, Burke and coworkers have shown that phenylselenolactone 86 (see Scheme 16), produced by phenylselenolactonization of y,S-unsaturated acid 85, can be converted to free radical intermediate 87 with triphenyltin hydride. In the presence of excess methyl acrylate, 87 is trapped stereoselectively, affording compound 88 in 70% yield 37 it is noteworthy that the intramolecular carbon-carbon bond forming event takes place on the less hindered convex face of bicyclic radical 87. [Pg.397]

There is evidence, both experimental and theoretical, that there are intermediates in at least some Sn2 reactions in the gas phase, in charge type I reactions, where a negative ion nucleophile attacks a neutral substrate. Two energy minima, one before and one after the transition state, appear in the reaction coordinate (Fig. 10.1). The energy surface for the Sn2 Menshutkin reaction (p. 499) has been examined and it was shown that charge separation was promoted by the solvent.An ab initio study of the Sn2 reaction at primary and secondary carbon centers has looked at the energy barrier (at the transition state) to the reaction. These minima correspond to unsymmetrical ion-dipole complexes. Theoretical calculations also show such minima in certain solvents, (e.g., DMF), but not in water. "... [Pg.393]

Several benzothiazinone analogs have been synthesized in an attempt to introduce hetero substituents at the a-carbon center in these heterocyclic compounds. The required a-halo-benzothiazinone intermediate 148 was prepared by chlorination with sulfiiryl chloride. This material was used successfully in an Arbuzov reaction to prepare the phosphonate diester 149,... [Pg.39]

Under low oxygen conditions, C5 -sugar radicals can react with the base residue on the same nucleotide. In purine nucleotides, the carbon-centered radical 91 can add to the C8-position of the nucleobase (Scheme 8.31). Oxidation of the intermediate nucleobase radical 92 yields the 8,5 -cyclo-2 -deoxypurine lesion 93197,224,225,230-233 Similarly, in pyrimidine nucleotides, the C5 -radical can add to the C6-position of nucleobase. Reduction of the resulting radical intermediate yields the 5, 6-cyclo-5,6-dihydro-2 -deoxypyrimidine lesion 94,234-236... [Pg.362]

It is necessary for the intermediate cation or complex to bear considerable car-bocationic character at the carbon center in order for effective hydride transfer to be possible. By carbocationic character it is meant that there must be a substantial deficiency of electron density at carbon or reduction will not occur. For example, the sesquixanthydryl cation l,26 dioxolenium ion 2,27 boron-complexed imines 3, and O-alkylated amide 4,28 are apparently all too stable to receive hydride from organosilicon hydrides and are reportedly not reduced (although the behavior of 1 is in dispute29). This lack of reactivity by very stable cations toward organosilicon hydrides can enhance selectivity in ionic reductions. [Pg.7]

Alternatively, unreactive mixtures of organosilicon hydrides and carbonyl compounds react by hydride transfer from the silicon center to the carbon center when certain nucleophilic species with a high affinity for silicon are added to the mixture.76 94 This outcome likely results from the formation of valence-expanded, pentacoordinate hydrosilanide anion reaction intermediates that have stronger hydride-donating capabilities than their tetravalent precursors (Eq. 6).22,95 101... [Pg.10]

See other pages where Intermediate carbon-centered is mentioned: [Pg.80]    [Pg.66]    [Pg.723]    [Pg.379]    [Pg.317]    [Pg.332]    [Pg.2257]    [Pg.80]    [Pg.66]    [Pg.723]    [Pg.379]    [Pg.317]    [Pg.332]    [Pg.2257]    [Pg.166]    [Pg.246]    [Pg.85]    [Pg.386]    [Pg.390]    [Pg.396]    [Pg.398]    [Pg.398]    [Pg.401]    [Pg.416]    [Pg.58]    [Pg.144]    [Pg.248]    [Pg.76]    [Pg.248]    [Pg.257]    [Pg.13]    [Pg.861]    [Pg.903]    [Pg.29]    [Pg.264]    [Pg.510]    [Pg.515]    [Pg.85]    [Pg.253]    [Pg.9]   
See also in sourсe #XX -- [ Pg.193 , Pg.194 , Pg.195 , Pg.249 ]



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Carbon centers

Carbon-centered

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