Methylidenation

Imines. The group >C=NH is named either by the suffix -imine or by citing the name of the bivalent radical R R C< as a prefix to amine. For example, CH3CH2CH2CH=NH could be named 1-butanimine or butylideneamine. When the nitrogen is substituted, as in CH2=N—CH2CH3, the name is A-(methylidene)ethylamine. 

Methoxymethylene, 231 Ethoxymethylene, 231 Dimethoxymethylene, 232 1 -Methoxyethylidene, 232 1 -Ethoxyethylidine, 232 Methylidene, 233 Phthalide, 233... 

HOMO of triphenylphosphine-methylidene provides evidence for or against a fully-developed It bond. 

Examine the charge on the methylidene group, as well as the magnitude and direction of the molecule s dipole moment. Are they consistent with representation of the ylide as a hypervalent molecule or as a zwitterion ... 

Reaction of 2,3-dihydro-3-hydroxy-3-methyl- 240 (R = Me), or a mixture of 2,3-dihydro-3-hydroxy-3-aryl-57/-pyrido[l,2,3-dfe]-l,4-benzoxazin-5-ones 240 (R = Ar) and (8-aroylmethoxy)quinolin-2(l//)-ones 241 (R = Ar) with ethyl 2-(bromomethyl)acrylate in the presence of activated Zn and hydroquinone gave 8-[(2,3,4,5-tetrahydro-4-methylidene-5-oxo-2-furanyl)-methoxy]quinolin-2(l//)-ones (242) (97HCA1161). 6,7-Dihydro derivatives of 240 reacted similarly (00HCA349). 

Unfortunately, the highest enantioselectivity so far obtained for the synthesis of styrene oxide by this route is only 57 % ee with Goodman s sulfide 30 [21]. Thus methylidene transfer is not yet an effective strategy for the synthesis of terminal epoxides. 

Tetraphenylmolybdenocene dihydride Mo(r 5-C5HPh4)CpH2 (45) was formed by addition of diphenylacetylene to MoCpL(PhC CPh)CH3 (L = P(OMe)3) (Eq. 15), presumably via an ot-hydrogen abstraction to an intermediate methylidene hydrido complex, followed by addition of two equivalents of diphenylacetylene and C — H insertion with concomitant elimination of L [57 b],... 

The mechanistic investigations presented in this section have stimulated research directed to the development of advanced ruthenium precatalysts for olefin metathesis. It was pointed out by Grubbs et al. that the utility of a catalyst is determined by the ratio of catalysis to the rate of decomposition [31]. The decomposition of ruthenium methylidene complexes, which attribute to approximately 95% of the turnover, proceeds monomolecularly, which explains the commonly observed problem that slowly reacting substrates require high catalyst loadings [31]. This problem has been addressed by the development of a novel class of ruthenium precatalysts, the so-called second-generation catalysts. 

The methylidene complex [E] is the true catalyst, which as far as we can tell has the shortest half-life, and its reaction with an olefin produces ethylene as a by-product. 

A second metallacyclobutane [F] is formed via die reassociation of terminal olefin from discrete oligomers (or monomer) with the active methylidene, produced in [E] (see above). 

Leahy demonstrated that unsaturation at the 5-position of a 4-cyano-l,3-dioxane can lead to a reversal in selectivity [12] (Eq. 6). Alkylation of cyanohydrin acetonide 19 with benzyl bromide generated a 9 1 mixture of 20 and 21, with the flufz-isomer 20 predominating, in 57% overall yield. An alkylithium intermediate in which overlap with the methylidene tt orbital favors the axial configuration could account for this anomalous selectivity. 

Treatment of l,2 3,5-di-0-methylidene-6-0-tosyl-a-D-glucofuranose (310) with KF (in refl. ethylene glycol, 3 min) gave a mixture of 6-deoxy-6-fluoro (311, 60%), an alkene (312, 18%), and 6-0-(2-hydroxyethyl) derivatives (12%). 

The radical dissociation of the Gomberg dimer , [3-(diphenyl-methylidene)-6-(triphenylmethyl)-l,4-cyclohexadiene] [48], is familiar to organic chemists as the original observation of carbon-carbon a bond dissociation in a solution (Gomberg, 1900 Lankamp et al., 1968). The yellow colour of the triphenylmethyl radical in the benzene solution should have been an observation convincing synthetic organic chemists of the stable existence of the triphenylmethyl radical [8-j. 

Leconte and Basset [161-166] proposed two other possible mechanisms (Scheme 39) the first one implies a 1,2 carbon-carbon activation which invokes the de-insertion of a methylidene fragment from a surface metal-alkyl species, and the second implies a 1,3 carbon-carbon bond activation in which the key steps are the formation of a dimetallacyle by y-H activation from a metal-alkyl followed by carbon-carbon bond cleavage via a concerted electron transfer. 

The reaction of A A -Thiocarbonyldiimidazole (ImCSIm) with (methylidene)-triphenylphosphorane is carried out in analogy to that of CDI.[9]... 

The next task was removal of the C3,C3 -esters. Although the palladium-catalyzed decarboxylation protocol performed well in previous systems, a competing C-H insertion reaction was discovered with the methylidene bridge needed for cercosporin (see below). Since reexamination of alternate decarboxylation methods [48] led to no success, a decarbonylation strategy was explored [49]. Formation of the requisite dialdehyde was best accomplished by overreduction using DIB AL and... 

Alkylisoselenocyanates 339 are also used in the synthesis of 2-methylidene-l,3-selenazolidine derivatives <06T3344>. Nucleophilic addition of the carbanion derived from malononitrile 347 to 339 leads to an intermediate kcten-A, -acetal 348, which reacts with 2-haloacetate ester and 1,2-dibromoethane to provide l,3-selenazolidin-4-ones 350 and 1,3-selenazolidines 352, respectively. 

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