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Carbene Complexes with Group

Carbene Complexes with Group 1 and Group 2 Elements... [Pg.207]

Abstract The photoinduced reactions of metal carbene complexes, particularly Group 6 Fischer carbenes, are comprehensively presented in this chapter with a complete listing of published examples. A majority of these processes involve CO insertion to produce species that have ketene-like reactivity. Cyclo addition reactions presented include reaction with imines to form /1-lactams, with alkenes to form cyclobutanones, with aldehydes to form /1-lactones, and with azoarenes to form diazetidinones. Photoinduced benzannulation processes are included. Reactions involving nucleophilic attack to form esters, amino acids, peptides, allenes, acylated arenes, and aza-Cope rearrangement products are detailed. A number of photoinduced reactions of carbenes do not involve CO insertion. These include reactions with sulfur ylides and sulfilimines, cyclopropanation, 1,3-dipolar cycloadditions, and acyl migrations. [Pg.157]

The thermal benzannulation of Group 6 carbene complexes with alkynes (the Dotz reaction) is highly developed and has been used extensively in synthesis [90,91]. It is thought to proceed through a chromium vinylketene intermediate generated by sequential insertion of the alkyne followed by carbon monoxide into the chromium-carbene-carbon double bond [92]. The realization that photodriven CO insertion into Z-dienylcarbene complexes should generate the same vinylketene intermediate led to the development of a photochemical variant of the Dotz reaction (Table 14). [Pg.178]

Diaminocarbene complexes were reported as early as 1968 [152], Preparation and applications of such complexes have been reviewed [153], Because of 7t-electron donation by both nitrogen atoms, diaminocarbenes are very weak tt-acceptors and have binding properties towards low-valent transition metals similar to those of phosphines or pyridines [18,153]. For this reason diaminocarbenes form complexes with a broad range of different metals, including those of the titanium group. Titanium does not usually form stable donor-substituted carbene complexes, but rather ylide-like, nucleophilic carbene complexes with non-heteroatom-substituted carbenes (Chapter 3). [Pg.27]

Treatment of Fischer-type carbene complexes with different oxidants can lead to the formation of carbonyl compounds [150,253]. Treatment with sulfur leads to the formation of complexed thiocarbonyl compounds [141]. Conversion of the carbene carbon atom into a methylene or acetal group can be achieved by treatment with reducing agents. Treatment of vinylcarbene complexes with diborane can also lead to demetallation and formation of diols [278]. The conversion of heteroatom-substituted carbene complexes to non-heteroatom-substituted carbene complexes... [Pg.37]

Low-valent, 18-electron (Fischer-type) carbene complexes with strong n-acceptors usually are electrophilic at the carbene carbon atom (C ). These complexes can undergo reactions similar to those of free carbenes, e.g. cyclopropanation or C-H insertion reactions. The carbene-like character of these complexes becomes more pronounced when electron-accepting groups are directly bound to C (Chapter 4), whereas electron-donating groups strongly attenuate the reactivity (Chapter 2). [Pg.104]

The reaction of acceptor-substituted carbene complexes with alcohols to yield ethers is a valuable alternative to other etherification reactions [1152,1209-1211], This reaction generally proceeds faster than cyclopropanation [1176], As in other transformations with electrophilic carbene complexes, the reaction conditions are mild and well-suited to base- or acid-sensitive substrates [1212], As an illustrative example, Experimental Procedure 4.2.4 describes the carbene-mediated etherification of a serine derivative. This type of substrate is very difficult to etherify under basic conditions (e.g. NaH, alkyl halide [1213]), because of an intramolecular hydrogen-bond between the nitrogen-bound hydrogen and the hydroxy group. Further, upon treatment with bases serine ethers readily eliminate alkoxide to give acrylates. With the aid of electrophilic carbene complexes, however, acceptable yields of 0-alkylated serine derivatives can be obtained. [Pg.196]

If chiral catalysts are used to generate the intermediate oxonium ylides, non-racemic C-O bond insertion products can be obtained [1265,1266]. Reactions of electrophilic carbene complexes with ethers can also lead to the formation of radical-derived products [1135,1259], an observation consistent with a homolysis-recombination mechanism for 1,2-alkyl shifts. Carbene C-H insertion and hydride abstraction can efficiently compete with oxonium ylide formation. Unlike free car-benes [1267,1268] acceptor-substituted carbene complexes react intermolecularly with aliphatic ethers, mainly yielding products resulting from C-H insertion into the oxygen-bound methylene groups [1071,1093]. [Pg.205]

Figure 5 Steric repulsion between ruthenium-carbene complex with the silyloxy group in trans-substituents. Figure 5 Steric repulsion between ruthenium-carbene complex with the silyloxy group in trans-substituents.
The use of alkenes with chiral auxiliary groups leads to chiral cyclobutanones 4. Reaction yields of 50 67% and diastereomeric excesses of 86-97% were obtained for the 3-amidocy-clobutanones which were obtained from cycloaddition of the chromium carbene complexes with chiral ene carbamates (see also Section 1.3.4.3.3.).11... [Pg.222]

The more bulky 1-ethoxycyclopropyl group also induced a complete Z-diastereoselec-tivity to the Michael reaction of the ethynyl carbene complex with dimethylamine (equation 179)246. This is due to the sterically favored arm-position acquired by the bulky group in the intermediate. Unlike the parent cyclopropyl carbene complex, which gave only... [Pg.565]

Olefin metathesis has proved to be a powerful synthetic tool in organic synthesis.5 The advent of well-defined metal carbene complexes with remarkable functional group tolerance has rendered metathesis as an efficient route to the synthesis of new C-C bonds. Examples of widely used ruthenium metathesis catalysts include [Ru-1],6 [Ru-2]7 and [Ru-3] 8 (Figure 1). [Pg.316]

I would emphasize that the reaction of the amino acid-carbene complex with boron tribromide represents a good possibility of again cleaving the carbenyl protective group under extremely mild conditions at —25°C. [Pg.26]

The first group 1 carbene complex with an N-bound anionic functional group was reported in 2004.12 An alkylamino carbene is readily deprotonated using //-butyl lithium to afford 4 (Fig. 3). The solid state structure comprises a discrete dimer via bridging amido groups. Although there is severe distortion of the lithium-NCN bond (147.9° compared to the closer to linear 161.8° in 3), the lithium-NHC bond distance of 2.124(4) A is still short, suggesting that the interaction is predominantly ionic. [Pg.19]

Reaction of a monopyridyl functionalised imidazoUum salt with AgBF in the presence of a base (NaOH), a variant of the Ag O method since Ag O is usually synthesised from AgNOj and NaOH, yields a silver(I) bis-carbene complex with two pendant pyridyl functional groups [15] (see Figure 3.3). [Pg.57]

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Carbene complexes with group 13 elements

Carbene group

With Carbenes

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