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Electron transfer silyl enol ethers

Amination. The complexes (1) are very effective for aminating electron-rich silyl enol ethers, providing a-amino ketones. These are the first members of nitrogen transfer agents other than porphyrin derivatives. Usually, the reaction is conducted in the presence of (CFjC0)20 to acylate the amino group. [Pg.229]

Both the Af-fluorosulfonamides and the A -fluoroammonium salts are very effective in the fluormation of enol acetates, enamines, silyl enol ethers, and enolates (Table 2) The reactions are thought to proceed through a mechanism which involves Sf 2 attack on the fluorine atom, but contributions from electron-transfer pathways also exist [65, 68, 73, 75, 76, 79, 80, 81, 82]... [Pg.155]

Cyclic and acyclic silyl enol ethers can be nitrated with tetranitromethane to give ct-nitro ketones in 64-96% yield fEqs. 2.42 and 2.43. " The mechanism involves the electron transfer from the silyl enol ether to tetranitromethane. A fast homolydc conphng of the resultant cadon radical of silyl enol ether with NO leads tn ct-nitro ketones. Tetranitromethane is a neutral reagent it is commercially available or readdy prepared. " ... [Pg.16]

Mattay et al. examined the regioselective and stereoselective cyclization of unsaturated silyl enol ethers by photoinduced electron transfer using DCA and DCN as sensitizers. Thereby the regiochemistry (6-endo versus 5-exo) of the cyclization could be controlled because in the absence of a nucleophile, like an alcohol, the cyclization of the siloxy radical cation is dominant, whereas the presence of a nucleophile favors the reaction pathway via the corresponding a-keto radical. The resulting stereoselective cis ring juncture is due to a favored reactive chair like conformer with the substituents pseudoaxial arranged (Scheme 27) [36,37]. [Pg.201]

In addition to the former example, Pandey et al. achieved efficient a-aryla-tion of ketones by the reaction of silyl enol ethers with arene radical cations generated by photoinduced electron transfer from 1,4-dicyanonaphthalene. Using this strategy various five-, six-, seven-, and eight-membered benzannulated compounds are accessible in yields in the range 60-70% [39],... [Pg.202]

Pandey, G., Karthikeyan, M., and Mumgan, A. (1998) New intramolecular a-arylation strategy of ketones by the reaction of silyl enol ethers to photosensitized electron transfer generated arene radical cations construction of benzannulated and benzospiroannulated compounds. Journal of Organic Chemistry, 63, 2867-2872. [Pg.285]

A versatile strategy for efficient intramolecular oc-arylation of ketones was achieved by the reaction of silyle enol ethers with PET-generated arene radical cations. This strategy involved one-electron transfer from the excited methoxy-substituted arenes to ground-state DCN [42]. Pandey et al. reported the construction of five- to eight-membered benzannulated as well as benzospiroannulated compounds using this approach (Sch. 20) [42a]. The course of the reaction can be controlled via the silyl enol ether obtained... [Pg.280]

Similar to the deprotonation of enol radical cations, silyl enol ether radical cations can undergo loss of trialkylsilyl cations (most likely not as ionic silicenium ions [190]). Based on photoinduced electron transfer (PET), Gass-man devised a strategy for the selective deprotection of trimethylsilyl enol ethers in the presence of trimethylsilyl ethers [191]. Using 1-cyanonapthalene (1-CN) ( = 1.84 V) in acetonitrile/methanol or acetonitrile/water trimethylsilyl enol ether 93 ( j = 1.29 V) readily afforded cyclohexanone 64 in 60%. Mechanistically it was proposed that the silyl enol ether radical cation 93 undergoes O-Si bond cleavage, most likely induced by added methanol [192-194], and that radical 66 abstracts a hydrogen from methanol. Alternatively, back electron transfer from 1-CN - to 66 would yield the enolate of cyclohexanone which should be readily protonated by the solvent. [Pg.214]

The oxidation of ketones to enones via the reaction of their silyl enol ethers with 2,3-dichloro-5,6-dicyano-l,4-benzoquinone (DDQ) has been suggested originally to proceed via allylic hydride abstraction [195-198]. A recent reinvestigation, however, [199] has established the intermediate formation of a substrate-quinone adduct 96 which was presumably formed from a geminate radical ion pair after electron transfer. Decomposition of the adduct then finally afforded the observed enone product 97. Recently, the critical role of solvent polarity in the formation of 97 from the PET reaction of 93 and chloranil has been identified by time-resolved spectroscopy [200]. [Pg.214]

Oxidative coupling of silyl enol ethers as a useful synthetic method for carbon-carbon bond formation has been known for a long time. Several oxidants have been successfully applied to synthesize 1,4-diketones from silyl enol ethers, e.g. AgjO [201], Cu(OTf)2 [202], Pb(OAc)4 [203] and iodosobenzene/BFj EtjO [204]. Although some of these reagents above are known to react as one-electron oxidants, the potential involvement of silyl enol ether radical cations in the above reactions has not been studied. Some recent papers, however, have now established the presence of silyl enol ether radical cations in similar C-C bond formation reactions under well-defined one-electron oxidative conditions. For example, C-C bond formation was reported in the photoinduced electron transfer reaction of 2,3-dichIoro-1,4-naphthoquinone (98) with various silyl enol ethers 99 [205], From similar reactions with methoxy alkenes [206,207] it was assumed that, after photoexcitation, an ion radical pair is formed. [Pg.215]

This reaction was first reported by Mukaiyama et al. in 1974. It is a Lewis acid-catalyzed Michael conjugate addition of silyl enol ether to o ,/3-unsaturated compounds. Therefore, it is generally referred to as the Mukaiyama-Michael reaction. Because this reaction is essentially a conjugate addition, it is also known as the Mukaiyama-Michael addition or Mukaiyama-Michael conjugate addition. This reaction is a mechanistic complement for the base-catalyzed Michael addition, j and often occurs at much milder conditions and affords superior regioselectivity. s Besides silyl enol ether, silyl ketene acetals are also suitable nucleophiles in this reaction.For the hindered ketene silyl acetals, the Lewis acid actually mediates the electron transfer from the nucleophiles to o ,/3-unsaturated carbonyl molecules.On the other hand, the Q ,j8-unsaturated compounds, such as 3-crotonoyl-2-oxazolidinone, alkylidene malonates, and a-acyl-a,/3-unsaturated phosphonates are often applied as the Michael acceptors. It has been found that the enantioselectivity is very sensitive to the reactant structures —for example, Q -acyl-Q ,j8-unsaturated phosphonates especially prefers the unique syn- vs anft-diastereoselectivity in this reaction. In addition,... [Pg.1996]

The r-nucleophilicity and electron-transfer oxidation of silyl enol ethers and ketene silyl acetals has been studied by DFT, focusing on local softness and local nucle-ophilicity index as parameters for intramolecular reactivity and the corresponding group parameters for intermolecular reactivity. ... [Pg.39]

A kinetic study of reactions of 2,3-dichloro-5,6-dicyano-pflra-benzoquinone (140, DDQ) with silyl enol ethers, silyl ketene acetals, allylsilanes, enamino esters and diazomethanes has been carried out in acetonitrile and DCM, allowing correlations with nucleophilicity parameters for the latter species to be examined. These are found to be 2-5 orders of magnitude larger than expected for Single Electron Transfer processes, supporting a polar mechanism for C-C bond formation at C(5). However, rate constants for (9-attack do correlate well with calculated values assuming rate-determining SET. [Pg.49]


See other pages where Electron transfer silyl enol ethers is mentioned: [Pg.8]    [Pg.838]    [Pg.179]    [Pg.172]    [Pg.292]    [Pg.8]    [Pg.218]    [Pg.245]    [Pg.2418]    [Pg.255]    [Pg.174]    [Pg.163]    [Pg.305]    [Pg.394]    [Pg.242]    [Pg.383]    [Pg.133]    [Pg.372]    [Pg.405]    [Pg.92]    [Pg.112]    [Pg.259]    [Pg.838]    [Pg.173]   
See also in sourсe #XX -- [ Pg.201 ]




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